DS3181+ - Maxim Integrated

1 REV: 102406

Note: Some revisions of this device may incorporate deviations from published specifications known as errata. Multiple revisions of any device

may be simultaneously available through various sales channels. For information about device errata, click here: www.maxim-ic.com/errata.

GENERAL DESCRIPTION

The DS3181, DS3182, DS3183, and DS3184

(DS318x) integrate ATM cell/HDLC packet

processor(s) with a DS3/E3 framer(s) and LIU(s) to

map/demap ATM cells or packets into as many as

four DS3/E3 physical copper lines with DS3-framed,

E3-framed, or clear-channel data streams on per-port

basis.

APPLICATIONS

Access Concentrators

SONET/SDH ADM

Multiservice Access

Platform (MSAP)

SONET/SDH Muxes

PBXs

Multiservice Protocol

Platform (MSPP)

Digital Cross Connect

Test Equipment

ATM and Frame Relay

Equipment

Routers and Switches

Integrated Access

Device (IAD)

PDH Multiplexer/

Demultiplexer

ORDERING INFORMATION

PART TEMP RANGE PIN-PACKAGE

DS3181 0°C to +70°C 400 TE-PBGA (27mm x

27mm, 1.27mm pitch)

DS3181N -40°C to +85°C 400 TE-PBGA (27mm x

27mm, 1.27mm pitch)

DS3182 0°C to +70°C 400 TE-PBGA (27mm x

27mm, 1.27mm pitch)

DS3182N -40°C to +85°C 400 TE-PBGA (27mm x

27mm, 1.27mm pitch)

DS3183 0°C to +70°C 400 TE-PBGA (27mm x

27mm, 1.27mm pitch)

DS3183N -40°C to +85°C 400 TE-PBGA (27mm x

27mm, 1.27mm pitch)

DS3184 0°C to +70°C 400 TE-PBGA (27mm x

27mm, 1.27mm pitch)

DS3184N -40°C to +85°C 400 TE-PBGA (27mm x

27mm, 1.27mm pitch)

Note: Add the “+” suffix for the lead-free package option.

FUNCTIONAL DIAGRAM

DS318x

POS-PHY

UTOPIA

DS3/E3/STS-1

PORTS

DS3/E3/STS-1 LIU

DS3/E3

FRAMER/

FORMATTER

SYSTEM

INTERFACE

CELL/

PACKET

PROCESSOR

FEATURES

 Single (DS3181), Dual (DS3182), Triple

(DS3183), or Quad (DS3184) with Integrated LIU

ATM/Packet PHYs for DS3, E3, and Clear-

Channel 52Mbps (CC52)

 Pin Compatible for Ease of Port Density

Migration in the Same PC Board Platform

 Each Port Independently Configurable

 Perform Receive Clock/Data Recovery and

Transmit Waveshaping

 Jitter Attenuator can be Placed Either in the

Receive or Transmit Paths

 Interfaces to 75Ω Coaxial Cable at Lengths Up to

380 Meters or 1246 Feet (DS3) or 440 Meters or

1443 Feet (E3)

 Uses 1:2 Transformers on Both Tx and Rx

 Universal PHYs Map ATM Cells and/or HDLC

Packets into DS3 or E3 Data Streams

 UTOPIA L2/L3 or POS-PHY™ L2/L3 or SPI-3

Interface with 8-, 16-, or 32-Bit Bus Width

 66MHz UTOPIA L3 and POS-PHY L3 Clock

 52MHz UTOPIA L2 and POS-PHY L2 Clock

 Ports Independently Configurable for Cell or

Packet Traffic in POS-PHY Bus Modes

 Direct, PLCP, DSS, and Clear-Channel Cell

Mapping

DS3181/DS3182/DS3183/DS3184

Single/Dual/Triple/Quad

ATM/Packet PHYs with Built-In LIU

www.maxim-ic.com

POS-PHY and POS-PHY Level 3 are trademarks of PMC-Sierra, Inc.

DS3181/DS3182/DS3183/DS3184

FEATURES (continued)

 Direct and Clear-Channel Packet Mapping

 On-Chip DS3 (M23 or C-Bit) and E3 (G.751 or

G.832) Framer(s)

 Ports Independently Configurable for DS3, E3

(Full or Subrate) or Arbitrary Framing Protocols

Up to 52Mbps

 Programmable (Externally Controlled or

Internally Finite State Machine Controlled)

Subrate DS3/E3

 Full-Featured DS3/E3/PLCP Alarm Generation

and Detection

 Built-In HDLC Controllers with 256-Byte FIFOs

for Insertion/Extraction of DS3 PMDL, G.751 Sn

Bit, and G.832 NR/GC Bytes and PLCP NR/GC

Bytes

 On-Chip BERTs for PRBS and Repetitive Pattern

Generation, Detection, and Analysis

 Large Performance-Monitoring Counters for

Accumulation Intervals of at Least 1 Second

 Flexible Overhead Insertion/Extraction Ports for

DS3, E3, and PLCP Framers

 Loopbacks Include Line, Diagnostic, Framer,

Payload, Analog, and System Interface with

Capabilities to Insert AIS in the Directions Away

from Loopback Directions

 Ports can be Disabled to Reduce Power

 Integrated Clock Rate Adapter to Generate the

Remaining Internally Required 44.736MHz

(DS3), 34.368MHz (E3), and 52MHz (Arbitrary

Framing at Up to 52Mbps) from a Single Clock

Reference Source at One of Those Three

Frequencies

 Pin Compatible with the DS3171/2/3/4 Family

and the DS3161/2/3/4 Family

 8/16-Bit Generic Microprocessor Interface

 Low-Power (2.7W typ) 3.3V Operation (5V-

Tolerant I/O)

 Small, High-Density, Thermally Enhanced, BGA

Packaging (TE-PBGA) with 1.27mm Pin Pitch

 Industrial Temperature Operation:

-40°C to +85°C

 IEEE1149.1 JTAG Test Port

DETAILED DESCRIPTION

The DS3181 (single), DS3182 (dual), DS3183 (triple), and DS3184 (quad) PHYs perform all the functions

necessary for mapping/demapping ATM cells and/or packets into as many as four DS3 (44.736Mbps) framed, E3

(34.368Mbps) framed, or 52Mbps clear-channel data streams on DS3, E3, or STS-1 physical copper lines. Each

line interface unit (LIU) has independent receive and transmit paths. The receiver LIU block performs clock and

data recovery from a B3ZS- or HDB3-coded AMI signal and monitors for loss of the incoming signal or can be

bypassed for direct clock and data inputs. The receiver LIU block optionally performs B3ZS/HDB3 decoding. The

transmitter LIU drives standard pulse-shape waveforms onto 75Ω coaxial cable or can be bypassed for direct clock

and data outputs. The jitter attenuator can be placed in either transmit or receive data path when the LIU is

enabled. Dedicated cell processor and packet processor blocks prepare outgoing cells or packets for transmission

and check incoming cells or packets upon arrival. Built-in DS3/E3 framers transmit and receive cell/packet data in

properly formatted M23 DS3, C-bit DS3, G.751 E3, or G.832 E3 data streams. PLCP framers provide legacy ATM

transmission-convergence support. DSS scrambling is performed for clear-channel ATM cell support. With

integrated hardware support for both cells and packets, the DS318x DS3/E3 ATM/Packet PHYs provide system on-

chip solutions (from DS3/E3/STS-1 physical copper lines to ATM/Packet UTOPIA/POS-PHY Level 2/3 system

switch) for universal high-density line cards in the unchannelized DS3/E3/clear-channel DS3 ATM/Packet

applications. Unused functions can be powered down to reduce device power. The DS318x ATM/Packet PHYs with

embedded LIU conform to the telecommunications standards listed in Section 4.

DS3181/DS3182/DS3183/DS3184

TABLE OF CONTENTS

1 BLOCK DIAGRAMS 14

2 APPLICATIONS 15

3 FEATURE DETAILS 17

3.1 GLOBAL FEATURES .......................................................................................................................17

3.2 RECEIVE DS3/E3/STS-1 LIU FEATURES .......................................................................................17

3.3 RECEIVE DS3/E3 FRAMER FEATURES ...........................................................................................17

3.4 RECEIVE PLCP FRAMER FEATURES ..............................................................................................18

3.5 RECEIVE CELL PROCESSOR FEATURES .........................................................................................18

3.6 RECEIVE PACKET PROCESSOR FEATURES .....................................................................................18

3.7 RECEIVE FIFO FEATURES .............................................................................................................19

3.8 RECEIVE SYSTEM INTERFACE FEATURES .......................................................................................19

3.9 TRANSMIT SYSTEM INTERFACE FEATURES .....................................................................................19

3.10 TRANSMIT FIFO FEATURES ...........................................................................................................19

3.11 TRANSMIT CELL PROCESSOR FEATURES .......................................................................................19

3.12 TRANSMIT PACKET PROCESSOR FEATURES ...................................................................................19

3.13 TRANSMIT PLCP FORMATTER FEATURES ......................................................................................20

3.14 TRANSMIT DS3/E3 FORMATTER FEATURES ...................................................................................20

3.15 TRANSMIT DS3/E3/STS-1 LIU FEATURES .....................................................................................20

3.16 JITTER ATTENUATOR FEATURES ....................................................................................................20

3.17 CLOCK RATE ADAPTER FEATURES.................................................................................................20

3.18 HDLC OVERHEAD CONTROLLER FEATURES ..................................................................................20

3.19 FEAC CONTROLLER FEATURES ....................................................................................................21

3.20 TRAIL TRACE BUFFER FEATURES...................................................................................................21

3.21 BIT ERROR RATE TESTER (BERT) FEATURES................................................................................21

3.22 LOOPBACK FEATURES ...................................................................................................................21

3.23 MICROPROCESSOR INTERFACE FEATURES.....................................................................................21

3.24 SUBRATE FEATURES (FRACTIONAL DS3/E3)..................................................................................21

3.25 TEST FEATURES............................................................................................................................22

4 STANDARDS COMPLIANCE 23

5 ACRONYMS AND GLOSSARY 25

6 MAJOR OPERATIONAL MODES 26

6.1 DS3/E3 ATM/PACKET MODE ........................................................................................................26

6.2 DS3/E3 ATM/PACKET—OHM MODE ............................................................................................27

6.3 DS3/E3 INTERNAL FRACTIONAL (SUBRATE) ATM/PACKET MODE ...................................................28

6.4 DS3/E3 EXTERNAL FRACTIONAL (SUBRATE) ATM/PACKET MODE..................................................29

6.5 DS3/E3 FLEXIBLE EXTERNAL FRACTIONAL (SUBRATE) MODE CONFIGURATION MODE ....................30

6.6 DS3/E3 G.751 PLCP ATM MODE ................................................................................................31

6.7 DS3/E3 G.751 PLCP ATM—OHM MODE ....................................................................................32

6.8 CLEAR-CHANNEL ATM/PACKET MODE...........................................................................................34

6.9 CLEAR-CHANNEL ATM/PACKET—OHM MODE ..............................................................................35

6.10 CLEAR-CHANNEL OCTET ALIGNED ATM/PACKET—OHM MODE .....................................................36

7 MAJOR LINE INTERFACE OPERATING MODES 37

7.1 DS3HDB3/B3ZS/AMI LIU MODE .................................................................................................37

7.2 HDB3/B3ZS/AMI NON-LIU LINE INTERFACE MODE .......................................................................39

7.3 UNI LINE INTERFACE MODE ..........................................................................................................40

7.4 UNI LINE INTERFACE—OHM MODE ..............................................................................................41

8 PIN DESCRIPTIONS 42

DS3181/DS3182/DS3183/DS3184

8.1 SHORT PIN DESCRIPTIONS ............................................................................................................42

8.2 DETAILED PIN DESCRIPTIONS ........................................................................................................48

8.3 PIN FUNCTIONAL TIMING................................................................................................................66

8.3.1 Line IO.................................................................................................................................................. 66

8.3.2 DS3/E3 Framing and PLCP Overhead Functional Timing................................................................... 69

8.3.3 Internal (IFRAC) and External (XFRAC) Fractional DS3/E3 Overhead Functional Timing ................. 72

8.3.4 Flexible Fractional (FFRAC) DS3/E3 Overhead Interface Functinal Timing ....................................... 73

8.3.5 UTOPIA/POS-PHY/SPI-3 System Interface Functional Timing........................................................... 75

8.3.6 Microprocessor Interface Functional Timing ........................................................................................ 87

8.3.7 JTAG Functional Timing....................................................................................................................... 91

9 INITIALIZATION AND CONFIGURATION 92

9.1 MONITORING AND DEBUGGING ......................................................................................................94

9.1.1 Cell/Packet FIFO.................................................................................................................................. 94

9.1.2 Cell Processor...................................................................................................................................... 94

9.1.3 Packet Processor ................................................................................................................................. 95

10 FUNCTIONAL DESCRIPTION 96

10.1 PROCESSOR BUS INTERFACE ........................................................................................................96

10.1.1 8/16-Bit Bus Widths.............................................................................................................................. 96

10.1.2 Ready Signal (

RDY

) ............................................................................................................................. 96

10.1.3 Byte Swap Modes ................................................................................................................................ 96

10.1.4 Read-Write/Data Strobe Modes........................................................................................................... 96

10.1.5 Clear on Read/Clear on Write Modes .................................................................................................. 96

10.1.6 Global Write Method ............................................................................................................................ 97

10.1.7 Interrupt and Pin Modes....................................................................................................................... 97

10.1.8 Interrupt Structure ................................................................................................................................ 97

10.2 CLOCKS........................................................................................................................................99

10.2.1 Line Clock Modes................................................................................................................................. 99

10.2.2 Sources of Clock Output Pin Signals................................................................................................. 100

10.2.3 Line IO Pin Timing Source Selection ................................................................................................. 103

10.2.4 Clock Structures On Signal IO Pins ................................................................................................... 105

10.2.5 Gapped Clocks................................................................................................................................... 106

10.3 RESET AND POWER-DOWN..........................................................................................................107

10.4 GLOBAL RESOURCES ..................................................................................................................109

10.4.1 Clock Rate Adapter (CLAD)............................................................................................................... 109

10.4.2 8 kHz Reference Generation ............................................................................................................. 111

10.4.3 One-Second Reference Generation .................................................................................................. 113

10.4.4 General-Purpose IO Pins................................................................................................................... 113

10.4.5 Performance Monitor Counter Update Details................................................................................... 114

10.4.6 Transmit Manual Error Insertion ........................................................................................................ 115

10.5 PER-PORT RESOURCES ..............................................................................................................116

10.5.1 Loopbacks.......................................................................................................................................... 116

10.5.2 Loss Of Signal Propagation ............................................................................................................... 118

10.5.3 AIS Logic............................................................................................................................................ 118

10.5.4 Loop Timing Mode ............................................................................................................................. 121

10.5.5 HDLC Overhead Controller................................................................................................................ 121

10.5.6 Trail Trace .......................................................................................................................................... 121

10.5.7 BERT.................................................................................................................................................. 121

10.5.8 Fractional Payload Controller............................................................................................................. 122

10.5.9 PLCP/Fractional port pins .................................................................................................................. 122

10.5.10 Framing Modes .................................................................................................................................. 127

10.5.11 Mapping Modes.................................................................................................................................. 128

10.5.12 Line Interface Modes.......................................................................................................................... 132

10.6 UTOPIA/POS-PHY/SPI-3 SYSTEM INTERFACE...........................................................................134

10.6.1 General Description ........................................................................................................................... 134

10.6.2 Features ............................................................................................................................................. 134

10.6.6 System Interface Bus Controller ........................................................................................................ 135

DS3181/DS3182/DS3183/DS3184

10.7 ATM CELL/HDLC PACKET PROCESSING .....................................................................................139

10.7.1 General Description ........................................................................................................................... 139

10.7.2 Features ............................................................................................................................................. 139

10.7.3 Transmit Cell/Packet Processor......................................................................................................... 140

10.7.4 Receive Cell/Packet Processor.......................................................................................................... 141

10.7.5 Cell Processor.................................................................................................................................... 141

10.7.6 Packet Processor ............................................................................................................................... 146

10.7.7 FIFO ................................................................................................................................................... 148

10.7.8 System Loopback............................................................................................................................... 149

10.8 DS3/E3 PLCP FRAMER..............................................................................................................150

10.8.1 General Description ........................................................................................................................... 150

10.8.2 Features ............................................................................................................................................. 150

10.8.3 Transmit PLCP Frame Processor ...................................................................................................... 151

10.8.4 Receive PLCP Frame Processor ....................................................................................................... 151

10.8.5 Transmit DS3 PLCP Frame Processor .............................................................................................. 151

10.8.6 Receive DS3 PLCP Frame Processor ............................................................................................... 154

10.8.7 Transmit E3 PLCP Frame Processor................................................................................................. 155

10.8.8 Receive E3 PLCP Frame Processor.................................................................................................. 158

10.9 FRACTIONAL PAYLOAD CONTROLLER...........................................................................................160

10.9.1 General Description ........................................................................................................................... 160

10.9.2 Features ............................................................................................................................................. 160

10.9.3 Transmit Fractional Interface ............................................................................................................. 161

10.9.4 Transmit Fractional Controller............................................................................................................ 161

10.9.5 Receive Fractional Interface .............................................................................................................. 161

10.9.6 Receive Fractional Controller............................................................................................................. 161

10.10 DS3/E3 FRAMER/FORMATTER ....................................................................................................163

10.10.1 General Description ........................................................................................................................... 163

10.10.2 Features ............................................................................................................................................. 163

10.10.3 Transmit Formatter............................................................................................................................. 164

10.10.4 Receive Framer.................................................................................................................................. 164

10.10.5 C-bit DS3 Framer/Formatter .............................................................................................................. 168

10.10.6 M23 DS3 Framer/Formatter............................................................................................................... 171

10.10.7 G.751 E3 Framer/Formatter............................................................................................................... 174

10.10.8 G.832 E3 Framer/Formatter............................................................................................................... 176

10.10.9 Clear-Channel Frame Processor ....................................................................................................... 181

10.11 HDLC OVERHEAD CONTROLLER .................................................................................................181

10.11.1 General Description ........................................................................................................................... 181

10.11.2 Features ............................................................................................................................................. 182

10.11.3 Transmit FIFO .................................................................................................................................... 182

10.11.4 Transmit HDLC Overhead Processor ................................................................................................ 182

10.11.5 Receive HDLC Overhead Processor ................................................................................................. 183

10.11.6 Receive FIFO ..................................................................................................................................... 184

10.12 TRAIL TRACE CONTROLLER .........................................................................................................184

10.12.1 General Description ........................................................................................................................... 184

10.12.2 Features ............................................................................................................................................. 185

10.12.3 Functional Description........................................................................................................................ 185

10.12.4 Transmit Data Storage....................................................................................................................... 186

10.12.5 Transmit Trace ID Processor ............................................................................................................. 186

10.12.6 Transmit Trail Trace Processing ........................................................................................................ 186

10.12.7 Receive Trace ID Processor .............................................................................................................. 186

10.12.8 Receive Trail Trace Processing ......................................................................................................... 186

10.12.9 Receive Data Storage ........................................................................................................................ 187

10.13 FEAC CONTROLLER ...................................................................................................................188

10.13.1 General Description ........................................................................................................................... 188

10.13.2 Features ............................................................................................................................................. 188

10.13.3 Functional Description........................................................................................................................ 188

10.14 LINE ENCODER/DECODER ...........................................................................................................190

10.14.1 General Description ........................................................................................................................... 190

DS3181/DS3182/DS3183/DS3184

10.14.2 Features ............................................................................................................................................. 190

10.14.3 B3ZS/HDB3 Encoder ......................................................................................................................... 190

10.14.4 Transmit Line Interface ...................................................................................................................... 191

10.14.5 Receive Line Interface ....................................................................................................................... 191

10.14.6 B3ZS/HDB3 Decoder ......................................................................................................................... 191

10.15 BERT.........................................................................................................................................193

10.15.1 General Description ........................................................................................................................... 193

10.15.2 Features ............................................................................................................................................. 193

10.15.3 Configuration and Monitoring............................................................................................................. 193

10.15.4 Receive Pattern Detection ................................................................................................................. 194

10.15.5 Transmit Pattern Generation.............................................................................................................. 196

10.16 LINE INTERFACE UNIT (LIU).........................................................................................................197

10.16.1 General Description ........................................................................................................................... 197

10.16.2 Features ............................................................................................................................................. 197

10.16.3 Detailed Description ........................................................................................................................... 198

10.16.4 Transmitter ......................................................................................................................................... 198

10.16.5 Receiver ............................................................................................................................................. 199

11 OVERALL REGISTER MAP 202

12 REGISTER MAPS AND DESCRIPTIONS 204

12.1 REGISTERS BIT MAPS .................................................................................................................204

12.1.1 Global Register Bit Map ..................................................................................................................... 204

12.1.2 HDLC Register Bit Map...................................................................................................................... 207

12.1.3 T3 Register Bit Map ........................................................................................................................... 209

12.1.4 E3 G.751 Register Bit Map ................................................................................................................ 210

12.1.5 E3 G.832 Register Bit Map ................................................................................................................ 211

12.1.6 Clear-Channel Register Bit Map ........................................................................................................ 212

12.1.7 Fractional Register Bit Map................................................................................................................ 212

12.1.8 Transmit Cell Processor Bit Map ....................................................................................................... 215

12.1.9 Transmit Packet Processor Bit Map................................................................................................... 216

12.2 GLOBAL REGISTERS....................................................................................................................219

12.2.1 Register Bit Descriptions.................................................................................................................... 219

12.3 UTOPIA/POS-PHY SYSTEM INTERFACE.....................................................................................227

12.3.1 Transmit System Interface ................................................................................................................. 227

12.3.2 Receive System Interface Register Map............................................................................................ 229

12.4 PER-PORT COMMON ...................................................................................................................231

12.4.1 Per-Port Common Register Map........................................................................................................ 231

12.4.2 Per-Port Common Register Bit Descriptions...................................................................................... 231

12.5 BERT.........................................................................................................................................242

12.5.1 BERT Register Map ........................................................................................................................... 242

12.5.2 BERT Register Bit Descriptions ......................................................................................................... 242

12.6 B3ZS/HDB3 LINE ENCODER/DECODER.......................................................................................251

12.6.1 Transmit Side Line Encoder/Decoder Register Map ......................................................................... 251

12.6.2 Receive Side Line Encoder/Decoder Register Map .......................................................................... 252

12.7 HDLC.........................................................................................................................................256

12.7.1 HDLC Transmit Side Register Map.................................................................................................... 256

12.7.2 HDLC Receive Side Register Map..................................................................................................... 260

12.8 FEAC CONTROLLER ...................................................................................................................264

12.8.1 FEAC Transmit Side Register Map.................................................................................................... 264

12.8.2 FEAC Receive Side Register Map..................................................................................................... 267

12.9 TRAIL TRACE ..............................................................................................................................270

12.9.1 Trail Trace Transmit Side................................................................................................................... 270

12.9.2 Trail Trace Receive Side Register Map ............................................................................................. 272

12.10 DS3/E3 FRAMER ........................................................................................................................276

12.10.1 Transmit DS3 ..................................................................................................................................... 276

12.10.2 Receive DS3 Register Map................................................................................................................ 279

12.10.3 Transmit G.751 E3............................................................................................................................. 289

DS3181/DS3182/DS3183/DS3184

12.10.4 Receive G.751 E3 Register Map ....................................................................................................... 291

12.10.5 Transmit G.832 E3 Register Map ...................................................................................................... 297

12.10.6 Receive G.832 E3 Register Map ....................................................................................................... 300

12.10.7 Transmit Clear Channel ..................................................................................................................... 309

12.10.8 Receive Clear Channel ...................................................................................................................... 310

12.11 FRACTIONAL DS3/E3 ..................................................................................................................312

12.11.1 Fractional Transmit Side Register Map.............................................................................................. 312

12.11.2 Fractional Receive Side Register Map............................................................................................... 314

12.12 DS3/E3 PLCP............................................................................................................................316

12.12.1 Transmit Side PLCP........................................................................................................................... 316

12.12.2 Receive Side PLCP Register Map ..................................................................................................... 320

12.13 FIFO REGISTERS........................................................................................................................331

12.13.1 Transmit FIFO Register Map ............................................................................................................. 331

12.13.2 Receive FIFO Register Map .............................................................................................................. 335

12.14 CELL/PACKET PROCESSOR .........................................................................................................338

12.14.1 Transmit Cell Processor Register Map .............................................................................................. 338

12.14.2 Receive Cell Processor...................................................................................................................... 345

12.14.3 Transmit Packet Processor Register Map ......................................................................................... 357

12.14.4 Receive Packet Processor Register Map .......................................................................................... 362

13 JTAG INFORMATION 372

13.1 JTAG DESCRIPTION....................................................................................................................372

13.2 JTAG TAP CONTROLLER STATE MACHINE DESCRIPTION.............................................................373

13.3 JTAG INSTRUCTION REGISTER AND INSTRUCTIONS......................................................................375

13.4 JTAG ID CODES.........................................................................................................................376

13.5 JTAG FUNCTIONAL TIMING..........................................................................................................376

13.6 IO PINS ......................................................................................................................................376

14 PIN ASSIGNMENT 377

15 PACKAGE INFORMATION 380

15.1 400-LEAD TE-PBGA (27MM X 27MM, 1.27MM PITCH) (56-G6003-003) .......................................380

16 PACKAGE THERMAL INFORMATION 381

17 DC ELECTRICAL CHARACTERISTICS 382

18 AC TIMING CHARACTERISTICS 384

18.1 FRACTIONAL PORT CHARACTERISTICS .........................................................................................386

18.2 LINE INTERFACE AC CHARACTERISTICS.......................................................................................386

18.3 MISCELLANEOUS PIN AC CHARACTERISTICS................................................................................387

18.4 OVERHEAD PORT AC CHARACTERISTICS .....................................................................................387

18.5 SYSTEM INTERFACE AC CHARACTERISTICS .................................................................................388

18.6 MICRO INTERFACE AC CHARACTERISTICS ...................................................................................390

18.7 CLAD JITTER CHARACTERISTICS ................................................................................................393

18.8 LIU INTERFACE AC CHARACTERISTICS ........................................................................................393

18.8.1 Waveform Templates ......................................................................................................................... 393

18.8.2 LIU Input/Output Characteristics........................................................................................................ 397

18.9 JTAG INTERFACE AC CHARACTERISTICS ....................................................................................399

19 REVISION HISTORY 400

DS3181/DS3182/DS3183/DS3184

LIST OF FIGURES

Figure 1-1. LIU External Connections for a DS3/E3/STS-1 Port of a DS318x Device.............................................. 14

Figure 1-2. DS318x Functional Block Diagram ......................................................................................................... 14

Figure 2-1. Four-Port Unchannelized ATM over DS3/E3/CC52 Line Card ............................................................... 15

Figure 2-2. Four-Port Unchannelized HDLC over DS3/E3/CC52 Line Card.............................................................16

Figure 6-1. DS3/E3 ATM/Packet Mode ..................................................................................................................... 26

Figure 6-2. DS3/E3 ATM/Packet—OHM Mode ......................................................................................................... 27

Figure 6-3. DS3/E3 Internal Fractional ATM/Packet Mode ....................................................................................... 28

Figure 6-4. DS3/E3 External Fractional ATM/Packet Mode ...................................................................................... 29

Figure 6-5. DS3/E3 Flexible External Fractional Mode ............................................................................................. 30

Figure 6-6. DS3/E3 G.751 PLCP ATM Mode ............................................................................................................ 31

Figure 6-7. DS3/E3 G.751 PLCP ATM—OHM Mode................................................................................................ 33

Figure 6-8. Clear-Channel ATM/Packet Modes......................................................................................................... 34

Figure 6-9. Clear-Channel ATM/Packet—OHM Mode .............................................................................................. 35

Figure 6-10. Clear-Channel Octet Aligned ATM/Packet—OHM Mode...................................................................... 36

Figure 7-1. HDB3/B3ZS/AMI LIU Mode..................................................................................................................... 38

Figure 7-2. HDB3/B3ZS/AMI Non-LIU Line Interface Mode...................................................................................... 39

Figure 7-3. UNI Line Interface Mode ......................................................................................................................... 40

Figure 7-4. UNI Line Interface—OHM Mode ............................................................................................................. 41

Figure 8-1. TX Line IO B3ZS Functional Timing Diagram......................................................................................... 66

Figure 8-2. TX Line IO HDB3 Functional Timing Diagram ........................................................................................ 67

Figure 8-3. RX Line IO B3ZS Functional Timing Diagram......................................................................................... 67

Figure 8-4. RX Line IO HDB3 Functional Timing Diagram ........................................................................................ 68

Figure 8-5. TX Line IO UNI OHM Functional Timing Diagram .................................................................................. 68

Figure 8-6. TX Line IO UNI Octet Aligned OHM Functional Timing Diagram............................................................ 68

Figure 8-7. RX Line IO OHM UNI Functional Timing Diagram.................................................................................. 69

Figure 8-8. RX Line IO UNI Octet Aligned OHM Functional Timing Diagram ........................................................... 69

Figure 8-9. DS3 Framing Receive Overhead Port Timing......................................................................................... 69

Figure 8-10. E3 G.751 Framing Receive Overhead Port Timing .............................................................................. 70

Figure 8-11. E3 G.832 Framing Receive Overhead Port Timing .............................................................................. 70

Figure 8-12. DS3 Framing Transmit Overhead Port Timing...................................................................................... 70

Figure 8-13. E3 G.751 Framing Transmit Overhead Port Timing ............................................................................. 70

Figure 8-14. E3 G.832 Framing Transmit Overhead Port Timing ............................................................................. 71

Figure 8-15. DS3 PLCP Receive Overhead Port Timing........................................................................................... 71

Figure 8-16. E3 G.751 PLCP Receive Overhead Port Timing .................................................................................. 71

Figure 8-17. DS3 PLCP Transmit Overhead Port Timing.......................................................................................... 71

Figure 8-18. E3 G.751 PLCP Transmit Overhead Port Timing ................................................................................. 72

Figure 8-19. External (XFRAC) Transmit Fractional Timing...................................................................................... 72

Figure 8-20. External (XFRAC) Receive Fractional Timing....................................................................................... 72

Figure 8-21. Internal (IFRAC) Transmit Fractional Timing ........................................................................................ 73

Figure 8-22. Internal (IFRAC) Receive Fractional Timing ......................................................................................... 73

Figure 8-23. Transmit Flexible Fractional (FFRAC) Timing....................................................................................... 74

Figure 8-24. Receive Flexible Fractional (FFRAC) Timing........................................................................................ 74

Figure 8-25. UTOPIA Level 2 Transmit Cell Transfer Direct Mode ........................................................................... 75

Figure 8-26. UTOPIA Level 2 Receive Cell Transfer Direct Mode ............................................................................ 76

Figure 8-27. UTOPIA Level 2 Transmit Multiple Cell Transfer Polled Mode............................................................. 77

Figure 8-28. UTOPIA Level 2 Receive Multiple Cell Transfer Polled Mode.............................................................. 77

Figure 8-29. UTOPIA Level 2 Receive Unexpected Multiple Cell Transfer............................................................... 78

Figure 8-30. UTOPIA Level 3 Transmit Multiple Cell Transfer Direct Mode.............................................................. 78

Figure 8-31. UTOPIA Level 3 Transmit Multiple Cell Transfer Polled Mode............................................................. 79

Figure 8-32. UTOPIA Level 3 Receive Multiple Cell Transfer Direct Mode............................................................... 80

Figure 8-33. UTOPIA Level 3 Receive Multiple Cell Transfer Polled Mode.............................................................. 80

Figure 8-34. Transmit Multiple Packet Transfer to Different PHY ports (direct status mode) ................................... 81

Figure 8-35. POS-PHY Level 2 Receive Multiple Packet Transfer from Different

PHY Ports/Devices(direct status mode)............................................................................................................ 82

Figure 8-36. POS-PHY Level 2 Transmit Multiple Packet Transfer to Different PHY Ports (polled status mode) .... 83

Figure 8-37. POS-PHY Level 2 Receive Multiple Packet Transfer (polled status mode).......................................... 84

Figure 8-38. POS-PHY Level 3 Transmit Multiple Packet Transfer In-Band Addressing.......................................... 85

DS3181/DS3182/DS3183/DS3184

Figure 8-39. POS-PHY Level 3 Receive Multiple Packet Transfer In-Band Addressing........................................... 86

Figure 8-40. 16-Bit Mode Write.................................................................................................................................. 87

Figure 8-41. 16-Bit Mode Read ................................................................................................................................. 87

Figure 8-42. 8-Bit Mode Write.................................................................................................................................... 88

Figure 8-43. 8-Bit Mode Read ................................................................................................................................... 88

Figure 8-44. 16-Bit Mode without Byte Swap ............................................................................................................ 89

Figure 8-45. 16-Bit Mode with Byte Swap ................................................................................................................. 89

Figure 8-46. Clear Status Latched Register on Read................................................................................................ 90

Figure 8-47. Clear Status Latched Register on Write................................................................................................ 90

Figure 8-48. RDY Signal Functional Timing Writes ................................................................................................... 90

Figure 8-49. RDY Signal Functional Timing Read..................................................................................................... 91

Figure 10-1. Interrupt Structure ................................................................................................................................. 98

Figure 10-2. Internal TX Clock................................................................................................................................. 101

Figure 10-3. Internal RX Clock ................................................................................................................................ 102

Figure 10-4. Example IO Pin Clock Muxing............................................................................................................. 106

Figure 10-5. Reset Sources..................................................................................................................................... 107

Figure 10-6. CLAD Block ......................................................................................................................................... 110

Figure 10-7. 8KREF Logic ....................................................................................................................................... 112

Figure 10-8. Performance Monitor Update Logic .................................................................................................... 115

Figure 10-9. Transmit Error Insert Logic.................................................................................................................. 116

Figure 10-10. Loopback Modes............................................................................................................................... 117

Figure 10-11. ALB Mux............................................................................................................................................ 117

Figure 10-12. AIS Signal Flow ................................................................................................................................. 120

Figure 10-13. DS3 C-Bit or DS3 M23 (with C-Bit Generation) Frame..................................................................... 128

Figure 10-14. DS3 PLCP Frame.............................................................................................................................. 129

Figure 10-15. DS3 M23 (with C-Bits Used as Payload) Frame............................................................................... 130

Figure 10-16. E3 G.751 Frame................................................................................................................................ 130

Figure 10-17. E3 PLCP Frame ................................................................................................................................ 131

Figure 10-18. Example E3 G.751 Internal Fractional Frame................................................................................... 131

Figure 10-19. E3 G.832 Frame................................................................................................................................ 132

Figure 10-20. System Interface Functional Diagram............................................................................................... 134

Figure 10-21. Normal Packet Format in 32-Bit Mode .............................................................................................. 135

Figure 10-22. Normal Packet Format in 16-Bit Mode .............................................................................................. 135

Figure 10-23. Byte Reordered Packet Format in 32-Bit Mode ................................................................................ 135

Figure 10-24. Byte Reordered Packet Format in 16-Bit Mode ................................................................................ 136

Figure 10-25. ATM Cell/HDLC Packet Functional Diagram .................................................................................... 139

Figure 10-26. Receive DSS Scrambler Synchronization State Diagram................................................................. 143

Figure 10-27. Cell Delineation State Diagram ......................................................................................................... 144

Figure 10-28. HEC Error Monitoring State Diagram................................................................................................ 145

Figure 10-29. Cell Format for 53-Byte Cell With 32-Bit Data Bus ........................................................................... 145

Figure 10-30. Cell Format for 52-Byte Cell With 32-Bit Data Bus ........................................................................... 146

Figure 10-31. PLCP Framer Functional Diagram .................................................................................................... 150

Figure 10-32. DS3 PLCP Frame Format ................................................................................................................. 152

Figure 10-33. DS3 PLCP G1 Byte Format .............................................................................................................. 152

Figure 10-34. E3 PLCP Frame Format.................................................................................................................... 156

Figure 10-35. E3 PLCP G1 Byte Format ................................................................................................................. 156

Figure 10-36. Fractional Payload Controller Detailed Block Diagram ..................................................................... 160

Figure 10-37. Data Group Format ........................................................................................................................... 162

Figure 10-38. Frame Format.................................................................................................................................... 162

Figure 10-39. Framer Detailed Block Diagram ........................................................................................................ 163

Figure 10-40. DS3 Frame Format............................................................................................................................ 165

Figure 10-41. DS3 Sub-Frame Framer State Diagram............................................................................................ 166

Figure 10-42. DS3 Multiframe Framer State Diagram............................................................................................. 167

Figure 10-43. G.751 E3 Frame Format ................................................................................................................... 174

Figure 10-44. G.832 E3 Frame Format ................................................................................................................... 176

Figure 10-45. MA Byte Format ................................................................................................................................ 177

Figure 10-46. HDLC Controller Block Diagram ....................................................................................................... 182

Figure 10-47. Trail Trace Controller Block Diagram ................................................................................................ 185

Figure 10-48. Trail Trace Byte (DT = Trail Trace Data)........................................................................................... 187

DS3181/DS3182/DS3183/DS3184

Figure 10-49. FEAC Controller Block Diagram........................................................................................................ 188

Figure 10-50. FEAC Codeword Format................................................................................................................... 189

Figure 10-51. Line Encoder/Decoder Block Diagram.............................................................................................. 190

Figure 10-52. B3ZS Signatures ............................................................................................................................... 192

Figure 10-53. HDB3 Signatures............................................................................................................................... 192

Figure 10-54. BERT Block Diagram ........................................................................................................................ 193

Figure 10-55. PRBS Synchronization State Diagram.............................................................................................. 195

Figure 10-56. Repetitive Pattern Synchronization State Diagram........................................................................... 196

Figure 10-57. LIU Functional Diagram..................................................................................................................... 197

Figure 10-58. DS3/E3/STS-1 LIU Block Diagram.................................................................................................... 198

Figure 10-59. Receiver Jitter Tolerance .................................................................................................................. 201

Figure 13-1. JTAG Block Diagram........................................................................................................................... 372

Figure 13-2. JTAG TAP Controller State Machine .................................................................................................. 373

Figure 13-3. JTAG Functional Timing...................................................................................................................... 376

Figure 14-1. DS3184 Pin Assignments—400-Lead TE-PBGA................................................................................ 377

Figure 14-2. DS3183 Pin Assignments—400-Lead TE-PBGA................................................................................ 378

Figure 14-3. DS3182 Pin Assignments—400-Lead TE-PBGA................................................................................ 378

Figure 14-4. DS3181 Pin Assignments—400-Lead TE-PBGA................................................................................ 379

Figure 18-1. Clock Period and Duty Cycle Definitions............................................................................................. 384

Figure 18-2. Rise Time, Fall Time, and Jitter Definitions......................................................................................... 384

Figure 18-3. Hold, Setup, and Delay Definitions (Rising Clock Edge) .................................................................... 384

Figure 18-4. Hold, Setup, and Delay Definitions (Falling Clock Edge).................................................................... 385

Figure 18-5. To/From High-Z Delay Definitions (Rising Clock Edge)...................................................................... 385

Figure 18-6. To/From High-Z Delay Definitions (Falling Clock Edge) ..................................................................... 385

Figure 18-7. Micro Interface Nonmultiplexed Read/Write Cycle ............................................................................. 391

Figure 18-8. Micro Interface Multiplexed Read Cycle.............................................................................................. 392

Figure 18-9. E3 Waveform Template....................................................................................................................... 395

Figure 18-10. STS-1 Pulse Mask Template ............................................................................................................ 396

Figure 18-11. DS3 Pulse Mask Template................................................................................................................ 397

DS3181/DS3182/DS3183/DS3184

LIST OF TABLES

Table 4-1. Standards Compliance ............................................................................................................................. 23

Table 6-1. DS3/E3 ATM/Packet Mode Configuration Registers................................................................................ 26

Table 6-2. DS3/E3 ATM/Packet—OHM Mode Configuration Registers.................................................................... 27

Table 6-3. DS3/E3 Internal Fractional (IFRAC) ATM/Packet Mode Configuration Registers ................................... 28

Table 6-4. DS3/E3 External Fractional (XFRAC) ATM/Packet Mode Configuration Registers................................. 29

Table 6-5. DS3/E3 Flexible External Fractional (Subrate) Mode Configuration Registers........................................ 30

Table 6-6. DS3/E3 G.751 PLCP ATM Mode Configuration Registers ...................................................................... 31

Table 6-7. DS3/E3 G.751 PLCP ATM—OHM Mode Configuration Registers .......................................................... 32

Table 6-8. Clear-Channel ATM/Packet Mode Configuration Modes ......................................................................... 34

Table 6-9. Clear-Channel ATM/Packet—OHM Mode Configuration Registers......................................................... 35

Table 6-10. Clear-Channel Octet Aligned ATM/Packet—OHM Mode Configuration Registers................................ 36

Table 7-1. HDB3/B3ZS/AMI LIU Mode Configuration Registers ............................................................................... 37

Table 7-2. HDB3/B3ZS/AMI Non-LIU Mode Configuration Registers ....................................................................... 39

Table 7-3. UNI Line Interface Mode Configuration Registers.................................................................................... 40

Table 7-4. UNI Line Interface—OHM Mode Configuration Registers........................................................................ 41

Table 8-1. DS3184 Short Pin Descriptions................................................................................................................ 42

Table 8-2. Detailed Pin Descriptions ......................................................................................................................... 48

Table 9-1. Configuration of Global Register Settings ................................................................................................ 93

Table 9-2. Configuration of Port Register Settings .................................................................................................... 93

Table 10-1. LIU Enable Table.................................................................................................................................. 100

Table 10-2. All Possible Clock Sources Based on Mode and Loopback................................................................. 100

Table 10-3. Source Selection of TLCLK Clock Signal ............................................................................................. 101

Table 10-4. Source Selection of TCLKOn (internal TX clock) ................................................................................. 102

Table 10-5. Source Selection of RCLKO Clock Signal (internal RX clock) ............................................................. 102

Table 10-6. Transmit Line Interface Signal Pin Valid Timing Source Select ........................................................... 103

Table 10-7. Transmit Framer Pin Signal Timing Source Select .............................................................................. 104

Table 10-8. Receive Line Interface Pin Signal Timing Source Select ..................................................................... 104

Table 10-9. Receive Framer Pin Signal Timing Source Select ............................................................................... 105

Table 10-10. Reset and Power-Down Sources ....................................................................................................... 108

Table 10-11. CLAD IO Pin Decode.......................................................................................................................... 111

Table 10-12. Global 8 kHz Reference Source Table............................................................................................... 112

Table 10-13. Port 8 kHz Reference Source Table................................................................................................... 112

Table 10-14. GPIO Global Signals .......................................................................................................................... 113

Table 10-15. GPIO Pin Global Mode Select Bits..................................................................................................... 113

Table 10-16. GPIO Port Alarm Monitor Select ........................................................................................................ 114

Table 10-17. Loopback Mode Selections ................................................................................................................ 116

Table 10-18. Line AIS Enable Modes...................................................................................................................... 120

Table 10-19. Payload (Downstream) AIS Enable Modes........................................................................................ 121

Table 10-20. TSOFIn/TOHMIn Input Pin Functions ................................................................................................ 122

Table 10-21. TSERn/TPOHn/TFOHn Input Pin Functions ...................................................................................... 122

Table 10-22. TPDENIn/TPOHENn/TFOHENIn Input Pin Functions ....................................................................... 123

Table 10-23. TSOFOn/TDENn/TPOHSOFn/TFOHENOn Output Pin Functions .................................................... 123

Table 10-24. TCLKOn/TGCLKn/TPOHCLKn Output Pin Functions........................................................................ 124

Table 10-25. TPDATn Input Pin Functions.............................................................................................................. 124

Table 10-26. TPDENOn Output Pin Functions........................................................................................................ 124

Table 10-27. RSERn/RPOHn Output Pin Functions ............................................................................................... 125

Table 10-28. RPDENIn/RFOHENIn Input Pin Functions......................................................................................... 125

Table 10-29. RPDATn Input Pin Functions ............................................................................................................. 125

Table 10-30. RSOFOn/RDENn/RPOHSOFn/RFOHENOn Output Pin Functions................................................... 126

Table 10-31. RCLKOn/RGCLKn/RPOHCLKn Output Pin Functions ...................................................................... 126

Table 10-32. Framing Mode Select Bits FM[5:0] ..................................................................................................... 127

Table 10-33. Line Mode Select Bits LM[2:0]............................................................................................................ 133

Table 10-34. C-Bit DS3 Frame Overhead Bit Definitions ........................................................................................ 169

Table 10-35. M23 DS3 Frame Overhead Bit Definitions ......................................................................................... 171

Table 10-36. G.832 E3 Frame Overhead Bit Definitions......................................................................................... 177

Table 10-37. Payload Label Match Status............................................................................................................... 180

Table 10-38. Pseudorandom Pattern Generation.................................................................................................... 194

DS3181/DS3182/DS3183/DS3184

Table 10-39. Repetitive Pattern Generation ............................................................................................................ 194

Table 10-40. Transformer Characteristics ............................................................................................................... 199

Table 10-41. Recommended Transformers............................................................................................................. 200

Table 11-1. Global and Test Register Address Map ............................................................................................... 203

Table 11-2. Per-Port Register Address Map ........................................................................................................... 203

Table 12-1. Global Register Bit Map........................................................................................................................ 204

Table 12-2. System Interface Bit Map ..................................................................................................................... 205

Table 12-3. Port Register Bit Map ........................................................................................................................... 205

Table 12-4. BERT Register Bit Map ........................................................................................................................ 206

Table 12-5. LINE Register Bit Map .......................................................................................................................... 206

Table 12-6. HDLC Register Bit Map ........................................................................................................................ 207

Table 12-7. FEAC Register Bit Map ........................................................................................................................ 208

Table 12-8. Trail Trace Register Bit Map................................................................................................................. 208

Table 12-9. T3 Register Bit Map.............................................................................................................................. 209

Table 12-10. E3 G.751 Register Bit Map................................................................................................................. 210

Table 12-11. E3 G.832 Register Bit Map................................................................................................................. 211

Table 12-12. Clear-Channel Register Bit Map......................................................................................................... 212

Table 12-13. Fractional Register Bit Map ................................................................................................................ 212

Table 12-14. PLCP Register Bit Map....................................................................................................................... 213

Table 12-15. FIFO Register Bit Map........................................................................................................................ 214

Table 12-16. Transmit Cell Processor Register Bit Map ......................................................................................... 215

Table 12-17. Transmit Packet Processor Register Bit Map .................................................................................... 216

Table 12-18. Receive Cell Processor Register Bit Map .......................................................................................... 216

Table 12-19. Receive Packet Processor Register Bit Map ..................................................................................... 217

Table 12-20. Global Register Map........................................................................................................................... 219

Table 12-21. Transmit System Interface Register Map ........................................................................................... 227

Table 12-22. Receive System Interface Register Map ............................................................................................ 229

Table 12-23. Per-Port Common Register Map ........................................................................................................ 231

Table 12-24. BERT Register Map............................................................................................................................ 242

Table 12-25. Transmit Side B3ZS/HDB3 Line Encoder/Decoder Register Map ..................................................... 251

Table 12-26. Receive Side B3ZS/HDB3 Line Encoder/Decoder Register Map ...................................................... 252

Table 12-27. Transmit Side HDLC Register Map .................................................................................................... 256

Table 12-28. Receive Side HDLC Register Map ..................................................................................................... 260

Table 12-29. FEAC Transmit Side Register Map .................................................................................................... 264

Table 12-30. FEAC Receive Side Register Map ..................................................................................................... 267

Table 12-31. Transmit Side Trail Trace Register Map............................................................................................. 270

Table 12-32. Trail Trace Receive Side Register Map.............................................................................................. 272

Table 12-33. Transmit DS3 Framer Register Map .................................................................................................. 276

Table 12-34. Receive DS3 Framer Register Map ................................................................................................... 279

Table 12-35. Transmit G.751 E3 Framer Register Map .......................................................................................... 289

Table 12-36. Receive G.751 E3 Framer Register Map ........................................................................................... 291

Table 12-37. Transmit G.832 E3 Framer Register Map .......................................................................................... 297

Table 12-38. Receive G.832 E3 Framer Register Map ........................................................................................... 300

Table 12-39. Transmit Clear-Channel Register Map............................................................................................... 309

Table 12-40. Receive Clear-Channel Register Map................................................................................................ 310

Table 12-41. Fractional Transmit Side Register Map.............................................................................................. 312

Table 12-42. Receive Side Register Map................................................................................................................ 314

Table 12-43. Transmit Side PLCP Register Map .................................................................................................... 316

Table 12-44. Receive Side PLCP Register Map ..................................................................................................... 320

Table 12-45. Transmit FIFO Register Map.............................................................................................................. 331

Table 12-46. Receive FIFO Register Map............................................................................................................... 335

Table 12-47. Transmit Cell Processor Register Map............................................................................................... 338

Table 12-48. HEC Error Mask ................................................................................................................................. 341

Table 12-49. Receive Cell Processor Register Map................................................................................................ 345

Table 12-50. Transmit Packet Processor Register Map.......................................................................................... 357

Table 12-51. Receive Packet Processor Register Map........................................................................................... 362

Table 13-1. JTAG Instruction Codes ....................................................................................................................... 375

Table 13-2. JTAG ID Codes .................................................................................................................................... 376

Table 14-1. Pin Assignment Breakdown ................................................................................................................. 377

DS3181/DS3182/DS3183/DS3184

Table 17-1. Recommended DC Operating Conditions ............................................................................................ 382

Table 17-2. DC Electrical Characteristics................................................................................................................ 382

Table 17-3. Output Pin Drive ................................................................................................................................... 383

Table 18-1. Fractional Port Timing .......................................................................................................................... 386

Table 18-2. Line Interface Timing ............................................................................................................................ 386

Table 18-3. Miscellaneous Pin Timing..................................................................................................................... 387

Table 18-4. Overhead Port Timing .......................................................................................................................... 387

Table 18-5. System Interface L2 Timing.................................................................................................................. 388

Table 18-6. System Interface L3 Timing.................................................................................................................. 389

Table 18-7. Micro Interface Timing .......................................................................................................................... 390

Table 18-8. DS3 Waveform Template ..................................................................................................................... 393

Table 18-9. DS3 Waveform Test Parameters and Limits ........................................................................................ 393

Table 18-10. STS-1 Waveform Template................................................................................................................ 394

Table 18-11. STS-1 Waveform Test Parameters and Limits................................................................................... 394

Table 18-12. E3 Waveform Test Parameters and Limits......................................................................................... 395

Table 18-13. Receiver Input Characteristics—DS3 and STS-1 Modes................................................................... 397

Table 18-14. Receiver Input Characteristics—E3 Mode ......................................................................................... 398

Table 18-15. Transmitter Output Characteristics—DS3 and STS-1 Modes............................................................ 398

Table 18-16. Transmitter Output Characteristics—E3 Mode .................................................................................. 398

Table 18-17. JTAG Interface Timing........................................................................................................................ 399

DS3181/DS3182/DS3183/DS3184

1 BLOCK DIAGRAMS

Figure 1-1 shows the external components required at each LIU interface for proper operation. Figure 1-2 shows

the functional block diagram of one channel ATM/Packet PHY.

Figure 1-1. LIU External Connections for a DS3/E3/STS-1 Port of a DS318x Device

1:2ct

Transmit

Receive

TXP

TXN

RXP

RXN

0.01uF 3.3V

Power

Plane

Ground

Plane

VDD

Each T3/E3 LIU

0.1uF 1uF

330

Ω

(1%)

330

Ω

(1%)

0.01uF 0.1uF 1uF

VDD

VSS

Figure 1-2. DS318x Functional Block Diagram

TPOHSOFn/TSOFOn/

TDENn\TFOHENOn

RLCLKn

RXPn

RXNn

TPOSn/

TDATn

TNEGn/

TOHMOn/

TLCLKn

DS3/E3

Transmit

LIU

IEEE P1149.1

JTAG Test

Access Port

D[15:0]

A[10:1]

ALE

RD/DS

WR/ R/W

Microprocessor

Interface

JTDO

JTCLK

JTMS

JTDI

JTRST

HDLC

FEAC

TXPn

TXNn

LLB

DLB

DS3 / E3

Transmit

Formatter

DS3 / E3

Receive

Framer

Trail

Trace

Buffer

Tx Cell

Processor Tx

FIFO

System

Interface

Rx Cell

Processor

FIFO

ROHn

ROHCLKn

ROHSOFn

TOHn

TOHCLKn

TOHSOFn

TCLKIn

Tx Packet

Processor

RPOHn/RSERn

RPOHCLKn/

RCLKOn/

RPOHSOFn/RSOFOn/

RDENn/RFOHENOn

TSCLK

TADR[4:0]

TDATA[31:0]

TPRTY

TEN

TDXA[4:2]

TSOX

TEOP

TSPA

TSX

TMOD[1:0]

TERR

RSCLK

RADR[4:0]

RDATA[31:0]

RPRTY

REN

RDXA[1]/RPXA

RDXA[4:2]

RSOX

REOP

RVAL

RMOD[1:0]

RERR

SLB

Rx Packet

Processor

DS3/E3

Receive

LIU

TAIS

TUA1

TX FRAC/

PLCP

RX FRAC/

PLCP

TOHENn

Clock Rate

Adapter

TX BERT

RX BERT

CLKA

CLKB

CLKC

RFOHENIn/

MODE

INT

GPIO[8:1]

WIDTH

RDY

TPOHCLKN/

TCLKOn/TGCLKn

PLB

ALB

TOHMIn/TSOFIn

UA1

GEN

TPOHn/TFOHn/TSERn

TPOHENn/TFOHENIn/

TPDENIn

TPDENOn

TPDATn

RDATn

RPOSn/

RNEGn/

RLCVn/

ROHMIn

RPDENIn

RST

RPDATn

RGCLKn

A[0]/BSWAP

TDXA[1]/TPXA

/RSX

B3ZS/

HDB3

Encoder

B3ZS/

HDB3

Decoder

n = port # (1-4)

DS318x

DS3181/DS3182/DS3183/DS3184

2 APPLICATIONS

• Access Concentrators

• Multiservice Access Platforms

• ATM and Frame Relay Equipment

• Routers and Switches

• SONET/SDH ADM

• SONET/SDH Muxes

• PBXs

• Digital Cross Connect

• PDH Multiplexer/Demultiplexer

• Test Equipment

• Integrated Access Device (IAD)

Figure 2-1 and Figure 2-2 show applications for the DS3184 as four-port unchannelized ATM and packet DS3/E3

line cards, respectively.

Figure 2-1. Four-Port Unchannelized ATM over DS3/E3/CC52 Line Card

Typical ATM Line Card

DS3/E3

Line

Utopia

POS -

2/3

DS3154 #1

4-Chan

DS3/E

LIU

DS3164 #1

4-Chan

DS3/E

ATM

Switch

Card

(S/W+

Igr/Egr Mgt)

OC-12

DS3/E3

Line

DS3154 #3

4-Chan

DS3/E

LIU

DS3164 #3

4-Chan

DS3/E

ATM

Utopia

POS-

PHY

2/3

DS3/E3

Line

DS315x #1

4-Chan

DS3/E3

LIU

DS316x #1

4-Chan

DS3/E3

ATM

PHY

ATM

Switch

Card

(S/W+

Igr/Egr Mgt)

OC- n

ATM

DS3/E3

Line

DS315x #3

4-Chan

DS3/E3

LIU

DS316x #3

4-Chan

DS3/E3

ATM

PHY

POS-

DS318x

X = 1, 2, 3, 4

PHY

DS3181/DS3182/DS3183/DS3184

Figure 2-2. Four-Port Unchannelized HDLC over DS3/E3/CC52 Line Card

Typical Packet Line Card

DS3/E3

Line

Utopia

POS-

PHY

2/3

DS3154 #1

4-Chan

DS3/E

LIU

DS3164 #1

4-Chan

DS3/E

ATM

Switch

Card

(S/W+

Igr/Egr Mgt)

OC-12

DS3/E3

Line

DS3154 #3

4-Chan

DS3/E

LIU

DS3164 #3

4-Chan

DS3/E

ATM

Utopia

POS-

PHY

2/3

DS3/E3

Line

POS-

DS315x #1

4-Chan

DS3/E3

LIU

DS316x #1

4-Chan

DS3/E3

PKT

PHY

IP/PKT

Switch

Card

(S/W+

Igr/Egr Mgt)

OC- n

POS

DS3/E3

Line

DS315x #3

4-Chan

DS3/E3

LIU

DS316x #3

4-Chan

DS3/E3

PHY

POS-

DS318x

X = 1, 2, 3, 4

DS3181/DS3182/DS3183/DS3184

3 FEATURE DETAILS

The following sections describe the features provided by the DS3181 (single), DS3182 (dual), DS3183 (triple), and

DS3184 (quad) PHYs.

3.1 Global Features

• System interface configurable for UTOPIA L2/UTOPIA L3 for ATM cell traffic or POS-PHY L2/POS-PHY L3 or

SPI-3 for HDLC packets or mixed packet/cell traffic

• Supports the following transmission protocols:

• Direct-mapped ATM over DS3 or sub-rate DS3

• PLCP-mapped ATM over DS3

• Direct-mapped ATM over G.751 E3 or sub-rate G.751 E3

• PLCP-mapped ATM over G.751 E3

• Direct-mapped ATM over G.832 E3 or sub-rate G.832 E3

• Bit or byte synchronous (octet aligned) direct-mapped ATM over externally-defined frame formats up to

52 Mbps

• Clear-channel ATM (cell-based physical layer) at line rates up to 52 Mbps

• Clear-channel ATM DSS at line rates up to 52 Mbps

• Direct-mapped HDLC over DS3 or sub-rate DS3

• Direct-mapped HDLC over G.751 E3 or sub-rate G.751 E3

• Direct-mapped HDLC over G.832 E3 or sub-rate G.832 E3

• Bit or byte synchronous (octet aligned) direct-mapped HDLC over externally-defined frame formats up

to 52 Mbps

• Clear-channel HDLC at line rates up to 52 Mbps

• In UTOPIA bus mode, ports are independently configurable for any ATM protocol

• In POS-PHY bus mode, ports are independently configurable for any ATM or HDLC protocol

• Programmable to support internally or externally controlled sub-rate DS3 or E3 on any ports

• Supports gapped 52 MHz clock rates for signals embedded in SONET/SDH

• Optional transmit loop timed clock(s) mode using the associated port’s receive clock(s)

• Optional transmit clock mode using references generated by the internal Clock Rate Adapter (CLAD)

• Requires only a single reference clock for all three LIU data rates using internal CLAD

• The LIU can be powered down and bypassed for direct logic IO to/from line circuits.

• Jitter attenuator can be placed in either transmit or receive path when the LIU is enabled.

• Clock, data and control signals can be inverted for a direct interface to many other devices

• Detection of loss of transmit clock and loss of receive clock

• Automatic one-second, external or manual update of performance monitoring counters

• Each port can be placed into a low-power standby mode when not being used

• Framing and line code error insertion available

3.2 Receive DS3/E3/STS-1 LIU Features

• AGC/Equalizer block handles from 0 dB to 15 dB of cable loss

• Loss-of-lock PLL status indication

• Interfaces directly to a DSX monitor signal (20 dB flat loss) using built-in pre-amp

• Digital and analog Loss of Signal (LOS) detectors (ANSI T1.231 and ITU G.775)

• Per-channel power-down control

3.3 Receive DS3/E3 Framer Features

• Frame synchronization for M23 or C-bit Parity DS3, or G.751 E3 or G.832 E3

• B3ZS/HDB3/AMI decoding

• Detection and accumulation of bipolar violations (BPV), code violations (CV), excessive zeroes occurrences

(EXZ), F-bit errors, M-bit errors, FAS errors, LOF occurrences, P-bit parity errors, CP-bit parity errors, BIP-8

errors, and far end block errors (FEBE)

DS3181/DS3182/DS3183/DS3184

• Detection of RDI, AIS, DS3 idle signal, loss of signal (LOS), severely errored framing event (SEFE), change of

frame alignment (COFA), receipt of B3ZS/HDB3 code words, DS3 application ID bit, DS3 M23/C-bit format

mismatch, G.751 national bit, and G.832 RDI (FERF), payload type, and timing marker bits

• HDLC port for DS3 path maintenance data link (PMDL), G.751 national bit or G.832 NR or GC channels

• FEAC port for DS3 FEAC channel

• 16-byte Trail Trace Buffer port for G.832 trail access point identifier

• DS3 M23 C bits and stuff bits configurable as payload or overhead, stored in registers for software inspection

• Most framing overhead fields presented on the receive overhead port

• Support for internal and external subrate DS3/E3 control (Fractional DS3/E3)

3.4 Receive PLCP Framer Features

• PLCP frame synchronization

• C1 cycle/stuff counter interpretation

• Detection of out of frame (OOF), BIP-8 errors, FEBE and RAI (Yellow Signal)

• Frame timing can be presented on the GPIO2 output pin or used as the transmit PLCP reference

• All path overhead fields presented on the PLCP receive overhead port

• HDLC port for data link messages on F1, M1 or M2 bytes

• Trail Trace port for trace messages on F1 byte

3.5 Receive Cell Processor Features

• HEC-based cell delineation within the DS3/E3 frame, the PLCP frame, an externally defined frame, or the

entire line bandwidth

• Cell descrambling using the self-synchronizing scrambler (x43+1) for ATM over DS3/E3

• Distributed Sample Scrambler (DSS) for clear-channel ATM (cell-based physical layer)

• HEC error detection and correction; HEC discard

• Filtering of idle, unassigned and/or invalid cells (provisionable)

• Header pattern comparison vs. 32-bit header pattern and mask registers; counting of matching or non-

matching cells; discard of matching or non-matching cells

• Four-cell Receive FIFO

• Controls include enables/disables/settings for: cell processing, coset polynomial addition, error correction,

erred cell extraction, cell descrambling, idle/unassigned/invalid cell filtering, header pattern match

counting/discarding, LCD integration time

• Status fields include: out of cell delineation (OCD), loss of cell delineation (LCD) and receipt of idle,

unassigned, invalid, erred, corrected or header-pattern-match cells

• Performance monitoring counters for forwarded cells, corrected cells, uncorrectable cells, header pattern

match/no-match cells, and filtered idle/unassigned/invalid cells

• Octet alignment option for externally defined frame formats

3.6 Receive Packet Processor Features

• Packet descrambling using the self-synchronizing scrambler (x43+1)

• Flag detection, packet delineation, and inter-frame fill discard (flags and all-ones)

• Packet abort detection and accumulation

• Bit or octet destuffing

• FCS checking (16-bit or 32-bit), error accumulation, and FCS discard

• Packet size checking vs. programmable minimum and maximum size registers

• Abort declaration for packets with non-integral number of bytes

• Controls include enables/disables/settings for: packet processing, descrambling, 16/32-bit FCS, filtering of FCS

erred packets, FCS discard, minimum/maximum packet size

• Status fields include: receipt of FCS erred packet, aborted packet, size violation packet, non-integer-length

packets

• Performance monitoring counters for forwarded packets, forwarded bytes, aborted bytes, FCS erred packets,

aborted packets, size violation packets (min, max, non-integer-length)

• Octet alignment with octet destuffing option for externally defined frame formats

DS3181/DS3182/DS3183/DS3184

3.7 Receive FIFO Features

• Storage capacity for four cells or 256 bytes of packet data per port

• Programmable port address

• Programmable fill level thresholds

• Underflow and overflow status indications

3.8 Receive System Interface Features

• UTOPIA L2 / UTOPIA L3 interface in cell mode, POS-PHY L2 / POS-PHY L3 or SPI-3 interface in packet or

mixed traffic modes

• 8, 16, or 32-bit data bus at clock rates from 10 MHz to 66 MHz (52 MHz in L2 modes)

• Polled and direct cell available outputs

• Controls include enables/disables/settings for: HEC transfer, signal inversions, parity enable/polarity, cell

available deassertion time

3.9 Transmit System Interface Features

• UTOPIA L2 / UTOPIA L3 interface in cell mode, POS-PHY L2 / POS-PHY L3 or SPI-3 interface in packet or

mixed traffic modes

• 8, 16, or 32-bit data bus at clock rates from 10 MHz to 66 MHz (52 MHz in L2 modes)

• Polled and direct cell available outputs

• Controls include enables/disables/settings for: HEC transfer, signal inversions, parity enable/polarity, cell

available deassertion time

3.10 Transmit FIFO Features

• Storage capacity for four cells or 256 bytes of packet data per port

• Programmable port address

• Programmable fill level thresholds

• Underflow and overflow status indications

3.11 Transmit Cell Processor Features

• Programmable fill cell type

• HEC calculation and insertion/overwrite, including coset addition

• Cell scrambling using the self-synchronizing scrambler (x43+1) for ATM over DS3/E3

• Distributed Sample Scrambler (DSS) for clear-channel ATM (cell-based physical layer)

• Single-bit and multiple-bit header error insertion for diagnostics

• Controls include enables/disables/settings for: cell processing, HEC insertion, coset polynomial addition, cell

scrambling, fill cell type, error insertion type/rate/count, HEC bit corruption

• Counter for number of cells read from the transmit FIFO

• Cell mapping into the DS3/E3 frame, the PLCP frame, an externally defined frame, or the entire line bandwidth

• Octet alignment option for externally defined frame formats

3.12 Transmit Packet Processor Features

• FCS calculation (16-bit or 32-bit) and insertion/overwrite

• Programmable FCS error insertion for diagnostics

• Bit or octet stuffing

• Programmable inter-frame fill insertion (flags or all-ones)

• Automatic packet abort insertion

• Packet scrambling using the self-synchronizing scrambler (x43+1)

• Controls include enables/disables/settings for: packet processing, FCS insertion or overwrite, 16/32-bit FCS,

inter-frame fill type/length, scrambling, FCS error insertion type/rate/count

• Counters for number of packets and bytes read from the transmit FIFO

• Octet alignment with octet stuffing option for externally defined frame formats

DS3181/DS3182/DS3183/DS3184

3.13 Transmit PLCP Formatter Features

• Insertion of FAS bytes (A1, A2), path overhead identification (POI) bytes, and path overhead bytes

• Generation of BIP-8 (B1), FEBE and RAI (G1)

• C1 cycle/stuff counter generation referenced to GPIO4 input pin, referenced to the received PLCP timing, or

based on an 8 kHz division of one of the clock sources

• Automatic or manual insertion of FAS errors, BIP-8 errors

• All path overhead fields can be sourced from the PLCP transmit overhead port

• HDLC port for data link messages on F1, M1 or M2 bytes

• Trail Trace port for trace messages on F1 byte

3.14 Transmit DS3/E3 Formatter Features

• Insertion of framing overhead for M23 or C-bit parity DS3, or G.751 E3 or G.832 E3

• B3ZS/HDB3 encoding

• Generation of RDI, AIS, and DS3 idle signal

• Automatic or manual insertion of bipolar violations (BPVs), excessive zeroes (EXZ) occurrences, F-bit errors,

M-bit errors, FAS errors, P-bit parity errors, CP-bit parity errors, BIP-8 errors, and far end block errors (FEBE)

• HDLC port for DS3 path maintenance data link (PMDL), G.751 national bit or G.832 NR or GC channels

• FEAC port for DS3 FEAC channel can be configured to send one codeword, one codeword continuously, or

two different code words back-to-back to send DS3 Line Loopback commands

• 16-byte Trail Trace Buffer port for the G.832 trail access point identifier

• Insertion of G.832 payload type, and timing marker bits from registers

• DS3 M23 C bits configurable as payload or overhead; as overhead they can be controlled from registers or the

transmit overhead port

• Most framing overhead fields can be sourced from transmit overhead port

• Formatter bypass mode for clear-channel or externally defined format applications

• Support for subrate DS3/E3, internally or externally controlled (Fractional DS3/E3)

3.15 Transmit DS3/E3/STS-1 LIU Features

• Wide 50+20% transmit clock duty cycle

• Line Build-Out (LBO) control

• Tri-state line driver outputs support protection switching applications

• Per-channel power-down control

• Output driver monitor status indication

3.16 Jitter Attenuator Features

• Fully integrated and requiring no external components

• Can be placed in transmit or receive path

• FIFO depth of 16 bits

• Standard compliant transmission jitter and wander

3.17 Clock Rate Adapter Features

• Generation of the internally needed DS3 (44.736 MHz), E3 (34.368 MHz), and STS-1 (51.84 MHz) clocks a

from single input reference clock

• Input reference clock can be 51.84 MHz, 44.736MHz or 34.368 MHz

• Internally derived clocks can be used as references for LIU and jitter attenuator

• Derived clocks can be transmitted off-chip for external system use

• Standards compliant jitter and wander requirements.

3.18 HDLC Overhead Controller Features

• Each port has a dedicated HDLC controller for DS3/E3 framer or PLCP link management

• 256-byte receive and transmit FIFOs

• Handles all of the normal Layer 2 tasks including zero stuffing/destuffing, FCS generation/checking, abort

generation/checking, flag generation/detection, and byte alignment

• Programmable high and low water marks for the transmit and receive FIFOs

DS3181/DS3182/DS3183/DS3184

• Terminates the Path Maintenance Data Link in DS3 C-bit Parity mode and optionally the G.751 Sn bit or the

G.832 NR or GC channels or PLCP F1, M1 or M2 bytes

• RX data is forced to all ones during LOS, LOF and AIS detection to eliminate false packets

3.19 FEAC Controller Features

• Each port has a dedicated FEAC controller for DS3/E3 link management

• Designed to handle multiple FEAC code words without Host intervention

• Receive FEAC automatically validates incoming code words and stores them in a 4-byte FIFO

• Transmit FEAC can be configured to send one codeword, one codeword continuously, or two different code

words back-to-back to send DS3 Line Loopback commands

• Terminates the FEAC channel in DS3 C-Bit Parity mode and optionally the Sn bit in E3 mode

3.20 Trail Trace Buffer Features

• Each port has a dedicated Trail Trace Buffer for E3-G.832 or DS3/E3 PLCP link management

• Extraction and storage of the incoming G.832 or PLCP trail access point identifier in a 16-byte receive register

• Insertion of the outgoing trail access point identifier from a 16-byte transmit register

• Receive trace identifier unstable status indication

3.21 Bit Error Rate Tester (BERT) Features

• Each port has a dedicated BERT tester

• Generation and detection of pseudo-random patterns and repetitive patterns from 1 to 32 bits in length

• Pattern insertion/extraction in PLCP payload, DS3/E3 payload, DS3/E3 fractional payload or entire data stream

to and from the line interface

• Large 24-bit error counter allows testing to proceed for long periods without host intervention

• Errors can be inserted in the generated BERT patterns for diagnostic purposes (single bit errors or specific bit-

error rates)

3.22 Loopback Features

• Analog interface loopback – ALB (transmit to receive)

• Line facility loopback – LLB (receive to transmit) with optional transmission of unframed all-one AIS payload

toward system/trunk interface

• Framer diagnostic loopback – DLB (transmit to receive) with automatic transmission of DS3 AIS or unframed

all-one AIS signal toward line/tributary interface(s)

• DS3/E3 framer payload loopback – PLB (receive to transmit) with optional transmission of unframed all-one

AIS payload toward system/trunk interface

• System interface loopback – SLB (transmit to receive)

• Simultaneous line facility loopback and framer diagnostic loopback

3.23 Microprocessor Interface Features

• Multiplexed or non-multiplexed address bus modes

• 8 or 16-bit data bus modes

• Byte swapping option in 16-bit data bus mode

• Read/Write and Data Strobe modes

• Ready handshake output signal

• Global reset input pin

• Global interrupt output pin

• Two programmable I/O pins per port

3.24 Subrate Features (Fractional DS3/E3)

• Independent per-port built-in support for subrate DS3 or E3

• Independent subrate operation for both RX and TX data paths

• Subrate operation for each channel is totally independent from the other channels’ operation, i.e. all subrate

functions within the device are mutually exclusive

• Three distinct subrate algorithms:

DS3181/DS3182/DS3183/DS3184

• (FFRAC) Externally controlled with DS3 or E3 payload manipulating capability

• (XFRAC) Externally controlled with flexible DS3 or E3 data rate reduction capability

• (IFRAC) Internally controlled with simple DS3 or E3 data rate reduction capability

• Subrate algorithm selection is on per-port basis

• Internal subrate mechanism allows down to bit-level granularity of the DS3 or E3 payload

3.25 Test Features

• Five pin JTAG port

• All functional pins are in/out pins in JTAG mode

• Standard JTAG instructions: SAMPLE/PRELOAD, BYPASS, EXTEST, CLAMP, HIGHZ, IDCODE

• RAM BIST on all internal RAM

• High-Z pin to force all digital output and in/out pins into HIZ

• TEST pin for manufacturing scan test modes

DS3181/DS3182/DS3183/DS3184

4 STANDARDS COMPLIANCE

Table 4-1. Standards Compliance

SPECIFICATION SPECIFICATION TITLE

ANSI

T1.102-1993 Digital Hierarchy – Electrical Interfaces

T1.107-1995 Digital Hierarchy – Formats Specification

T1.231-1997 Digital Hierarchy – Layer 1 In-Service Digital Transmission Performance Monitoring

T1.404-1994 Network-to-Customer Installation – DS3 Metallic Interface Specification

T1.646-1995 Broadband ISDN – Physical Layer Specification for User-Network Interfaces Including

DS1/ATM

ATM FORUM

af-phy-0034.000 E3 Public UNI, August, 1995

af-phy-0039.000 UTOPIA Level 2, Version 1.0, June, 1995

af-phy-0043.000 A Cell-Based Transmission Convergence Sublayer for Clear-Channel Interfaces,

November, 1995

af-phy-0054.000 DS3 Physical Layer Interface Specification, January, 1996

af-phy-0136.000 UTOPIA L3 Physical Layer Interface, November, 1999

af-phy-0143.000 Frame-based ATM Interface (Level 3), March, 2000

af-bici-0013.003 BISDN Inter Carrier Interface (B-ICI) Specification Version 2.0 (Integrated), December, 1995

ETSI

ETS 300 686 Business TeleCommunications; 34Mbps and 140Mbits/s digital leased lines (D34U, D34S,

D140U and D140S); Network interface presentation, 1996

ETS 300 337

Transmission and Multiplexing (TM); Generic frame structures for the transport of various

signals (including Asynchronous Transfer Mode (ATM) cells and Synchronous Digital

Hierarchy (SDH) elements) at the ITU-T Recommendation G.702 hierarchical rates of 2 048

kbit/s, 34 368 kbit/s and 139 264 kbit/s, Second Edition, June, 1997

ETS EN 300 689 Access and Terminals (AT); 34Mbps Digital Leased Lines (D34U and D34S); Terminal

equipment interface, July 2001

ETS 300 689 Business TeleCommunications (BTC); 34 Mbps digital leased lines (D34U and D34S),

Terminal equipment interface, V 1.2.1, 2001-07

IETF

RFC 1661 The Point-to-Point Protocol (PPP), July, 1994

RFC 1662 PPP in HDLC-like Framing, July, 1994

RFC 2496 Definition of Managed Objects for the DS3/E3 Interface Type, January, 1999

ISO

ISO 3309:1993 Information Technology – Telecommunications & information exchange between systems –

High Level Data Link Control (HDLC) procedures – Frame structure, Fifth Edition, 1993

ITU-T

G.703 Physical/Electrical Characteristics of Hierarchical Digital Interfaces, 1991

G.704 Synchronous Frame Structures Used at 1544, 6312, 2048, 8488 and 44 736 kbit/s

Hierarchical Levels, July, 1995

G.751 Digital Multiplex Equipment Operating at the Third Order Bit Rate of 34,368 kbit/s and the

Fourth Order bit Rate of 139,264 kbit/s and Using Positive Justification, 1993

G.775 Loss Of Signal (LOS) and Alarm Indication Signal (AIS) Defect Detection and Clearance

Criteria, November, 1994

G.804 ATM Cell Mapping Into Plesiochronous Digital Hierarchy (PDH), November, 1993

G.823 The Control of Jitter and Wander Within Digital Networks Which are Based on the 2048

kbit/s Hierarchy, 1993

G.824 The Control of Jitter and Wander within Di

ital Networks that are Based on the 1544kb

DS3181/DS3182/DS3183/DS3184

SPECIFICATION SPECIFICATION TITLE

Hierarchy, 1993

G.832 Transport of SDH Elements on PDH Networks – Frame and Multiplexing Structures,

November, 1995

I.432 B-ISDN User-Network Interface – Physical Layer Specification, March, 1993

O.151 Error Performance Measuring Equipment Operating at the Primary Rate and Above,

October, 1992

Q.921 ISDN User-Network Interface – Data Link Layer Specification, March 1993

OIF

OIF-SPI3-01.0 System Packet Interface Level 3 (SPI-3): OC-48 System Interface for Physical and Link

Layer Devices

SATURN® GROUP

POS-PHY L2 POS-PHY Level 2 Packet Over SONET Interface Specification for Physical Layer Devices,

December, 1998

POS-PHY L3 POS-PHY Level 3 Packet Over SONET Interface Specification for Physical and Link Layer

Devices, June, 2000

TELCORDIA

GR-253-CORE SONET Transport Systems: Common Generic Criteria, Issue 2, December 1995

GR-499-CORE Transport Systems Generic Requirements (TSGR): Common Requirements, Issue 2,

December 1998

GR-820-CORE Generic Digital Transmission Surveillance, Issue 1, November 1994

IEEE

IEEE Std 1149-

1990

IEEE Standard Test Access Port and Boundary-Scan Architecture, (Includes IEEE Std

1149-1993) October 21, 1993

SATURN is a registered trademark of PMC-Sierra, Inc.

DS3181/DS3182/DS3183/DS3184

5 ACRONYMS AND GLOSSARY

Definition of the terms used in this data sheet:

Acronyms

• ATM – Asynchronous Transfer Mode

• CC52 – Clear-Channel 52 Mbps (STS-1 Clock Rate)

• CLAD – Clock Rate Adapter

• CLR – Clear-Channel Mode

• DSS – Distributed Sample Scrambler

• FFRAC – Flexible Fractional Mode

• FRM – Frame Mode

• HDLC – High Level Data Link Control

• IFRAC – Internal Fractional Mode

• OHM – Overhead Mask mode (LIU disabled) for externally defined framing

• PLCP – Physical Layer Convergence Protocol

• SPI-3 – same as POS-PHY L3

• XFRAC – External Fractional Mode

Glossary

• Cell – ATM cell

• Clear-Channel – A datastream with no framing included

• Fractional – Uses only a portion of available payload for data, also known as subrate

• Octet Aligned – Byte aligned

• Packet – HDLC packet

• Subrate – See Fractional

• Unchannelized – See Clear-Channel

DS3181/DS3182/DS3183/DS3184

6 MAJOR OPERATIONAL MODES

The major operational modes are determined by the FM[5:0] framer mode bits and a few other control bits. Unused

features are powered down and the data paths are held in reset. The configuration registers of the unused features

can be written to and read from. The function of some IO pins change in different operational modes. The line

interface operational mode is determined by the LM[2:0] bits.

6.1 DS3/E3 ATM/Packet Mode

DS3/E3 ATM/Packet mode is a normal mode of operation for the DS318x device, which maps/demaps ATM cells

or packet data into a DS3 or E3 data stream via the selected mapping mode. Major functional blocks for the

DS3/E3 ATM/Packet mode are shown in Figure 6-1. Mapping configuration is programmable on per-port basis and

is shown in Table 6-1.

Table 6-1. DS3/E3 ATM/Packet Mode Configuration Registers

MODE FM[5:0]

SIM[1:0]

GL.CR1

PMCPE

PORT.CR2

UTOPIA L2 ATM 0XX000 00 X

UTOPIA L3 ATM 0XX000 01 X

POS-PHY L2 ATM 0XX000 10 1

POS-PHY L3 ATM 0XX000 11 1

POS-PHY L2 Packet 0XX000 10 0

POS-PHY L3 Packet 0XX000 11 0

Figure 6-1. DS3/E3 ATM/Packet Mode

RLCLKn

RXPn

RXNn

TPOSn/

TDATn

TNEGn/

TOHMOn/

TLCLKn

DS3/E3

Transmit

LIU

IEEE P1149.1

JTAG Test

Access Port

Microprocessor

Interface

HDLC

FEAC

TXPn

TXNn

LLB

DLB

DS3 / E3

Transmit

Formatter

DS3 / E3

Receive

Framer

Trail

Trace

Buffer

Tx Cell

Processor Tx

FIFO

System

Interface

Rx Cell

Processor

FIFO

ROHn

ROHCLKn

ROHSOFn

TOHn

TOHCLKn

TOHSOFn

TCLKIn

Tx Packet

Processor

SLB

Rx Packet

Processor

DS3/E3

Receive

LIU

TAIS

TUA1

TOHENn

Clock Rate

Adapter

TX BERT

RX BERT

CLKA

CLKB

CLKC

PLB

ALB

TSOFIn

UA1

GEN

RDATn

RPOSn/

RNEGn/

RLCVn/

ROHMIn

RST

B3ZS/

HDB3

Encoder

B3ZS/

HDB3

Decoder

RCLKOn/

RGCLKn

TCLKOn/

TGCLKn

n = port # (1-4)

DS3181/DS3182/DS3183/DS3184

6.2 DS3/E3 ATM/Packet—OHM Mode

DS3/E3 ATM/Packet—OHM Mode is a normal mode of operation for the DS318x devices, which maps/demaps

ATM cells or packet data into a DS3 or E3 data stream, supporting externally defined framing protocols. Major

functional blocks for the DS3/E3 ATM/Packet—OHM Mode are shown in Figure 6-2. Mapping configuration is

programmable on per-port basis and is shown in Table 6-2.

Table 6-2. DS3/E3 ATM/Packet—OHM Mode Configuration Registers

MODE FM[5:0]

SIM[1:0]

GL.CR1

PMCPE

PORT.CR2

UTOPIA L2 ATM 0XX001 00 X

UTOPIA L3 ATM 0XX001 01 X

POS-PHY L2 ATM 0XX001 10 1

POS-PHY L3 ATM 0XX001 11 1

POS-PHY L2 Packet 0XX001 10 0

POS-PHY L3 Packet 0XX001 11 0

Figure 6-2. DS3/E3 ATM/Packet—OHM Mode

RLCLKn

RDATn

ROHMIn

TOHENn

TDATn

TOHMOn

TLCLKn

IEEE 1149.1

JTAG Test

Access Port

RST

Microprocessor

Interface

HDLC FEAC

LLB

DLB

DS3/E3

Transmit

Formatter

DS3/E3

Receive

Framer

Tx Cell

Processor Tx

FIFO

System

Interface

Rx Cell

Processor

FIFO

ROHn

ROHCLKn

ROHSOFn

TOHn

TOHCLKn

TOHSOFn

TCLKIn

SLB

TUA1

Clock Rate

Adapter

TX BERT

RX BERT

CLKA

CLKB

CLKC

TOHMIn

TCLKOn/TGCLKn

Tx Packet

Processor

Tx Packet

Processor

TRAIL

TRACE

UA1

GEN

RCLKOn/RGCLKn

n = port # (1-4)

Analog Loopback

DS3181/DS3182/DS3183/DS3184

6.3 DS3/E3 Internal Fractional (Subrate) ATM/Packet Mode

DS3/E3 Internal Fractional Mode allows subrate datastreams to be inserted into a DS3 or E3 line, with the

fractional overhead internally controlled. Major functional blocks for the DS3/E3 Internal Fractional Mode are shown

in Figure 6-3. Mapping configuration is programmable on per-port basis and is shown in Table 6-3.

The “-OHM” modes are not allowed in fractional framing modes since the user is not able to distinguish between

internal framing overhead and external framing overhead bit locations.

Table 6-3. DS3/E3 Internal Fractional (IFRAC) ATM/Packet Mode Configuration Registers

MODE FM[5:0]

SIM[1:0]

GL.CR1

PMCPE

PORT.CR2

UTOPIA L2 ATM 0XX010 00 X

UTOPIA L3 ATM 0XX010 01 X

POS-PHY L2 ATM 0XX010 10 1

POS-PHY L3 ATM 0XX010 11 1

POS-PHY L2 Packet 0XX010 10 0

POS-PHY L3 Packet 0XX010 11 0

Figure 6-3. DS3/E3 Internal Fractional ATM/Packet Mode

RLCLKn

RXPn

RXNn

TPOSn/

TDATn

TNEGn/

TOHMOn/

TLCLKn

DS3/E3

Transmit

LIU

IEEE P1149.1

JTAG Test

Access Port

Microprocessor

Interface

HDLC

FEAC

TXPn

TXNn

LLB

DLB

DS3 / E3

Transmit

Formatter

DS3 / E3

Receive

Framer

Trail

Trace

Buffer

Tx Cell

Processor Tx

FIFO

System

Interface

Rx Cell

Processor

FIFO

ROHn

ROHCLKn

ROHSOFn

TOHn

TOHCLKn

TOHSOFn

TCLKIn

Tx Packet

Processor

SLB

Rx Packet

Processor

DS3/E3

Receive

LIU

TAIS

TUA1

TOHENn

Clock Rate

Adapter

TX BERT

RX BERT

CLKA

CLKB

CLKC

PLB

ALB

TOHMIn/TSOFIn

UA1

GEN

RDATn

RPOSn/

RNEGn/

RLCVn/

ROHMIn

RST

B3ZS/

HDB3

Encoder

B3ZS/

HDB3

Decoder

RX FRAC

RCLKOn/RGCLKn

RSERn

RFOHENOn

TX FRAC

TFOHENOn

TFOHn

TCLKOn/TGCLKn

n = port # (1-4)

DS3181/DS3182/DS3183/DS3184

6.4 DS3/E3 External Fractional (Subrate) ATM/Packet Mode

DS3/E3 External Fractional Mode allows subrate datastreams to be inserted into a DS3 or E3 line, with the

fractional overhead externally controlled. Major functional blocks for the DS3/E3 Internal Fractional Mode are

shown in Figure 6-4. Mapping configuration is programmable on per-port basis and is shown in Table 6-4.

The “-OHM” modes are not allowed in fractional framing modes since the user cannot distinguish between internal

framing overhead and external framing overhead bit locations.

Table 6-4. DS3/E3 External Fractional (XFRAC) ATM/Packet Mode Configuration

Registers

MODE FM[5:0]

SIM[1:0]

GL.CR1

PMCPE

PORT.CR2

UTOPIA L2 ATM 0XX011 00 X

UTOPIA L3 ATM 0XX011 01 X

POS-PHY L2 ATM 0XX011 10 1

POS-PHY L3 ATM 0XX011 11 1

POS-PHY L2 Packet 0XX011 10 0

POS-PHY L3 Packet 0XX011 11 0

Figure 6-4. DS3/E3 External Fractional ATM/Packet Mode

RLCLKn

RXPn

RXNn

TPOSn/

TDATn

TNEGn/

TOHMOn/

TLCLKn

DS3/E3

Transmit

LIU

IEEE P1149.1

JTAG Test

Access Port

Microprocessor

Interface

HDLC

FEAC

TXPn

TXNn

LLB

DLB

DS3 / E3

Transmit

Formatter

DS3 / E3

Receive

Framer

Trail

Trace

Buffer

Tx Cell

Processor Tx

FIFO

System

Interface

Rx Cell

Processor

FIFO

ROHn

ROHCLKn

ROHSOFn

TOHn

TOHCLKn

TOHSOFn

TCLKIn

Tx Packet

Processor

SLB

Rx Packet

Processor

DS3/E3

Receive

LIU

TAIS

TUA1

TOHENn

Clock Rate

Adapter

TX BERT

RX BERT

CLKA

CLKB

CLKC

PLB

ALB

TOHMIn/TSOFIn

UA1

GEN

RDATn

RPOSn/

RNEGn/

RLCVn/

ROHMIn

RST

B3ZS/

HDB3

Encoder

B3ZS/

HDB3

Decoder

RX FRAC

RCLKOn/RGCLKn

RSERn

RSOFOn/RDENn

TX FRAC

TFOHENOn

TFOHn

TCLKOn/TGCLKn

RFOHENIn

TFOHENIn

n = port # (1-4)

DS3181/DS3182/DS3183/DS3184

6.5 DS3/E3 Flexible External Fractional (Subrate) Mode Configuration Mode

DS3/E3 Flexible External Fractional Mode allows subrate datastreams to be inserted into a DS3 or E3 line, with the

fractional overhead and payload externally multiplexed. Major functional blocks for the DS3/E3 Flexible External

Fractional Mode are shown in Figure 6-5. Mapping configuration is programmable on per-port basis and is shown

in Table 6-5.

The “-OHM” modes are not allowed in fractional framing modes since the user cannot distinguish between internal

framing overhead and external framing overhead bit locations.

Table 6-5. DS3/E3 Flexible External Fractional (Subrate) Mode Configuration Registers

MODE FM[5:0]

SIM[1:0]

GL.CR1

PMCPE

PORT.CR2

UTOPIA L2 ATM 0XX110 00 X

UTOPIA L3 ATM 0XX110 01 X

POS-PHY L2 ATM 0XX110 10 1

POS-PHY L3 ATM 0XX110 11 1

POS-PHY L2 Packet 0XX110 10 0

POS-PHY L3 Packet 0XX110 11 0

Figure 6-5. DS3/E3 Flexible External Fractional Mode

TSOFOn/TDENn

RLCLKn

RXPn

RXNn

TPOSn/

TDATn

TNEGn/

TOHMOn

TLCLKn

DS3/E3

Transmit

LIU

IEEE P1149.1

JTAG Test

Access Port

Microprocessor

Interface

HDLC

FEAC

TXPn

TXNn

LLB

DLB

DS3 / E3

Transmit

Formatter

DS3 / E3

Receive

Framer

Trail

Trace

Buffer

Tx Cell

Processor Tx

FIFO

System

Interface

Rx Cell

Processor

FIFO

ROHn

ROHCLKn

ROHSOFn

TOHn

TOHCLKn

TOHSOFn

TCLKIn

Tx Packet

Processor

RSERn

RSOFOn/RDENn

RCLKOn/RGCLKn

SLB

Rx Packet

Processor

DS3/E3

Receive

LIU

TAIS

TUA1

TOHENn

Clock Rate

Adapter

TX BERT

RX BERT

CLKA

CLKB

CLKC

TPDENIn

PLB

ALB

TSOFIn

UA1

GEN

TCLKOn/ TGCLKn

TSERn

TPDENOn

TPDATn

RDATn

RPOSn/

RNEGn/

RLCVn/

ROHMIn

RPDENIn

RST*

RPDATn

B3ZS/

HDB3

Encoder

B3ZS/

HDB3

Decoder

n = port # (1-4)

DS3181/DS3182/DS3183/DS3184

6.6 DS3/E3 G.751 PLCP ATM Mode

DS3/E3 G.751 PLCP ATM mode is a normal mode of operation for the DS318x devices, which maps/demaps ATM

cells into/from the DS3/E3 PLCP data stream. Major functional blocks for the DS3/E3 ATM/Packet mode are shown

in Figure 6-6. Mapping configuration is programmable on per-port basis and is shown in Table 6-6.

The PMCPE configuration bit is ignored when in PLCP mode and ATM cell processing is forced.

Table 6-6. DS3/E3 G.751 PLCP ATM Mode Configuration Registers

MODE FM[5:0]

SIM[1:0]

GL.CR1

PMCPE

PORT.CR2

UTOPIA L2 ATM 0XX100 00 X

UTOPIA L3 ATM 0XX100 01 X

POS-PHY L2 ATM 0XX100 10 1

POS-PHY L3 ATM 0XX100 11 1

POS-PHY L2 Packet 0XX100 10 0

POS-PHY L3 Packet 0XX100 11 0

Figure 6-6. DS3/E3 G.751 PLCP ATM Mode

TOHENn

TSOFIn

TPOHENn

TPOHSOFn

IEEE 1149.1

JTAG Test

Access Port

RST

Microprocessor

Interface

HDLC

FEAC

Tx Cell

Processor Tx

FIFO

System

Interface

Rx Cell

Processor

FIFO

ROHn

ROHCLKn

ROHSOFn

TOHn

TOHCLKn

TOHSOFn

TCLKIn

SLB

PLCP

RX PLCP

BERT

CLKA

CLKB

CLKC

RPOHn

RPOHCLKn/RCLKOn

RPOHSOFn

TPOHn

TRAIL

TRACE

UA1

GEN

RLCLKn

RXPn

RXNn

TPOSn/

TDATn

TNEGn/

TOHMOn/

TLCLKn

DS3/E3

Transmit

LIU

TXPn

TXNn

LLB

DLB

DS3/E3

Receive

LIU

TAIS

TUA1

Clock Rate

Adapter

ALB

RDATn

RPOSn/

RNEGn/

RLCVn/

ROHMIn

B3ZS/

HDB3

Encoder

B3ZS/

HDB3

Decoder

DS3 / E3

Transmit

Formatter

DS3 / E3

Receive

Framer

PLB

n = port # (1-4)

DS3181/DS3182/DS3183/DS3184

6.7 DS3/E3 G.751 PLCP ATM—OHM Mode

DS3/E3 G.751 PLCP ATM—OHM mode is a normal mode of operation for the DS318x devices, which

maps/demaps ATM cells into/from the DS3/E3 PLCP data stream, supporting externally defined framing modes.

Major functional blocks for the DS3/E3 G.751 PLCP ATM—OHM mode are shown in Figure 6-7. Mapping

configuration is programmable on per-port basis and is shown in Table 6-7.

The PMCPE configuration bit is ignored when in PLCP mode and ATM cell processing is forced.

Table 6-7. DS3/E3 G.751 PLCP ATM—OHM Mode Configuration Registers

MODE FM[5:0] SIM[1:0]

PMCPE

PORT.CR2

DS3 UTOPIA L2 ATM 0XX101 00 X

DS3 UTOPIA L3 ATM 0XX101 01 X

DS3 POS-PHY L2 ATM 0XX101 10 X

DS3 POS-PHY L3 ATM 0XX101 11 X

E3 G.751 UTOPIA L2 ATM 010101 00 X

E3 G.751 UTOPIA L3 ATM 010101 01 X

E3 G.751 POS-PHY L2 ATM 010101 10 X

E3 G.751 POS-PHY L3 ATM 010101 11 X

DS3181/DS3182/DS3183/DS3184

Figure 6-7. DS3/E3 G.751 PLCP ATM—OHM Mode

TOHENn

TPOHENn

TPOHSOFn

TDATn

TOHMOn

TLCLKn

IEEE 1149.1

JTAG Test

Access Port

Microprocessor

Interface

HDLC

FEAC

DS3/E3

Transmit

Formatter

DS3/E3

Receive

Framer

Tx Cell

Processor Tx

FIFO

System

Interface

Rx Cell

Processor

FIFO

ROHn

ROHCLKn

ROHSOFn

TOHn

TOHCLKn

TOHSOFn

TCLKIn

SLB

TX PLCP

RX PLCP

Clock Rate

Adapter

TX BERT

RX BERT

CLKA

CLKB

CLKC

RPOHn

RPOHCLKn/RCLKOn

RPOHSOFn

TPOHn

TPOHCLKn/

TCLKOn

RLCLKn

RDATn

ROHMIn

TRAIL

TRACE

UA1

GEN

LLB

DLB

TUA1

n = port # (1-4)

TOHMIn

Analog Loopback

DS3181/DS3182/DS3183/DS3184

6.8 Clear-Channel ATM/Packet Mode

The Clear-Channel ATM/Packet Mode maps/demaps ATM cells or HDLC packets into/from a serial datastream,

bypassing the DS3/E3 formatter/framer. Major functional blocks for the Clear-Channel ATM/Packet Mode are

shown in Figure 6-8. Mapping configuration is programmable on per-port basis and is shown in Table 6-8.

Table 6-8. Clear-Channel ATM/Packet Mode Configuration Modes

MODE FM[5:0]

SIM[1:0]

GL.CR1

PMCPE

PORT.CR2

UTOPIA L2 ATM 1XX0X0 00 X

UTOPIA L3 ATM 1XX0X0 01 X

POS-PHY L2 ATM 1XX0X0 10 1

POS-PHY L3 ATM 1XX0X0 11 1

POS-PHY L2 Packet 1XX0X0 10 0

POS-PHY L3 Packet 1XX0X0 11 0

Figure 6-8. Clear-Channel ATM/Packet Modes

RLCLKn

RXPn

RXNn

TPOSn/

TDATn

TNEGn/

TOHMOn/

TLCLKn

DS3/E3

Transmit

LIU

IEEE P1149.1

JTAG Test

Access Port

Microprocessor

Interface

TXPn

TXNn

LLB

DLB

Tx Cell

Processor Tx

FIFO

System

Interface

Rx Cell

Processor

FIFO

TCLKIn

Tx Packet

Processor

SLB

Rx Packet

Processor

DS3/E3

Receive

LIU

TAIS

TUA1

Clock Rate

Adapter

TX BERT

RX BERT

CLKA

CLKB

CLKC

PLB

ALB

UA1

GEN

RDATn

RPOSn/

RNEGn/

RLCVn/

ROHMIn

RST

B3ZS/

HDB3

Encoder

B3ZS/

HDB3

Decoder

RCLKOn/

RGCLKn

TCLKOn/

TGCLKn

n = port # (1-4)

DS3181/DS3182/DS3183/DS3184

6.9 Clear-Channel ATM/Packet—OHM Mode

The Clear-Channel ATM/Packet—OHM Mode maps/demaps ATM cells or HDLC packets into/from a serial

datastream, bypassing both the DS3/E3 formatter/framer and the LIU, supporting externally defined framing

modes. Major functional blocks for the Clear-Channel ATM/Packet—OHM Mode are shown in Figure 6-9. Mapping

configuration is programmable on per-port basis and is shown in Table 6-9.

Table 6-9. Clear-Channel ATM/Packet—OHM Mode Configuration Registers

MODE FM[5:0]

SIM[1:0]

GL.CR1

PMCPE

PORT.CR2

UTOPIA L2 ATM 1XX001 00 X

UTOPIA L3 ATM 1XX001 01 X

POS-PHY L2 ATM 1XX001 10 1

POS-PHY L3 ATM 1XX001 11 1

POS-PHY L2 Packet 1XX001 10 0

POS-PHY L3 Packet 1XX001 11 0

Figure 6-9. Clear-Channel ATM/Packet—OHM Mode

TCLKIn

TCLKOn

TDATn

TOHMOn

TLCLKn

IEEE 1149.1

JTAG Test

Access Port

RST

Microprocessor

Interface

LLB

DLB

Tx Cell

Processor Tx

FIFO

System

Interface

Rx Cell

Processor

FIFO

SLB

TUA1

Clock Rate

Adapter

TX BERT

RX BERT

CLKA

CLKB

CLKC

RLCLKn

RDATn

ROHMIn

Tx Packet

Processor

Rx Packet

Processor

UA1

GEN

RCLKOn

n = port # (1-4)

TOHMIn

Analog Loopback

DS3181/DS3182/DS3183/DS3184

6.10 Clear-Channel Octet Aligned ATM/Packet—OHM Mode

The Clear-Channel Octet Aligned ATM/Packet—OHM Mode maps/demaps ATM cells or HDLC packets into/from a

serial datastream, bypassing both the DS3/E3 formatter/framer and the LIU, supporting arbitrary framing modes.

Major functional blocks for the Clear-Channel Octet Aligned ATM/Packet—OHM Mode are shown in Figure 6-10.

Mapping configuration is programmable on per-port basis and is shown in Table 6-10.

Table 6-10. Clear-Channel Octet Aligned ATM/Packet—OHM Mode Configuration

Registers

MODE FM[5:0]

SIM[1:0]

GL.CR1

PMCPE

PORT.CR2

UTOPIA L2 ATM 1XX011 00 X

UTOPIA L3 ATM 1XX011 01 X

POS-PHY L2 ATM 1XX011 10 1

POS-PHY L3 ATM 1XX011 11 1

POS-PHY L2 Packet 1XX011 10 0

POS-PHY L3 Packet 1XX011 11 0

Figure 6-10. Clear-Channel Octet Aligned ATM/Packet—OHM Mode

TCLKIn

TCLKOn

RST

Clock Rate

Adapter

CLKA

CLKB

CLKC

Parallel to

Serial

Serial to

Parallel

RCLKOn

LLB

DLB

TUA1

Microprocessor

Interface

Tx Cell

Processor Tx

FIFO

System

Interface

Rx Cell

Processor

FIFO

SLB

TX BERT

RX BERT

Tx Packet

Processor

Rx Packet

Processor

IEEE 1149.1

JTAG Test

Access Port

UA1

GEN

TDATn

TOHMOn

TLCLKn

RLCLKn

RDATn

ROHMIn

n = port # (1-4)

TOHMIn

Analog Loopback

DS3181/DS3182/DS3183/DS3184

7 MAJOR LINE INTERFACE OPERATING MODES

The line interface modes provide the following functions:

1. Enabling/disabling of RX and TX LIU.

2. Enabling/Disabling of jitter attenuator (JA).

3. Selection of the location of JA, i.e., RX or TX path.

4. Selection of the line coding type, i.e., B3ZS/HDB3/AMI or UNI.

7.1 DS3HDB3/B3ZS/AMI LIU Mode

When the “- OHM” framing modes are enabled, the line interface is forced into the unipolar (UNI) mode. The

TZCDS and RZCDS bits in the line encoder/decoder block select between no encoding/decoding (AMI) and

encoding/decoding (B3ZS, HDB3). When the HDB3/B3ZS line decoder/encoder is enabled, the framing modes (FM

bits) select between B3ZS and HDB3 line coding. DS3 and CC52 frame modes select the B3ZS line code while the

E3 modes select the HDB3 line code.

Table 7-1. HDB3/B3ZS/AMI LIU Mode Configuration Registers

MODE LM[2:0]

LINE.TCR.TZSD

AND

LINE.RCR.RZSD

TLEN

PORT.CR2

JA Off, B3ZS or HDB3 001 0 0

JA RX, B3ZS or HDB3 010 0 0

JA TX, B3ZS or HDB3 011 0 0

JA Off, AMI 001 1 0

JA RX, AMI 010 1 0

JA TX, AMI 011 1 0

DS3181/DS3182/DS3183/DS3184

Figure 7-1. HDB3/B3ZS/AMI LIU Mode

n = port # (1-4)

RXPn

RXNn

TXPn

TXNn

LLB

DLB

DS3/E3

Receive

LIU

TAIS

TUA1

Clock Rate

Adapter

CLKA

CLKB

CLKC

ALB

B3ZS/

HDB3

Encoder

B3ZS/

HDB3

Decoder

FROM FRAMING LOGIC

OR EXTERNAL PINS

TO FRAMING LOGIC

OR EXTERNAL PINS

DS3/E3

Transmit

LIU

DS3181/DS3182/DS3183/DS3184

7.2 HDB3/B3ZS/AMI Non-LIU Line Interface Mode

The Non-LIU Line Interface Mode disables the LIU and a digital representation of AMI is output/input on the

TPOSn/TNEGn signals and the RPOSn/RNEGn signals. Selection between AMI and HDB3/B3ZS is made via the

LINE.TCR Register. HDB3 and B3ZS selection is controlled by the configuration selected by the FM bits. DS3 and

CC52 frame modes select the B3ZS line code while the E3 modes select the HDB3 line code. The DS3AIS signal

can only be generated in non-OHM DS3 modes.

Table 7-2. HDB3/B3ZS/AMI Non-LIU Mode Configuration Registers

MODE LM[2:0]

LINE.TCR.TZSD

AND

LINE.RCR.RZSD

TLEN

PORT.CR2

LIU Off, B3ZS or HDB3 000 0 1

LIU Off, AMI 000 1 1

Figure 7-2. HDB3/B3ZS/AMI Non-LIU Line Interface Mode

n = port # (1-4)

LLB

DLB

TAIS

TUA1

Clock Rate

Adapter

CLKA

CLKB

CLKC

B3ZS/

HDB3

Encoder

B3ZS/

HDB3

Decoder

FROM FRAMING LOGIC

OR EXTERNAL PINS

TO FRAMING LOGIC

OR EXTERNAL PINS

TPOSn

TNEGn

TLCLKn

RLCLKn

RPOSn

RNEGn

ALB

DS3181/DS3182/DS3183/DS3184

7.3 UNI Line Interface Mode

This mode is valid for all framing modes, providing a digital NRZ input/output on RDATn and TDATn and clocked

by RLCLKn and TLCLKn. The B3ZS/HDB3 decoder/encoder block is disabled except for the BPV counter, which is

used to count RLCV errors.

Table 7-3. UNI Line Interface Mode Configuration Registers

MODE LM[2:0]

LINE.TCR.TZSD

AND

LINE.RCR.RZSD

TLEN

PORT.CR2

Unipolar Mode 1XX X 1

Figure 7-3. UNI Line Interface Mode

TDATn

TLCLKn

n = port #

(1-4)

TUA1

Clock Rate

Adapter

CLKA

CLKB

CLKC

RLCLKn

RDATn

FROM FRAMING LOGIC

OR EXTERNAL PINS

TO FRAMING LOGIC

OR EXTERNAL PINS

ALB

LLB

DLB

DS3181/DS3182/DS3183/DS3184

7.4 UNI Line Interface—OHM Mode

The line interface is forced into UNI mode when the framer is in any OHM mode; therefore, the LM bits are Don’t

Cares. This mode is the same as the UNI Line Interface Mode except that the OHM pins determine whether the

data is payload or not.

Table 7-4. UNI Line Interface—OHM Mode Configuration Registers

MODE FM[5:0] LM[2:0]

LINE.TCR.TZSD

AND

LINE.RCR.RZSD

TLEN

PORT.CR2

DS3/E3 Overhead

Mask Mode 0XXX01 XXX X 1

Clear-Channel

Overhead Mask Mode 1XX0X1 XXX X 1

Figure 7-4. UNI Line Interface—OHM Mode

TDATn

TOHMOn

TLCLKn

n = port #

Line Loopback

Framer Diagnostic

Loopback

TUA1

Clock Rate

Adapter

CLKA

CLKB

CLKC

RLCLKn

RDATn

ROHMIn

FROM FRAMING LOGIC

OR EXTERNAL PINS

TO FRAMING LOGIC

OR EXTERNAL PINS

TOHMIn

ALB

DS3181/DS3182/DS3183/DS3184

8 PIN DESCRIPTIONS

Note: In JTAG mode, all digital pins are bidirectional to increase the effectiveness of board-level ATPG patterns for isolation of interconnect

failures.

8.1 Short Pin Descriptions

Table 8-1. DS3184 Short Pin Descriptions

n = 1,2,3,4 (port number). Ipu (input with pullup), Oz (output tri-stateable), (needs an external pullup or pulldown resistor to keep from floating),

Oa (analog output), Ia (analog input), IO (bidirectional in/out). All unused input pins without pullup should be tied low.

NAME TYPE FUNCTION PORT

PORT

LINE IO

TLCLKn O

Transmit Line Clock Output V11 C11 Y8 A8

TPOSn / TDATn O Transmit Positive AMI / Data V14 C14 V4 C4

TNEGn / TOHMOn O Transmit Negative AMI / Line OH Mask W14 B14 U4 D4

TXPn Oa Transmit Positive Analog W6 B6 M2 J2

TXNn Oa Transmit Negative Analog Y6 A6 M1 J1

RLCLKn I Receive Clock Input Y12 A12 W8 B8

RXPn Ia Receive Positive Analog W5 B5 R2 F2

RXNn Ia Receive Negative Analog Y5 A5 R1 F1

RPOSn / RDATn I Positive AMI / Data W15 B15 Y3 A3

RNEGn / RLCVn /

ROHMIn I Negative AMI / Line Code Violation / Line OH

Mask Output Y15 A15 W3 B3

DS3/E3 OVERHEAD INTERFACE

TOHn I Transmit Overhead U11 D11 U8 D8

TOHENn I Transmit Overhead Enable T14 E14 T5 E5

TOHCLKn O Transmit Overhead Clock T11 E11 V8 C8

TOHSOFn O Transmit Overhead Start Of Frame T12 E12 V7 C7

ROHn O Receive Overhead T10 E10 U10 D10

ROHCLKn O Receive Overhead Clock T13 E13 U5 D5

ROHSOFn O Receive Overhead Start Of Frame U14 D14 Y2 B2

DS3/E3 SERIAL DATA, PLCP AND FRACTIONAL DS3/E3 OVERHEAD INTERFACE

TCLKIn I Transmit Line Clock Input Y14 A14 W4 B4

TSOFIn / TOHMIn I Transmit Start Of Frame Input / OH Mask Input U12 D12 W7 B7

TSERn/ TPOHn /

TFOHn/ I Transmit Serial Data / PLCP Overhead /

Fractional Overhead V13 C13 T6 E6

TPDENIn /

TPOHENn /

TFOHENIn

Transmit Payload Data Enable Input / PLCP

Overhead Enable / Fractional OH Enable Input U13 D13 V5 C5

TCLKOn / TGCLKn /

TPOHCLKn O Transmit Clock Output / Gapped Clock / PLCP

Overhead Clock Y13 A13 U7 D7

TSOFOn / TDENn /

TPOHSOFn /

TFOHENOn

Transmit Framer Start Of Frame / Data Enable /

PLCP Overhead Start Of Frame / Fractional OH

Enable Output

V12 C12 Y7 A7

TPDENOn O Transmit Payload Data Enable Output W10 B10 Y9 A9

TPDATn O Transmit Payload Data V10 C10 W9 B9

RPDENIn /

RFOHENIn I Receive Payload Data Enable Input / Fractional

Overhead Enable Input W13 B13 U6 D6

RPDATn I Receive Payload Data Y10 A10 V9 C9

RSERn / RPOHn O Receive Serial Data / PLCP Overhead W11 B11 T9 E9

RCLKOn / RGCLKn

RPOHCLKn O Receive / Clock Output / Gapped Clock / PLCP

Overhead Clock Y11 A11 U9 D9

DS3181/DS3182/DS3183/DS3184

NAME TYPE FUNCTION PORT

PORT

RSOFOn / RDENn /

RPOHSOFn /

RFOHENOn

Receive Framer Start Of Frame / Data Enable /

PLCP Overhead Start Of Frame / Fractional

Overhead Enable Output

W12 B12 T8 E8

NAME TYPE FUNCTION PIN

UTOPIA L2/L3 OR POS-PHY L2/3 OR SPI-3 SYSTEM INTERFACE

TSCLK I Transmit System Clock J20

TADR[4] C15

TADR[3] D15

TADR[2] E15

TADR[1] A16

TADR[0]

I Transmit Address [4:0]

A18

TDATA[31] U15

TDATA[30] T15

TDATA[29] U16

TDATA[28] U17

TDATA[27] D18

TDATA[26] D17

TDATA[25] C19

TDATA[24] F20

TDATA[23] E16

TDATA[22] D16

TDATA[21] C16

TDATA[20] C18

TDATA[19] C17

TDATA[18] T17

TDATA[17] T16

TDATA[16] R17

TDATA[15] V16

TDATA[14] W17

TDATA[13] Y18

TDATA[12] V17

TDATA[11] W18

TDATA[10] W19

TDATA[9] B19

TDATA[8] C20

TDATA[7] W20

TDATA[6] U18

TDATA[5] V18

TDATA[4] V19

TDATA[3] U19

TDATA[2] V20

TDATA[1] T18

TDATA[0]

I Transmit Data [31:0]

U20

TPRTY I Transmit Parity A17

TEN I Transmit Enable (Active Low) A19

TDXA[1]/TPXA Oz

Transmit Direct Cell/Packet Available [1] /

Polled Cell/Packet Available (Tri-State) K17

TDXA[4] D19

TDXA[3] E19

TDXA[2]

O Transmit Direct Cell/Packet Available [4:2]

D20

TSOX I Transmit Start Of Cell/Packet W16

DS3181/DS3182/DS3183/DS3184

NAME TYPE FUNCTION PIN

TSPA Oz Transmit Selected Packet Available K16

TEOP I Transmit End Of Packet V15

TSX I Transmit Start of Transfer Y16

TMOD[1] B18

TMOD[0] I Transmit Packet Data Modulus [1:0] B17

TERR I Transmit Packet Error Y17

RSCLK I Receive System Clock M20

RADR[4] T19

RADR[3] T20

RADR[2] R18

RADR[1] R19

RADR[0]

I Receive Address [4:0]

R20

RDATA[31] F16

RDATA[30] G16

RDATA[29] H16

RDATA[28] J16

RDATA[27] E17

RDATA[26] F17

RDATA[25] G17

RDATA[24] H17

RDATA[23] J17

RDATA[22] H18

RDATA[21] J18

RDATA[20] E18

RDATA[19] G19

RDATA[18] H19

RDATA[17] G20

RDATA[16] H20

RDATA[15] M16

RDATA[14] N16

RDATA[13] P16

RDATA[12] R16

RDATA[11] M17

RDATA[10] N17

RDATA[9] P17

RDATA[8] P18

RDATA[7] P19

RDATA[6] P20

RDATA[5] N18

RDATA[4] N19

RDATA[3] N20

RDATA[2] M18

RDATA[1] M19

RDATA[0]

Oz Receive Data [31:0] (Tri-State)

L20

RPRTY Oz Receive Parity K20

REN I Receive Enable (Active Low) G18

RDXA[1]/RPXA/RSX Oz

Receive Direct Cell/Packet Available [1]/Polled

Cell/Packet Available/Start Of Transfer (Tri-

State)

K19

RDXA[4] E20

RDXA[3] F18

RDXA[2]

O Receive Direct Cell/Packet Available [4:2]

F19

RSOX Oz Receive Start Of Cell/Packet (Tri-State) L17

DS3181/DS3182/DS3183/DS3184

NAME TYPE FUNCTION PIN

REOP Oz Receive End Of Packet L16

RVAL Oz Receive Packet Data Valid K18

RMOD[1] L19

RMOD[0] Oz Receive Packet Data Modulus [1:0] L18

RERR Oz Receive Packet Error J19

MICROPROCESSOR INTERFACE

D[15] J5

D[14] T4

D[13] R4

D[12] P4

D[11] N4

D[10] V3

D[9] U3

D[8] T3

D[7] P3

D[6] N3

D[5] W2

D[4] U2

D[3] T2

D[2] P2

D[1] U1

D[0]

IO Data [15:0]

A[10] C3

A[9] D3

A[8] E3

A[7] G3

A[6] H3

A[5] D2

A[4] E2

A[3] G2

A[2] H2

A[1]

I Address [10:1]

A[0]/BSWAP Address [0] / Byte Swap H1

ALE I Address Latch Enable N2

CS I Chip Select (Active Low) L3

RD/DS I Read Strobe (Active Low) / Data Strobe (Active

Low) K3

WR/R/W I Write Strobe (Active Low) / R/W Select K4

RDY Oz Ready Handshake (Active Low) K2

INT Oz Interrupt (Active Low) L4

MODE I Mode Select RD/WR or DS Strobe Mode B1

WIDTH I WIDTH Select 8 or 16-Bit Interface L5

DS3181/DS3182/DS3183/DS3184

NAME TYPE FUNCTION PIN

MISC I/O

GPIO[8] V2

GPIO[7] V1

GPIO[6] C2

GPIO[5] C1

GPIO[4] P5

GPIO[3] R5

GPIO[2] G5

GPIO[1]

IO General-Purpose IO [8:1]

TEST I Test Enable (Active Low) M3

HIZ I High-Impedance Test Enable (Active Low) R3

RST I Reset (Active Low) B16

JTAG

JTCLK I JTAG Clock F3

JTMS Ipu JTAG Mode Select (with Pullup) F4

JTDI Ipu JTAG Data Input (with Pullup) J3

JTDO Oz JTAG Data Output G4

JTRST Ipu JTAG Reset (Active Low with Pullup) E4

CLAD

CLKA I Clock A K1

CLKB IO Clock B L1

CLKC IO Clock C L2

POWER

VSS PWR Ground, 0V Potential

K10, K9, K8, J10, J9, J8,

H10, H9, M7, M6, L7. L6,

K7. K6, J7, J6, A1, N10,

N9, M10, M9, M8, L10, L9,

L8, R12, R11, R10, R9,

P12, P11, P10, P9, Y1,

N12, N11, M13, M12, M11,

L13, L12, L11, M15, M14,

L15, L14, K15, K14, J15,

J14, Y20, K13, K12, K11,

J13, J12, J11, H12, H11,

G12, G11, G10, G9, F12,

F11, F10, F9, A20

VDD PWR Digital 3.3V

H8, H7, H6, G8, G7, G6,

F8, F7, F6, A2, R8, R7, R6,

P8, P7, P6, N8, N7, N6,

W1, R15, R14, R13, P15,

P14, P13, N15, N14, N13,

Y19, H15, H14, H13, G15,

G14, G13, F15, F14, F13,

B20

DS3181/DS3182/DS3183/DS3184

PIN #

NAME TYPE FUNCTION PORT

PORT

AVDDRn PWR Analog 3.3V for Receive LIU on Port n Y4 A4 T1 D1

AVDDTn PWR Analog 3.3V for Transmit LIU on Port n T7 E7 N1 J4

AVDDJn PWR Analog 3.3V for Jitter Attenuator on Port n V6 C6 N5 G1

AVDDC PWR Analog 3.3V for CLAD K5

NO CONNECTS

NC NC No Connect, Unused H4 H5 M4 M5

DS3181/DS3182/DS3183/DS3184

8.2 Detailed Pin Descriptions

Table 8-2. Detailed Pin Descriptions

n = 1,2,3,4 (port number). Ipu (input with pullup), Oz (output tri-stateable) (needs an external pullup or pulldown resistor to keep from floating),

Oa (Analog output), Ia (analog input), IO (bidirectional in/out). All unused input pins without pullup should be tied low.

PIN TYPE FUNCTION

LINE IO

TLCLKn O

Transmit Line Clock Output

TLCLKn: This signal is available when the transmit line interface pins are enabled

(PORT.CR2.TLEN). This clock is typically used as the clock reference for the TPOSn

/ TDATn and TNEG / TOHMOn signals, but can also be used as the reference for the

TOHMIn / TSOFIn, TFOHn / TSERn, TFOHENIn and TSOFOn / TDENn /

TFOHENOn signals.

This output signal can be inverted.

o DS3: 44.736 MHz +20 ppm

o E3: 34.368 MHz +20 ppm

o CC52: 52 MHz +20 ppm

TPOSn /

TDATn O

Transmit Positive AMI / Data Output

TPOSn: When the port line interface is configured for B3ZS, HDB3 or AMI mode and

the framer is not configured for one of the “-OHM” modes (see Table 10-32) and the

transmit line interface pins are enabled (PORT.CR2.TLEN), a high on this pin

indicates that a positive pulse should be transmitted on the line. The signal is updated

on the positive clock edge of the referenced clock pin if the clock pin signal is not

inverted, otherwise it is updated on the falling edge of the clock. The signal is typically

referenced to the TLCLKn line clock output pins, but it can be referenced to the

TCLKOn, TCLKIn, RLCLKn or RCLKOn pins. This output signal can be disabled

when the TX LIU is enabled.

This output signal can be inverted.

TDATn: When the port line interface is configured for UNI mode or the framer is

configured for one of the “-OHM” modes (see Table 10-32) and the transmit line

interface pins are enabled (PORT.CR2.TLEN), the un-encoded transmit signal is

output on this pin. The signal is updated on the positive clock edge of the referenced

clock pin if the clock pin signal is not inverted, otherwise it is updated on the falling

edge of the clock. The signal is typically referenced to the TLCLK line clock output

pins, but it can be referenced to the TCLKOn, TCLKIn, RLCLKn or RCLKOn pins

This output signal can be inverted.

o DS3: 44.736 Mbps +20ppm

o E3: 34.368 Mbps +20ppm

o CC52: 52 Mbps +20ppm

DS3181/DS3182/DS3183/DS3184

PIN TYPE FUNCTION

TNEGn /

TOHMOn O

Transmit Negative AMI / Line OH Mask

TNEGn: When the port line is configured for B3ZS, HDB3 or AMI mode and the

framer is not configured for one of the “-OHM” modes (see Table 10-32) and the

transmit line interface pins are enabled (PORT.CR2.TLEN), a high on this pin

indicates that a negative pulse should be transmitted on the line. The signal is

updated on the positive clock edge of the referenced clock pin if the clock pin signal is

not inverted, otherwise it is updated on the falling edge of the clock. The signal is

typically referenced to the TLCLKn line clock output pins, but it can be referenced to

the TCLKOn, TCLKIn, RLCLKn or RCLKOn pins.

This output signal can be inverted.

o DS3: 44.736 Mbps +20ppm

o E3: 34.368 Mbps +20ppm

o CC52: 52 Mbps +20ppm

TOHMOn: When the framer is configured for one of the “-OHM” modes (see Table

10-32) and the transmit line interface pins are enabled (PORT.CR2.TLEN), the

transmit overhead mask signal is output on this pin. This signal is a delayed version of

TOHMIn or ROHMIn when in local loopback (three clock period delay). This signal will

be high to indicate that the data on TDATn is not valid data and can be overwritten by

external logic to add an external frame signal. This signal will be low to indicate that

the data on TDATn is valid. The signal is updated on the positive clock edge of the

referenced clock pin if the clock pin signal is not inverted, otherwise it is updated on

the falling edge of the clock. The signal is typically referenced to the TLCLKn line

clock output pins, but it can be referenced to the TCLKOn, TCLKIn, RLCLKn or

RCLKOn pins.

This output signal can be inverted.

TXPn Oa

Transmit Positive Analog

TXPn: This pin and the TXNn pin form a differential AMI output which is coupled to

the outbound 75Ω coaxial cable through a 2:1 step-down transformer (Figure 1-1).

This output is enabled when the TX LIU is enabled and the output is enabled to be

driven. When it is not enabled, it is in a high impedance state.

o DS3: 44.736 Mbps +20ppm

o E3: 34.368 Mbps +20ppm

o CC52: 52 Mbps +20ppm

TXNn Oa

Transmit Negative Analog

TXNn: This pin and the TXPn pin form a differential AMI output which is coupled to

the outbound 75Ω coaxial cable through a 2:1 step-down transformer (Figure 1-1).

This output is enabled when the TX LIU is enabled and the output is enabled to be

driven. When it is not enabled, it is in a high impedance state.

o DS3: 44.736 Mbps +20ppm

o E3: 34.368 Mbps +20ppm

o CC52: 52 Mbps +20ppm

RXPn Ia

Receive Positive analog

RXPn: This pin and the RXNn pin form a differential AMI input which is coupled to the

outbound 75Ω coaxial cable through a 2:1 step-up transformer (Figure 1-1). This input

is used when the RX LIU is enabled and is ignored when the LIU is disabled.

o DS3: 44.736 Mbps +20ppm

o E3: 34.368 Mbps +20ppm

o CC52: 52 Mbps +20ppm

RXNn Ia

Receive Negative analog

RXNn: This pin and the RXPn pin form a differential AMI input which is coupled to the

outbound 75Ω coaxial cable through a 2:1 step-up transformer (Figure 1-1). This input

is used when the LIU is enabled and is ignored when the LIU is disabled.

o DS3: 44.736 Mbps +20ppm

o E3: 34.368 Mbps +20ppm

o CC52: 52 Mbps +20ppm

DS3181/DS3182/DS3183/DS3184

PIN TYPE FUNCTION

RLCLKn I

Receive Line Clock Input

RLCLKn: This clock is typically used for the reference clock for the RPOSn / RDATn,

RNEGn / RLCVn / ROHMIn signals but can also be used as the reference clock for

the RSERn, RSOFOn / RDENn / RFOHENOn, RFOHENIn, TOHMIn / TSOFIn,

TFOHn / TSERn, TFOHENIn, TSOFOn / TDENn / TFOHENOn, TPOSn / TDATn and

TNEGn / TOHMOn signals. This input is ignored when the LIU is enabled.

This input signal can be inverted.

o DS3: 44.736 MHz +20 ppm

o E3: 34.368 MHz +20 ppm

o CC52: 52 MHz +20 ppm

RPOSn /

RDATn I

Receive Positive AMI / Data

RPOSn: When the port line is configured for B3ZS, HDB3 or AMI mode and the

framer is not configured for one of the “-OHM” modes and the LIU is disabled, a high

on this pin indicates that a positive pulse has been detected using an external LIU.

The signal is sampled on the positive clock edge of the referenced clock pin if the

clock pin signal is not inverted, otherwise it is sampled on the falling edge of the clock.

The signal is typically referenced to the RLCLKn line clock input pins, but it can be

referenced to the RCLKOn output pins.

This input signal can be inverted.

RDATn: When the port line interface is configured for UNI mode or the framer is

configured for one of the “-OHM” modes, the un-encoded receive signal is input on

this pin. The signal is sampled on the positive clock edge of the referenced clock pin if

the clock pin signal is not inverted, otherwise it is sampled on the falling edge of the

clock. The signal is typically referenced to the RLCLKn line clock input pins, but it can

be referenced to the RCLKOn output pins.

This input signal can be inverted.

o DS3: 44.736 Mbps +20ppm

o E3: 34.368 Mbps +20ppm

o CC52: 52 Mbps +20ppm

RNEGn /

RLCVn /

ROHMIn

Receive Negative AMI / Line Code Violation / Line OH Mask input

RNEGn: When the port line is configured for B3ZS, HDB3 or AMI mode and the

framer is not configured for one of the “-OHM” modes and the LIU is disabled, a high

on this pin indicates that a negative pulse has been detected using an external LIU.

The signal is sampled on the positive clock edge of the referenced clock pin if the

clock pin signal is not inverted, otherwise it is sampled on the falling edge of the clock.

The signal is typically referenced to the RLCLKn line clock input pins, but it can be

referenced to the RCLKOn output pins.

This input signal can be inverted.

o DS3: 44.736 Mbps +20ppm

o E3: 34.368 Mbps +20ppm

o CC52: 52 Mbps +20ppm

RLCVn: When the port line interface is configured for UNI mode and the framer is not

configured for one of the “-OHM” modes, the BPV counter in the encoder/decoder

block is incremented each clock when this signal is high. The signal is sampled on the

positive clock edge of the referenced clock pin if the clock pin signal is not inverted,

otherwise it is sampled on the falling edge of the clock. The signal is typically

referenced to the RLCLKn line clock input pins, but it can be referenced to the

RCLKOn output pins.

This input signal can be inverted.

ROHMIn: When the port framer is configured for one of the “-OHM” modes, this signal

is used to mark the overhead bits on the RDATn pins when it is high. The DS318x will

ignore overhead bits. The signal is sampled on the positive clock edge of the

referenced clock pin if the clock pin signal is not inverted, otherwise it is sampled on

the falling edge of the clock. The signal is typically referenced to the RLCLKn line

clock input pins, but it can be referenced to the RCLKOn output pins.

This input signal can be inverted.

DS3181/DS3182/DS3183/DS3184

PIN TYPE FUNCTION

DS3/E3 OVERHEAD INTERFACE

TOHn I

Transmit Overhead / Line OH Mask Input

TOHn: When the port framer is configured for one of the DS3 or E3 framing modes,

this signal will be used to over-write the DS3 or E3 framing overhead bits when

TOHENn is active. In T3 mode, the X-bits, P-bits, M-bits, F-bits, and C-bits are input.

In G.751 E3 mode, all of the FAS, RAI, and National Use bits are input. In G.832 E3

mode, all of the FA1, FA2, EM, TR, MA, NR, and GC bytes are input. The TOHSOFn

signal marks the start of the framing bit sequence. This signal is sampled at the same

time as the TOHCLKn signal transitions high to low.

This signal can be inverted.

TOHENn I

Transmit Overhead Enable / Start Of Frame Input

TOHENn: When the port framer is configured for one of the DS3 or E3 framing

modes, this signal will be used the determine which DS3 or E3 framing overhead bits

to over-write with the signal on the TOHn pins. The TOHSOFn signal marks the start

of the framing bit sequence. This signal is sampled at the same time as the TOHCLKn

signal transitions high to low.

This signal can be inverted.

TOHCLKn O

Transmit Overhead Clock

TOHCLKn: When the port framer is configured for one of the DS3 or E3 framing

modes, this clock is used for the transmit overhead port signals TOHn, TOHENn and

TOHSOFn. The TOHSOFn output signal is updated and the TOHn and TOHENn

input signals are sampled at the same time this clock signal transitions from high to

low. The external logic is expected to sample TOHSOFn signal and update the TOHn

and TOHENn signals on the rising edge of this clock signal. This clock is a low

frequency clock.

This signal can be inverted.

TOHSOFn O

Transmit Overhead Start Of Frame

TOHSOFn: When the port framer is configured for one of the DS3 or E3 framing

modes, this signal is used to mark the start of a DS3 or E3 overhead sequence on the

TOHn pins. In T3 mode, the first X-bit is marked. In G.751 E3 mode, the first bit of the

FAS word is marked. In G.832 E3 mode, the first bit of the FA1 byte is marked. The

sequence starts on the same high to low transition of the TOHCLKn clock that this

signal is high. This signal is updated at the same time as the TOHCLKn signal

transitions high to low.

This signal can be inverted.

ROHn O

Receive Overhead

ROHn: When the port framer is configured for one of the DS3 or E3 framing modes,

this signal outputs the value of the receive overhead bits. The ROHSOFn signal

marks the start of the framing bit sequence. In T3 mode, the X-bits, P-bits, M-bits, F-

bits, and C-bits are output (Note: In M23 mode, the C-bits are extracted even though

they are marked as data at the payload interface). In G.751 E3 mode, all of the FAS,

RAI, and National Use bits are output. In G.832 E3 mode, all of the FA1, FA2, EM,

TR, MA, NR, and GC bytes are output.

This signal is updated at the same time as the ROHCLKn signal transitions high to

low.

This signal can be inverted.

ROHCLKn O

Receive Overhead Clock

ROHCLKn: When the port framer is configured for one of the DS3 or E3 framing

modes, this clock is used for the receive overhead port signals ROHn and ROHSOFn.

The ROHSOFn and ROHn output signals are updated at the same time this clock

signal transitions from high to low. The external logic is expected to sample

ROHSOFn and ROHn signal on the rising edge of this clock signal. This clock is a low

frequency clock.

This signal can be inverted.

DS3181/DS3182/DS3183/DS3184

PIN TYPE FUNCTION

ROHSOFn O

Receive Overhead Start Of Frame

ROHSOFn: When the port framer is configured for one of the DS3 or E3 framing

modes this signal is used to mark the start of a DS3 or E3 overhead sequence on the

ROHn pins. In T3 mode, the first X-bit is marked. In G.751 E3 mode, the first bit of the

FAS word is marked. In G.832 E3 mode, the first bit of the FA1 byte is marked. The

sequence starts on the same high to low transition of the ROHCLKn clock that this

signal is high. This signal is updated at the same time as the ROHCLKn signal

transitions high to low.

This signal can be inverted.

DS3/E3 SERIAL DATA, PLCP AND FRACTIONAL DS3/E3 OVERHEAD INTERFACE

TCLKIn I

Transmit Line Clock Input

TCLKIn: This clock is typically used for the reference clock for the TOHMIn / TSOFIn,

TFOHn / TSERn, TFOHENIn / TPDENIn, TPDATn, TPDENOn and TSOFOn / TDENn

/ TFOHENOn signals but can also be used as the reference for the TPOSn / TDATn

and TNEGn / TOHMOn signals. This clock is not used when the part is in loop time

mode or the CLAD clocks are used as the transmit clock source.

(PORT.CR3.CLADC)

This input signal can be inverted.

o DS3: 44.736 MHz +20 ppm

o E3: 34.368 MHz +20 ppm

o CC52: 52 MHz +20 ppm

TSOFIn /

TOHMIn I

Transmit Start Of Frame Input / OH Mask Input. See Table 10-20.

TSOFIn: When the port framer is configured for any of the DS3 or E3 non “-OHM”

framed modes, this signal can be used to align the start of the DS3 or E3 frames on

the TSER pin to an external signal. In the fractional mode, the TSOFIn signal can be

used to align the start of frame signal position on the TSERn/TOHn

pin to the rising edge of a signal on this pin. The signal edge does not need to occur

on every frame and can be tied high or low. The signal is sampled on the positive

clock edge of the referenced clock pin if the clock pin signal is not inverted, otherwise

it is sampled on the falling edge of the clock. The signal is typically referenced to the

TCLKIn transmit clock input pins, but it can be referenced to the TLCLKn, TCLKOn,

RCLKOn and RLCLKn clock pins.

This signal can be inverted.

TOHMIn: When the port framer is configured for one of the “- OHM” modes, this

signal is used to mark clock periods when valid data bits are available on the TDATn

output pins. When this signal is low, valid data bits will be available on the TDATn

output pins three clock periods later. This signal precedes the signal on TDATn and

TOHMOn by three clock periods. The signal is sampled on the positive clock edge of

the referenced clock pin if the clock pin signal is not inverted, otherwise it is sampled

on the falling edge of the clock. The signal is typically referenced to the TCLKIn

transmit clock input pins, but it can be referenced to the TLCLKn, TCLKOn, RCLKOn

and RLCLKn clock pins.

This signal can be inverted.

TSERn /

TPOHn /

TFOHn /

Transmit Serial Data / PLCP Overhead / Fractional Overhead. See Table 10-21.

TSERn: When the port framer is configured for Flexible Fractional mode, this pin is

used as the source of the DS3/E3 payload data. The signal is sampled on the positive

clock edge of the referenced clock pin if the clock pin signal is not inverted, otherwise

it is sampled on the falling edge of the clock. The signal is typically referenced to the

TCLKIn transmit clock input pins, but it can be referenced to the TLCLKn, TCLKOn /

TGCLKn, RCLKOn and RLCLKn clock pins

This signal can be inverted.

o DS3: 44.736 Mbps +20ppm

o E3: 34.368 Mbps +20ppm

o CC52: 52 Mbps +20ppm

TPOHn: When the port framer is configured for one of the DS3 or E3 PLCP framing

modes, and the port is enabled, this signal will be used to over-write the DS3 or E3

DS3181/DS3182/DS3183/DS3184

PIN TYPE FUNCTION

PLCP framing overhead bits when TPOHENn is active. The TPOHSOFn signal marks

the start of the framing bit sequence. This signal is sampled at the same time as the

TPOHCLKn signal transitions high to low.

This signal can be inverted.

TFOHn: When the port framer is configured for one of the DS3 or E3 internal or

external fractional framing modes, and the port is enabled the internal fractional

framing modes, this pin can be used to source the fractional overhead data. The

signal is sampled on the positive clock edge of the referenced clock pin if the clock

pin signal is not inverted, otherwise it is sampled on the falling edge of the clock. The

signal is typically referenced to the TCLKIn transmit clock input pins, but it can be

referenced to the TLCLKn, TCLKOn / TGCLKn, RCLKOn and RLCLKn clock pins

This signal can be inverted.

TPDENIn /

TPOHENn /

TFOHENIn

Transmit Payload Data Enable Input / PLCP Overhead Enable / Fractional OH Enable

Input. See Table 10-22.

TPDENIn: When the port is configured for the Flexible fractional mode, this pin is

used to enable payload data from the cell/packet processor. There is a three-clock

delay between TPDENIn and TPDENOn. The signal is sampled on the positive clock

edge of the referenced clock pin if the clock pin signal is not inverted, otherwise it is

sampled on the falling edge of the clock. The signal is typically referenced to the

TCLKIn transmit clock input pins, but it can be referenced to the TLCLKn, TCLKOn,

RCLKOn and RLCLKn clock pins

This signal can be inverted.

TPOHENn: When the port framer is configured for one of the DS3 or E3 PLCP

framing modes, and the port is enabled, this signal will be used the determine which

DS3 or E3 PLCP framing overhead bits to over-write with the signal on the TPOHn

pins. The TPOHSOFn signal marks the start of the framing bit sequence. This signal

is sampled at the same time as the TPOHCLKn signal transitions high to low.

This signal can be inverted.

TFOHENIn: When the port framer is configured for the DS3 or E3 External Fractional

framing, this pin is used to mark the fractional overhead data on the TFOHn pin. The

TSOFOn or TSOFIn pins can be used to select which DS3/E3 payload bits relative to

the start of the DS3/E3 frame to mark. The signal is sampled on the positive clock

edge of the referenced clock pin if the clock pin signal is not inverted, otherwise it is

sampled on the falling edge of the clock. The signal is typically referenced to the

TCLKIn transmit clock input pins, but it can be referenced to the TLCLKn, TCLKOn,

RCLKOn and RLCLKn clock pins

This signal can be inverted.

TCLKOn /

TGCLKn /

TPOHCLKn

Transmit Clock Output / Gapped Clock / PLCP Overhead Clock. See Table 10-24.

TCLKOn: When the port is configured external fractional modes and TCLKOn is

selected, or any other mode and the port pins are enabled and TCLKOn is selected,

this clock output is enabled. This clock is the same clock as the internal framer

transmit clock. This clock is typically used for the reference clock for the TOHMIn /

TSOFIn, TFOHn / TSERn, TFOHENIn and TSOFOn / TDENn / TFOHENOn signals

but can also be used as the reference for the TPOSn / TDATn and TNEGn /

TOHMOn signals.

This signal can be inverted.

o DS3: 44.736 MHz +20 ppm

o E3: 34.368 MHz +20 ppm

o CC52: 52 MHz +20 ppm

TGCLKn: When the port is configured internal fractional mode or any simple DS3/E3

framed mode and the port pins are enabled and TGCLKn is selected, this gated

output clock is enabled. This gapped clock is the same clock as the internal framer

transmit clock and is gated by either TDENn or TFOHENOn depending on which

signal is active. This clock is typically used for the reference clock for the TFOHn /

TSERn signals.

This signal can be inverted.

TPOHCLKn: When the port framer is configured for one of the DS3 or E3 PLCP

DS3181/DS3182/DS3183/DS3184

PIN TYPE FUNCTION

framing modes, the port pins are enabled and the TCLKOn pin function is not

selected, this clock is used for the transmit overhead port signals TPOHn, TPOHENn

and TPOHSOFn. The TPOHSOFn output signal is updated and the TPOHn and

TPOHENn input signals are sampled at the same time this clock signal transitions

from high to low. The external logic is expected to sample TPOHSOFn signal and

update the TPOHn and TPOHENn signals on the rising edge of this clock signal. This

clock is a low frequency clock.

This signal can be inverted.

TSOFOn /

TDENn /

TPOHSOFn /

TFOHENOn

Transmit PLCP Overhead Start Of Frame / Framer Start Of Frame /Data Enable

See Table 10-23.

TSOFOn: When the port framer is configured for the External Fractional or Flexible

Fractional modes and the port pins are enabled and the TSOFOn pin function is

selected, this signal is used to indicate the start of the DS3/E3 frame on the TPOHn /

TFOHn / TSERn pin. The signal is also active in the non-PLCP non-fractional DS3 or

E3 framing modes when the port pins are enabled and the TSOFOn pin function is

selected. This signal pulses high three clocks before the first overhead bit in a DS3 or

E3 frame that will be input on TSERn or TFOHn. The signal is updated on the positive

clock edge of the referenced clock pin if the clock pin signal is not inverted, otherwise

it is updated on the falling edge of the clock. The signal is typically referenced to the

TCLKIn transmit clock input pins, but it can be referenced to the TLCLKn, TCLKOn,

RCLKOn and RLCLKn clock pins.

This signal can be inverted.

TDENn: When the port framer is configured for the External Fractional or Flexible

Fractional modes and the port pins are enabled and the TDENn pin function is

selected, this signal is used to mark the DS3/E3 frame bits on the TPOHn / TFOHn /

TSERn pin. The signal is also active in the non-PLCP non-fractional DS3 or E3

framing modes when the port pins are enabled and the TDENn pin function is

selected. The signal goes high three clocks before the start of DS3/E3 payload bits

and goes low three clocks before the end of the DS3/E3 payload bits. The signal is

updated on the positive clock edge of the referenced clock pin if the clock pin signal is

not inverted, otherwise it is updated on the falling edge of the clock. The signal is

typically referenced to the TCLKIn transmit clock input pins, but it can be referenced

to the TLCLKn, TCLKOn, RCLKOn and RLCLKn clock pins.

This signal can be inverted.

TPOHSOFn: When the port framer is configured for one of the PLCP framing modes

and the port pins are enabled, this signal is used to mark the start of a DS3 or E3

PLCP overhead sequence on the TPOHn pins. The sequence starts on the same high

to low transition of the TPOHCLKn clock that this signal is high. This signal is updated

at the same time as the TPOHCLKn signal transitions high to low.

This signal can be inverted.

TFOHENOn: When the port framer is configured for one of the internal fractional

modes and the port pins are enabled, this signal is used to indicate the fractional

overhead bit positions of the data on the TOHn pin. The signal goes high one clock

before the start of DS3/E3 fractional overhead bits and goes low one clock before the

end of the DS3/E3 fractional payload bits. The signal is updated on the positive clock

edge of the referenced clock pin if the clock pin signal is not inverted, otherwise it is

updated on the falling edge of the clock. The signal is typically referenced to the

TCLKIn transmit clock input pin, but it can be referenced to the TLCLKn, TCLKOn,

RCLKOn or RLCLKn clock pin.

This signal can be inverted.

DS3181/DS3182/DS3183/DS3184

PIN TYPE FUNCTION

TPDENOn O

Transmit Payload Data Enable Output. See Table 10-26.

TPDENOn: When the port framer is enabled for the Flexible fractional mode and the

port pins are enabled, this signal marks which bits on the TPDATn pin are valid

payload data bits. It is high during the same clock cycle the TPDATn payload data bit

is valid. The signal is updated on the positive clock edge of the referenced clock pin if

the clock pin signal is not inverted, otherwise it is updated on the falling edge of the

clock. The signal is typically referenced to the TCLKIn transmit clock input pin, but it

can be referenced to the TLCLKn, TCLKOn, RCLKOn or RLCLKn clock pin.

This signal can be inverted.

TPDATn O

Transmit Payload Data. See Table 10-26.

TPDATn: When the port framer is enabled for the Flexible fractional mode and the

port pins are enabled, this signal is the payload bits from the cell/packet processor.

The data is valid if the TPDENOn signal is high during the same clock cycle. The

signal is updated on the positive clock edge of the referenced clock pin if the clock pin

signal is not inverted, otherwise it is updated on the falling edge of the clock. The

signal is typically referenced to the TCLKIn transmit clock input pin, but it can be

referenced to the TLCLKn, TCLKOn, RCLKOn or RLCLKn clock pin.

This signal can be inverted.

RPDENIn /

RFOHENIn I

Receive Payload Data Enable Input / Fractional Overhead Enable Input

See Table 10-28.

RPDENIn: When the port is configured for the flexible fractional mode, this pin is used

to enable payload data for the cell/packet processor. The data on RPDATn is used

when this signal is high. The signal is sampled on the positive clock edge of the

referenced clock pin if the clock pin signal is not inverted, otherwise it is sampled on

the falling edge of the clock. The signal is typically referenced to the RCLKOn receive

clock output pins, but it can be referenced to the RLCLKn clock input pin.

This signal can be inverted.

RFOHENIn: When the port framer is configured for the external fractional framing

mode, this pin is used to mark the receive bits to use for fractional overhead data. The

signal on the RSOFOn pin can be used to select which DS3/E3 payload bits relative

to the start of the DS3/E3 frame to mark. The signal needs to go high for each bit on

the RSERn pin that should be treated as fractional overhead in the DS3/E3 payload.

RFOHENIn needs to go high or low three clock periods after the data bit on RSERn is

present to mark that bit as payload or fractional overhead. The signal is sampled on

the positive clock edge of the referenced clock pin if the clock pin signal is not

inverted, otherwise it is sampled on the falling edge of the clock. The signal is typically

referenced to the RCLKOn receive clock output pins, but it can be referenced to the

RLCLKn clock input pin.

This signal can be inverted.

RPDATn I

Receive Payload Data. See Table 10-29.

RPDATn: When the port framer is enabled for the Flexible fractional mode and the

port pins are enabled, this signal is the payload bits for the cell/packet processor. The

data is used if the RPDENOn signal is high during the same clock cycle. The signal is

sampled on the positive clock edge of the referenced clock pin if the clock pin signal

is not inverted, otherwise it is sampled on the falling edge of the clock. The signal is

typically referenced to the RCLKOn receive clock output pins, but it can be referenced

to the RLCLKn clock input pin.

This signal can be inverted.

RSERn /

RPOHn O

Receive Serial Data / PLCP Overhead. See Table 10-27.

RSERn: When the port framer is configured for the external fractional mode, internal

fractional mode, or flexible fractional mode, and the port pins are enabled, this pin

outputs the receive data signal from the LIU or receive line pins. The signal is updated

on the positive clock edge of the referenced clock pin if the clock pin signal is not

inverted, otherwise it is updated on the falling edge of the clock. The signal is typically

referenced to the RCLKOn receive clock output pin, but it can be referenced to the

RGCLKn and RLCLKn clock pins.

This signal can be inverted

DS3181/DS3182/DS3183/DS3184

PIN TYPE FUNCTION

o DS3: 44.736 Mbps +20ppm

o E3: 34.368 Mbps +20ppm

o CC52: 52 Mbps +20ppm

RPOHn: When the port framer is configured for one of the PLCP framing modes and

the port pins are enabled, this signal outputs the value of the receive PLCP overhead

bits. The RPOHSOFn signal marks the start of the framing bit sequence. This signal

is updated at the same time as the RPOHCLKn signal transitions high to low.

This signal can be inverted.

RCLKOn /

RGCLKn /

RPOHCLKn

Receive Clock Output / Gapped Clock / PLCP Overhead Clock. See Table 10-31.

RCLKOn: When the port is configured for external fractional mode or flexible

fractional mode and RCLKOn is selected, or any other mode and the port pins are

enabled and RCLKOn is selected, this clock output signal is active. It is the same as

the internal receive framer clock. This clock is typically used for the reference clock

for the RSERn, RSOFOn / RDENn / RFOHENOn, RPDATn, and RFOHENIn /

RPDENIn signals but can also be used as the reference for the RPOSn / RDATn,

RNEGn / RLCVn / ROHMIn TOHMIn / TSOFIn, TFOHn / TSERn, TFOHENIn,

TSOFOn / TDENn / TFOHENOn, TPOSn / TDATn and TNEGn / TOHMOn signals.

This signal can be inverted.

o DS3: 44.736 MHz +20 ppm

o E3: 34.368 MHz +20 ppm

o CC52: 52 MHz +20 ppm

RGCLKn: When the port is configured for internal fractional or any simple DS3/E3

framed mode and the port pins are enabled and RGCLKn is selected, this gated clock

output signal is active. It is the internal receive framer clock gated by either RDENn or

RFOHENOn, depending on which signal is active. This clock is typically used as the

reference clock for the RSERn pin.

This signal can be inverted

RPOHCLKn: When the port framer is configured for one of the PLCP framing modes

and the port pins are enabled, this clock is used for the receive PLCP overhead port

signals RPOHn and RPOHSOFn. The RPOHSOFn and RPOHn output signals are

updated at the same time this clock signal transitions from high to low. The external

logic is expected to sample RPOHSOFn and RPOHn signal on the rising edge of this

clock signal. This clock is a low frequency clock.

This signal can be inverted.

DS3181/DS3182/DS3183/DS3184

PIN TYPE FUNCTION

RSOFOn /

RDENn /

RPOHSOFn /

RFOHENOn

Receive Framer Start Of Frame /Data Enable / PLCP Overhead Start Of Frame. See

Table 10-30.

RSOFOn: When the port framer is configured for External Fractional or Flexible

Fractional mode and the RSOFOn pin function is enabled, or when it is configured for

one of the DS3 or E3 framed only modes and the port pins are enabled and the

RSOFOn pin function is enabled, this signal is used to indicate the start of the DS3/E3

frame. This signal indicates the first DS3/E3 overhead bit on the RSERn pin when

high. The signal is updated on the positive clock edge of the referenced clock pin if

the clock pin signal is not inverted, otherwise it is updated on the falling edge of the

clock. The signal is typically referenced to the RCLKOn receive clock output pin, but it

can be referenced to the RLCLKn clock input pin.

This signal can be inverted.

RDENn: When the port framer is configured for External Fractional or Flexible

Fractional mode and the RDENn pin function is enabled and the port pins are enabled

and the RDENn pin function is enabled, this signal is used to indicate the DS3/E3

payload bit positions of the data on the RSERn pin. The signal goes high during each

DS3/E3 payload bit and goes low during each DS3/E3 overhead bit. The signal is

updated on the positive clock edge of the referenced clock pin if the clock pin signal is

not inverted, otherwise it is updated on the falling edge of the clock. The signal is

typically referenced to the RCLKOn receive clock output pin, but it can be referenced

to the RLCLKn clock input pin.

This signal can be inverted.

RPOHSOFn: When the port framer is configured for one of the PLCP framing modes

and the port pins are enabled, this signal is used to mark the start of a DS3 or E3

PLCP overhead sequence on the RPOHn pins. The sequence starts on the same

high to low transition of the RPOHCLKn clock that this signal is high. This signal is

updated at the same time as the RPOHCLKn signal transitions high to low.

This signal can be inverted.

RFOHENOn: When the port framer is configured for internal fractional mode and the

port pins are enabled, this signal is used to indicate the fractional overhead bit

positions of the data on the RSERn pin. The signal goes high during each DS3/E3

fractional overhead bit and goes low during each DS3/E3 fractional payload bit. The

signal is updated on the positive clock edge of the referenced clock pin if the clock pin

signal is not inverted, otherwise it is updated on the falling edge of the clock. The

signal is typically referenced to the RCLKOn receive clock output pin, but it can be

referenced to the RLCLKn clock input pin.

This signal can be inverted.

UTOPIA/POS-PHY/SPI-3 SYSTEM INTERFACE

TSCLK I

Transmit System Clock

TSCLK: This signal is used to sample or update the other transmit system interface

signals.

TSCLK has a maximum frequency of 66 MHz in L3 modes and 52 MHz in L2 modes.

TADR[4:0] I

Transmit Address [4:0]

TADR[4:0]: In UTOPIA L2, UTOPIA L3 or POS-PHY L2 modes, this 5-bit address

bus is used by the ATM/Link layer device to select a specific port for data transfer or

to poll for FIFO status..

In POS-PHY L3 modes, this 5-bit address is used by the Link layer device to poll for

FIFO status.

TADR[4] is the MSB and TADR[0] is the LSB. This bus is sampled on the rising edge

of TSCLK.

TDATA[31:0] I

Transmit Data [31:0]

TDATA[31:0]: This 32-bit data bus is used to transfer cell/packet data from the

ATM/Link layer device. This bus is sampled on the rising edge of TSCLK.

In 32-bit mode, TDATA[31] is the MSB and TDATA[0] is the LSB.

In 16-bit mode, TDATA[15] is the MSB, TDATA[0] is the LSB, and TDATA[31:16] are

not used and ignored.

DS3181/DS3182/DS3183/DS3184

PIN TYPE FUNCTION

In 8-bit mode, TDATA[7] is the MSB, TDATA[0] is the LSB, and TDATA[31:8] are not

used and ignored.

TPRTY I

Transmit Parity

TPRTY: This signal indicates the parity on the data bus when parity checking is

enabled. This option is programmable. TPRTY is ignored if parity checking is

disabled. This signal is sampled on the rising edge of TSCLK.

TEN I

Transmit Enable (active low)

TEN: This signal is used by the ATM/Link device to control the transfer of cell/packet

data on the TDATA bus. If TEN is high, no transfer occurs. If TEN is low, a transfer

occurs. This signal can be sampled on the rising edge of TSCLK.

TDXA[1] /

TPXA Oz

Transmit Direct Cell/Packet Available [1] / Polled Cell/Packet Available (tri-state)

This signal is tri-state when global reset is applied.

TDXA[1]: When direct status mode is selected, this signal is used to indicate when

port 1 can accept data from the ATM/Link layer device. This signal is updated on the

rising edge of TSCLK.

In UTOPIA L2 or UTOPIA L3 modes, TDXA goes high when port 1 can accept the

transfer of more than a programmable number of ATM cells. TDXA goes low when

port 1 cannot accept the transfer of a complete ATM cell.

In POS-PHY L2 or POS-PHY L3 modes, TDXA goes high when port 1 can store more

data than the "almost full" level. TDXA goes low when port 1 is full.

TPXA: (reset default) When polled status mode is selected, this signal is used to

indicate when the polled port, as selected by TADR[4:0], can accept data from the

ATM/Link layer device. This signal is updated on the rising edge of TSCLK.

In UTOPIA L2 or UTOPIA L3 modes, TPXA goes high when the polled port’s FIFO

can accept the transfer of more than a programmable number of ATM cells (the

“almost full” level). TPXA goes low when the polled port cannot accept the transfer of

a complete ATM cell.

In POS-PHY L2 or POS-PHY L3 modes, TPXA goes high when the polled port’s FIFO

can store more data than the "almost full" level. TPXA goes low when the polled port

is full.

In UTOPIA L2 (reset default) or POS-PHY L2 modes, this signal is driven when one

of the ports is being polled, and is tri-stated when none of the ports is being polled or

when data path reset is active.

In UTOPIA L3 or POS-PHY L3 modes, this signal is driven.

Note: Polled status mode or direct status mode is selected by the GL.CR1.DIREN bit.

TDXA[4:2] O

Transmit Direct Cell/Packet Available [4:2]

TDXA[4:2]: This signal is used to indicate when the associated port can accept data

from the ATM/Link layer device. This signal can be updated on the rising edge of

TSCLK.

In UTOPIA L2 or L3 modes, TDXA goes high when the associated port’s can accept

the transfer of more than a programmable number of ATM cells (“almost full” level).

TDXA goes low when the associated port cannot accept the transfer of a complete

ATM cell.

In POS-PHY L2 or L3 modes, TDXA goes high when the associated port’s FIFO can

store more data than the "almost full" level. TDXA goes low when the associated

port’s FIFO is full.

TSOX I

Transmit Start Of Cell/Packet

TSOX: This signal is used to indicate the first transfer of a cell/packet. This signal

can be sampled on the rising edge of TSCLK.

In UTOPIA L2 or L3 modes, TSOX indicates the first transfer of a cell.

In POS-PHY L2 or L3 modes, TSOX indicates the first transfer of a packet.

TSPA Oz

Transmit Selected Packet Available

This signal is tri-state when global reset is applied.

TSPA: In POS-PHY L2 or POS-PHY L3 modes, this signal is used to indicate the

selected port can accept data from the Link layer device. TSPA goes high when a

port is selected for transfer and it can accept more data than the "almost full" level.

DS3181/DS3182/DS3183/DS3184

PIN TYPE FUNCTION

TSPA goes low when the selected port is "full" or no port is selected. This signal is

updated on the rising edge of TSCLK.

In UTOPIA L3 mode this signal is low.

In POS-PHY L2 mode, this signal is driven when one of the ports is selected for data

transfer, and tri-state when TEN is deasserted, none of the ports is selected or when

data path reset is active.

POS-PHY L3 or UTOPIA L3 modes this signal is driven.

In UTOPIA L2 (reset default) mode this signal is tri-stated.

TEOP I

Transmit End Of Packet

TEOP: In POS-PHY L2 or L3 modes, this signal is used to indicate the last transfer

of a packet. This signal is sampled on the rising edge of TSCLK.

In UTOPIA L2 or L3 modes, this signal is ignored.

TSX I

Transmit Start Of Transfer

TSX: In POS-PHY L3 mode, this signal indicates the start of a data transfer. TSX

goes high goes high immediately before the start of data transfer to indicate that the

in-band port address is present on TDATA. TSX goes high when the value of TDATA

is the address of the transmit port to which data is to be transferred. When TSX goes

low, all subsequent transfers will be to the port specified by the in-band address.

This signal is sampled on the rising edge of TSCLK. TSX is only valid when TEN is

high.

In UTOPIA L2, UTOPIA L3 or POS-PHY L2 modes, this signal is ignored.

TMOD[1:0] I

Transmit Packet Data Modulus [1:0]

TMOD[1:0]: In POS-PHY L2 or L3 modes, this signal indicates the number of valid

bytes on the TDATA bus.

TMOD[1:0]=00 TDAT[31:0] valid

TMOD[1:0]=01 TDAT[31:8] valid

TMOD[1:0]=10 TDAT[31:16] valid

TMOD[1:0]=11 TDAT[31:24] valid

This signal is sampled on the rising edge of TSCLK. TMOD is only valid when TEOP

is high.

In 16-bit POS-PHY L2 or 16-bit POS-PHY L3 mode, TMOD[1] is ignored.

In 8-bit POS-PHY L2 or 8-bit POS-PHY L3 modes, TMOD[1:0] are ignored.

In UTOPIA L2 or UTOPIA L3 modes, TMOD[1:0] are ignored.

TERR I

Transmit Packet Error

TERR: In POS-PHY L2 or POS-PHY L3 modes, this signal indicates that the current

packet is erred. When TERR is high, the current packet should be aborted. This

signal is sampled on the rising edge of TSCLK. TERR is only valid when TEOP is

high.

In UTOPIA L2 or UTOPIA L3 modes, this signal is ignored.

RSCLK I

Receive System Clock

RSCLK: This signal is used to sample or update the other receive system interface

signals.

RSCLK has a maximum frequency of 66 MHz in UTOPIA L3 or POS-PHY L3 modes

and 52 MHZ in UTOPIA L2 or POS-PHY L2 modes.

RADR[4:0] I

Receive Address [4:0]

RADR[4:0]: In UTOPIA L2, Utopia L3 or POS-PHY L2 modes, this 5-bit address bus

is used by the ATM/Link layer device to select a specific port for data transfer and

polling FIFO status. RADR[4] is the MSB and RADR[0] is the LSB. This bus is

sampled on the rising edge of RSCLK. In POS-PHY Level 3 (or SPI-3) mode, this bus

is ignored.

DS3181/DS3182/DS3183/DS3184

PIN TYPE FUNCTION

RDATA[31:0] Oz

Receive Data [31:0] (tri-state)

This signal is tri-state when global reset is applied.

RDATA[31:0]: This 32-bit data bus is used to transfer cell/packet data to the

ATM/Link layer device. This bus is updated on the rising edge of RSCLK.

In 32-bit mode-

RDATA[31] is the MSB and RDATA[0] is the LSB.

In UTOPIA L2 or POS-PHY L2 modes, RDATA[31:0] are driven when one of

the ports is selected for data transfer, and tri-stated when REN is deasserted,

none of the ports is selected or data path reset is active.

In UTOPIA L3 or POS-PHY L3 modes RDATA[31:0] are driven.

In 16-bit mode-

RDATA[15] is the MSB, RDATA[0] is the LSB, and RDATA[31:16] are not

used.

In UTOPIA L2 or POS-PHY L2 modes, RDATA[15:0] are driven when one of

the ports is selected for data transfer, and tri-stated when REN is deasserted,

none of the ports is selected or data path reset is active. RDATA[31:16] are

tri-stated.

In UTOPIA L3 or POS-PHY L3 modes, RDATA[31:0] are driven.

In 8-bit mode (reset default)-

RDATA[7] is the MSB, RDATA[0] is the LSB, and RDATA[31:8] are not used.

In UTOPIA L2 (reset default) or POS-PHY L2 modes, RDATA[7:0] are driven

when one of the ports is selected for data transfer, and tri-stated when REN

is deasserted, none of the ports is selected or data path reset is applied.

RDATA[31:8] are tri-stated.

In UTOPIA L3 or POS-PHY L3 modes, RDATA[31:0] are driven.

RPRTY Oz

Receive Parity (tri-state)

RPRTY: This signal indicates the parity on the data bus when parity generation is

enabled. This option programmable. RPRTY is held low if parity generation is

disabled. This signal is updated on the rising edge of RSCLK.

In UTOPIA L2 (reset default) or POS-PHY L2 modes, this signal is driven when one

of the ports is selected for data transfer, and tri-stated when REN is deasserted,

none of the ports is selected or data path reset is active.

In UTOPIA L3 or POS-PHY L3 modes this signal is driven.

REN I

Receive Enable (active low)

REN: This signal is used by the ATM/Link device to control the transfer of cell/packet

data on the RDATA bus. If REN is high, no transfer occurs. If REN is low, a transfer

occurs. This signal can be sampled on the rising edge of RSCLK.

RDXA[1] /

RPXA /

RSX

Receive Direct Cell/Packet Available [1] / Polled Cell/Packet Available / Start of

Transfer (tri-state)

This signal is tri-state when global reset is applied.

RDXA[1]: This signal is active in UTOPIA L2, Utopia L3 or POS-PHY L2 modes

when direct status mode is selected. It is used to indicate when port 1 can send data

to the ATM/Link layer device. This signal is updated on the rising edge of RSCLK.

In UTOPIA L2 or UTOPIA L3 modes, RDXA goes high when the port 1 FIFO has

more than a programmable number of ATM cells ready for transfer ("almost empty"

level). RDXA goes low when the associated port does not have a complete ATM cell

ready for transfer.

In POS-PHY L2 mode, RDXA goes high when the port 1 FIFO contains more data

than the "almost empty" level or has an end of packet ready for transfer. RDXA goes

low when the associated port does not have an end of packet ready for transfer and

is "almost empty".

RPXA: (Reset default) This signal is active in UTOPIA L2, UTOPIA L3 or POS-PHY

L2 modes when polled status mode is selected. It is used to indicate when the polled

port, as selected by RADR[4:0], can send data to the ATM/Link layer device. This

signal is updated on the rising edge of RSCLK.

DS3181/DS3182/DS3183/DS3184

PIN TYPE FUNCTION

In UTOPIA L2 or UTOPIA L3 modes, RPXA goes high when the polled port has more

than a programmable number of ATM cells ready for transfer ("almost empty" level of

the associated FIFO). RPXA goes low when the polled port’s FIFO does not have a

complete ATM cell ready for transfer.

In POS-PHY L2 mode, RPXA goes high when the polled port’s FIFO contains more

data than the "almost empty" level or has an end of packet ready for transfer. RPXA

goes low when the port does not have an end of packet ready for transfer and is

"almost empty".

In UTOPIA L2 (reset default) or POS-PHY L2 modes, this signal is driven when one

of the ports is being polled, and is tri-stated when none of the ports is being polled or

when data path reset is active.

In UTOPIA L3 mode this signal is driven.

RSX: This signal is active in POS-PHY L3 modes and indicates the start of a data

transfer. This signal is updated on the rising edge of RSCLK.

RSX goes high immediately before the start of data transfer to indicate that the in-

band port address is present on RDATA. RSX goes high when the value of RDATA

is the address of the receive port from which data is to be transferred. When RSX

goes low, all subsequent transfers will be from the port specified by the in-band

address. When RSX is high, RVAL must be low.

This signal is always driven in POS-PHY L3 mode.

RDXA[4:2] O

Receive Direct Cell/Packet Available [4:2]

RDXA[4:2]: This signal is used to indicate when the associated port can send data

to the ATM/Link layer device. This signal is updated on the rising edge of RSCLK.

In UTOPIA L2 or UTOPIA L3 modes, RDXA goes high when the associated port has

more than a programmable number of ATM cells ready for transfer ("almost empty"

level). RDXA goes low when the associated port does not have a complete ATM cell

ready for transfer.

In POS-PHY L2 mode, RDXA goes high when the associated port’s FIFO contains

more data than the "almost empty" level or has an end of packet ready for transfer.

RDXA goes low when the associated port’s FIFO does not have an end of packet

ready for transfer and is "almost empty".

In POS-PHY Level 3 (or SPI-3) mode or when polled status mode is selected, these

signals are held low.

RSOX Oz

Receive Start Of Cell/Packet (tri-state)

This signal is tri-state when global reset is applied.

RSOX: This signal is used to indicate the first transfer of a cell/packet. This signal is

updated on the rising edge of RSCLK.

In UTOPIA L2 or UTOPIA L3 modes, RSOX is used to indicate the first transfer of a

cell.

In POS-PHY L2 or POS-PHY L3 modes, RSOX is used to indicate the first transfer of

a packet.

In UTOPIA L2 (reset default) or POS-PHY L2 modes, this signal is driven when one

of the ports is selected for data transfer, and tri-stated when REN is deasserted,

none of the ports is selected or data path reset is active.

In UTOPIA L3 or POS-PHY L3 modes this signal is driven.

REOP Oz

Receive End Of Packet (tri-state)

This signal is tri-state when global reset is applied.

REOP: In POS-PHY L2 or POS-PHY L3 modes, this signal is used to indicate the

last transfer of a packet. This signal is updated on the rising edge of RSCLK.

In UTOPIA L3 mode, this signal is held low.

In POS-PHY L2 mode, this signal is driven when one of the ports is selected for data

transfer, and tri-stated when REN is deasserted, none of the ports is selected or data

path reset is active.

In UTOPIA L2 (reset default) mode this signal is tri-stated.

In all UTOPIA L3 or POS-PHY L3 modes this signal is driven.

DS3181/DS3182/DS3183/DS3184

PIN TYPE FUNCTION

RVAL Oz

Receive Packet Data Valid (tri-state)

This signal is tri-state when global reset is applied.

RVAL: In POS-PHY L2 or POS-PHY L3 modes, this signal is used to indicate the

validity of a receive data transfer. When RVAL is high, the receive data bus (RDATA,

RPRTY, RSOX, REOP, RMOD, and RERR) is valid and a packet data transfer

occurs. When RVAL is low, the receive data bus is invalid and a data transfer does

not occurs. This signal is updated on the rising edge of RSCLK.

RVAL goes high when a port is selected for packet data transfer and the port has a

programmable size block of data or an end of packet ready for transfer. In POS-PHY

L2 mode, RVAL goes low if the selected port is empty, at the end of a packet, or

when REN is deasserted. Once RVAL goes low, it will remain low until REN is

deasserted.

In POS-PHY L3 mode, RVAL goes low if the selected port is empty or at the end of a

packet if the minimum deassertion time is greater than zero. RVAL will remain

deasserted for the programmable minimum deassertion time.

In UTOPIA L3 mode, this signal is held low.

In POS-PHY L2 mode, this signal is driven when one of the ports is selected for data

transfer, and tri-stated when REN is deasserted, none of the ports is selected or data

path reset is active.

In UTOPIA L2 (reset default) mode this signal is tri-stated.

In all UTOPIA L3 or POS-PHY L3 modes this signal is driven.

RMOD[1:0] Oz

Receive Packet Data Modulus [1:0] (Tri-State).

This signal is tri-state when global reset is applied.

RMOD[1:0]: In POS-PHY L2 or POS-PHY L3 modes, this signal is used to indicate

the number of valid bytes on the RDATA bus.

RMOD[1:0]=00 RDATA[31:0] valid

RMOD[1:0]=01 RDATA[31:8] valid

RMOD[1:0]=10 RDATA[31:16] valid

RMOD[1:0]=11 RDATA[31:24] valid

This signal is updated on the rising edge of RSCLK.

RMOD is only valid when REOP is high.

In UTOPIA L3, 8-bit POS-PHY L2 or 8-bit POS-PHY L3 modes, RMOD[1:0] signals

are held low.

In 16-bit POS-PHY L2 or 16 bit POS-PHY L3 modes, RMOD[1] is held low.

In POS-PHY L2 mode, these signals are driven when one of the ports is selected for

data transfer, and tri-stated when REN is deasserted, none of the ports is selected or

data path reset is active.

In UTOPIA L2 (reset default) mode these signals are tri-stated.

In UTOPIA L3 or POS-PHY L3 modes these signals are driven.

RERR Oz

Receive Packet Error (Tri-State).

This signal is tri-state when global reset is applied.

RERR: In POS-PHY L2 or POS-PHY L3 modes, this signal is used to indicate that

the current packet is erred. When RERR is high, the current packet should be

aborted. This signal is updated on the rising edge of RSCLK.

RERR is only valid when REOP is high.

In UTOPIA L3 mode this signal is held low.

In POS-PHY L2 mode, this signal is driven when one of the ports is selected for data

transfer, and tri-stated when REN is deasserted, none of the ports is selected or data

path reset is active.

In UTOPIA L2 (reset default) mode this signal is tri-stated.

In UTOPIA L3 or POS-PHY L3 modes, this signal is driven.

DS3181/DS3182/DS3183/DS3184

PIN TYPE FUNCTION

MICROPROCESSOR INTERFACE

D[15:0] IO

Bidirectional 16- or 8-Bit Data Bus

This bus is tri-state when RST pin is low or CS pin is high.

D[15:0]: A 16-bit or 8-bit data bus used to input data during register writes, and data

outputs during register reads. The upper 8 bits are not used and never driven in 8-bit

bus mode.

Weak pullup resistors or bus holders should be used for each pin.

A[10:1] I

Address Bus (minus LSB)

A[10:1]: identifies the specific 16 bit registers, or group of 8 bit registers, being

accessed. A[10] must be tied to ground for the DS3181 and DS3182 versions.

A[0] /

BSWAP

Address Bus LSB / Byte Swap

A[0]: This signal is connected to the lower address bit in 8-bit systems. (WIDTH=0)

1 = Output register bits 15:8 on D[7:0], D[15:8] not driven

0 = Output register bits 7:0 on D[7:0], D[15:8] not driven

BSWAP: This signal is tied high or low in 16-bit systems.

(WIDTH=1)

1 = Output register bits 15:8 on D[7:0], 7:0 on D[15:8]

0 = Output register bits 7:0 on D[7:0], 15:8 on D[15:8]

ALE I

Address Latch Enable

ALE: This signal is used to latch the address on the A[10:0] pins in multiplexed

address systems. When it is high the address is fed through the address latch to the

internal logic. When it transitions to low, the address is latched and held internally

until the signal goes back high. ALE should be tied high for non-multiplexed address

systems.

CS I Chip Select (active low)

CS: This signal must be low during all accesses to the registers

RD / DS I

Read Strobe (active low) / Data Strobe (active low)

RD: Read Strobe mode (MODE=0):

RD is low during a register read.

DS: Data Strobe mode (MODE=1):

DS is low during either a register read or a write.

WR / R/W I

Write Strobe (active low) / R/W Select

WR: Write Strobe mode (MODE=0):

WR is low during a register write.

R/W: Data Strobe mode (MODE=1):

R/W is high during a register read cycle, and low during a register write cycle.

RDY Oz

Ready Handshake (active low)

RDY: This ready signal is driven low when the current read or write cycle is in

progress. When the current read or write cycle is not ready it is driven high. When

device is not selected, it is not driven.

INT Oz

Interrupt (active low)

This signal is tri-state when RST pin is low.

INT: This interrupt signal is driven low when an event is detected on any of the

enabled interrupt sources in any of the register banks. When there are no active and

enabled interrupt sources, the pin can be programmed to either drive high or not drive

high. The reset default is to not drive high when there are no active and enabled

interrupt source. All interrupt sources are disabled when RST=0 and they must be

programmed to be enabled.

MODE I

Mode Select RD/WR or DS Strobe Mode

MODE: 1 = Data Strobe Mode, 0 = Read/Write Strobe Mode

WIDTH I

Data Bus Width Select 8- or 16-Bit Interface

WIDTH: 1 = 16-bits, 0 = 8 bits

DS3181/DS3182/DS3183/DS3184

PIN TYPE FUNCTION

MISC I/O

GPIO1 IO

General-Purpose IO 1

GPIO1: This signal is configured to be a general-purpose IO pin, or an alarm output

signal for port 1. This pin is an input after reset and should have a pullup resistor on it

if not connected to a signal or programmed as an output.

GPIO2 IO

General-Purpose IO 2

GPIO2: This signal is configured to be a general-purpose IO pin, or the 8KREFO

output signal, or an alarm output signal for port 1. This pin is an input after reset and

should have a pullup resistor on it if not connected to a signal or programmed as an

output.

GPIO3 IO

General-Purpose IO 3

GPIO3: This signal is configured to be a general-purpose IO pin, or an alarm output

signal for port 2. This pin is an input after reset and should have a pullup resistor on it

if not connected to a signal or programmed as an output.

GPIO4 IO

General-Purpose IO 4

GPIO4: This signal is configured to be a general-purpose IO pin, or the 8KREFI input

signal, or an alarm output signal for port 2. When configured for 8KREFI mode the

signal frequency should be 8,000 Hz +/- 500 ppm and about 50% duty cycle. This pin

is an input after reset and should have a pullup resistor on it if not connected to a

signal or programmed as an output.

GPIO5 IO

General-Purpose IO 5

GPIO5: This signal is configured to be a general-purpose IO pin, or an alarm output

signal for port 3. This pin is an input after reset and should have a pullup resistor on it

if not connected to a signal or programmed as an output.

GPIO6 IO

General-Purpose IO 6

GPIO6: This signal is configured to be a general-purpose IO pin, or the TMEI input

signal, or an alarm output signal for port 3. When configured for TMEI input, the signal

low time and high time must be greater than 500ns. This pin is an input after reset

and should have a pullup resistor on it if not connected to a signal or programmed as

an output.

GPIO7 IO

General-Purpose IO 7

GPIO7: This signal is configured to be a general-purpose IO pin, or an alarm output

signal for port 4.

This pin is an input after reset and should have a pullup resistor on it if connected to a

signal or programmed as an output.

GPIO8 IO

General-Purpose IO 8

GPIO8: This signal is configured to be a general-purpose IO pin, or the PMU input

signal, or an alarm output signal for port 4. When configured for PMU input, the signal

low time and high time must be greater than 500ns. This pin is an input after reset

and should have a pullup resistor on it if not connected to a signal or programmed as

an output.

TEST I

Test Enable (active low)

TEST: This signal enables the internal scan test mode when low. For normal operation

tie high. This is an asynchronous input.

HIZ I

High-Impedance Test Enable (active low)

HIZ: This signal puts all digital output and bidirectional pins in the high-impedance

state when it low and JTRST is low. For normal operation tie high. This is an

asynchronous input.

RST I

Reset (active low)

RST: This signal resets all the internal processor registers and logic when low. Global

and port data path resets are enabled and port power-downs are enabled. This pin

should be low while power is applied and set high after the power is stable. This is an

asynchronous input.

DS3181/DS3182/DS3183/DS3184

PIN TYPE FUNCTION

JTAG

JTCLK I

JTAG Clock

JTCLK: This clock input is typically a low frequency (less than 10 MHz) 50% duty

cycle clock signal.

JTMS Ipu

JTAG Mode Select (with pullup)

JTMS: This input signal is used to control the JTAG controller state machine and is

sampled on the rising edge of JTCLK.

JTDI Ipu

JTAG Data Input (with pullup)

JTDI: This input signal is used to input data into the register that is enabled by the

JTAG controller state machine and is sampled on the rising edge of JTCLK.

JTDO Oz

JTAG Data Output

JTDO: This output signal is the output of an internal scan shift register enabled by the

JTAG controller state machine and is updated on the falling edge of JTCLK. The pin

is in the high impedance mode when a register is not selected or when the JTRST

signal is high. The pin goes into and exits the high impedance mode after the falling

edge of JTCLK

JTRST Ipu

JTAG Reset (active low with pullup)

JTRST: This input forces the JTAG controller logic into the reset state and forces the

JTDO pin into high impedance when low. This pin should be low while power is

applied and set high after the power is stable. The pin can be driven high or low for

normal operation, but must be high for JTAG operation.

CLAD

CLKA I

Clock A

CLKA: This clock input is a DS3 signal (44.736MHz ±20ppm) when the CLAD is

disabled or it is one of the CLAD reference clock signals when the CLAD is enabled.

CLKB IO

Clock B

CLKB: This pin is a E3 (34.368 MHz ±20 ppm) input signal when the CLAD is

disabled (reset default) or it can be enabled to output a generated clock when the

CLAD is enabled. The pin is driven low when it is not selected to output a clock signal

and the CLAD is enabled. See Table 10-11.

CLKC IO

Clock C

CLKC: This pin is a STS-1 (51.84 MHz ±20ppm) input signal when the CLAD is

disabled or it can be enabled to output a generated clock when the CLAD is enabled.

The pin is driven low when it is not selected to output a clock signal and the CLAD is

enabled. See Table 10-11.

POWER

VSS PWR

Ground, 0V potential. Common to digital core, digital IO and all analog circuits.

VDD PWR

Digital 3.3V. Common to digital core and digital IO.

AVDDRn PWR

Analog 3.3V for receive LIU on port n. Powers receive LIU on port n.

AVDDTn PWR

Analog 3.3V for transmit LIU on port n. Powers transmit LIU on port n.

AVDDJn PWR

Analog 3.3V for jitter attenuator on port n. Powers jitter attenuator on port n.

AVDDC PWR

Analog 3.3V for CLAD. Powers clock rate adapter common to all ports.

DS3181/DS3182/DS3183/DS3184

8.3 Pin Functional Timing

8.3.1 Line IO

8.3.1.1 B3ZS/HDB3/AMI Mode Transmit Pin Functional Timing

There is no suggested time alignment between the TXPn, TXNn and TX LINE signals and the TLCLKn clock signal.

The TX DATA signal is not a readily available signal, it is meant to represent the data value of the other signals.

The TXPn and TXNn signals are only available when the line is in B3ZS/HDB3 or AMI mode and the LIU is

enabled. The TPOSn, TNEGn and TLCLKn signals are only available when the line is in B3ZS/HDB3 or AMI mode

and the transmit line pins are enabled. The TPOSn, TNEGn and TLCLKn pins can be enabled at the same as the

LIU is enabled.

The TPOSn and TNEGn signals change a small delay after the positive edge of the reference clock if the clock pin

is not inverted; otherwise they change after the negative edge. The TLCLKn clock pin is the clock reference

typically used for the TPOSn and TNEGn signals, but they can be time referenced to the TCLKIn, TCLKOn,

RLCLKn or RCLKOn clock pins. The TPOSn and TNEGn pins can be inverted, but the polarity of TXPn and TXNn

cannot be inverted.

TXPn and TXNn are differential analog output pins. They are biased around ½ VDD and pulse above and below

the bias voltage by about 1 Volt. These signals are connected to the windings of a 1:2 step down transformer and

the other winding of the transformer creates the TX LINE signal. The TX LINE signal is a bipolar signal that pulses

about 1 Volt positive and 1 Volt negative above and below ground (0 volts). See Figure 1-1 for a diagram of the

external connections.

Figure 8-1 and Figure 8-2 shows the relationship between the analog and the digital outputs.

Figure 8-1. TX Line IO B3ZS Functional Timing Diagram

TLCLK

TPOS

TNEG

(TX DATA)

B3ZS CODEWORD

(TX LINE) +

TXP

TXN

0 V

BIAS V

DS3181/DS3182/DS3183/DS3184

Figure 8-2. TX Line IO HDB3 Functional Timing Diagram

TLCLK

TPOS

TNEG

(TX DATA)

HDB3 CODEWORD

(TX LINE) +

TXP

TXN

0 V

BIAS V

8.3.1.2 B3ZS/HDB3/AMI Mode Receive Pin Functional Timing

There is no suggested time alignment between the RXPn, RXNn and RX LINE signals and the RLCLKn clock

signal. The RX DATA signal is not an always readily available signal, it is meant to represent the data value of the

other signals.

The RXPn and RXNn pins are only available when the line is in B3ZS/HDB3 or AMI mode and the LIU is enabled.

The RPOSn, RNEGn and RLCLKn pins are only available when the line is in B3ZS/HDB3 or AMI mode and the LIU

is disabled.

The RPOSn and RNEGn signals are sampled at the rising edge of the reference clock signal if the clock pin is not

inverted; otherwise they are sampled at the negative edge. The RLCLKn clock pin is the clock reference used for

the RPOSn and RNEGn signals. The RPOSn and RNEGn pins can be inverted.

RXPn and RXNn are differential analog input pins. They are biased around ½ VDD and pulse above and below the

bias voltage by about 1 Volt with zero cable length. These signals are connected to the windings of a 1:2 step up

transformer and the other winding of the transformer is connected to the RX LINE signal. The RX LINE signal is a

bipolar signal that pulses about 1 Volt positive and 1 Volt negative above and below ground (0 volts) with zero

cable length. See Figure 1-1 for a diagram of the external connections.

Figure 8-3 and Figure 8-4 shows the relationship between the analog and the digital outputs.

Figure 8-3. RX Line IO B3ZS Functional Timing Diagram

RLCLK

RPOS

RNEG

(RX DATA)

B3ZS CODEWORD

(RX LINE) +

RXP

RXN

0 V

BIAS V

DS3181/DS3182/DS3183/DS3184

Figure 8-4. RX Line IO HDB3 Functional Timing Diagram

RLCLK

RPOS

RNEG

(RX DATA)

HDB3 CODEWORD

(RX LINE) +

RXP

RXN

0 V

BIAS V

8.3.1.3 UNI Mode Transmit Pin Functional Timing

The TDATn pin is available when the line interface is in the UNI mode and the transmit line pins are enabled. The

TOHMOn and TOHMIn pins are available when the framer is in one of the “- OHM” modes and the transmit line

pins are enabled. The line interface is forced into the UNI mode when the framer is in one of the “- OHM” modes.

The TOHMIn pin is used to control the insertion of gaps in the data by stopping the internal formatters and data

sources. These gaps are inserted where external logic will add more overhead bits to the signal. The TOHMOn

signal is delayed from the TOHMIn signal by three clock periods. The TOHMOn signal aligns to the TDATn signal

and is high when internal framing and signal source has stopped inserting data. The TDATn signal should be

ignored when TOHMOn is high. In the “- OHM Octet” framing modes, the first payload bit after the TOHMOn signal

goes low is the MSB (Bit 1) of a payload Octet.

The TDATn and TOHMOn signals change a small delay after the positive edge of the reference clock signal if the

clock pin is not inverted, other wise they change after the negative edge. The TOHMIn signal is sampled at the

rising edge of the reference clock signal if the clock pin is not inverted; otherwise it is sampled at the negative

edge. The TLCLKn clock pin is the clock reference typically used for the TDATn, TOHMOn and TOHMIn signals,

but they can be time referenced to the TCLKIn, TCLKOn, RLCLKn or RCLKOn clock pins. The TDATn, TOHMOn,

and TOHMIn pins can be inverted. See Figure 8-5 and Figure 8-6

Figure 8-5. TX Line IO UNI OHM Functional Timing Diagram

TLCLK

TDAT

TOHMI

TOHMO TDAT GAP FOR EXT OVERHEAD INSERTION

Figure 8-6. TX Line IO UNI Octet Aligned OHM Functional Timing Diagram

TLCLK

TDAT

TOHMI

TOHMO

ATM Cell /Packet Octet n+1

B1 B2 B3 B4 B5 B6 B7 B8 B1B6 B7 B8

Octet n

EXT OH BIT LOCATIONS

DS3181/DS3182/DS3183/DS3184

8.3.1.4 UNI Mode Receive Pin Functional Timing

The RDATn pin is available when the line interface is in the UNI mode. The ROHMIn pin is available when the

framer is in one of the “-OHM” modes. The RLCVn pin is available when the line interface is in the UNI mode and

the framer is not in one of the “-OHM” modes. The line interface is forced into the UNI mode when the framer is in

one of the “-OHM” modes.

The ROHMIn pin is used to mark the RDATn bits that will be ignored by the internal receive logic. When the

ROHMIn pin is high, the internal framers and data sinks will ignore the corresponding RDATn bits. In the “- OHM

Octet” framing modes, the data on RDATn is octet aligned with the ROHMIn signal, the first bit of the serial data on

RDATn is the MSB (Bit 1) of a payload Octet.

All bits on the RDATn pin, even the bits that are marked by ROHMIn, will come out the RSERn pin, if the RSERn

pin is enabled.

The signal on the RLCVn pin enables the BPV counter, which is in the line interface, to increment each clock it is

high.

The RDATn, ROHMIn and RLCVn signals are sampled at the rising edge of the reference clock signal if the clock

pin is not inverted; otherwise they are sampled at the negative edge. The RLCLKn clock pin is the clock reference

used for the RDATn, ROHMIn and RLCVn signals. The RDATn, ROHMIn and RLCVn pins can be inverted. See

Figure 8-7 and Figure 8-8.

Figure 8-7. RX Line IO OHM UNI Functional Timing Diagram

RLCLK

RDAT

RLVC

ROHM RDAT DATA WILL BE IGNORED

INC BPV COUNTER TWICE INC BPV COUNTER ONCE

Figure 8-8. RX Line IO UNI Octet Aligned OHM Functional Timing Diagram

RLCLK

RDAT

ROHM

ATM Cell /Packet Octet n+1

B1 B2 B3 B4 B5 B6 B7 B8 B1B6 B7 B8

Octet n

EXT OH BIT LOCATIONS

8.3.2 DS3/E3 Framing and PLCP Overhead Functional Timing

Figure 8-9 shows the relationship of the DS3 receive-overhead port pins.

Figure 8-9. DS3 Framing Receive Overhead Port Timing

ROH

ROHSOF

ROHCLK

F74C73F73

1 2 3 4 5 6 7 8 9 1011121314 16171819202122232415

F11 C11

X1 F13C12

F12 C13 F14 F21 C21

X2 F23C22

F22 C23 F24 F31 C31

P1 C32

F32

DS3181/DS3182/DS3183/DS3184

Figure 8-10 shows the relationship of the E3 G.751 receive-overhead port pins.

Figure 8-10. E3 G.751 Framing Receive Overhead Port Timing

ROH

ROHSOF

ROHCLK

FAS

1 2 3 4 5 6 7 8 9 10 11 12 13 14 16 17 18 19 20 21 22 23 2415

FAS

10 A

FAS

NFAS

FAS

Figure 8-11 shows the relationship of the E3 G.832 receive-overhead port pins.

Figure 8-11. E3 G.832 Framing Receive Overhead Port Timing

ROH

ROHSOF

ROHCLK

1 2 3 4 5 6 7 8 9 10 11 12 13 14 16 17 18 19 20 21 22 23 2415

FA1

FA2

Figure 8-12 shows the relationship of the DS3 transmit-overhead port pins.

Figure 8-12. DS3 Framing Transmit Overhead Port Timing

TOH

TOHSOF

TOHCLK

F74C73F73

1 2 3 4 5 6 7 8 9 1011121314 16171819202122232415

F11

X1 F13C12F12 C13 F14 F21 C21

X2 F23C22

F22 C23 F24 F31 C31P1 C32F32

TOHEN

C11

Figure 8-13 shows the relationship of the E3 G.751 transmit-overhead port pins.

Figure 8-13. E3 G.751 Framing Transmit Overhead Port Timing

TOH

TOHSOF

TOHCLK

FAS

1234567891011121314 16171819202122232415

FAS

10 A

FAS

NFAS

FAS

TOHEN

DS3181/DS3182/DS3183/DS3184

Figure 8-14 shows the relationship of the E3 G.832 transmit-overhead port pins.

Figure 8-14. E3 G.832 Framing Transmit Overhead Port Timing

TOH

TOHCLK

1234567891011121314 16171819202122232415

FA1

FA2

TOHSOF

TOHEN

Figure 8-15 shows the relationship of the DS3 PLCP receive-overhead port pins.

Figure 8-15. DS3 PLCP Receive Overhead Port Timing

RPOH

RPOHSOF

RPOHCLK

1234567891011121314 16171819202122232415

Figure 8-16 shows the relationship of the E3 G.751 PLCP receiver-overhead port pins.

Figure 8-16. E3 G.751 PLCP Receive Overhead Port Timing

RPOH

RPOHSOF

RPOHCLK

1234567891011121314 16171819202122232415

Figure 8-17 shows the relationship of the DS3 PLCP transmit-overhead port pins.

Figure 8-17. DS3 PLCP Transmit Overhead Port Timing

1 2 3 4 5 6 7 8 9 10 11 12 13 14 16 17 18 19 20 21 22 23 2415

TPOH

TPOHCLK

TPOHSOF

TPOHEN

DS3181/DS3182/DS3183/DS3184

Figure 8-18 shows the relationship of the E3 G.751 PLCP transmit-overhead port pins.

Figure 8-18. E3 G.751 PLCP Transmit Overhead Port Timing

TPOH

TPOHCLK

1 2 3 4 5 6 7 8 9 1011121314 16171819202122232415

TPOHSOF

TPOHEN

8.3.3 Internal (IFRAC) and External (XFRAC) Fractional DS3/E3 Overhead Functional Timing

The fractional overhead pins provide the ability to insert bits in the DS3/E3 payload that are not used for cells or

packets. The source of fractional overhead bits is controlled by an internal register (see FRAC.TCR), specifying

internal generation or external sourcing via the TFOHENIn pin. The allocation of DS3/E3 payload used for cell and

packet data is also programmable or controlled by the TFOHENIn pin. The TSOFIn, TSOFOn, TDENn, RSOFOn

and RDENn pins are used to determine which bit positions are DS3/E3 overhead so that fractional overhead bits

will be inserted only in DS3/E3 payload. The TCLKOn and RCLKOn clocks can be configured for gapped modes

that will toggle for each fractional overhead bit, allowing a simple way of using the overhead bits for messaging.

Figure 8-19 shows the timing with the external fractional transmit port pins. P designates payload bits, F designates

fractional overhead, and L designates DS3/E3 overhead, based on TDEN.

Figure 8-19. External (XFRAC) Transmit Fractional Timing

123456789101112131415161718192021222324

TFOH

TFOHENI

FX1 FX2 FX3 F22

TSOFI

TSOFO

TDEN

PX5 PX6

PX5 PX6 L1 L2

L2F11 F12 F13 F21L1 P11 P12 P13 P14 P15 P15 P21 P22 P23 P24 P25 P26

P11 P12 P13 P14 P15 P16 P21 P22 P23 P24 P25 P26

TCLKI or

TCLKO

Figure 8-20 shows the timing with the external fractional receive port pins.

Figure 8-20. External (XFRAC) Receive Fractional Timing

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24

RDEN

RFOHENI

RSER

RSOF

L1 P11 P12 P13 P14 P15 P16 P22 P23PY4 PY5 PY6

L1FY1 FY2 FY3 F11 F12 F13 L2 F21

PY3 L2 P21

P21 P22 P23 P24 P25 P26P11 P12 P13 P14 P15 P16PY5 PY6PY4

RCLKI or

RCLKO

DS3181/DS3182/DS3183/DS3184

Figure 8-21 shows the timing with the internal fractional transmit port pins.

Figure 8-21. Internal (IFRAC) Transmit Fractional Timing

123456789

TFOH

TFOHENO

TCLKI or

TCLKO

FOH FOH FOH XXXXXX

TGCLK

10 11 12 13 14

FOH

XX XXX

16 17 18 19 20 21 22 23 24

FOH FOH X XXXXXX FOH

Figure 8-22 shows the timing with the internal fractional transmit port pins.

Figure 8-22. Internal (IFRAC) Receive Fractional Timing

123456789

RSER

RFOHENO

RCLKI or

RCLKO

FOH FOH

FOH XXX X

RGCLK

10 11 12 13 14

FOH

XX X

16 17 18 19 20 21 22 23 24

FOH

FOH XXXXXXFOH

FOH

8.3.4 Flexible Fractional (FFRAC) DS3/E3 Overhead Interface Functinal Timing

The Flexible fractional mode provides the capability to modify the payload data from the cell/packet processor

before inserting it into the DS3 or E3 payload. The bit rate of the payload from the cell/packet processor can be

less than the DS3 or E3 payload bit rate. The interface to the DS3 or E3 payload uses the TSOFIn, TSOFOn,

TDENn, TSERn, RSOFOn, RDENn and RSERn pins. The interface to the cell/packet processor uses the

TPDENIn, TPDENOn, TPDATn, RPDENIn and RPDATn pins. The TPDENIn pin is used to determine the bit rate of

the transmit cell/packet payload data. The TPDENOn pin is high when the data on TPDATn is valid. The delay

between TPDENIn and TPDENOn is three clocks. The RPDENIn pin is used to determine the bit rate of the receive

cell/packet processor data. The cell/packet processor uses the cell/packet data on the RPDATn pin when the

RPDENIn pin is high.

DS3181/DS3182/DS3183/DS3184

Figure 8-23 shows the timing with the flexible fractional transmit port pins.

Figure 8-23. Transmit Flexible Fractional (FFRAC) Timing

TPDENI

TCLKI or

TCLKO

TSOFI

TSOFO

TDEN

TSER

TPDAT P4 P5 P6 P17P2 P3 P13

P10 P11 P12 P16

P14 P8 P9 P14 P15

TPDENO

FOx FOy FOz FO5FPy FPz OH2FO1 FO2 FO3 FO4OH1 FP1 FP2 FP3 FP4 FP5 FP6 FP7 FP8 FP9 FP10 FP11 FP12FPx

123456789101112131415161718192021222324

Figure 8-24 shows the timing with the flexible fractional receive port pins.

Figure 8-24. Receive Flexible Fractional (FFRAC) Timing

RDEN

RPDENI

RSER

RSOFO

OH1FO1 FO2 FO3 FO4 FO5 FO6 OH2 FP19FP13 FP14 FP15 FP16 FP17 FP18FP7 FP8 FP9 FP10 FP11 FP12FP5 FP6FP4

RCLKI or

RCLKO

1 2 3 4 5 6 7 8 9 101112131415161718192021222324

RSER XXP3 P13 P14 P15 P16P1 P2 P7 P8 P9 P10 P11 P12P5 P6P4

DS3181/DS3182/DS3183/DS3184

8.3.5 UTOPIA/POS-PHY/SPI-3 System Interface Functional Timing

8.3.5.1 UTOPIA Level 2 Functional Timing

Figure 8-25 shows a multidevice transmit-interface multiple cell transfer to different PHY devices. On clock edge 2,

the ATM device places address ‘00h’ on the address bus (which is mapped to Port 1). PHY device '1' (Port 1)

indicates to the ATM device that it can accept cell data by asserting TDXA[1]. On clock edge 4, the ATM device

selects PHY device '1'. On clock edge 5, the ATM device starts a cell transfer to PHY device '1' by asserting TEN,

placing the first byte of cell data on TDATA, and asserting TSOX to indicate the transfer of the first byte of the cell.

On clock edge 6, the ATM device deasserts TSOX as it continues to place additional bytes of the cell on TDATA..

On clock edge 13, PHY device ‘2’ asserts TDXA[2] to indicate to the ATM device that it is ready to accept cell data.

On clock edge 15, PHY device '1’ indicates that it cannot accept the transfer of a complete cell by deasserting

TDXA[1]. On clock edge 16, the ATM device deselects PHY device '1' and selects PHY device '2' by deasserting

TEN and placing PHY device '2's address on TADR. On clock edge 17, the ATM device starts the transfer of a cell

to PHY device '2' by asserting TEN, placing the first byte of cell data on TDATA, and asserting TSOX to indicate the

transfer of the first byte of the cell. On clock edge 18, the ATM device deasserts TSOX as it continues to place

additional bytes of the cell on TDATA.

Figure 8-25. UTOPIA Level 2 Transmit Cell Transfer Direct Mode

TADR

TEN

TDATA

TSOX

19 20

…

TCLK

H3 P43 P44 P45 P46 P47 P48P42H1 H2

01h00h

Transfer

Cell To: PORT 1

H2 H3 H4

PORT 2

2345 76 8 10 11 12 13 14 15 16 17 189

TDXA[1]

TDXA[2]

TDXA[3]

TDXA[4]

DS3181/DS3182/DS3183/DS3184

Figure 8-26 shows a multidevice transmit-interface multiple cell transfer to different PHY devices. On clock edge 2,

the ATM device places address ‘00h’ on the address bus (which is mapped to Port 1). PHY device '1' (Port 1)

indicates to the ATM device that it has a complete cell to send by asserting RDXA[1]. On clock edge 4, the ATM

device selects PHY device '1'. On clock edge 5, the ATM device asserts REN. On clock edge 6, the PHY device ‘1’

starts a cell transfer to the ATM device by placing the first byte of cell data on RDATA, and asserting RSOX to

indicate the transfer of the first byte of the cell. On clock edge 7, the PHY device deasserts RSOX as it continues to

place additional bytes of the cell on RDATA. On clock edge 13, PHY device ‘2’ asserts RDXA[2] to indicate to the

ATM device that it is ready to send a cell. On clock edge 15, PHY device '1’ indicates that it cannot transfer a

complete cell by deasserting RDXA[1]. On clock edge 16, the ATM device deselects PHY device '1' and selects

PHY device '2' by deasserting REN and placing PHY device '2's address on RADR. On clock edge 17, the ATM

device asserts REN. On clock edge 18, PHY device ‘2’ (Port 2) starts the transfer of a cell to the ATM device by

placing the first byte of cell data on RDATA, and asserting RSOX to indicate the transfer of the first byte of the cell.

On clock edge 18, the PHY device deasserts RSOX as it continues to place additional bytes of the cell on RDATA.

Figure 8-26. UTOPIA Level 2 Receive Cell Transfer Direct Mode

RADR

REN

RDATA

RSOX

19 20

…

RSCLK

H3 P43 P44 P45 P46 P47 P48P42H1 H2

01h00h

Transfer

Cell From: PORT 1

H2 H3

PORT 2

2345 76 8 10 11 12 13 14 15 16 17 189

RDXA[1]

RDXA[2]

RDXA[3]

RDXA[4]

Figure 8-27 shows a multidevice transmit-interface multiple cell transfer to different PHY devices. On clock edge 2,

the ATM device polls PHY device 'N'. On clock edge 3, PHY device 'N' indicates to the ATM device that it can

accept cell data by asserting TPXA. On clock edge 4, the ATM device selects PHY device 'N'. On clock edge 5, the

ATM device starts a cell transfer to PHY device 'N' by asserting TEN, placing the first byte of cell data on TDATA,

and asserting TSOX to indicate the transfer of the first byte of the cell. On clock edge 6, the ATM device deasserts

TSOX as it continues to place additional bytes of the cell on TDATA. On clock edge 6, the ATM device also polls

PHY device 'O'. On clock edge 7, PHY device 'O' indicates that it can accept the transfer of a complete cell. On

clock edge 14, the ATM device polls PHY device 'N'. On clock edge 15, PHY device 'N' indicates that it cannot

accept the transfer of a complete cell. On clock edge 16, the ATM device deselects PHY device 'N' and selects

PHY device 'O' by deasserting TEN and placing PHY device 'O's address on TADR. On clock edge 17, the ATM

device starts the transfer of a cell to PHY device 'O' by asserting TEN, placing the first byte of cell data on TDATA,

and asserting TSOX to indicate the transfer of the first byte of the cell. On clock edge 18, the ATM device

deasserts TSOX as it continues to place additional bytes of the cell on TDATA.

DS3181/DS3182/DS3183/DS3184

Figure 8-27. UTOPIA Level 2 Transmit Multiple Cell Transfer Polled Mode

TADR

TPXA

TEN

TDATA

TSOX

19 20

…

TCLK

H3 P43 P44 P45 P46 P47 P48P42

H1 H2

1F 1F N1F 1FO1F L1F M1F N1F O1F P1F LN

M N N O P L M N O P

M…

Transfer

Cell To:

H2 H3 H4

2345 76 8 10 11 12 13 14 15 16 17 189

Figure 8-28 shows a multidevice receive-interface multiple cell transfer from different PHY devices. On clock edge

2, the ATM device polls PHY device 'N'. On clock edge 3, PHY device 'N' indicates to the ATM device that it has a

complete cell ready for transfer by asserting RPXA. On clock edge 4, the ATM device selects PHY device 'N'. On

clock edge 5, the ATM device asserts REN. On clock edge 6, PHY device 'N' starts a cell transfer by placing the

first byte of cell data on RDATA, and asserting RSOX to indicate the transfer of the first byte of the cell. On clock

edge 7, PHY device 'N' deasserts RSOX as it continues to place additional bytes of the cell on RDATA. On clock

edge 12, the ATM device polls PHY device 'O'. On clock edge 13, PHY device 'O' indicates to the ATM device that

it has a complete cell ready for transfer by asserting RPXA. On clock edge 16, the ATM device deselects PHY

device 'N' and selects PHY device 'O' by deasserting REN and placing PHY device 'O's address on RADR. On

clock edge 17, the ATM device asserts REN and PHY device 'N' stops transferring cell data and tri-states its

RDATA and RSOX outputs. On clock edge 18, PHY device 'O' starts a cell transfer by placing the first byte of cell

data on RDATA, and asserting RSOX to indicate the transfer of the first byte of the cell. On clock edge 19, PHY

device 'O' deasserts RSOX as it continues to place additional bytes of the cell on RDATA.

Figure 8-28. UTOPIA Level 2 Receive Multiple Cell Transfer Polled Mode

RADR

RPXA

REN

RDATA

RSOX

19 20

…

RCLK

1F 1F N1F 1FO1F M1F O1F P1F O1F N1F PN

M N N O L M O P O N

M…

H1 H2

Transfer

Cell From: N

H2H1P43 P44 P45 P46 P47 P48P42P41

2345 76 8 10 11 12 13 14 15 16 17 189

Figure 8-29 shows a multidevice receive-interface unexpected multiple cell transfer. Prior to clock edge 1, the cell

transfer was started. On clock edge 4, since no other PHY device has a cell ready for transfer, the ATM device

assumes another cell transfer from PHY device 'N' and leaves REN asserted. On clock edge 5, PHY device 'N'

stops transferring cell data and indicates that it does not have another cell ready for transfer by not asserting

RSOX. On clock edge 6, the ATM device deasserts REN to end the cell transfer process. At the same time, PHY

device 'N' indicates to the ATM device that it now has a complete cell ready for transfer by placing the first byte of

cell data on RDAT, and asserting RSOX to indicate the transfer of the first byte of the cell. On clock edge 7, PHY

device 'N' tri-states its RDAT and RSOX outputs because REN is deasserted. On clock edge 8, the ATM device

selects PHY device 'N'. On clock edge 9, the ATM device asserts REN. On clock edge 10, PHY device 'N'

continues the cell transfer by placing the second byte of cell data on RDAT, and deasserting RSOX.

DS3181/DS3182/DS3183/DS3184

Figure 8-29. UTOPIA Level 2 Receive Unexpected Multiple Cell Transfer

RADR

RPXA

REN*

RDAT

RSOX

19 20

RCLK

1F 1F N1F 1FO1F P1F L1F M1F O1F P1F LM

L M N O N P L M O P

Transfer

Cell From: N

P45 P46 P47 P48 XH1

23 4 5 76 8 10 11 12 13 14 15 16 17 189

H2 P2P1H3 H4 P6P5P3 P4 P7 P8

8.3.5.2 UTOPIA Level 3 Functional Timing

Figure 8-30 shows a multiport transmit-interface multiple cell transfer to different PHY devices. PHY port '1', ‘3’, ‘4’

indicate to the ATM device that they can accept cell data by asserting the TDXA[n]. On clock edge 2, the ATM

device selects PHY port '1' by putting address ‘00h’ on the address bus. On clock edge 5, the ATM device starts a

cell transfer to PHY port '1' by asserting TEN, placing the first byte of cell data on TDATA, and asserting TSOX to

indicate the transfer of the first byte of the cell. On clock edge 6, the ATM device deasserts TSOX as it continues to

place additional bytes of the cell on TDATA. On clock edge 13, PHY port ‘2’ asserts TDXA[2] to indicate it is ready

to accept a cell. On clock edge 15, PHY port ‘1’ deasserts TDXA[1] to indicate to the ATM device that it does not

have the availability to receive another complete cell. On clock edge 16, the ATM device selects PHY port '2' by

deasserting TEN and placing PHY port '2's address on TADR. On clock edge 17, the ATM device starts the transfer

of a cell to PHY port '2' by asserting TEN, placing the first byte of cell data on TDATA, and asserting TSOX to

indicate the transfer of the first byte of the cell. On clock edge 18, the ATM device deasserts TSOX as it continues

to place additional bytes of the cell on TDATA.

Figure 8-30. UTOPIA Level 3 Transmit Multiple Cell Transfer Direct Mode

TADR

TEN

TDATA

TSOX

19 20

…

TSCLK

H3 P43 P44 P45 P46 P47 P48P42H1 H2

01h00h

Transfer

Cell To: PORT 1

H2 H3 H4

PORT 2

2345 76 8 10 11 12 13 14 15 16 17 189

TDXA[1]

TDXA[2]

TDXA[3]

TDXA[4]

DS3181/DS3182/DS3183/DS3184

Figure 8-31 shows a multiport transmit-interface multiple cell transfer to different PHY devices. On clock edge 1,

the ATM device polls PHY port 'N'. On clock edge 3, PHY port 'N' indicates to the ATM device that it can accept cell

data by asserting TPXA. On clock edge 5, the ATM device selects PHY port 'N'. On clock edge 6, the ATM device

starts a cell transfer to PHY port 'N' by asserting TEN, placing the first byte of cell data on TDATA, and asserting

TSOX to indicate the transfer of the first byte of the cell. On clock edge 7, the ATM device deasserts TSOX as it

continues to place additional bytes of the cell on TDATA. On clock edge 11, the ATM device polls PHY port 'M'. On

clock edge 12, the ATM device polls PHY port 'N'. On clock edge 13, PHY port 'M' indicates that it can accept the

transfer of a complete cell. On clock edge 14, PHY port 'N' indicates that it cannot accept the transfer of a complete

cell. On clock edge 16, the ATM device deselects PHY port 'N' and selects PHY port 'M' by deasserting TEN and

placing PHY port 'M's address on TADR. On clock edge 17, the ATM device starts the transfer of a cell to PHY port

'M' by asserting TEN, placing the first byte of cell data on TDATA, and asserting TSOX to indicate the transfer of

the first byte of the cell. On clock edge 18, the ATM device deasserts TSOX as it continues to place additional

bytes of the cell on TDATA.

Figure 8-31. UTOPIA Level 3 Transmit Multiple Cell Transfer Polled Mode

TADR

TPXA

TEN

TDATA

TSOX

19 20

TCLK

P44 P45 P46 P47 P48P43X

N P Q N L M N O P Q R J K LO

LNP KMOQR

Transfer

Cell To: N

2345 76 8 10 11 12 13 14 15 16 17 189

MJLNPXJ

X X XXX H3H2

R KJ

OQR

…

XH1 H2 H3 P1

…

Figure 8-32 shows a multiport receive-interface multiple cell transfer from different PHY ports. On clock edge 3,

PHY port 'N' indicates to the ATM device that it has a complete cell ready for transfer by asserting RPXA. On clock

edge 5, the ATM device selects PHY port 'N'. On clock edge 6, the ATM device indicates to PHY port 'N' that it is

ready to accept a complete cell transfer by asserting REN. On clock edge 8, PHY port 'N' starts a cell transfer by

placing the first byte of cell data on RDATA, and asserting RSOX to indicate the transfer of the first byte of the cell.

On clock edge 9, PHY port 'N' deasserts RSOX as it continues to place additional bytes of the cell on RDAT. On

clock edge 11, the ATM device polls PHY device 'N'. On clock edge 12, PHY port 'M' indicates to the ATM device

that it has a complete cell ready for transfer by asserting RPXA. On clock edge 12, PHY port 'N' indicates to the

ATM device that it does not have a complete cell ready for transfer by deasserting RPXA. On clock edge 15, the

ATM device deselects PHY port 'N' and selects PHY port 'M' by deasserting REN and placing PHY port 'M's

address on RADR. On clock edge 16, the ATM device asserts REN. On clock edge 17, PHY port 'N' stops

transferring cell data. On clock edge 18, PHY port 'M' starts a cell transfer by placing the first byte of cell data on

RDATA, and asserting RSOX to indicate the transfer of the first byte of the cell. On clock edge 19, PHY port 'M'

deasserts RSOX as it continues to place additional bytes of the cell on RDATA.

DS3181/DS3182/DS3183/DS3184

Figure 8-32. UTOPIA Level 3 Receive Multiple Cell Transfer Direct Mode

RADR

REN

RDATA

RSOX

19 20

…

RSCLK

H3 P43 P44 P45 P46 P47 P48P42H1 H2

01h00h

Transfer

Cell From: PORT 1

H2 H3

PORT 2

2345 76 8 10 11 12 13 14 15 16 17 189

RDXA[1]

RDXA[2]

RDXA[3]

RDXA[4]

Figure 8-33 shows a multiport receive-interface multiple cell transfer from different PHY ports. On clock edge 1, the

ATM device polls PHY port 'N'. On clock edge 3, PHY port 'N' indicates to the ATM device that it has a complete

cell ready for transfer by asserting RPXA. On clock edge 5, the ATM device selects PHY port 'N'. On clock edge 6,

the ATM device indicates to PHY port 'N' that it is ready to accept a complete cell transfer by asserting REN. On

clock edge 8, PHY port 'N' starts a cell transfer by placing the first byte of cell data on RDATA, and asserting RSOX

to indicate the transfer of the first byte of the cell. On clock edge 9, PHY port 'N' deasserts RSOX as it continues to

place additional bytes of the cell on RDAT. On clock edge 11, the ATM device polls PHY device 'N'. On clock edge

12, PHY port 'M' indicates to the ATM device that it has a complete cell ready for transfer by asserting RPXA. On

clock edge 12, PHY port 'N' indicates to the ATM device that it does not have a complete cell ready for transfer by

deasserting RPXA. On clock edge 15, the ATM device deselects PHY port 'N' and selects PHY port 'M' by

deasserting REN and placing PHY port 'M's address on RADR. On clock edge 16, the ATM device asserts REN.

On clock edge 17, PHY port 'N' stops transferring cell data. On clock edge 18, PHY port 'M' starts a cell transfer by

placing the first byte of cell data on RDATA, and asserting RSOX to indicate the transfer of the first byte of the cell.

On clock edge 19, PHY port 'M' deasserts RSOX as it continues to place additional bytes of the cell on RDATA.

Figure 8-33. UTOPIA Level 3 Receive Multiple Cell Transfer Polled Mode

RADR

RPXA

REN

RDAT

RSOX

19 20

RCLK

N P Q N L J MO

LNP M

Transfer

Cell From: 2345 76 8 10 11 12 13 14 15 16 17 189

MJ K

X X XXX

R KJ

OQR

…

XH2 …

X X P1

…

N O P Q R

MOQLNP

P44 P45 P46 P47 P48P43

M K L

H1 H2

DS3181/DS3182/DS3183/DS3184

8.3.5.3 POS-PHY Level 2 Functional Timing

Figure 8-34 shows a multidevice transmit interface in byte transfer mode multiple packet transfer to different PHY

ports. Prior to clock edge 1, the POS device started a packet transfer to PHY port '1'. On clock edge 2, PHY port '1'

deasserts its TDXA to indicate to the POS device that it cannot accept any more data transfers. On clock edge 3,

the POS device stops the packet transfer to PHY port '1', and starts a packet transfer to PHY port '2' by leaving

TEN asserted, placing PHY port '2's address on TADR, placing the first byte of packet data on TDATA, and

asserting TSOX to indicate the transfer of the first byte of the packet. On clock edge 7, PHY port '2' deasserts its

TDXA to indicate to the POS device that it cannot accept any more data transfers. On clock edge 8, the POS

device stops the packet transfer to PHY port '2', and resumes a packet transfer to PHY port '3'. On clock edge 12,

PHY port '2' indicates to the POS device that it can accept a block of packet data by asserting its TDXA. Also, the

POS device indicates it is transferring the last byte of packet data by asserting TEOP. On clock edge 13, the POS

device ends the packet transfer to PHY port '3', and starts a packet transfer to PHY port '4'. On clock edge 15, PHY

port '1' indicates to the POS device that it can accept a block of packet data. On clock edge 17, PHY port '4'

deasserts its TDXA to indicate to the POS device that it cannot accept any more data transfers. On clock edge 18,

the POS device stops the packet transfer to PHY port '4', and resumes a packet transfer to PHY port '1'.

Figure 8-34. Transmit Multiple Packet Transfer to Different PHY ports (direct status

mode)

P36 P37 P38

'1'

TEN

TSOX

TEOP

TERR

TDATA

TCLK

TDXA[1]

TADR

TDXA[2]

TDXA[3]

TDXA[4]

119 202345 76 8 10 11 12 13 14 15 16 17 189

Transfer

To Port

P34 P19 P20 P49P63 P1 P2

…

'3'

P64

'4'

…P50

'1'

P1 P2 P41

…P42

P35

'2'

'1' '2' '3' '4' '1'

Figure 8-35 shows a multidevice receive interface in byte transfer mode multiple packet transfer from different PHY

ports/devices. Prior to clock edge 1, a packet data transfer was initiated from PHY port '1', and PHY ports '2', '3',

and '4' indicated to the POS device that they have a block of packet data or an end of packet ready for transfer by

asserting their RDXA. On clock edge 2, the POS device indicates to PHY port '1' that it cannot accept any more

data transfers by removing its address from RADR, and indicates to PHY port '2' that it is ready to accept a block of

packet data by placing its address on RADR and leaving REN asserted. On clock edge 3, PHY port '1' stops

transferring packet data, and PHY port '2' starts a packet transfer by leaving RVAL asserted, placing the first byte

of the packet on RDATA, and asserting RSOX to indicate that this is the first transfer of the packet. On clock edge

4, PHY port '2' deasserts RSOX as it leaves RVAL asserted and continues to place additional bytes of the packet

on RDATA. On clock edge 8, the POS device deasserts REN to indicate to PHY port '2' that it cannot accept any

more data transfers. On clock edge 9, PHY port '2' ends the packet transfer process by deasserting RVAL and tri-

stating its RVAL, RDATA, RSOX, REOP, and RERR outputs. And, the POS device indicates to PHY port '3' that it

is ready to accept a block of packet data by placing its address on RADR and reasserting REN. On clock edge 10,

PHY port '3' continues a packet transfer by asserting RVAL and placing the next byte of packet data on RDATA.

DS3181/DS3182/DS3183/DS3184

On clock edge 14, PHY port '3' places the last byte of the packet on RDATA, and asserts REOP to indicate that this

is the last transfer of the packet. On clock edge 15, PHY port '3' deasserts RVAL and REOP ending the packet

transfer process, as well as, deasserting RDXA to indicate that it does not have another block of packet data or an

end of packet ready for transfer. On clock edge 16, the POS device indicates to PHY port '4' that it is ready to

accept a block of packet data by placing its address on RADR and leaving REN asserted. On clock edge 17, PHY

port '4' starts a packet transfer by leaving RVAL asserted, placing the first byte of the packet on RDATA, and

asserting RSOX to indicate that this is the first transfer of the packet. On clock edge 18, PHY port '4' deasserts

RSOX as it leaves RVAL asserted and continues to place additional bytes of the packet on RDATA.

Figure 8-35. POS-PHY Level 2 Receive Multiple Packet Transfer from Different PHY

Ports/Devices (direct status mode)

RCLK

RDXA[1]

RADR

RDXA[2]

RDXA[3]

RDXA[4]

119 202345 76 8 10 11 12 13 14 15 16 17 189

RSOX

REOP

RERR

RDATA

Transfer

From PHY

RVAL

REN

P34 P1 P2 P41

…P42

P35

'4'1F '3''1' '2'

…

P19 P20 P2P63 X XP64 P3

'1' '2' '3' '4'

P4P43 P1

Figure 8-36 shows a multidevice transmit interface in packet transfer mode multiple packet transfer to different PHY

ports. On clock edge 2, the POS device polls PHY port 'N'. On clock edge 3, PHY port 'N' indicates to the POS

device that it can accept a block of packet data by asserting TPXA. On clock edge 4, the POS device selects PHY

port 'N'. On clock edge 5, the POS device starts a packet transfer to PHY port 'N' by asserting TEN, placing the first

byte of packet data on TDATA, and asserting TSOX to indicate the transfer of the first byte of the packet. On clock

edge 6, the POS device deasserts TSOX as it continues to place additional bytes of the packet on TDATA. And,

PHY port 'N' drives its TSPA output high. On clock edge 10, the POS device polls PHY port 'M'. On clock edge 11,

the POS device asserts TEOP to indicate the transfer of the last byte of the packet to PHY port 'N' and PHY port

'M' indicates to the POS device that it can accept a block of packet data by asserting TPXA. On clock edge 12, the

POS device deasserts TEN to end the packet transfer process to PHY port 'N' and selects PHY port 'M'. On clock

edge 13, the POS device starts a packet transfer to PHY port 'M' by asserting TEN, placing the first byte of packet

data on TDATA, and asserting TSOX to indicate the transfer of the first byte of the packet. And, PHY port 'N' tri-

states its TSPA output. On clock edge 14, the POS device deasserts TSOX as it continues to place additional

bytes of the packet on TDATA. And, PHY port 'M' drives its TSPA output high.

DS3181/DS3182/DS3183/DS3184

Figure 8-36. POS-PHY Level 2 Transmit Multiple Packet Transfer to Different PHY Ports

(polled status mode)

TCLK

TADR

TPXA

1F 1F N1F 1FO1F M1F M1F N1F O1F P1F LN…

M N NOLM

119 202345 76 8 10 11 12 13 14 15 16 17 189

XP5XX P6 P7 P8

TEN

TSOX

TEOP

TERR

TDAT

Transfer

To PHY

P1 P2 P3 …P62 P63 P64 XP1 P2 P3 P4

M N O P

TSPA

Figure 8-37 shows a multidevice receive interface in packet transfer mode multiple packet transfer. On clock edge

2, the POS device polls PHY port 'N'. On clock edge 3, PHY port 'N' indicates to the POS device that it has a block

of packet data or an end of packet ready for transfer by asserting RPXA. On clock edge 4, the POS device selects

PHY port 'N'. On clock edge 5, the POS device indicates to PHY port 'N' that it is ready to accept a block of packet

data by placing its address on RADR and asserting REN. On clock edge 6, PHY port 'N' starts packet transfer by

asserting RVAL, placing the first byte of the packet on RDATA, and asserting RSOX to indicate that this is the first

transfer of the packet. On clock edge 7, PHY port 'N' deasserts RSOX as it leaves RVAL asserted and continues to

place additional bytes of the packet on RDATA. On clock edge 14, PHY port 'N' places the last byte of the packet

on RDATA, and asserts REOP to indicate that this is the last transfer of the packet. On clock edge 15, PHY port 'N'

deasserts RVAL and REOP ending the packet transfer process. On clock edge 16, the POS device deasserts REN

and selects PHY port 'P'. On clock edge 17, PHY port 'N' tri-states its RVAL, RDATA, RSOX, REOP, and RERR

outputs and the POS device indicates to PHY port 'P' that it is ready to accept a block of packet data by placing its

address on RADR and asserting REN. On clock edge 18, PHY port 'P' starts packet transfer by asserting RVAL,

placing the first byte of the packet on RDATA, and asserting RSOX to indicate that this is the first transfer of the

packet. On clock edge 19, PHY port 'P' deasserts RSOX as it leaves RVAL asserted and continues to place

additional bytes of the packet on RDATA. While this example shows a different PHY port ('P') being selected for the

next packet transfer, the timing is identical if the same PHY port ('N') is chosen for the next packet transfer.

DS3181/DS3182/DS3183/DS3184

Figure 8-37. POS-PHY Level 2 Receive Multiple Packet Transfer (polled status mode)

RCLK

RPXA

RADR

119 202345 768

10 11 12 13 14 15 16 17 189

…

P4 P61 P62 P63

RSOX

REOP

RERR

RDAT

Transfer

From PHY N

RVAL

REN

P2P1

1F 1F N1F 1FO1F 1F M1F O1F P1F L1F MN…

M N NOP LM O P L

P3 P3P64 X X

P2P1

DS3181/DS3182/DS3183/DS3184

8.3.5.4 POS-PHY Level 3 Functional Timing

Figure 8-38 shows a multiport transmit interface multiple packet transfer to different PHY ports. On clock edge 1,

PHY port 'N' indicates to the POS device that it can accept a block of packet data by asserting TPXA. On clock

edge 3, the POS device selects PHY port 'N' by placing its address on TDATA and asserting TSX while TEN is

deasserted. On clock edge 4, the POS device starts a packet transfer to PHY port 'N' by deasserting TSX,

asserting TEN, placing the first byte of packet data on TDATA, and asserting TSOX to indicate the transfer of the

first byte of the packet. On clock edge 5, the POS device deasserts TSOX as it continues to place additional bytes

of the packet on TDATA and PHY port 'N' asserts TSPA. On clock edge 11, the POS device polls PHY port 'L'. On

clock edge 12, PHY port 'N' indicates that it cannot accept any more data transfers by deasserting TSPA. On clock

edge 13, PHY port 'L' indicates to the POS device that it can accept a block of packet data by asserting TPXA. On

clock edge 14, the POS device deasserts TEN to end the packet transfer process to PHY port 'N' and selects PHY

port 'L' by placing its address on TDATA and asserting TSX while TEN is deasserted. On clock edge 15, the POS

device starts a packet transfer to PHY port 'L' by asserting TEN, deasserting TSX, placing the first byte of packet

data on TDATA, and asserting TSOX to indicate the transfer of the first byte of the packet. On clock edge 16, the

POS device deasserts TSOX as it continues to place additional bytes of the packet on TDATA and PHY port 'L'

asserts TSPA.

Figure 8-38. POS-PHY Level 3 Transmit Multiple Packet Transfer In-Band Addressing

M N O LP

P39P38

PMOLN

P40 P41 P42

TCLK

TADR

TPXA

P M N O P L M N OPL

119 202345 76 8 10 11 12 13 14 15 16 17 189

XP5 P6

TEN

TEOP

TERR

TDAT

Transfer

To PHY N

LNPM

TSPA

OPMOLN

P43

TSOX

P44 LP1 P2 P3 P4

TSX

M O …

…

NP1 P2 …

Figure 8-39 shows a multiport receive-interface multiple packet transfer from different ports. On clock edge 1, the

POS device indicates to PHY port 'N' that it is ready to accept a block of packet data by asserting REN. On clock

edge 3, the PHY device selects port 'N' for transfer by asserting RSX and placing its address on RDATA. On clock

edge 4, PHY port 'N' starts packet transfer by deasserting RSX, asserting RVAL, placing the first byte of the packet

on RDATA, and asserting RSOX to indicate that this is the first transfer of the packet. On clock edge 5, PHY port

'N' deasserts RSOX as it leaves RVAL asserted and continues to place additional bytes of the packet on RDATA.

On clock edge 10, PHY port 'N' places the last byte of the packet on RDATA, and asserts REOP to indicate that

this is the last transfer of the packet. On clock edge 11, the PHY device deasserts RVAL and REOP ending the

packet transfer process from port 'N' and selects PHY port 'L' for transfer by asserting RSX and placing its address

on RDATA. On clock edge 12, PHY port 'L' starts packet transfer by deasserting RSX, asserting RVAL, placing the

first byte of the packet on RDATA, and asserting RSOX to indicate that this is the first transfer of the packet. On

clock edge 13, PHY port 'L' deasserts RSOX as it leaves RVAL asserted and continues to place additional bytes of

the packet on RDATA.

DS3181/DS3182/DS3183/DS3184

Figure 8-39. POS-PHY Level 3 Receive Multiple Packet Transfer In-Band Addressing

Transfer

From PHY N L

RCLK

119 202345 76 8 10 11 12 13 14 15 16 17 189

RDAT

RSOX

REOP

RERR

X N P1 P2 …P62 P63 P64 LP9

REN

RVAL

RSX

P1 P2 P3 P4 P5 P6 P7 P8

DS3181/DS3182/DS3183/DS3184

8.3.6 Microprocessor Interface Functional Timing

Figure 8-40 and Figure 8-42 shows examples of a 16-bit databus and an 8-bit databus, respectively. In 16-bit

mode, the A[0]/BSWAP signal controls whether or not to byte swap. In 8-bit mode, the A[0]/BSWAP signal is used

as the LSB of the address bus (A[0]). The selection of databus size is determined by the WIDTH input signal. See

also Section 10.1.1.

Figure 8-40. 16-Bit Mode Write

0x1234

0x2B0

D[15:0]

A[10:1]

A[0]/BSWAP

RDY Z

Note: Address 0x2B0 = 0x1234

Figure 8-41. 16-Bit Mode Read

D[15:0]

A[10:1]

A[0]/BSWAP

0x2B0

0x1234

Note: Address 0x2B0 = 0x1234

RDY

DS3181/DS3182/DS3183/DS3184

Figure 8-42. 8-Bit Mode Write

0x34 0x12

0x2B0 0x2B0

D[7:0]

A[10:1]

A[0]/BSWAP

Note: Address 0x2B0 = 0x34

0x2B1 = 012

RDY

Figure 8-43. 8-Bit Mode Read

D[7:0]

A[10:1]

A[0]/BSWAP

0x2B0

0x34

0x2B0

0x12

Note: Address 0x2B0 = 0x34

0x2B1 = 012

RDY

Figure 8-44 and Figure 8-45 are examples of databuses without and with byte swapping enabled, respectively.

When the A[0]/BSWAP pin is set to 0, byte swapping is disabled, and when one, byte swapping is enabled. This

pin should be static and not change while operating. Note: Address bit A[0] is not used in 16-bit mode. See also

Section 10.1.2.

DS3181/DS3182/DS3183/DS3184

Figure 8-44. 16-Bit Mode without Byte Swap

0x1234 0x5678

Note: Address 0x2B0 = 0x1234

0x2B2 = 0x5678

0x2B0 0x2B2

D[15:0]

A[10:1]

A[0]/BSWAP

RDY

Figure 8-45. 16-Bit Mode with Byte Swap

0x3412 0x7856

Note: Address 0x2B0 = 0x1234

0x2B2 = 0x5678

0x2B0 0x2B2

D[15:0]

A[10:1]

A[0]/BSWAP

RDY

Clearing status latched registers on a read or write access is selectable via the GL.CR1.LSBCRE register bit.

Clearing on read clears all bits in the register, while the clear on write clears only those bits which are written with a

‘1’ when the user writes to the status latched register.

To use the Clear on Read method, the user must only read the status latched register. All bits are set to zero after

the read. Figure 8-46 shows a read of a status latched register and another read of the same register verifying the

To use the Clear on Write method, the user must write the register with ones in the bit locations that he desires to

clear. Figure 8-47 shows a read, a write, and then a subsequent read revealing the results of clearing of the bits

that he wrote a ‘1’. See also Section 10.1.5

DS3181/DS3182/DS3183/DS3184

Figure 8-46. Clear Status Latched Register on Read

D[15:0]

A[10:1]

A[0]/BSWAP

0x1C0

0xFFFF

0x1C0

0x0000

RDY

Figure 8-47. Clear Status Latched Register on Write

D[15:0]

A[10:1]

A[0]/BSWAP

0x1C0

0xFFFF

0x1C0

0x5555

0x1C0

0xAAAA

RDY

Figure 8-48 and Figure 8-49 show exaggerated views of the Ready Signal to describe the difference in access

times to write or read to or from various memory locations on the DS318x device. Some registers will have a faster

access time than others will and if needed, the user can implement the RDY signal to maximize efficiency of read

and write accesses.

Figure 8-48. RDY Signal Functional Timing Writes

0x1234 0x0078

0x2B0 0x3A4

D[15:0]

A[10:1]

A[0]/BSWAP

RDY

DS3181/DS3182/DS3183/DS3184

Figure 8-49. RDY Signal Functional Timing Read

D[15:0]

A[10:1]

A[0]/BSWAP

0x1C0

0xFFFF

0x3A4

0xFFFF

RDY

See also Figure 18-7 and Figure 18-8.

8.3.7 JTAG Functional Timing

See Section 13.5.

DS3181/DS3182/DS3183/DS3184

9 INITIALIZATION AND CONFIGURATION

STEP 1: Check Device ID Code.

Before any testing can be done, the device ID code, which is stored in GL.IDR, should be checked against device

ID codes shown below to ensure that the correct device is being used.

Current device ID codes are:

o DS3181 rev 1.0: 0048h

o DS3182 rev 1.0: 0049h

o DS3183 rev 1.0: 004Ah

o DS3184 rev 1.0: 004Bh

STEP 2: Initialize the Device.

Before configuring for operation, make sure the device is in a known condition with all registers set to their default

value by initiating a Global Reset. (See Section 10.3) A Global Reset can be initiated via the RST pin or by the

Global Reset bit (GL.CR1.RST). A Port Reset is not necessary since the global reset includes a reset of all ports to

their default values.

STEP 3: Clear the Reset.

It is necessary to clear the RST bit to begin normal operation.

After clearing the RST bit, the device is configured for default mode.

Default mode:

System Interface: UTOPIA Level 2, 8-bit databus

Framer: C-bit DS3

LIU: Disabled

STEP 4: Clear the Data Path Resets and the Port Power-Down bit.

The default value of the Data Path Resets is one, which keeps the internal logic in the reset status. The user needs

to clear the following bits:

GL.CR1.RSTDP = 0

PORT.CR1.RSTDP = 0

PORT.CR1.PD = 0

STEP 5: Configure the CLAD.

If using the LIU, configure the CLAD (the Clock Rate Adapter, which supplies the clock to the Receive LIU)

via the CLAD bits in

the GL.CR2 register.

Note: The user must supply a DS3, E3, or STS-1 clock to the CLKA pin.

STEP 6: Select the clock source for the transmitter.

Loop Time (use the receive clock): Set PORT.CR3.LOOPT = 1

CLAD Source: Set PORT.CR3.CLADC = 0

TCLKI Source: Set PORT.CR3.CLADC = 1

If using the CLAD, properly configure the CLAD by setting the CLAD bits in GL.CR2.

STEP 7: Configure the Framing Mode and the Line Mode.

PORT.CR2.LM[2:0] = 011 -LIU on, JA in RX side-or another setting. See Table 10-33.

PORT.CR2.FM[5:0] set to the correct framing mode. See Table 10-32.

STEP 8: Disable Payload AIS (downstream AIS) and Line AIS

PORT.CR1.PAIS[2:0] = 111

PORT.CR1.LAIS[1:0] = 11

STEP 9: Initialize and configure the FIFOs.

Reset the Transmit and Receive FIFO.

FF.TCR.TFRST = 1.

DS3181/DS3182/DS3183/DS3184

FF.RCR.RFRST = 1.

Clear the FIFO Reset bits.

FF.TCR.TFRST = 0.

FF.RCR.RFRST = 0.

Set the FIFO Transmit Level Control Register and the FIFO Transmit Port Address Control Register.

Set the FIFO Receive Level Control Register and the FIFO Receive Port Address Control Register.

The Port Address needs to be configured to match the master controller address for each port.

STEP 10: Configure the System Bus

Configure for bus size and for interface type. See Table 9-1.

Optionally, set the System Interface Transmit Control Register, System Interface Receive Control Register

#1 and #2 to fine tune for the specific application.

(User may leave registers at default value.)

STEP 11: Configure the Cell or Packet Processor

For cell mode, the default is to send the cell across the system interface without the HEC. Also, default

mode scrambles the cell data to the line.

To attach the HEC to the cell, set SI.TCR.THECT = 1 and SI.RCR.RHECT = 1.

STEP 12: Enable each port (for non-LIU modes)

PORT.CR2.TLEN = 1

Table 9-1. Configuration of Global Register Settings

Note: This table assumes a DS3 clock input on the CLKA pin.

MODE GL.CR1

0x002

GL.CR20x00

GL.GIOCR

0x00A

UTOPIA L2 0000 XX00 0000 0000 0x0204 0x0000

UTOPIA L3 0000 XX01 0000 0000 0x0204 0x0000

POS-PHY L2 0000 XX10 0000 0000 0x0204 0x0000

POS-PHY L3 or SPI-3 0000 XX11 0000 0000 0x0204 0x0000

8-Bit System Bus 0000 00XX 0000 0000 0x0204 0x0000

16-Bit System Bus 0000 01XX 0000 0000 0x0204 0x0000

32-Bit System Bus 0000 10XX 0000 0000 0x0204 0x0000

Table 9-2. Configuration of Port Register Settings

Note: The Line Mode has been configured with the LIU enabled and the JA in the receive path (LM[2:0] = 011) for all modes except OHM mode.

Only Port 1 registers have been displayed.

MODE PORT.CR1

0x040

PORT.CR2

0x042

PORT.CR3

0x044

PORT.CR4

0x046

DS3 C-Bit 0x7C00 0000 0011 0000 000X 0x0000 0x0000

DS3 C-Bit PLCP 0x7C00 0000 0011 0000 010X 0x0000 0x0000

DS3 M23 0x7C00 0000 0011 0000 100X 0x0000 0x0000

DS3 M23 PLCP 0x7C00 0000 0011 0000 110X 0x0000 0x0000

E3.751 0x7C00 0000 0011 0001 000X 0x0000 0x0000

E3.751 PLCP 0x7C00 0000 0011 0001 010X 0x0000 0x0000

E3.823 0x7C00 0000 0011 0001 100X 0x0000 0x0000

OHM Mode (DS3/E3/Clear

Channel) 0x7C00 1100 0XXX 00XX XXXX 0x0000 0x0000

DS3181/DS3182/DS3183/DS3184

Considerations

Select the HDLC Controller connection. The default setting connects it to the DS3/E3 Framers. Setting

PORT.CR1.HDSEL = 1 connects the HDLC Controller to the PLCP framers.

In POS-PHY mode, to select cell processing rather than packet processing, set PORT.CR2.PMCPE = 1.

For best performance of the CLAD to meet jitter requirements across the temperature range, especially @ -40 C,

the following test registers should be set after reset:

Address 0x20B = 0x11

Address 0x20F = 0x11

9.1 Monitoring and Debugging

To determine if the device is receiving a good signal and that the chip is correctly configured for its environment,

check the following status registers.

Receive Loss of Lock – PORT.SR.RLOL – The clock recovery circuit of the LIU was unable to recover the clock

from the incoming signal. This may indicate that the LIU’s master clock does not match the frequency of the

incoming signal. Verify that the CLAD is configured to match the clock input on the CLKA, CLKB, and CLKC pins

(DS3, E3, STS-1). See Table 10-11.

Loss of Signal – LINE.RSR.LOS – This indicates that the LIU is unable to recover the clock and data because there

is no signal on the line, or that the signal is attenuated beyond recovery.

Loss of Frame – T3.RSR1.LOF (or E3751.RSR1 or E3832.RSR1) – This indicates that the framer was unable to

synchronize to the incoming data. Verify that the FM bits have been correctly configured for the correct mode of

traffic (DS3, E3 G.751, E3 G.832)

Other helpful techniques diagnose a problem include using Line Loopback and Diagnostic Loopback. These

features help to isolate and identify the source of the problem. Line Loopback will loop the receive input to the

transmit output, eliminating the transmit side input from the equation. Diagnostic Loopback will loop the transmit

output before the LIU to the receive framer, eliminating the analog Receive LIU and the receive side analog

circuitry.

One other potential problem is the Line Encoding/Decoding. The device needs to be configured in the same mode

as the far end piece of equipment. If the far end piece of equipment is transmitting and receiving HDB3/B3ZS

encoded data, the DS318x also must be configured to do the same. This is controlled by the LINE.TCR.TZSD and

the LINE.RCR.RZSD bits.

9.1.1 Cell/Packet FIFO

Check the status registers of the FIFO block. Common indicators to check would be the Transmit Underflow,

Transmit Overflow, and Receive Overflow status bits. These status bits are located in the FIFO.TSRL Register and

the FIFO.RSRL Register.

A Transmit Underflow indicates that the transmit cell processor or packet processor has attempted a read while

the FIFO was empty.

A Transmit Overflow indicates that either a start of cell or a start of packet or a short packet was received when the

FIFO was full. Additionally, if additional packet data is received when the FIFO is already full, it will result in an

abort status for the current packet and the Transmit Overflow being declared.

A Receive Overflow occurs when cell data is received while the FIFO is full. In a packet system, the overflow will be

declared when a start of packet or a short packet is received or packet data is received when the FIFO is full

resulting in an abort status for the current packet and the Receive Overflow being declared.

9.1.2 Cell Processor

Monitoring the Loss of Cell Delineation in the Cell Processor is recommended to insure proper operation. The LCD

status bit is located in the CP.RSR Register and indicates when an Out of Cell Delineation persists for a

programmed number of cells (set in the CP.RLTC Register).

DS3181/DS3182/DS3183/DS3184

9.1.3 Packet Processor

Monitoring the number of errored packets in the Packet Processor is recommended for proper operation. The

REPC status bit is located in the PP.RSR Register and indicates when the errored packet count is not zero. An

errored packet is detected when an errored FCS is detected. To determine how many errored packets have been

received, the FCS Errored Packet Count Registers must first be updated via the PMU signal.

DS3181/DS3182/DS3183/DS3184

10 FUNCTIONAL DESCRIPTION

10.1 Processor Bus Interface

10.1.1 8/16-Bit Bus Widths

The external processor bus can be sized for 8 or 16 bits using the WIDTH pin. When in 8-bit mode (WIDTH=0), the

address is composed of all the address bits including A[0], the lower 8 data lines D[7:0] are used and the upper 8

data lines D[15:8] are not used and never driven during a read cycle. When in 16-bit mode (WIDTH=1), the

address bus does not include A[0] (the LSB of the address bus is not routed to the chip) and all 16 data lines

D[15:0] are used. See Figure 8-40 and Figure 8-42 for functional timing diagrams.

10.1.2 Ready Signal (RDY)

The RDY signal allows the microprocessor to use the minimum bus cycle period for maximum efficiency. When this

signal goes low, the RD or WR cycle can be terminated. See Figure 8-48 for functional timing diagrams.

NOTE: The RDY signal will not go active if the user attempts to read or write unused ports or unused registers not

assigned to any design blocks. The RDY signal will go active if the user writes or reads reserved registers or

unused registers within design blocks.

10.1.3 Byte Swap Modes

The processor interface can operate in byte swap mode when the data bus is configured for 16-bit operation. The

A[0]/BSWAP pin is used to determine whether byte swapping is enabled. This pin should be static and not change

while operating. When the A[0]/BSWAP pin is low the upper register bits REG[15:8] are mapped to the upper

external data bus lines D[15:8], and the lower register bits REG[7:0] are mapped to the lower external data bus

lines D[7:0]. When the A[0]/BSWAP pin is high the upper register bits REG[15:8] are mapped to the lower external

data bus lines D[7:0], and the lower register bits REG[7:0] are mapped to the upper external data bus lines D[15:8].

See Figure 8-44 and Figure 8-45 for functional timing diagrams.

10.1.4 Read-Write/Data Strobe Modes

The processor interface can operate in either read-write strobe mode or data strobe mode. When MODE=0 the

read-write strobe mode is enabled and a negative pulse on RD performs a read cycle, and a negative pulse on WR

performs a write cycle. When MODE=1 the data strobe mode is enabled and a negative pulse on DS when R/W is

high performs a read cycle, and a negative pulse on DS when R/W is low performs a write cycle. The read-write

strobe mode is commonly called the “Intel” mode, and the data strobe mode is commonly called the “Motorola”

mode.

10.1.5 Clear on Read/Clear on Write Modes

The latched status register bits can be programmed to clear on a read access or clear on a write access. The

global control register bit GL.CR1.LSBCRE controls the mode that all of the latched registers are cleared. When

LSBCRE=0, the latched register bits will be cleared when the register is written to and the write data has the

read.

The clear on write mode expects the user to use the following protocol:

1. Read the latched status register

2. Write to the registers with the bits set that need to be cleared.

This protocol is useful when multiple uncoordinated software tasks access the same latched register. Each task

should only clear the bits with which it is concerned; the other tasks will clear the bits with which they are

concerned.

The clear on read mode is simpler since the bits that were read as being set will be cleared automatically. This

method will work well in a software system where multiple tasks do not read the same latched status register. The

DS3181/DS3182/DS3183/DS3184

latched status register bits in clear on read mode are carefully designed not to miss events that occur while a

10.1.6 Global Write Method

All of the ports can be written to simultaneously using the global write method. This method is enabled by setting

the GL.CR1.GWM bit. When the global write method is enabled, a write to a register on any valid port will write to

the same register on all valid ports. A valid port is a port that is available in a particular packaged part. For

example, port four would not be valid in a DS3183 device. After reset, the global write method is not enabled.

When the GWM bit is set, read data from the port registers is not valid and read data from the global and test

registers is valid. The data value read back from a port register should be ignored.

10.1.7 Interrupt and Pin Modes

The interrupt (INT) pin is configurable to drive high or float when not active. The GL.CR1.INTM bit controls the pin

configuration, when it is set the INT pin will drive high when not active. After reset, the INT pin will be in high

impedance mode until an interrupt source is active and enabled to drive the interrupt pin.

10.1.8 Interrupt Structure

The interrupt structure is designed to efficiently guide the user to the source of an enabled interrupt source. The

status bits in the global status (GL.SR) and global status latched register (GL.SRL) are read to determine if the

interrupt source is a global event like the UTOPIA/POS-PHY interface, global performance monitor update or

whether it came from one of the ports. If the interrupt event came from one of the ports then the port status register

(PORT.SR) and port status register latched (PORT.SRL) can be read to determine if the interrupt source is a

common port event like the performance monitor update or LIU or whether it came from one of the DS3/E3

Framers, PLCP Framer, ATM/PKT, BERT, HDLC, FEAC or Trail Trace status registers. If the interrupt came from

one of the DS3/E3 Framers, PLCP Framer, ATM/PKT, BERT, HDLC, FEAC or Trail Trace status registers, then

one of those registers will need to be read to determine the event that caused the interrupt.

The source of an interrupt can be determined by reading three status registers: global, port and block status

registers.

When a mode is not enabled, then interrupts from that source will not occur. For example, if PLCP framing is not

enabled then the potential interrupts from the latched status register in the PLCP block cannot occur. Similarly, if

E3 framing mode is enabled, an interrupt source that is defined in DS3 framing, but not in E3 framing, cannot

create a new interrupt. Note that when modes are changed, the latched status bits of the new mode, as well as any

other mode, may get set. If the data path reset is set during or after the mode change, the latched status bits will be

automatically cleared. If the data path reset is not used to clear the latched status bits, then the registers must be

cleared by reading or writing to them based on the register clear method selected.

DS3181/DS3182/DS3183/DS3184

Figure 10-1. Interrupt Structure

GL.ISR.PISRn

PORT.ISR bit

SRL bit

SRIE bit

BLOCK LATCHED

STATUS and

INTERRUPT

ENABLE

REGISTERS

PORT INTERRUPT

STATUS

GLOBAL

INTERRUPT

STATUS REGISTER

and INTERRUPT

ENABLE REGISTER

GL.ISRIE.

PISRIEn INT

PORT

INTERRUPTS

TRANSMIT SYSTEM

INTERFACE INTERRUPTS

GLOBAL

INTERRUPTS

Figure 10-1 not only tells the user how to determine which event caused the interrupt, it also tells the user how to

enable a particular interrupt. Each block has a Status Register Interrupt Enable register that must be set in order to

enable an interrupt. The next step is to unmask the interrupt at the port level, on a per-port basis. This is controlled

in the Global Interrupt Status Register Interrupt Enable register (GL.ISRIE). Now the device is ready to drive the

INT pin low when a particular status bit gets set.

For example, in order to enable DS3 Out of Frame interrupts on Port 2, the following registers would need to be

written:

T3.RSRIE1.OOFIE 0x32C 0x0002 Unmask OOF interrupt on Port 2

GL.ISRIE.PISRIE2 0x012 0x0020 Unmask Port 2 interrupts

The following status registers bits will be set upon reception of OOF on Port 2:

T3.RSRL1.OOFL 0x328 0x0002 DS3 Out of Frame on Port 2

PORT.ISR.FMSR 0x250 0x0001 Framer Block Interrupt Active, Port 2

GL.ISR.PISR2 0x010 0x0020 Port 2 Interrupt Active

DS3181/DS3182/DS3183/DS3184

10.2 Clocks

10.2.1 Line Clock Modes

The system loopback (SLB) function does not affect the line clocks in any way.

10.2.1.1 Loop Timing Enabled

When loop timing is enabled (PORT.CR3.LOOPT), the transmit clock source is the same as the receive clock

source. The TCLKIn pins are not used as a clock source. Because loop timing is enabled, the loopback functions

(LLB, PLB and DLB) do not cause the clock sources to switch when they are activated. The transmit and receive

signal pins can be timed to a single clock reference without concern about having the clock source change during

loopbacks.

10.2.1.1.1 LIU Enabled, Loop Timing Enabled

In this mode, the receive LIU sources the clock for both the receive and transmit logic. The RCLKOn, TCLKOn and

TLCLKn clock output pins will be the same. The transmit or receive line, payload and fractional signal pins can be

timed to any of these clock. The use of the RCLKOn pin as the timing source is suggested. If RCLKOn is used as

the timing source, be sure to set PORT.CR3.RFTS = 0 for output timing.

10.2.1.1.2 LIU Disabled, Loop Timing Enabled

In this mode, the RLCLKn pins are the source of the clock for both the receive and transmit logic. The RCLKOn,

TCLKOn and TLCLKn clock output pins will both be the same as the RLCLKn clock. The transmit or receive line,

payload and fractional signals can be timed to any of these clock pins. The use of the RLCLKn pin as the timing

source is suggested. If RLCLKn is used as the timing source, be sure to set PORT.CR3.RFTS = 1 for input timing.

10.2.1.2 Loop Timing Disabled

When loop timing is disabled, the transmit clock source can be different than the receive clock source. The

loopback functions, LLB, PLB and DLB, will cause the clock sources to switch when they are activated. Care must

be taken when selecting the clock reference for the transmit and receive signals.

The most versatile clocking option has the receive line interface signals timed to RLCLKn, the transmit line

interface signals timed to TLCLKn, the receive framer and fractional signals timed to RCLKOn, and the transmit

framer and fractional signals timed to TCLKOn. This clocking arrangement works in all modes.

When LLB is enabled, the clock on the TLCLKn pins will switch to the clock from the RLCLKn pins or RX LIU. It is

recommended that the transmit line interface signals be timed to the TLCLKn pins. If TLCLKn is used as the timing

source, be sure to set PORT.CR3.TLTS = 0 for output timing.

When PLB is enabled, the TCLKIn pin will not be used and the internal transmit clock is switched to the internal

receive clock. The clock on the TCLKOn pins will switch to the clock from the RLCLKn pins or RX LIU. The framer

or fractional input signals will be ignored while PLB is enabled. It is recommended that the transmit line interface

signals be timed to the TCLKOn pins.

When DLB is enabled, the internal receive clock is switched to the internal transmit clock which is sourced from the

TCLKIn pins or one of the CLAD clocks, and the clock on the RLCLKn pins or from the RX LIU will not be used.

The clock on the RCLKOn pins will switch to the clock on the TCLKIn pins or one of the CLAD clocks. The receive

line signals from the RX LIU or line interface pins will be ignored. It is recommended that the receive framer and

fractional pins be timed to the RCLKOn pins. If TCLKOn is used as the timing source, be sure to set

PORT.CR3.TFTS = 0 for output timing.

When both DLB and LLB are enabled, the TLCLKn clock pins are connected to either the RX LIU recovered clock

or the RLCLKn clock pins, and the RCLKOn clock pins will be connected to the TCLKIn clock pins or one of the

CLAD clocks. It is recommended that the transmit line signals be timed to the TLCLKn pins, the receive line

interface signals be timed to the RLCLKn pins, the receive framer and fractional signals be timed to the RCLKOn

pins, and the transmit framer and fractional signals be timed to the TCLKOn pins.

10.2.1.2.1 LIU Enabled - CLAD Timing Disabled – no LB

In this mode, the receive LIU sources the clock for the receive logic and the TCLKIn pins source the clock for the

transmit logic.

DS3181/DS3182/DS3183/DS3184

100

10.2.1.2.2 LIU Enabled - CLAD Timing Enabled – no LB

In this mode, the receive LIU sources the clock for the receive logic and one of the CLAD clocks sources the clock

for the transmit logic.

10.2.1.2.3 LIU Disabled - CLAD Timing Disabled – no LB

In this mode, the RLCLKn pins source the clock for the receive logic and the TCLKIn pins source the clock for the

transmit logic.

10.2.1.2.4 LIU Disabled - CLAD Timing Enabled – no LB

In this mode, the RLCLKn pins source the clock for the receive logic and one of the CLAD clocks sources the clock

for the transmit logic.

10.2.2 Sources of Clock Output Pin Signals

The clock output pins can be sourced from many clock sources. The clock sources are the transmit input clocks

pins (TCLKIn), the receive clock input pins (RLCLKn), the recovered clock in the receive LIUs, and the clock

signals in the clock rate adapter circuit (CLAD). The default clock source for the receive logic is the RLCLKn pin if

the LIU is disabled; otherwise the default clock is sourced from the RX LIU clock when the RX LIU is enabled. The

default clock source for the transmit logic is the CLAD clocks.

The LIU is enabled based on the line mode bits (LM[2:0]) (See Table 10-33). The bits LM[2:0], LBM[2:0], LOOPT

and CLADC are located in the port configuration registers. LIUEN is not a register bit; it is a variable based on the

line mode bits. LIUEN is also zero (LIU disabled) when an “-OHM” mode is selected. Table 10-1 decodes the LM

bits for LIUEN selection.

Table 10-1. LIU Enable Table

LM[2:0] LIUEN LIU

STATUS

000 0 Disabled

001 1 Enabled

010 1 Enabled

011 1 Enabled

1XX 0 Disabled

Table 10-2 identifies the framer clock source and the line clock source depending on the mode that the device is

configured. Putting the device in loopback will typically mux in a different clock than the normal clock source.

Table 10-2. All Possible Clock Sources Based on Mode and Loopback

MODE LOOPBACK

RX FRAMER

CLOCK

SOURCE

TX FRAMER

CLOCK

SOURCE

TX LINE

CLOCK

SOURCE

Loop Timed Any RLCLKn or

RXLIU Same as RX Same as RX

Normal None

RLCLKn or

RXLIU

TCLKIn or

CLAD Same as TX

Normal LLB

RLCLKn or

RXLIU

TCLKIn or

CLAD Same as RX

Normal PLB

RLCLKn or

RXLIU Same as RX Same as RX

Normal DLB Same as TX TCLKIn or

CLAD Same as TX

Normal LLB and DLB Same as TX TCLKIn or

CLAD

RLCLKn or

RXLIUn

DS3181/DS3182/DS3183/DS3184

101

Table 10-3 identifies the source of the output signal TLCLKn based on certain variables and register bits.

Table 10-3. Source Selection of TLCLK Clock Signal

SIGNAL LOOPT

PORT.CR3

LBM[2:0]

(PORT.CR4)

LLB OR

PLB? LIUEN CLADC

(PORT.CR3) SOURCE

1 XXX NA 1 X RX LIU

1 XXX NA 0 X RLCLKn

0 010 LLB 1 X RX LIU

0 110 LLB 1 X RX LIU

0 010 LLB 0 X RLCLKn

0 110 LLB 0 X RLCLKn

0 011 PLB 1 X RX LIU

0 011 PLB 0 X RLCLKn

0 000 NO X 0 CLAD

0 001 NO X 0 CLAD

0 100 NO X 0 CLAD

0 10X NO X 0 CLAD

0 111 NO X 0 CLAD

0 000 NO X 1 TCLKIn

0 001 NO X 1 TCLKIn

0 100 NO X 1 TCLKIn

0 10X NO X 1 TCLKIn

TLCLKn

0 111 NO X 1 TCLKIn

Figure 10-2 shows the source of the TCLKOn signals.

Figure 10-2. Internal TX Clock

CLAD

TCLKI

PORT.CR3.

CLADC

RCLKO

PAYLOAD

LOOPBACK

TCLKO

Table 10-4 identifies the source of the output signal TCLKOn based on certain variables and register bits.

DS3181/DS3182/DS3183/DS3184

102

Table 10-4. Source Selection of TCLKOn (internal TX clock)

SIGNAL LOOPT

PORT.CR3

LBM[2:0]

(PORT.CR4) LIUEN CLADC

(PORT.CR3) SOURCE

1 XXX 1 X RX LIU

1 XXX 0 X RLCLKn

0 PLB (011) 1 X RX LIU

0 PLB (011) 0 X RLCLKn

0 PLB disabled X 0 CLAD

TCLKOn

0 PLB disabled X 1 TCLKIn

Figure 10-3 shows the source of the RCLKOn signals.

Figure 10-3. Internal RX Clock

Rx LIU CLOCK

RLCLK

LIUEN

TCLKO

DIAGNOSTIC

LOOPBACK

RCLKO

Table 10-5 identifies the source of the output signal RCLKOn based on certain variables and register bits.

Table 10-5. Source Selection of RCLKO Clock Signal (internal RX clock)

SIGNAL LOOPT

PORT.CR3

LBM[2:0]

(PORT.CR4) LIUEN CLADC

(PORT.CR3) SOURCE

1 XXX 1 X RX LIU

1 XXX 0 X RLCLKn

0 DLB disabled 1 X RX LIU

0 DLB disabled and

ALB disabled 0 X RLCLKn

0 DLB (1XX) X 0 CLAD

0 DLB (1XX) or ALB

(001) 0 1 TCLKIn

RCLKOn

0 DLB (1XX) 1 1 TCLKIn

DS3181/DS3182/DS3183/DS3184

103

10.2.3 Line IO Pin Timing Source Selection

The line IO pins can use any input clock pin (RLCLKn or TCLKIn) or output clock pin (TLCLKn, RCLKOn, or

TCLKOn) for its clock pin and meet the AC timing specifications as long as the clock signal is valid for the mode the

part is in. The clock select bit for the transmit line IO signal group PORT.CR3.TLTS selects the correct input or

output clock timing.

10.2.3.1 Transmit Line Interface Pins Timing Source Selection

(TPOSn/TDATn, TNEGn/TOHMOn)

The transmit line interface signal pin group has the same functional timing clock source as the TLCLKn pin

described in Table 10-3. Other clock pins can be used for the external timing. The TLCLKn transmit line clock

output pin is always a valid output clock for external logic to use for these signals when PORT.CR3.TLTS=0.

The transmit line timing select bit (TLTS) is used to select input or output clock pin timing. When TLTS=0, output

clock timing is selected. When TLTS=1, input clock timing is selected. If TLTS is set for input clock timing and an

output clock pin is used, or if TLTS is set for output clock timing and an input clock pin is used, then the setup, hold

and delay timings, as specified in Table 18-1, will not be valid. There are some combinations of TLTS=1 and other

modes in which there is no input clock pin available for external timing since the clock source is derived internally

from the RX LIU or the CLAD.

Table 10-6. Transmit Line Interface Signal Pin Valid Timing Source Select

LOOPT

LBM[2:0]

LIUEN

CLADC

TLTS

VALID TIMING TO THESE CLOCK PINS

1 XXX X X 0 TLCLKn, TCLKOn, RCLKOn

1 XXX 0 X 1 RLCLKn

1 XXX 1 X 1 No valid timing to any input clock pin

0 DLB (100) X X 0 TLCLKn, TCLKOn, RCLKOn

0 LLB (010) or PLB (011) X X 0 TLCLKn, RCLKOn

0 DLB&LLB (110) X X 0 TLCLKn

not DLB (100),

not LLB (010), not PLB (011)

and not LLB&DLB (110)

X X 0 TLCLKn, TCLKOn (default)

0 not LLB (010) and not PLB (011)

and not LLB&DLB (110) X 0 1 No valid timing to any input clock pin

0 not LLB (010) and not PLB (011)

and not LLB&DLB (110) X 1 1 TCLKIn

0 LLB (010) or PLB (011)

or DLB&LLB (110) 0 X 1 RLCLKn

0 LLB (010) or PLB (011)

or DLB&LLB (110) 1 X 1 No valid timing to any input clock pin

10.2.3.2 Transmit Framer and Fractional Pin Timing Source Selection

(TFOHn/TSERn, TFOHENIn/TPDENIn, TOHMIn/TSOFIn, TSOFOn/TDENn/TFOHENOn, TPDATn, TPDENOn)

The transmit framer and fractional signal pin group has the same functional timing clock source as the TCLKO pin

described in Table 10-4. Other clock pins can be used for the external timing. The TCLKO transmit clock output pin

is always a valid output clock for external logic to use for these signals when TFTS=0.

The transmit framer and fractional timing select bit (TFTS) is used to select input or output clock pin timing. When

TFTS=0, output clock timing is selected. When TFTS=1, input clock timing is selected. If TFTS is set for input clock

timing and an output clock pin is used, or If TFTS is set for output clock timing and an input clock pin is used, then

the setup, hold and delay timings, as specified in Table 18-1, will not be valid. There are some combinations of

TFTS=1 and other modes in which there is no input clock pin available for external timing since the clock source is

derived internally from the RX LIU or the CLAD.

DS3181/DS3182/DS3183/DS3184

104

Table 10-7. Transmit Framer Pin Signal Timing Source Select

LOOPT LBM[2:0] LIUEN CLADC TFTS

VALID TIMING TO THESE

CLOCK PINS

1 XXX X X 0 TCLKOn, TLCLKn, RCLKOn

1 XXX 0 X 1 RLCLKn

1 XXX 1 X 1

No valid timing to any input

clock pin

0 PLB (011) or DLB (100) or

ALB (001) 0 X 0 TCLKOn, TLCLKn, RCLKOn

0 PLB (011) or DLB (100) 1 X 0 TCLKOn, TLCLKn, RCLKOn

0 DLB&LLB (110) X X 0 TCLKOn, RCLKOn

0 LLB (010) X X 0 TCLKOn

0 not LLB, DLB or PLB (00X) X X 0 TCLKOn, TLCLKn

0 not PLB (011) X 0 1 No valid timing to any input

clock pin

0 not PLB (011) X 1 1 TCLKIn

0 PLB (011) 0 X 1 RLCLKn

0 PLB (011) 1 X 1

No valid timing to any input

clock pin

10.2.3.3 Receive Line Interface Pin Timing Source Selection

(RPOSn/RDATn, RNEGn/RLCVn/ROHMIn)

The receive line interface signal pin group must clocked in with the RLCLK clock input pin. When the LIU is

enabled, the receive line interface pins are not used so there is no valid clock reference.

Table 10-8. Receive Line Interface Pin Signal Timing Source Select

LOOPT LBM[2:0] LIUEN CLADC

VALID TIMING TO THESE

CLOCK PINS

X XXX 0 X RLCLKn

X XXX 1 X No valid timing to any clock pin

10.2.3.4 Receiver Framer and Fractional Pin Timing Source Selection

(RSERn, RSOFOn/RDENn/RFOHENOn, RFOHENIn/RPDENIn, RPDATn)

The receive framer and fractional signal pin group has the same functional timing clock source as the RCLKOn pin

described in Table 10-5.

Other clock pins can be used for the external timing. The RCLKOn receive clock output pin is always a valid output

clock for external logic to use for these signals when PORT.CR3.RFTS=0.

The receive framer and fractional timing select bit (RFTS) is used to select input or output clock pin timing. When

RFTS=0, output clock timing is selected. When RFTS=1, input clock timing is selected. If RFTS is set for input

clock timing and an output clock pin is used, or If RFTS is set for output clock timing and an input clock pin is used,

then the setup, hold and delay timings, as specified in Table 18-1, will not be valid. There are some combinations

of RFTS=1 and other modes in which there is no input clock pin available for external timing since the clock source

is derived internally from the RX LIU or the CLAD.

DS3181/DS3182/DS3183/DS3184

105

Table 10-9. Receive Framer Pin Signal Timing Source Select

LOOPT LBM[2:0] LIUEN CLADC RFTS

VALID TIMING TO THESE

CLOCK PINS

1 XXX X X 0 RCLKOn, TLCLKn, TCLKOn

1 XXX 0 X 1 RLCLKn

1 XXX 1 X 1

No valid timing to any input clock

0 PLB (011) or DLB (100) or

ALB (001) 0 X 0 RCLKOn, TLCLKn, TCLKOn

0 PLB (011) or DLB (100) 1 X 0 RCLKOn, TLCLKn, TCLKOn

0 DLB&LLB (110) X X 0 RCLKOn, TCLKOn

0 LLB (010) X X 0 RCLKOn, TLCLKn

0 not LLB, DLB or PLB (00X) X X 0 RCLKOn

0 DLB (100) or LLB&DLB(110) X 0 1 No valid timing to any input clock

0 DLB (100) or LLB&DLB(110) X 1 1 TCLKIn

0 not DLB (100) and

not LLB&DLB(110) 0 X 1 RLCLKn

0 not DLB (100) and

not LLB&DLB(110) 1 X 1

No valid timing to any input clock

10.2.4 Clock Structures On Signal IO Pins

The signals on the input pins (RFOHENIn, TOHMIn/TSOFIn, TFOHn/TSERn, TFOHENIn) can be used with any of

the clock pins for setup/hold timing on clock input and output pins. There will be a flop at each input whose clock is

connected to the signal from the input or output clock source pins with as little delay as possible from the signal on

the clock IO pins. This means using the input clock signal before the delays of the internal clock tree to clock the

input signals, and using the output clock signals used to drive the output clock pins to clock the input signals.

The signals on the output pins (TPOSn/TDATn, TNEGn/TOHMOn, TSOFOn/TDENn/TFOHENOn, RSERn,

RSOFOn/RDENn/RFOHENOn) can be used with any of the clock sources for delay timing. There will be a flop at

each output whose clock is connected to the signal from the input or output clock source pins with as little delay as

possible from the signal on the clock IO pins. This means using the input clock signal before the delays of the

internal clock tree to clock the input signals, and using the output clock signals to drive the output clock pins to

clock the input signals.

DS3181/DS3182/DS3183/DS3184

106

Figure 10-4. Example IO Pin Clock Muxing

SET

CLR

INTERNAL

SIGNAL

TCLKI

PIN INVERT

RLCLK

PIN INVERT

RX LIU CLK

DS3 CLK

E3 CLK

STS-1 CLK

CLAD CLOCKS

TCLKO

PIN INVERT

CLOCK TREE

TDEN

PIN INVERT

SET

CLR

DELAY

TFTS

TSER

PIN INVERT Q

SET

CLR

SET

CLR

INTERNAL

SIGNAL

DELAY

TFTS

SET

CLR

INTERNAL

SIGNAL

TLCLK

PIN INVERT

CLOCK TREE

TPOS

PIN INVERT

SET

CLR

DELAY

TLTS

SET

CLR

INTERNAL

SIGNAL

RCLKO

PIN INVERT

CLOCK TREE

RSER

PIN INVERT

SET

CLR

DELAY

RFTS

10.2.5 Gapped Clocks

The transmit and receive output clocks can be gapped in certain configurations. See Table 10-24 and Table 10-31

for the configuration settings. The gapped clocks are active during DS3 or E3 framed payload bits or DS3 or E3

fractional overhead bits depending on which mode the device is configured for.

In the internal DS3 or E3 fractional modes, the transmit gapped clock is created by the logical OR of the TCLKOn

and TFOHENOn signals creating a positive or negative clock edge for each fractional overhead bit, the receive

gapped clock is created by the logical OR of the RCLKOn and RFOHENOn signals. In the internal DS3 or E3 non-

fractional modes, the transmit gapped clock is created by the logical OR of the TCLKOn and TDENn signals

creating a positive or negative clock edge for each payload bit, the receive gapped clock is created by the logical

OR of the RCLKOn and RDENn signals.

When the output clock is disabled, the gapped output signal is high during clock periods if the pin is not inverted;

otherwise it will be low.

The gapped clocks are very useful when the data being clocked does not need to be aligned with any frame

structure. The data is simply clocked one bit at a time as a continuous data stream.

DS3181/DS3182/DS3183/DS3184

107

10.3 Reset and Power-Down

The device can be reset at a global level via the GL.CR1.RST bit or the RST pin and at the port level via the

PORT.CR1.RST bit and each port can be explicitly powered down via the PORT.CR1.PD bit. The JTAG logic is

reset using the JTRST pin.

The external RST pin and the global reset bit in the global configuration register (GL.CR1.RST) are combined to

create an internal global reset signal. The global reset signal resets all the status and control registers on the chip,

except the GL.CR1.RST bit, to their default values and resets all the other flops in the system bus interface, global

logic and ports to their reset values. The processor bus output signals are also forced to be HIZ when the RST pin

is active (low). The global reset bit (GL.CR1.RST) stays set after a one is written to it, but is reset to zero when the

external RST pin is active or when a zero is written to it.

At the port level, the global reset signal combines with the port reset bit in the port control register

(PORT.CR1.RST) to create a port reset signal. The port reset signal resets all the status and control registers on

the port to their default values and resets all the other flops, except PORT.CR1.RST, to their reset values. The port

reset bit (PORT.CR1.RST) stays set after a one is written to it, but is reset to zero when the global reset signal is

active or when a zero is written to it.

The data path reset function is a little different from the “general” reset function. The data path reset signal does not

reset the control register bits, but it does reset all of the status registers, counters and flops, the “general” reset

signal resets everything including the control register bits, excluding the reset bit. All clocks are functional, being

controlled by configuration bits, while data path reset is active. The LIU and CLAD circuits will be operating

normally during data path reset, which allows the internal phase locked loops to settle as quickly as possible. The

LIU will be sending all zeroes (LOS) since data path reset will be forcing the transmit TPOSn and TNEGn to logic

zero. (NOTE: The BERT data path and control registers are reset when the global data path reset or the port data

path reset or the port power-down signal is active.)

The global data path reset bit (GL.CR1.RSTDP) gets set to one when the global reset signal is active. The port

data path reset bit (PORT.CR1.RSTDP) and the port power-down bit (PORT.CR1.PD) bit get set to one when the

global reset signal is active or the port reset signal is active. These control bits will be cleared when a zero is

written to them if the global reset signal or the port reset signal is not active. The global data path reset signal is

active when the global data path reset bit is set. The port data path reset signal is active when either the global

data path reset bit or the port data path reset bit is set. The port power-down signal is active when the port power-

down bit is set.

Figure 10-5. Reset Sources

SET

CLR

SET

CLR

SET

CLR

SET

CLR

RST pin

Global Reset

Port Reset

Global Data Path Reset

Port Data Path Reset

GL.CR1. RST

GL.CR1. RSTDP

PORT.CR1.

RST

PORT.CR1.

RSTDP

NOTE: Assumes

active high signals

SET

CLR

DPort Power Down

PORT.CR1. PD

DS3181/DS3182/DS3183/DS3184

108

Table 10-10. Reset and Power-Down Sources

Forced: Internally controlled

Set: User controlled

PIN REGISTER BITS INTERNAL SIGNALS

RST

G:RST

G:RSTDP

P:RST

P:RSTDP

P:PD

Global

reset

Global DP

reset

Port reset

Port DP

reset

Port power

Dan

0 F0 F1 F0 F1 F1 1 1 1 1 1

1 1 F1 F0 F1 F1 1 1 1 1 1

1 0 1 1 F1 F1 0 1 1 1 1

1 0 1 0 X 1 0 1 0 1 1

1 0 1 0 X 0 0 1 0 1 0

1 0 0 1 F1 F1 0 0 1 1 1

1 0 0 0 1 1 0 0 0 1 1

1 0 0 0 1 0 0 0 0 1 0

1 0 0 0 0 1 0 0 0 1 1

1 0 0 0 0 0 0 0 0 0 0

The reset signals in the device are asynchronous so they no not require a clock to put the logic into the reset state.

Clock signals may be needed to make the logic come out of the reset state.

The power-down function disables the appropriate clocks to cause the logic to generate a minimum of power. It

also puts the LIU circuits into the power-down mode. Note that the UTOPIA/POS-PHY system interface logic

cannot be powered down, the clocks cannot be stopped. The 8KREF and ONESEC circuits can be powered down

by disabling the 8KREF source. The CLAD can also be powered down by disabling it.

After a global reset, all of the control and status registers in all ports are set to their default values and all the other

flops are reset to their reset values. The global register GL.CR1.RSTDP, and the port register PORT.CR1.RSTDP

and PORT.CR1.PD bits in all ports, are set after the global reset. A valid initialization sequence would be to clear

the PORT.CR1.PD bits in the ports that are to be active, write to all of the configuration registers to set them in the

desired modes, then clear the GL.CR1.RSTDP and PORT.CR1.RSTDP bits. This would cause the logic in the

ports to start up in a repeatable sequence. The device can also be initialized by clearing the GL.CR1.RSTDP,

PORT.CR1.RSTDP and PORT.CR1.PD them writing to all of the configuration registers to set them in the desired

modes, and clearing all of the latched status bits. The second initialization scheme could cause the device to

temporarily go into modes of operation that were not requested, but will quickly go into the requested modes of

operation.

Some of the IO pins are put in a known state at reset. The transmit LIU outputs TXPn and TXNn are quiet and will

not drive positive or negative pulses. The global IO pins (GPIO[7:0]) are set as inputs at global reset. The port

output pins (TLCLKn, TPOSn/TDATn, TNEGn/TOHMOn, TOHCLKn, TOHSOFn, TPOHSOFn/TSOFOn/TDENn/

TFOHENOn, TPOHCLKn/TCLKOn/TGCLKn, ROHn, ROHCLKn, ROHSOFn, RPOHn/RSERn,

RPOHSOFn/RSOFOn/RDENn/RFOHENOn, RPOHCLKn/RCLKOn/RGCLKn) are driven low at global or port reset

and should stay low until after the port power-down PORT.CR1.PD and port data path reset PORT.CR1.RSTDP

bits are cleared. The CLAD clock pins CLKA, CLKB and CLKC are the LIU reference clock inputs at global reset.

The system interface three-state output pins (TDXA[1]/TPXA, TSPA, RDATA[31:0], RPRTY, RDXA[1]/RPXA/RSX,

RSOX, REOP, RVAL, RMOD[1:0], RERR) are in the high impedance and the system interface output pins

(TDXA[4:2],RDXA[4:2]) are driven low at global reset. The processor port three-state output pins (D[15:0], RDY,

INT) are forced into the high impedance state when the RST pin is active, but not when the GL.CR1.RST bit is

active.

DS3181/DS3182/DS3183/DS3184

109

After reset, the device will be in the default configuration:: The latched status bits are enabled to be cleared on

write. The CLAD is disabled. The global 8KREF and one-second timers are disabled. The line interface is in B3ZS

mode and the LIU is disabled and the transmit line pins are also disabled. The frame mode is DS3 C-bit with

automatic downstream AIS on LOS or OOF is enabled and automatic RDI on LOF, LOS, SEF or AIS is enabled

and automatic FEBE is enabled. Transmit clock comes from the CLAD CLKA pin. Cell processing is enabled with

payload scrambling and HEC recalculation and Coset addition enabled. The transmit and receive FIFOs are held in

reset so no cell traffic will occur until the FIFOs are configured. The system interface is in 8-bit UTOPIA L2 with odd

parity enabled and HEC transfer disabled. The pin inversion on all pins is disabled.

Individual blocks are reset and powered down when not used determined by the settings in the line mode bits

PORT.CR2.LM[2:0] and framer mode bits PORT.CR2.FM[5:0].

10.4 Global Resources

10.4.1 Clock Rate Adapter (CLAD)

The clock rate adapter is used to create multiple clocks for LIU reference clocks or transmit clocks from a single

clock reference input on the CLKA pin. The clock frequency applied to this pin must be at the DS3 (44.736 MHz),

E3 (34.368 MHz) and STS-1 (51.84 MHz) clock rates. Given one of these clocks the other two clocks will be

generated. The internally generated signals can be driven on output pins (CLKB and CLKC) for external use.

The receive LIU is supplied a reference clock from the CLAD. The receive LIU selects the clock frequency based

upon the mode the user selects via the FM bits. The CLAD output is also available as a transmit clock source if

selected via the PORT.CR2.CLADC register bit.

The user must supply at least one of the three rates (DS3, E3, STS-1) to the CLKA pin. The CLAD[3:0] bits informs

the PLL of the frequency applied to the pins. Selection of the output clock of the CLAD applied to the LIU and

optionally the transmitter is controlled by the FM bits (located in PORT.CR2). The CLAD allows maximum flexibility

to the user. The user may supply any of the three clock rates and use the CLAD to convert the rate to the particular

clock rate needed for his application.

DS3181/DS3182/DS3183/DS3184

110

Figure 10-6. CLAD Block

CLKA

CLKB

CLKC

DS3 clock

E3 clock

CC52 clock

CLAD

CLAD MODE

The clock rate adapter can also be disabled and all three clocks supplied externally using the CLKA, CLKB and

CLKC pins as clock inputs. When the CLAD is disabled, the three reference clocks DS3, E3 and STS-1 will need to

be applied to the CLKA, CLKB and CLKC pins, respectively. If any of the three frequencies is not required, it does

not need to be applied to the CLAD CLK pins.

The CLAD MODE inputs to the clock rate adapter are composed of CLAD[3:0] control bits (located in the GL.CR2

CLAD[3:0]=00XX, the PLL circuits are disabled and the signals on the input clock pins are used as the internal LIU

reference clocks. When CLAD[3:0]=(01XX or 10XX or 11XX), none, one or two PLL circuits are enabled to

generate the required clocks as determined by the CLAD[3:0] bits and the framing mode (FM[5:0]) and the line

mode (LM[2:0]) control bits. If a clock rate is not required on the CLAD output clock pins or for a reference clock for

any of the LIU, then the PLL used to generate that clock is disabled and powered down.

For example, in a design that only has the ports running at DS3 rates, then CLAD[3:0] can be set = 0100 and the

DS3 clock signal on the CLKA pin will be used as the DS3 LIU reference clock and no PLL circuit will be disabled.

DS3181/DS3182/DS3183/DS3184

111

Table 10-11. CLAD IO Pin Decode

GL.CR2

CLAD[3:0] CLKA PIN CLKB PIN CLKC PIN

00 XX DS3 clock input E3 clock input STS-1 clock input

01 00 DS3 clock input Low output Low output

01 01 DS3 clock input E3 clock output Low output

01 10 DS3 clock input Low output STS-1 clock output

01 11 DS3 clock input STS-1 clock output E3 clock output

10 00 E3 clock input Low output Low output

10 01 E3 clock input DS3 clock output Low output

10 10 E3 clock input Low output STS-1 clock output

10 11 E3 clock input STS-1 clock output DS3 clock output

11 00 STS-1 clock input Low output Low output

11 01 STS-1 clock input E3 output Low output

11 10 STS-1 clock input Low output DS3 clock output

11 11 STS-1 clock input DS3 clock output E3 clock output

10.4.2 8 kHz Reference Generation

The 8KREF signal is used to control the rate of PLCP frames to precisely 8000 per second. The global 8KREF

signal is also used to generate the one-second-reference signal by dividing it by 8000. This signal can be derived

from almost any clock source on the chip as well as the general-purpose IO pin GPIO4. The port 8KREF signal can

be sourced from either the global 8KREF signal or from the transmit or receive port clock or from the receive

8KREF signal. The minimum input frequency stability of the 8KREF input pin is +/- 500 ppm.

The global 8KREF signal can come from an external 8000 Hz reference connected to the GPIO4 general-purpose

IO pin by setting the GL.CR2.G8KIS bit. The global 8KREF signal can be output on the GPIO2 general-purpose IO

pin when the GL.CR2.G8KOS bit is set.

The global 8KREF signal can be derived from the CLAD PLL or pins or come from any of the port 8KREF signals

by clearing GL.CR2.G8KIS bit and selecting the source using the GL.CR2.G8KRS[2:0] bits.

The port 8KREF signal can be derived from either the receive PLCP 8KREF signal or from the transmit clock input

pin or from the receive LIU or input clock pin. The PORT.CR3.P8KRS[1:0] bits are used to select which source.

The transmit PLCP 8KREF signal can be selected to be either the global 8KREF signal or the port 8KREF signal

using the PORT.CR3.P8KREF bit.

The 8KREF 8.000 kHz signal is a simple divisor of 51840 kHz (CC52 divided by 6480), 44736 kHz (DS3 divided by

5592) or 33368 kHz (E3 divided by 4296). The correct divisor for the port 8KREF source is selected by the mode

the port is configured for. The CLAD clock chosen for the clock source selects the correct divisor for the global

8KREF. The 8KREF signal is only as accurate as the clock source chosen to generate it.

Table 10-12 lists the selectable sources for global 8 kHz reference sources.

DS3181/DS3182/DS3183/DS3184

112

Table 10-12. Global 8 kHz Reference Source Table

GL.CR2.

G8KIS

GL.CR2.

G8KRS[2:0] SOURCE

0 000 None, the 8KHZ divider is disabled.

0 001

Derived from CLAD DS3 clock output or CLKA pin if CLAD

is disabled (Note: CLAD is disabled after reset)

0 010

Derived from CLAD E3 clock output or CLKB pin if CLAD is

disabled

0 011

Derived from CLAD STS-1 clock output or CLKC pin if CLAD

is disabled

0 100 Port 1 8KREF source selected by P8KRS[1:0]

0 101 Port 2 8KREF source selected by P8KRS[1:0]

0 110 Port 3 8KREF source selected by P8KRS[1:0]

0 111 Port 4 8KREF source selected by P8KRS[1:0]

1 XXX GPIO4 pin

Table 10-13 lists the selectable sources for port 8 kHz reference sources.

Table 10-13. Port 8 kHz Reference Source Table

PORT.CR3.P8KRS[1:0] SOURCE

0X Receive PLCP 8kHZ output

10 Receive internal framer clock (based on RLCLKn

pin or RX LIU recovered clock)

11 Transmit internal framer clock (based on TCLKIn

pin or CLAD clock)

The 8 kHz reference logic tree is shown below.

Figure 10-7. 8KREF Logic

CLOCK DIVIDER

TX CLOCK

RX CLOCK

FRAME MODE

(FM BITS)

RX PLCP 8KREF

PORT.CR3.

P8KRS[1]

PORT.CR3.P8KRS[0]

GPIO4

OTHER

PORT

8KREF

DS3 CLK

E3 CLK

CC52 CLK

FROM CLAD

GL.CR2.

G8KRS[1:0]

GL.CR2.G8KRS[1:0]

GL.CR2.G8KRS[2]

G8KREF

PORT.CR3.P8KREF

GLOBAL 8KREF

PORT 8KREF

TX PLCP 8KREF

DS3181/DS3182/DS3183/DS3184

113

10.4.3 One-Second Reference Generation

The one-second-reference signal is used as an option to update the performance registers on a precise one-

second interval. The generated internal signal should be about 50% duty cycle and it is derived from the Global

8kHz reference signal by dividing it by 8000. The low to high edge on this signal will set the GL.SRL.ONESL

latched one second detect bit which can generate an interrupt when the GL.SRIE.ONESIE interrupt enable bit is

set. The low to high edge can also be used to generate performance monitor updates when GL.CR1.GPM[1:0]=1X.

10.4.4 General-Purpose IO Pins

There are eight general-purpose IO pins that can be used for general IO, global signals and per-port alarm signals.

Each pin is independently configurable to be a general-purpose input, general-purpose output, global signal or port

alarm. Two of the GPIO pins are assigned to each port and can be programmed to output one or two alarm

statuses using one or two GPIO pins. One of the two pins assigned to each port can be programmed as global

input or output signals. When the device is bonded out (or has ports powered down) to have 1, 2 or 3 ports active,

the GPIO pins associated with the disabled ports will still operate as either general-purpose inputs, general-

purpose outputs or global signals. When the ports are disabled and GL.GIOCR.GPIOx[1:0] = 01, the GPIO pin will

be an output driving low. The 8KREFI, TMEI, and PMU signals that can be sourced by the GPIO pin will be driven

low into the core logic when the GPIO pin is not selected for the source of the signal.

Table 10-14 lists the purpose and control thereof of the General-Purpose IO Pins.

Table 10-14. GPIO Global Signals

PIN GLOBAL SIGNAL CONTROL BIT

GPIO2 8KREFO output GL.CR2.G8KOS

GPIO4 8KREFI input GL.CR2.G8KIS

GPIO6 TMEI input GL.CR1.MEIMS

GPIO8 PMU input GL.CR1.GPM[1:0]

Table 10-15 describes the selection of mode for the GPIO Pins.

Table 10-15. GPIO Pin Global Mode Select Bits

GL.GIOCR.GPIOnSx GPIO PIN MODE

00 Input

01 Port alarm status selected by port GPIO

10 Output logic 0

11 Output logic 1

n = port 1 to 4, x = A or B, valid when a GPIO pin is not selected for a global signal

Table 10-16 lists the various port alarm monitors that can be output on the GPIO pins. The GPIO(A/B)[3:0] bits are

located in the PORT.CR4 Register.

DS3181/DS3182/DS3183/DS3184

114

Table 10-16. GPIO Port Alarm Monitor Select

PORT.CR4

GPIO(A/B)[3:0]

LINE LOS

DS3/E3 OOF

DS3/E3 LOF

DS3/E3 AIS

DS3/E3 RAI

DS3 IDLE

PLCP OOF

PLCP LOF

PLCP RAI

ATM OCD

ATM LCD

0000 X

0001 X

0010 X

0011 X

0100 X

0101 X

0110 X

0111 X

1000 X

1001 X

1010 X

1011 X X X

1100 X X

1101 X X X X X

1110 X X X

1111 X X X X X X X X X X X

10.4.5 Performance Monitor Counter Update Details

The performance monitor counters are designed to count at least one second of events before saturating to the

maximum count. There is a status bit associated with some of the performance monitor counters that is set when

the its counter is greater than zero, and a latched status bit that gets set when the counter changes from zero to

one. There is also a latched status bit that gets set on every event that causes the error counter to increment.

There is a read register for each performance monitor counter. The count value of the counter gets loaded into this

at the exact moment (clock cycle) that the counter is to be cleared then the counter will be set to a value of one so

that that event will be counted.

The Performance Monitor Update signal affects the counter registers of the following blocks: the BERT, the DS3/E3

framer, the Line Encoder/Decoder, the DS3/E3 PLCP framer, the Cell Processor, and the Packet Processor.

The update-clear operation is controlled by the Performance Monitor Update signal (PMU). The update-clear

operation will update the error counter registers with the value of the error counter and also reset each counter.

The PMU signal can be created in hardware or software. The hardware sources can come from the one second

counter or one of the general-purpose IO pins, which can be programmed to source this signal. The software

sources can come from one of the per-port control register bits or one of the global control register bits. When

using the software update method, the PMU control bit should be set to initiate the process and when the PMS

status bit gets set, the PMU control bit should be cleared making it ready for the next update. When using the

hardware update method, the PMS bit will be set shortly after the hardware signal goes high, and cleared shortly

after the hardware signal goes low. The latched PMS signal can be used to generate an interrupt for reading the

count registers. If the port is not configured for global PMU signals, the PMS signal from that port should be

blocked from affecting the global PMS status.

DS3181/DS3182/DS3183/DS3184

115

Figure 10-8. Performance Monitor Update Logic

GL.SR.GPMS

PORT.SR.PMS

PORT.CR1.PMU

PORT.CR1.PMUM

GL.CR1.GPM

GL.CR1.GPMU

GPIO8(GPMU) PIN

ONE SEC

PERF

COUNTER

other port counters

other ports

PMU PMS

GTZ

10.4.6 Transmit Manual Error Insertion

Transmit errors can be inserted in some of the functional blocks. These errors can be inserted using register bits in

the functional blocks, using the global GL.CR1.TMEI bit, using the port PORT.CR1.TMEI bit, or by using the GPIO6

pin configured for TMEI mode.

There is a transmit error insertion register in the functional blocks that allow error insertion. The MEIMS bit controls

whether the error is inserted using the bits in the error insertion register or using error insertion signals external to

that block. When bit MEIMS=0, errors are inserted using other bits in the transmit error insertion register. When bit

MEIMS=1, errors are inserted using a signal generated in the port or global control registers or using the external

GPIO6 pin configured for TMEI operation.

DS3181/DS3182/DS3183/DS3184

116

Figure 10-9. Transmit Error Insert Logic

BERT ERROR

INSERT

BERT.TEICR.MEIMS

BERT.TEICR error

insertion bit 0

PORT.CR.MEIMS

PORT.CR.TMEI

GL.CR1.MEIMS

GL.CR1.TMEI

GPIO6 PIN

(TMEI)

T3.TEIR.MEIMS

T3.TEIR error

insertion bit

T3 ERROR

INSERT

10.5 Per-Port Resources

10.5.1 Loopbacks

There are several loopback paths available. The following table lists the loopback modes available for analog

loopback (ALB), line loopback (LLB), payload loopback (PLB) and diagnostic loopback (DLB). System loopback

(SLB) does not interact with these loopbacks and is given its own control bit. The LBM bits are located in

PORT.CR4.

Table 10-17. Loopback Mode Selections

LBM[2:0] ALB LLB PLB DLB

000 0 0 0 0

001 1 0 0 0

010 0 1 0 0

011 0 0 1 0

10X 0 0 0 1

110 0 1 0 1

111 0 0 0 1

DS3181/DS3182/DS3183/DS3184

117

Figure 10-10 highlights where each loopback mode is located and gives an overall view of the various loopback

paths available.

Figure 10-10. Loopback Modes

DS3/E3

Transmit

LIU

IEEE P1149.1

JTAG Test

Access Port

Microprocessor

Interface

HDLC

FEAC

LLB

DLB

DS3 / E3

Transmit

Formatter

DS3 / E3

Receive

Framer

Trail

Trace

Buffer

Tx Cell

Processor Tx

FIFO

System

Interface

Rx Cell

Processor

FIFO

Tx Packet

Processor

SLB

Rx Packet

Processor

DS3/E3

Receive

LIU

TAIS

TUA1

TX FRAC/

PLCP

RX FRAC/

PLCP

Clock Rate

Adapter

TX BERT

RX BERT

PLB

ALB

UA1

GEN

B3ZS/

HDB3

Encoder

B3ZS/

HDB3

Decoder

10.5.1.1 Analog Loopback (ALB)

Analog loopback is enabled by setting PORT.CR4.LBM[2:0] = 001. Analog loopback mode will not be enabled

when the port is configured for loop timed mode (set via the PORT.CR3.LOOPT bit).

The analog loopback is a loopback as close to the pins as possible. When both the TX and RX LIU is enabled, it

loops back TXPn and TXNn to RXPn and RXNn, respectively. If the transmit signals on TXPn and TXNn are not

terminated properly, this loopback path may have data errors or loss of signal. When the LIU is not enabled, it

loops back TLCLKn, TPOSn / TDATn, TNEGn / TOHMOn to RLCLKn ,RPOSn / RDATn , RNEGn / ROHMIn.

Figure 10-11. ALB Mux

RXP

RXN

TXP

TXN

LIU

DS3181/DS3182/DS3183/DS3184

118

10.5.1.2 Line Loopback (LLB)

Line loopback is enabled by setting PORT.CR4.LBM[2:0] = X10. DLB and LLB are enabled at the same time when

LBM[2:0] = 110, and only LLB is enabled when LBM[2:0] = 010.

The clock from the receive LIU or the RLCLK pin will be output to the transmit LIU or TCLKOn pin. The POS and

NEG data from the receive LIU or the RPOS and RNEG pin will be sampled with the receive clock to time it to the

LIU or pin interface.

When LLB is enabled, unframed all ones AIS can optionally be automatically enabled on the receive data path.

This AIS signal will be output on the RSERn pin in flexible fractional mode, and sent to the receive cell or packet

processor in framer modes, effectively stopping cell or packet data flow. When DLB and LLB is enabled, the AIS

signal will not be transmitted. See Figure 10-10.

10.5.1.3 Payload Loopback (PLB)

Payload loopback is enabled by setting PORT.CR4.LBM[2:0] = 011.

The payload loopback copies the payload data from the receive framer to the transmit framer (before the fractional

logic) which then re-frames the payload before transmission. Payload loopback is operational in all framing modes

except “- OHM” modes.

When PLB is enabled, unframed all ones AIS transmission can optionally be automatically enabled on the receive

data path. This AIS signal will be output on the RSER pin in flexible fractional mode, and sent to the receive cell or

packet processor in framer modes, effectively stopping cell or packet data flow.

In all modes, the TSOFIn input pin is ignored.

The external transmit output pins TDENn and TSOFOn/TDENn can optionally be disabled by forcing a zero when

PLB is enabled.

In the framed modes, the data flow from the transmit cell or packet processor can be optionally disabled when PLB

is enabled. If the data flow is not disabled, the cells or packets from the system interface will be discarded. See

Figure 10-10.

10.5.1.4 Diagnostic Loopback (DLB)

Diagnostic loopback is enabled by setting PORT.CR4.LBM[2:0] = 1XX. DLB and LLB are enabled at the same time

when LBM[2:0] = 110, only DLB is enabled when LBM[2:0] = 10X or 111.

The Diagnostic loopback sends the transmit data, before line encoding, back to the receive side.

Transmit AIS can still be enabled using PORT.CR1.LAIS[2:0] even when DLB is enabled. See Figure 10-10.

10.5.1.5 System Loopback (SLB)

System loopback is enabled by setting the PORT.CR4.SLB bit. The system loopback sends the packets or cells

from the transmit UTOPIA or POS-PHY interface back to the receive UTOPIA or POS-PHY interface. Cells and

packets from the line interface will be discarded. See Figure 10-10.

10.5.2 Loss Of Signal Propagation

The Loss Of Signal (LOS) is detected in the line decoder logic if the device is set for HDB3 or B3ZS line encoding.

In unipolar (UNI) line interface modes and AMI modes LOS detection is disabled. The LOS signal from the line

decoder is sent to the DS3/E3 framer and the top level payload AIS logic except when DLB is activated. When DLB

is activated the LOS signal to the framer and AIS logic is never active. The LOS status in the line decoder status

10.5.3 AIS Logic

There is AIS logic in both the framers and at the top level logic of the ports. The framer AIS is enabled by setting

the TAIS bit in the appropriate framer transmit control register (T3, E3-G.751, E3-G.832, or Clear Channel). The

top level AIS is enabled by setting the PORT.CR1.LAIS[2:0] bits (see Table 10-18). The AIS signal is an unframed

all ones pattern or a DS3 framed 101010… pattern depending on the FM[5:0] mode bits. The DS3 Framed Alarm

Indication Signal (AIS) is a DS3 signal with valid F-bits, M-bits, and P-bits (P1 and P2). The X-bits (X1 and X2) are

set to one, all C-bits (CXY) are set to zero, and the payload bits are set to a 1010 pattern starting with a one

DS3181/DS3182/DS3183/DS3184

119

immediately after each overhead bit. The DS3 framed AIS pattern is only available in DS3 modes. The unframed all

ones pattern is available in all framing and clear-channel modes including the DS3 modes. The transmit line

interface can send both unframed all ones AIS and DS3 framed AIS patterns from either the AIS generator in the

framer or the AIS generator at the top level.

The AIS signal generated in the framer can be initiated and terminated without introducing any errors in the signal.

When the unframed AIS signal is initiated or terminated, there will be no BPV or CV errors introduced, there will be

framing errors if a framed mode is enabled. When the DS3 framed AIS signal is initiated or terminated, in addition

to no BPV or CV errors, there should be no framing or P-bit (parity) or CP-bit errors introduced.

The AIS signal generated at the top level will not generate BPV errors but may generate P-bit and CP-bit errors

when the signal is initiated and terminated. The framed DS3 AIS signal will not cause the far end receiver to re-

sync when the signal is initiated, but it may cause a re-sync when terminated if the DS3 frame position in the

framer is changed while the DS3 AIS signal is being generated. A sequence of events can be executed which will

enable the initiation and termination of DS3 AIS or unframed all ones at the top level without any errors introduced.

The sequence will only work when the automatic AIS generation is not enabled. CV and P-bit errors can occur

when AIS is automatically generated and cannot be avoided. This sequence to generate an error free DS# AIS at

the top level is to have the DS3 AIS or unframed all ones signal initiate in the DS3 framer, and a few frames sent

before initiating or terminating the DS3 AIS or unframed all ones at the top level. After the top level AIS signal is

activated, the AIS signal in the framer can be terminated, DLB activated and diagnostic patterns generated. The

DS3 AIS signal generated at the top level will not change frame alignment after starting even if the DS3 frame

position in the framer is changed.

The transmit line AIS generator at the top level can generate AIS signals even when the framer is looped back

using DLB, but not when the line is looped back using LLB. The AIS signal generated in the framer will be looped

back to the receive side when DLB is activated.

The receive framer can detect both unframed all ones AIS and DS3 framed AIS patterns. When in DS3 framing

modes, both framed DS3 AIS and unframed all ones can be detected. In E3 framing modes E3 AIS, which is

unframed all ones, is detected. In clear-channel modes, unframed all ones is detected.

The receive payload interface going to the RSERn pin or the PLCP, FRAC, BERT or ATM/PKT logic can have an

unframed all ones AIS signal replacing the receive signal, this is called Payload AIS. The all ones AIS signal is

generated from either the DS3/E3 framer or the downstream top level unframed all ones AIS generator. The

unframed all ones AIS signal generated in the framer will be looped back to the transmit side when PLB is

activated. The unframed all ones AIS signal generated at the top level will be sent to the RSERn pin and other

receive logic, but not to the transmit side while PLB is activated. The top level AIS generator is used when a

downstream AIS signal is desired while payload loopback is activated and is enabled by default after rest and must

be cleared during configuration. Note that the downstream AIS circuit in the framer, when a DS3 mode is selected,

enforces the OOF to be active for 2.5 ms before activating when automatic AIS in the framer is enabled. The top

level downstream AIS will be generated with no delay when OOF is detected when automatic AIS at the top level is

enabled.

There is no detection of any AIS signal on the transmit payload signal from the TSERn pin or anywhere on the

transmit data path.

The transmit AIS generator at the top level can also be activated with a software bit or automatically when DLB is

activated. The receive AIS generator in the framer can be activated with a software bit, and automatically when

AIS, LOS or OOF are detected. The receive payload AIS generator at the top level can be activated with a software

bit or automatically when LOS, DS3/E3 OOF, LLB or PLB is activated.

When the port is configured for “- OHM” modes, the transmit DS3 AIS signal pattern generation is paused when the

TOHMI signal is active. Also the receive DS3 AIS and unframed all ones detectors do not use the bits marked for

overhead from the ROHMIn signal when DLB is not activated or the TOHMIn signal when DLB is activated. The

payload unframed all ones overwrites the receive signal with all ones even in overhead bit positions.

DS3181/DS3182/DS3183/DS3184

120

Figure 10-12 shows the AIS signal flow through the device.

Figure 10-12. AIS Signal Flow

UA1

AIS

UA1

AIS

DS3/

UA1

AIS

DS3/

UA1

AIS

optional

B3ZS/

HDB3

decoder

optional

B3ZS/

HDB3

encoder PLB

DLB

LLB

DS3/UA1

AIS

detector

FRAMER

TAIS

DAIS

TAIS

DAIS

TRANSMIT

LINE

RECEIVE

LINE

TRANSMIT

PAYLOAD

RECEIVE

PAYLOAD

TSOFO

LINE/TRIBUTARY

SIDE SYSTEM/

TRUNK SIDE

Table 10-18 lists the LAIS decodes for various line AIS enable modes.

Table 10-18. Line AIS Enable Modes

LAIS[1:0]

PORT.CR1 FRAME MODE DESCRIPTION AIS CODE

00 DS3

Automatic AIS when DLB is enabled

(PORT.CR4.LBM = 1XX) DS3AIS

00 E3 Automatic AIS when DLB is enabled UA1

00 Clear Channel Automatic AIS when DLB is enabled UA1

01 Any Send UA1 UA1

10 DS3 Send AIS DS3AIS

10 E3 or Clear

Channel Send AIS UA1

11 Any Disable none

DS3181/DS3182/DS3183/DS3184

121

Table 10-19 lists the PAIS decodes for various payload AIS enable modes.

Table 10-19. Payload (Downstream) AIS Enable Modes

PAIS[2:0]

PORT.CR1 WHEN AIS IS SENT AIS CODE

000 Always UA1

001 When LLB (no DLB) active UA1

010 When PLB active UA1

011 When LLB(no DLB) or PLB active UA1

100 When LOS (no DLB) active UA1

101 When OOF active UA1

110 When OOF, LOS. LLB (no DLB), or

PLB active UA1

111 Never none

10.5.4 Loop Timing Mode

Loop timing mode is enabled by setting the PORT.CR3.LOOPT bit. This mode replaces the clock from the TCLKIn

pin with the internal receive clock from either the RLCLKn pin if the RX LIU is disabled, or the recovered clock from

the RX LIU if it is enabled. The loop timing mode can be activated in any framing or line interface mode.

10.5.5 HDLC Overhead Controller

There is a single HDLC controller for use in line maintenance protocols. The DS3, E3 and PLCP framers share the

same HDLC controller. Since the PLCP and DS3 or E3 framers can potentially use the HDLC controller at the

same time, there is a select bit in the port control register to chose which one uses the HDLC controller

(PORT.CR1.HDSEL). The port that does not get access to the HDLC controller will transmit all ones in the

overhead bits that the HDLC controller would connect to. The external overhead ports can be used to connect to

an external HDLC controller if both framers need the function.

The data signal to the receive HDLC controller will be forced to a one while still being clocked when the framer

(DS3, E3, or PLCP), to which the HDLC is connected, detects LOF or AIS. Forcing the data signal to all ones will

cause an HDLC packet abort if the data started to look like a packet instead of allowing a bad, and possibly very

long, HDLC packet.

10.5.6 Trail Trace

There is a single Trail Trace controller for use in line maintenance protocols. The E3-G.832 and PLCP framers can

use the trail trace controller and it is shared automatically since the E3-G.832 and PLCP framing cannot be

enabled at the same time.

10.5.7 BERT

There is a Bit Error Rate Test (BERT) circuit for each port for use in generating and detecting test signals in the

payload bits. The BERT can generate and detect PRBS patterns up to 2^32-1 bits as well as repeating patterns up

to 32 bits long. The generated BERT signal replaces the cells or packets from the system interface when the BERT

is enabled by setting the PORT.CR1.BENA.

The cells or packets from the system interface will still be processed using the same bit rate as when the BERT

was not enabled. Any transmit cells will be simply discarded when the BERT is enabled, and any cells or packets

on the line interface will be processed and sent to the system bus when the BERT is enabled. The TDENn and

RDENn pins will still be active but the data on the TSERn pin will be discarded when the BERT is enabled.

DS3181/DS3182/DS3183/DS3184

122

10.5.8 Fractional Payload Controller

The Fractional Payload Controller allows the user flexibility to control sub-rate datastreams. The Fractional Payload

Controller performs fractional overhead/payload data multiplexing. Fractional overhead is sourced from either an

internal register or the external interface. The allocation of the DS3/E3 payload is also controlled either internally

(internally controlled mode) or through the external interface (externally controlled mode).

The third option is Flexible Mode that allows the user to externally multiplex payload and overhead, bypassing the

Fractional Payload Controller.

10.5.9 PLCP/Fractional port pins

The PLCP/Fractional port pins are have multiple functions based on the framing mode the device is in as well as

other pin mode select bits.

10.5.9.1 Transmit PLCP/Fractional port pins

The transmit PLCP/Fractional pins are TSOFIn / TOHMIn, TPOHn / TFOHn / TSERn, TPOHENn / TFOHENIn /

TPDENIn, TPOHSOFn / TSOFOn / TDENn / TFOHENOn, TPDENOn, TPDATn, and TPOHCLKn / TCLKOn /

TGCLKn. They have different functions based on the framing mode and other pin mode bits. Unused input pin

functions should drive a logic zero into the device circuits expecting a signal from that pin. The control bits that

configure the pins’ modes are PORT.CR2.FM[5:0], PORT.CR3.TPFPE, PORT.CR3.TSOFOS and

PORT.CR3.TCLKS.

Table 10-20 to Table 10-26 describe the function selected by the FM bits and other pin mode bits for the

multiplexed pins.

Table 10-20. TSOFIn/TOHMIn Input Pin Functions

FM[5:0]

PORT.CR2

FUNCTION

0XXX00 (FRM) TSOFIn

0XXX1X (FRM) TSOFIn

0XXX01 (OHM) TOHMIn

1XX0X1 (OHM) TOHMIn

1XX0X0 (UFRM) Not used

1XX1XX (UFRM) Not used

Table 10-21. TSERn/TPOHn/TFOHn Input Pin Functions

FM[5:0] PORT.CR2 TPFPE

PORT.CR3

FUNCTION

0XX00X (FRM) X Not used

0XX010 (IFRAC) 0 Not used

0XX010 (IFRAC) 1 TFOHn

0XX011 (XFRAC) X TFOHn

0XX10X (PLCP) 0 Not used

0XX10X (PLCP) 1 TPOHn

0XX110 (FFRAC) X TSERn

1XX0XX (CLR) X Not used

DS3181/DS3182/DS3183/DS3184

123

Table 10-22. TPDENIn/TPOHENn/TFOHENIn Input Pin Functions

FM[5:0] PORT.CR2 TPFPE

PORT.CR3

FUNCTION

0XX00X (FRM) X Not used

0XX010 (IFRAC) X Not used

0XX011 (XFRAC) X TFOHENIn

0XX10X (PLCP) 0 Not used

0XX10X (PLCP) 1 TPOHENn

0XX110 (FFRAC) X TPDENIn

1XXXXX (CLR) X Not used

Table 10-23. TSOFOn/TDENn/TPOHSOFn/TFOHENOn Output Pin Functions

FM[5:0] PORT.CR2 TPFPE

PORT.CR3

TSOFOS

PORT.CR3

FUNCTION

0XX00X (FRM) 0 X Low

0XX00X (FRM) 1 0 TDENn

0XX00X (FRM) 1 1 TSOFOn

0XX010 (IFRAC) 0 X Low

0XX010 (IFRAC) 1 X TFOHENOn

0XX011 (XFRAC) X 0 TDENn

0XX011 (XFRAC) X 1 TSOFOn

0XX10X (PLCP) 0 X Low

0XX10X (PLCP) 1 X TPOHSOFn

0XX110 (FFRAC) X 0 TDENn

0XX110 (FFRAC) X 1 TSOFOn

1XX0XX (CLR) X X Low

DS3181/DS3182/DS3183/DS3184

124

Table 10-24. TCLKOn/TGCLKn/TPOHCLKn Output Pin Functions

FM[5:0]

PORT.CR2

TPFPE

PORT.CR3

TCLKS

PORT.CR3

FUNCTION GAP SOURCE

0XX00X (FRM) 0 X Low none

0XX00X (FRM) 1 0 TGCLKn TDENn

0XX00X (FRM) 1 1 TCLKOn none

0XX010 (IFRAC) 0 X Low none

0XX010 (IFRAC) 1 0 TGCLKn TFOHENOn

0XX010 (IFRAC) 1 1 TCLKOn none

0XX011 (XFRAC) X X TCLKOn none

0XX10X (PLCP) 0 X Low none

0XX10X (PLCP) 1 0 TPOHCLKn none

0XX10X (PLCP) 1 1 TCLKOn none

0XX110 (FFRAC) X 0 Low none

0XX110 (FFRAC) X 1 TCLKOn none

1XX0XX (CLR) 0 X Low none

1XX0XX (CLR) 1 X TCLKOn none

Table 10-25. TPDATn Input Pin Functions

FM[5:0]

PORT.CR2

TPFPE

PORT.CR3

FUNCTION

0XX0XX (FRM) X Low

0XXX0X (FRM) X Low

0XX110 (FFRAC) X TPDATn

1XXXXX (CLR) X Low

Table 10-26. TPDENOn Output Pin Functions

FM[5:0]

PORT.CR2

TPFPE

PORT.CR3

FUNCTION

0XX0XX (FRM) X Low

0XXX0X (FRM) X Low

0XX110 (FFRAC) X TPDENOn

1XXXXX (CLR) X Low

10.5.9.2 Receive PLCP/Fractional port pins

The receive PLCP/Fractional pins are RPOHn / RSERn, RFOHENIn / RPDENIn, RPDATn, RPOHSOFn / RSOFOn

/ RDENn / RFOHENOn and RPOHCLKn / RCLKOn / RGCLKn. They have different functions based on the framing

mode and other pin mode bits. Unused input pin functions should drive a logic zero into the device circuits

expecting a signal from that pin. The control bits that configure these pins are PORT.CR2.FM[5:0],

PORT.CR3.RPFPE, PORT.CR3.RSOFOS and PORT.CR3.RCLKS.

Table 10-27 to Table 10-31 describe the function selected by the FM bits and other pin mode bits for the

multiplexed pins.

DS3181/DS3182/DS3183/DS3184

125

Table 10-27. RSERn/RPOHn Output Pin Functions

FM[5:0]

PORT.CR2

RPFPE

PORT.CR3

FUNCTION

0XX00X (FRM) 0 Low

0XX00X (FRM) 1 RSERn

0XX010 (IFRAC) 0 Low

0XX010 (IFRAC) 1 RSERn

0XX011 (XFRAC) X RSERn

0XX10X (PLCP) 0 Low

0XX10X (PLCP) 1 RPOHn

0XX110 (FFRAC) X RSERn

1XX0XX (CLR) 0 Low

1XX0XX (CLR) 1 RSERn

Table 10-28. RPDENIn/RFOHENIn Input Pin Functions

FM[5:0]

PORT.CR2

RPFPE

PORT.CR3

FUNCTION

0XX00X (FRM) X Not used

0XX010 (IFRAC) X Not used

0XX011 (XFRAC) X RFOHENIn

0XX10X (PLCP) X Not used

0XX110 (FFRAC) X RPDENIn

1XXXXX (CLR) X Not used

Table 10-29. RPDATn Input Pin Functions

FM[5:0]

PORT.CR2

RPFPE

PORT.CR3

FUNCTION

0XX0XX (FRM) X Not used

0XXX0X (FRM) X Not used

0XX110 (FFRAC) X RPDATn

1XXXXX (CLR) X Not used

DS3181/DS3182/DS3183/DS3184

126

Table 10-30. RSOFOn/RDENn/RPOHSOFn/RFOHENOn Output Pin Functions

FM[5:0]

PORT.CR2

RPFPE

PORT.CR3

RSOFOS

PORT.CR3

FUNCTION

0XX00X (FRM) 0 X Low

0XX00X (FRM) 1 0 RDENn

0XX00X (FRM) 1 1 RSOFOn

0XX010 (IFRAC) 0 X Low

0XX010 (IFRAC) 1 X RFOHENOn

0XX011 (XFRAC) X 0 RDENn

0XX011 (XFRAC) X 1 RSOFOn

0XX10X (PLCP) 0 X Low

0XX10X (PLCP) 1 X RPOHSOFn

0XX110 (FFRAC) X 0 RDENn

0XX110 (FFRAC) X 1 RSOFOn

1XX0XX (CLR) X X Low

Table 10-31. RCLKOn/RGCLKn/RPOHCLKn Output Pin Functions

FM[5:0]

PORT.CR2

RPFPE

PORT.CR3

RCLKS

PORT.CR3

FUNCTION GAP SOURCE

0XX00X (FRM) 0 X Low none

0XX00X (FRM) 1 0 RGCLKn RDEN

0XX00X (FRM) 1 1 RCLKOn none

0XX010 (IFRAC) 0 X Low none

0XX010 (IFRAC) 1 0 RGCLKn RFOHENOn

0XX010 (IFRAC) 1 1 RCLKOn none

0XX011 (XFRAC) X X RCLKOn none

0XX10X (PLCP) 0 X Low none

0XX10X (PLCP) 1 0 RPOHCLKn none

0XX10X (PLCP) 1 1 RCLKOn none

0XX110 (FFRAC) X 0 Low none

0XX110 (FFRAC) X 1 RCLKOn none

1XX0XX (CLR) 0 X Low none

1XX0XX (CLR) 1 X RCLKOn none

DS3181/DS3182/DS3183/DS3184

127

10.5.10 Framing Modes

The framing modes are selected independently of the line interface modes using the PORT.CR2.FM[5:0] control

bits. Different blocks are used in different framing modes. The bit error test (BERT) function can be enabled in any

mode. The LIU, JA and line encoder/decoder blocks are selected by the line mode (LM[2:0]) code.

The “- OHM” mode, also known as “externally defined frame mode”, is a mode that allow the use of the external

frame overhead bit mask pins TOHMIn, TOHMOn and ROHMIn. This mode allows external logic to select bit

locations where another level of framing can add overhead bits such as SONET/SDH overhead bits. Payload

loopback (PLB) is disabled in this mode. The “Clear-Channel—OHM Octet aligned” modes perform octet alignment

to the overhead mask for ATM and packets and the packets become octet stuffed instead of bit stuffed.

See Table 10-32.

Table 10-32. Framing Mode Select Bits FM[5:0]

FM[5:0] DESCRIPTION LINE CODE SYSTEM FIGURE

0 00 000 DS3 C-bit B3ZS/AMI/UNI ATM/PKT Figure 6-1

0 00 001 DS3 C-bit—OHM UNI ATM/PKT Figure 6-2

0 00 010 DS3 C-bit Internal Fractional B3ZS/AMI/UNI ATM/PKT Figure 6-3

0 00 011 DS3 C-bit External Fractional B3ZS/AMI/UNI ATM/PKT Figure 6-4

0 00 100 DS3 C-bit PLCP B3ZS/AMI/UNI ATM Figure 6-6

0 00 101 DS3 C-bit PLCP—OHM UNI ATM Figure 6-7

0 00 110 DS3 C-bit Flexible Fractional B3ZS/AMI/UNI ATM/PKT Figure 6-5

0 01 000 DS3 M23 B3ZS/AMI/UNI ATM/PKT Figure 6-1

0 01 001 DS3 M23—OHM UNI ATM/PKT Figure 6-2

0 01 010 DS3 M23 Internal Fractional B3ZS/AMI/UNI ATM/PKT Figure 6-3

0 01 011 DS3 M23 External Fractional B3ZS/AMI/UNI ATM/PKT Figure 6-4

0 01 100 DS3 M23 PLCP B3ZS/AMI/UNI ATM Figure 6-6

0 01 101 DS3 M23 PLCP—OHM UNI ATM Figure 6-7

0 01 110 DS3 M23 Flexible Fractional B3ZS/AMI/UNI ATM/PKT Figure 6-5

0 10 000 E3 G.751 HDB3/AMI/UNI ATM/PKT Figure 6-1

0 10 001 E3 G.751—OHM UNI ATM/PKT Figure 6-2

0 10 010 E3 G.751 Internal Fractional HDB3/AMI/UNI ATM/PKT Figure 6-3

0 10 011 E3 G.751 External Fractional HDB3/AMI/UNI ATM/PKT Figure 6-4

0 10 100 E3 G.751 PLCP HDB3/AMI/UNI ATM Figure 6-6

0 10 101 E3 G.751 PLCP—OHM UNI ATM Figure 6-7

0 10 110 E3 G.751 Flexible Fractional HDB3/AMI/UNI ATM/PKT Figure 6-5

0 11 000 E3 G.832 HDB3/AMI/UNI ATM/PKT Figure 6-1

0 11 001 E3 G.832—OHM UNI ATM/PKT Figure 6-2

0 11 010 E3 G.832 Internal Fractional HDB3/AMI/UNI ATM/PKT Figure 6-3

0 11 011 E3 G.832 External Fractional HDB3/AMI/UNI ATM/PKT Figure 6-4

0 11 100 Reserved

0 11 101 Reserved

0 11 110 E3 G.832 Flexible Fractional HDB3/AMI/UNI ATM/PKT Figure 6-5

1 00 0X0 DS3 Clear Channel B3ZS/AMI/UNI ATM/PKT Figure 6-8

1 00 001 DS3 Clear-Channel—OHM UNI ATM/PKT Figure 6-9

1 00 011 DS3 Clear-Channel—OHM Octet aligned UNI ATM/PKT Figure 6-10

1 01 0X0 STS-1 Clear Channel B3ZS/AMI/UNI ATM/PKT Figure 6-8

1 01 001 STS-1 Clear-Channel—OHM UNI ATM/PKT Figure 6-9

1 01 011 STS-1 Clear-Channel—OHM Octet aligned UNI ATM/PKT Figure 6-10

1 1X 0X0 E3 Clear Channel HDB3/AMI/UNI ATM/PKT Figure 6-8

1 1X 001 E3 Clear-Channel—OHM UNI ATM/PKT Figure 6-9

1 1X 011 E3 Clear-Channel—OHM Octet aligned UNI ATM/PKT Figure 6-10

DS3181/DS3182/DS3183/DS3184

128

10.5.11 Mapping Modes

Cells and packets are mapped into various internally generated frame structures or mapped with no framing or

mapped into an externally generated frame structure. When ATM cells are mapped into an internally generated

frame structure they are either directly mapped into a DS3 or E3 frame or they are mapped into a PLCP frame and

then the PLCP frame is mapped into a DS3 or E3 frame. ATM cells are always delineated using bit-by-bit HEC

searching except when byte aligned OHM modes are used, then HEC is searched for byte-by-byte. HDLC packets

are always use the bit stuffing protocol searching bit-by-bit except when byte aligned OHM modes are used, then

they use the byte stuffing protocol. PLCP framing is always searched for bit-by-bit.

The following sections give examples of the major framed mapping configurations:

10.5.11.1 DS3 C-Bit or DS3 M23 (with C-Bit Generation) Direct and PLCP Mapping

For direct mapping into DS3 C-bit and DS3 M23 (with C-bit generation) frames, ATM cells are nibble aligned or bit

aligned, HDLC packets are always bit aligned. For PLCP mapping into DS3 C-bit and DS3 M23 (with C-bit

generation) frames, the PLCP frame is always nibble aligned. The ATM cell nibble/bit alignment is controlled with

the NAD bit in the PORT.CR1 register.

Figure 10-13. DS3 C-Bit or DS3 M23 (with C-Bit Generation) Frame

680 Bits

7 Sub-

Frames

F11

F21

F31

F41

F51

F61

F71

F12

F22

F32

F42

F52

F62

F72

F13

F23

F33

F43

F53

F63

F73

F14

F24

F34

F44

F54

F64

F74

C11

C21

C31

C41

C51

C61

C71

C12

C22

C32

C42

C52

C62

C72

C13

C23

C33

C43

C53

C63

C73

bits

In DS3 PLCP framing, the ATM cell is always cell aligned into the PLCP frame, HDLC packets cannot be mapped

into PLCP frames. The DS3 PLCP frame can only be mapped into a DS3 C-bit frame or DS3 M23 (with generated

C-bits) frame. The NAD control bit is ignored.

DS3181/DS3182/DS3183/DS3184

129

Figure 10-14. DS3 PLCP Frame

13 or 14

Nibbles

Subframes

A1 A2

Subframe (57 Bytes)

A1 A2

P11

P10

53 Payload Bytes (1 cell)

Trailer

53 Payload Bytes

10.5.11.2 DS3 M23 (with C-bits used as payload) Direct Mapping

For direct mapping into DS3 M23 (with the C-bits used as payload) frames, ATM cells must be bit aligned, HDLC

packets are always bit aligned. The NAD bit must be set to one in this mode when direct mapping ATM cells into

DS3 M23 (with the C-bits used as payload) frames.

NOTE: PLCP mapping into DS3 M23 (with the C-bits used as payload) frames will not operate correctly.

DS3181/DS3182/DS3183/DS3184

130

Figure 10-15. DS3 M23 (with C-Bits Used as Payload) Frame

680 Bits

7 Sub-

Frames

F11

F21

F31

F41

F51

F61

F71

F12

F22

F32

F42

F52

F62

F72

F13

F23

F33

F43

F53

F63

F73

F14

F24

F34

F44

F54

F64

F74

bits

169

bits

169

bits

169

bits

10.5.11.3 E3 G.751 Direct and PLCP Mapping

For direct mapping into E3 G.751 frames, ATM cells and HDLC packets are bit aligned. ATM cells can also be

PLCP mapped to the E3 G.751 frame. When E3 PLCP mapping is used, the first four bits of the payload (E3 frame

bits 13,14,15 and 16) are forced to be 1100 and the rest of the payload is used for the PLCP frame that is

transmitted byte aligned and the NAD bit is ignored.

Figure 10-16. E3 G.751 Frame

FAS

384 Payload Bits

384 bits

4 Rows

A N

384 Payload Bits

376 Payload Bits

In E3 PLCP framing, the ATM cell is always cell aligned into the PLCP frame, HDLC packets cannot be mapped

into PLCP frames. The E3 PLCP frame can only be mapped into a E3 G.751 frame. The NAD control bit is ignored.

DS3181/DS3182/DS3183/DS3184

131

Figure 10-17. E3 PLCP Frame

9 Sub-

frames

Subframe

A1 A2

P0 Trailer

18 or 20

Bytes

53 Payload Bytes

53 Payload Bytes (1 cell)

10.5.11.4 Example E3 G.751 Internal Fractional Mapping

The example E3 G.751 internal fractional mapping shown in Figure 10-16 is accomplished using the internal

fractional block. The first four bits of the E3. G.751 payload is designated fractional overhead This is done by

setting Section A (FRAC.TDASR) register of the fractional block to be overhead and setting its size to be four bits.

The data group size (FRAC.TDGSR) register should be set to the length of the normal payload (1524) or any

number greater than that. The four bits of fractional overhead (E3 frame bits 13,14,15 and 16) can be set to all

ones, all zeros, or a 1010 pattern. Both ATM cell and HDLC packet mapping in this mode is bit aligned. The NAD

bit is ignored.

Figure 10-18. Example E3 G.751 Internal Fractional Frame

FAS

384 Payload Bits

384 bits

4 Rows

A N

384 Payload Bits

372 Payload Bits

XXXX

10.5.11.5 E3 G.832 Direct Mapping

For mapping into E3 G.832 frames ATM cells are byte aligned or bit aligned, HDLC packets are always bit aligned.

The ATM cell byte/bit alignment is controlled with the NAD bit in the PORT.CR1 register. The NAD bit is ignored

when HDLC packets are mapped into the E3 G.832 frame.

DS3181/DS3182/DS3183/DS3184

132

Figure 10-19. E3 G.832 Frame

FA1

FA2

59 Byte Payload

Subframe

9 Subframes

59 Byte Payload

58 Byte Payload

10.5.12 Line Interface Modes

The line interface modes can be selected semi-independently of the framing modes using the PORT.CR2.LM[2:0]

control bits. The major blocks controlled are the transmit LIU (TX LIU), receive LIU (RX LIU), jitter attenuator (JA)

and the line encoder/decoder. The line encoder/decoder is used for B3ZS, HDB3 and AMI line interface encoding

modes. The line encoder-decoder block is not used for line encoding or decoding in the UNI mode but the BPV

counter in it can be used to count external pulses on the RNEGn / RCLVn / ROHMn pin. In “OHM” modes, the line

encoder-decoder does not count pulses on the RNEGn / RLCVn / ROHMn pin. The jitter attenuator (JA) can be off

(OFF) or put in either the transmit (TX) or receive (RX) path with the TX LIU or RX LIU. Both TX LIU and RX LIU

can be enabled (ON) or disabled (OFF).

The “Analog Loopback” (ALB) is available when the LIU is enabled or disabled. It is an actual loopback of the

analog positive and negative pulses from the TX LIU to the RX LIU when the LIU is enabled. If the LIU is disabled,

it is a digital loopback of the TLCLK, TPOS, TNEG signals to the RLCLK, RPOS and RNEG signals.

When the line is configured for B3ZS/HDB3/AMI line codes, the line codes are determined by the framing mode

and the TZCDS and RZCDS control the AMI line mode selection bits in the line encoder/decoder blocks. The DS3

and CC52 framing modes select the B3ZS line coding, the E3 framing modes select the HDB3 line codes. See

Table 10-33 for configuration.

DS3181/DS3182/DS3183/DS3184

133

Table 10-33. Line Mode Select Bits LM[2:0]

LINE.TCR.TZSD

AND

LINE.RCR.RZSD

LM[2:0]

(PORT.CR2) LINE CODE LIU JA

0 000 B3ZS/HDB3 OFF OFF

0 001 B3ZS/HDB3 ON OFF

0 010 B3ZS/HDB3 ON TX

0 011 B3ZS/HDB3 ON RX

1 000 AMI OFF OFF

1 001 AMI ON OFF

1 010 AMI ON TX

1 011 AMI ON RX

X 1XX UNI OFF OFF

DS3181/DS3182/DS3183/DS3184

134

10.6 UTOPIA/POS-PHY/SPI-3 System Interface

10.6.1 General Description

The UTOPIA/POS-PHY system interface transports ATM cells or HDLC packets between the DS318x and an ATM

or Link Layer device. In UTOPIA mode, the DS318x is connected to an ATM layer device and cells are transported

via a UTOPIA L2 or UTOPIA L3 Bus. In POS-PHY packet mode, the DS318x is connected to a Link Layer device

and the packets are transported via a POS-PHY 2 or a POS-PHY 3 (or SPI-3) Bus. In POS-PHY cell mode, the

DS318x is connected to an ATM layer device and cells are transported via a POS-PHY 2 or a POS-PHY 3 (or SPI-

3) Bus. The system interface supports 8-bit, 16-bit, or 32-bit transfers at a rate of 66MHz or less.

The receive direction removes cell/packet data for each port from the FIFO, and outputs the cell/packet data to the

ATM/Link Layer device via the system interface.

The transmit direction inputs the cell/packet data from the ATM/Link Layer device via the system interface, and

stores the cell/packet data for each port in the FIFO.

See Figure 10-20 for the location of the system interface block in the DS318x devices.

Figure 10-20. System Interface Functional Diagram

DS3/E3

Trans mit

LIU

IEEE P1149.1

JTAG Test

Access Port

Microprocessor

Inte rf ac e

HDLC

FEAC

LLB

DLB

DS3 / E3

Transmit

Formatter

DS3 / E3

Rec eiv e

Framer

Trail

Trac e

Buffer

Tx Cell

Processor Tx

FIFO

System

Interface

Rx Cell

Processor

FIFO

Tx Pac ket

Processor

SLB

Rx Pac ket

Processor

DS3/E3

Rec e iv e

LIU

TAIS

TUA 1

TX FRA C/

PL CP

RX FRA C/

PLCP

Cloc k Rate

Adapter

TX BERT

RX BERT

PLB

ALB

UA 1

GEN

B3ZS/

HDB3

Encoder

B3ZS/

HDB3

Dec oder

10.6.2 Features

• Programmable system interface type – When performing cell mapping/demapping, the system interface can

be programmed as a UTOPIA Level 2 Bus, a UTOPIA Level 3 Bus, a POS-PHY Level 2 Bus, or a POS-PHY

Level 3 (or SPI-3) Bus. When performing packet mapping/demapping, the system interface can be

programmed as a POS-PHY Level 2 Bus or a POS-PHY Level 3 (or SPI-3) Bus.

• Selectable system interface bus width – The data bus can be a 32-bit, 16-bit, or 8-bit bus at operations

speeds up to 66 MHz.

• Supports multiple ports on the system interface – Each line has its own port address for access via the

system interface.

• Supports per-port system loopback – Each port can be placed in system loopback which causes

cells/packets from the transmit FIFO to be looped back to the receive FIFO.

• System interface byte reordering – In 16-bit and 32-bit modes, the received/transmitted order of the bytes

transferred across the system interface is programmable. i.e., the first byte received/transmitted by ATM cell /

packet processing can be transferred in [31:24] ([15:8]) or [7:0].

DS3181/DS3182/DS3183/DS3184

135

10.6.6 System Interface Bus Controller

The Transmit and Receive System Interface Bus Controller can be programmed to operate as a UTOPIA Level 2,

UTOPIA Level 3, POS-PHY Level 2, or POS-PHY Level 3 (or SPI-3) bus controller. It controls the system interface

bus timing and provides a common interface to the Transmit and Receive FIFO for FIFO status polling and

cell/packet data transfer. Normally, the first byte transmitted is transferred across the system interface as the most

significant byte (TDATA[31:24] in 32-bit mode or TDATA[15:8] in 16-bit mode). If byte reordering is enabled, the

first byte transmitted is transferred across the system interface as the least significant byte (TDATA[7:0]).On the

receive side, the first byte received is transferred across the system interface as the most significant byte

(RDATA[31:24] in 32-bit mode or RDATA[15:8] in 16-bit mode). If byte reordering is enabled, the first byte received

is transferred across the system interface as the least significant byte (RDATA[7:0]).

See Figure 10-21, Figure 10-22, Figure 10-23, and Figure 10-24. Byte reordering is ignored in 8-bit mode.

Figure 10-21. Normal Packet Format in 32-Bit Mode

Bit 31 Bit 0

Byte 1 Byte 2 Byte 3 Byte 4 1st Transfer

Byte 5 Byte 6 Byte 7 Byte 8 2nd Transfer

•

Byte 4n-7 Byte 4n-6 Byte 4n-5 Byte 4n-4 (n-1)th Transfer

Byte 4n-3 Byte 4n-2 Byte 4n-1 Byte 4n nth Transfer

Figure 10-22. Normal Packet Format in 16-Bit Mode

Bit 15 Bit 0

Byte 1 Byte 2 1st Transfer

Byte 3 Byte 4 2nd Transfer

•

Byte 2n-3 Byte 2n-2 (n-1)th Transfer

Byte 2n-1 Byte 2n nth Transfer

Figure 10-23. Byte Reordered Packet Format in 32-Bit Mode

Bit 31 Bit 0

Byte 4 Byte 3 Byte 2 Byte 1 1st Transfer

Byte 8 Byte 7 Byte 6 Byte 5 2nd Transfer

•

Byte 4n-4 Byte 4n-5 Byte 4n-6 Byte 4n-7 (n-1)th Transfer

Byte 4n Byte 4n-1 Byte 4n-2 Byte 4n-3 nth Transfer

DS3181/DS3182/DS3183/DS3184

136

Figure 10-24. Byte Reordered Packet Format in 16-Bit Mode

Bit 15 Bit 0

Byte 2 Byte 1 1st Transfer

Byte 4 Byte 3 2nd Transfer

•

Byte 2n-2 Byte 2n-3 (n-1)th Transfer

Byte 2n Byte 2n-1 nth Transfer

10.6.6.4 UTOPIA Level 2, Transmit Side

In UTOPIA Level 2, an ATM layer device pushes cells across the system interface. The ATM layer device polls the

individual ports of the DS318x to determine which ports have space available for a cell, and selects a port for cell

transfer. More than one PHY layer device can be present on a UTOPIA Level 2 bus. Whether or not the HEC byte

is transferred with the cells is programmable.

The Transmit System Interface Bus Controller accepts a transmit clock (TSCLK), transmit address (TADR[4:0]),

transmit enable (TEN), and a transmit data bus consisting of transmit data (TDATA[31:0]), transmit parity (TPRTY),

and transmit start of cell (TSOX). It outputs transmit direct cell available (TDXA) and transmit polled cell available

(TPXA) signals. The transmit data bus is used to transfer cell data whenever one of the ports is selected for cell

data transfer. TSOX is asserted during the first transfer of a cell, cell data is transferred on TDATA, and the data

bus parity is indicated on TPRTY. All signals are sampled or updated using TSCLK. The TDXA and TPXA signals

are used to indicate when the Transmit FIFO has space available for a programmable number of cells. There is a

TDXA for each port in the device. TDXA goes high when the associated port's Transmit FIFO has more space

available than a programmable number of cells. TDXA goes low when the associated port's Transmit FIFO is full

(does not have space for another cell). TPXA reflects the current status of a port's TDXA signal when the port is

polled. The TPXA signal is tri-stated unless one of the ports is being polled for FIFO fill status.

10.6.6.5 UTOPIA Level 3, Transmit Side

In UTOPIA Level 3, the ATM layer device pushes cells across the system interface. The ATM layer device polls the

individual ports of the DS318x to determine which ports have space available for a cell, and selects a port for cell

transfer. Only one PHY layer device can be present on a UTOPIA Level 3 bus. Whether or not the HEC byte is

transferred with the cells is programmable.

The Transmit System Interface Bus Controller accepts a transmit clock (TSCLK), transmit address (TADR[7:0]),

transmit enable (TEN), and a transmit data bus consisting of transmit data (TDATA[31:0]), transmit parity (TPRTY),

and transmit start of cell (TSOX). It outputs transmit direct cell available (TDXA) and transmit polled cell available

(TPXA) signals. The transmit data bus is used to transfer cell data whenever one of the ports is selected for cell

data transfer. TSOX is asserted during the first transfer of a cell, cell data is transferred on TDATA, and the data

bus parity is indicated on TPRTY. All signals are sampled or updated using TSCLK. The TDXA and TPXA signals

are used to indicate when the Transmit FIFO has space available for a programmable number of cells.

There is a TDXA for each port in the device. TDXA goes high when the associated port's Transmit FIFO has more

space available than a programmable number of cells. TDXA goes low when the associated port's Transmit FIFO

is full (does not have space for another cell). TPXA reflects the current status of a port's TDXA signal when the port

is polled. The TPXA signal is always driven.

10.6.6.6 UTOPIA Level 2, Receive Side

In UTOPIA Level 2, the ATM layer device pulls cells across the system interface. The ATM layer device polls the

individual ports to determine which ports have cells available, and selects a port for cell transfer. More than one

PHY layer device can be present on a UTOPIA Level 2 bus. Whether or not the HEC byte is transferred with the

cells is programmable.

The Receive System Interface Bus Controller accepts a receive clock (RSCLK), receive address (RADR[4:0]), and

receive enable (REN). It outputs a receive data bus consisting of receive data (RDATA[31:0]), receive parity

(RPRTY), and receive start of cell (RSOX), as well as, receive direct cell available (RDXA) and receive polled cell

DS3181/DS3182/DS3183/DS3184

137

available (RPXA) signals. The receive bus is used to transfer cell data whenever one of the ports is selected for cell

data transfer. RSOX is asserted during the first transfer of a cell, cell data is transferred on RDATA, and the data

bus parity is indicated on RPRTY. All signals are sampled or updated using RSCLK. The data bus is tri-stated

unless REN is asserted (low) and one of the ports is selected for data transfer. The RDXA and RPXA signals are

used to indicate when the Receive FIFO has a programmable number of cells available for transfer. There is an

RDXA for each port in the device. RDXA goes high when the associated port's Receive FIFO contains more than a

programmable number of cells. RDXA goes low when the associated port's Receive FIFO is empty (does not

contain any cells). RPXA reflects the current status of a port's RDXA signal when the port is polled. The RPXA

signal is tri-stated unless one of the ports is being polled for FIFO fill status.

10.6.6.2 UTOPIA Level 3, Receive Side

In UTOPIA Level 3, the ATM layer device pulls cells across the system interface. The ATM layer device polls the

individual ports to determine which ports have cells available, and selects a port for cell transfer. Only one PHY

layer device can be present on a UTOPIA Level 3 bus. Whether or not the HEC byte is transferred with the cells is

programmable.

The Receive System Interface Bus Controller accepts a receive clock (RSCLK), receive address (RADR[7:0]), and

receive enable (REN). It outputs a receive data bus consisting of receive data (RDATA[31:0]), receive parity

(RPRTY), and receive start of cell (RSOX), as well as, receive direct cell available (RDXA) and receive polled cell

available (RPXA) signals. The receive data bus is used to transfer cell data whenever one of the ports is selected

for cell data transfer. RSOX is asserted during the first transfer of a cell, cell data is transferred on RDATA, and the

data bus parity is indicated on RPRTY. All signals are sampled or updated using RSCLK. The data bus is always

driven. The RDXA and RPXA signals are used to indicate when the Receive FIFO has a programmable number of

cells available for transfer. There is an RDXA for each port in the device. RDXA goes high when the associated

port's Receive FIFO contains more than a programmable number of cells. RDXA goes low when the associated

port's Receive FIFO is empty (does not contain any cell ends). RPXA reflects the current status of a port's RDXA

signal when the port is polled. The RPXA signal is always driven.

10.6.6.3 POS-PHY Level 2, Transmit Side

In POS-PHY Level 2, the Link layer device pushes packets across the system interface. The Link layer device

polls the individual ports of the DS318x to determine which ports have space available for packet data, and selects

a port for packet data transfer. More than one PHY layer device can be present on a POS-PHY Level 2 bus.

The Transmit System Interface Bus Controller accepts a transmit clock (TSCLK), transmit address (TADR[4:0]),

transmit enable (TEN), and a transmit data bus consisting of transmit data (TDATA[31:0]), transmit parity (TPRTY),

transmit start of packet (TSOX), transmit end of packet (TEOP), transmit error (TERR), and transmit modulus

(TMOD[1:0]). It outputs transmit direct packet available (TDXA), transmit polled packet available (TPXA), and

transmit selected packet available (TSPA) signals. The transmit data bus is used to transfer packet data whenever

one of the ports is selected for packet data transfer. TSOX is asserted during the first transfer of a packet, TEOP is

asserted during the last transfer of a packet, TERR is asserted when a packet has an error, TMOD indicates the

number of bytes transferred on TDATA during the last transfer of a packet, packet data is transferred on TDATA,

and the data bus parity is indicated on TPRTY. All signals are sampled and updated using TSCLK. The TDXA,

TPXA, and TSPA signals are used to indicate when the Transmit FIFO has space available for a programmable

number of bytes. There is a TDXA for each port in the device. TDXA goes high when the associated port's

Transmit FIFO has space available for more than a programmable number of bytes. TDXA goes low when the

associated port's Transmit FIFO is full. TPXA reflects the current status of a port's TDXA signal when the system

interface is in polled mode. TSPA reflects the current status of a port's TDXA signal when the port is selected. The

TSPA signal is tri-stated unless TEN is asserted (low) and one of the ports is selected for packet data transfer. The

TPXA signal is tri-stated unless one of the ports is being polled for FIFO fill status.

10.6.6.4 POS-PHY Level 3 (or SPI-3), Transmit Side

In POS-PHY Level 3 (or SPI-3), the Link layer device pushes packets across the system interface. The Link layer

device polls the individual ports of the DS318x to determine which ports have space available for packet data, and

selects a port for packet data transfer. Only one PHY layer device can be present on a POS-PHY Level 3 (or SPI-

3) bus.

The Transmit System Interface Bus Controller accepts a transmit clock (TSCLK), transmit enable (TEN), and a

transmit data bus consisting of transmit data (TDATA[31:0]), transmit parity (TPRTY), transmit start of packet

(TSOX), transmit end of packet (TEOP), transmit error (TERR), transmit start of transfer (TSX), and transmit

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modulus (TMOD[1:0]). It outputs transmit direct packet available (TDXA), transmit polled packet available (TPXA),

and transmit selected packet available (TSPA) signals. The transmit bus is used to transfer packet data whenever

one of the ports is selected for packet data transfer. TSOX is asserted during the first transfer of a packet, TEOP is

asserted during the last transfer of a packet, TERR is asserted when a packet has an error, TMOD indicates the

number of bytes transferred on TDATA during the last transfer of a packet, TSX is asserted when the selected

FIFO's port address has been placed on TDATA, packet data is transferred on TDATA, and the data bus parity is

indicated on TPRTY. All signals are sampled and updated using TSCLK. The TDXA, TPXA, and TSPA signals are

used to indicate when the Transmit FIFO has space available for a programmable number of bytes. There is a

TDXA for each port in the device. TDXA goes high when the associated port's Transmit FIFO has space available

for more than a programmable number of bytes. TDXA goes low when the associated port's Transmit FIFO is full.

TPXA reflects the current status of a port's TDXA signal when the port is polled. TSPA reflects the current status of

a port's TDXA signal when the port is selected. The TPXA and TSPA signals are always driven.

10.6.6.5 POS-PHY Level 2, Receive Side

In POS-PHY Level 2, the Link layer device pulls packets across the system interface. The Link layer device polls

the individual ports to determine which ports have packet data available, and selects a port for packet data transfer.

More than one PHY layer device can be present on a POS-PHY Level 2 bus.

The Receive System Interface Bus Controller accepts a receive clock (RSCLK), receive address (RADR[4:0]), and

receive enable (REN). It outputs a receive data bus consisting of receive data (RDATA[31:0]), receive parity

(RPRTY), receive start of packet (RSOX), receive end of packet (REOP), receive error (RERR), receive data valid

(RVAL), and receive modulus (RMOD[1:0]), as well as, a receive direct packet available (RDXA) signal and a

receive polled packet available (RPXA) signal. The receive data bus is used to transfer packet data whenever one

of the ports is selected for packet data transfer. RSOX is asserted during the first transfer of a packet, REOP is

asserted during the last transfer of a packet, RERR is asserted when a packet has an error, RMOD indicates the

number of bytes transferred on RDATA during the last transfer of a packet, RVAL is asserted when the receive

data bus is valid, RDATA transfers packet data, and RPRTY indicates the data bus parity. All signals are sampled

and updated using RSCLK. The RDXA and RPXA signals are used to indicate when the Receive FIFO has a

programmable number of bytes or an end of packet available for transfer. There is an RDXA for each port in the

device. RDXA goes high when the associated port's Receive FIFO contains more than a programmable number of

bytes or an end of packet. RDXA goes low when the associated port's Receive FIFO is empty. RPXA reflects the

current status of a port's RDXA signal when the port is polled. The data bus is tri-stated unless REN is asserted

(low) and one of the ports is selected for packet data transfer. The RPXA signal is tri-stated unless one of the ports

is being polled for FIFO fill status.

10.6.6.6 POS-PHY Level 3 (or SPI-3), Receive Side

In POS-PHY Level 3, the DS318x pushes packets across the system interface. The DS318x selects a port for

packet data transfer when it has packet data available. Only one PHY layer device can be present on a POS-PHY

Level 3 (or SPI-3) bus.

The Receive System Interface Bus Controller accepts a receive clock (RSCLK) and receive enable (REN). It

outputs a receive data bus consisting of receive data (RDATA[31:0]), receive parity (RPRTY), receive start of

packet (RSOX), receive end of packet (REOP), receive error (RERR), receive data valid (RVAL), receive start of

transfer (RSX), and receive modulus (RMOD[1:0]). The receive data bus is used to transfer packet data whenever

one of the ports has packet data available for transfer. RSOX is asserted during the first transfer of a packet, REOP

is asserted during the last transfer of a packet, RERR is asserted when a packet has an error, RMOD indicates the

number of bytes transferred on RDATA during the last transfer of a packet, RSX is asserted when the Link layer

port address has been placed on RDATA, RVAL is asserted when the receive data bus is valid, RDATA transfers

packet data, and RPRTY indicates the data bus parity. All signals are sampled and updated using RSCLK. The

data bus is always driven.

In POS-PHY Level 3 (or SPI-3) the Receive System Interface Bus Controller determines which port to transfer data

from using a round-robin arbitration scheme (the ports are checked one after another in numerical order according

to their line number x (R[x]DT[1:8]). A transfer is initiated from a port when it is not almost empty (contains more

data than the almost empty level or contains an end of packet). Transfer from a port is terminated when the

maximum burst length has been transferred, the FIFO is emptied, or an end of packet is transferred while the

Receive FIFO is almost empty (contains the same or less data than the almost empty level and does not contain an

end of packet). When a transfer is terminated, a transfer is initiated from the next available port that is not almost

empty. At the end of a packet or between a transfer from one port and the transfer from the next port, RVAL will go

low for a programmable number of clock cycles (0-7) to allow the POS-PHY master to halt data transfer. At the end

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139

of a packet, data transfer will continue from the same port if the port is not almost empty. When the maximum burst

length has been transferred, data transfer will continue from the same port if no other port has data available, and

the port is not almost empty. The maximum burst length is programmable (8 – 256 bytes in four byte increments),

or can be disabled.

10.7 ATM Cell/HDLC Packet Processing

10.7.1 General Description

The ATM cell/packet processing demaps the ATM cells or HDLC packets from the receive data stream and maps

ATM cells or HDLC packets into the transmit data stream. ATM cell / packet processing supports any framed or

unframed bit synchronous or byte synchronous (octet aligned) data stream with a bit or byte rate of 52 MHz or less.

The receive direction extracts the payload from physical data stream, performs cell/packet processing on the

individual lines, and stores the cell/packet data from each line in the FIFO.

The transmit direction removes the cell/packet data for each line from the FIFO, performs cell/packet processing for

each individual line and inserts the payload into the physical data stream.

See Figure 10-25 for the location of the Cell/Packet processing block in the DS318x devices.

Figure 10-25. ATM Cell/HDLC Packet Functional Diagram

DS3/E3

Trans mit

LIU

IEEE P1149.1

JTAG Test

Access Port

Microprocessor

Inte rf ac e

HDLC

FEAC

LLB

DLB

DS3 / E3

Transmit

Formatter

DS3 / E3

Rec eiv e

Framer

Trail

Trac e

Buffer

Tx Cell

Processor Tx

FIFO

System

Interface

Rx Cell

Processor

FIFO

Tx Pac ket

Processor

SLB

Rx Pac ket

Processor

DS3/E3

Rec e iv e

LIU

TAIS

TUA 1

TX FRA C/

PL CP

RX FRA C/

PLCP

Cloc k Rate

Adapter

TX BERT

RX BERT

PLB

ALB

UA 1

GEN

B3ZS/

HDB3

Encoder

B3ZS/

HDB3

Dec oder

10.7.2 Features

10.7.2.1 General

• Up to 4 data lines(ports) each with a bit or byte rate of 0-52 MHz

• Supports bit or byte wide, framed or unframed data lines – Each port is programmable as bit synchronous

or octet aligned, the data stream can be framed or unframed, and the clock can be continuous or gapped.

• Bit reordering – The received/transmitted order of the bits as transferred across the system interface is

programmable on a per-port basis. That is, in bit synchronous mode, the first bit received/transmitted by ATM

cell/packet processing can be transferred in bit position 7 (31, 23, 15, or 7) or bit position 0 (24, 16, 8, or 0). In

octet aligned mode, the bit received/transmitted by ATM cell/packet processing in bit position 7 can be

transferred in bit position 7 (31, 23, 15, or 7) or bit position 0 (24, 16, 8, or 0).

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10.7.2.2 ATM Cell Processor

• Programmable HEC insertion and extraction – The transmit side can be programmed to accept cells from

the system interface that do or do not contain a HEC byte. If cells are transferred without a HEC byte, the HEC

byte will be computed and inserted. If cells are transferred with a HEC byte, then the transferred HEC byte can

be programmed to be passed through or overwritten with a newly calculated HEC. The receive side can be

programmed to send cells to the system interface that do or don't contain the HEC byte.

• Programmable erred cell insertion – An HEC error mask can be programmed for insertion of single or

multiple errors individually or continuously at a programmable rate.

• Programmable transmit cell synchronization – The transmit data line can be provisioned to be bit

synchronous or octet aligned.

• PLCP or HEC based cell delineation – Cell delineation is determined from the PLCP frame during PLCP

framing modes, and from the HEC during all other ATM modes.

• Programmable header cell pass-through – Receive cell filtering can pass-through only those cells that

matching a programmable header value.

• Selectable idle/unassigned/invalid/programmable header cell padding and filtering – Transmit cell

padding can be programmed for idle cell or programmable header cell padding. The padded cell payload byte

contents are also programmable. Receive cell filtering can be programmed for any combination of idle cell,

unassigned cell, invalid cell, or programmable header cell filtering. Or, all cell filtering can be disabled.

• Optional header error correction – Receive side single bit header error correction can enabled.

• Separate corrected and uncorrected erred cell counts – Separate counts of erred cells containing a

corrected HEC error, and cells containing non-corrected HEC errors are kept.

• Optional HEC uncorrected erred cell filtering – Uncorrected erred cell extraction can be disabled.

• Selectable cell scrambling/descrambling – Cell scrambling and/or descrambling can be disabled. The

scrambling can be a self-synchronous scrambler (x43 + 1) over the payload only, a self-synchronous scrambler

over the entire cell, or a Distributed Sample Scrambler (x31 + x28 + 1).

• Optional HEC calculation coset polynomial addition – The performance of coset polynomial addition during

HEC calculation can be disabled.

10.7.2.3 HDLC Packet Processor

• Programmable FCS insertion and extraction – The transmit side can be programmed to accept packets

from the system interface that do or don't contain FCS bytes. If packets are transferred without FCS bytes, the

FCS will be computed and appended to the packet. If packets are transferred with FCS bytes, then the FCS

can be programmed to be passed through or overwritten with a newly calculated FCS. The receive side can be

programmed to send packets to the system interface that do or don't contain FCS bytes.

• Programmable transmit packet synchronization – The transmit data line can be provisioned to be bit

synchronous or octet aligned.

• Programmable FCS type – The FCS can be programmed to be a 16-bit FCS or a 32-bit FCS.

• Supports FCS error insertion – FCS error insertion can be programmed for insertion of errors individually or

continuously at a programmable rate.

• Supports bit or byte stuffing/destuffing – The bit or byte synchronous (octet aligned) mode determines the

bit or byte stuffing/destuffing.

• Programmable packet size limits – The receive side can be programmed to abort packets over a

programmable maximum size or under a programmable minimum size. The maximum packet size allowed is

65,535 bytes.

• Selectable packet scrambling/descrambling – Packet scrambling and/or descrambling can be disabled.

• Separate FCS erred packet and aborted packet counts – Separate counts of aborted packets, size violation

packets, and FCS erred packets are kept.

• Optional erred packet filtering – Erred packet extraction can be disabled

• Programmable inter-frame fill – The transmit inter-frame fill value is programmable.

10.7.3 Transmit Cell/Packet Processor

The Transmit Cell Processor and Transmit Packet Processor both receive the 32-bit parallel data stream from the

Transmit FIFO, however, only one of the processors will be enabled. Which processor is enabled is determined by

the system interface mode. In UTOPIA mode, the Transmit Cell Processor is enabled. In POS-PHY mode, if the

PORT.CR2.PMCPE bit is low, the Transmit Packet Processor is enabled. If the PORT.CR2.PMCPE bit

(PORT.CR2) is high, the Transmit Cell Processor is enabled.

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10.7.4 Receive Cell/Packet Processor

The Receive Cell Processor and Receive Packet Processor both receive the incoming data stream from the

Receive Framer (minus all overhead and stuff data), however, only one of the processors will be enabled. The

other will be disabled. Which processor is enabled is determined by the system interface mode. In UTOPIA mode,

the Receive Cell Processor is enabled. In POS-PHY mode, if the PORT.CR2.PMCPE bit is low, the Receive

Packet Processor is enabled. If the PORT.CR2.PMCPE bit is high, the Receive Cell Processor is enabled.

The bits in a byte are received MSB first, LSB last. When they are output serially, they are output MSB first, LSB

last. The bits in a byte in an incoming signal are numbered in the order they are received , 1 (MSB) to 8 (LSB).

However, when a byte is stored in a register, the MSB is stored in the highest numbered bit (7], and the LSB is

stored in the lowest numbered bit (0). This is to differentiate between a byte in a register and the corresponding

byte in a signal.

10.7.5 Cell Processor

10.7.5.1 Transmit Cell Processor

The Transmit Cell Processor accepts data from the Transmit FIFO and performs bit reordering, cell padding, HEC

processing, cell error insertion, and cell scrambling. The data output from the Transmit Cell Processor can be either

a serial data stream (bit synchronous mode) or an 8-bit parallel data stream (octet-aligned mode). Cell processing

can be disabled (clear-channel enable). Disabling cell processing disables cell padding, HEC processing, and cell

error insertion. Only bit reordering and cell scrambling are not disabled.

When cell processing is disabled, data is continually read out of the Transmit FIFO. When the Transmit FIFO is

empty, the output data stream is padded with FFh until the Transmit FIFO contains more data than the "almost

empty" level.

The 32-bit data words read from the Transmit FIFO are multiplexed into an 8-bit parallel data stream and passed

on to bit reordering.

Bit reordering changes the bit order of each byte. If bit reordering is enabled, the incoming 8-bit data stream

DT[7:0] with DT[7] being the MSB and DT[0] being the LSB is rearranged so that the MSB is in DT[0] and the LSB

is in DT[7] of the outgoing data stream DT[7:0]. In bit synchronous mode, DT[7] is the first bit transmitted. If cell

processing is disabled the data stream is passed on to cell scrambling, bypassing cell padding, HEC processing,

and cell error insertion.

Cell padding inserts fill cells. After a cell end, fill cells are inserted into the data stream if the Transmit FIFO does

not contain a complete cell. The fill cell type and fill cell payload value are programmable. The resulting data

stream is passed on to HEC processing. If cell processing is disabled, cell padding will not be performed.

HEC processing calculates a HEC and inserts it into the cell. HEC calculation is a CRC-8 calculation over the four

header bytes. The polynomial used is x8 + x2 + x + 1. The coset polynomial, x6 + x4 + x2 + 1, is added (modulo 2) to

the residue. The calculated HEC is then inserted into the byte immediately following the header. HEC coset

polynomial addition is programmable. If the cell received from the Transmit FIFO contains a HEC byte, the received

HEC byte can be passed through or overwritten with the calculated HEC byte. HEC byte pass through is

programmable. If the cell received from the Transmit FIFO does not contain a HEC byte, the calculated HEC byte

is inserted into the cell. If cell processing is disabled, HEC processing will not be performed.

Cell error insertion inserts errors into the HEC byte. The HEC bits to be errored are programmable. Error insertion

can be controlled by a register or by the manual error insertion input (TMEI). The error insertion initiation type

(register or input) is programmable. If a register controls error insertion, the number and frequency of the errors are

programmable. If cell processing is disabled, cell error insertion will not be performed.

Cell scrambling can scramble the 48-byte cell payload, scramble the entire cell data stream, or scramble the data

stream with a Distributed Sample Scrambler (DSS). If the payload or the entire data stream is scrambled, a self-

synchronous scrambler with a generation polynomial of x43 + 1 is used. For payload scrambling, the scrambler

scrambles the 48-byte payload, and does not scramble the four header or the HEC bytes. For a DSS scrambled

data stream, a distributed sample scrambler with a generation polynomial of x31 + x28 + 1 is used for scrambling.

The transmit DSS scrambler scrambles the 48-byte payload and the four byte header. Scrambles the first HEC bit

(HEC[1]) with the first transmit DSS scrambler sample (the transmit DSS scrambler bit from 211 bits earlier),

scrambles the second HEC bit (HEC[2]) with the second transmit DSS scrambler sample (the current transmit DSS

scrambler bit), and. Does not scramble the remaining HEC bits (HEC[3:8]). DSS scrambling can only be performed

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in bit synchronous mode. Cell scrambling is programmable (payload, entire data stream, or DSS). If cell processing

is disabled, the entire data stream will be scrambled whenever scrambling is enabled

Once all cell processing has been completed, in bit synchronous mode, the 8-bit parallel data stream is multiplexed

into a serial data stream and passed on. In octet aligned mode, the 8-bit parallel data stream is passed on.

10.7.5.2 Receive Cell Processor

The Receive Cell Processor performs cell descrambling, cell delineation, cell filtering, header pattern comparison,

OCD detection, HEC error monitoring, HEC byte filtering, and bit reordering. The data coming in can be either a

serial data stream (bit synchronous mode) or an 8-bit parallel data stream (octet aligned mode). The type of data

stream received affects cell descrambling and cell delineation, however, it does not affect OCD detection, HEC

error monitoring, cell filtering, header pattern comparison, HEC byte filtering, or bit reordering. Cell processing can

be disabled (clear-channel enable). Disabling cell processing disables cell delineation, OCD detection, cell filtering,

header pattern comparison, HEC error monitoring, and HEC byte filtering. Only cell descrambling and bit reordering

are not disabled.

Cell descrambling can descramble the 48-byte cell payload, descramble the entire cell data stream, or descramble

a data stream scrambled by a Distributed Sample Scrambler (DSS). If the payload or the entire data stream is

descrambled, a self-synchronous scrambler with a generation polynomial of x43 + 1 is used for descrambling.

Payload descrambling descrambles the 48-byte payload, and does not descramble the four header bytes or the

HEC byte. For a DSS scrambled data stream, a distributed sample scrambler with a generation polynomial of x31 +

x28 + 1 is used for descrambling. The receive DSS scrambler is synchronized to the transmit DSS scrambler by

DSS scrambler synchronization. DSS descrambling can only be performed in bit synchronous mode. Cell

descrambling is programmable (payload, entire data stream, or DSS). In bit synchronous mode, descrambling is

performed one bit at a time, and the serial data stream is demultiplexed in to an 8-bit data stream before being

passed on. In octet aligned mode, descrambling is performed 8-bits at a time, and only payload or entire data

stream descrambling can be performed. When cell processing is disabled, the entire data stream will be

descrambled if descrambling is enabled.

DSS Scrambler Synchronization synchronizes the receive DSS scrambler with the transmit DSS scrambler used to

scramble the incoming data stream. The DSS Scrambler Synchronization state machine has three states:

"Acquisition", "Verification", and "Steady State". The "Acquisition" state adds the transmit DSS scrambler samples

from 16 incoming cells into the receive DSS scrambler (32 samples total). The samples are derived from the two

MSBs (HEC[1:2]) of the incoming HEC byte. Each time the samples in a cell are loaded into the receive DSS

scrambler, the confidence counter is incremented. When the confidence counter reaches 16, DSS scrambler

synchronization transitions to the “Verification” state. The "Verification" state verifies the samples in the incoming

cells by comparing the samples from the cell with the corresponding receive DSS scrambler bits. Each time both

samples from a cell match the corresponding receive DSS scrambler bits, the confidence counter is incremented.

Each time one of the samples from a cell does not match the corresponding receive DSS scrambler bit, the

confidence counter is decremented if the confidence counter reaches 24, DSS scrambler synchronization

transitions to the “Steady State” state. If the confidence counter reaches 8, DSS scrambler synchronization

transitions to the “Acquisition” state. The "Steady State" state continues to verify the samples in the incoming cells.

Each time both samples from a cell match the corresponding receive DSS scrambler bits, the confidence counter is

incremented (maximum count = 24). Each time one of the samples from a cell does not match the corresponding

receive DSS scrambler bit, the confidence counter is decremented. If the confidence counter reaches 16, DSS

scrambler synchronization transitions to the “Acquisition” state. The DSS scrambler synchronization state diagram

is shown in Figure 10-26. DSS scrambler synchronization starts in the “Acquisition” state. Note: All ATM cells are

discarded during the “Acquisition” and “Verification” states.

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143

Figure 10-26. Receive DSS Scrambler Synchronization State Diagram

Steady

State

AcquisitionVerification

8 Cells Fail Verification

32 Samples Loaded

8 Cells Pass Verification

8 Cells Fail Verification

If cell processing is disabled, a cell boundary is arbitrarily chosen, and the data is divided into "cells" whose size is

programmable. If HEC transfer is enabled in the receive system interface, the incoming data stream will be divided

into 53-byte "cells". If HEC transfer is disabled in the receive system interface, the data is divided into 52-byte

"cells". These cells are then passed on to bit reordering bypassing cell delineation, OCD detection, cell filtering,

header pattern comparison, HEC error monitoring, and HEC byte filtering.

Cell delineation determines the cell boundary by identifying the header bytes and the HEC byte of a cell, and

detects an out of cell delineation (OCD) condition or a change of cell delineation (COCD). Cell delineation is

performed off-line, and the data path cell boundary is only updated by cell delineation if an OCD condition is

present. Performing cell delineation off-line results in fewer cells being discarded when the cell boundary changes.

If DSS scrambling is enabled (bit synchronous mode only), only the six least significant bits (LSBs) of the HEC

(HEC[3:8]) are used for cell delineation, as the two most significant bits (MSBs) are scrambled. An OCD condition

is declared if seven consecutive cells are received with incorrect HEC bytes. An OCD condition is terminated if

“Delta” consecutive cells are received with correct HEC bytes, if cell delineation updates the data path cell

boundary, or if the PLCP framer updates the data path cell boundary (PLCP modes only). All ATM cells are

discarded during an OCD condition. A COCD is declared when Cell Delineation or the PLCP framer updates the

data path cell boundary with a cell boundary that is different from the current data path cell boundary .

Cell delineation has three states: "Hunt", "Presync", and "Sync". The "Hunt" state searches for the cell boundary.

Each time slot is checked for an HEC byte (six LSBs of the HEC byte if DSS is enabled). The cell boundary is set

once the header and HEC bytes are identified, and cell delineation transitions to the “Presync” state. The "Presync"

state verifies the cell boundary identified in the “Hunt” state. The HEC is checked in each incoming cell. If “Delta”

cells (including the "Hunt" to "Presync" transition cell) with a correct HEC are received, cell delineation transitions

to the “Sync” state. If a cell with an incorrect HEC is received, cell delineation transitions to the “Hunt” state. The

"Sync" state checks the HEC in each cell. If a cell with a correct HEC is received, cell delineation updates the data

path cell boundary if an OCD condition is present. If a cell with an incorrect HEC is received, cell delineation

transitions to the “Hunt” state. The cell delineation state diagram is shown in Figure 10-27. The cell delineation

process starts in the "Hunt" state. In octet-aligned mode, the HEC check is performed one byte at a time, so up to

53 checks may be needed to find the cell boundary. In bit synchronous mode, the HEC check is performed one bit

at a time, so up to 424 checks may be needed to find the cell boundary. HEC calculation coset polynomial addition

can be disabled. The cell delineation process can be programmed to ignore the first header byte (for DQDB

applications) when calculating the HEC. If cell processing is disabled, cell delineation will not be performed. A

“Delta” of eight is used during the DS3 clear-channel, STS-1 clear-channel, and E3 clear-channel modes. A “Delta”

DS3181/DS3182/DS3183/DS3184

144

of six is used during all other modes including the DS3 Clear-Channel—OHM; STS-1 Clear-Channel—OHM; and

E3 Clear-Channel—OHM modes. In bit synchronous mode, the serial data stream is demultiplexed into an 8-bit

parallel data stream (as determined by the data path cell boundary updated) before being passed on to cell

filtering.

Figure 10-27. Cell Delineation State Diagram

Sync

HuntPresync

Incorrect HEC

Correct HEC

Delta Correct HECs

Incorrect HEC

Cell filtering discards specific cell types. The 8-bit parallel data stream is monitored for idle, unassigned, and invalid

cells. (Cells discarded during cell delineation or DSS descrambling are not monitored for cell filtering.) If cell filtering

is enabled and the indicated cell type is found, the cell is discarded. Idle cell, unassigned cell, and invalid cell

filtering are programmable. Idle cells have a header value of 00000000 00000000 00000000 00000001.

Unassigned cells have a header value of xxxx0000 00000000 00000000 0000xxx0. Where x can be any value.

Invalid cells have a header value of xxxxyyyy yyyy0000 00000000 0000xxxx. Where x can be any value and

yyyyyyyy can be any value other than 00000000. All cells discarded are counted. If cell processing is disabled, cell

filtering will not be performed.

Header pattern comparison checks for a specific pattern in the header, and either discards and counts cells with a

matching header (discard match), discards and counts cells without a matching header (discard no match), counts

cells with a matching header (count match), or counts cells without a matching header (count no match). (Cells

discarded during OCD detection, DSS descrambling, or cell filtering processes are not monitored for header pattern

comparison.) The 8-bit parallel data stream is monitored for cells that have a header that matches the comparison

header. In discard match mode, cells with a matching header are counted and discarded. In discard no match

mode, cells without a matching header are counted and discarded. In count match mode, cells with a matching

header are counted and passed on. In count no match mode, cells without a matching header are counted and

passed on. The comparison header and comparison header pattern mode are programmable. If cell processing is

disabled, header pattern comparison will not be performed.

HEC error monitoring checks the HEC and detects errored and correctable cell headers. (Cells discarded during

OCD detection, DSS descrambling, cell filtering, or header pattern comparisons are not monitored for HEC errors.).

HEC Error Monitoring has two states, the "Correction" and "Detection" states. . In the “Correction” state, cells

received without any header errors (good cells) are passed on. Cells received with a single header error

(correctable cells) are corrected and passed on. The corrected cell count is incremented. Cells received with

multiple errors are considered errored cells. If errored cell extraction is enabled, errored cells are discarded, and

the errored cell count is incremented. If errored cell extraction is disabled, errored cells are passed on. If a cell is

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received with an incorrect HEC, HEC error monitoring transitions to the “Detection” state. In the “Detection” state,

good cells are passed on. Cells received with one or more errors are considered errored cells. If m cells are

received with a correct HEC or the data path cell boundary is updated, HEC error monitoring will transition to the

“Correction” state. The value of m is programmable (1, 2, 4, or 8). The HEC Error Monitoring state diagram is

shown in Figure 10-28. HEC Error Monitoring starts in the “Correction” state. If header error correction is disabled,

HEC error monitoring will remain in the “Detection” state. If cell processing is disabled, HEC error monitoring will

not be performed.

Figure 10-28. HEC Error Monitoring State Diagram

DetectionCorrection

mth good cell

corrected cell

errored cell

cell boundary update

HEC byte filtering discards the HEC byte. If HEC transfer is disabled in the receive system interface, the HEC byte

is extracted from the cell and discarded. The resulting 52-byte cell is then passed on for storage in the Receive

FIFO. If HEC transfer is enabled, the 53-byte cell is passed on for storage in the Receive FIFO. If cell processing is

disabled, HEC byte filtering will not be performed.

Bit reordering changes the bit order of each byte. If bit reordering is enabled, the incoming 8-bit data stream

DT[7:0] with DT[7] being the MSB and DT[0] being the LSB is rearranged so that the MSB is in DT[0] and the LSB

is in DT[7] of the outgoing FIFO data stream DT[7:0]. In bit synchronous mode, DT[7] is the first bit received.

Once all cell processing has been completed, the 8-bit parallel data stream is demultiplexed into a 32-bit parallel

data stream and passed on to the Receive FIFO. Cells are stored in the Receive FIFO in a cell format. regardless

of whether or not they are transferred across a UTOPIA or POS-PHY interface. The cell format for a 53-byte cell

with a 32-bit bus is shown in Figure 10-29. The cell format for a 52-byte cell with a 32-bit bus is shown in Figure

10-30.

Figure 10-29. Cell Format for 53-Byte Cell With 32-Bit Data Bus

Bit 31 Bit 0

Header 1 Header 2 Header 3 Header 4 1st Transfer

HEC 00h 00h 00h 2nd Transfer

Payload 1 Payload 2 Payload 3 Payload 4 3rd Transfer

Payload 5 Payload 6 Payload 7 Payload 8 4th Transfer

•

Payload 41 Payload 42 Payload 43 Payload 44 13th Transfer

Payload 45 Payload 46 Payload 47 Payload 48 14th Transfer

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Figure 10-30. Cell Format for 52-Byte Cell With 32-Bit Data Bus

Bit 31 Bit 0

Header 1 Header 2 Header 3 Header 4 1st Transfer

Payload 1 Payload 2 Payload 3 Payload 4 2nd Transfer

Payload 5 Payload 6 Payload 7 Payload 8 3rd Transfer

•

Payload 41 Payload 42 Payload 43 Payload 44 12th Transfer

Payload 45 Payload 46 Payload 47 Payload 48 13th Transfer

10.7.6 Packet Processor

10.7.6.1 Transmit Packet Processor

The Transmit Packet Processor accepts data from the Transmit FIFO performs bit reordering, FCS processing,

packet error insertion, stuffing, packet abort sequence insertion, inter-frame padding, and packet scrambling. The

data output from the Transmit Packet Processor can be either a serial data stream (bit synchronous mode) or an 8-

bit parallel data stream (octet-aligned mode). The type of data stream output from the Transmit Packet Processor

affects stuffing, abort insertion, inter-octet padding, inter-frame padding, and packet scrambling, however, it does

not affect bit reordering, FCS processing, or packet error insertion. Packet processing can be disabled (clear-

channel enable). Disabling packet processing disables FCS processing, packet error insertion, stuffing, packet

abort sequence insertion, and inter-frame padding. Only bit reordering and packet scrambling are not disabled.

When packet processing is disabled, data is continually read out of the Transmit FIFO. When the Transmit FIFO is

read empty, the output data stream will be padded with FFh until the Transmit FIFO contains more data than the

"almost empty" level. The 32-bit data words read from the Transmit FIFO are multiplexed into an 8-bit parallel data

stream and passed on to bit reordering.

Bit reordering changes the bit order of each byte. If bit reordering is enabled, the incoming 8-bit data stream

DT[7:0] with DT[7] being the MSB and DT[0] being the LSB is rearranged so that the MSB is in DT[0] and the LSB

is in DT[7] of the outgoing data stream DT[7:0]. In bit synchronous mode, DT[7] is the first bit transmitted. If packet

processing is disabled the data stream is passed on to packet scrambling, bypassing FCS processing, packet error

insertion, stuffing, packet abort sequence insertion, and inter-frame padding. If packet processing is disabled in bit

synchronous mode, the serial data stream is demultiplexed in to an 8-bit data stream before being passed on.

FCS processing calculates a FCS and appends it to the packet. FCS calculation is a CRC-16 or CRC-32

calculation over the entire packet. The polynomial used for FCS-16 is x16 + x12 + x5 + 1. The polynomial used for

FCS-32 is x32 + x26 + x23 + x22 + x16 + x12 + x11 + x10 + x8 + x7 + x5 + x4 + x2 + x + 1. The FCS is inverted after

calculation. The FCS type is programmable. If FCS append is enabled, the calculated FCS is appended to the

packet. If FCS append is disabled, the packet is transmitted without a FCS. The FCS append mode is

programmable. If packet processing is disabled, FCS processing is not performed.

Packet error insertion inserts errors into the FCS bytes. A single FCS bit is corrupted in each errored packet. The

FCS bit corrupted is changed from errored packet to errored packet. Error insertion can be controlled by a register

or by the manual error insertion input (TMEI). The error insertion initiation type (register or input) is programmable.

If a register controls error insertion, the number and frequency of the errors are programmable. If FCS append is

disabled, packet error insertion will not be performed. If packet processing is disabled, packet error insertion is not

performed.

Stuffing inserts control data into the packet to prevent packet data from mimicking flags. Stuffing is performed from

the beginning of a packet until the end of a packet. In bit synchronous mode, the 8-bit parallel data stream is

multiplexed into a serial data stream, and bit stuffing is performed. Bit stuffing consists of inserting a '0' directly

following any five contiguous '1's. In octet aligned mode, byte stuffing is performed. Byte stuffing consists of

detecting bytes that mimic flag and escape sequence bytes (7Eh and 7Dh), and replacing the mimic bytes with an

escape sequence (7Dh) followed by the mimic byte exclusive ORed with 20h. If packet processing is disabled,

stuffing is not performed.

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Inter-frame padding inserts start flags, end flags and inter-frame fill between packets. There will be at least one flag

plus a programmable number of additional flags between packets. In octet aligned mode, the inter-frame fill is flags.

In bit synchronous mode, the inter-frame fill can be flags or all 1s followed by a start flag. If the inter-frame fill is all

'1's, the number of '1's between the end and start flags may not be an integer number of bytes, however, there will

be at least 15 consecutive '1's between the end and start flags. The bit synchronous mode inter-frame padding type

is programmable. If packet processing is disabled, inter-frame padding is not performed.

Packet abort insertion inserts a packet abort sequences as necessary. If a packet abort indication is detected, a

packet abort sequence is inserted and inter-frame padding is done until a packet start flag is detected. In bit

synchronous mode, the abort sequence is FFh. In octet aligned mode, the abort sequence is 7D7Eh. If packet

processing is disabled, packet abort insertion is not performed.

The packet scrambler is a x43 + 1 self-synchronous scrambler that scrambles the entire packet data stream. Packet

scrambling is programmable.

Once all packet processing has been completed, in bit synchronous mode, the 8-bit parallel data stream is

multiplexed into a serial data stream and passed on. In octet aligned mode, the 8-bit parallel data stream is passed

on.

10.7.6.2 Receive Packet Processor

The Receive Packet Processor performs packet descrambling, packet delineation, inter-frame fill filtering, packet

abort detection, destuffing, packet size checking, FCS error monitoring, FCS byte extraction, and bit reordering.

The data coming in can be either a serial data stream or an 8-bit parallel data stream, depending on the framing

mode (see Table 10-32 for configuration information). The type of data stream received affects packet

descrambling, packet delineation, inter-frame fill filtering, packet abort detection, and destuffing, however, it does

not affect packet size checking, FCS error monitoring, FCS byte extraction, or bit reordering. Packet processing

can be disabled (clear-channel enable). Disabling packet processing disables packet delineation, inter-frame fill

filtering, packet abort detection, destuffing, packet size checking, FCS error monitoring, and FCS byte extraction.

Only packet descrambling and bit reordering are not disabled.

The packet descrambler is a self-synchronous x43 + 1 descrambler that descrambles the entire packet data stream.

Packet descrambling is programmable. If packet processing is disabled in bit synchronous mode, the serial data

stream is demultiplexed in to an 8-bit data stream before being passed on.

If packet processing is disabled, a packet boundary is arbitrarily chosen, and the data is divided into "packets"

whose size is programmable (maximum packet size setting). These packets are then passed on to bit reordering

bypassing packet delineation, inter-frame fill filtering, packet abort detection, destuffing, packet size checking, FCS

error monitoring, and FCS byte extraction.

Packet delineation determines the packet boundary by identifying a packet start or end flag. Each time slot is

checked for a flag sequence (7Eh). Once a flag is found, it is identified as a start or end flag, and the packet

boundary is set. If packet processing is disabled, packet delineation is not performed.

Inter-frame fill filtering removes the inter-frame fill between packets. When a packet end flag is detected, all data is

discarded until a packet start flag is detected. In bit synchronous mode, the inter-frame fill can be flags or all '1's.

When the interframe fill is all ‘1’s, the number of '1's between the start and end flags does not need to be an integer

number of bytes. In bit synchronous mode when inter-frame fill is flags, there may be only one flag between

packets, or the flags may have a shared zero (011111101111110). In octet aligned mode, the inter-frame fill can

only be flags, and there may be only one flag between packets. If packet processing is disabled, inter-frame fill

filtering is not performed.

Packet abort detection searches for a packet abort sequence. Between a packet start flag and a packet end flag, if

an abort sequence is detected, the packet is marked with an abort indication, the aborted packet count is

incremented, and all subsequent data is discarded until a packet start flag is detected. In bit synchronous mode,

the abort sequence is seven consecutive ones. In octet aligned mode, the abort sequence is 7D7Eh. If packet

processing is disabled, packet abort detection is not performed.

Destuffing removes the extra data inserted to prevent data from mimicking a flag or an abort sequence. In bit

synchronous mode, bit destuffing is performed. Bit destuffing consists of discarding any '0' that directly follows five

contiguous '1's. In octet aligned mode, byte destuffing is performed. Byte destuffing consists of detecting an escape

sequence (7Dh), discarding it and exclusive ORing the next byte with 20h. In bit synchronous mode, after

destuffing is completed, the serial bit stream is demultiplexed into an 8-bit parallel data stream and passed on to

packet size checking. If there is less than eight bits in the last byte, an invalid packet flag is raised, the packet is

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tagged with an abort indication, and the packet size violation count is incremented. In octet aligned mode, after

destuffing is completed, the 8-bit parallel data stream is passed on to packet size checking. If packet processing is

disabled, destuffing is not performed.

Packet size checking checks each packet for a programmable maximum and programmable minimum size. As the

packet data comes in, the total number of bytes is counted. If the packet length is below the minimum size limit, the

packet is marked with an aborted indication, and the packet size violation count is incremented. If the packet length

is above the maximum size limit, the packet is marked with an aborted indication, the packet size violation count is

incremented, and all packet data is discarded until a packet start is received. The minimum and maximum lengths

include the FCS bytes, and are determined after destuffing has occurred. If packet processing is disabled, packet

size checking is not performed.

FCS error monitoring checks the FCS and aborts errored packets. If a FCS error is detected, the FCS errored

packet count is incremented and the packet is marked with an aborted indication. The FCS type (16-bit or 32-bit) is

programmable. If FCS processing or packet processing is disabled, FCS byte extraction is not performed.

FCS byte extraction discards the FCS bytes. If FCS extraction is enabled, the FCS bytes are extracted from the

packet and discarded. If FCS extraction is disabled, the FCS bytes are stored in the receive FIFO with the packet.

If FCS processing or packet processing is disabled, FCS byte extraction is not performed.

Bit reordering changes the bit order of each byte. If bit reordering is enabled, the incoming 8-bit data stream

DT[7:0] with DT[7] being the MSB and DT[0] being the LSB is rearranged so that the MSB is in DT[0] and the LSB

is in DT[7] of the outgoing FIFO data stream DT[7:0]. In bit synchronous mode, DT[7] is the first bit received.

Once all packet processing has been completed, the 8-bit parallel data stream is demultiplexed into a 32-bit parallel

data stream and passed on to the Receive FIFO.

10.7.7 FIFO

10.7.7.1 Transmit FIFO

The Transmit FIFO block contains memory for 64 32-bit data words. The Transmit FIFO separates the transmit

system interface timing from the transmit physical interface timing. The Transmit FIFO functions include filling the

memory, tracking the memory fill level, maintaining the memory read and write pointers, and detecting memory

overflow and underflow conditions. The number of data transfers that can occur after the Transmit FIFO "full"

indication is deasserted is programmable. The Transmit FIFO port address used for selection and polling by the

Transmit System Interface Bus Controller is programmable. In system loopback, the data from the Transmit FIFO is

looped back to the Receive FIFO, and a FIFO empty indication is passed on to the Transmit Cell/Packet Processor.

In cell processing mode, all operations are cell based. The Transmit FIFO is considered empty when it does not

contain any data. The Transmit FIFO is considered "almost empty" when it does not contain a cell. The Transmit

FIFO is considered "almost full" when it does not have space available to store a programmable number of cells.

The Transmit FIFO is considered full when it does not have space available for a complete cell. When the Transmit

FIFO level drops below the “almost full” indication, the TDXA[n] is asserted. The Transmit FIFO accepts cell

transfers from the Transmit System Interface Bus Controller until it is full. If a start of cell is received while full, the

cell is discarded and a FIFO overflow condition is declared. Once a FIFO overflow condition is declared, the

Transmit FIFO will discard cell data until a start of cell is received while the FIFO has more space available than

the "almost full" level. If the Transmit FIFO receives cell data other than a start of cell after a complete cell has

been received, an invalid transfer is declared and all cell data is discarded until a start of cell is received. If a start

of cell is received before a previous cell transfer has been completed, the current cell is discarded and a short

transfer is declared. The new cell is processed normally. If the Transmit Cell Processor attempts a read while the

Transmit FIFO is empty, a FIFO underflow condition is declared. Once a FIFO underflow condition is declared, the

Transmit FIFO data will be discarded until a start of cell is received.

In packet processing mode, all operations are byte based. The Transmit FIFO is considered empty when its

memory does not contain any data. The Transmit FIFO is considered "almost empty" when its memory does not

contain a packet end and there is a programmable number of bytes or less stored in the memory. The Transmit

FIFO is considered "almost full" when its memory has a programmable number of bytes or less available for

storage. When the Transmit FIFO has more bytes available for storage than the “almost full” level the TDXA[n] or

TPXA pin will be asserted to signal to the POS device that it is ready to receive more packet data. The Transmit

FIFO is considered full when it does not have any space available for storage. When the Transmit FIFO is full, the

TDXA[n] pin will be deasserted. The Transmit FIFO accepts data from the Transmit System Interface Bus

Controller until full. If a start of packet or short packet (32-bit data word with a start of packet and end of packet) is

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received while full, the data is discarded and a FIFO overflow condition is declared. If any other packet data is

received while full, the current packet being transferred is marked with an abort indication, and a FIFO overflow

condition is declared. Once a FIFO overflow condition is declared, the Transmit FIFO will discard data until a start

of packet is received while the FIFO has more space available than the "almost full" level. If a packet error (a

transfer with TERR and TEOP asserted) is received from the Transmit System Interface Bus Controller, an aborted

transfer is declared, the data is stored in memory with a packet abort indication, and the Transmit FIFO will discard

data until a start of packet is received. If an end of a packet has been received and the Transmit FIFO receives

packet data other than a start of packet, an invalid transfer is declared, and all packet data is discarded until a start

of packet is received. If a start of packet is received before a previous packet transfer has been completed (an end

of packet was never received), the current packet being transferred is marked with an abort indication and a short

transfer is declared. The new packet is processed normally. If the Transmit Packet Processor attempts a read while

the Transmit FIFO is empty, a FIFO underflow condition is declared. Once a FIFO underflow condition is declared,

the Transmit FIFO data will be discarded until a start of cell is received.

10.7.7.2 Receive FIFO

The Receive FIFO block contains memory for 64 32-bit data words. The Receive FIFO separates the receive

system interface timing from the receive physical interface timing. The Receive FIFO functions include filling the

memory, tracking the memory fill level, maintaining the memory read and write pointers, and detecting memory

overflow and underflow conditions. The Receive FIFO port address used for selection and polling by the Receive

System Interface Bus Controller is programmable. In system loopback, data is looped back from the Transmit FIFO

to the Receive FIFO.

In cell processing mode, all operations are cell based. The Receive FIFO is considered empty unless it contains a

cell. The Receive FIFO is considered "almost empty" when it contains a programmable number of cells or less.

When the Receive FIFO level has more data available for transfer than the “almost empty” level, the RDXA[n] pin is

asserted. The Receive FIFO is considered "almost full" when it does not have space available to store a complete

cell. The Receive FIFO is considered full when it does not have any space available. The Receive FIFO accepts

cell data from the Receive Cell Processor until full. If cell data is received while the FIFO is full, the cell is discarded

and a FIFO overflow condition is declared. Once a FIFO overflow condition is declared, the Receive FIFO will

discard cell data until a cell start is received while the FIFO has space available to store a complete cell. If the

Receive System Interface Bus Controller attempts a read while the FIFO is empty, the read is ignored.

In packet processing mode, all operations are 32-bit word based. The Receive FIFO is considered empty when it

does not contain any data. The Receive FIFO is considered "almost empty" when its memory does not contain a

packet end and there is a programmable number of words or less stored in the memory. When the Receive FIFO

has more bytes available for transfer than the “almost empty” level or has an end of packet, the RDXA[n] pin is

asserted (POS-PHY Level 2). The Receive FIFO is considered "almost full" when its memory has a programmable

number of words or less available for storage. The Receive FIFO is considered full when it does not have any

space available for storage. The Receive FIFO accepts data from the Receive Packet Processor until full. If a

packet start or short packet is received while full, the data is discarded and a FIFO overflow condition is declared. If

any other packet data (packet end or middle) is received while full, the current packet being received is marked

with an abort indication, and a memory overflow condition is declared. Once a memory overflow condition is

declared, the Receive FIFO will discard data until a packet start is received while the FIFO has more space

available than the "almost full" level. If the Receive System Interface Bus Controller attempts a read while the FIFO

is empty, the read is ignored.

10.7.8 System Loopback

There is a system loopback available in the ATM/HDLC Mapper. The loopback can be performed on a per-port

basis. When a port is placed in system loopback, the data coming in from the System Interface is looped back from

the Transmit FIFO to the Receive FIFO, a FIFO empty indication is passed on to the Transmit Cell/Packet

Processor, and all data coming from the Receive Cell/Packet Processor is discarded. The maximum throughput of

a single port is limited to half of the Receive System Interface bandwidth in 32-bit mode. A loss of data may occur if

the Receive System Interface clock (RSCLK) has a frequency that is greater than one and one half times the

Transmit System Interface clock (TSCLK).

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10.8 DS3/E3 PLCP Framer

10.8.1 General Description

The PLCP Framer demaps the ATM cells from the DS3/E3 PLCP data stream in the receive direction and maps

ATM cells into the DS3/E3 PLCP data stream in the transmit direction.

The receive direction extracts the PLCP frame from the DS3/E3 data stream, performs frame processing, and

outputs the cells with a beginning of cell indication via the payload interface.

The transmit direction inputs the cells via the payload interface, generates the frame, and inserts the PLCP frame

into the DS3/E3 data stream. See Figure 10-31 for the location of the PLCP framer in the DS318x devices.

Figure 10-31. PLCP Framer Functional Diagram

DS3/E3

Trans mit

LIU

IEEE P1149.1

JTAG Test

Access Port

Microprocessor

Inte rf ac e

HDLC

FEAC

LLB

DLB

DS3 / E3

Transmit

Formatter

DS3 / E3

Rec eiv e

Framer

Trail

Trac e

Buffer

Tx Cell

Processor Tx

FIFO

System

Interface

Rx Cell

Processor

FIFO

Tx Pac ket

Processor

SLB

Rx Pac ket

Processor

DS3/E3

Rec e iv e

LIU

TAIS

TUA 1

TX FRA C/

PL CP

RX FRA C/

PLCP

Cloc k Rate

Adapter

TX BERT

RX BERT

PLB

ALB

UA 1

GEN

B3ZS/

HDB3

Encoder

B3ZS/

HDB3

Dec oder

10.8.2 Features

• DS3 PLCP frame ATM cell extraction and insertion – Accepts a DS3 payload and performs DS3 PLCP

overhead termination and generation.

• E3 PLCP frame ATM cell extraction and insertion – Accepts a G.751 E3 payload and performs E3 PLCP

overhead termination and generation.

• Generates and detects alarms and errors – In the receive direction, PLCP alarm conditions (OOF, LOF,

COFA, and RAI) and errors (framing, parity, and REI) are detected on the receive signal. In the transmit

direction, alarm conditions and errors can be inserted into the transmit data stream.

• Receive overhead extraction port – Extracts all PLCP overhead from the receive signal and outputs it on a

serial interface (RPOH pin).

• Externally controlled transmit overhead insertion port – Can insert all PLCP overhead into the transmit

signal from a serial interface. Overhead insertion is fully controlled via the serial overhead interface (TPOH,

TPOHEN, TPOHSOF, TPOHCLK).

• Full Duplex serial HDLC channel extraction/insertion – An HDLC channel can be extracted from and/or

inserted into the F1, M1, M2, or M1 and M2 bytes in the PLCP data stream.

• Full Duplex serial Trail Trace extraction/insertion – A trail trace can be extracted from and/or inserted into

the F1 byte in the PLCP data stream.

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10.8.3 Transmit PLCP Frame Processor

The Transmit PLCP Frame Processor receives the ATM cells from the ATM/Packet Processor performs trailer

generation, framing generation, error insertion, and overhead insertion.

The bits in a byte are transmitted MSB first, LSB last. When they are input serially, they are input in the order they

are to be transmitted. The bits in a byte in an outgoing signal are numbered in the order they are transmitted, 1

(MSB) to 8 (LSB). However, when a byte is stored in a register, the MSB is stored in the highest numbered bit (7),

and the LSB is stored in the lowest numbered bit (0). This is to differentiate between a byte in a register and the

corresponding byte in a signal.

10.8.4 Receive PLCP Frame Processor

The Receive PLCP Frame Processor accepts the data stream from the DS3/E3 Framer and extracts the entire

DS3/E3 overhead and processes only the PLCP frame data.

The bits in a byte are received MSB first, LSB last. When they are output serially, they are output in the order they

are received. The bits in a byte in an incoming signal are numbered in the order they are received, 1 (MSB) to 8

(LSB). However, when a byte is stored in a register, the MSB is stored in the highest numbered bit (7), and the LSB

is stored in the lowest numbered bit (0). This is to differentiate between a byte in a register and the corresponding

byte in a signal.

Some bits, bit groups, or bytes (data) are integrated. Integration requires the data to have a new value for five

consecutive occurrences before the new data value will be stored in the data register. Integrated data may have an

associated unstable indication. Integrated data is considered unstable if for eight consecutive occurrences the

received data value does not match the currently stored (integrated) data value or the previously received data

value.

10.8.5 Transmit DS3 PLCP Frame Processor

The DS3 PLCP frame format is shown in Figure 10-32. A1 and A2 are the sub-frame alignment bytes that have a

value of F6h and 28h respectively. P11 – P0 are the Path Overhead Identifier (POI) bytes that indicate the path

overhead byte contained in the current sub-frame. Z6 – Z1 are growth bytes reserved for future use. F1 is the Path

User Channel byte allocated for user communications purposes (This byte is undefined in ATM). B1 is the Bit

Interleaved Parity-8 (BIP-8) byte used for PLCP path error monitoring. G1 is the PLCP Path Status Byte (See

Figure 10-33) used for far-end path status and performance monitoring (bits 6 – 8 are undefined in ATM). M2 and

M1 are the DQDB Layer Management Information bytes used for DQDB layer management communications

(These bytes are undefined in ATM). C1 is the Cycle/Stuff Counter byte used as for PLCP superframe alignment

and stuff indication.

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Figure 10-32. DS3 PLCP Frame Format

13 or 14

Nibbles

Subframes

A1 A2

Subframe (57 Bytes)

A1 A2

P11

P10

First Cell

Second Cell

Third Cell

Fourth Cell

Fifth Cell

Sixth Cell

Seventh Cell

Eight Cell

Ninth Cell

Tenth Cell

Eleventh Cell

Twelfth Cell Trailer

Figure 10-33. DS3 PLCP G1 Byte Format

REI - Remote Error Indicator

RAI - Remote Alarm Indicator

LSS - Link Status Signal

REI REI REI REI RAI LSS LSS LSS

MSB

LSB

10.8.5.1 Transmit DS3 PLCP Trailer Generation

DS3 PLCP trailer generation inserts the DS3 PLCP frame trailer immediately following sub-frame 0 (POI equals

01h), and generates the C1 byte. The trailer size is determined by the DS3 PLCP superframe counter, and the 8

kHz reference clock. The DS3 PLCP superframe counter is a free running counter that indicates the current frame

of the three-frame superframe. In the first frame of the superframe, the trailer size is set to 13, and C1 is set to FFh.

In the second frame of the superframe, the trailer size is set to 14, and C1 is set to 00h. In the third frame of the

superframe, the trailer size is variable. The trailer size is controlled by the 8kHz reference clock. If the indicated

trailer size is 13, C1 is set to 66h. If the indicated trailer size is 14, C1 is set to 99h, and the indicated number of

nibbles (13 or 14) are added after sub-frame 0. The trailer nibbles are all set to 1100.

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10.8.5.2 Transmit DS3 PLCP Frame Generation

DS3 PLCP frame generator receives the incoming PLCP payload data stream, and overwrites all of the overhead

byte locations.

The first two bytes of each sub-frame are overwritten with the frame alignment bytes A1 and A2, which have a

value of F6h and 28h respectively.

The third byte of sub-frame # is overwritten with POI byte # (P#). The value of P# is 00####0Pb (0 = a logic zero,

#### = the hexadecimal value of #, and P = the odd parity bit).

The fourth byte of sub-frames #11 – 6 are overwritten with the Z6 – Z1 bytes from the corresponding registers.

The fourth byte of sub-frame 5 is overwritten with the F1 byte from the corresponding register, the trail trace byte

input from the transmit trail trace controller, or the HDLC Overhead Processor. The F1 byte source is

programmable PLCP.TCR.TF1C[1:0] (trail trace controller, HDLC, or register).

The fourth byte of sub-frame 4 is overwritten with the calculated BIP-8. The BIP-8 is calculated over all of the path

overhead bytes and cell bytes of the previous frame after all PLCP processing (frame generation, error insertion,

and overhead insertion) has been completed.

The first four bits of the fourth byte of sub-frame 3 are overwritten with the G1 byte REI bits (G1[1:4]). The Remote

Error Indication (REI) bits can be generated automatically or inserted from the G1 register bits. The REI source is

programmable (auto or register). If the REI bits are generated automatically, they are set to zero when the receive

side B1 byte exactly matches the BIP-8 calculated for the previous receives side frame. Otherwise, the REI is set to

a value of one to eight to indicate the number of parity errors (BIP-8 errors) detected in the receive PLCP frame (B1

byte).

The fifth bit of the fourth byte of sub-frame 3 is overwritten with the G1 byte RAI bit (G1[5]). The Remote Alarm

Indication (RAI) bit is sourced from a register.

The last three bits of the fourth byte of sub-frame 3 are overwritten with the G1 byte LSS bits (G1[6:8]). The Link

Status Signal (LSS) bits are sourced from a register. The three register bits are inserted in the sixth, seventh, and

eighth bits of the G1 byte in each frame.

The fourth byte of sub-frames 2 and 1 are overwritten with the M2 and M1 bytes respectively. Each byte can be

individually sourced from a register, or from the transmit HDLC controller. The M2 byte and M1 byte sources are

each programmable (register or HDLC). If both bytes are programmed to be sourced from the transmit HDLC

controller, they are concatenated as a single data link as opposed to two separate data links.

The fourth byte of sub-frame 0 is overwritten with the C1 byte created during trailer generation.

Once all of the overhead bytes have been overwritten, the data stream is passed on to error insertion.

10.8.5.3 Transmit DS3 PLCP Error Insertion

Error insertion inserts various types of errors into the different overhead bytes. The types of errors that can be

inserted are framing errors, BIP-8 parity errors, and Remote Error Indication (REI) errors.

The type of framing error(s) inserted is programmable (frame bit error or framing byte error). A framing bit error is a

single bit error in a frame alignment byte (A1 or A2) or POI byte (P#). A framing byte error is an error in all eight bits

of a frame alignment byte (A1 or A2) or path overhead indicator (POI) byte (P#). Framing error(s) can be inserted

one error at a time, or in two consecutive bytes (A1 & A2 or P# & P#+1). The framing error insertion rate (single A1

or A2, single P#, A1 & A2, or P# & P#+1) is programmable.

The type of BIP-8 error(s) inserted is programmable (errored BIP-8 bit or errored BIP-8 byte). An errored BIP-8 bit

is inverting a single bit error in the B1 byte. An errored BIP-8 byte is inverting all eight bits in the B1 byte. BIP-8

error(s) can be inserted one error at a time, or continuously. The BIP-8 error insertion rate (single or continuous) is

programmable.

The type of REI error(s) inserted is programmable (single REI error or eight REI errors). A single REI error is

generated by setting the first four bits of the G1 byte to a value of 1h. Eight REI errors are generated by setting the

first four bits of the G1 byte to a value of 8h. REI error(s) can be inserted one error at a time, or continuously. The

REI error insertion rate (single or continuous) is programmable.

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Error insertion can be initiated by a register bit (PLCP.TEIR.TSEI) or initiated by the manual error insertion input

(TMEI). Each error type is individually enabled by a register bit. The error insertion initiation type (register or input)

is programmable. Once all error insertion has been performed, the data stream is passed on to overhead insertion.

10.8.5.4 Transmit DS3 PLCP Overhead Insertion

Overhead insertion can insert any (or all) of the path overhead bytes into the DS3 PLCP frame. The overhead

bytes Z6 – Z1, F1, B1, G1, M1, M2, and C1 can be sourced from the transmit overhead interface (TPOHCLK,

TPOH, TPOHEN, and TPOHSOF). The B1 and C1 bytes are sourced as error masks (modulo 2 addition of the

input B1/C1 byte and the generated B1/C1 byte). The overhead insertion is fully controlled by the transmit

overhead interface. If the transmit PLCP overhead data enable signal (TPOHEN) is driven high, then the bit on the

transmit PLCP overhead signal (TPOH) is inserted into the output data stream. Insertion of bits using the TPOH

signal overwrites internal overhead insertion.

10.8.6 Receive DS3 PLCP Frame Processor

The DS3 PLCP frame format is shown in Figure 10-32. A1 and A2 are the sub-frame Alignment bytes that have a

value of F6h and 28h respectively. P11 – P0 are the Path Overhead Identifier (POI) bytes that indicate the path

overhead byte contained in the current sub-frame. Z6 – Z1 are growth bytes reserved for future use. F1 is the Path

User Channel byte allocated for user communications purposes (This byte is undefined in ATM). B1 is the Bit

Interleaved Parity-8 (BIP-8) byte used for PLCP path error monitoring. G1 is the PLCP Path Status Byte (See

Figure 10-33) used for far-end path status and performance monitoring (bits 6 – 8 are undefined in ATM). M1 and

M2 are the DQDB Layer Management Information bytes used for DQDB layer management communications

(These bytes are undefined in ATM). C1 is the Cycle/Stuff Counter byte used as for PLCP superframe alignment

and stuff indication.

10.8.6.1 Receive DS3 PLCP Framing

DS3 PLCP framing determines the DS3 PLCP frame boundary. The frame boundary is found by identifying the

frame alignment bytes (A1 & A2), and the path overhead indicator (POI) byte (P#). The framer is an off-line framer

that updates the data path frame counters when an out of frame (OOF) condition is present. The use of an off-line

framer reduces the number of ATM cells discarded during the framing process. The framer continually searches for

two consecutive sets of alignment bytes (A1 and A2), and two sequential POI bytes (P#) are identified. The data

path frame counters are updated if an OOF condition is present. The maximum average reframe time is 17 µs.

10.8.6.2 Receive DS3 PLCP Nibble Destuffing

Nibble destuffing discards the DS3 PLCP frame trailer immediately following sub-frame 0 (POI equals 01h). The

trailer size is determined by the DS3 PLCP superframe counter, and the cycle counter byte (C1). The trailer is 13

nibbles in the first frame of the superframe (C1 equals FFh). The trailer is 14 nibbles in the second frame of the

superframe (C1 equals 00h). The trailer length is variable in the third frame of the superframe. It is 14 nibbles if C1

equals 66h and 14 nibbles if C1 equals 99h. The superframe counter is updated immediately upon receiving an

error free C1. In the third superframe, majority voting (5 of 8) is used to determine the trailer size. Once the trailer

size has been determined, the trailer nibbles are discarded.

10.8.6.3 Receive DS3 PLCP Performance Monitoring

Performance monitoring checks the DS3 PLCP frame for errors and alarm conditions. The alarm conditions

detected are OOF, LOF, COFA, and RAI. All alarm conditions are defect conditions. The PLCP Framer does not

integrate alarms for failure conditions.

An Out Of Frame (OOF) condition is declared when two consecutive framing bytes (A1 and A2) or two consecutive

POI bytes (P0 - P11) are erred. An OOF condition is terminated when two sequential POI bytes and two

consecutive framing words (A1 and A2) are error free or the DS3 PLCP framer updates the data path frame

counters.

If the Loss Of Frame (LOF) integration counter is disabled, an LOF condition is declared when an OOF condition

has been continuously present for 1 ms. If the LOF integration counter is enabled, an LOF condition is declared by

the LOF integration counter when the counter has been active for a total of 1 ms. The LOF integration counter is

active (increments count) when an OOF condition is present, it is inactive (holds count) when an OOF condition is

absent, and it is reset when an OOF condition is continuously absent for 1 ms. An LOF condition is terminated

when an OOF condition is continuously absent for 1 ms.

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A Change Of Frame Alignment (COFA) is declared when the DS3 PLCP framer updates the data path frame

counters with a frame alignment that is different from the current data path frame alignment.

A Remote Alarm Indication (RAI) condition is declared when ten consecutive frames are received with the RAI bit

(fifth bit of G1) set to one. An RAI condition is terminated when ten consecutive frames are received with the RAI

bit set to zero.

Three types of errors are accumulated, framing errors, BIP-8 errors and Remote Error Indication (REI) errors.

Framing errors are determined by comparing A1, A2, and P# to their expected values. The type of framing errors

accumulated is programmable (OOF, bit, byte, or word). An OOF error increments the count whenever an OOF

condition is first detected (up to 1 per 3 sub-frames). A bit error increments the count once for each bit in A1, each

bit in A2, and each bit in P# that does not match its expected value (up to 24 per sub-frame). A byte error

increments the count once for each A1 byte, A2 byte, and P# byte that does not match its expected value (up to 3

per sub-frame). A word error increments the count once for each frame alignment word (A1, A2, and P#) that does

not match its expected value (up to 1 per sub-frame). The detection of POI byte (P#) framing errors is

programmable (on or off).

BIP-8 errors are determined by calculating the BIP-8 of the current frame (path overhead and cell bytes), and

comparing the calculated BIP-8 to the B1 byte in the next frame. The type of BIP-8 errors accumulated is

programmable (bit or block). A bit error increments the count once for each bit in the B1 byte that does not match

the corresponding bit in the calculated BIP-8 (up to 8 per frame). A block error increments the count if any bit in the

B1 byte does not match the corresponding bit in the calculated BIP-8 (up to 1 per frame).

REI errors are determined by the four REI bits (first four bits of G1). The REI error count is incremented by the

value of the four REI bits (up to 8 per frame). Values of 9h - Fh are treated as zero errors.

10.8.6.4 Receive DS3 PLCP Overhead Extraction

Overhead extraction extracts all of the DS3 PLCP path overhead bytes from the DS3 PLCP frame. All of the PLCP

path overhead (POH) bytes (Z6 – Z1, F1, B1, G1, M2, M1, and C1) are output on the receive overhead bus

(RPOHCLK, RPOH, and RPOHSOF). The B1 byte is output as an error indication (modulo 2 addition of the

calculated BIP-8 and the B1 byte). In addition, the Z6 – Z1, F1, G1 (6:8), M2, and M1 bytes are integrated and

stored in registers along with change indications. G1 (6:8) has an unstable indication as well. The F1 byte is sent to

the receive trail trace buffer, and can also be sent to the receive HDLC controller. The M2 byte and/or M1 byte can

be sent to the receive HDLC controller. The source of the data transferred to the receive HDLC controller is

programmable (F1, M2, M1, or M2 & M1). If both the M2 and M1 byte are programmed to be the source for the

receive HDLC controller, they are concatenated as a single data link as opposed to two separate data links.

Once all frame processing has been completed, the ATM cells are passed on to the ATM/Packet Processor with a

start of cell indication.

10.8.7 Transmit E3 PLCP Frame Processor

The E3 PLCP frame format is shown in Figure 10-34. A1 and A2 are the sub-frame Alignment bytes that have a

value of F6h and 28h, respectively. P8–P0 are the Path Overhead Identifier (POI) bytes that indicate the path

overhead byte contained in the current sub-frame. Z3–Z1 are growth bytes reserved for future use. F1 is the Path

User Channel byte allocated for user communications purposes (This byte is undefined in ATM). B1 is the Bit

Interleaved Parity-8 (BIP-8) byte used for PLCP path error monitoring. G1 is the PLCP Path Status Byte (See

Figure 10-35) used for far-end path status and performance monitoring (bits 6–8 are undefined in ATM). M2 and

M1 are the DQDB Layer Management Information bytes used for DQDB layer management communications

(These bytes are undefined in ATM). C1 is the Cycle/Stuff Counter byte used as for stuff indication.

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Figure 10-34. E3 PLCP Frame Format

9 Rows

57 Columns

A1 A2

First Cell

Second Cell

Third Cell

Fourth Cell

Fifth Cell

Sixth Cell

Seventh Cell

Eight Cell

Ninth Cell Trailer

18 or 20

Bytes

Figure 10-35. E3 PLCP G1 Byte Format

REI - Remote Error Indicator

RAI - Remote Alarm Indicator

LSS - Link Status Signal

REI REI REI REI RAI LSS LSS LSS

MSB

LSB

10.8.7.1 Transmit E3 PLCP Trailer Generation

E3 PLCP trailer generation inserts the E3 PLCP frame trailer immediately following sub-frame 0 (POI equals 01h),

and generates the C1 byte. The trailer size is determined by the phase relationship of the G.751 E3 frame and

PLCP frame and by the transmit 8 kHz reference clock. The trailer size is variable in all frames. The trailer size can

be 17, 18, 19, 20, or 21 bytes. C1 is set to 3Bh, 4Fh, 75h, 9Dh, or A7h respectively, and the indicated number of

bytes (17 – 21) are added after sub-frame 0. The trailer bytes are all set to 11001100.

10.8.7.2 Transmit E3 PLCP Frame Generation

E3 PLCP frame generation receives the incoming PLCP payload data stream, and overwrites all of the overhead

byte locations.

The first two bytes of each sub-frame are overwritten with the frame alignment bytes A1 and A2, which have a

value of F6h and 28h respectively.

The third byte of sub-frame # is overwritten with POI byte # (P#). The value of P# is 00####0Pb (0 = a logic zero,

#### = the hexadecimal value of #, and P = the odd parity bit).

The fourth byte of sub-frames #8 – 6 are overwritten with the Z3 – Z1 bytes from the corresponding registers.

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The fourth byte of sub-frame 5 is overwritten with the F1 byte from the corresponding register or the trail trace byte

input from the transmit trail trace controller. The F1 byte from the corresponding register, the trail trace byte input

from the transmit trail trace controller, or the HDLC Overhead Processor interface). The F1 byte source is

programmable (PLCP.TCR.TF1C[1:0]) (trail trace data link, HDLC, or register).

The fourth byte of sub-frame 4 is overwritten with the B1 byte, which is a BIP-8, calculated over all of the path

overhead bytes and cell bytes of the previous frame after all PLCP processing (frame generation, error insertion,

and overhead insertion) has been completed.

The first four bits of the fourth byte of sub-frame 3 are overwritten with the G1 byte REI bits (G1[1:4]). The Remote

Error Indication (REI) bits can be generated automatically or inserted from the G1 register bits. The REI source is

programmable (auto or register). If the REI bits are generated automatically, they are set to zero when the receive

side B1 byte exactly matches the BIP-8 calculated for the previous receives side frame. Otherwise, the REI is set to

a value of one to eight to indicate the number of parity errors (BIP-8 errors) detected in the receive PLCP frame (B1

byte).

The fifth bits of the fourth byte of sub-frame 3 is overwritten with the G1 byte RAI bit (G1[5]). The Remote Alarm

Indication (RAI) bit is sourced from a register.

The last three bits of the fourth byte of sub-frame 3 are overwritten with the G1 byte LSS bits (G1[6:8]). The Link

Status Signal (LSS) bits are sourced from a register. The three register bits are inserted in the sixth, seventh, and

eighth bits of the G1 byte in each frame.

The fourth byte of sub-frames 2 and 1 are overwritten with the M2 and M1 bytes respectively. Each byte can be

individually sourced from a register, or from the transmit HDLC Overhead Processor. The M2 byte and M1 byte

sources are each programmable (register or HDLC). If both bytes are programmed to be sourced from the transmit

HDLC controller, they are concatenated as a single data link as opposed to two separate data links.

The fourth byte of sub-frame 0 is overwritten with the C1 byte created during trailer generation.

Once all of the overhead bytes have been overwritten, the data stream is passed on to error insertion.

10.8.7.3 Transmit E3 PLCP Error Insertion

Error insertion inserts various types of errors into the different overhead bytes. The types of errors that can be

inserted are framing errors, BIP-8 parity errors, and Remote Error Indication (REI) errors.

The type of framing error(s) inserted is programmable (frame bit error or framing byte error). A framing bit error is a

single bit error in a frame alignment byte (A1 or A2) or POI byte (P#). A framing byte error is an error in all eight bits

of a frame alignment byte (A1 or A2) or path overhead indicator (POI) byte (P#). Framing error(s) can be inserted

one error at a time, or in two consecutive bytes (A1 & A2 or P# & P#+1). The framing error insertion rate (single A1

or A2, single P#, A1 & A2, or P# & P#+1) is programmable.

The type of BIP-8 error(s) inserted is programmable (errored BIP-8 bit or errored BIP-8 byte). An errored BIP-8 bit

is inverting a single bit error in the B1 byte. An errored BIP-8 byte is inverting all eight bits in the B1 byte. BIP-8

error(s) can be inserted one error at a time, or continuously. The BIP-8 error insertion rate (single or continuous) is

programmable.

The type of REI error(s) inserted is programmable (single REI error or eight REI errors). A single REI error is

generated by setting the first four bits of the G1 byte to a value of 1h. Eight REI errors are generated by setting the

first four bits of the G1 byte to a value of 8h. REI error(s) can be inserted one error at a time, or continuously. The

REI error insertion rate (single or continuous) is programmable.

Error insertion can be initiated by a register bit (PLCP.TEIR.TSEI) or initiated by the manual error insertion input

(TMEI). Each error type is individually enabled by a register bit. The error insertion initiation type (register or input)

is programmable. Once all error insertion has been performed, the data stream is passed on to overhead insertion.

10.8.7.4 Transmit E3 PLCP Overhead Insertion

Overhead insertion can insert any (or all) of the path overhead bytes into the E3 PLCP frame. The overhead bytes

Z3 – Z1, F1, B1, G1, M1, M2, and C1 can be sourced from the transmit overhead interface (TPOHCLK, TPOH,

TPOHEN, and TPOHSOF). The B1 and C1 bytes are sourced as error masks (modulo 2 addition of the input

B1/C1 byte and the generated B1/C1 byte). The overhead insertion is fully controlled by the transmit overhead

interface. If the transmit PLCP overhead data enable signal (TPOHEN) is driven high, then the bit on the transmit

PLCP overhead signal (TPOH) is inserted into the output data stream. Insertion of bits using the TPOH signal

overwrites internal overhead insertion.

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10.8.8 Receive E3 PLCP Frame Processor

The Receive E3 PLCP Frame Processor performs E3 PLCP framing, byte destuffing, performance monitoring and

overhead extraction.

The E3 PLCP frame format is shown in Figure 10-34. A1 and A2 are the sub-frame Alignment bytes that have a

value of F6h and 28h respectively. P8 – P0 are the Path Overhead Identifier (POI) bytes that indicate the path

overhead byte contained in the current sub-frame. Z3 – Z1 are growth bytes reserved for future use. F1 is the Path

User Channel byte allocated for user communications purposes (This byte is undefined in ATM). B1 is the Bit

Interleaved Parity-8 (BIP-8) byte used for PLCP path error monitoring. G1 is the PLCP Path Status Byte (See

Figure 10-35) used for far-end path status and performance monitoring (bits 6 – 8 are undefined in ATM). M1 and

M2 are the DQDB Layer Management Information bytes used for DQDB layer management communications

(These bytes are undefined in ATM). C1 is the Cycle/Stuff Counter byte used as for PLCP stuff indication.

10.8.8.1 Receive E3 PLCP Framing

E3 PLCP framing determines the E3 PLCP frame boundary. The frame boundary is found by identifying the frame

alignment bytes (A1 & A2), and the path overhead indicator (POI) byte (P#). The framer is an off-line framer that

updates the data path frame counters when an out of frame (OOF) condition is present. The use of an off-line

framer reduces the number of ATM cells discarded during the framing process. The continually searches for two

consecutive sets of alignment bytes (A1 and A2), and two sequential POI bytes (P#) are identified. The data path

frame counters are updated if an OOF condition is present). The maximum average reframe time is 23 µs.

10.8.8.2 Receive E3 PLCP Byte Destuffing

Byte destuffing discards the E3 PLCP frame trailer immediately following sub-frame 0 (POI equals 01h). The trailer

size is determined by the cycle counter byte (C1). The trailer is 17 to 21 bytes. It is 17 bytes if C1 equals 3Bh; 18

bytes if C1 equals 4Fh; 19 bytes if C1 equals 75h; 20 bytes if C1 equals 9Dh; and 21 bytes if C1 equals A7h. The

C1 codes provide error correction capability, and the C1 byte is corrected if required, and then used to determine

the trailer size. Once the trailer size has been determined, the trailer bytes are discarded.

10.8.8.3 Receive E3 PLCP Performance Monitoring

Performance monitoring checks the E3 PLCP frame for errors and alarm conditions. The alarm conditions detected

are OOF, LOF, COFA, and RAI. All alarm conditions are defect conditions. The FEAC Controller does not integrate

alarms for failure conditions.

An Out Of Frame (OOF) condition is declared when an error is detected in both bytes in a framing word (A1 and

A2) or two consecutive POI bytes (P0 - P11) are erred. An OOF condition is terminated when two sequential POI

bytes and two consecutive framing words (A1 and A2) are error free or the E3 PLCP framer updates the data path

frame counters.

If the Loss Of Frame (LOF) integration counter is disabled, an LOF condition is declared when an OOF condition

has been continuously present for 1 ms. If the LOF integration counter is enabled, an LOF condition is declared by

the LOF integration counter when the counter has been active for a total of 1 ms. The LOF integration counter is

active (increments count) when an OOF condition is present, it is inactive (holds count) when an OOF condition is

absent, and it is reset when an OOF condition is continuously absent for 1 ms. An LOF condition is terminated

when an OOF condition is continuously absent for 1 ms.

A Change Of Frame Alignment (COFA) is declared when the E3 PLCP framer updates the data path frame

counters with a frame alignment that is different from the current data path frame alignment.

A Remote Alarm Indication (RAI) condition is declared when ten consecutive frames are received with the RAI bit

(fifth bit of G1) set to one. An RAI condition is terminated when ten consecutive frames are received with the RAI

bit set to zero.

Three types of errors are accumulated: framing errors, BIP-8 errors and Remote Error Indication (REI) errors.

Framing errors are determined by comparing A1, A2, and P# to their expected values. The type of framing errors

accumulated is programmable (OOF, bit, byte, or word). An OOF error increments the count whenever an OOF

condition is first detected (up to 1 per 3 sub-frames). A bit error increments the count once for each bit in A1, each

bit in A2, and each bit in P# that does not match its expected value (up to 24 per sub-frame). A byte error

increments the count once for each A1 byte, A2 byte, and P# byte that does not match its expected value (up to 3

per sub-frame). A word error increments the count once for each frame alignment word (A1, A2, and P#) that does

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not match its expected value (up to 1 per sub-frame). The detection of POI byte (P#) framing errors is

programmable (on or off).

BIP-8 errors are determined by calculating the BIP-8 of the current frame (path overhead and cell bytes), and

comparing the calculated BIP-8 to the B1 byte in the next frame. The type of BIP-8 errors accumulated is

programmable (bit or block). A bit error increments the count once for each bit in the B1 byte that does not match

the corresponding bit in the calculated BIP-8 (up to 8 per frame). A block error increments the count if any bit in the

B1 byte does not match the corresponding bit in the calculated BIP-8 (up to 1 per frame).

REI errors are determined by the four REI bits (first four bits of G1). The count is incremented by the value of the

four REI bits (up to 8 per frame). Values of 9h - Fh are treated as zero errors.

10.8.8.4 Receive E3 PLCP Overhead Extraction

Overhead extraction extracts all of the E3 PLCP path overhead bytes from the E3 PLCP frame. All of the PLCP

path overhead (POH) bytes (Z3 – Z1, F1, B1, G1, M1, M2, and C1) are output on the receive overhead bus

(RPOHCLK, RPOH, and RPOHSOF). The B1 byte is output as an error indication (modulo 2 addition of the

calculated BIP-8 and the B1 byte). In addition, the Z3 – Z1, F1, G1 (6:8), M1, and M2 bytes are integrated and

stored in registers along with change indications. G1 (6:8) has an unstable indication as well. The F1 byte is sent to

the receive trail trace buffer, and can also be sent to the receive HDLC controller. The M2 byte and/or M1 byte can

be sent to the receive HDLC controller. The source of the data transferred to the receive HDLC controller is

programmable (F1, M2, M1, or M2 & M1). If both the M2 and M1 bytes are programmed to be the source for the

receive HDLC controller, they are concatenated as a single data link as opposed to two separate data links.

Once all frame processing has been completed, the ATM cells are passed on to the ATM/Packet Processor with a

start of cell indication.

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10.9 Fractional Payload Controller

10.9.1 General Description

The Fractional Payload Controller uses a fraction of the DS3/E3 payload for ATM cell or HDLC packets. The

unused DS3/E3 payload is considered fractional overhead and can be used as a proprietary data link. The

allocation given to the fractional payload is programmable controlled using internal counters or controlled

externally. The fractional overhead data can optionally be programmed to transmit all 0’s, all 1’s, a 1010 pattern, or

insert data from an external source.

The Fractional Payload Controller demaps fractional payload and overhead data from the DS3/E3 payload in the

receive direction and maps fractional payload and overhead data into the DS3/E3 payload in the transmit direction.

The receive direction extracts the fractional payload and fractional overhead data bits from the receive DS3/E3

payload, performs fractional payload/overhead data demultiplexing, sends the fractional payload to the ATM/Packet

processor, and sends the fractional overhead data to an external interface.

The transmit direction accepts the fractional overhead from an internal register or the external interface and

fractional payload data from the ATM/Packet processor, performs fractional overhead/payload data multiplexing,

and inserts the fractional overhead and payload data into the transmit DS3/E3 payload.

See Figure 10-36 for the location of the Fractional Payload Controller in the DS318x devices.

Figure 10-36. Fractional Payload Controller Detailed Block Diagram

DS3/E3

Trans mit

LIU

IEEE P1149.1

JTAG Test

Access Port

Microprocessor

Inte rf ac e

HDLC

FEAC

LLB

DLB

DS3 / E3

Transmit

Formatter

DS3 / E3

Rec eiv e

Framer

Trail

Trac e

Buffer

Tx Cell

Processor Tx

FIFO

System

Interface

Rx Cell

Processor

FIFO

Tx Pac ket

Processor

SLB

Rx Pac ket

Processor

DS3/E3

Rec e iv e

LIU

TAIS

TUA 1

TX FRA C/

PL CP

RX FRA C/

PLCP

Cloc k Rate

Adapter

TX BERT

RX BERT

PLB

ALB

UA 1

GEN

B3ZS/

HDB3

Encoder

B3ZS/

HDB3

Dec oder

10.9.2 Features

• Programmable payload allocation – The payload data and fractional overhead allocation can be

programmed via registers.

• Externally controlled payload allocation – The payload data and fractional overhead allocation can be

controlled by an external source via pins.

• Fractional overhead extraction and insertion – Extracts all fractional overhead from the DS3/E3 payload

and sends it to an external serial interface. Inserts all fractional overhead from a serial interface and into the

transmit DS3/E3 payload. Optionally, the transmit fractional overhead can be set to insert all 0’s, all 1’s, or a

1010 pattern.

DS3181/DS3182/DS3183/DS3184

161

10.9.3 Transmit Fractional Interface

The Transmit Fractional Interface receives the payload data stream from the ATM/Packet Processor and inserts a

fractional overhead stream.

The incoming fractional overhead stream consists of fractional overhead (TFOHn), input fractional overhead enable

(TFOHENIn), and output fractional overhead enable (TFOHENOn). TFOHn, TFOHENOn and TFOHENIn are

typically referenced to TCLKIn (but also could be referenced to the TLCLKn, TCLKOn/TGCLKn, RCLKOn or

RLCLKn clock pins). If external control is enabled, TFOHENIn marks the fractional overhead periods, and

TFOHENOn is held low. If internal control is enabled, TFOHENOn marks the fractional overhead periods, and

TFOHENIn is ignored. Fractional overhead control is programmable (internal or external). The fractional overhead

source is programmable (all 0's, all 1's, a 10 pattern, or TFOH). See the FRAC.TCR Register Definition.

See Section 8.3.3 above for specific timing relationships between these pins.

10.9.4 Transmit Fractional Controller

The Transmit Fractional Controller generates the transmit fractional overhead enable output (TFOHENOn) used in

internal control mode to insert fractional overhead. The outgoing transmit data stream to the DS3/E3 Framer is

divided into frames. Each frame is composed of data groups that have a programmable size (1 – 8191 bits). Each

data group is divided into two sections. The first section (Section A) has a programmable size (0 – 8191 bits). The

second section (Section B) contains the remaining bits (g – a bits). See Figure 10-37. The section that contains

fractional overhead is programmable (Section A or Section B by setting the FRAC.TCR.TSASS register bit).

TFOHENOn is high during the fractional overhead section of the data group, and low during the payload section of

the data group. TFOHENOn is also low during line overhead/stuff periods.

10.9.5 Receive Fractional Interface

The Receive Fractional Interface receives the DS3/E3 payload from the DS3/E3 Framer, and performs fractional

overhead extraction on the payload.

The receive fractional overhead pins are the input fractional overhead enable (RFOHENIn), and the output

fractional overhead enable (RFOHENOn). RFOHENIn is sampled on the rising edge of RCLKOn, typically, or it can

be referenced to the RLCLKn pin. RFOHENOn is updated on the rising edge of RCLKOn (or alternatively the

RLCLKn pin).

If external control is enabled, the receive fractional overhead enable input (RFOHENIn) marks the fractional

overhead bits contained in the DS3/E3 payload. RFOHENIn is high while a fractional overhead period is available

on RSERn. RFOHENIn is low during payload data or line overhead/stuff periods.

If internal control is enabled, the receive fractional overhead enable output (RFOHENOn) marks the fractional

overhead bits in the received DS3/E3 payload. RFOHENOn is high during a fractional overhead bit period on

RSERn. RFOHENOn is low during a payload data or line overhead/stuff period. See Section 8.3.3 above for

specific timing relationships between these pins.

10.9.6 Receive Fractional Controller

The Receive Fractional Controller generates the receive fractional overhead enable output (RFOHENOn) used in

internal control mode to extract fractional overhead to the RFOHn pin. The DS3/E3 payload is divided into frames

composed of data groups that have a programmable size (1 – 8191 bits). Each data group is divided into two

sections. The first section (Section A) has a programmable size (a, 0 – 8191 bits). The second section (Section B)

contains the remaining bits (g – a bits). See Figure 10-37. The section that contains fractional overhead is

programmable (Section A or Section B by setting the FRAC.RCR.RSASS register bit). RFOHENOn is high during

the fractional overhead section of the data group, and low during the payload section of the data group.

RFOHENOn is also low during line overhead/stuff periods.

The first bit of a frame is the first bit of a data group. If a frame does not contain an integer number of data groups (f

/ g is not an integer), the last data group in the frame will be a short data group. The last bit of the short data group

will be the last data period before the start of frame period.

DS3181/DS3182/DS3183/DS3184

162

Figure 10-37. Data Group Format

Section A (a bits) Section B (g-a bits)

Data Group (g bits)

Figure 10-38. Frame Format

Frame (f bits)

Data Group Data Group Data Group Data Group Data Group Data Group

• • •

DS3181/DS3182/DS3183/DS3184

163

10.10 DS3/E3 Framer/Formatter

10.10.1 General Description

The Receive DS3/E3 Framer receives a unipolar DS3/E3 signal, determines frame alignment and extracts the

DS3/E3 overhead in the receive direction. The Transmit DS3/E3 Formatter receives a DS3/E3 payload, generates

framing, inserts DS3/E3 overhead, and outputs a unipolar DS3/E3 signal in the transmit direction.

The Receive DS3/E3 Framer receives a DS3/E3 signal, determines the frame alignment, extracts the DS3/E3

overhead, and outputs the payload with frame and overhead

The Transmit DS3/E3 Formatter receives a DS3/E3 payload from the ATM/Packet Processor, generates a DS3/E3

frame, optionally inserts DS3/E3 overhead, and transmits the DS3/E3 signal.

See Figure 10-39 for the location of the DS3/E3 Framer/Formatter blocks in the DS318x devices.

Figure 10-39. Framer Detailed Block Diagram

DS3/E3

Trans mit

LIU

IEEE P1149.1

JTAG Test

Access Port

Microprocessor

Inte rf ac e

HDLC

FEAC

LLB

DLB

DS3 / E3

Transmit

Formatter

DS3 / E3

Rec eiv e

Framer

Trail

Trac e

Buffer

Tx Cell

Processor Tx

FIFO

System

Interface

Rx Cell

Processor

FIFO

Tx Pac ket

Processor

SLB

Rx Pac ket

Processor

DS3/E3

Rec e iv e

LIU

TAIS

TUA 1

TX FRA C/

PL CP

RX FRA C/

PLCP

Cloc k Rate

Adapter

TX BERT

RX BERT

PLB

ALB

UA 1

GEN

B3ZS/

HDB3

Encoder

B3ZS/

HDB3

Dec oder

10.10.2 Features

10.10.2.1 Transmit Formatter

• Programmable DS3 or E3 formatter – Accepts a DS3 (M23 or C-bit) or E3 (G.751 or G.832) signal and

performs DS3/E3 overhead generation.

• Arbitrary framing format support – Generates a signal with an arbitrary framing format. The line

overhead/stuff periods are added into the data stream using an overhead mask signal.

• Generates alarms and errors – DS3 alarm conditions (AIS, RDI, and Idle) and errors (framing, parity, and

FEBE), or E3 alarm conditions (AIS and RDI/RAI) and errors (framing, parity, and REI) can be inserted into the

outgoing data stream.

• Externally controlled serial DS3/E3 overhead insertion port – Can insert all DS3 or E3 overhead via a

serial interface. DS3/E3 overhead insertion is fully controlled via the serial overhead interface.

• HDLC overhead insertion – An HDLC channel can be inserted into the DS3 or E3 data stream.

• FEAC insertion – A FEAC channel can be inserted into the DS3 or E3 data stream.

• Trail Trace insertion – Inputs and inserts the G.832 E3 TR byte.

10.10.2.2 Receive Framer

• Programmable DS3 or E3 framer – Accepts a DS3 (M23 or C-bit) or E3 (G.751 or G.832) signal and performs

DS3/E3 overhead termination.

DS3181/DS3182/DS3183/DS3184

164

• Arbitrary framing format support – Accepts a signal with an arbitrary framing format. The Line overhead/stuff

periods are removed from the data stream using an overhead mask signal.

• Detects alarms and errors – Detects DS3 alarm conditions (SEF, OOMF, OOF, LOF, COFA, AIS, AIC, RDI,

and Idle) and errors (framing, parity, and FEBE), or E3 alarm conditions (OOF, LOF, COFA, AIS, and RDI/RAI)

and errors (framing, parity, and REI).

• Serial DS3/E3 overhead extraction port – Extracts all DS3 or E3 overhead and outputs it on a serial

interface.

• HDLC overhead extraction – An HDLC channel can be extracted from the DS3 or E3 data stream.

• FEAC extraction – A FEAC channel can be extracted from the DS3 or E3 data stream.

• Trail Trace extraction – Extracts and outputs the G.832 E3 TR byte.

10.10.3 Transmit Formatter

The Transmit Formatter receives a DS3, E3 or CC52 clear-channel data stream and performs framing generation,

error insertion, overhead insertion, and AIS/Idle generation for C-bit DS3, M23 DS3, G.751 E3, G.832 E3, or CC52

clear-channel framing protocols. In clear-channel mode, only AIS/Idle generation is performed.

The bits in a byte are transmitted MSB first, LSB last. When they are input serially, they are input in the order they

are to be transmitted. The bits in a byte in an outgoing signal are numbered in the order they are transmitted, 1

(MSB) to 8 (LSB). However, when a byte is stored in a register, the MSB is stored in the highest numbered bit (7),

and the LSB is stored in the lowest numbered bit (0). This is to differentiate between a byte in a register and the

corresponding byte in a signal.

After all frame formatting is completed, the frame processor inserts a DS3/E3 (or Clear Channel) data stream into a

line data stream (OHM modes only). The line data stream is an upper level signal with a DS3, E3, or clear-channel

data stream embedded within the upper level frame. For example, if a DS3 signal has two line overhead/stuff

periods occur between the beginning of one frame and the beginning of the next frame, there will be 4762 clock

periods between the beginnings of the two frames (4760 for the DS3 data periods plus two for the line

overhead/stuff periods).

10.10.4 Receive Framer

The Receive Framer receives the incoming DS3, E3, or clear-channel line/tributary data stream, performs

appropriate framing, terminates and extracts the associated overhead bytes, and extracts the DS3, E3, or clear-

channel payload data stream (OHM modes only). The line data stream is an upper-level signal with a DS3, E3, or

clear-channel data stream embedded within the upper level frame. For example, if a DS3 signal has two line

overhead/stuff periods occur between the beginning of one frame and the beginning of the next frame, there will be

4762 clock periods between the beginnings of the two frames (4760 for the DS3 data periods plus two for the line

overhead/stuff periods).

The Receive Framer processes a C-bit format DS3, M23 format DS3, G.751 format E3, G.832 format E3, or clear-

channel data stream, performing framing, performance monitoring, overhead extraction, and generates

downstream AIS, if necessary. In clear-channel mode, only performance monitoring and downstream AIS

generation are performed.

The bits in a byte are received MSB first, LSB last. When they are output serially, they are output MSB first, LSB

last. The bits in a byte in an incoming signal are numbered in the order they are received, 1 (MSB) to 8 (LSB).

However, when a byte is stored in a register, the MSB is stored in the highest numbered bit (7), and the LSB is

stored in the lowest numbered bit (0). This is to differentiate between a byte in a register and the corresponding

byte in a signal.

Some bits, bit groups, or bytes (data) are integrated before being stored in a register. Integration requires the data

to have the same new data value for five consecutive occurrences before the new data value will be stored in the

data register. Unless stated otherwise, integrated data may have an associated unstable indication. Integrated data

is considered unstable if the received data value does not match the currently stored (integrated) data value or the

previously received data value for eight consecutive occurrences. The unstable condition is terminated when the

same value is received for five consecutive occurrences.

10.10.4.1.1 Receive DS3 Framing

DS3 framing determines the DS3 frame boundary. In order to identify the DS3 frame boundary, first the sub-frame

boundary must be found. The sub-frame boundary is found by identifying the sub-frame alignment bits FX1, FX2, FX3,

and FX4, which have a value of one, zero, zero, and one respectively. See Figure 10-40. Once the sub-frame

DS3181/DS3182/DS3183/DS3184

165

boundary is found, the multiframe frame boundary can be found. The multiframe boundary is found by identifying

the multiframe alignment bits M1, M2, and M3, which have a value of zero, one, and zero respectively. The DS3

framer is an off-line framer that only updates the data path frame counters when either an out of frame (OOF) or an

out of multiframe (OOMF) condition is present. The use of an off-line framer reduces the average time required to

reframe, and reduces data loss caused by burst error. The DS3 framer has a Maximum Average Reframe Time

(MART) of approximately 1.0ms.

Figure 10-40. DS3 Frame Format

680 Bits

7 Sub-

Frames

F11

F21

F31

F41

F51

F61

F71

F12

F22

F32

F42

F52

F62

F72

F13

F23

F33

F43

F53

F63

F73

F14

F24

F34

F44

F54

F64

F74

C11

C21

C31

C41

C51

C61

C71

C12

C22

C32

C42

C52

C62

C72

C13

C23

C33

C43

C53

C63

C73

The sub-frame framer continually searches four adjacent bit positions for a sub-frame boundary. A sub-frame

alignment bit (F-bit) checker checks each bit position. All four-bit positions must fail before any other bit positions

are checked for a sub-frame boundary. There are 170 possible bit positions that must be checked, and four

positions are checked simultaneously. Therefore up to 43 checks may be needed to identify the sub-frame

boundary. The sub-frame framer enables the multiframe frame once it has identified a sub-frame boundary. See

Figure 10-41 for the sub-frame framer state diagram.

DS3181/DS3182/DS3183/DS3184

166

Figure 10-41. DS3 Sub-Frame Framer State Diagram

Sync

LoadVerify

All 4 bit positions failed

2 F-bits loaded

3 bit positions failed or

16 F-bits verified

All 4 bit positions failed

The multiframe framer checks for a multiframe boundary. When the multiframe framer identifies a multiframe

boundary, it updates the data path frame counters if either an OOF or OOMF condition is present. The multiframe

framer waits until a sub-frame boundary has been identified. Then, each bit position is checked for the multiframe

boundary. The multiframe boundary is found by identifying the three multiframe alignment bits (M-bits). Since there

are seven multiframe bits and three bits are required to identify the multiframe boundary, up to 9 checks may be

needed to find the multiframe boundary. Once the multiframe boundary is identified, it is checked in each

subsequent frame. The data path frame counters are updated if the three multiframe alignment bits are error free,

and an OOF or OOMF condition exists. If the multiframe framer checks more than 15 multiframe bit (X-bits, P-bits,

and M-bits) positions without identifying the multiframe boundary, the multiframe framer times out, and forces the

sub-frame framer back into the load state. See Figure 10-42 for the multiframe framer state diagram.

10.10.4.1.2 Receive DS3 Performance Monitoring

Performance monitoring checks the DS3 frame for alarm conditions and errors. The alarm conditions detected are

OOMF, OOF, SEF, LOF, COFA, LOS, AIS, Idle, RUA1, and RDI. The errors accumulated are framing, P-bit parity,

C-bit parity (C-bit format only), and Far-End Block Error (FEBE) (C-bit format only) errors.

An Out Of Multiframe (OOMF) condition is declared when a multiframe alignment bit (M-bit) error has been

detected in two or more of the last four consecutive DS3 frames, or when a manual - is requested. An OOMF

condition is terminated when no M-bit errors have been detected in the last four consecutive DS3 frames, or when

the DS3 framer updates the data path frame counters. See Figure 10-42 for the multiframe framer state diagram.

DS3181/DS3182/DS3183/DS3184

167

Figure 10-42. DS3 Multiframe Framer State Diagram

Sync

LoadVerify

Timeout

2 multiframe loaded

M-bits identified

M-bit error and timeout

M-bit error

If multiframe alignment OOF is disabled, an Out Of Frame (OOF) condition is declared when three or more out of

the last 16 consecutive sub-frame alignment bits (F-bits) have been errored, or a manual resynchronization is

requested. If multiframe alignment OOF is enabled, an OOF condition is declared when three or more out of the

last 16 consecutive F-bits have been errored, when an OOMF condition is declared, or when a manual

resynchronization is requested. If multiframe alignment OOF is disabled, an OOF condition is terminated when

none of the last 16 consecutive F-bits has been errored, or when the DS3 framer updates the data path frame

counters. If multiframe alignment OOF is enabled, an OOF condition is terminated when an OOMF condition is not

active and none of the last 16 consecutive F-bits has been errored, or when the DS3 framer updates the data path

frame counters. Multiframe alignment OOF is programmable (on or off).

A Severely Errored Frame (SEF) condition is declared when three or more out of the last 16 consecutive F-bits

have been errored, or when a manual resynchronization is requested. An SEF condition is terminated when an

OOF condition is absent.

A Loss Of Frame (LOF) condition is declared by the LOF integration counter when it has been active for a total of T

ms. The LOF integration counter is active (increments count) when an OOF condition is present, it is inactive (holds

count) when an OOF condition is absent, and it is reset when an OOF condition is absent for T continuous ms. T is

programmable (0, 1, 2, or 3). An LOF condition is terminated when an OOF condition is absent for T continuous

ms.

A Change Of Frame Alignment (COFA) is declared when the DS3 framer updates the data path frame counters

with a frame alignment that is different from the current data path DS3 frame alignment.

A Loss Of Signal (LOS) condition is declared when the B3ZS encoder is active, and it declares a LOS condition. A

LOS condition is terminated when the B3ZS encoder is inactive, or it terminates a LOS condition.

An Alarm Indication Signal (AIS) is a DS3 signal with valid F-bits and M-bits. The X-bits (X1 and X2) are set to one,

the P-bits (P1 and P2) are set to zero, all C-bits (CXY) are set to zero, and the payload bits are set to a 1010 pattern

starting with a one immediately after each DS3 overhead bit. An AIS signal is present when a DS3 frame is

received with valid F-bits and M-bits, both X-bits set to one, both P-bits set to zero, all C-bits set to zero, and all but

seven or fewer payload data bits matching the DS3 overhead aligned 1010 pattern. An AIS signal is absent when a

DS3 frame is received that does not meet the aforementioned criteria for an AIS signal being present. The AIS

integration counter declares an AIS condition when it has been active for a total of 10 to 17 DS3 frames. The AIS

integration counter is active (increments count) when an AIS signal is present, it is inactive (holds count) when an

DS3181/DS3182/DS3183/DS3184

168

AIS signal is absent, and it is reset when an AIS signal is absent for 10 to 17 consecutive DS3 frames. An AIS

condition is terminated when an AIS signal is absent for 10 to 17 consecutive DS3 frames.

A Receive Unframed All 1’s (RUA1) condition is declared if in each of 4 consecutive 2047 bit windows, five or less

zeros are detected and an OOF condition is continuously present. A RUA1 condition is terminated if in each of 4

consecutive 2047-bit windows, six or more zeros are detected or an OOF condition is continuously absent.

An Idle Signal (Idle) is a DS3 signal with valid F-bits, M-bits, and P-bits (P1 and P2). The X-bits (X1 and X2) are set

to one, C31, C32, and C33 are set to zero, and the payload bits are set to a 1100 pattern starting with 11 immediately

after each overhead bit. In C-bit mode, an Idle signal is present when a DS3 frame is received with valid F-bits, M-

bits, and P-bits, both X-bits set to one, C31, C32, and C33 set to zero, and all but seven or fewer payload data bits

matching the overhead aligned 1100 pattern. In M23 mode, an Idle signal is present when a DS3 frame is received

with valid F-bits, M-bits, and P-bits, both X-bits set to one, and all but seven or fewer payload data bits matching

the T3 overhead aligned 1100 pattern. An Idle signal is absent when a DS3 frame is received that does not meet

aforementioned criteria for an Idle signal being present. The Idle integration counter declares an Idle condition

when it has been active for a total of 10 to 17 DS3 frames. The Idle integration counter is active (increments count)

when an Idle signal is present, it is inactive (holds count) when an Idle signal is absent, and it is reset when an Idle

signal is absent for 10 to 17 consecutive DS3 frames. An Idle condition is terminated when an Idle signal is absent

for 10 to 17 consecutive DS3 frames.

A Remote Defect Indication (RDI) condition (also called a far-end SEF/AIS defect condition) is declared when four

consecutive DS3 frames are received with the X-bits (X1 and X2) set to zero. An RDI condition is terminated when

four consecutive DS3 frames are received with the X-bits set to one.

A DS3 Framing Format Mismatch (DS3FM) condition is declared when the DS3 format programmed (M23, C-bit)

does not match the incoming DS3 signal-framing format. A DS3FM condition is terminated when the incoming DS3

signal-framing format is the same format as programmed. Framing errors are determined by comparing F-bits and

M-bits to their expected values. The type of framing errors accumulated is programmable (OOF, F & M, F, or M).

An OOF error increments the count whenever OOF condition is first detected. An F & M error increments the count

once for each F-bit or M-bit that does not match its expected value (up to 31 per DS3 frame). An F error increments

the count once for each F-bit that does not match its expected value (up to 28 per DS3 frame). An M error

increments the count once for each M-bit that does not match its expected value (up to 3 per DS3 frame).

P-bit parity errors are determined by calculating the parity of the current DS3 frame (payload bits only), and

comparing the calculated parity to the P-bits (P1 and P2) in the next DS3 frame. If the calculated parity does not

match P1 or P2, a single P-bit parity error is declared.

C-bit parity errors (C-bit format only) are determined by calculating the parity of the current DS3 frame (payload bits

only), and comparing the calculated parity to the C-bits in sub-frame three (C31, C32, and C33) in the next DS3

frame. If the calculated parity does not match C31, C32, or C33, a single C-bit parity error is declared.

FEBE errors (C-bit format only) are determined by the C-bits in sub-frame four (C41, C42, and C43). A value of 111

indicates no error and any other value indicates an error.

10.10.5 C-bit DS3 Framer/Formatter

10.10.5.1 Transmit C-bit DS3 Frame Processor

The C-bit DS3 frame format is shown in Figure 10-40. Table 10-34 shows the function of each overhead bit in the

DS3 Frame

DS3181/DS3182/DS3183/DS3184

169

Table 10-34. C-Bit DS3 Frame Overhead Bit Definitions

BIT DEFINITION

X1, X2 Remote Defect Indication

(RDI)

P1, P2 Parity Bits

M1, M2, and M3 Multiframe Alignment Bits

FXY Sub-frame Alignment Bits

C11 Application Identification

Channel (AIC)

C12 Reserved

C13 Far-End Alarm and Control

(FEAC) signal

C21, C22, and C23 Unused

C31, C32, and C33 C-bit parity bits

C41, C42, and C43 Far-End Block Error (FEBE)

bits

C51, C52, and C53 Path Maintenance Data Link

(or HDLC) bits

C61, C62, and C63 Unused

C71, C72, and C73 Unused

X1 and X2 are the Remote Defect Indication (RDI) bits (also referred to as the far-end SEF/AIS bits). P1 and P2 are

the parity bits used for line error monitoring. M1, M2, and M3 are the multiframe alignment bits. FXY are the sub-

frame alignment bits. C11 is the Application Identification Channel (AIC). C12 is reserved for future network use, and

has a value of one. C13 is the Far-End Alarm and Control (FEAC) signal. C21, C22, and C23 are unused, and have a

value of one. C31, C32, and C33 are the C-bit parity bits used for path error monitoring. C41, C42, and C43 are the Far-

End Block Error (FEBE) bits used for remote path error monitoring. C51, C52, and C53 are the path maintenance

data link (or HDLC) bits. C61, C62, and C63 are unused, and have a value of one. C71, C72, and C73 are unused, and

have a value of one. The X-bit, P-bit, M-bit, C-bit, and F-bit positions are overhead bits, and the other bit positions

in the DS3 frame are payload bits.

10.10.5.2 Transmit C-bit DS3 Frame Generation

C-bit DS3 frame generation receives the incoming payload data stream, and overwrites the entire overhead bit

locations.

The multiframe alignment bits (M1, M2, and M3) are overwritten with the values zero, one, and zero (010)

respectively.

The sub-frame alignment bits (FX1, FX2, FX3, and FX4) are overwritten with the values one, zero, zero, and one

(1001) respectively.

The X-bits (X1 and X2) are both overwritten with the Remote Defect Indicator (RDI). The RDI source is

programmable (automatic, 1, or 0). If the T3.TCR.ARDID is one then the T3.TCR.TRDI register bit controls this bit.

If the RDI is generated automatically (T3.TCR.ARDID=0), the X-bits are set to zero when one or more of the

indicated alarm conditions is present, and set to one when all of the indicated alarm conditions are absent.

Automatically setting RDI on LOS, SEF, LOF, or AIS is individually programmable (on or off).

The P-bits (P1 and P2) are both overwritten with the calculated payload parity from the previous DS3 frame. The

payload parity is calculated by performing modulo 2 addition of all of the payload bits after all frame processing has

been completed. P-bit generation is programmable (on or off) via the T3.TCR.PBGE register bit. The P-bits will be

generated if either P-bit generation is enabled or frame generation is enabled.

The bits C11, C12, C21, C22, C23, C61, C62, C63, C71, C72, and C73 are all overwritten with a one.

DS3181/DS3182/DS3183/DS3184

170

The bit C13 is overwritten with the Far-End Alarm and Control (FEAC) data input from the transmit FEAC controller.

The bits C31, C32, and C33 are all overwritten with the calculated payload parity from the previous DS3 frame.

The bits C41, C42, and C43 are all overwritten with the Far-End Block Error (FEBE) bit. The FEBE bit can be

generated automatically or inserted from a register bit. The FEBE bit source is programmable (automatic or

FEBE bit is generated automatically, it is zero when at least one C-bit parity error has been detected during the

previous frame.

The bits C51, C52, and C53 are overwritten with the path maintenance data link input from the HDLC controller.

Once all of the DS3 overhead bits have been overwritten, the data stream is passed on to error insertion. If frame

generation is disabled, the incoming DS3 signal is passed on to error insertion. Frame generation is programmable

(on or off). Note: P-bit generation may still be performed even if frame generation is disabled.

10.10.5.3 Transmit C-bit DS3 Error Insertion

Error insertion inserts various types of errors into the different DS3 overhead bits. The types of errors that can be

inserted are framing errors, P-bit parity errors, C-bit parity errors, and Far-End Block Error (FEBE) errors.

The framing error insertion mode is programmable (F-bit, M-bit, SEF, or OOMF). An F-bit error is a single sub-

frame alignment bit (FXY) error. An M-bit error is a single multiframe alignment bit (M1, M2, or M3) error. An SEF

error is an error in all the sub-frame alignment bits in a sub-frame (FX1, FX2, FX3, and FX4). An OOMF error is a

single multiframe alignment bit (M1, M2, or M3) error in two consecutive DS3 frames.

A P-bit parity error is generated by is inverting the value of the P-bits (P1 and P2) in a single DS3 frame. P-bit parity

error(s) can be inserted one error at a time, or continuously. The P-bit parity error insertion mode (single or

continuous) is programmable.

A C-bit parity error is generated by is inverting the value of the C31, C32, and C33 bits in a single DS3 frame. C-bit

parity error(s) can be inserted one error at a time, or continuously. The C-bit parity error insertion mode (single or

continuous) is programmable.

A FEBE error is generated by forcing the C41, C42, and C43 bits in a single multiframe to zero. FEBE error(s) can be

inserted one error at a time, or continuously. The FEBE error insertion rate (single or continuous) is programmable.

Each error type (framing, P-bit parity, C-bit parity, or FEBE) has a separate enable. Continuous error insertion

mode inserts errors at every opportunity. Single error insertion mode inserts an error at the next opportunity when

requested. The framing multi-error modes (SEF or OOMF) insert the indicated number of error(s) at the next

opportunities when requested; i.e., a single request will cause multiple errors to be inserted. The requests can be

initiated by a register bit (TSEI) or by the manual error insertion input (TMEI). The error insertion initiation type

(register or input) is programmable. The insertion of each particular error type is individually enabled. Once all error

insertion has been performed, the data stream is passed on to overhead insertion.

10.10.5.4 Transmit C-bit DS3 Overhead Insertion

Overhead insertion can insert any (or all) of the DS3 overhead bits into the DS3 frame. The DS3 overhead bits X1,

X2, P1, P2, MX, FXY, and CXY can be sourced from the transmit overhead interface (TOHCLKn, TOHn, TOHENn, and

TOHSOFn). The P-bits (P1 and P2) and C31, C32, and C33 bits are received as an error mask (modulo 2 addition of

the input bit and the internally generated bit). The DS3 overhead insertion is fully controlled by the transmit

overhead interface. If the transmit overhead data enable signal (TOHENn) is driven high, then the bit on the

transmit overhead signal (TOHn) is inserted into the output data stream. Insertion of bits using the TOHn signal

overwrites internal overhead insertion.

10.10.5.5 Transmit C-bit DS3 AIS/Idle Generation

C-bit DS3 AIS/Idle generation overwrites the data stream with AIS or an Idle signal. If transmit Idle is enabled, the

data stream payload is forced to an 1100 pattern with two ones immediately following each DS3 overhead bit. M1,

M2, and M3 bits are overwritten with the values zero, one, and zero (010) respectively. FX1, FX2, FX3, and FX4 bits are

overwritten with the values one, zero, zero, and one (1001) respectively. X1 and X2 are overwritten with 11. And,

P1, P2, C31, C32, and C33 are overwritten with the calculated payload parity from the previous output DS3 frame.

If transmit AIS is enabled, the data stream payload is forced to a 1010 pattern with a one immediately following

each DS3 overhead bit. M1, M2, and M3 bits are overwritten with the values zero, one, and zero (010) respectively.

FX1, FX2, FX3, and FX4 bits are overwritten with the values one, zero, zero, and one (1001) respectively. X1 and X2

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are overwritten with 11. P1, P2, C31, C32, and C33 are overwritten with the calculated payload parity from the previous

output DS3 frame. And, CX1, CX2, and CX3 (X ≠ 3) are overwritten with 000. AIS will overwrite a transmit Idle signal.

10.10.5.5.1 Receive C-bit DS3 Frame Format

The DS3 frame format is shown in Figure 10-40. X1 and X2 are the Remote Defect Indication (RDI) bits (also

referred to as the far-end SEF/AIS bits). P1 and P2 are the parity bits used for line error monitoring. M1, M2, and M3

are the multiframe alignment bits that define the multiframe boundary. FXY are the sub-frame alignment bits that

define the sub-frame boundary. Note: Both the M-bits and F-bits define the DS3 frame boundary. C11 is the

Application Identification Channel (AIC). C12 is reserved for future network use, and has a value of one. C13 is the

Far-End Alarm and Control (FEAC) signal. C21, C22, and C23 are unused, and have a value of one. C31, C32, and C33

are the C-bit parity bits used for path error monitoring. C41, C42, and C43 are the Far-End Block Error (FEBE) bits

used for remote path error monitoring. C51, C52, and C53 are the path maintenance data link (or HDLC) bits. C61,

C62, and C63 are unused, and have a value of one. C71, C72, and C73 are unused, and have a value of one.

10.10.5.5.2 Receive C-bit DS3 Overhead Extraction

Overhead extraction extracts all of the DS3 overhead bits from the C-bit DS3 frame. All of the DS3 overhead bits

X1, X2, P1, P2, MX, FXY, and CXY are output on the receive overhead interface (ROH, ROHSOF, and ROHCLK). The

P1, P2, C31, C32, and C33 bits are output as an error indication (modulo 2 addition of the calculated parity and the

bit). In addition, the Application Identification Channel (AIC), which is stored in a register bit, is determined from the

C11 bit. The AIC is set to one (C-bit format) if the C11 bit is set to one in 31 consecutive multiframes. The AIC is set

to zero (M23 format) if the C11 bit is set to zero in four of the last 31 consecutive multiframes. Note: The stored AIC

bit must not change when a LOS, OOF, or AIS condition is present. The C13 bit is sent over to the receive FEAC

controller. The C51, C52, and C53 bits are sent to the receive HDLC overhead controller.

10.10.6 M23 DS3 Framer/Formatter

10.10.6.1 Transmit M23 DS3 Frame Processor

The M23 DS3 frame format is shown in Figure 10-40. Table 10-35 defines the framing bits for M23 DS3. X1 and X2

are the Remote Defect Indication (RDI) bits (also referred to as the far-end SEF/AIS bits). P1 and P2 are the parity

bits used for line error monitoring. M1, M2, and M3 are the multiframe alignment bits. FXY are the sub-frame

alignment bits. C11 is the Application Identification Channel (AIC). CX1, CX2, and CX3 are the stuff control bits for

tributary #X. The X-bit, P-bit, M-bit, C-bit, and F-bit positions are overhead bits, and the other bit positions in the

DS3 frame are payload bits.

Table 10-35. M23 DS3 Frame Overhead Bit Definitions

BIT DEFINITION

X1, X2 Remote Defect Indication

(RDI)

P1, P2 Parity Bits

M1, M2, and M3 Multiframe Alignment Bits

FXY Sub-frame Alignment Bits

C11 Application Identification

Channel (AIC)

CX1, CX2, and CX3 Stuff Control Bits for Tributary

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10.10.6.2 Transmit M23 DS3 Frame Generation

M23 DS3 frame generation receives the incoming payload data stream, and overwrites the entire DS3 overhead bit

locations.

The multiframe alignment bits (M1, M2, and M3) are overwritten with the values zero, one, and zero (010)

respectively.

The sub-frame alignment bits (FX1, FX2, FX3, and FX4) are overwritten with the values one, zero, zero, and one

(1001) respectively.

The X-bits (X1 and X2) are both overwritten with the Remote Defect Indicator (RDI). The RDI source is

programmable (automatic, 1, or 0). If the T3.TCR.ARDID is one then the T3.TCR.TRDI register bit controls this bit.

If the RDI is generated automatically (T3.TCR.ARDID=0), the X-bits are set to zero when one or more of the

indicated alarm conditions is present, and set to one when all of the indicated alarm conditions are absent.

Automatically setting RDI on LOS, SEF, LOF, or AIS is individually programmable (on or off).

The P-bits (P1 and P2) are both overwritten with the calculated payload parity from the previous DS3 frame. The

payload parity is calculated by performing modulo 2 addition of all of the payload bits after all frame processing has

been completed. P-bit generation is programmable (on or off). The P-bits will be generated if either P-bit generation

is enabled or frame generation is enabled.

If C-bit generation is enabled (T3.TCR.CBGD), the bit C11 is overwritten with an alternating one zero pattern, and

all of the other C-bits (CXY) are overwritten with zeros. If C-bit generation is disabled, then all of the C-bit timeslots

(CXY) will be treated as payload data, and passed through. C-bit generation is programmable (on or off). Note:

Overhead insertion may still overwrite the C-bit time slots even if C-bit generation is disabled.

Once all of the DS3 overhead bits have been overwritten, the data stream is passed on to error insertion. If frame

generation is disabled, the incoming DS3 signal is passed on directly to error insertion. Frame generation is

programmable (on or off). Note: P-bit generation may still be performed even if frame generation is disabled.

10.10.6.3 Transmit M23 DS3 Error Insertion

Error insertion inserts various types of errors into the different DS3 overhead bits. The types of errors that can be

inserted are framing errors and P-bit parity errors.

The framing error insertion mode is programmable (F-bit, M-bit, SEF, or OOMF). An F-bit error is a single sub-

frame alignment bit (FXY) error. An M-bit error is a single multiframe alignment bit (M1, M2, or M3) error. An SEF

error is an error in all the sub-frame alignment bits in a sub-frame (FX1, FX2, FX3, and FX4). An OOMF error is a

single multiframe alignment bit (M1, M2, or M3) error in each of two consecutive DS3 frames.

A P-bit parity error is generated by is inverting the value of the P-bits (P1 and P2) in a single DS3 frame. P-bit parity

error(s) can be inserted one error at a time, or continuously. The P-bit parity error insertion mode (single or

continuous) is programmable.

Each error type (framing or P-bit parity) has a separate enable. Continuous error insertion mode inserts errors at

every opportunity. Single error insertion mode inserts an error at the next opportunity when requested. The framing

multi-error insertion modes (SEF or OOMF) insert the indicated number of error(s) at the next opportunities when

requested; i.e., a single request will cause multiple errors to be inserts. The requests can be initiated by a register

bit (TSEI) or by the manual error insertion input (TMEI). The error insertion request source (register or input) is

programmable. The insertion of each particular error type is individually enabled. Once all error insertion has been

performed, the data stream is passed on to overhead insertion.

10.10.6.4 Transmit M23 DS3 Overhead Insertion

Overhead insertion can insert any (or all) of the DS3 overhead bits into the DS3 frame. The DS3 overhead bits X1,

X2, P1, P2, MX, FXY, and CXY can be sourced from the transmit overhead interface (TOHCLK, TOH, TOHEN, and

TOHSOF). The P-bits (P1 and P2) are received as an error mask (modulo 2 addition of the input bit and the

internally generated bit). The DS3 overhead insertion is fully controlled by the transmit overhead interface. If the

transmit overhead data enable signal (TOHEN) is driven high, then the bit on the transmit overhead signal (TOH) is

inserted into the output data stream. Insertion of bits using the TOH signal overwrites internal overhead insertion.

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10.10.6.5 Transmit M23 DS3 AIS/Idle Generation

M23 DS3 AIS/Idle generation overwrites the data stream with AIS or an Idle signal. If transmit Idle is enabled, the

data stream payload is forced to an 1100 pattern with two ones immediately following each DS3 overhead bit. M1,

M2, and M3 bits are overwritten with the values zero, one, and zero (010) respectively. FX1, FX2, FX3, and FX4 bits are

overwritten with the values one, zero, zero, and one (1001) respectively. X1 and X2 are overwritten with 11.. P1 and

P2 are overwritten with the calculated payload parity from the previous output DS3 frame. And, C31, C32, and C33

are overwritten with 000.

If transmit AIS is enabled, the data stream payload is forced to a 1010 pattern with a one immediately following

each DS3 overhead bit. M1, M2, and M3 bits are overwritten with the values zero, one, and zero (010) respectively.

FX1, FX2, FX3, and FX4 bits are overwritten with the values one, zero, zero, and one (1001) respectively. X1 and X2

are overwritten with 11. P1 and P2 are overwritten with the calculated payload parity from the previous DS3 frame.

And, CX1, CX2, and CX3 are overwritten with 000. AIS will overwrite a transmit Idle signal.

10.10.6.5.1 Receive M23 DS3 Frame Format

The DS3 frame format is shown in Figure 10-40. The X1 and X2 are the Remote Defect Indication (RDI) bits (also

referred to as the far-end SEF/AIS bits). P1 and P2 are the parity bits used for line error monitoring. M1, M2, and M3

are the multiframe alignment bits that define the multiframe boundary. FXY are the sub-frame alignment bits that

define the sub-frame boundary. Note: Both the M-bits and F-bits define the DS3 frame boundary. C11 is the

Application Identification Channel (AIC). CX1, CX2, and CX3 are the stuff control bits for tributary #X.

10.10.6.5.2 Receive M23 DS3 Overhead Extraction

Overhead extraction extracts all of the DS3 overhead bits from the M23 DS3 frame. All of the DS3 overhead bits

X1, X2, P1, P2, MX, FXY, and CXY are output on the receive overhead interface (ROH, ROHSOF, and ROHCLK). The

P1 and P2 bits are output as an error indication (modulo 2 addition of the calculated parity and the bit). In addition,

the Application Identification Channel (AIC) is extracted from the C11 bit and stored in a register. The AIC is set to

one (C-bit format) if the C11 bit is set to one in 31 consecutive multiframes. The AIC is set to zero (M23 format) if

the C11 bit is set to zero in four of the last 31 consecutive multiframes. Note: The stored AIC bit must not change

when a LOS, OOF, or AIS condition is present.

10.10.6.5.3 Receive DS3 Downstream AIS Generation

Downstream DS3 AIS (all ‘1’s) can be automatically generated on an OOF, LOS, or AIS condition or manually

inserted. If automatic downstream AIS is enabled, downstream AIS is inserted when an LOS or AIS condition is

declared, or no earlier than 2.25 ms and no later than 2.75 ms after an OOF condition is declared. Automatic

downstream AIS is programmable (on or off). If manual downstream AIS insertion is enabled, downstream AIS is

inserted. Manual downstream AIS insertion is programmable (on or off). Downstream AIS is removed when all

OOF, LOS, and AIS conditions are terminated and manual downstream AIS insertion is disabled.

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10.10.7 G.751 E3 Framer/Formatter

10.10.7.1 Transmit G.751 E3 Frame Processor

The G.751 E3 frame format is shown in Figure 10-43. FAS is the Frame Alignment Signal. A is the Alarm indication

bit used to indicate the presence of an alarm to the remote terminal equipment. N is the National use bit reserved

for national use.

Figure 10-43. G.751 E3 Frame Format

FAS

1524 Bit Payload

384 bits

4 Rows

A N

10.10.7.2 Transmit G.751 E3 Frame Generation

G.751 E3 frame generation receives the incoming payload data stream, and overwrites the entire E3 overhead bit

locations.

The first 10 bits of the frame are overwritten with the frame alignment signal (FAS), which has a value of

1111010000b.

The 11th bit of the frame is overwritten with the alarm indication (A) bit. The A bit can be generated automatically,

sourced from the transmit FEAC controller, set to one, or set to zero. The A bit source is programmable (automatic,

FEAC, 1, or 0). If the A bit is generated automatically, it is set to one when one or more of the indicated alarm

conditions is present, and set to zero when all of the indicated alarm conditions are absent. Automatically setting

RDI on LOS, LOF, or AIS is individually programmable (on or off).

The twelfth bit of the frame is overwritten with the national use (N) bit. The N bit can be sourced from the transmit

FEAC controller, sourced from the transmit HDLC overhead controller, set to one, or set to zero. The N bit source

is programmable (FEAC, HDLC, 1, or 0). Note: The FEAC controller will source one bit per frame regardless of

whether the A bit only, the N bit only, or both are programmed to be sourced from the FEAC controller.

Once all of the E3 overhead bits have been overwritten, the data stream is passed on to error insertion. If frame

generation is disabled, the incoming E3 signal is passed on directly to error insertion. Frame generation is

programmable (on or off).

10.10.7.3 Transmit G.751 E3 Error Insertion

Error insertion inserts framing errors into the frame alignment signal (FAS). The type of error(s) inserted into the

FAS is programmable (errored FAS bit or errored FAS). An errored FAS bit is a single bit error in the FAS. An

errored FAS is an error in all ten bits of the FAS (a value of 0000101111b is inserted in the FAS). Framing error(s)

can be inserted one error at a time, or in four consecutive frames. The framing error insertion number (single or

four) is programmable.

Single error insertion mode inserts an error at the next opportunity when requested. The multi-error insertion mode

inserts the indicated number of errors at the next opportunities when requested. That is, a single request will cause

multiple errors to be inserted. The requests can be initiated by a register bit (TSEI) or by the manual error insertion

input (TMEI). The error insertion initiation type (register or input) is programmable. The insertion of each particular

error type is individually enabled.

Once all error insertion has been performed, the data stream is passed on to overhead insertion.

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10.10.7.4 Transmit G.751 E3 Overhead Insertion

Overhead insertion can insert any (or all) of the E3 overhead bits into the E3 frame. The FAS, A bit, and N bit can

be sourced from the transmit overhead interface (TOHCLK, TOH, TOHEN, and TOHSOF). The E3 overhead

insertion is fully controlled by the transmit overhead interface. If the transmit overhead data enable signal (TOHEN)

is driven high, then the bit on the transmit overhead signal (TOH) is inserted into the output data stream. Insertion

of bits using the TOH signal overwrites internal overhead insertion.

10.10.7.5 Transmit G.751 E3 AIS Generation

G.751 E3 AIS generation overwrites the data stream with AIS. If transmit AIS is enabled, the data stream (payload

and E3 overhead) is forced to all ones.

10.10.7.6 Receive G.751 E3 Frame Processor

The G.751 E3 frame format is shown in Figure 10-43. FAS is the Frame Alignment Signal. A is the Alarm indication

bit used to indicate the presence of an alarm to the remote terminal equipment. N is the National use bit reserved

for national use.

10.10.7.6.1 Receive G.751 E3 Framing

G.751 E3 framing determines the G.751 E3 frame boundary. The frame boundary is found by identifying the frame

alignment signal (FAS), which has a value of 1111010000b. The framer is an off-line framer that updates the data

path frame counters when an out of frame (OOF) condition has been detected. The use of an off-line framer

reduces the average time required to reframe, and reduces data loss caused by burst error. The G.751 E3 framer

checks each bit position for the FAS. The frame boundary is set once the FAS is identified. Since, the FAS check is

performed one bit at a time, up to 1536 checks may be needed to find the frame boundary. The data path frame

counters are updated if an error free FAS is received for two additional frames, and an OOF condition is present, or

if a manual frame re-synchronization has been initiated.

10.10.7.6.2 Receive G.751 E3 Performance Monitoring

Performance monitoring checks the E3 frame for alarm conditions. The alarm conditions detected are OOF, LOF,

COFA, LOS, AIS, RUA1, and RAI. An Out Of Frame (OOF) condition is declared when four consecutive frame

alignment signals (FAS) contain one or more errors or at the next FAS check when a manual reframe is requested.

An OOF condition is terminated when three consecutive FASs are error-free or the G.751 E3 framer updates the

data path frame counters.

A Loss Of Frame (LOF) condition is declared by the LOF integration counter when it has been active for a total of T

ms. The LOF integration counter is active (increments count) when an OOF condition is present, it is inactive (holds

count) when an OOF condition is absent, and it is reset when an OOF condition is absent for T continuous ms. T is

programmable (0, 1, 2, or 3). An LOF condition is terminated when an OOF condition is absent for T continuous

ms.

A Change Of Frame Alignment (COFA) is declared when the G.751 E3 framer updates the data path frame

counters with a frame alignment that is different from the current data path frame alignment.

A Loss Of Signal (LOS) condition is declared when the HDB3 encoder is active, and it declares a LOS condition. A

LOS condition is terminated when the HDB3 encoder is inactive, or it terminates a LOS condition.

An Alarm Indication Signal (AIS) condition is declared when 4 or less zeros are detected in each of two consecutive

frame periods. An AIS condition is terminated when 5 or more zeros are detected in each of two consecutive frame

periods.

A Receive Unframed All 1’s (RUA1) condition is declared if in each of 4 consecutive 2047 bit windows, five or less

zeros are detected and an OOF condition is continuously present. A RUA1 condition is terminated if in each of 4

consecutive 2047-bit windows, six or more zeros are detected or an OOF condition is continuously absent.

A Remote Alarm Indication (RAI) condition is declared when four consecutive frames are received with the A bit

(first bit after the FAS) set to one. An RAI condition is terminated when four consecutive frames are received with

the A bit set to zero.

Only framing errors are accumulated. Framing errors are determined by comparing the FAS to its expected value.

The type of framing errors accumulated is programmable (OOF, bit, or word). An OOF error increments the count

whenever an OOF condition is first detected. A bit error increments the count once for each bit in the FAS that does

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not match its expected value (up to 10 per frame. A word error increments the count once for each FAS that does

not match its expected value (up to 1 per frame).

The receive alarm indication (RAI) signal is high when one or more of the indicated alarm conditions is present, and

low when all of the indicated alarm conditions are absent. Setting the receive alarm indication on LOS, OOF, LOF,

or AIS is individually programmable (on or off).

10.10.7.6.3 Receive G.751 E3 Overhead Extraction

Overhead extraction extracts all of the E3 overhead bits from the G.751 E3 frame. The FAS, A bit, and N bit are

output on the receive overhead interface (ROH, ROHSOF, and ROHCLK). In addition, the A bit is integrated and

stored in a register along with a change indication, and can be output over the receive FEAC controller. The N bit is

integrated and stored in a register along with a change indication, is sent to the receive HDLC overhead controller,

and can also be sent to the receive FEAC controller. The bit sent to the receive FEAC controller is programmable

(A or N).

10.10.7.6.4 Receive G.751 Downstream AIS Generation

Downstream G.751 E3 AIS can be automatically generated on an OOF, LOS, or AIS condition or manually

inserted. If automatic downstream AIS is enabled, downstream AIS is inserted when a LOS, OOF, or AIS condition

is declared. Automatic downstream AIS is programmable (on or off). If manual downstream AIS insertion is

enabled, downstream AIS is inserted. Manual downstream AIS insertion is programmable (on or off). Downstream

AIS is removed when all OOF, LOS, and AIS conditions are terminated and manual downstream AIS insertion is

disabled. RPDT will be forced to all ones during downstream AIS.

10.10.8 G.832 E3 Framer/Formatter

10.10.8.1 Transmit G.832 E3 Frame Processor

The G.832 E3 frame format is shown in Figure 10-44.

Figure 10-44. G.832 E3 Frame Format

FA1

FA2

530 Byte Payload

59 Columns

9 Rows

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Figure 10-45. MA Byte Format

RDI - Remote Defect Indicator

REI - Remote Error Indicator

SL - Signal Label

MI - Multi-frame Indicator

TM - Timing Marker

RDI REI SL SL SL MI MI TM

MSB

LSB

Table 10-36 shows the function of each overhead bit in the DS3 Frame.

Table 10-36. G.832 E3 Frame Overhead Bit Definitions

BYTE DEFINITION

FA1, FA2 Frame Alignment bytes

EM Error Monitoring byte

TR Trail Trace byte

MA Maintenance and Adaptation

byte

NR Network Operator byte

GC General-Purpose

Communication Channel byte

FA1 and FA2 are the Frame Alignment bytes. EM is the Error Monitoring byte used for path error monitoring. TR is

the Trail Trace byte used for end-to-end connectivity verification. MA is the Maintenance and Adaptation byte used

for far-end path status and performance monitoring.

NR is the Network Operator byte allocated for network operator maintenance purposes. GC is the General-Purpose

Communications Channel byte allocated for user communications purposes.

10.10.8.2 Transmit G.832 E3 Frame Generation

G.832 E3 frame generation receives the incoming payload data stream, and overwrites all of the E3 overhead byte

locations.

The first two bytes of the first row in the frame are overwritten with the frame alignment bytes FA1 and FA2, which

have a value of F6h and 28h respectively.

The first byte in the second row of the frame is overwritten with the EM byte which is a BIP-8 calculated over all of

the bytes of the previous frame after all frame processing (frame generation, error insertion, overhead insertion,

and AIS generation) has been performed. The first byte in the third row of the frame is overwritten with the TR byte

which is input from the transmit trail trace controller.

The first byte in the fourth row of the frame is overwritten with the MA byte (see Figure 10-45), which consists of the

RDI bit, REI bit, payload type, multiframe indicator, and timing source indicator.

The RDI (remote defect indicator) bit can be generated automatically, set to one, or set to zero. The RDI source is

programmable (automatic, 1, or 0). If the RDI is generated automatically, it is set to one when one or more of the

indicated alarm conditions are detected on the receive side, and set to zero when all of the indicated alarm

conditions are absent. Automatically setting RDI on LOS, LOF, or AIS is individually programmable (on or off).

The REI (remote error indicator) bit can be generated automatically or inserted from a register bit

(E3G832.TCR.TFEBE). The REI source is programmable (automatic or register bit). If REI is generated

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automatically, it is set to one when at least one parity error has been detected on the receive side during the

previous frame.

The payload type is sourced from a register. The three register bits are inserted in the third, fourth, and fifth bits of

the MA byte in each frame.

The multiframe indicator and timing marker bits can be directly inserted from a 3-bit register or generated from a 4-

bit register. The multiframe indicator and timing marker insertion type is programmable (direct or generated). When

the multiframe indicator and timing marker bits are directly inserted, the three register bits are inserted in the last

three bits of the MA byte in each frame. When the multiframe indicator and timing marker bits are generated, the

four timing source indicator bits are transferred in a four-frame multiframe, MSB first. The multiframe indicator bits

(sixth and seventh bits of the MA byte) identify the phase of the multiframe (00, 01, 10, or 11), and the timing

marker bit (eighth bit of the MA byte) contains the corresponding timing source indicator bit (TMABR register bits

TTI3, TTI2, TTI1, or TTI0 respectively). Note: The initial phase of the multiframe is arbitrarily chosen.

The first byte in the fifth row of the frame is overwritten with the NR byte which can be sourced from a register, from

the transmit FEAC controller, or from the transmit HDLC controller. The NR byte source is programmable (register,

FEAC, or HDLC). Note: The HDLC controller will source eight bits per frame period regardless of whether the NR

byte only, GC byte only, or both are programmed to be sourced from the HDLC controller.

The first byte in the sixth row of the frame is overwritten with the GC byte which can be sourced from a register or

from the transmit HDLC controller. The GC byte source is programmable (register or HDLC).

Once all of the E3 overhead bytes have been overwritten, the data stream is passed on to error insertion. If frame

generation is disabled, the incoming E3 signal is passed on directly to error insertion. Frame generation is

programmable (on or off).

10.10.8.3 Transmit G.832 E3 Error Insertion

Error insertion inserts various types of errors into the different E3 overhead bytes. The types of errors that can be

inserted are framing errors, BIP-8 parity errors, and Remote Error Indication (REI) errors.

The type of framing error(s) inserted is programmable (errored frame alignment bit or errored frame alignment

word). A frame alignment bit error is a single bit error in the frame alignment word (FA1 or FA2). A frame alignment

word error is an error in all 16 bits of the frame alignment word (the values 09h and D7h are inserted in the FA1

and FA2 bytes, respectively). Framing error(s) can be inserted one error at a time, or four consecutive frames. The

framing error insertion mode (single or four) is programmable.

The type of BIP-8 error(s) inserted is programmable (errored BIP-8 bit or errored BIP-8 byte). An errored BIP-8 bit

is inverting a single bit error in the EM byte. An errored BIP-8 byte is inverting all eight bits in the EM byte. BIP-8

error(s) can be inserted one error at a time, or continuously. The BIP-8 error insertion mode (single or continuous)

is programmable.

An REI error is generated by forcing the second bit of the MA byte to a one. REI error(s) can be inserted one error

at a time, or continuously. The REI error insertion mode (single or continuous) is programmable.

Each error type (framing, BIP-8, or REI) has a separate enable. Continuous error insertion mode inserts errors at

every opportunity. Single error insertion mode inserts an error at the next opportunity when requested. The framing

multi-error insertion mode inserts the indicated number of errors at the next opportunities when requested. I.e., a

single request will cause multiple errors to be inserted. The requests can be initiated by a register bit (TSEI) or by

the manual error insertion input (TMEI). The error insertion request source (register or input) is programmable. The

insertion of each particular error type is individually enabled. Once all error insertion has been performed, the data

stream is passed on to overhead insertion.

10.10.8.4 Transmit G.832 E3 Overhead Insertion

Overhead insertion can insert any (or all) of the E3 overhead bytes into the E3 frame. The E3 overhead bytes FA1,

FA2, EM, TR, MA, NR, and GC can be sourced from the transmit overhead interface (TOHCLK, TOH, TOHEN, and

TOHSOF). The EM byte is sourced as an error mask (modulo 2 addition of the input EM byte and the generated

EM byte). The E3 overhead insertion is fully controlled by the transmit overhead interface. If the transmit overhead

data enable signal (TOHEN) is driven high, then the bit on the transmit overhead signal (TOH) is inserted into the

output data stream. Insertion of bits using the TOH signal overwrites internal overhead insertion.

DS3181/DS3182/DS3183/DS3184

179

10.10.8.5 Transmit G.832 E3 AIS Generation

G.832 E3 AIS generation overwrites the data stream with AIS. If transmit AIS is enabled, the data stream (payload

and E3 overhead) is forced to all ones.

10.10.8.6 Receive G.832 E3 Frame Processor

The G.832 E3 frame format is shown in Figure 10-44. FA1 and FA2 are the Frame Alignment bytes. EM is the Error

Monitoring byte used for path error monitoring. TR is the Trail Trace byte used for end-to-end connectivity

verification. MA is the Maintenance and Adaptation byte used for far-end path status and performance monitoring

(See Figure 10-45). NR is the Network Operator byte allocated for network operator maintenance purposes. GC is

the General-Purpose Communications Channel byte allocated for user communications purposes.

10.10.8.7 Receive G.832 E3 Framing

G.832 E3 framing determines the G.832 E3 frame boundary. The frame boundary is found by identifying the frame

alignment bytes FA1 and FA2, which have a value of F6h and 28h, respectively. The framer is an off-line framer

that updates the data path frame counters when an out of frame (OOF) condition has been detected. The use of an

off-line framer reduces the average time required to reframe, and reduces data loss caused by burst error. The

G.832 E3 framer checks each bit position for the frame alignment word (FA1 and FA2). The frame boundary is set

once the frame alignment word is identified. Since, the frame alignment word check is performed one bit at a time;

up to 4296 checks may be needed to find the frame boundary. The data path frame counters are updated if an

error free frame alignment word is received for two additional frames, and an OOF condition is present.

10.10.8.8 Receive G.832 E3 Performance Monitoring

Performance monitoring checks the E3 frame for alarm conditions and errors. The alarm conditions detected are

OOF, LOF, COFA, LOS, AIS, RUA1, and RDI. The errors accumulated are framing, parity, and Remote Error

Indication (REI) errors. An Out Of Frame (OOF) condition is declared when four consecutive frame alignment

words (FA1 and FA2) contain one or more errors, when 986 or more frames out of 1,000 frames has a BIP-8 block

error, or at the next framing word check when a manual reframe is requested. An OOF condition is terminated

when three consecutive frame alignment words (FA1 and FA2) are error free or the G.832 E3 framer updates the

data path frame counters.

A Loss Of Frame (LOF) condition is declared by the LOF integration counter when it has been active for a total of T

ms. The LOF integration counter is active (increments count) when an OOF condition is present, it is inactive (holds

count) when an OOF condition is absent, and it is reset when an OOF condition is absent for T continuous ms. T is

programmable (0, 1, 2, or 3). An LOF condition is terminated when an OOF condition is absent for T continuous

ms.

A Change Of Frame Alignment (COFA) is declared when the G.832 E3 framer updates the data path frame

counters with a frame alignment that is different from the current data path frame alignment.

A Loss Of Signal (LOS) condition is declared when the HDB3 encoder is active, and it declares a LOS condition. A

LOS condition is terminated when the HDB3 encoder is inactive, or it terminates a LOS condition.

An Alarm Indication Signal (AIS) condition is declared when 7 or less zeros are detected in each of two consecutive

frame periods that do not contain a frame alignment word. An AIS condition is terminated when 8 or more zeros are

detected in each of two consecutive frame periods.

A Receive Unframed All 1’s (RUA1) condition is declared if in each of 4 consecutive 2047 bit windows, five or less

zeros are detected and an OOF condition is continuously present. A RUA1 condition is terminated if in each of 4

consecutive 2047-bit windows, six or more zeros are detected or an OOF condition is continuously absent.

A Remote Defect Indication (RDI) condition is declared when four consecutive frames are received with the RDI bit

(first bit of MA byte) set to one. An RDI condition is terminated when four consecutive frames are received with the

RDI bit set to zero.

Three types of errors are accumulated, framing, parity, and Remote Error Indication (REI) errors. Framing errors

are determined by comparing FA1 and FA2 to their expected values. The type of framing errors accumulated is

programmable (OOF, bit, byte, or word). An OOF error increments the count whenever an OOF condition is first

detected. A bit error increments the count once for each bit in FA1 and each bit in FA2 that does not match its

expected value (up to 16 per frame). A byte error increments the count once for each FA byte (FA1 or FA2) that

does not match its expected value (up to 2 per frame). A word error increments the count once for each FA word

(both FA1 and FA2) that does not match its expected value (up to 1 per frame).

DS3181/DS3182/DS3183/DS3184

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Parity errors are determined by calculating the BIP-8 (8-Bit Interleaved Parity) of the current E3 frame (overhead

and payload bytes), and comparing the calculated BIP-8 to the EM byte in the next frame. The type of parity errors

accumulated is programmable (bit or block). A bit error increments the count once for each bit in the EM byte that

does not match the corresponding bit in the calculated BIP-8 (up to 8 per frame). A block error increments the

count if any bit in the EM byte does not match the corresponding bit in the calculated BIP-8 (up to 1 per frame).

REI errors are determined by the REI bit (second bit of MA byte). A one indicates an error and a zero indicates no

errors.

The receive defect indication (RDI) alarm is transmitted when the receive framer detects one or more of the

indicated alarm conditions. The RDI bit is not transmitted when all of the indicated alarm conditions are absent. The

RDI bit in the MA byte of the G.832 overhead is set high in the transmit formatter to transmit the alarm. Setting the

receive defect indication on LOS, OOF, LOF, or AIS is individually programmable (on or off).

The receive error indication (REI) bit of the MA byte in the transmit frame will transition from low to high once for

each frame in which a parity error is detected by the receive framer.

10.10.8.9 Receive G.832 E3 Overhead Extraction

Overhead extraction extracts all of the E3 overhead bytes from the G.832 E3 frame. All of the E3 overhead bytes

FA1, FA2, EM, TR, MA, NR, and GC are output on the receive overhead interface (ROH, ROHSOF, and

ROHCLK).

The EM byte is output as an error indication (modulo 2 addition of the calculated BIP-8 and the EM byte.

The TR byte is sent to the receive trail trace controller.

The payload type (third, fourth, and fifth bits of the MA byte) is integrated and stored in a register with change and

unstable indications. The integrated received payload type is also compared against an expected payload type. If

the received and expected payload types do not match (See Table 10-37), a mismatch indication is set.

Table 10-37. Payload Label Match Status

EXPECTED RECEIVED STATUS

000 000 Match

000 001 Mismatch

000 XXX Mismatch

001 000 Mismatch

001 001 Match

001 XXX Match

XXX 000 Mismatch

XXX 001 Match

XXX XXX Match

XXX YYY Mismatch

XXX and YYY equal any value other than 000 or 001; XXX

≠

YYY

The multiframe indicator and timing marker bits (sixth, seventh, and eighth bits of the MA byte) can be integrated

and stored in three register bits or extracted, integrated, and stored in four register bits. The bits (three or four) are

stored with a change indication. The multiframe indicator and timing marker storage type is programmable

(integrated or extracted). When the multiframe indicator and timing marker bits are integrated, the last three bits of

the MA byte are integrated and stored in three register bits. When the multiframe indicator and timing marker bits

are extracted, four timing source indicator bits are transferred in a four-frame multiframe, MSB first. The multiframe

indicator bits (sixth and seventh bits of the MA byte) identify the phase of the multiframe (00, 01, 10, or 11). The

timing marker bit (eighth bit of the MA byte) contains the timing source indicator bit indicated by the multiframe

indicator bits (first, second, third, or fourth bit, respectively). The four timing source indicator bits are extracted from

the multiframe, integrated, and stored in four register bits with unstable and change indications.

DS3181/DS3182/DS3183/DS3184

181

The NR byte is integrated and stored in a register along with a change indication, it is sent to the receive FEAC

controller, and it can be sent to the receive HDLC controller. The byte sent to the receive HDLC controller is

programmable (NR or GC).

The GC byte is integrated and stored in a register along with a change indication, and can be sent to the receive

HDLC controller. The byte sent to the receive HDLC controller is programmable (NR or GC).

10.10.8.10 Receive G.832 Downstream AIS Generation

Downstream G.832 E3 AIS can be automatically generated on an OOF, LOS, or AIS condition or manually

inserted. If automatic downstream AIS is enabled, downstream AIS is inserted when a LOS, OOF, or AIS condition

is declared. Automatic downstream AIS is programmable (on or off). If manual downstream AIS insertion is

enabled, downstream AIS is inserted. Manual downstream AIS insertion is programmable (on or off). Downstream

AIS is removed when all OOF, LOS, and AIS conditions are terminated and manual downstream AIS insertion is

disabled. RPDT will be forced to all ones during downstream AIS.

10.10.9 Clear-Channel Frame Processor

10.10.9.1 Transmit Clear-Channel AIS Generation

Clear-channel AIS generation overwrites the data stream with AIS. If transmit AIS is enabled, the data stream

(payload) is forced to all ones.

10.10.9.2 Receive Clear-Channel Performance Monitoring

Performance monitoring checks the clear-channel signal for alarm conditions. The alarm conditions detected are

LOS and RUA1. A Loss Of Signal (LOS) condition is declared when the B3ZS/HDB3 encoder is active, and it

declares a LOS condition. A LOS condition is terminated when the B3ZS/HDB3 encoder is inactive, or it terminates

a LOS condition.

A Receive Unframed All 1’s (RUA1) condition is declared if in each of 4 consecutive 2047 bit windows, five or less

zeros are detected. A RUA1 condition is terminated if in each of 4 consecutive 2047 bit windows, six or more zeros

are detected.

10.10.9.3 Receive Clear-Channel Downstream AIS Generation

Downstream clear-channel AIS can be automatically generated on a LOS condition or manually inserted. If

automatic downstream AIS is enabled, downstream AIS is inserted when a LOS condition is declared. Automatic

downstream AIS is programmable (on or off). If manual downstream AIS insertion is enabled, downstream AIS is

inserted. Manual downstream AIS insertion is programmable (on or off). Downstream AIS is removed when all LOS

conditions are terminated and manual downstream AIS insertion is disabled. All bits will be forced to ones during

downstream AIS.

10.11 HDLC Overhead Controller

10.11.1 General Description

The DS318x devices contain built-in HDLC controllers (one per port) with 256-byte FIFOs for insertion/extraction of

DS3 PMDL, G.751 Sn bit and G.832 NR/GC bytes and PLCP NR/GC bytes.

The HDLC Overhead Controller demaps HDLC overhead packets from the DS3/E3 data stream in the receive

direction and maps HDLC packets into the DS3/E3 data stream in the transmit direction.

The receive direction performs packet processing and stores the packet data in the FIFO. It removes packet data

from the FIFO and outputs the packet data to the microprocessor via the register interface.

The transmit direction inputs the packet data from the microprocessor via the register interface and stores the

packet data in the FIFO. It removes the packet data from the FIFO and performs packet processing.

The bits in a byte are received MSB first, LSB last. When they are output serially, they are output MSB first, LSB

last. The bits in a byte in an incoming signal are numbered in the order they are received, 1 (MSB) to 8 (LSB).

However, when a byte is stored in a register, the MSB is stored in the lowest numbered bit (0), and the LSB is

stored in the highest numbered bit (7). This is to differentiate between a byte in a register and the corresponding

byte in a signal.

DS3181/DS3182/DS3183/DS3184

182

See Figure 10-46 for the location of HDLC controllers within the DS318x devices.

Figure 10-46. HDLC Controller Block Diagram

DS3/E3

Trans mit

LIU

IEEE P1149.1

JTAG Test

Access Port

Microprocessor

Inte rf ac e

HDLC

FEAC

LLB

DLB

DS3 / E3

Transmit

Formatter

DS3 / E3

Rec eiv e

Framer

Trail

Trac e

Buffer

Tx Cell

Processor Tx

FIFO

System

Interface

Rx Cell

Processor

FIFO

Tx Pac ket

Processor

SLB

Rx Pac ket

Processor

DS3/E3

Rec e iv e

LIU

TAIS

TUA 1

TX FRA C/

PL CP

RX FRA C/

PLCP

Cloc k Rate

Adapter

TX BERT

RX BERT

PLB

ALB

UA 1

GEN

B3ZS/

HDB3

Encoder

B3ZS/

HDB3

Dec oder

10.11.2 Features

• Programmable inter-frame fill – The inter-frame fill between packets can be all 1’s or flags.

• Programmable FCS generation/monitoring – A FCS-16 can be generated and appended to the end of the

packet, and the FCS can be checked and removed from the end of the packet.

• Programmable bit reordering – The packet data can be can be output MSB first or LSB first from the FIFO.

• Programmable data inversion – The packet data can be inverted immediately after packet processing on the

transmit, and immediately before packet processing on the receive.

• Fully independent transmit and receive paths

• Fully independent Line side and register interface timing – The data storage can be read from or written to

via the microprocessor interface while all line side clocks and signals are inactive, and read from or written to

via the line side while all microprocessor interface clocks and signals are inactive.

10.11.3 Transmit FIFO

The Transmit FIFO block contains memory for 256 bytes of data with data status information and controller circuitry

for reading and writing the memory. The Transmit FIFO controller functions include filling the memory, tracking the

memory fill level, maintaining the memory read and write pointers, and detecting memory overflow and underflow

conditions. The Transmit FIFO receives data and status from the microprocessor interface, and stores the data

along with the data status information in memory. The Transmit Packet Processor reads the data and data status

information from the Transmit FIFO. The Transmit FIFO also outputs FIFO fill status (empty/data storage

available/full) via the microprocessor interface. All operations are byte based. The Transmit FIFO is considered

empty when its memory does not contain any data. The Transmit FIFO is considered to have data storage

available when its memory has a programmable number of bytes or more available for storage. The Transmit FIFO

is considered full when it does not have any space available for storage. The Transmit FIFO accepts data from the

register interface until full. If the Transmit FIFO is written to while the FIFO is full, the write is ignored, and a FIFO

overflow condition is declared. The Transmit Packet Processor reads the Transmit FIFO. If the Transmit Packet

Processor attempts to read the Transmit FIFO while it is empty, a FIFO underflow condition is declared.

10.11.4 Transmit HDLC Overhead Processor

The Transmit HDLC Overhead Processor accepts data from the Transmit FIFO, performs bit reordering, FCS

processing, stuffing, packet abort sequence insertion, and inter-frame padding.

A byte is read from the Transmit FIFO with a packet end status. When a byte is marked with a packet end

indication, the output data stream will be padded with FFh and marked with a FIFO empty indication if the Transmit

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183

FIFO contains less than two bytes or transmit packet start is disabled. Transmit packet start is programmable (on

or off). When the Transmit Packet Processor reads the Transmit FIFO while it is empty, the output data stream is

marked with an abort indication. Once the Transmit FIFO is empty, the output data stream will be padded with

interframe fill until the Transmit FIFO contains two or more bytes of data and transmit packet start is enabled.

Bit reordering changes the bit order of each byte. If bit reordering is disabled, the outgoing 8-bit data stream

DT[1:8] with DT[1] being the MSB and DT[8] being the LSB is input from the Transmit FIFO with the MSB in TFD[0]

and the LSB in TFD[7] of the transmit FIFO data TFD[7:0]. If bit reordering is enabled, the outgoing 8-bit data

stream DT[1:8] is input from the Transmit FIFO with the MSB in TFD[7] and the LSB in TFD[0] of the transmit FIFO

data TFD[7:0]. DT[1] is the first bit transmitted on the outgoing data stream.

FCS processing calculates a FCS and appends it to the packet. FCS calculation is a CRC-16 calculation over the

entire packet. The polynomial used for the CRC-16 is x16 + x12 + x5 + 1. The CRC-16 is inverted after calculation,

and appended to the packet. For diagnostic purposes, a FCS error can be inserted. This is accomplished by

appending the calculated CRC-16 without inverting it. FCS error insertion is programmable (on or off). When FCS

processing is disabled, the packet is output without appending a FCS. FCS processing is programmable (on or off).

Stuffing inserts control data into the packet to prevent packet data from mimicking flags. Stuffing is halted during

FIFO empty periods. The 8-bit parallel data stream is multiplexed into a serial data stream, and bit stuffing is

performed. Bit stuffing consists of inserting a '0' directly following any five contiguous '1's. Stuffing is performed

from a packet start until a packet end.

Inter-frame padding inserts inter-frame fill between the packet start and end flags when the FIFO is empty. The

inter-frame fill can be flags or '1's. If the inter-frame fill is flags, flags (minimum two) are inserted until a packet start

is received. If the inter-frame fill is all '1's, an end flag is inserted, ‘1’s are inserted until a packet start is received,

and a start flag is inserted after the ‘1’s. The number of '1's between the end flag and start flag may not be an

integer number of bytes, however, the inter-frame fill will be at least 15 consecutive '1's. If the FIFO is not empty

between a packet end and a packet start, then two flags are inserted between the packet end and packet start. The

inter-frame padding type is programmable (flags or ‘1’s).

Packet abort insertion inserts a packet abort sequences as necessary. If a packet abort indication is detected, a

packet abort sequence is inserted and inter-frame padding is done until a packet start is detected. The abort

sequence is FFh.

Once all packet processing has been completed, the datastream is inserted into the DS3/E3 datastream at the

proper locations. If transmit data inversion is enabled, the outgoing data is inverted after packet processing is

performed. Transmit data inversion is programmable (on or off).

10.11.5 Receive HDLC Overhead Processor

The Receive HDLC Overhead Packet Processor accepts data from the DS3/E3 Framer or the PLCP Framer and

performs packet delineation, inter-frame fill filtering, packet abort detection, destuffing, FCS processing, and bit

reordering. If receive data inversion is enabled, the incoming data is inverted before packet processing is

performed. Receive data inversion is programmable (on or off).

Packet delineation determines the packet boundary by identifying a packet start flag. Each time slot is checked for

a flag sequence (7Eh). Once a flag is found, if it is identified as a start or end flag, and the packet boundary is set.

There may be a single flag (both end and start) between packets, there may be an end flag and a start flag with a

shared zero (011111101111110) between packets, there may be an end flag and a start flag (two flags) between

packets, or there may be an end flag, inter-frame fill, and a start flag between packets. The flag check is performed

one bit at a time.

Inter-frame fill filtering removes the inter-frame fill between a start flag and an end flag. All inter-frame fill is

discarded. The inter-frame fill can be flags (01111110) or all '1's. When inter-frame fill is all ‘1’s, the number of '1's

between the end flag and the start flag may not be an integer number of bytes. When inter-frame fill is flags, the

number of bits between the end flag and the start flag will be an integer number of bytes (flags). Any time there is

less than 16 bits between two flags, the data will be discarded.

Packet abort detection searches for a packet abort sequence. Between a packet start flag and a packet end flag, if

an abort sequence is detected, the packet is marked with an abort indication, and all subsequent data is discarded

until a packet start flag is detected. The abort sequence is seven consecutive ones.

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184

Packet abort detection searches for a packet abort sequence. Between a packet start flag and a packet end flag, if

an abort sequence is detected, the packet is marked with an abort indication, and all subsequent data is discarded

until a packet start flag is detected. The abort sequence is seven consecutive ones.

Destuffing removes the extra data inserted to prevent data from mimicking a flag or an abort sequence. After a start

flag is detected, destuffing is performed until an end flag is detected. Destuffing consists of discarding any '0' that

directly follows five contiguous '1's. After destuffing is completed, the serial bit stream is demultiplexed into an 8-bit

parallel data stream and passed on with packet start, packet end, and packet abort indications. If there is less than

eight bits in the last byte, an invalid packet status is set, and the packet is tagged with an abort indication.

FCS processing checks the FCS, discards the FCS bytes, and marks FCS erred packets. The FCS is checked for

errors, and the last two bytes are removed from the end of the packet. If a FCS error is detected, the packet is

marked with a FCS error indication. The HDLC CONTROLLER performs FCS-16 checking. FCS processing is

programmable (on or off). If FCS processing is disabled, FCS checking is not performed, and all of the packet data

is passed on.

Bit reordering changes the bit order of each byte. If bit reordering is disabled, the incoming 8-bit data stream

DT[1:8] with DT[1] being the MSB and DT[8] being the LSB is output to the Receive FIFO with the MSB in RFD[0]

and the LSB in RFD[7] of the receive FIFO data RFD[7:0]. If bit reordering is enabled, the incoming 8-bit data

stream DT[1:8] is output to the Receive FIFO with the MSB in RFD[7] and the LSB in RFD[0] of the receive FIFO

data RFD[7:0]. DT[1] is the first bit received from the incoming data stream.

Once all of the packet processing has been completed, The 8-bit parallel data stream is passed on to the Receive

FIFO with packet start, packet end, and packet error indications.

10.11.6 Receive FIFO

The Receive FIFO block contains memory for 256 bytes of data with data status information and controller circuitry

for reading and writing the memory. The Receive FIFO Controller controls filling the memory, tracking the memory

fill level, maintaining the memory read and write pointers, and detecting memory overflow and underflow

conditions. The Receive FIFO accepts data and data status from the Receive Packet Processor and stores the

data along with data status information in memory. The data is read from the receive FIFO via the microprocessor

interface. The Receive FIFO also outputs FIFO fill status (empty/data available/full) via the microprocessor

interface. All operations are byte based. The Receive FIFO is considered empty when it does not contain any data.

The Receive FIFO is considered to have data available when there is a programmable number of bytes or more

stored in the memory. The Receive FIFO is considered full when it does not have any space available for storage.

The Receive FIFO accepts data from the Receive Packet Processor until full. If a packet start is received while full,

the data is discarded and a FIFO overflow condition is declared. If any other packet data is received while full, the

current packet being transferred is marked with an abort indication, and a FIFO overflow condition is declared.

Once a FIFO overflow condition is declared, the Receive FIFO will discard incoming data until a packet start is

received while the Receive FIFO has 16 or more bytes available for storage. If the Receive FIFO is read while the

FIFO is empty, the read is ignored, and an invalid data indication given.

10.12 Trail Trace Controller

10.12.1 General Description

Each port has a dedicated Trail Trace Buffer for E3-G.832 or DS3/E3 PLCP link management

The Trail Trace Controller performs extraction and storage of the incoming G.832 or PLCP trail access point

identifier in a 16-byte receive register.

The Trail Trace Controller extracts/inserts E3-G.832 or PLCP trail access point identifiers using a 16-byte register

(one for transmit, one for receive). (E3-G.832 and PLCP Framing are mutually exclusive; therefore one controller

can be used for both.)

The Trail Trace Controller demaps a 16-byte trail trace identifier from the E3-G.832 TR Byte of the overhead or

PLCP datastream in the receive direction and maps a trace identifier into the E3-G.832 or PLCP datastream in the

transmit direction.

The receive direction inputs the trace ID data stream, performs trace ID processing, and stores the trace identifier

data in the data storage using line timing. It removes trace identifier data from the data storage and outputs the

DS3181/DS3182/DS3183/DS3184

185

trace identifier data to the microprocessor via the microprocessor interface using register timing. The data is forced

to all ones during LOS, LOF and AIS detection to eliminate false messages

The transmit direction inputs the trace identifier data from the microprocessor via the microprocessor interface and

stores the trace identifier data in the data storage using register timing. It removes the trace identifier data from the

data storage, performs trace ID processing, and outputs the trace ID data stream. See Figure 10-47 for the location

of the Trail Trace Controller with the DS318x devices.

Figure 10-47. Trail Trace Controller Block Diagram

DS3/E3

Trans mit

LIU

IEEE P1149.1

JTAG Test

Access Port

Microprocessor

Inte rf ac e

HDLC

FEAC

LLB

DLB

DS3 / E3

Transmit

Formatter

DS3 / E3

Rec eiv e

Framer

Trail

Trac e

Buffer

Tx Cell

Processor Tx

FIFO

System

Interface

Rx Cell

Processor

FIFO

Tx Pac ket

Processor

SLB

Rx Pac ket

Processor

DS3/E3

Rec e iv e

LIU

TAIS

TUA 1

TX FRA C/

PL CP

RX FRA C/

PLCP

Cloc k Rate

Adapter

TX BERT

RX BERT

PLB

ALB

UA 1

GEN

B3ZS/

HDB3

Encoder

B3ZS/

HDB3

Dec oder

10.12.2 Features

• Programmable trail trace ID – The trail trace ID controller can be programmed to handle a 16-byte trail trace

identifier (trail trace mode).

• Programmable transmit trace ID – All 16 bytes of the transmit trail trace identifier are programmable.

• Programmable receive expected trace ID – A 16-byte expected trail trace identifier can be programmed.

Both a mismatch and unstable indication are provided.

• Programmable trace ID multiframe alignment – The transmit side can be programmed to perform trail trace

multiframe alignment insertion. The receive side can be programmed to perform trail trace Multiframe

synchronization.

• Programmable bit reordering – The trace identifier data can be output MSB first or LSB first from the data

storage.

• Programmable data inversion – The trace identifier data can be inverted immediately after trace ID

processing on the transmit side, and immediately before trail ID processing on the receive side.

• Fully independent transmit and receive sides

• Fully independent Line side and register interface timing – The data storage can be read from or written to

via the microprocessor interface while all line side clocks and signals are inactive, and read from or written to

via the line side while all microprocessor interface clocks and signals are inactive.

10.12.3 Functional Description

The bits in a byte are received most significant bit (MSB) first and least significant bit (LSB) last. When they are

output serially, they are output MSB first and LSB last. The bits in a byte in an incoming signal are numbered in the

order they are received, 1 (MSB) to 8 (LSB). However, when a byte is stored in a register, the MSB is stored in the

highest numbered bit (7), and the LSB is stored in the lowest numbered bit (0). This is to differentiate between a

byte in a register and the corresponding byte in a signal.

DS3181/DS3182/DS3183/DS3184

186

10.12.4 Transmit Data Storage

The Transmit Data Storage block contains memory for 16 bytes of data and controller circuitry for reading and

writing the memory. The Transmit Data Storage controller functions include filling the memory and maintaining the

memory read and write pointers. The Transmit Data Storage receives data from the microprocessor interface, and

stores the data in memory. The Transmit Trace ID Processor reads the data from the Transmit Data Storage. The

Transmit Data Storage contains the transmit trail trace identifier. Note: The contents of the transmit trail (path) trace

identifier memory will be random data immediately after power-up, and will not change during a reset (RST or DRST

low).

10.12.5 Transmit Trace ID Processor

The Transmit Trace ID Processor accepts data from Transmit Data Storage, processes the data according to the

Transmit Trace ID mode, and outputs the serial trace ID data stream.

10.12.6 Transmit Trail Trace Processing

The Transmit Trail Trace Processing accepts data from the Transmit Data Storage performs bit reordering and

multiframe alignment insertion.

Bit reordering changes the bit order of each byte. If bit reordering is disabled, the outgoing 8-bit data stream

DT[1:8] with DT[1] being the MSB and DT[8] being the LSB is input from the Transmit Data Storage with the MSB

in TTD[7] and the LSB in TTD[0] of the transmit trace ID data TTD[7:0]. If bit reordering is enabled, the outgoing 8-

bit data stream DT[1:8] is input from the Transmit Data Storage with the MSB is in TTD[0] and the LSB is in TTD[7]

of the transmit trace ID data TTD[7:0]. DT[1] is the first bit transmitted on the outgoing data stream.

Multiframe alignment insertion overwrites the MSB of each trail trace byte with the multiframe alignment signal. The

MSB of the first byte in the trail trace identifier is overwritten with a one, the MSB of the other 15 bytes in the trail

trace identifier are overwritten with a zero. Multiframe alignment insertion is programmable (on or off).

If transmit data inversion is enabled, the outgoing data is inverted after trail trace processing is performed. Transmit

data inversion is programmable (on or off). If transmit trail trace identifier idle (Idle) is enabled, the trail trace data is

overwritten with all zeros. Transmit Idle is programmable (on or off).

10.12.7 Receive Trace ID Processor

The Receive Trace ID Processor receives the incoming serial trace ID data stream and processes the incoming

data according to the Receive Trace ID mode, and passes the trace ID data on to Receive Data Storage.

The bits in a byte are received MSB first, LSB last. The bits in a byte in an incoming signal are numbered in the

order they are received, 1 (MSB) to 8 (LSB). However, when a byte is stored in a register, the MSB is stored in the

highest numbered bit (7), and the LSB is stored in the lowest numbered bit (0). This is to differentiate between a

byte in a register and the corresponding byte in a signal.

10.12.8 Receive Trail Trace Processing

The Receive Trail Trace Processing accepts an incoming data line and performs trail trace alignment, trail trace

extraction, expected trail trace comparison, and bit reordering. If receive data inversion is enabled, the incoming

data is inverted before trail trace processing is performed. Receive data inversion is programmable (on or off).

Trail trace alignment determines the trail trace identifier boundary by identifying the multiframe alignment signal.

The multiframe alignment signal (MAS) is located in the MSB of each byte (see Figure 10-48). The MAS bits are

each checked for the multiframe alignment start bit, which is a one. Once a multiframe alignment start bit is found,

the remaining 15 bits of the MAS are verified as being zero. The MAS check is performed one byte at a time.

Multiframe alignment is programmable (on or off). When multiframe alignment is disabled, the incoming bytes are

sequentially stored starting with a random byte.

DS3181/DS3182/DS3183/DS3184

187

Figure 10-48. Trail Trace Byte (DT = Trail Trace Data)

Bit 1

MSB

Bit 2 Bit 3 Bit 4 Bit 5 Bit 6 Bit 7 Bit 8

LSB

MAS or

DT[1]

DT[2] DT[3] DT[4] DT[5] DT[6] DT[7] DT[8]

Trail trace extraction extracts the trail trace identifier from the incoming trail trace data stream, generates a trail

trace identifier change indication, detects a trail trace identifier idle (Idle) condition, and detects a trail trace

identifier unstable (TIU) condition. The trail trace identifier bytes are stored sequentially with the first byte (MAS

equals 1 if trail trace alignment is enabled) being stored in the first byte of memory. If the exact same non-zero trail

trace identifier is received five consecutive times and it is different from the receive trail trace identifier, a receive

trail trace identifier update is performed, and the receive trail trace identifier change indication is set.

An Idle condition is declared when an all zeros trail trace identifier is received five consecutive times. An Idle

condition is terminated when a non-zero trail trace identifier is received five consecutive times or a TIU condition is

declared. A TIU condition is declared if eight consecutive trail trace identifiers are received that do not match either

the receive trail trace identifier or the previously stored current trail trace identifier. The TIU condition is terminated

when a non-zero trail trace identifier is received five consecutive times or an Idle condition is declared.

Expected trail trace comparison compares the received and expected trail trace identifiers. The comparison is a 7-

bit comparison of the seven least significant bits (DT[2:8] (see Figure 10-48) of each trail trace identifier byte (The

multiframe alignment signal is ignored). If the received and expected trail trace identifiers do not match, a trail trace

identifier mismatch (TIM) condition is declared. If they do match the TIM condition is terminated. The 16-byte

expected trail trace identifier is programmable. Expected trail trace comparison is programmable (on or off). If

multiframe alignment is disabled, expected trail trace comparison is disabled. Immediately after a reset, the receive

trail trace identifier is invalid. All comparisons between the receive trail trace identifier and expected trail trace

identifier will match (a TIM condition cannot occur) until after the first receive trail trace identifier update occurs.

Bit reordering changes the bit order of each byte. If bit reordering is disabled, the incoming 8-bit data stream

DT[1:8] with DT[1] being the MSB and DT[8] being the LSB is output to the Receive Data Storage with the MSB in

RTD[7] and the LSB in RTD[0] of the receive trace ID data RTD[7:0]. If bit reordering is enabled, the incoming 8-bit

data stream DT[1:8] is output to the Receive Data Storage with the MSB in RTD[0] and the LSB in RTD[7] of the

receive trace ID data RTD[7:0]. DT[1] is the first bit received from the incoming data stream.

Once all of the trail trace processing has been completed, The 8-bit parallel data stream is passed on to the

Receive Data Storage.

10.12.9 Receive Data Storage

The Receive Data Storage block contains memory for 48 bytes of data, maintains data status information, and has

controller circuitry for reading and writing the memory. The Receive Data Storage controller functions include filling

the memory and maintaining the memory read and write pointers. The Receive Data Storage accepts data and

data status from the Receive Trace ID Processor, stores the data in memory, and maintains data status

information. The data is read from the Receive Data Storage via the microprocessor interface. The Receive Data

Storage contains the current trail trace identifier, the receive trail trace identifier, and the expected trail trace

identifier.

DS3181/DS3182/DS3183/DS3184

188

10.13 FEAC Controller

10.13.1 General Description

The FEAC Controller demaps FEAC codewords from a DS3/E3 data stream in the receive direction and maps

FEAC codewords into a DS3/E3 data stream in the transmit direction. The transmit direction demaps FEAC

codewords from a DS3/E3 data stream.

The receive direction performs FEAC processing, and stores the codewords in the FIFO using line timing. It

removes the codewords from the FIFO and outputs them to the microprocessor via the register interface.

The transmit direction inputs codewords from the microprocessor via the register interface and stores the

codewords. It removes the codewords and performs FEAC processing. See Figure 10-49 for the location of the

FEAC Controller in the block diagram

Figure 10-49. FEAC Controller Block Diagram

DS3/E3

Transmit

LIU

IEEE P1149.1

JTAG Test

Access Port

Microprocessor

Interface

HDLC

FEAC

LLB

DLB

DS3 / E3

Transmit

Formatter

DS3 / E3

Receive

Framer

Trail

Trace

Buffer

Tx Cell

Processor Tx

FIFO

System

Interface

Rx Cell

Processor

FIFO

Tx Packet

Processor

SLB

Rx Packet

Processor

DS3/E3

Receive

LIU

TAIS

TUA1

TX FRAC/

PLCP

RX FRAC/

PLCP

Clock Rate

Adapter

TX BERT

RX BERT

PLB

ALB

UA1

GEN

B3ZS/

HDB3

Encoder

B3ZS/

HDB3

Decoder

10.13.2 Features

• Programmable dual codeword output – The transmit side can be programmed to output a single codeword

ten times, one codeword ten times followed by a second codeword ten times, or a single codeword

continuously.

• Four codeword receive FIFO

• Fully independent transmit and receive paths

• Fully independent Line side and register side timing – The FIFO can be read from or written to at the

side while all register interface side clocks and signals are inactive.

10.13.3 Functional Description

The bits in a code are received MSB first, LSB last. When they are output serially, they are output MSB first, LSB

last. The bits in a code in an incoming signal are numbered in the order they are received, 1 (MSB) to 6 (LSB).

However, when a code is stored in a register, the MSB is stored in the lowest numbered bit (0), and the LSB is

stored in the highest numbered bit (5). This is to differentiate between a code in a register and the corresponding

code in a signal.

10.13.3.1 Transmit Data Storage

The Transmit Data Storage block contains the registers for two FEAC codes (C[1:6]) and controller circuitry for

reading and writing the memory. The Transmit Data Storage receives data from the microprocessor interface, and

stores the data in memory. The Transmit FEAC Processor reads the data from the Transmit Data Storage.

DS3181/DS3182/DS3183/DS3184

189

10.13.3.2 Transmit FEAC Processor

The Transmit FEAC Processor accepts data from the Transmit Data Storage performs FEAC processing. The

FEAC codes are read from Transmit Data Storage with the MSB (C[1]) in TFCA[0] or TFCB[0], and the LSB (C[6])

in TFCA[5] or TFCB[5].

FEAC processing has four modes of operation (Idle, single code, dual code, and continuous code). In Idle mode, all

ones are output on the outgoing FEAC data stream. In single code mode, the code from TFCA[5:0] is inserted into

a codeword (See Figure 10-50), and sent ten consecutive times. Once the ten codewords have been sent, all ones

are output. In dual code mode, the code from TFCA[5:0] is inserted into a codeword, and sent ten consecutive

times. Then the code from TFCB[5:0] is inserted into a codeword, and sent ten consecutive times. Once both

codewords have both been sent ten times, all ones are output. In continuous mode, the code from TFCA[5:0] is

inserted into a codeword, and sent until the mode is changed

10.13.3.3 Receive FEAC Processor

The Receive FEAC Processor accepts an incoming data line and extracts all overhead and performs FEAC code

extraction, and Idle detection.

Figure 10-50. FEAC Codeword Format

Cx - FEAC Code

Receive/Transmit Order

10C60

MSB

LSB

1111111C5 C4 C3 C2 C1

FEAC code extraction determines the codeword boundary by identifying the codeword sequence and extracts the

FEAC code. A FEAC codeword is a repeating 16-bit pattern (See Figure 10-50). The codeword sequence is the

pattern (0xxxxxx011111111) that contains each FEAC code (C[6:1]). Each time slot is checked for a codeword

sequence. Once a codeword sequence is found, the FEAC code is checked. If the same FEAC code is received in

three consecutive codewords without errors, the FEAC code detection indication is set, and the FEAC code is

stored in the Receive FIFO with the MSB (C[1]) in RFF[0], and the LSB (C[6]) in RFF[5]. The FEAC code detection

indication is cleared if two consecutively received FEAC codewords differ from the current FEAC codeword, or a

FEAC Idle condition is detected.

Idle detection detects a FEAC Idle condition. A FEAC idle condition is declared if 16 consecutive ones are

received. The FEAC Idle condition is terminated when the FEAC code detection indication is set.

10.13.3.4 Receive FEAC FIFO

The Receive FIFO block contains memory for four FEAC codes (C[1:6]) and controller circuitry for reading and

writing the memory. The Receive FIFO controller functions include filling the memory, tracking the memory fill level,

maintaining the memory read and write pointers, and detecting memory overflow and underflow conditions. The

Receive FIFO accepts data from the Receive FEAC Processor and stores the data in memory. The data is read

from the receive FIFO via the microprocessor interface. The Receive FIFO also outputs FIFO fill status (empty) via

the microprocessor interface. All operations are code based (six bits). The Receive FIFO is considered empty when

it does not contain any data. The Receive FIFO accepts data from the Receive FEAC Processor until full. If a

FEAC code is received while full, the data is discarded and a FIFO overflow condition is declared. If the Receive

FIFO is read while the FIFO is empty, the read is ignored.

DS3181/DS3182/DS3183/DS3184

190

10.14 Line Encoder/Decoder

10.14.1 General Description

The B3ZS/HDB3 Decoder converts a bipolar signal to a unipolar signal in the receive direction. B3ZS/HDB3

Encoder converts a unipolar signal to a bipolar signal in the transmit direction.

In the transmit direction, the Encoder converts the unipolar signal to a bipolar signal, optionally performing zero

suppression encoding (HDB3/B3ZS), optionally inserting errors, and outputs the bipolar signal.

In the receive direction, the Decoder receives a bipolar signal, monitors it for alarms and errors, optionally

performing zero suppression decoding (HDB3/B3ZS), and converts it to a unipolar signal.

If the port line interface is configured for a Unipolar mode and the framer is not configured for one of the “-OHM”

modes, the BPV detector will count pulses on the RLCVn pin. Figure 10-51 shows the locations of the Line

Encoder/Decoder block in the DS318x devices.

Figure 10-51. Line Encoder/Decoder Block Diagram

DS3/E3

Transmit

LIU

IEEE P1149.1

JTAG Test

Access Port

Microprocessor

Interface

HDLC

FEAC

LLB

DLB

DS3 / E3

Transmit

Formatter

DS3 / E3

Receive

Framer

Trail

Trace

Buffer

Tx Cell

Processor Tx

FIFO

System

Interface

Rx Cell

Processor

FIFO

Tx Packet

Processor

SLB

Rx Packet

Processor

DS3/E3

Receive

LIU

TAIS

TUA1

TX FRAC/

PLCP

RX FRAC/

PLCP

Clock Rate

Adapter

TX BERT

RX BERT

PLB

ALB

UA1

GEN

B3ZS/

HDB3

Encoder

B3ZS/

HDB3

Decoder

10.14.2 Features

• Performs bipolar to unipolar encoding and decoding – Converts a unipolar signal into an AMI bipolar signal

(POS data, and NEG data) and vice versa.

• Programmable zero suppression – B3ZS or HDB3 zero suppression encoding and decoding can be

performed, or the bipolar data stream can be left as an AMI encoded data stream.

• Programmable receive zero suppression code format – The signature of B3ZS or HDB3 is selectable.

• Generates and detects alarms and errors – In the receive direction, detects LOS alarm condition BPV

errors, and EXZ errors. In the transmit direction, errors can be inserted into the outgoing data stream.

10.14.3 B3ZS/HDB3 Encoder

B3ZS/HDB3 Encoder performs unipolar to bipolar conversion and zero suppression encoding.

Unipolar to bipolar conversion converts the unipolar data stream into an AMI bipolar data stream (POS and NEG).

In an AMI bipolar data stream a zero is represented by a zero on both the POS and NEG signals, and a one is

represented by a one on a bipolar signal (POS or NEG), and a zero on the other bipolar signal (NEG or POS).

Successive ones are represented by ones that are alternately output on the POS and NEG signals. I.e., if a one is

represented by a one on POS and a zero on NEG, the next one will be represented by a one on NEG and a zero

on POS.

DS3181/DS3182/DS3183/DS3184

191

Zero suppression encoding converts an AMI bipolar data stream into a B3ZS or HDB3 encoded bipolar data

stream. A B3ZS encoded bipolar signal is generated by inserting a B3ZS signature into the bipolar data stream if

both the POS and NEG signals are zero for three consecutive clock periods. An HDB3 encoded bipolar signal is

generated by inserting an HDB3 signature into the bipolar data stream if both the POS and NEG signals are zero

for four consecutive clock periods. Zero suppression encoding can be disabled which will result in AMI-coded data.

Error insertion is also performed. Error insertion inserts bipolar violation (BPV) or excessive zero (EXZ) errors onto

the bipolar signal. A BPV error will be inserted when three consecutive ones occur. An EXZ error will be inserted

when three (or four) consecutive zeros on the bipolar signal occur by inhibiting the insertion of a B3ZS (HDB3)

signature. There will be at least one intervening pulse between consecutive BPV or EXZ errors. A single BPV or

EXZ error inserted will be detected as a single BPV/EXZ error at the far-end, and will not cause any other type of

error to be detected. For example, if a BPV error is inserted, the far-end should not also detect a data error.

10.14.4 Transmit Line Interface

The Transmit Line Interface accepts a bipolar data stream from the B3ZS/HDB3 Encoder, performs error insertion,

and transmits the bipolar data stream.

Error insertion inserts BPV or EXZ errors into the bipolar signal. When a BPV error is to be inserted, the Transmit

Line Interface waits for the next occurrence of three consecutive ones. The first bipolar one is generated according

to the normal AMI rules. The second bipolar one is generated by transmitting the same values on TPOS and TNEG

as the values for the first one. The third bipolar one is generated according to the normal AMI rules. When an EXZ

error is to be inserted, the Transmit Line Interface waits for the next occurrence of three (four) consecutive zeros on

the bipolar signal, and inhibits the insertion of a B3ZS (HDB3) signature. There must be at least one intervening

one between consecutive BPV or EXZ errors. A single BPV or EXZ error inserted must be detected as a single

BPV/EXZ error at the far-end, and not cause any other type of error to be detected. For example, if a BPV error is

inserted, the far-end should not also detect a data error. If a second error insertion request of a given type (BPV or

EXZ) is initiated before a previous request has been completed, the second request will be ignored.

The outgoing bipolar data stream consists of positive pulse data (TPOSn) and negative pulse data (TNEGn).

TPOSn and TNEGn are updated on the rising edge of TLCLKn.

10.14.5 Receive Line Interface

The Receive Line Interface receives a bipolar signal. The incoming bipolar data line consists of positive pulse data

(RPOSn), negative pulse data (RNEGn), and clock (RLCLKn) signals. RPOSn and RNEGn are sampled on the

rising edge of RLCLKn. The incoming bipolar signal is checked for a Loss Of Signal (LOS) condition, and passed

on to B3ZS/HDB3 Decoder. An LOS condition is declared if both RPOSn and RNEGn do not have any transitions

for 192 clock cycles. The LOS condition is terminated after 192 clock cycles without any EXZ errors. Note: When

zero suppression (B3ZS or HDB3) decoding is disabled, the LOS condition is cleared, and cannot be detected.

10.14.6 B3ZS/HDB3 Decoder

The B3ZS/HDB3 Decoder receives a bipolar signal from the LIU (or the RPOS/RNEG pins). The incoming bipolar

signal is checked for a Loss of Signal (LOS) condition. A LOS condition is declared if both the positive pulse data

and negative pulse data signals do not have any transitions for 192 clock cycles. The LOS condition is terminated

after 192 clock cycles without any EXZ errors.

B3ZS/HDB3 Decoder performs EXZ detection, zero suppression decoding, BPV detection, and bipolar to unipolar

conversion.

EXZ detection checks the bipolar data stream for excessive zeros (EXZ) errors. In B3ZS mode, an EXZ error is

declared whenever there is an occurrence of 3 or more zeros. In HDB3 mode, an EXZ error is declared whenever

there is an occurrence of 4 or more zeros. EXZ errors are accumulated in the EXZ counter (LINE.REXZCR

Zero suppression decoding converts B3ZS or HDB3 encoded bipolar data into an AMI bipolar signal. In B3ZS

mode, the encoded bipolar signal is checked for a B3ZS signature. If a B3ZS signature is found, it is replaced with

three zeros. In HDB3 mode, the encoded bipolar signal is checked for an HDB3 signature. If an HDB3 signature is

found, it is replaced with four zeros. The format of both an HDB3 signature and a B3ZS signature is programmable.

When LINE.RCR.REZSF = 0, the decoder will search for a zero followed by a BPV in B3ZS mode, and in HDB3

mode it will search for two zeros followed by a BPV. If LINE.RCR.REZSF = 1, the same criteria is applied with an

additional requirement that the BPV must be the opposite polarity of the previous BPV. See Figure 10-52 and

DS3181/DS3182/DS3183/DS3184

192

Figure 10-53. Zero suppression decoding is also programmable (on or off). Note: Immediately after a reset or a

LOS condition, the first B3ZS/HDB3 signature to be detected will not depend upon the polarity of any BPV

contained within the signature.

Figure 10-52. B3ZS Signatures

RLCLK

RPOS

RNEG

(RX DATA)

B3ZS SIGNATURE WHEN

LINE.RCR.REZSF = 0

RLCLK

RPOS

RNEG

(RX DATA)

B3ZS SIGNATURE WHEN

LINE.RCR.REZSF = 1

Figure 10-53. HDB3 Signatures

RLCLK

RPOS

RNEG

(RX DATA)

HDB3 SIGNATURE WHEN

LINE.RCR.REZSF = 0

RLCLK

RPOS

RNEG

(RX DATA)

HDB3 SIGNATURE WHEN

LINE.RCR.REZSF = 1

BPV detection checks the bipolar signal for bipolar violation (BPV) errors and E3 code violation (CV) errors. A BPV

error is declared if two 1’s are detected on RXP or RXN without an intervening 1 on RXN or RXP, and the 1’s are

not part of a B3ZS/HDB3 signature, or when both RXP and RXN are a one. An E3 coding violation is declared if

consecutive BPVs of the same polarity are detected (ITU O.161 definition). E3 CVs are accumulated in the BPV

counter (LINE.RBPVCR register) if E3 CV detection has been enabled (applicable only in HDB3 mode), otherwise,

BPVs are accumulated in the BPV counter. If zero code suppression is disabled, the BPV counter will count all

bipolar violations. The BPV counter will count pulses on the RLCVn pin when the device is configured for unipolar

mode.

DS3181/DS3182/DS3183/DS3184

193

Note: Immediately after a reset (or datapath reset) or a LOS condition, a BPV will not be declared when the first

valid one (RPOS high and RNEG low, or RPOS low and RNEG high) is received. Bipolar to unipolar conversion

converts the AMI bipolar data into a unipolar signal by ORing together the RXP and RXN signals.

10.15 BERT

10.15.1 General Description

The BERT is a software-programmable test-pattern generator and monitor capable of meeting most error

performance requirements for digital transmission equipment. It will generate and synchronize to pseudo-random

patterns with a generation polynomial of the form xn + xy + 1, where n and y can take on values from 1 to 32 and to

repetitive patterns of any length up to 32 bits.

The transmit direction generates the programmable test pattern, and inserts the test pattern payload into the data

stream.

The receive direction extracts the test pattern payload from the receive data stream, and monitors the test pattern

payload for the programmable test pattern. Figure 10-54 shows the location of the BERT Block within the DS318x

devices.

Figure 10-54. BERT Block Diagram

DS3/E3

Transmit

LIU

IEEE P1149.1

JTAG Test

Access Port

Microprocessor

Interface

HDLC

FEAC

LLB

DLB

DS3 / E3

Transmit

Formatter

DS3 / E3

Receive

Framer

Trail

Trace

Buffer

Tx Cell

Processor Tx

FIFO

System

Interface

Rx Cell

Processor

FIFO

Tx Packet

Processor

SLB

Rx Packet

Processor

DS3/E3

Receive

LIU

TAIS

TUA1

TX FRAC/

PLCP

RX FRAC/

PLCP

Clock Rate

Adapter

TX BERT

RX BERT

PLB

ALB

UA1

GEN

B3ZS/

HDB3

Encoder

B3ZS/

HDB3

Decoder

10.15.2 Features

• Programmable PRBS pattern – The Pseudo Random Bit Sequence (PRBS) polynomial (xn + xy + 1) and seed

are programmable (length n = 1 to 32, tap y = 1 to n - 1, and seed = 0 to 2n - 1).

• Programmable repetitive pattern – The repetitive pattern length and pattern are programmable (the length n

= 1 to 32 and pattern = 0 to 2n - 1).

• 24-bit error count and 32-bit bit count registers

• Programmable bit error insertion – Errors can be inserted individually, on a pin transition, or at a specific

rate. The rate 1/10n is programmable (n = 1 to 7).

• Pattern synchronization at a 10-3 BER – Pattern synchronization will be achieved even in the presence of a

random Bit Error Rate (BER) of 10-3.

10.15.3 Configuration and Monitoring

Set PORT.CR1.BENA = 1 to enable the BERT. The BERT must be enabled before the pattern is loaded for the

pattern load operation to take affect.

The following tables show how to configure the on-board BERT to send and receive common patterns.

DS3181/DS3182/DS3183/DS3184

194

Table 10-38. Pseudorandom Pattern Generation

BERT.PCR REGISTER BERT.CR

PATTERN TYPE PTF[4:0]

(hex)

PLF[4:0]

(hex) PTS QRSS

BERT.

PCR

BERT.

SPR2

BERT.

SPR1 TPIC,

RPIC

29-1 O.153 (511 type) 04 08 0 0 0x0408 0xFFFF 0xFFFF 0

211-1 O.152 and O.153

(2047 type) 08 0A 0 0 0x080A 0xFFFF 0xFFFF 0

215-1 O.151 0D 0E 0 0 0x0D0E 0xFFFF 0xFFFF 1

220-1 O.153 10 13 0 0 0x1013 0xFFFF 0xFFFF 0

220-1 O.151 QRSS 02 13 0 1 0x0253 0xFFFF 0xFFFF 0

223-1 O.151 11 16 0 0 0x1116 0xFFFF 0xFFFF 1

Table 10-39. Repetitive Pattern Generation

BERT.PCR REGISTER

PATTERN TYPE PTF[4:0]

(hex)

PLF[4:0]

(hex) PTS QRSS

BERT.

PCR

BERT.

SPR2

BERT.

SPR1

all 1s NA 00 1 0 0x0020 0xFFFF 0xFFFF

all 0s NA 00 1 0 0x0020 0xFFFF 0xFFFE

alternating 1s and 0s NA 01 1 0 0x0021 0xFFFF 0xFFFE

double alternating and 0s NA 03 1 0 0x0023 0xFFFF 0xFFFC

3 in 24 NA 17 1 0 0x0037 0xFF20 0x0022

1 in 16 NA 0F 1 0 0x002F 0xFFFF 0x0001

1 in 8 NA 07 1 0 0x0027 0xFFFF 0xFF01

1 in 4 NA 03 1 0 0x0023 0xFFFF 0xFFF1

After configuring these bits, the pattern must be loaded into the BERT. This is accomplished via a zero-to-one

transition on BERT.CR.TNPL and BERT.CR.RNPL.

Monitoring the BERT requires reading the BERT.SR Register that contains the Bit Error Count (BEC) bit and the

Out of Synchronization (OOS) bit. The BEC bit will be one when the bit error counter is one or more. The OOS will

be one when the receive pattern generator is not synchronized to the incoming pattern, which will occur when it

receives a minimum 6 bit errors within a 64 bit window. The Receive BERT Bit Count Register (BERT.RBCR1) and

the Receive BERT Bit Error Count Register (BERT.RBECR1) will be updated upon the reception of a Performance

Monitor Update signal (e.g., BERT.CR.LPMU). This signal will update the registers with the values of the counters

since the last update and will reset the counters. See Section 10.4.5 for more details of the PMU.

10.15.4 Receive Pattern Detection

When the Receive BERT is enabled it can be used as an off-line monitor. The incoming datastream flows to the

receive BERT as well as the Cell/Packet Processor. If it is not desired that the datastream flows to the Cell/Packet

processor, the user should disable the Receive FIFO by setting the FIFO.RCR.RFRST bit.

The Receive BERT receives only the payload data and synchronizes the receive pattern generator to the incoming

pattern. The receive pattern generator is a 32-bit shift register that shifts data from the least significant bit (LSB) or

bit 1 to the most significant bit (MSB) or bit 32. The input to bit 1 is the feedback. For a PRBS pattern (generating

polynomial xn + xy + 1), the feedback is an XOR of bit n and bit y. For a repetitive pattern (length n), the feedback is

bit n. The values for n and y are individually programmable (1 to 32). The output of the receive pattern generator is

the feedback. If QRSS is enabled, the feedback is an XOR of bits 17 and 20, and the output will be forced to one if

the next 14 bits are all zeros. QRSS is programmable (on or off). For PRBS and QRSS patterns, the feedback will

be forced to one if bits 1 through 31 are all zeros. Depending on the type of pattern programmed, pattern detection

performs either PRBS synchronization or repetitive pattern synchronization.

DS3181/DS3182/DS3183/DS3184

195

10.15.4.1 Receive PRBS Synchronization

PRBS synchronization synchronizes the receive pattern generator to the incoming PRBS or QRSS pattern. The

receive pattern generator is synchronized by loading 32 data stream bits into the receive pattern generator, and

then checking the next 32 data stream bits. Synchronization is achieved if all 32 bits match the incoming pattern. If

at least six incoming bits in the current 64-bit window do not match the receive pattern generator, automatic pattern

re-synchronization is initiated. Automatic pattern re-synchronization can be disabled.

See Figure 10-55 for the PRBS synchronization diagram.

Figure 10-55. PRBS Synchronization State Diagram

Sync

LoadVerify

1 bit error

32 bits loaded

32 bits without errors

6 of 64 bits with errors

10.15.4.2 Receive Repetitive Pattern Synchronization

Repetitive pattern synchronization synchronizes the receive pattern generator to the incoming repetitive pattern.

The receive pattern generator is synchronized by searching each incoming data stream bit position for the

repetitive pattern, and then checking the next 32 data stream bits. Synchronization is achieved if all 32 bits match

the incoming pattern. If at least six incoming bits in the current 64-bit window do not match the receive PRBS

pattern generator, automatic pattern re-synchronization is initiated. Automatic pattern re-synchronization can be

disabled. See Figure 10-56 for the repetitive pattern synchronization state diagram.

DS3181/DS3182/DS3183/DS3184

196

Figure 10-56. Repetitive Pattern Synchronization State Diagram

Sync

MatchVerify

1 bit error

Pattern Matches

32 bits without errors

6 of 64 bits with errors

10.15.4.3 Receive Pattern Monitoring

Receive pattern monitoring monitors the incoming data stream for both an OOS condition and bit errors and counts

the incoming bits. An Out Of Synchronization (OOS) condition is declared when the synchronization state machine

is not in the “Sync” state. An OOS condition is terminated when the synchronization state machine is in the “Sync”

state.

Bit errors are determined by comparing the incoming data stream bit to the receive pattern generator output. If they

do not match, a bit error is declared, and the bit error and bit counts are incremented. If they match, only the bit

count is incremented. The bit count and bit error count are not incremented when an OOS condition exists.

10.15.5 Transmit Pattern Generation

Pattern Generation generates the outgoing test pattern, and passes it onto Error Insertion. The transmit pattern

generator is a 32-bit shift register that shifts data from the least significant bit (LSB) or bit 1 to the most significant

bit (MSB) or bit 32. The input to bit 1 is the feedback. For a PRBS pattern (generating polynomial xn + xy + 1), the

feedback is an XOR of bit n and bit y. For a repetitive pattern (length n), the feedback is bit n. The values for n and

y are individually programmable (1 to 32). The output of the receive pattern generator is the feedback. If QRSS is

enabled, the feedback is an XOR of bits 17 and 20, and the output will be forced to one if the next 14 bits are all

zeros. QRSS is programmable (on or off). For PRBS and QRSS patterns, the feedback will be forced to one if bits

1 through 31 are all zeros. When a new pattern is loaded, the pattern generator is loaded with a seed/pattern value

before pattern generation starts. The seed/pattern value is programmable (0 – 2n - 1).

10.15.5.1 Transmit Error Insertion

Error insertion inserts errors into the outgoing pattern data stream. Errors are inserted one at a time or at a rate of

one out of every 10n bits. The value of n is programmable (1 to 7 or off). Single bit error insertion can be initiated

from the microprocessor interface, or by the manual error insertion input (TMEI). The method of single error

insertion is programmable (register or input). If pattern inversion is enabled, the data stream is inverted before the

overhead/stuff bits are inserted. Pattern inversion is programmable (on or off).

DS3181/DS3182/DS3183/DS3184

197

10.16 Line Interface Unit (LIU)

10.16.1 General Description

The line interface units (LIUs) perform the functions necessary for interfacing at the physical layer to DS3, E3, or

STS-1 lines. Each LIU has independent receive and transmit paths and a built-in jitter attenuator. See Figure 10-57

for the location within the DS318x device of the LIU.

Figure 10-57. LIU Functional Diagram

DS3/E3

Transmit

LIU

IEEE P1149.1

JTAG Test

Access Port

Microprocessor

Interface

HDLC

FEAC

LLB

DLB

DS3 / E3

Transmit

Formatter

DS3 / E3

Receive

Framer

Trail

Trace

Buffer

Tx Cell

Processor Tx

FIFO

System

Interface

Rx Cell

Processor

FIFO

Tx Packet

Processor

SLB

Rx Packet

Processor

DS3/E3

Receive

LIU

TAIS

TUA1

TX FRAC/

PLCP

RX FRAC/

PLCP

Clock Rate

Adapter

TX BERT

RX BERT

PLB

ALB

UA1

GEN

B3ZS/

HDB3

Encoder

B3ZS/

HDB3

Decoder

10.16.2 Features

• Each Port Independently Configurable

• Perform Receive Clock/Data Recovery and Transmit Waveshaping

• Jitter Attenuators can be Placed in Either the Receive or Transmit Paths

• Interface to 75Ω Coaxial Cable at Lengths Up to 380 meters (DS3), 440 meters (E3), or 360 meters (STS-1)

• Use 1:2 Transformers on TX and RX

• Require Minimal External Components

• Local and Remote Loopbacks

10.16.2.1 Transmitter

• Gapped clock capable up to 52MHz

• Wide 50 ±20% transmit clock duty cycle

• Clock inversion for glue-less interfacing

• Unframed all-ones generator (E3 AIS)

• Line build-out (LBO) control

• Tri-state line driver outputs support protection switching applications

• Per-channel power-down control

• Output driver monitor

10.16.2.2 Receiver

• AGC/equalizer block handles from 0 to 15dB of cable loss

• Loss-of-lock (LOL) PLL status indication

• Interfaces directly to a DSX monitor signal (~20dB flat loss) using built-in preamp

• Digital and analog loss-of-signal (LOS) detectors (ANSI T1.231 and ITU G.775)

• Clock inversion for glue-less interfacing

• Per-channel power-down control

DS3181/DS3182/DS3183/DS3184

198

10.16.3 Detailed Description

The receiver performs clock and data recovery from an alternate mark inversion (AMI) coded signal or a B3ZS- or

HDB3-coded AMI signal and monitors for loss of the incoming signal. The transmitter drives standard pulse-shape

waveforms onto 75Ω coaxial cable. See Figure 10-58 for a detailed functional block diagram of the DS3/E3/STS-1

LIU. The jitter attenuator can be mapped into the receiver data path, mapped into the transmitter data path, or be

disabled. The DS3/E3/STS1 LIU conforms to the telecommunications standards listed in Table 4-1. Figure 1-1

shows the external components required for proper operation.

Figure 10-58. DS3/E3/STS-1 LIU Block Diagram

Analog

Local

Loopback

Preamp

Clock &

Data

Recovery

Line Driver

Waveshaping

RXPn

RXNn

TXPn

TXNn

Power

Supply

squelch

Jitter Attenuator

(can be placed in either the receive path or the transmit path)

Driver

Monitor

VDD

VSS

Automatic

Gain

Control

Adaptive

Equalizer

ALOS

CLKC

Clock Rate

Adapter

CLKBCLKA

TO B3ZS/HDB3

DECODER

FROM B3ZS/HDB3

ENCODER

FROM DS3/E3/

STS-1 LINE

TO DS3/E3/STS-1

LINE

10.16.4 Transmitter

10.16.4.1 Transmit Clock

The clock used in the LIU Transmitter is typically based on either the CLAD clock or TCLKI, selected by the

CLADC bit in PORT.CR3.

10.16.4.2 Waveshaping, Line Build-Out, Line Driver

The waveshaping block converts the transmit clock, positive data, and negative data signals into a single AMI

signal with the waveshape required for interfacing to DS3/E3/STS1 lines. Table 18-8 through Table 18-12 and

Figure 18-9 (AC Timing Section) show the waveform template specifications and test parameters.

Because DS3 and STS-1 signals must meet the waveform templates at the cross-connect through any cable length

from 0 to 450ft, the waveshaping circuitry includes a selectable LBO feature. For cable lengths of 225ft or greater,

the TLBO configuration bit (PORT.CR2.TLBO) should be low. When TLBO is low, output pulses are driven onto the

coaxial cable without any pre-attenuation. For cable lengths less than 225ft, TLBO should be high to enable the

LBO circuitry. When TLBO is high, pulses are pre-attenuated by the LBO circuitry before being driven onto the

coaxial cable. The LBO circuitry provides attenuation that mimics the attenuation of 225ft of coaxial cable.

The transmitter line driver can be disabled and the TXPn and TXNn outputs tri-stated by asserting the LTS

configuration bit (PORT.CR2.LTS). Powering down the transmitter through the TPD configuration bit (CPU bus

mode) also tri-states the TXPn and TXNn outputs.

DS3181/DS3182/DS3183/DS3184

199

10.16.4.3 Interfacing to the Line

The transmitter interfaces to the outgoing DS3/E3/STS-1 coaxial cable (75Ω) through a 2:1 step-down transformer

connected to the TXPn and TXNn pins. Figure 1-1 shows the arrangement of the transformer and other

recommended interface components. Table 10-40 specifies the required characteristics of the transformer.

10.16.4.4 Transmit Driver Monitor

If the transmit driver monitor detects a faulty transmitter, it sets the PORT.SR.TDM status bit. When the transmitter

is tri-stated, the transmit driver monitor is also disabled. The transmitter is declared to be faulty when the

transmitter outputs see a load of less than ~25Ω.

10.16.4.5 Transmitter Power-Down

To minimize power consumption when the transmitter is not being used, assert the PORT.CR1.PD configuration

bit. When the transmitter is powered down, the TXPn and TXNn pins are put in a high-impedance state and the

transmit amplifiers are powered down.

10.16.4.6 Transmitter Jitter Generation (Intrinsic)

The transmitter meets the jitter generation requirements of all applicable standards, with or without the jitter

attenuator enabled.

10.16.4.7 Transmitter Jitter Transfer

Without the jitter attenuator enabled in the transmit side, the transmitter passes jitter through unchanged. With the

jitter attenuator enabled in the transmit side, the transmitter meets the jitter transfer requirements of all applicable

telecommunication standards. See Table 4-1.

10.16.5 Receiver

10.16.5.1 Interfacing to the Line

The receiver can be transformer-coupled or capacitor-coupled to the line. Typically, the receiver interfaces to the

incoming coaxial cable (75Ω) through a 1:2 step-up transformer. Figure 1-1 shows the arrangement of the

transformer and other recommended interface components. Table 10-40 specifies the required characteristics of

the transformer. Figure 10-58 shows a general overview of the LIU block. The receiver expects the incoming signal

to be in B3ZS- or HDB3-coded AMI format.

Table 10-40. Transformer Characteristics

PARAMETER VALUE

Turns Ratio 1:2ct ±2%

Bandwidth 75Ω 0.250MHz to 500MHz (typ)

Primary Inductance 19µH (min)

Leakage Inductance 0.12µH (max)

Interwinding Capacitance 10pF (max)

Isolation Voltage 1500VRMS (min)

DS3181/DS3182/DS3183/DS3184

200

Table 10-41. Recommended Transformers

MANUFACTURER PART TEMP

RANGE

PIN-PACKAGE/

SCHEMATIC

OCL

PRIMARY

(µH) (min)

(µH)

(max)

BANDWIDTH

75Ω (MHz)

Pulse Engineering PE-65968 0°C to +70°C 6 SMT

LS-1/C 19 0.06 0.250 to 500

Pulse Engineering PE-65969 0°C to +70°C 6 Thru-Hole

LC-1/C 19 0.06 0.250 to 500

Halo Electronics TG07-

0206NS 0°C to +70°C 6 SMT

SMD/B 19 0.06 0.250 to 500

Halo Electronics TD07-

0206NE 0°C to +70°C 6 DIP

DIP/B 19 0.06 0.250 to 500

Note: Table subject to change. Industrial temperature range and multiport transformers are also available. Contact the manufacturers for details

at www.pulseeng.com and www.haloelectronics.com.

10.16.5.2 Optional Preamp

The receiver can be used in monitoring applications, which typically have series resistors with a resistive loss of

approximately 20dB. When the PORT.CR2.RMON bit is high, the receiver compensates for this resistive loss by

applying flat gain to the incoming signal before sending the signal to the AGC/ equalizer block.

10.16.5.3 Automatic Gain Control (AGC) and Adaptive Equalizer

The AGC circuitry applies flat (frequency independent) gain to the incoming signal to compensate for flat losses in

the transmission channel and variations in transmission power. Since the incoming signal also experiences

frequency-dependent losses as it passes through the coaxial cable, the adaptive equalizer circuitry applies

frequency-dependent gain to offset line losses and restore the signal. The AGC/equalizer circuitry automatically

adapts to coaxial cable losses from 0 to 15dB, which translates into 0 to 380 meters (DS3), 0 to 440 meters (E3), or

0 to 360 meters (STS-1) of coaxial cable (AT&T 734A or equivalent). The AGC and the equalizer work

simultaneously but independently to supply a signal of nominal amplitude and pulse shape to the clock and data

recovery block. The AGC/equalizer block automatically handles direct (0 meters) monitoring of the transmitter

output signal.

10.16.5.4 Clock and Data Recovery (CDR)

The CDR block takes the amplified, equalized signal from the AGC/equalizer block and produces a separate clock,

positive data, and negative data signals. The CDR requires a master clock. This clock is derived from CLKA,

CLKB, or CLKC depending on the CLAD configuration (DS3, E3, STS-1). If, however, there is no clock source on

CLKA, CLKB, or CLKC the CDR block will automatically switch to TCLKIn to use as its master clock.

The receive clock is locked using a clock recovery PLL. The status of the PLL lock is indicated in the RLOL

(PORT.SR) status bit. The receive loss-of-lock status bit (RLOL) is set when the difference between the recovered

clock frequency and the master clock frequency is greater than 7900ppm and cleared when the difference is less

than 7700ppm. A change of state of the PORT.SR.RLOL status bit can cause an interrupt on the INT pin if enabled

to do so by the PORT.SRIE.RLOLIE interrupt-enable bit. Note that if the master clock is not present, or the master

clock is high and TCLK is not present, RLOL is not set.

10.16.5.5 Loss-of-Signal (LOS) Detector

The receiver contains analog and digital LOS detectors. The analog LOS detector resides in the AGC/equalizer

block. If the incoming signal level is less than a signal level approximately 24dB below nominal, analog LOS

(ALOS) is declared. The ALOS signal cannot be directly examined, but when ALOS occurs the AGC/equalizer

mutes the recovered data, forcing all zeros out of the data recovery circuitry and causing digital LOS (DLOS).

DLOS is determined by the Line Decoder block (see 10.14.4) and indicated by the LOS status bit (LINE.RSR.LOS).

ALOS clears when the incoming signal level is greater than or equal to a signal level approximately 18dB below

nominal.

DS3181/DS3182/DS3183/DS3184

201

For E3 LOS Assertion:

The ALOS detector in the AGC/equalizer block detects that the incoming signal is less than or equal to a signal

level approximately 24dB below nominal, and mutes the data coming out of the clock and data recovery block.

(24dB below nominal in the “tolerance range” of G.775, where LOS may or may not be declared.)

For E3 LOS Clear:

The ALOS detector in the AGC/equalizer block detects that the incoming signal is greater than or equal to a signal

level approximately 18dB below nominal, and enables data to come out of the CDR block. (18dB is in the

“tolerance range” of G.775, where LOS may or may not be declared.)

10.16.5.6 Receiver Power-Down

To minimize power consumption when the receiver is not being used, write a one to the PORT.CR1.PD bit. When

the receiver is powered down, the RCLKO pin is tri-stated. In addition, the RXP and RXN pins become high

impedance.

10.16.5.7 Receiver Jitter Tolerance

The receiver exceeds the input jitter tolerance requirements of all applicable telecommunication standards in Table

4-1. See Figure 10-59.

Figure 10-59. Receiver Jitter Tolerance

10 100 1k 10k 100k 1M

60k22.3k2.3k669

0.1

1.0

300k 800k30030

0.1

0.15

0.3

1.5

E3 G.823

DS3 GR-499 Cat II

DS3 GR-499 Cat I

DS318x JITTER TOLERANCE

15 STS-1 GR253

FREQUENCY (Hz)

JITTER TOLERANCE (UIP-P)

DS3181/DS3182/DS3183/DS3184

202

11 OVERALL REGISTER MAP

The register addresses of the global, test and all four ports are concatenated to cover the address range of 000 to

7FF. The address map requires 11 bits of address, ADR[10:0]. The upper address bit A[10] is decoded for the

DS3184 and DS3183 devices. The upper address bit A[10] it is not used by the DS3182 and DS3181 devices and

must be tied low at the pin.

The register banks that are not marked with an “X” are not writeable and read back all zeroes. Bits that are

underlined are read-only; all other bits are read-write.

After Global Reset, all Registers will be reset to their default values.

When writing to registers with unused bits marked with “—“, always write a zero to these unused bits and

ignore the value read back from these bits.

Configuration registers can be written to and read from during a data path reset (DRST low, and RST high).

However, all changes to these registers will be ignored during the data path reset. As a result, all initiating action

requiring a “0 to 1” transition must be re-initiated after the data path reset is released.

All counters saturate at their maximum count. A counter register is updated by asserting (low to high transition) the

performance monitoring update signal (RPMU). During the counter register update process, the performance

monitoring status signal (RPMS) will be deasserted. The counter register update process consists of loading the

counter register with the current count, resetting the counter, forcing the zero count status indication low for one

clock period, and then asserting RPMS. No events shall be missed during an update procedure.

A latched bit is set when the associated event occurs, and remains set until it is cleared. Once cleared, a latched

bit will not be set again until the associated event reoccurs (goes away and comes back). A latched on change bit

is a latched bit that is set when the event occurs, and when it goes away. A latched status bit can be cleared using

clear on read or clear on write techniques, selectable by the GL.CR1.LSBCRE bit. When clear on read is selected,

the latched bits in a latched status register will be cleared after the register is read from. If the device is configured

for 16-bit mode, all 16 latched status bits will be cleared. If the device is configured for 8-bit mode, only the 8 bits

being accessed will be cleared. When clear on write is selected, the latched bits in a latched status register will be

cleared when a logic 1 is written to that bit position. For example, writing a FFFFh to a 16-bit latched status register

will clear any latched status bit, whereas writing a 0001h will only clear latched bit 0 of the latched status register.

Reserved bits and registers are implemented in a different mode. Reserved configuration bits and registers can be

written and read, however they will not effect the operation of the current mode. Reserved status bits will be zero.

Reserved latched status bits cannot be set, however, they may remain set or get set during a mode change.

Reserved interrupt enable bits can be written and read, and can cause an interrupt if the associated latched status

bit is set. Reserved counter registers and the associated counter will retain the values held before a mode change,

however, the associated counter cannot be incremented. A performance monitor update will operate normally. If

the data path reset is set during or after a mode change, the latched status bits and counter registers (with the

associated counters) will be automatically cleared. If the data path reset is not used, then the latched status bits

must be cleared via the register interface in the normal manner. And, the counter registers must be cleared by

performing two performance monitor updates. The first to clear the associated counter, and load the current count

into the counter register, and the second to clear the counter register.

DS3181/DS3182/DS3183/DS3184

203

Table 11-1. Global and Test Register Address Map

ADDRESS DESCRIPTION

000–01F Global Registers, Section 12.1

020–02F Unused

030–037 UTOPIA/POS-PHY Transmit System Bus, Section 12.3

038–03F UTOPIA/POS-PHY Receive System Bus, Section 12.3.2

040–1FF Port 1 Register Map

200–23F Test Registers

240–3FF Port 2 Register Map

400–43F Test Registers

440–5FF Port 3 Register Map

600–63F Unused

640–6FF Port 4 Register Map

Each port has a relative address range of 040h to 1FFh. The lower 000h to 03Fh address range is used for global,

test and reserved registers. The following table is a map of the registers for each port. The address offset is from

the start of each port range of 000h, 200h, 400h and 600h. In a DS3183, writes to registers in port 4 will be ignored

and reads from port 4 registers will read back zero values. Similarly, in a DS3181, writes to registers in port 2 will

be ignored and reads from port 2 will read back zero values.

Note: The

RDY

signal will not go active if the user attempts to read or write unused ports or unused registers not assigned to

any design blocks. The

RDY

signal will go active if the user writes or reads reserved registers or unused registers within design

blocks.

Table 11-2. Per-Port Register Address Map

Port 1 Port 2 Port 3 Port 4

040–1FF 240–3FF 440–5FF 640–7FF

ADDRESS

OFFSET DESCRIPTION

040–05F Port Common Registers

060–07F BERT

080–08B Reserved

08C–08F B3ZS/HDB3 Transmit Line Encoder

090–09F B3ZS/HDB3 Receive Line Decoder

0A0–0AF HDLC Transmit

0B0–0BF HDLC Receive

0C0–0CF FEAC Transmit

0D0–0DF FEAC Receive

0E0–0E7 Reserved

0E8–0EF Trail Trace Transmit

0F0–0FF Trail Trace Receive

ADDRESS

OFFSET DESCRIPTION

100– 117 Reserved

118–11F DS3/E3 Framer Transmit

120–13F DS3/E3 Framer Receive

140–147 DS3/E3 Fractional Transmit

148–14F DS3/E3 Fractional Receive

150–15F DS3/E3 PLCP Transmit

160–17F DS3/E3 PLCP Receive

180–18F UTOPIA/POS-PHY Transmit FIFO

190–19F UTOPIA/POS-PHY Receive FIFO

1A0–1BF Transmit Cell/Packet Processor

1C0–1FF Receive Cell/Packet Processor

DS3181/DS3182/DS3183/DS3184

204

12 REGISTER MAPS AND DESCRIPTIONS

12.1 Registers Bit Maps

Note: In 8-bit mode, register bits[15:8] correspond to the upper byte, and register bits[7:0] correspond to the lower

byte. For example, address 001h is the upper byte (bits [15:8]) and address 000h is the lower byte (bits [7:0]) for

RDY signal to go low when written to or read from. The “—“ designation indicates that the bit is not assigned.

12.1.1 Global Register Bit Map

Table 12-1. Global Register Bit Map

Address Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

16-bit 8-bit Register Type

Bit 15 Bit 14 Bit 13 Bit 12 Bit 11 Bit 10 Bit 9 Bit 8

000 ID7 ID6 ID5 ID4 ID3 ID2 ID1 ID0

000 001 GL.IDR R ID15 ID14 ID13 ID12 ID11 ID10 ID9 ID8

002 TMEI MEIMS GPM1 GPM0 PMU LSBCRE RSTDP RST

002 003 GL.CR1 RW GWRM INTM DIREN — SIW1 SIW0 SIM1 SIM0

004 — — — — CLAD3 CLAD2 CLAD1 CLAD0

004 005 GL.CR2 RW — — — G8KRS2 G8KRS1 G8KRS0 G8K0S G8KIS

006- — — — — — — — —

006-

008 009 UNUSED — — — — — — — —

00A GPIO4S1 GPIO4S0 GPIO3S1 GPIO3S0 GPIO2S1 GPIO2S0 GPIO1S1 GPIO1S0

00A 00B GL.GIOCR RW GPIO8S1 GPIO8S0 GPIO7S1 GPIO7S0 GPIO6S1 GPIO6S0 GPIO5S1 GPIO5S0

00C — — — — — — — —

00C 00D UNUSED — — — — — — — —

010 PISR4 PISR3 PISR2 PISR1 — — TSSR GSR

010 011 GL.ISR R — — — — — — — —

012 PISRIE4 PISRIE3 PISRIE2 PISRIE1 — — TSSRIE GSRIE

012 013 GL.ISRIE RW

014 — — — — — — CLOL GPMS

014 015 GL.SR R — — — — — — — —

016 — — — 8KREFL CLADL ONESL CLOLL GPMSL

016 017 GL.SRL RL — — — — — — — —

018 — — — — — ONESIE CLOLIE GPMSIE

018 019 GL.SRIE R — — — — — — — —

01A — — — — — — — —

01A 01B UNUSED — — — — — — — —

01C GPIO8 GPIO7 GPIO6 GPIO5 GPIO4 GPIO3 GPIO2 GPIO1

01C 01D GL.GIORR R — — — — — — — —

01E — — — — — — — —

01E 01F UNUSED — — — — — — — —

DS3181/DS3182/DS3183/DS3184

205

Table 12-2. System Interface Bit Map

Address Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

16-bit 8-bit Register Type

Bit 15 Bit 14 Bit 13 Bit 12 Bit 11 Bit 10 Bit 9 Bit 8

030 — — — — TPARP TFLVI TSBRE THECT

030 031 SI.TCR RW — — TXAD5 TXAD4 TXAD3 TXAD2 TXAD1 TXAD0

032 — — — — — — TSCLKAL TPREL

032 033 SI.TSRL RL — — — — — — — —

034 — — — — — — — TPREIE

034 035 SI.TSRIE RW — — — — — — — —

036 — — — — — — — —

036 037 UNUSED — — — — — — — —

038 — RXAD2 RXAD1 RXAD0 RPARP RFLVI RSBRE RHECT

038 039 SI.RCR1 RW — — — — — RMDT2 RMDT1 RMDT0

03A RLBL7 RLBL6 RLBL5 RLBL4 RLBL3 RLBL2 RLBL1 RLBL0

03A 03B SI.RCR2 RW — — RMBL5 RMBL4 RMBL3 RMBL2 RMBL1 RMBL0

03C — — — — — — — RSCLKA

03C 03D SI.RSRL RL — — — — — — — —

03E — — — — — — — —

03E 03F UNUSED R — — — — — — — —

Table 12-3. Port Register Bit Map

Note: J and K are variable dependent upon port.

Port 1 Port 2 Port 3 Port 4

J 0 2 4 6

K 1 3 5 7

Address Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

16-bit 8-bit Register Type

Bit 15 Bit 14 Bit 13 Bit 12 Bit 11 Bit 10 Bit 9 Bit 8

J40 TMEI MEIM — PMUM PMU PD RSTDP RST

J40 J41 PORT.CR1 RW NAD PAIS2 PAIS1 PAIS0 LAIS1 LAIS0 BENA HDSEL

J42 RCDIS PMCPE FM5 FM4 FM3 FM2 FM1 FM0

J42 J43 PORT.CR2 RW TLEN LTS RMON TLBO RCDV8 LM2 LM1 LM0

J44 P8KRS1 P8KRS0 P8KREF LOOPT CLADC RFTS TFTS TLTS

J44 J45 PORT.CR3 RW — — RCLKS RSOFOS RPFPE TCLKS TSOFOS TPFPE

J46 GPIOB3 GPIOB2 GPIOB1 GPIOB0 GPIOA3 GPIOA2 GPIOA1 GPIOA0

J46 J47 PORT.CR4 RW — — — — SLB LBM2 LBM1 LBM0

J48 — — — — — — — —

J48 J49 UNUSED — — — — — — — —

J4A TOHI TOHCKI TSOFII TNEGI TPOSI TLCKI TCKOI TCKII

J4B TPDEI TPDTI — TPOHSI TPOHEI TPOHI TOHSI TOHEI

J4C ROHI ROHCKI — RNEGI RPOSI RLCKI RCKOI —

J4D — RPDTI RFOHEI RPOHSI — RPOHI ROHSI —

J4E — — — — — — — —

J4E J4F UNUSED — — — — — — — —

J50 TTSR FSR HSR BSR SFSR CPSR PPSR FMSR

J50 J51 PORT.ISR R — — — — — — PSR LCSR

J52 — — — — — TDM RLOL PMS

J52 J53 PORT.SR R — — — — — — — —

J54 RLCLKA TCLKIA — — — TDML RLOLL PMSL

J54 J55 PORT.SRL RL — — — — — — — —

J56 — — — — — TDMIE RLOLIE PMSIE

J56 J57 PORT.SRIE RW — — — — — — — —

DS3181/DS3182/DS3183/DS3184

206

Address Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

16-bit 8-bit Register Type

Bit 15 Bit 14 Bit 13 Bit 12 Bit 11 Bit 10 Bit 9 Bit 8

J58- — — — — — — — —

J58-

J5E J5F UNUSED — — — — — — — —

Table 12-4. BERT Register Bit Map

Address Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

16-bit 8-bit Register Type

Bit 15 Bit 14 Bit 13 Bit 12 Bit 11 Bit 10 Bit 9 Bit 8

J60 PMUM LPMU RNPL RPIC MPR APRD TNPL TPIC

J60 J61 BERT.CR RW — — — — — — — —

J62 — QRSS PTS PLF4 PLF3 PLF2 PLF1 PLF0

J62 J63 BERT.PCR RW — — — PTF4 PTF3 PTF2 PTF1 PTF0

J64 BSP7 BSP6 BSP5 BSP4 BSP3 BSP2 BSP1 BSP0

J64 J65 BERT.SPR1 RW BSP15 BSP14 BSP13 BSP12 BSP11 BSP10 BSP9 BSP8

J66 BSP23 BSP22 BSP21 BSP20 BSP19 BSP18 BSP17 BSP16

J66 J67 BERT.SPR2 RW BSP31 BSP30 BSP29 BSP28 BSP27 BSP26 BSP25 BSP24

J68 — — TEIR2 TEIR1 TEIR0 BEI TSEI MEIMS

J68 J69 BERT.TEICR RW — — — — — — — —

J6A — — — — — — — —

J6A J6B UNUSED — — — — — — — —

J6C — — — — PMS — BEC OOS

J6C J6D BERT.SR R — — — — — — — —

J6E — — — — PMSL BEL BECL OOSL

J6E J6F BERT.SRL RL — — — — — — — —

J70 — — — — PMSIE BEIE BECIE OOSIE

J70 J71 BERT.SRIE RW — — — — — — — —

J72 — — — — — — — —

J72 J73 UNUSED — — — — — — — —

J74 BEC7 BEC6 BEC5 BEC4 BEC3 BEC2 BEC1 BEC0

J74 J75 BERT.RBECR1 R BEC15 BEC14 BEC13 BEC12 BEC11 BEC10 BEC9 BEC8

J76 BEC23 BEC22 BEC21 BEC20 BEC19 BEC18 BEC17 BEC16

J76 J77 BERT.RBECR2 R — — — — — — — —

J78 BC7 BC6 BC5 BC4 BC3 BC2 BC1 BC0

J78 J79 BERT.RBCR1 R BC15 BC14 BC13 BC12 BC11 BC10 BC9 BC8

J7A BC23 BC22 BC21 BC20 BC19 BC18 BC17 BC16

J7A J7B BERT.RBCR2 R BC31 BC30 BC29 BC28 BC27 BC26 BC25 BC24

J7C — — — — — — — —

J7C-

J7E J7F UNUSED — — — — — — — —

Table 12-5. LINE Register Bit Map

Address Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

16-bit 8-bit Register Type

Bit 15 Bit 14 Bit 13 Bit 12 Bit 11 Bit 10 Bit 9 Bit 8

J8C — — — TZSD EXZI BPVI TSEI MEIMS

J8C J8D LINE.TCR RW — — — — — — — —

J8E — — — — — — — —

J8E J8F UNUSED — — — — — — — —

J90 — — — — E3CVE REZSF RDZSF RZSD

J90 J91 LINE.RCR RW — — — — — — — —

J92 — — — — — — — —

J92 J93 UNUSED — — — — — — — —

J94 — — — — EXZC — BPVC LOS

J94 J95 LINE.RSR R — — — — — — — —

DS3181/DS3182/DS3183/DS3184

207

Address Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

16-bit 8-bit Register Type

Bit 15 Bit 14 Bit 13 Bit 12 Bit 11 Bit 10 Bit 9 Bit 8

J96 — — ZSCDL EXZL EXZCL BPVL BPVCL LOSL

J96 J97 LINE.RSRL RL — — — — — — — —

J98 — — ZSCDIE EXZIE EXZCIE BPVIE BPVCIE LOSIE

J98 J99 LINE.RSRIE RW — — — — — — — —

J9A — — — — — — — —

J9A J9B UNUSED — — — — — — — —

J9C BPV7 BPV6 BPV5 BPV4 BPV3 BPV2 BPV1 BPV0

J9C J9D LINE.RBPVCR R BPV15 BPV14 BPV13 BPV12 BPV11 BPV10 BPV9 BPV8

J9E EXZ7 EXZ6 EXZ5 EXZ4 EXZ3 EXZ2 EXZ1 EXZ0

J9E J9F LINE.REXZCR R EXZ15 EXZ14 EXZ13 EXZ12 EXZ11 EXZ10 EXZ9 EXZ8

12.1.2 HDLC Register Bit Map

Table 12-6. HDLC Register Bit Map

Address Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

16-bit 8-bit Register Type

Bit 15 Bit 14 Bit 13 Bit 12 Bit 11 Bit 10 Bit 9 Bit 8

JA0 — TPSD TFEI TIFV TBRE TDIE TFPD TFRST

JA0 JA1 HDLC.TCR RW — — — TDAL4 TDAL3 TDAL2 TDAL1 TDAL0

JA2 — — — — — — — TDPE

JA2 JA3 HDLC.TFDR RW TFD7 TFD6 TFD5 TFD4 TFD3 TFD2 TFD1 TFD0

JA4 — — — — — TFF TFE THDA

JA4 JA5 HDLC.TSR R — — TFFL5 TFFL4 TFFL3 TFFL2 TFFL1 TFFL0

JA6 — — TFOL TFUL TPEL — TFEL THDAL

JA6 JA7 HDLC.TSRL RL — — — — — — — —

JA8 — — TFOIE TFUIE TPEIE — TFEIE THDAIE

JA8 JA9 HDLC.TSRIE RW — — — — — — — —

JAA — — — — — — — —

JAA-

JAE JAF UNUSED — — — — — — — —

JB0 — — — — RBRE RDIE RFPD RFRST

JB0 JB1 HDLC.RCR RW — — — RDAL4 RDAL3 RDAL2 RDAL1 RDAL0

JB2 — — — — — — — —

JB2 JB3 UNUSED — — — — — — — —

JB4 — — — — — RFF RFE RHDA

JB4 JB5 HDLC.RSR R — — — — — — — —

JB6 RFOL — — RPEL RPSL RFFL — RHDAL

JB6 JB7 HDLC.RSRL RL — — — — — — — —

JB8 RFOIE — — RPEIE RPSIE RFFIE — RHDAIE

JB8 JB9 HDLC.RSRIE RW — — — — — — — —

JBA — — — — — — — —

JBA JBB UNUSED — — — — — — — —

JBC — — — — RPS2 RPS1 RPS0 RFDV

JBC JBD HDLC.RFDR R RFD7 RFD6 RFD5 RFD4 RFD3 RFD2 RFD1 RFD0

JBE — — — — — — — —

JBE JBF UNUSED — — — — — — — —

DS3181/DS3182/DS3183/DS3184

208

Table 12-7. FEAC Register Bit Map

Address Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

16-bit 8-bit Register Type

Bit 15 Bit 14 Bit 13 Bit 12 Bit 11 Bit 10 Bit 9 Bit 8

JC0 — — — — — TFCL TFS1 TFS0

JC0 JC1 FEAC.TCR RW — — — — — — — —

JC2 — — TFCA5 TFCA4 TFCA3 TFCA2 TFCA1 TFCA0

JC2 JC3 FEAC.TFDR RW — — TFCB5 TFCB4 TFCB3 TFCB2 TFCB1 TFCB0

JC4 — — — — — — — TFI

JC4 JC5 FEAC.TSR R — — — — — — — —

JC6 — — — — — — — TFIL

JC6 JC7 FEAC.TSRL RL — — — — — — — —

JC8 — — — — — — — TFIIE

JC8 JC9 FEAC.TSRIE RW — — — — — — — —

JCA — — — — — — — — JCA-

JCE JCF UNUSED — — — — — — — —

JD0 — — — — — — — RFR

JD0 JD1 FEAC.RCR RW — — — — — — — —

JD2 — — — — — — — —

JD2 JD3 UNUSED — — — — — — — —

JD4 — — — — RFFE — RFCD RFI

JD4 JD5 FEAC.RSR R — — — — — — — —

JD6 — — — — — RFFOL RFCDL RFIL

JD6 JD7 FEAC.RSRL RL — — — — — — — —

JD8 — — — — — RFFOIE RFCDIE RFIIE

JD8 JD9 FEAC.RSRIE RW — — — — — — — —

JDA — — — — — — — —

JDA JDB UNUSED — — — — — — — —

JDC RFFI — RFF5 RFF4 RFF3 RFF2 RFF1 RFF0

JDC JDD FEAC.RFDR R — — — — — — — —

JDE — — — — — — — —

JDE JDF UNUSED — — — — — — — —

Table 12-8. Trail Trace Register Bit Map

Address Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

16-bit 8-bit Register Type

Bit 15 Bit 14 Bit 13 Bit 12 Bit 11 Bit 10 Bit 9 Bit 8

JE8 — — — Reserved TMAD TIDLE TDIE TBRE

JE8 JE9 TT.TCR RW — — — — — — — —

JEA — — Reserved Reserved TTIA3 TTIA2 TTIA1 TTIA0

JEA JEB TT.TTIAR R — — — — — — — —

JEC TTD7 TTD6 TTD5 TTD4 TTD3 TTD2 TTD1 TTD0

JEC JED TT.TIR R — — — — — — — —

JEE — — — — — — — —

JEE JEF UNUSED — — — — — — — —

JF0 — — Reserved Reserved RMAD RETCE RDIE RBRE

JF0 JF1 TT.RCR RW — — — — — — — —

JF2 — — Reserved Reserved RTIA3 RTIA2 RTIA1 RTIA0

JF2 JF3 TT.RTIAR R — — Reserved Reserved ETIA3 ETIA2 ETIA1 ETIA0

JF4 — — — — — RTIM RTIU RIDL

JF4 JF5 TT.RSR R — — — — — — — —

JF6 — — — — RTICL RTIML RTIUL RIDLL

JF6 JF7 TT.RSRL RL — — — — — — — —

DS3181/DS3182/DS3183/DS3184

209

Address Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

16-bit 8-bit Register Type

Bit 15 Bit 14 Bit 13 Bit 12 Bit 11 Bit 10 Bit 9 Bit 8

JF8 — — — — RTICIE RTIMIE RTIUIE RIDLIE

JF8 JF9 TT.RSRIE RW — — — — — — — —

JFA — — — — — — — —

JFA JFB UNUSED — — — — — — — —

JFC RTD7 RTD6 RTD5 RTD4 RTD3 RTD2 RTD1 RTD0

JFC JFD TT.RIR R — — — — — — — —

JFE ETD7 ETD6 ETD5 ETD4 ETD3 ETD2 ETD1 ETD0

JFE JFF TT.EIR R — — — — — — — —

— — — — — — — —

K00-

K16

K00-

K117 RESERVED — — — — — — — —

12.1.3 T3 Register Bit Map

Table 12-9. T3 Register Bit Map

Address Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

16-bit 8-bit Register Type

Bit 15 Bit 14 Bit 13 Bit 12 Bit 11 Bit 10 Bit 9 Bit 8

K18 — — TFEBE AFEBED TRDI ARDID TFGD TAIS

K18 K19 T3.TCR RW — — — PBGE TIDLE CBGD — —

K1A Reserved CPEIE PEI FEIC1 FEIC0 FEI TSEI MEIMS

K1A K1B T3.TEIR RW — — — — CCPEIE CPEI CFBEIE FBEI

K1C — — — — — — — —

K1C-

K1E K1F RESERVED — — — — — — — —

K20 RAILE RAILD RAIOD RAIAD ROMD LIP1 LIP0 FRSYNC

K20 K21 T3.RCR RW — COVHD MAOD MDAISI AAISD ECC FECC1 FECC0

K22 — — — — — — — —

K22 K23 RESERVED — — — — — — — —

K24 OOMF SEF — LOF RAI AIS OOF LOS

K24 K25 T3.RSR1 R Reserved Reserved — Reserved T3FM AIC IDLE RUA1

K26 — — — — CPEC FBEC PEC FEC

K26 K27 T3.RSR2 R — — — — — — — —

K28 OOMFL SEFL COFAL LOFL RAIL AISL OOFL LOSL

K28 K29 T3.RSRL1 RL Reserved Reserved Reserved Reserved T3FML AICL IDLEL RUA1L

K2A — — — — CPECL FBECL PECL FECL

K2A K2B T3.RSRL2 RL — — — — CPEL FBEL PEL FEL

K2C OOMFIE SEFIE COFAIE LOFIE RAIIE AISIE OOFIE LOSIE

K2C K2D T3.RSRIE1 RW Reserved Reserved Reserved Reserved T3FMIE AICIE IDLEIE RUA1IE

K2E — — — — CPECIE FBECIE PECIE FECIE

K2E K2F T3.RSRIE2 RW — — — — CPEIE FBEIE PEIE FEIE

K30 — — — — — — — —

K30-

K32 K33 RESERVED — — — — — — — —

K34 FE7 FE6 FE5 FE4 FE3 FE2 FE1 FE0

K34 K35 T3.RFECR R FE15 FE14 FE13 FE12 FE11 FE10 FE9 FE8

K36 PE7 PE6 PE5 PE4 PE3 PE2 PE1 PE0

K36 K37 T3.RPECR R PE15 PE14 PE13 PE12 PE11 PE10 PE9 PE8

K38 FBE7 FBE6 FBE5 FBE4 FBE3 FBE2 FBE1 FBE0

K38 K39 T3.RFBECR R FBE15 FBE14 FBE13 FBE12 FBE11 FBE10 FBE9 FBE8

K3A CPE7 CPE6 CPE5 CPE4 CPE3 CPE2 CPE1 CPE0

K3A K3B T3.RCPECR R CPE15 CPE14 CPE13 CPE12 CPE11 CPE10 CPE9 CPE8

K3C — — — — — — — —

K3C-

K3E K3F UNUSED — — — — — — — —

DS3181/DS3182/DS3183/DS3184

210

12.1.4 E3 G.751 Register Bit Map

Table 12-10. E3 G.751 Register Bit Map

Address Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

16-bit 8-bit Register Type

Bit 15 Bit 14 Bit 13 Bit 12 Bit 11 Bit 10 Bit 9 Bit 8

K18 — — Reserved Reserved TABC1 TABC0 TFGD TAIS

K18 K19 E3G751.TCR RW Reserved — — Reserved Reserved Reserved TNBC1 TNBC0

K1A Reserved Reserved Reserved FEIC1 FEIC0 FEI TSEI MEIMS

K1A K1B E3G751.TEIR RW — — — — Reserved Reserved Reserved Reserved

K1C — — — — — — — —

K1C-

K1E K1F RESERVED — — — — — — — —

K20 RAILE RAILD RAIOD RAIAD ROMD LIP1 LIP0 FRSYNC

K20 K21 E3G751.RCR RW Reserved Reserved DLS MDAISI AAISD ECC FECC1 FECC0

K22 — — — — — — — —

K22 K23 RESERVED — — — — — — — —

K24 RAB RNB — LOF RAI AIS OOF LOS

K24 K25 E3G751.RSR1 R Reserved Reserved — Reserved Reserved Reserved Reserved RUA1

K26 — — — — Reserved Reserved Reserved FEC

K26 K27 E3G751.RSR2 R — — — — — — — —

K28 ACL NCL COFAL LOFL RAIL AISL OOFL LOSL

K28 K29 E3G751.RSRL1 RL Reserved Reserved Reserved Reserved Reserved Reserved Reserved RUA1L

K2A — — — — Reserved Reserved Reserved FECL

K2A K2B E3G751.RSRL2 RL — — — — Reserved Reserved Reserved FEL

K2C ACIE NCIE COFAIE LOFIE RAIIE AISIE OOFIE LOSIE

K2C K2D

E3G751.RSRIE1

RW Reserved Reserved Reserved Reserved Reserved Reserved Reserved RUA1IE

K2E — — — — Reserved Reserved Reserved FECIE

K2E K2F E3G751.RSRIE2 RW — — — — Reserved Reserved Reserved FEIE

K30 — — — — — — — —

K30-

K32 K33 RESERVED — — — — — — — —

K34 FE7 FE6 FE5 FE4 FE3 FE2 FE1 FE0

K34 K35 E3G751.RFECR R FE15 FE14 FE13 FE12 FE11 FE10 FE9 FE8

K36- — — — — — — — —

K36-

K3A K3B RESERVED — — — — — — — —

K3C- — — — — — — — —

K3C-

K3E K3F UNUSED — — — — — — — —

DS3181/DS3182/DS3183/DS3184

211

12.1.5 E3 G.832 Register Bit Map

Table 12-11. E3 G.832 Register Bit Map

Address Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

16-bit 8-bit Register Type

Bit 15 Bit 14 Bit 13 Bit 12 Bit 11 Bit 10 Bit 9 Bit 8

K18 — — TFEBE AFEBED TRDI ARDID TFGD TAIS

K18 K19 E3G832.TCR RW Reserved — — Reserved Reserved TGCC TNRC1 TNRC0

K1A Reserved Reserved Reserved FEIC1 FEIC0 FEI TSEI MEIMS

K1A K1B E3G832.TEIR RW — — — — Reserved Reserved Reserved Reserved

K1C TPT2 TPT1 TPT0 TTIGD TTI3 TTI2 TTI1 TTI0

K1C K1D

E3G832.TMAB

R RW — — — — — — — —

K1E TNR7 TNR6 TNR5 TNR4 TNR3 TNR2 TNR1 TNR0

K1E K1F

E3G832.TNGB

R RW TGC7 TGC6 TGC5 TGC4 TGC3 TGC2 TGC1 TGC0

K20 RDILE RDILD RDIOD RDIAD ROMD LIP1 LIP0 FRSYNC

K20 K21 E3G832.RCR RW Reserved PEC DLS MDAISI AAISD ECC FECC1 FECC0

K22 — — — — EPT2 EPT1 EPT0 TIED

K22 K23 E3G832.RMACR RW — — — — — — — —

K24 Reserved Reserved — LOF RAI AIS OOF LOS

K24 K25 E3G832.RSR1 R Reserved TIU — RPTU RPTM Reserved Reserved RUA1

K26 — — — — Reserved FBEC PEC FEC

K26 K27 E3G832.RSR2 R — — — — — — — —

K28 GCL NRL COFAL LOFL RAIL AISL OOFL LOSL

K28 K29 E3G832.RSRL1 RL Reserved TIUL TIL RPTUL RPTML RPTL Reserved RUA1L

K2A — — — — Reserved FBECL PECL FECL

K2A K2B E3G832.RSRL2 RL — — — — Reserved FBEL PEL FEL

K2C GCIE NRIE COFAIE LOFIE RAIIE AISIE OOFIE LOSIE

K2C K2D E3G832.RSRIE1 RW Reserved — TIIE RPTUIE RPTMIE RPTIE Reserved RUA1IE

K2E — — — — Reserved FBECIE PECIE FECIE

K2E K2F E3G832.RSRIE2 RW — — — — Reserved FBEIE PEIE FEIE

K30 — RPT2 RPT1 RPT0 TI3 TI2 TI1 TI0

K30 K31 E3G832.RMABR R — — — — — — — —

K32 RNR7 RNR6 RNR5 RNR4 RNR3 RNR2 RNR1 RNR0

K32 K33 E3G832.RNGBR R RGC7 RGC6 RGC5 RGC4 RGC3 RGC2 RGC1 RGC0

K34 FE7 FE6 FE5 FE4 FE3 FE2 FE1 FE0

K34 K35 E3G832.RFECR R FE15 FE14 FE13 FE12 FE11 FE10 FE9 FE8

K36 PE7 PE6 PE5 PE4 PE3 PE2 PE1 PE0

K36 K37 E3G832.RPECR R PE15 PE14 PE13 PE12 PE11 PE10 PE9 PE8

K38 FBE7 FBE6 FBE5 FBE4 FBE3 FBE2 FBE1 FBE0

K38 K39 E3G832.RFBER R FBE15 FBE14 FBE13 FBE12 FBE11 FBE10 FBE9 FBE8

K3A — — — — — — — —

K3A K3B RESERVED — — — — — — — —

K3C- — — — — — — — —

K3C-

K3E K3F UNUSED — — — — — — — —

DS3181/DS3182/DS3183/DS3184

212

12.1.6 Clear-Channel Register Bit Map

Table 12-12. Clear-Channel Register Bit Map

Address Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

16-bit 8-bit Register Type

Bit 15 Bit 14 Bit 13 Bit 12 Bit 11 Bit 10 Bit 9 Bit 8

K18 — — Reserved Reserved Reserved Reserved Reserved TAIS

K18 K19 CC.TCR RW Reserved — — Reserved Reserved Reserved Reserved Reserved

K1A — — — — — — — —

K1A-

K1E K1F RESERVED — — — — — — — —

K20 Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved

K20 K21 CC.RCR RW Reserved Reserved Reserved MDAISI AAISD Reserved Reserved Reserved

K22 — — — — — — — —

K22 K23 RESERVED — — — — — — — —

K24 Reserved Reserved — Reserved Reserved Reserved Reserved LOS

K24 K25 CC.RSR1 R Reserved Reserved — Reserved Reserved Reserved Reserved RUA1

K26 — — — — — — — —

K26 K27 RESERVED — — — — — — — —

K28 Reserved Reserved Reserved Reserved Reserved Reserved Reserved LOSL

K28 K29 CC.RSRL1 RL Reserved Reserved Reserved Reserved Reserved Reserved Reserved RUA1L

K2A — — — — — — — —

K2A K2B RESERVED — — — — — — — —

K2C Reserved Reserved Reserved Reserved Reserved Reserved Reserved LOSIE

K2C K2D CC.RSRIE1 RW Reserved Reserved Reserved Reserved Reserved Reserved Reserved RUA1IE

K2E- — — — — — — — —

K2E-

K3A K3B RESERVED — — — — — — — —

K3C- — — — — — — — —

K3C-

K3E K3F UNUSED — — — — — — — —

12.1.7 Fractional Register Bit Map

Table 12-13. Fractional Register Bit Map

Address Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

16-bit 8-bit Register Type

Bit 15 Bit 14 Bit 13 Bit 12 Bit 11 Bit 10 Bit 9 Bit 8

K40 — — — — — TFOSC1 TFOSC0 TSASS

K40 K41 FRAC.TCR RW — — — — — — — —

K42 TDGS7 TDGS6 TDGS5 TDGS4 TDGS3 TDGS2 TDGS1 TDGS0

K42 K43 FRAC.TDGSR RW — — — TDGS12 TDGS11 TDGS10 TDGS9 TDGS8

K44 TSAS7 TSAS6 TSAS5 TSAS4 TSAS3 TSAS2 TSAS1 TSAS0

K44 K45 FRAC.TSASR RW — — — TSAS12 TSAS11 TSAS10 TSAS9 TSAS8

K46 — — — — — — — —

K46 K47 UNUSED — — — — — — — —

K48 — — — — — — — RSASS

K48 K49 FRAC.RCR RW — — — — — — — —

K4A RDGS7 RDGS6 RDGS5 RDGS4 RDGS3 RDGS2 RDGS1 RDGS0

K4A K4B FRAC.RDGSR RW — — — RDGS12 RDGS11 RDGS10 RDGS9 RDGS8

K4C RSAS7 RSAS6 RSAS5 RSAS4 RSAS3 RSAS2 RSAS1 RSAS0

K4C K4D FRAC.RSASR RW — — — RSAS12 RSAS11 RSAS10 RSAS9 RSAS8

K4E — — — — — — — —

K4E K4F UNUSED — — — — — — — —

DS3181/DS3182/DS3183/DS3184

213

Table 12-14. PLCP Register Bit Map

Address Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

16-bit 8-bit Register Type

Bit 15 Bit 14 Bit 13 Bit 12 Bit 11 Bit 10 Bit 9 Bit 8

K50 — — — TMC1 TMC0 TF1C1 TF1C0 AREID

K50 K51 PLCP.TCR RW — — — — — — — —

K52 — — FEE FEIC1 FEIC0 FEI TSEI MEIMS

K52 K53 PLCP.TEIR RW — — REIME CREIIE REIEI PBEE CPEIE PEI

K54 TREI3 TREI2 TREI1 TREI0 TRAI TLSS2 TLSS1 TLSS0

K54 K55 PLCP.TFGBR RW TF17 TF16 TF15 TF14 TF13 TF12 TF11 TF10

K56 TM17 TM16 TM15 TM14 TM13 TM12 TM11 TM10

K56 K57 PLCP.TM12BR RW TM27 TM26 TM25 TM24 TM23 TM22 TM21 TM20

K58 TZ17 TZ16 TZ15 TZ14 TZ13 TZ12 TZ11 TZ10

K58 K59 PLCP.TZ12BR RW TZ27 TZ26 TZ25 TZ24 TZ23 TZ22 TZ21 TZ20

K5A TZ37 TZ36 TZ35 TZ34 TZ33 TZ32 TZ31 TZ30

K5A K5B PLCP.TZ34BR RW TZ47 TZ46 TZ45 TZ44 TZ43 TZ42 TZ41 TZ40

K5C TZ57 TZ56 TZ55 TZ54 TZ53 TZ52 TZ51 TZ50

K5C K5D PLCP.TZ56BR RW TZ67 TZ66 TZ65 TZ64 TZ63 TZ62 TZ61 TZ60

K5E — — — — — — — —

K5E K5F UNUSED — — — — — — — —

K60 — RLIE — PECC FEPD FECC ECC FRSYNC

K60 K61 PLCP.RCR RW — — — — — — RHSC1 RHSC0

K62 — — — — — — — —

K62 K63 UNUSED — — — — — — — —

K64 — — REIC PEC FEC RAI — OOF

K64 K65 PLCP.RSR1 R — — — — — — — LOF

K66 — — — — — — — LSSU

K66 K67 PLCP.RSR2 R — — — — — — — —

K68 — — REICL PECL FECL RAIL COFAL OOFL

K68 K69 PLCP.RSRL1 RL — — REIL PEL FEL — — LOFL

K6A RZ3L RZ2L RZ1L RM2L RM1L RF1L LSSL LSSUL

K6A K6B PLCP.RSRL2 RL — — — — — RZ6L RZ5L RZ4L

K6C — — REICIE PECIE FECIE RAIIE COFAIE OOFIE

K6C K6D PLCP.RSRIE1 RW — — REIIE PEIE FEIE — — LOFIE

K6E RZ3IE RZ2IE RZ1IE RM2IE RM1IE RF1IE LSSIE LSSUIE

K6E K6F PLCP.RSRIE2 RW — — — — — RZ6IE RZ5IE RZ4IE

K70 FE7 FE6 FE5 FE4 FE3 FE2 FE1 FE0

K70 K71 PLCP.RFECR R FE15 FE14 FE13 FE12 FE11 FE10 FE9 FE8

K72 PE7 PE6 PE5 PE4 PE3 PE2 PE1 PE0

K72 K73 PLCP.RPECR R PE15 PE14 PE13 PE12 PE11 PE10 PE9 PE8

K74 REI7 REI6 REI5 REI4 REI3 REI2 REI1 REI0

K74 K75 PLCP.RREICR R REI15 REI14 REI13 REI12 REI11 REI10 REI9 REI8

K76 — — — — — LSS2 LSS1 LSS0

K76 K77 PLCP.RFGBR R RF17 RF16 RF15 RF14 RF13 RF12 RF11 RF10

K78 RM17 RM16 RM15 RM14 RM13 RM12 RM11 RM10

K78 K79 PLCP.RM12BR R RM27 RM26 RM25 RM24 RM23 RM22 RM21 RM20

K7A RZ17 RZ16 RZ15 RZ14 RZ13 RZ12 RZ11 RZ10

K7A K7B PLCP.RZ12BR R RZ27 RZ26 RZ25 RZ24 RZ23 RZ22 RZ21 RZ20

K7C RZ37 RZ36 RZ35 RZ34 RZ33 RZ32 RZ31 RZ30

K7C K7D PLCP.RZ34BR R RZ47 RZ46 RZ45 RZ44 RZ43 RZ42 RZ41 RZ40

K7E RZ57 RZ56 RZ55 RZ54 RZ53 RZ52 RZ51 RZ50

K7E K7F PLCP.RZ56BR R RZ67 RZ66 RZ65 RZ64 RZ63 RZ62 RZ61 RZ60

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Table 12-15. FIFO Register Bit Map

Address Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

16-bit 8-bit Register Type

Bit 15 Bit 14 Bit 13 Bit 12 Bit 11 Bit 10 Bit 9 Bit 8

K80 — — — — — — — TFRST

K80 K81 FF.TCR RW — — — — — — — —

K82 — — TFAF5 TFAF4 TFAF3 TFAF2 TFAF1 TFAF0

K82 K83 FF.TLCR RW — — TFAE5 TFAE4 TFAE3 TFAE2 TFAE1 TFAE0

K84 — — —

TPA4 TPA3 TPA2 TPA1 TPA0

K84 K85 FF.TPAC RW — — — — — — — —

K86 — — — — — — — —

K86 K87 UNUSED — — — — — — — —

K88 — — — TFATL TFSTL TFITL TFUL TFOL

K88 K89 FF.TSRL RL — — — — — — — —

K8A — — — TFATIE TFSTIE TFITIE TFUIE TFOIE

K8A K8B FF.TSRIE RW — — — — — — — —

K8C — — — — — — — —

K8C-

K8F K8F UNUSED — — — — — — — —

K90 — — — — — — — RFRST

K90 K91 FF.RCR RW — — — — — — — —

K92 — — RFAF5 RFAF4 RFAF3 RFAF2 RFAF1 RFAF0

K92 K93 FF.RLCR RW — — RFAE5 RFAE4 RFAE3 RFAE2 RFAE1 RFAE0

K94 — — —

RPA4 RPA3 RPA2 RPA1 RPA0

K94 K95 FF.RFPAC RW — — — — — — — —

K96 — — — — — — — —

K96 K97 UNUSED — — — — — — — —

K98 — — — — — — — RFOL

K98 K99 FF.RSRL RL — — — — — — — —

K9A — — — — — — — RFOIE

K9A K9B FF.RSRIE RW — — — — — — — —

K9C — — — — — — — —

K9C-

K9F K9F UNUSED — — — — — — — —

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12.1.8 Transmit Cell Processor Bit Map

Table 12-16. Transmit Cell Processor Register Bit Map

Address Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

16-bit 8-bit Register Type

Bit 15 Bit 14 Bit 13 Bit 12 Bit 11 Bit 10 Bit 9 Bit 8

KA0 — — TFCH TFCP THSE TSD TBRE TPTE

KA0 KA1 CP.TCR RW — — — —

TDSE TDHE THPE TCPAD

KA2 — — — — — — — —

KA2 KA3 RESERVED — — — — — — — —

KA4 TCEN7 TCEN6 TCEN5 TCEN4 TCEN3 TCEN2 TCEN1 TCEN0

KA4 KA5 CP.TECC RW MEIMS TCER6 TCER5 TCER4 TCER3 TCER2 TCER1 TCER0

KA6 THEM7 THEM6 THEM5 THEM4 THEM3 THEM2 THEM1 THEM0

KA6 KA7 CP.THMRC RW — — — — — — — —

KAA THP7 THP6 THP5 THP4 THP3 THP2 THP1 THP0

KAA KA9 CP.THPC1 RW THP15 THP14 THP13 THP12 THP11 THP10 THP9 THP8

KAA THP23 THP22 THP21 THP20 THP19 THP18 THP17 THP16

KAA KAB CP.THPC2 RW THP31 THP30 THP29 THP28 THP27 THP26 THP25 THP24

KAC TFPP7 TFPP6 TFPP5 TFPP4 TFPP3 TFPP2 TFPP1 TFPP0

KAC KAD CP.TFPPC RW — — — — — — — —

KAE — — — — — — — TECF

KAE KAF CP.TSR R — — — — — — — —

KB0 — — — — — — — TECFL

KB0 KB1 CP.TSRL RL — — — — — — — —

KB2 — — — — — — — TECFIE

KB2 KB3 CP.TSRIE RW — — — — — — — —

KB4 TCC7 TCC6 TCC5 TCC4 TCC3 TCC2 TCC1 TCC0

KB4 KB5 CP.TCCR1 R TCC15 TCC14 TCC13 TCC12 TCC11 TCC10 TCC9 TCC8

KB6 TCC23 TCC22 TCC21 TCC20 TCC19 TCC18 TCC17 TCC16

KB6 KB7 CP.TCCR2 R — — — — — — — —

KB8- — — — — — — — —

KB8-

KBE KBF RESERVED — — — — — — — —

— — — — — — — —

KBC-

KBE

KBC-

KBF UNUSED — — — — — — — —

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12.1.9 Transmit Packet Processor Bit Map

Table 12-17. Transmit Packet Processor Register Bit Map

Address Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

16-bit 8-bit Register Type

Bit 15 Bit 14 Bit 13 Bit 12 Bit 11 Bit 10 Bit 9 Bit 8

KA0 — — TFAD TF16 TIFV TSD TBRE TPTE

KA0 KA1 PP.TCR RW — — — — RES RES RES RES

KA2 TIFG7 TIFG6 TIFG5 TIFG4 TIFG3 TIFG2 TIFG1 TIFG0

KA2 KA3 PP.TIFGC RW — — — — — — — —

KA4 TPEN7 TPEN6 TPEN5 TPEN4 TPEN3 TPEN2 TPEN1 TPEN0

KA4 KA5 PP.TEPC RW MEIMS TPER6 TPER5 TPER4 TPER3 TPER2 TPER1 TPER0

KA6- — — — — — — — —

KA6-

KAC KAD RESERVED — — — — — — — —

KAE — — — — — — — TEPF

KAE KAF PP.TSR R — — — — — — — —

KB0 — — — — — — — TEPFL

KB0 KB1 PP.TSRL RL — — — — — — — —

KB2 — — — — — — — TEPFIE

KB2 KB3 PP.TSRIE RW — — — — — — — —

KB4 TPC7 TPC6 TPC5 TPC4 TPC3 TPC2 TPC1 TPC0

KB4 KB5 PP.TPCR1 R TPC15 TPC14 TPC13 TPC12 TPC11 TPC10 TPC9 TPC8

KB6 TPC23 TPC22 TPC21 TPC20 TPC19 TPC18 TPC17 TPC16

KB6 KB7 PP.TPCR2 R — — — — — — — —

KB8 TBC7 TBC6 TBC5 TBC4 TBC3 TBC2 TBC1 TBC0

KB8 KB9 PP.TBCR1 R TBC15 TBC14 TBC13 TBC12 TBC11 TBC10 TBC9 TBC8

KBA TBC23 TBC22 TBC21 TBC20 TBC19 TBC18 TBC17 TBC16

KBA KBB PP.TBCR2 R TBC31 TBC30 TBC29 TBC28 TBC27 TBC26 TBC25 TBC24

KBC- — — — — — — — —

KBC-

KBE KBF RESERVED — — — — — — — —

Table 12-18. Receive Cell Processor Register Bit Map

Address Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

16-bit 8-bit Register Type

Bit 15 Bit 14 Bit 13 Bit 12 Bit 11 Bit 10 Bit 9 Bit 8

KC0 RROC1 RROC0 RCPAD RHECD RHDE RDD RBRE RPTE

KC0 KC1 CP.RCR1 RW RDDE RDHE RECED RHPM1 RHPM0 RICFD RUCFE RICFE

KC2 — — — — — — — —

KC2 KC3 RESERVED — — — — — — — —

KC4 RHP7 RHP6 RHP5 RHP4 RHP3 RHP2 RHP1 RHP0

KC4 KC5 CP.RHPC1 RW RHP15 RHP14 RHP13 RHP12 RHP11 RHP10 RHP9 RHP8

KC6 RHP23 RHP22 RHP21 RHP20 RHP19 RHP18 RHP17 RHP16

KC6 KC7 CP.RHPC2 RW RHP31 RHP30 RHP29 RHP28 RHP27 RHP26 RHP25 RHP24

KC8 RHPD7 RHPD6 RHPD5 RHPD4 RHPD3 RHPD2 RHPD1 RHPD0

KC8 KC9 CP.RHPMC1 RW RHPD15 RHPD14 RHPD13 RHPD12 RHPD11 RHPD10 RHPD9 RHPD8

KCA RHPD23 RHPD22 RHPD21 RHPD20 RHPD19 RHPD18 RHPD17 RHPD16

KCA KCB CP.RHPMC2 RW RHPD31 RHPD30 RHPD29 RHPD28 RHPD27 RHPD26 RHPD25 RHPD24

KCC RLT7 RLT6 RLT5 RLT4 RLT3 RLT2 RLT1 RLT0

KCC KCD CP.RLTC RW RLT15 RLT14 RLT13 RLT12 RLT11 RLT10 RLT9 RLT8

KCE — — — — — RECC RHPC RCHC

KCE KCF CP.RSR R — — — — OOS — OCD LCD

KD0 RECL RCHL RIDL RUDL RIVDL RECCL RHPCL RCHCL

KD0 KD1 CP.RSRL RL — — — — OOSL COCDL OCDCL LCDCL

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Address Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

16-bit 8-bit Register Type

Bit 15 Bit 14 Bit 13 Bit 12 Bit 11 Bit 10 Bit 9 Bit 8

KD2 RECIE RCHIE RIDIE RUDIE RIVDIE RECCIE RHPCIE RCHCIE

KD2 KD3 CP.RSRIE RW — — — — OOSIE COCDIE OCDCIE LCDCIE

KD4 RCC7 RCC6 RCC5 RCC4 RCC3 RCC2 RCC1 RCC0

KD4 KD5 CP.RCCR1 R RCC15 RCC14 RCC13 RCC12 RCC11 RCC10 RCC9 RCC8

KD6 RCC23 RCC22 RCC21 RCC20 RCC19 RCC18 RCC17 RCC16

KD6 KD7 CP.RCCR2 R — — — — — — — —

KD8 RECC7 RECC6 RECC5 RECC4 RECC3 RECC2 RECC1 RECC0

KD8 KD9 CP.RECCR1 R RECC15 RECC14 RECC13 RECC12 RECC11 RECC10 RECC9 RECC8

KDA RECC23 RECC22 RECC21 RECC20 RECC19 RECC18 RECC17 RECC16

KDA KDB CP.RECCR2 R — — — — — — — —

KDC RHPC7 RHPC6 RHPC5 RHPC4 RHPC3 RHPC2 RHPC1 RHPC0

KDC KDD CP.RHPCR1 R RHPC15 RHPC14 RHPC13 RHPC12 RHPC11 RHPC10 RHPC9 RHPC8

KDE — — — — — — — —

KDE KDF CP.RHPCR2 R RHPC23 RHPC22 RHPC21 RHPC20 RHPC19 RHPC18 RHPC17 RHPC16

KE0 RCHC7 RCHC6 RCHC5 RCHC4 RCHC3 RCHC2 RCHC1 RCHC0

KE0 KE1 CP.RCCCR1 R RCHC15 RCHC14 RCHC13 RCHC12 RCHC11 RCHC10 RCHC9 RCHC8

KE2 RCHC23 RCHC22 RCHC21 RCHC20 RCHC19 RCHC18 RCHC17 RCHC16

KE2 KE3 CP.RCCCR2 R — — — — — — — —

KE4 RFCC7 RFCC6 RFCC5 RFCC4 RFCC3 RFCC2 RFCC1 RFCC0

KE4 KE5 CP.RFCCR1 R RFCC15 RFCC14 RFCC13 RFCC12 RFCC11 RFCC10 RFCC9 RFCC8

KE6 RFCC23 RFCC22 RFCC21 RFCC20 RFCC19 RFCC18 RFCC17 RFCC16

KE6 KE7 CP.RFCCR2 R — — — — — — — —

KE8- — — — — — — — —

KE8-

KEE KEF RESERVED — — — — — — — —

KF0- — — — — — — — —

KF0-

KFE KFF UNUSED — — — — — — — —

Table 12-19. Receive Packet Processor Register Bit Map

Address Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

16-bit 8-bit Register Type

Bit 15 Bit 14 Bit 13 Bit 12 Bit 11 Bit 10 Bit 9 Bit 8

KC0 Reserved Reserved RFPD RF16 RFED RDD RBRE RPTE

KC0 KC1 PP.RCR RW RMNS7 RMNS6 RMNS5 RMNS4 RMNS3 RMNS2 RMNS1 RMNS0

KC2 RMX7 RMX6 RMX5 RMX4 RMX3 RMX2 RMX1 RMX0

KC2 KC3 PP.RMPSC RW RMX15 RMX14 RMX13 RMX12 RMX11 RMX10 RMX9 RMX8

KC4- — — — — — — — —

KC4-

KCC KCD RESERVED — — — — — — — —

KCE — — — — — REPC RAPC RSPC

KCE KCF PP.RSR R — — — — Reserved Reserved Reserved Reserved

KD0 REPL RAPL RIPDL RSPDL RLPDL REPCL RAPCL RSPCL

KD0 KD1 PP.RSRL RL — — — — Reserved Reserved Reserved Reserved

KD2 REPIE RAPIE RIPDIE RSPDIE RLPDIE REPCIE RAPCIE RSPCIE

KD2 KD3 PP.RSRIE RW — — — — Reserved Reserved Reserved Reserved

KD4 RPC7 RPC6 RPC5 RPC4 RPC3 RPC2 RPC1 RPC0

KD4 KD5 PP.RPCR1 R RPC15 RPC14 RPC13 RPC12 RPC11 RPC10 RPC9 RPC8

KD6 RPC23 RPC22 RPC21 RPC20 RPC19 RPC18 RPC17 RPC16

KD6 KD7 PP.RPCR2 R — — — — — — — —

KD8 RFPC7 RFPC6 RFPC5 RFPC4 RFPC3 RFPC2 RFPC1 RFPC0

KD8 KD9 PP.RFPCR1 R RFPC15 RFPC14 RFPC13 RFPC12 RFPC11 RFPC10 RFPC9 RFPC8

KDA RFPC23 RFPC22 RFPC21 RFPC20 RFPC19 RFPC18 RFPC17 RFPC16

KDA KDB PP.RFPCR2 R — — — — — — — —

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Address Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

16-bit 8-bit Register Type

Bit 15 Bit 14 Bit 13 Bit 12 Bit 11 Bit 10 Bit 9 Bit 8

KDC RAPC7 RAPC6 RAPC5 RAPC4 RAPC3 RAPC2 RAPC1 RAPC0

KDC KDD PP.RAPCR1 R RAPC15 RAPC14 RAPC13 RAPC12 RAPC11 RAPC10 RAPC9 RAPC8

KDE RAPC23 RAPC22 RAPC21 RAPC20 RAPC19 RAPC18 RAPC17 RAPC16

KDE KDF PP.RAPCR2 R — — — — — — — —

KE0 RSPC7 RSPC6 RSPC5 RSPC4 RSPC3 RSPC2 RSPC1 RSPC0

KE0 KE1 PP.RSPCR1 R RSPC15 RSPC14 RSPC13 RSPC12 RSPC11 RSPC10 RSPC9 RSPC8

KE2 RSPC23 RSPC22 RSPC21 RSPC20 RSPC19 RSPC18 RSPC17 RSPC16

KE2 KE3 PP.RSPCR2 R — — — — — — — —

KE4 — — — — — — — —

KE4-

KE6 KE7 RESERVED — — — — — — — —

KE8 RBC7 RBC6 RBC5 RBC4 RBC3 RBC2 RBC1 RBC0

KE8 KE9 PP.RBCR1 R RBC15 RBC14 RBC13 RBC12 RBC11 RBC10 RBC9 RBC8

KEA RBC23 RBC22 RBC21 RBC20 RBC19 RBC18 RBC17 RBC16

KEA KEB PP.RBCR2 R RBC31 RBC30 RBC29 RBC28 RBC27 RBC26 RBC25 RBC24

KEC REBC7 REBC6 REBC5 REBC4 REBC3 REBC2 REBC1 REBC0

KEC KED PP.REBCR1 R REBC15 REBC14 REBC13 REBC12 REBC11 REBC10 REBC9 REBC8

KEE REBC23 REBC22 REBC21 REBC20 REBC19 REBC18 REBC17 REBC16

KEE KEF PP.REBCR2 R REBC31 REBC30 REBC29 REBC28 REBC27 REBC26 REBC25 REBC24

KF0- — — — — — — — —

KF0-

KFE KFF UNUSED — — — — — — — —

Bits that are underlined are read-only; all other bits are read-write.

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12.2 Global Registers

Table 12-20. Global Register Map

ADDRESS REGISTER REGISTER DESCRIPTION

000h GL.IDR Global ID Register

002h GL.CR1 Global Control Register 1

004h GL.CR2 Global Control Register 2

006h — Unused

008h — Unused

00Ah GL.GIOCR Global General-Purpose IO Control Register

00Ch — Unused

00Eh — Unused

010h GL.ISR Global Interrupt Status Register

012h GL.ISRIE Global Interrupt Status Register Interrupt Enable

014h GL.SR Global Status Register

016h GL.SRL Global Status Register Latched

018h GL.SRIE Global Status Register Interrupt Enable

01Ah — Unused

01Ch GL.GIORR Global General-Purpose IO Read register

01Eh — Unused

12.2.1 Register Bit Descriptions

Bit # 15 14 13 12 11 10 9 8

Name ID15 ID14 ID13 ID12 ID11 ID10 ID9 ID8

Bit # 7 6 5 4 3 2 1 0

Name ID7 ID6 ID5 ID4 ID3 ID2 ID1 ID0

Bits 15 to 12: Device REV ID Bits 15 to 12 (ID15 to ID12). These bits of the device ID register has same

information as the four bits of JTAG REV ID portion of the JTAG ID register. JTAG ID[31:28].

Bits 11 to 0: Device CODE ID Bits 11 to 0 (ID11 to ID0). These bits of the device code ID register has same

information as the lower 12 bits of JTAG CODE ID portion of the JTAG ID register. JTAG ID[23:12].

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Bit # 15 14 13 12 11 10 9 8

Name GWRM INTM DIREN — SIW1 SIW0 SIM1 SIM0

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name TMEI MEIMS GPM1 GPM0 PMU LSBCRE RSTDP RST

Default 0 0 0 0 0 0 1 0

Bit 15: Global Write Mode (GWRM) This bit enables the global write mode. When this bit is set, a write to the

register of any port will write to the same register in all the ports. Reading the registers of any port is not supported

and will read back undefined data.

0 = Normal write mode

1 = Global write mode

Bit 14: INT pin mode (INTM) This bit determines the inactive mode of the INT pin. The INT pin always drives low

when active.

0 = Pin is high impedance when not active

1 = Pin drives high when not active

Bit 13: Direct Status Enable (DIREN) This bit selects between the direct status and polled status modes for

UTOPIA and POS-PHY.

0 = Polled status mode

1 = Direct status mode

Bits 11 and 10: System Interface Bus Width (SIW[1:0]) These bits configure the system bus width.

00 = 8-bit

01 = 16-bit

1X = 32-bit

Bits 9 and 8: System Interface Mode (SIM[1:0]) These bits configure the system bus mode.

00 = UTOPIA L2

01 = UTOPIA L3

10 = POS-PHY L2

11 = POS-PHY L3 or SPI-3

Bit 7: Transmit Manual Error Insert (TMEI) This bit is used insert an error in all ports and error insertion logic

configured for global error insertion. An error(s) is inserted at the next opportunity when this bit transitions from low

to high. The GL.CR1.MEIMS bit must be clear for this bit to operate.

Bit 6: Transmit Manual Error Insert Select (MEIMS) This bit is used to select the source of the global manual

error insertion signal

0 = Global error insertion using TMEI bit

1 = Global error insertion using the GPIO6 pin

Bits 5 and 4: Global Performance Monitor Update Mode (GPM[1:0]) These bits select the global performance

monitor register update mode.

00 = Global PM update using the PMU bit

01 = Global PM update using the GPIO8 pin

1x = One second PM update using the internal one second counter

Bit 3: Global Performance Monitor Update Register (PMU) This bit is used to update all of the performance

monitor registers configured to use this bit. When this bit is toggled from low to high the performance registers

configured to use this signal will be updated with the latest count value from the counters, and the counters will be

reset. The bit should remain high until the performance register update status bit (GL.SR.PMS) goes high, then it

should be brought back low which clears the PMS status bit.

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Bit 2: Latched Status Bit Clear on Read Enable (LSBCRE). This signal determines when latched status register

bits are cleared.

0 = Latched status register bits are cleared on a write

1 = Latched status register bits are cleared on a read

Bit 1: Reset Data Path (RSTDP). When this bit is set, it will force all of the internal data path registers in all ports

to their default state. This bit must be set high for a minimum of 100ns. See Section 10.3. Note: The default state is

a 1 (after a general reset, this bit will be set to one).

0 = Normal operation

1 = Force all data path registers to their default values

Bit 0: Reset (RST). When this bit is set, all of the internal data path and status and control registers (except this

RST bit), on all of the ports, will be reset to their default state. This bit must be set high for a minimum of 100ns.

See Section 10.3.

0 = Normal operation

1 = Force all internal registers to their default values

Bit # 15 14 13 12 11 10 9 8

Name — — — G8KRS2 G8KRS1 G8KRS0 G8K0S G8KIS

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — — — CLAD3 CLAD2 CLAD1 CLAD0

Default 0 0 0 0 0 0 0 0

Bits 12 to 10: Global 8KHz Reference Source [2:0] (G8KRS[2:0]). These bits determine the source for the

internally generated 8 kHz reference as well as the internal one-second reference, which is derived from the Global

8kHz reference. The source is selected from one of the CLAD clocks or from one of the port 8KREF clock sources.

These bits are ignored when the G8KIS bit = 1. See Table 10-12.

Bit 9: Global 8KHz Reference Output Select (G8KOS). This bit determines whether GPIO2 pin is used for the

global 8KREFO output signal, or is used as specified by GL.GIOCR.GPIO2S[1:0].

0 = GPIO2 pin mode selected by GL.GIOCR.GPIO2S[1:0]

1 = GPIO2 is the global 8KREFO output signal selected by GL.CR2.8KRS[2:0]

Bit 8: Global 8KHz Reference Input Select (G8KIS). This bit determines whether GPIO4 pin is used for the global

8KREFI input signal, or is used as specified by GL.GIOCR.GPIO4S[1:0]. G8KREFI signal will be low if not

selected. Global 8KREF pin signal will be low if not selected.

0 = GPIO4 pin mode selected by GL.GIOCR.GPIO4S[1:0]

1 = GPIO4 is the global 8KREFI input signal for one second timer and ports to use

Bits 3 to 0: CLAD IO Mode [3:0] (CLAD[3:0]). These bits control the CLAD clock IO pins CLKA, CLKB and CLKC.

Note: These bits control which clock is used to recover the RX Clock from the line in the LIU. See Table 10-11.

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Bit # 15 14 13 12 11 10 9 8

Name GPIO8S1 GPIO8S0 GPIO7S1 GPIO7S0 GPIO6S1 GPIO6S0 GPIO5S1 GPIO5S0

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name GPIO4S1 GPIO4S0 GPIO3S1 GPIO3S0 GPIO2S1 GPIO2S0 GPIO1S1 GPIO1S0

Default 0 0 0 0 0 0 0 0

Bits 15 to 14: General-Purpose IO 8 Select [1:0] (GPIO8S[1:0]). These bits determine the function of the GPIO8

pin. These selections are only valid if GL.CR1.GPM[1:0] is not set to 01.

00 = Input

01 = Port 4 B status output selected by PORT.CR4:GPIOB[3:0] in port control registers

10 = Output logic 0

11 = Output logic 1

Bits 13 to 12: General-Purpose IO 7 Select [1:0] (GPIO7S[1:0]). These bits determine the function of the GPIO7

pin.

00 = Input

01 = Port 4 A status output selected by PORT.CR4:GPIOA[3:0] in port control registers

10 = Output logic 0

11 = Output logic 1

Bits 11 to 10: General-Purpose IO 6 Select [1:0] (GPIO6S[1:0]). These bits determine the function of the GPIO6

pin. These selections are only valid if GL.CR1.MEIMS=0.

00 = Input

01 = Port 3 B status output selected by PORT.CR4:GPIOB[3:0] in port control registers

10 = Output logic 0

11 = Output logic 1

Bits 9 to 8: General-Purpose IO 5 Select [1:0] (GPIO5S[1:0]). These bits determine the function of the GPIO5

pin.

00 = Input

01 = Port 3 A status output selected by PORT.CR4:GPIOA[3:0] in port control registers

10 = Output logic 0

11 = Output logic 1

Bits 7 to 6: General-Purpose IO 4 Select [1:0] (GPIO4S[1:0]). These bits determine the function of the GPIO4

pin. These selections are only valid if GL.CR2 .G8KRIS=0.

00 = Input

01 = Port 2 B status output selected by PORT.CR4:GPIOB[3:0] in port control registers

10 = Output logic 0

11 = Output logic 1

Bits 5 to 4: General-Purpose IO 3 Select [1:0] (GPIO3S[1:0]). These bits determine the function of the GPIO3

pin.

00 = Input

01 = Port 2 A status output selected by PORT.CR4:GPIOA[3:0] in port control registers

10 = Output logic 0

11 = Output logic 1

Bits 3 to 2: General-Purpose IO 2 Select [1:0] (GPIO2S[1:0]). These bits determine the function of the GPIO2

pin. These selections are only valid if GL.CR2.GKROS=0.

00 = Input

01 = Port 1 B status output selected by PORT.CR4:GPIOB[3:0] in port control registers

10 = Output logic 0

11 = Output logic 1

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Bits 1 to 0: General-Purpose IO 1 Select [1:0] (GPIO1S[1:0]). These bits determine the function of the GPIO1

pin.

00 = Input

01 = Port 1 A status output selected by PORT.CR4:GPIOA[3:0] in port control registers

10 = Output logic 0

11 = Output logic 1

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Bit # 7 6 5 4 3 2 1 0

Name PISR4 PISR3 PISR2 PISR1 — — TSSR GSR

Bits 15 to 8: Not Used (—)

Bits 7 to 4: Port Interrupt Status Register [4:1] (PISR[4:1] ) The corresponding bit is set when any of the bits in

the port interrupt status registers (PORT.ISR) are set. The INT interrupt pin will be driven low when any bit is set

and the corresponding GL.ISRIE.PISRIE[4:1] interrupt enable bit is enabled.

Bit 1: Transmit System Interface Status Register Interrupt Status (TSSR) This bit is set when any of the

latched status register bits in the transmit system interface are set and enabled for interrupt. The INT pin will be

driven low when this bit is set and the GL.ISRIE.TSSRIE interrupt enable bit is enabled.

Bit 0: Global Status Register Interrupt Status (GSR) This bit is set when any of the latched status register bits in

the global latched status register (GL.SRL) are set and enabled for interrupt. The INT interrupt pin will be driven low

when this bit is set and the GL.ISRIE.GSRIE interrupt enable bit is enabled.

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Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name PISRIE4 PISRIE3 PISRIE2 PISRIE1 — — TSSRIE GSRIE

Default 0 0 0 0 0 0 0 0

Bits 15 to 8: Not Used (—)

Bits 7 to 4: Port Interrupt Status Register Interrupt Enable [4:1] (PISRIE[4:1]) When any interrupt enable bit in

this group is enabled corresponding to a status bit set in the GL.ISR.PISR[4:1] status bit group, the INT pin will be

driven low.

0 = interrupt disabled

1 = interrupt enabled

Bit 1: Transmit System Interface Status Register Interrupt Status Interrupt Enable (TSSRIE). When this bit is

enabled, and the GL.ISR.TSSR status bit is set, the INT pin will be driven low.

0 = interrupt disabled

1 = interrupt enabled

Bit 0: Global Status Register Interrupt Status Interrupt Enable (GSRIE) When this interrupt enable bit is

enabled, and the GL.ISR.GSR status bit is set, the INT pin will be driven low.

0 = interrupt disabled

1 = interrupt enabled

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Bit # 7 6 5 4 3 2 1 0

Name — — — — — — CLOL GPMS

Bit 1: CLAD Loss of Lock (CLOL) – This bit is set when any of the PLLs in the CLAD are not locked to the

reference frequency.

Bit 0: Global Performance Monitoring Update Status (GPMS) This bit is set when all of the port performance

set. It is an “AND” of all the globally enabled port PMU status bits. In global software update mode, the global

update request bit (GL.CR1.PMU) should be held high until this status bit goes high.

0 = The associated update request signal is low or not all register updates are completed

1 = The requested performance register updates are all completed

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Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Bit # 7 6 5 4 3 2 1 0

Name — — — 8KREFL CLADL ONESL CLOLL GPMSL

Bit 4: 8K Reference Activity Status Latched (8KREFL) This bit will be set when the 8 kHz reference signal on

the GPIO4 pin is active. The GL.CR2.G8KIS bit must be set for the activity to be monitored.

Bit 3: CLAD Reference Clock Activity Status Latched (CLADL) This bit will be set when the CLAD PLL

reference clock signal on the CLKA pin is active.

Bit 2: One Second Status Latched (ONESL) This bit will be set once a second. The GL.ISR.GSR status bit will

be set when this bit is set and the GL.SRIE.ONESIE bit is enabled. The INT pin will be driven low if this bit is set

and the GL.SRIE.ONESIE bit and the GL.ISRIE.GSRIE bit are enabled.

Bit 1: CLAD Loss Of Lock Latched (CLOLL) This bit will be set when the GL.SR.CLOL status bit changes from

low to high. The GL.ISR.GSR bit will be set when this bit is set and the GL.SRIE.CLOLIE bit is set and the INT pin

will be driven low if the GL.ISRIE.GSRIE bit is also enabled.

Bit 0: Global Performance Monitoring Update Status Latched (GPMSL) This bit will be set when the

GL.SR.GPMS status bit changes from low to high. This bit will set the GL.ISR.GSR status bit if the

GL.SRIE.GPMSIE is enabled. This bit will drive the interrupt pin low if the GL.SRIE.GPMSIE bit and the

GL.ISRIE.GSRIE bit are enabled.

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — — — — ONESIE CLOLIE GPMSIE

Default 0 0 0 0 0 0 0 0

Bit 2: One-Second Interrupt Enable (ONESIE) This bit will drive the interrupt pin low when this bit is enabled, the

GL.SRL.ONESL bit is set, and the GL.ISRIE.GSRIE bit is enabled.

0 = interrupt disabled

1 = interrupt enabled

Bit 1: CLAD Loss Of Lock Interrupt Enable (CLOLIE) The interrupt pin will be driven when this bit is enabled, the

GL.SRL.CLOLL is set, and GL.ISRIE.GSRIE bit is enabled.

0 = interrupt disabled

1 = interrupt enabled

Bit 0: Global Performance Monitoring Update Status Interrupt Enable (GPMSIE) The interrupt pin will be

driven when this bit is enabled and the GL.SRL.GPMSL bit is set and the GL.ISRIE.GSRIE bit is enabled.

0 = interrupt disabled

1 = interrupt enabled

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Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Bit # 7 6 5 4 3 2 1 0

Name GPIO8 GPIO7 GPIO6 GPIO5 GPIO4 GPIO3 GPIO2 GPIO1

Bits 7 to 0: General-Purpose IO Status [8:1]] (GPIO[8:1] ) These bits reflect the input or output signal on the 8

general-purpose IO pins.

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12.3 UTOPIA/POS-PHY System Interface

12.3.1 Transmit System Interface

The transmit system interface block has three registers.

12.3.1.1 Register Map

Table 12-21. Transmit System Interface Register Map

ADDRESS REGISTER REGISTER DESCRIPTION

030h SI.TCR System Interface Transmit Control Register

032h SI.TSRL System Interface Transmit Status Register Latched

034h SI.TSRIE System Interface Transmit Status Register Interrupt Enable

036h — Unused

12.3.1.2 Register Bit Descriptions

Bit # 15 14 13 12 11 10 9 8

Name — — TXAD5 TXAD4 TXAD3 TXAD2 TXAD1 TXAD0

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — — — TPARP TFLVI TSBRE THECT

Default 0 0 0 0 0 0 0 0

Bits 13 to 8: Transmit Cell/Packet Available Deassertion Time (TXAD[5:0]) –

These six bits indicate the amount of data that can be transferred after the cell/packet available signal is

deasserted. If more than the indicated amount of data is transferred, a Transmit FIFO overflow may occur.

In UTOPIA mode, only TXAD[2:0] are valid, and they indicate the number of transfers into the FIFO before the

Transmit FIFO is full. For UTOPIA Level 2, a value of 00h enables the default mode, which is 5 (TDXA will

transition low on the edge that samples payload byte 43 in 8-bit mode, payload bytes 37 and 38 in 16-bit mode,

and payload bytes 25, 26, 27, and 28 in 32-bit mode). For UTOPIA Level 3, a value of 00h or 01h enables the

default mode. The default for UTOPIA Level 3 is for TDXA to transition low on the clock edge following the edge

that samples the start of a cell.

In POS-PHY mode, TXAD[5:0] indicate the number four byte data groups that can be written into the Transmit

FIFO before it is full (maximum value 56 or 38h). In POS-PHY Level 2, a value of 00h enables the default mode,

which is 1 (For an x-byte transfer, TDXA and TSPA will transition low on the edge that samples byte x-4 in 8-bit

mode, bytes x-5 and x-4 in 16-bit mode, and bytes x-7, x-6, x-5, and x-4 in 32-bit mode). In POS-PHY Level 3 (or

SPI-3) 8-bit, a value of 00h enables the default mode, which is 1 (For a x-byte transfer, TDXA and TSPA will

transition low on the edge that samples byte x-4). For POS-PHY Level 3 (or SPI-3) 16-bit and 32-bit mode, a value

of 00h or 01h enables the default mode, which is 2 (For an x-byte transfer, TDXA and TSPA will transition low on

the edge that samples bytes x-9 and x-8 in 16-bit mode and bytes x-11, x-10, x-9, and x-8 in 32-bit mode). Note: A

packet that is 4x+1, 4x+2, 4x+3, or 4x+4 (where x is an integer) bytes long consumes x+1 four byte data groups of

space in the FIFO. This includes 2-byte and 3-byte packets, which consume a four-byte data group of space in the

FIFO.

Bit 3: Transmit System Parity Polarity (TPARP) – When 0, the TPAR signal will maintain odd parity (for all 0''s,

TPAR is high). When 1, the TPAR signal will maintain even parity (for all 0''s, TPAR is low).

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Bit 2: Transmit System Fill Level Inversion (TFLVI) – When 0, the polarity of the TPXA, TDXA, and TSPA

signals will be normal (high for data available). When 1, the polarity of the TPXA, TDXA, and TSPA signals will be

inverted (low for data available).

Bit 1: Transmit System Interface Byte Reordering Enable (TSBRE) – When 0, byte reordering is disabled, and

the first byte transmitted is transferred across the system interface as the most significant byte (TDATA[31:24] in

32-bit mode or TDATA[15:8] in 16-bit mode). When 1, byte reordering is enabled, and the first byte transmitted is

transferred across the system interface as the least significant byte (TDATA[7:0]).

Bit 0: Transmit System HEC Transfer (THECT) – When 0, The HEC byte is not transferred across the transmit

system interface. When 1, the HEC byte is transferred across the transmit system interface with the cell data.

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Bit # 7 6 5 4 3 2 1 0

Name — — — — — — TSCLKAL TPREL

Bit 1: Transmit System Interface Clock Active (TSCLKAL) – This bit is set when TSCLK is active.

Bit 0: Transmit System Interface Parity Error Latched (TPREL) – This bit is set when a parity error is detected

during a data transfer on the Transmit System Interface bus.

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — — — — — — TPREIE

Default 0 0 0 0 0 0 0 0

Bit 0: Transmit System Interface Parity Error Interrupt Enable (TPREIE) – This bit enables an interrupt if the

TPREL bit in the TSISRL register is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

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12.3.2 Receive System Interface Register Map

The receive system interface block has three registers.

Table 12-22. Receive System Interface Register Map

ADDRESS REGISTER REGISTER DESCRIPTION

038h SI.RCR1 System Interface Receive Control Register 1

03Ah SI.RCR2 System Interface Receive Control Register 2

03Ch SI.RSRL System Interface Receive Status Register Latched

03Eh — Unused

12.3.2.1 Register Bit Descriptions

Bit # 15 14 13 12 11 10 9 8

Name — — — — — RMDT2 RMDT1 RMDT0

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — RXAD2 RXAD1 RXAD0 RPARP RFLVI RSBRE RHECT

Default 0 0 0 0 0 0 0 0

Bits 10 to 8: Receive System RVAL Minimum Deassertion Time (RMDT[2:0]) – These three bits indicate the

minimum number of clock cycles that RVAL must remain deasserted between packets transferred from the same

port, a transfer of data equal to the maximum burst depth length (if enabled), or before RSX can be asserted. A

value of zero, means that RVAL will not deassert between packets transferred from the same port or between

transfers of the maximum burst length when no other port has data available. These bits are ignored in UTOPIA

and POS-PHY Level 2 modes. Note: The RVAL minimum deassertion time is for optionally extending the time

between packet transfers and port changes to allow a POS-PHY Level 3 Link Layer device enough time to

deassert REN and pause the next data transfer.

Bits 6 to 4: Receive Cell Available Deassertion Time (RXAD[2:0]) – These three bits indicate the number of

transfers that will occur after the selected Receive FIFO indicates it is "empty". A value of 000, enables the default

mode. The default for UTOPIA Level 2 is 0 (RDXA will transition low on the clock edge following the clock edge that

outputs payload byte 48 in 8-bit mode, payload bytes 47 and 48 in 16-bit mode, and payload bytes 45, 46, 47, and

48 in 32-bit mode). The default for UTOPIA Level 3 is for RDXA to transition low on the clock edge that outputs the

start of cell. These bits are ignored in POS-PHY mode.

Bit 3: Receive System Parity Polarity (RPARP) – When 0, the RPRTY signal will maintain odd parity (for all 0''s,

RPRTY is high). When 1, the RPRTY signal will maintain even parity (for all 0''s, RPRTY is low).

Bit 2: Receive System Fill Level Inversion (RFLVI) – When 0, the polarity of the RPXA and RDXA signals will be

normal (high for data available). When 1, the polarity of the RPXA and RDXA signals will be inverted (low for data

available).

Bit 1: Receive System Interface Byte Reordering Enable (RSBRE) – When 0, byte reordering is disabled, and

the first byte received is transferred across the system interface as the most significant byte (RDATA[31:24] in 32-

bit mode or RDATA[15:8] in 16-bit mode). When 1, byte reordering is enabled, and the first byte received is

transferred across the system interface as the least significant byte (RDATA[7:0]).

Bit 0: Receive System HEC Transfer Enable (RHECT) – When 0, The HEC byte is not transferred across the

receive system interface. When 1, the HEC byte is transferred across the receive system interface with the cell

data.

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Bit # 15 14 13 12 11 10 9 8

Name — — RMBL5 RMBL4 RMBL3 RMBL2 RMBL1 RMBL0

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RLBL7 RLBL6 RLBL5 RLBL4 RLBL3 RLBL2 RLBL1 RLBL0

Default 0 0 0 0 0 0 0 0

Bits 13 to 8: Receive Maximum Burst Length (RMBL[5:0]) – In POS-PHY Level 3, these six bits limit the

maximum number of four byte data groups that can be transferred from a port before switching to another port. The

maximum number of transfers is RMBL[5:0]+1 in 32-bit mode, 2 x (RMBL[5:0]+1} in 16-bit mode, and

4*(RMBL[5:0]+1} in 8-bit mode. Note: if no other port is ready to start a transfer, transfer from the current port will

continue if the port contains more data than the almost empty level or contains an end of packet. These bits are

ignored in POS-PHY Level 2 or UTOPIA mode. A value of 00h disables the maximum burst length. In 32-bit mode,

a value of 01h is treated as 02h.

Bits 7 to 0: Receive System Loopback Bandwidth Limit (RLBL[7:0]) – These eight bits limit the maximum

bandwidth of a single port during system loopback. For RLBL[7:0] equals x, the bandwidth will be limited to 1/x of

the maximum system interface bandwidth. In 8-bit and 16-bit mode, a value of 00h is treated as 01h. In 32-bit

mode, a value of 01h or 00h is treated as 02h.

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Bit # 7 6 5 4 3 2 1 0

Name — — — — — — — RSCLKAL

Bit 0: Receive System Interface Clock Active Latched (RSCLKAL) – This bit is set when RSCLK is active.

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12.4 Per-Port Common

12.4.1 Per-Port Common Register Map

Table 12-23. Per-Port Common Register Map

ADDRESS REGISTER REGISTER DESCRIPTION

(0,2,4,6)40h PORT.CR1 Port Control Register 1

(0,2,4,6)42h PORT.CR2 Port Control Register 2

(0,2,4,6)44h PORT.CR3 Port Control Register 3

(0,2,4,6)46h PORT.CR4 Port Control Register 4

(0,2,4,6)48h — Unused

(0,2,4,6)4Ah PORT.INV1 Port IO Invert Control Register 1

(0,2,4,6)4Ch PORTINV2 Port IO Invert Control Register 2

(0,2,4,6)4Eh — Unused

(0,2,4,6)50h PORT.ISR Port Interrupt Status Register

(0,2,4,6)52h PORT.SR Port Status Register

(0,2,4,6)54h PORT.SRL Port Status Register Latched

(0,2,4,6)56h PORT.SRIE Port Status Register Interrupt Enable

(0,2,4,6)58h — Unused

(0,2,4,6)5Ah — Unused

(0,2,4,6)5Ch — Unused

(0,2,4,6)5Eh — Unused

12.4.2 Per-Port Common Register Bit Descriptions

Bit # 15 14 13 12 11 10 9 8

Name NAD PAIS2 PAIS1 PAIS0 LAIS1 LAIS0 BENA HDSEL

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name TMEI MEIM — PMUM PMU PD RSTDP RST

Default 0 0 — 0 0 1 1 0

Bit 15: Nibble Align Disable (NAD). This bit is used to disable the nibble alignment of the transmit ATM cells in

direct mapped DS3 or E3 G.832 framing modes. It must be set when in DS3 M23 mode and the C-bits are used for

ATM payload.

0 = Nibble alignment enabled

1 = Nibble alignment disabled

Bits 14 to 12: Payload AIS Select [2:0] (PAIS[2:0]). This bit controls when an unframed all ones signal is forced

on the receive data path after the receive framer and payload loopback mux. Default: Payload AIS always sent.

See Table 10-19.

Bits 11 to 10: Line AIS Select [1:0] (LAIS[1:0). These bits control when a DS3 framed AIS or an unframed all

ones signal is to be transmitted on TPOSn/TNEGn and/or TXPn/TXNn. The signal on TPOSn/TNEGn can be AMI

or unipolar. This signal is sent even when in diagnostic loopback and always over-rides signals from the framers.

Default: AIS sent if DLB is enabled. See Table 10-18.

Bit 9: BERT Enable (BENA). This bit is used to enable the BERT logic. The BERT pattern will be the payload data

replacing the cell or packet data from the system interface.

0 = BERT logic disabled and powered down

1 = BERT logic enabled

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Note: Data on the receive side will flow to the Cell/Packet processor regardless of the setting of BENA. The packet

processor could detect packets even if not desired. To disable possible packets on the system interface, set the

FIFO.RCR.RFRST bit.

Bit 8: HDLC Select (HDSEL). This bit is used to select the source of the receive HDLC controller and the

destination of the transmit HDLC controller when in DS3 or E3 PLCP mode. When not in any PLCP mode, this bit

has no meaning and the HDLC controllers are connected to the DS3 or E3 framers if in DS3 or E3 mode.

0 = Connect HDLC controller to DS3 or E3 framers

1 = Connect HDLC controller to PLCP framers

Bit 7: Transmit Manual Error Insert (TMEI) This bit is used to insert errors in all error insertion logic configured to

use this bit when PORT.CR1.MEIM=0. The error(s) will be inserted when this bit is toggled low to high.

Bit 6: Transmit Manual Error Insert Mode (MEIM). These bits select the method transmit manual error insertion

for this port for error generators configured to use the external TMEI signal. The global updates are controlled by

the GL.CR1.MEIMS bit.

0 = Port software update via PORT.CR1.TMEI

1 = Global update source

Bit 4: Performance Monitor Update Mode (PMUM). These bits select the method of updating the performance

monitor registers. The global updates are controlled by the GL.CR1.GPM[1:0] bits.

0 = Port software update

1 = Global update

Bit 3: Performance Monitor Register Update (PMU) This bit is used to update all of the performance monitor

registers configured to use this bit when PORT.CR1.PMUM=0. The performance registers configured to use this

signal will be updated with the latest count value and the counters reset when this bit is toggled low to high. The bit

should remain high until the performance register update status bit (PORT.SR.PMS) goes high, then it should be

brought back low which clears the PMS status bit.

Bit 2: Power-Down (PD). When this bit is set, the LIU and digital logic for this port are powered down and

considered “out of service.” The logic is powered down by stopping the clocks. See Section 10.3.

0 = Normal operation

1 = Power-down port circuits (default state)

Bit 1: Reset Data Path (RSTDP). When this bit is set, it will force all of the internal data path registers in this port

to their default state. This bit must be set high for a minimum of 100ns and then set back low. See Section 10.3.

Note: The Default State of this bit is 1 (after a general reset (port or global), this bit will be set to one).

0 = Normal operation

1 = Force all data path registers to their default values

Bit 0: Reset (RST). When this bit is set, it will force all of the internal data path and status and control registers

(except this RST bit) of this port to their default state. See Section 10.3. This bit must be set high for a minimum of

100ns and then set back low. This software bit is logically ORed with the inverted hardware signal RST and the

GL.CR1.RST bit.

0 = Normal operation

1 = Force all internal registers to their default values

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Bit # 15 14 13 12 11 10 9 8

Name TLEN TTS RMON TLBO RCDV8 LM2 LM1 LM0

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RCDIS PMCPE FM5 FM4 FM3 FM2 FM1 FM0

Default 0 0 0 0 0 0 0 0

Bit 15: Transmit Line IO Signal Enable (TLEN). This bit is used to enable to transmit line interface output pins

TLCLKn, TPOSn/TDATn and TNEGn.

0 = Disable, force outputs low

1 = Enable normal operation

Bit 14: Transmit LIU Tri-State (TTS) This bit is used to tri-state the transmit TXPn and TXNn pins. The LIU is still

powered up when the pins are tri-stated. It has no effect when the LIU is disabled and powered down.

0 = TXPn and TXNn driven

1 = TXPn and TXNn tri-stated

Bit 13: Receive LIU Monitor Mode (RMON) This bit is used to enable the receive LIU monitor mode pre-amplifier.

Enabling the pre-amplifier adds about 20 dB of linear amplification for use in monitor applications where the signal

has been reduced 20 dB using resistive attenuator circuits.

0 = Disable the 20 dB pre-amp

1 = Enable the 20 dB pre-amp

Bit 12: Transmit LIU LBO (TLBO) This bit is used enable the transmit LBO circuit which causes the transmit

signal to have a wave shape that approximates about 225 feet of cable. This is used to reduce near end crosstalk

when the cable lengths are short. This signal is only valid in DS3 and STS-1 LIU modes.

0 = TXPn and TXNn have full amplitude signals

1 = TXPn and TXNn signals approximate 225 feet of cable

Bit 11: Receive ATM Cell Delineation Verify 8 Enable (RCDV8). This bit determines the number of good cells

required for the ATM cell delineator state machine to transition from the “Verify” state to the “Update” state. This

setting also determines how many valid cells required to clear the OCD status bit.

0 = Six valid ATM cells are required (typical for framed cells)

1 = Eight valid ATM cells are required (typical for unframed cells)

Bits 10 to 8: Port Interface Mode (LM[2:0]). The LM[2:0] bits select main port interface operational modes. The

default state disables the LIU and the JA. See Table 10-33.

Bit 7: Receive Cell Delineator Disable (RCDIS). This bit determines if the ATM cell delineator in the ATM cell

processor is active in PLCP modes. This ATM cell delineator in the ATM cell processor is always active in non-

PLCP ATM cell modes.

0 = ATM cell delineation is determined in the ATM cell processor

1 = ATM cell delineation is determined in the PLCP framer

Note: RCDIS = 1 is not a recommended mode.

Bit 6: POS-PHY Mode Cell Processor Enable (PMCPE). This bit determines the associated transmit and receive

port interface processing (cell/packet) to be performed in the POS-PHY mode. It is only active in POS-PHY mode

when PLCP is not enabled. When PLCP is enabled in POS-PHY mode, cell processing is performed.

0 = Packet processing will be performed

1 = Cell processing will be performed

Bits 5 to 0: Framing mode (FM[5:0]). The FM[5:0] bits select main framing operational modes. Default: DS3 C-bit.

See Table 10-32.

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Bit # 15 14 13 12 11 10 9 8

Name — — RCLKS RSOFOS RPFPE TCLKS TSOFOS TPFPE

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name P8KRS1 P8KRS0 P8KREF LOOPT CLADC RFTS TFTS TLTS

Default 0 0 0 0 0 0 0 0

Bit 13: Receive Clock Output Select (RCLKS). This bit is used to select the function of the RPOHCLKn /

RGCLKn / RCLKOn pins. See Table 10-31.

0 = Selects the RGCLKn signal, RPOHCLKn signal, or the drive low pin function.

1 = Selects RCLKOn signal.

Bit 12: Receive Start Of Frame Output Select (RSOFOS). This bit is to select the function of the RSOFOn /

RDENn pins. See Table 10-30.

0 = Selects RDENn signal.

1 = Selects RSOFOn signal.

Bit 11: Receive PLCP/Fractional Port Enable (RPFPE). This bit is used to enable the receive PLCP/Fractional

port pins. See tables in Section 10.5.9.2.

0 = Disable receive PLCP/Fractional port pins

1 = Enable receive PLCP/Fractional port pins

Bit 10: Transmit Clock Output Select (TCLKS). This bit is used to select the function of the TPOHCLKn /

TGCLKn / TCLKOn pins. See Table 10-24.

0 = Selects TGCLKn or TPOHCLKn signal.

1 = Selects TCLKOn signal.

Bit 9: Transmit Start Of Frame Output Select (TSOFOS). This bit is used to select the function of the TSOFOn /

TDENn pins. See Table 10-23.

0 = Selects TDENn signal.

1 = Selects TSOFOn signal.

Bit 8: Transmit PLCP/Fractional Port Enable (TPFPE). This bit is used to enable the transmit PLCP/fractional

port pins. See tables in Section 10.5.9.1.

0 = Disable transmit PLCP/Fractional port pins

1 = Enable transmit PLCP/Fractional port pins

Bits 7 and 6: Port 8 kHz Reference Source Select [1:0] (P8KRS [1:0]). These bits select the source of the 8 kHz

reference from the port sources. The 8K reference for this port can be used as the global 8K reference source. See

Table 10-13.

Bit 5: Port 8 kHz Reference Source (P8KREF). This bit selects the source of the 8 kHz reference for PLCP trailer

operation and one second timer.

0 = 8 kHz reference from global source

1 = 8 kHz reference from this ports selected source

Bit 4: Loop Time Enable (LOOPT). When this bit is set, the port is in loop time mode. The transmit clock is set to

the receive clock from the RLCLKn pin or the recovered clock from the LIU or the CLAD clock and the TCLKIn pin

is not used. This function of this bit is conditional on other control bits. See Table 10-4 for more details.

0 = Normal transmit clock operation

1 = Transmit using the receive clock

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Bit 3: CLAD Transmit Clock Source Control (CLADC). This bit is used to enable the CLAD clocks as the source

of the internal transmit clock. This function of this bit is conditional on other control bits. See Table 10-4 for more

details.

0 = Use CLAD clocks for the transmit clock as appropriate

1 = Do not use CLAD clocks for the transmit clock – (if no loopback is enabled, TCLKIn is the source)

Bit 2: Receive Framer IO Signal Timing Select (RFTS). This bit controls the timing reference for the signals on

the receive framer interface IO pins. The pins controlled are RSERn, RSOFOn / RDENn / RFOHENn and

RFOHENn. See Table 10-8 for more details.

0 = Use output clocks for timing reference

1 = Use input clocks for timing reference

Bit 1: Transmit Framer IO Signal Timing Select (TFTS). This bit controls the timing reference for the signals on

the transmit framer interface IO pins. The pins controlled are TOHMIn / TSOFIn, TFOHn / TSERn, TFOHENIn and

TSOFOn / TDENn / TFOHENOn. See Table 10-7 for more details.

0 = Use output clocks for timing reference

1 = Use input clocks for timing reference

Bit 0: Transmit Line IO Signal Timing Select (TLTS). This bit controls the timing reference for the signals on the

transmit line interface IO pins. The pins controlled are TPOSn / TDATn and TNEGn / TOHMOn. See Table 10-6 for

more details.

0 = Use output clocks for timing reference

1 = Use input clocks for timing reference

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Bit # 15 14 13 12 11 10 9 8

Name — — — — SLB LBM2 LBM1 LBM0

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name GPIOB3 GPIOB2 GPIOB1 GPIOB0 GPIOA3 GPIOA2 GPIOA1 GPIOA0

Default 0 0 0 0 0 0 0 0

Bit 11: System Bus Loopback (SLB). This bit enables the system bus loopback mode per port when the bit is set.

ATM cells and/or HDLC packets are looped back from the transmit system bus to the receive system bus through

the FIFOs. See Figure 10-10 for the block diagram highlighting loopback features.

Bits 10 to 8: Loopback Mode [2:0] (LBM[2:0]). These bits select the loopback modes for analog loopback (ALB),

line loopback (LLB), payload loopback (PLB) and diagnostic loopback (DLB). See Table 10-17 for the loopback

select codes. Default: No Loopback.

Bits 7 to 4: General-Purpose IO B Output Select[3:0] (GPIOB[3:0]) These bits determine which alarm status

signal to output on the GPIO2(port 1), GPIO4(port 2), GPIO6(port 3) or GPIO8(port 4) pins. The GPIO pin must be

enabled by setting the bits in the GL.GIOCR and either GL.CR1 or GL.CR2 registers to output the selected alarm

signal. See Table 10-15. See Table 10-16 for the alarm select codes.

Bits 3 to 0: General-Purpose IO A Output Select[3:0] (GPIOA[3:0]) These bits determine which alarm status

signal to output on the GPIO1(port 1), GPIO3(port 2), GPIO5(port 3) or GPIO7(port 4) pins. The GPIO pin must be

enabled for output by setting the bits in the GL.GIOCR register. See Table 10-15 for configuration settings. See

Table 10-16 for the alarm select codes.

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Bit # 15 14 13 12 11 10 9 8

Name TPDEI TPDTI — TPOHSI TPOHEI TPOHI TOHSI TOHEI

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name TOHI TOHCKI TSOFII TNEGI TPOSI TLCKI TCKOI TCKII

Default 0 0 0 0 0 0 0 0

Bit 15: TPDENOn Invert (TPDEI). This bit inverts the TPDENOn pin when set.

Bit 14: TPDATn Invert (TPDTI). This bit inverts the TPDATn pin when set.

Bit 12: TPOHSOFn / TSOFOn / TDENn/ TFOHENOn Invert (TPOHSI). This bit inverts the TPOHSOFn / TSOFOn

/ TDENn / TFOHENOn pin when set.

Bit 11: TPOHENn / TFOHENIn / TPDENIn Invert (TPOHEI). This bit inverts the TPOHENIn / TFOHENIn /

TPDENIn pin when set.

Bit 10: TPOHn / TFOHn / TSERn Invert (TPOHI). This bit inverts the TPOHn / TFOHn / TSERn pin when set.

Bit 9: TOHSOFn Invert (TOHSI). This bit inverts the TOHSOFn pin when set.

Bit 8: TOHENn Invert (TOHEI). This bit inverts the TOHENn pin when set.

Bit 7: TOHn Invert (TOHI). This bit inverts the TOHn pin when set.

Bit 6: TOHCLKn Invert (TOHCKI). This bit inverts the TOHCLKn pin when set.

Bit 5: TSOFIn / TOHMIn Invert (TSOFII). This bit inverts the TSOFIn / TOHMIn pin when set.

Bit 4: TNEGn / TOHMOn Invert (TNEGI). This bit inverts the TNEGn / TOHMOn pin when set.

Bit 3: TPOSn / TDATn Invert (TPOSI). This bit inverts the TPOSn / TDATn pin when set.

Bit 2: TLCLKn Invert (TLCKI). This bit inverts the TLCLKn pin when set.

Bit 1: TCLKOn / TGCLKn / TPOHCLKn Invert (TCKOI). This bit inverts the TCLKOn / TGCLKn / TPOHCLKn pin

when set.

Bit 0: TCLKIn Invert (TCKII). This bit inverts the TCLKIn pin when set.

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Bit # 15 14 13 12 11 10 9 8

Name — RPDTI RFOHEI RPOHSI — RPOHI ROHSI —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name ROHI ROHCKI — RNEGI RPOSI RLCKI RCKOI —

Default 0 0 0 0 0 0 0 0

Bit 14: RPDATn Invert (RPDTI). This bit inverts the RPDATn pin when set.

Bit 13: RFOHENIn / RPDENIn Invert (RFOHEI). This bit inverts the RFOHENIn / RPDENIn pin when set.

Bit 12: RPOHSOFn / RSOFOn / RDENn / RFOHENOn Invert (RPOHSI). This bit inverts the RPOHSOFn /

RSOFOn / RDENn / RFOHENOn pin when set.

Bit 10: RPOHn / RSERn Invert (RPOHI). This bit inverts the RPOHn / RSERn pin when set.

Bit 9: ROHSOFn Invert (ROHSI). This bit inverts the ROHSOFn pin when set.

Bit 7: ROHn Invert (ROHI). This bit inverts the ROHn pin when set.

Bit 6: ROHCLKn Invert (ROHCKI). This bit inverts the ROHCLKn pin when set.

Bit 4: RNEGn / RLCVn / ROHMIn Invert (RNEGI). This bit inverts the RNEGn / RLCVn / ROHMIn when set.

Bit 3: RPOSn / RDATn Invert (RPOSI). This bit inverts the RPOSn / RDATn pin when set.

Bit 2: RLCLKn Invert (RLCKI). This bit inverts the RLCLKn pin when set.

Bit 1: RCLKOn / RGCLKn / RPOHCLKn Invert (RCKOI). This bit inverts the RCLKOn / RGCLKn / RPOHCLKn

pin when set.

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Bit # 15 14 13 12 11 10 9 8

Name — — — — — —

PSR LCSR

Bit # 7 6 5 4 3 2 1 0

Name TTSR FSR HSR BSR SFSR CPSR PPSR FMSR

Bit 9: Port Status Register Interrupt Status (PSR) This bit is set when any of the latched status register bits, that

are enabled for interrupt, in the PORT.SRL register are set. The interrupt pin will be driven when this bit is set and

the corresponding GL.ISRIE.PISRIE[4:1] is set.

Bit 8: Line Code Status Register Interrupt Status (LCSR) This bit is set when any of the latched status register

bits, that are enabled for interrupt, in the B3ZS/HDB3 Line Encoder/Decoder block are set. The interrupt pin will be

driven when this bit is set and the corresponding GL.ISRIE.PISRIE[4:1] is set.

Bit 7: Trail Trace Status Register Interrupt Status (TTSR) This bit is set when any of the latched status register

bits, that are enabled for interrupt, in the trail trace block are set. The interrupt pin will be driven when this bit is set

and the corresponding GL.ISRIE.PISRIE[4:1] is set.

Bit 6: FEAC Status Register Interrupt Status (FSR) This bit is set when any of the latched status register bits,

that are enabled for interrupt, in the FEAC block are set. The interrupt pin will be driven when this bit is set and the

corresponding GL.ISRIE.PISRIE[4:1] is set.

Bit 5: HDLC Status Register Interrupt Status (HSR) This bit is set when any of the latched status register bits,

that are enabled for interrupt, in the HDLC block are set. The interrupt pin will be driven when this bit is set and the

corresponding GL.ISRIE.PISRIE[4:1] is set.

Bit 4: BERT Status Register Interrupt Status (BSR) This bit is set when any of the latched status register bits,

that are enabled for interrupt, in the BERT block are set. The interrupt pin will be driven when this bit is set and the

corresponding GL.ISRIE.PISRIE[4:1] is set.

Bit 3: System FIFO Status Register Interrupt Status (SFSR) This bit is set when any of the latched status

register bits, that are enabled for interrupt, in either the transmit or receive FIFO block are set. The interrupt pin will

be driven when this bit is set and the corresponding GL.ISRIE.PISRIE[4:1] is set.

Bit 2: Cell/Packet Status Register Interrupt Status (CPSR) This bit is set when any of the latched status register

bits, that are enabled for interrupt, in the active transmit or receive cell processor or packet processor block are set.

The interrupt pin will be driven when this bit is set and the corresponding GL.ISRIE.PISRIE[4:1] is set.

Bit 1: PLCP Status Register Interrupt Status (PPSR) This bit is set when any of the latched status register bits,

that are enabled for interrupt, in the active PLCP block are set. The interrupt pin will be driven when this bit is set

and the corresponding GL.ISRIE.PISRIE[4:1] is set.

Bit 0: Framer Status Register Interrupt Status (FMSR) This bit is set when any of the latched status register bits,

that are enabled for interrupt, in the active DS3 or E3 framer block are set. The interrupt pin will be driven when this

bit is set and the corresponding GL.ISRIE.PISRIE[4:1] is set.

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Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Bit # 7 6 5 4 3 2 1 0

Name — — — — — TDM RLOL PMS

Bit 2: Transmit Driver Monitor Status (TDM) This bits indicates the status of the transmit monitor circuit in the

transmit LIU.

0 = Transmit output not over loaded

1 = Transmit signal is overloaded

Bit 1: Receive Loss Of Lock Status (RLOL) This bits indicates the status of the receive LIU clock recovery PLL

circuit.

0 = Locked to the incoming signal

1 = Not locked to the incoming signal

Bit 0: Performance Monitoring Update Status (PMS) This bits indicates the status of all active performance

monitoring register and counter update signals in this port. It is an “AND” of all update status bits and is not set until

all performance registers are updated and the counters reset. In software update modes, the update request bit

PORT.CR1.PMU should be held high until this status bit goes high.

0 = The associated update request signal is low

1 = The requested performance register updates are all completed

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Bit # 7 6 5 4 3 2 1 0

Name RLCLKA TCLKIA — — — TDML RLOLL PMSL

Bit 7: Receive Line Clock Activity Status Latched (RLCLKA) This bit will be set when the signal on the RLCLKn

pin or the recovered clock from the LIU for this port is active.

Bit 6: Transmit Input Clock Activity Status Latched (TCLKIA) This bit will be set when the signal on the TCLKIn

pin for this port is active.

Bit 2: Transmit Driver Monitor Status Latched (TDML) This bit will be set when the PORT.SR.TDM status bit

changes from low to high. This bit will also set the PORT.ISR.PSR status bit if the PORT.SRIE.TDMIE bit is

enabled. The interrupt pin will be driven when this bit is set, the PORT.SRIE.TDMIE bit is set, and the

corresponding GL.ISRIE.PISRIE[4:1] bit is also set.

Bit 1: Receive Loss Of Lock Status Latched (RLOLL) This bit will be set when the PORT.SR.RLOL status bit

changes from low to high. This bit will also set the PORT.ISR.PSR status bit if the PORT.SRIE.RLOLIE bit is

enabled. The interrupt pin will be driven when this bit is set, the PORT.SRIE.RLOLIE bit is set, and the

corresponding GL.ISRIE.PISRIE[4:1] bit is also set.

Bit 0: Performance Monitoring Update Status Latched (PMSL) This bit will be set when the PORT.SR.PMS

status bit changes from low to high. This bit will also set the PORT.ISR.PSR status bit if the PORT.SRIE.PMUIE bit

is enabled. The interrupt pin will be driven when this bit is set, the PORT.SRIE.PMUIE bit is set, and the

PORT.SRIE.PMSIE bit are set.

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Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — — — — TDMIE RLOLIE PMSIE

Default 0 0 0 0 0 0 0 0

Bit 2: Transmit Driver Monitor Latched Status Interrupt Enable (TDMIE) The interrupt pin will be driven when

this bit is enabled and the PORT.SRL.TDML bit is set and the bit in GL.ISRIE.PISRIE[4:1] that corresponds to this

port is enabled.

Bit 1: Receive Loss Of Lock Latched Status Interrupt Enable (RLOLIE) The interrupt pin will be driven when

this bit is enabled and the PORT.SRL.RLOLL bit is set and the bit in GL.ISRIE.PISRIE[4:1] that corresponds to this

port is enabled.

Bit 0: Performance Monitoring Update Latched Status Interrupt Enable (PMSIE) The interrupt pin will be

driven when this bit is enabled and the PORT.SRL.PMSL bit is set and the bit in GL.ISRIE.PISRIE[4:1] that

corresponds to this port is enabled.

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12.5 BERT

12.5.1 BERT Register Map

The BERT uses 12 registers. Note that the BERT registers are cleared when GL.CR1.RSTDP or

PORT.CR1.RSTDP or PORT.CR1.PD is set.

Table 12-24. BERT Register Map

ADDRESS REGISTER REGISTER DESCRIPTION

(0,2,4,6)60h BERT.CR BERT Control Register

(0,2,4,6)62h BERT.PCR BERT Pattern Configuration Register

(0,2,4,6)64h BERT.SPR1 BERT Seed/Pattern Register 1

(0,2,4,6)66h BERT.SPR2 BERT Seed/Pattern Register 2

(0,2,4,6)68h BERT.TEICR BERT Transmit Error Insertion Control Register

(0,2,4,6)6Ah — Unused

(0,2,4,6)6Ch BERT.SR BERT Status Register

(0,2,4,6)6Eh BERT.SRL BERT Status Register Latched

(0,2,4,6)70h BERT.SRIE BERT Status Register Interrupt Enable

(0,2,4,6)72h — Unused

(0,2,4,6)74h BERT.RBECR1 BERT Receive Bit Error Count Register 1

(0,2,4,6)76h BERT.RBECR2 BERT Receive Bit Error Count Register 2

(0,2,4,6)78h BERT.RBCR1 BERT Receive Bit Count Register 1

(0,2,4,6)7Ah BERT.RBCR2 BERT Receive Bit Count Register 2

(0,2,4,6)7Ch — Unused

(0,2,4,6)7Eh — Unused

12.5.2 BERT Register Bit Descriptions

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name PMUM LPMU RNPL RPIC MPR APRD TNPL TPIC

Default 0 0 0 0 0 0 0 0

Bit 7: Performance Monitoring Update Mode (PMUM) – When 0, a performance monitoring update is initiated by

the LPMU register bit. When 1, a performance monitoring update is initiated by the global or port PMU register bit.

Note: If the LPMU bit or the global or port PMU bit is one, changing the state of this bit may cause a performance

monitoring update to occur.

Bit 6: Local Performance Monitoring Update (LPMU) – This bit causes a performance monitoring update to be

initiated if local performance monitoring update is enabled (PMUM = 0). A 0 to 1 transition causes the performance

monitoring registers to be updated with the latest data, and the counters reset (0 or 1). For a second performance

monitoring update to be initiated, this bit must be set to 0, and back to 1. If LPMU goes low before the PMS bit

goes high; an update might not be performed. This bit has no affect when PMUM=1.

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Bit 5: Receive New Pattern Load (RNPL) – A zero to one transition of this bit will cause the programmed test

pattern (QRSS, PTS, PLF[4:0}, PTF[4:0], and BSP[31:0]) to be loaded in to the receive pattern generator. This bit

must be changed to zero and back to one for another pattern to be loaded. Loading a new pattern will forces the

receive pattern generator out of the “Sync” state which causes a re-synchronization to be initiated.

Note: QRSS, PTS, PLF[4:0}, PTF[4:0], and BSP[31:0] must not change from the time this bit transitions from 0 to 1

until four receive clock cycles after this bit transitions from 0 to 1. Register bit PORT.CR1.BENA must be set and

the receive clock running in order for the pattern load to take affect.

Bit 4: Receive Pattern Inversion Control (RPIC) – When 0, the receive incoming data stream is not altered.

When 1, the receive incoming data stream is inverted.

Bit 3: Manual Pattern Re-synchronization (MPR) – A zero to one transition of this bit will cause the receive

pattern generator to re-synchronize to the incoming pattern. This bit must be changed to zero and back to one for

another re-synchronization to be initiated. Note: A manual re-synchronization forces the receive pattern generator

out of the “Sync” state.

Bit 2: Automatic Pattern Resynchronization Disable (APRD) – When 0, the receive pattern generator will

automatically re-synchronize to the incoming pattern if six or more times during the current 64-bit window the

incoming data stream bit and the receive pattern generator output bit did not match. When 1, the receive pattern

generator will not automatically re-synchronize to the incoming pattern.

Bit 1: Transmit New Pattern Load (TNPL) – A zero to one transition of this bit will cause the programmed test

pattern (QRSS, PTS, PLF[4:0}, PTF[4:0], and BSP[31:0]) to be loaded in to the transmit pattern generator. This bit

must be changed to zero and back to one for another pattern to be loaded.

Note: QRSS, PTS, PLF[4:0}, PTF[4:0], and BSP[31:0] must not change from the time this bit transitions from 0 to 1

until four transmit clock cycles after this bit transitions from 0 to 1. Register bit PORT.CR1.BENA must be set and

the transmit clock running in order for the pattern load to take affect.

Bit 0: Transmit Pattern Inversion Control (TPIC) – When 0, the transmit outgoing data stream is not altered.

When 1, the transmit outgoing data stream is inverted.

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Bit # 15 14 13 12 11 10 9 8

Name — — — PTF4 PTF3 PTF2 PTF1 PTF0

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — QRSS PTS PLF4 PLF3 PLF2 PLF1 PLF0

Default 0 0 0 0 0 0 0 0

Bits 12 to 8: Pattern Tap Feedback (PTF[4:0]) – These five bits control the PRBS “tap” feedback of the pattern

generator. The “tap” feedback will be from bit y of the pattern generator (y = PTF[4:0] +1). These bits are ignored

when programmed for a repetitive pattern. For a PRBS signal, the feedback is an XOR of bit n and bit y.

Bit 6: QRSS Enable (QRSS) – When 0, the pattern generator configuration is controlled by PTS, PLF[4:0], and

PTF[4:0], and BSP[31:0]. When 1, the pattern generator configuration is forced to a PRBS pattern with a

generating polynomial of x20 + x17 + 1. The output of the pattern generator will be forced to one if the next 14 output

bits are all zero.

Bit 5: Pattern Type Select (PTS) – When 0, the pattern is a PRBS pattern. When 1, the pattern is a repetitive

pattern.

Bits 4 to 0: Pattern Length Feedback (PLF[4:0]) – These five bits control the “length” feedback of the pattern

generator. The “length” feedback will be from bit n of the pattern generator (n = PLF[4:0] +1). For a PRBS signal,

the feedback is an XOR of bit n and bit y. For a repetitive pattern the feedback is bit n.

Bit # 15 14 13 12 11 10 9 8

Name BSP15 BSP14 BSP13 BSP12 BSP11 BSP10 BSP9 BSP8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name BSP7 BSP6 BSP5 BSP4 BSP3 BSP2 BSP1 BSP0

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: BERT Seed/Pattern (BSP[15:0]) – Lower 16 bits of 32 bits. Register description follows next register.

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Bit # 15 14 13 12 11 10 9 8

Name BSP31 BSP30 BSP29 BSP28 BSP27 BSP26 BSP25 BSP24

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name BSP23 BSP22 BSP21 BSP20 BSP19 BSP18 BSP17 BSP16

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: BERT Seed/Pattern (BSP[31:16]) - Upper 16 bits of 32 bits.

BERT Seed/Pattern (BSP[31:0]) – These 32 bits are the programmable seed for a transmit PRBS pattern, or the

programmable pattern for a transmit or receive repetitive pattern. BSP(31) will be the first bit output on the transmit

side for a 32-bit repetitive pattern or 32-bit length PRBS. BSP(31) will be the first bit input on the receive side for a

32-bit repetitive pattern.

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Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — TEIR2 TEIR1 TEIR0 BEI TSEI MEIMS

Default 0 0 0 0 0 0 0 0

Bits 5 to 3: Transmit Error Insertion Rate (TEIR[2:0]) – These three bits indicate the rate at which errors are

inserted in the output data stream. One out of every 10n bits is inverted. TEIR[2:0] is the value n. A TEIR[2:0] value

of 0 disables error insertion at a specific rate. A TEIR[2:0] value of 1 result in every 10th bit being inverted. A

TEIR[2:0] value of 2 result in every 100th bit being inverted. Error insertion starts when this register is written to with

a TEIR[2:0] value that is non-zero. If this register is written to during the middle of an error insertion process, the

new error rate will be started after the next error is inserted.

TEIR[2:0] Error Rate

000 Disabled

001 1*10-1

010 1*10-2

011 1*10-3

100 1*10-4

101 1*10-5

110 1*10-6

111 1*10-7

Bit 2: Bit Error Insertion Enable (BEI) – When 0, single bit error insertion is disabled. When 1, single bit error

insertion is enabled.

Bit 1: Transmit Single Error Insert (TSEI) – This bit causes a bit error to be inserted in the transmit data stream if

manual error insertion is disabled (MEIMS = 0) and single bit error insertion is enabled. A 0 to 1 transition causes a

single bit error to be inserted. For a second bit error to be inserted, this bit must be set to 0, and back to 1. Note: If

MEIMS is low, and this bit transitions more than once between error insertion opportunities, only one error will be

inserted.

Bit 0: Manual Error Insert Mode Select (MEIMS) – When 0, error insertion is initiated by the TSEI register bit.

When 1, error insertion is initiated by the transmit manual error insertion signal (TMEI). Note: If TMEI or TSEI is

one, changing the state of this bit may cause a bit error to be inserted.

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Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Bit # 7 6 5 4 3 2 1 0

Name — — — — PMS — BEC OOS

Bit 3: Performance Monitoring Update Status (PMS) – This bit indicates the status of the receive performance

monitoring register (counters) update. This bit will transition from low to high when the update is completed. PMS

will be forced low when the LPMU bit (PMUM = 0) or the global or port PMU bit (PMUM=1) goes low.

Bit 1: Bit Error Count (BEC) – When 0, the bit error count is zero. When 1, the bit error count is one or more. This

bit is cleared when the user updates the BERT counters via the PMU bit (BERT.CR).

Bit 0: Out Of Synchronization (OOS) – When 0, the receive pattern generator is synchronized to the incoming

pattern. When 1, the receive pattern generator is not synchronized to the incoming pattern.

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Bit # 7 6 5 4 3 2 1 0

Name — — — — PMSL BEL BECL OOSL

Bit 3: Performance Monitoring Update Status Latched (PMSL) – This bit is set when the PMS bit transitions

from 0 to 1.

Bit 2: Bit Error Latched (BEL) – This bit is set when a bit error is detected.

Bit 1: Bit Error Count Latched (BECL) – This bit is set when the BEC bit transitions from 0 to 1.

Bit 0: Out Of Synchronization Latched (OOSL) – This bit is set when the OOS bit changes state.

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Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — — — PMSIE BEIE BECIE OOSIE

Default 0 0 0 0 0 0 0 0

Bit 3: Performance Monitoring Update Status Interrupt Enable (PMSIE) – This bit enables an interrupt if the

PMSL bit is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 2: Bit Error Interrupt Enable (BEIE) – This bit enables an interrupt if the BEL bit is set and the bit in

GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 1: Bit Error Count Interrupt Enable (BECIE) – This bit enables an interrupt if the BECL bit is set and the bit in

GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 0: Out Of Synchronization Interrupt Enable (OOSIE) – This bit enables an interrupt if the OOSL bit is set and

the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

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Bit # 15 14 13 12 11 10 9 8

Name BEC15 BEC14 BEC13 BEC12 BEC11 BEC10 BEC9 BEC8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name BEC7 BEC6 BEC5 BEC4 BEC3 BEC2 BEC1 BEC0

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Bit Error Count (BEC[15:0]) – Lower 16 bits of 24 bits. Register description follows next register.

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name BEC23 BEC22 BEC21 BEC20 BEC19 BEC18 BEC17 BEC16

Default 0 0 0 0 0 0 0 0

Bits 7 to 0: Bit Error Count (BEC[23:16]) - Upper 8-bits of Register.

Bit Error Count (BEC[23:0]) – These 24 bits indicate the number of bit errors detected in the incoming data

stream. This count stops incrementing when it reaches a count of FF FFFFh. This bit error counter will not

increment when an OOS condition exists. This register is updated via the PMU signal (see Section 10.4.5).

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Bit # 15 14 13 12 11 10 9 8

Name BC15 BC14 BC13 BC12 BC11 BC10 BC9 BC8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name BC7 BC6 BC5 BC4 BC3 BC2 BC1 BC0

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Bit Count (BC[15:0]) – Lower 16 bits of 32 bits. Register description follows next register.

Bit # 15 14 13 12 11 10 9 8

Name BC31 BC30 BC29 BC28 BC27 BC26 BC25 BC24

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name BC23 BC22 BC21 BC20 BC19 BC18 BC17 BC16

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Bit Count (BC[31:16]) - Upper 16 bits of 32 bits.

Bit Count (BC[31:0]) – These 32 bits indicate the number of bits in the incoming data stream. This count stops

incrementing when it reaches a count of FFFF FFFFh. This bit counter will not increment when an OOS condition

exists. This register is updated via the PMU signal (see Section 10.4.5).

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12.6 B3ZS/HDB3 Line Encoder/Decoder

12.6.1 Transmit Side Line Encoder/Decoder Register Map

The transmit side uses one register.

Table 12-25. Transmit Side B3ZS/HDB3 Line Encoder/Decoder Register Map

ADDRESS REGISTER REGISTER DESCRIPTION

(0,2,4,6)8Ch LINE.TCR Line Transmit Control Register

(0,2,4,6)8Eh — Unused

12.6.1.1 Register Bit Descriptions

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — — TZSD EXZI BPVI TSEI MEIMS

Default 0 0 0 0 0 0 0 0

Bit 4: Transmit Zero Suppression Encoding Disable (TZSD) – When 0, the B3ZS/HDB3 Encoder performs zero

suppression (B3ZS or HDB3) and AMI encoding. When 1, zero suppression (B3ZS or HDB3) encoding is disabled,

and only AMI encoding is performed.

Bit 3: Excessive Zero Insert Enable (EXZI) – When 0, excessive zero (EXZ) event insertion is disabled. When 1,

EXZ event insertion is enabled.

Bit 2: Bipolar Violation Insert Enable (BPVI) – When 0, bipolar violation (BPV) insertion is disabled. When 1,

BPV insertion is enabled.

Bit 1: Transmit Single Error Insert (TSEI) – This bit causes an error of the enabled type(s) to be inserted in the

transmit data stream if manual error insertion is disabled (MEIMS = 0). A 0 to 1 transition causes a single error to

be inserted. For a second error to be inserted, this bit must be set to 0, and back to 1. Note: If MEIMS is low, and

this bit transitions more than once between error insertion opportunities, only one error will be inserted.

Bit 0: Manual Error Insert Mode Select (MEIMS) – When 0, error insertion is initiated by the TSEI register bit.

When 1, error insertion is initiated by the transmit manual error insertion signal (TMEI). Note: If TMEI or TSEI is

one, changing the state of this bit may cause an error to be inserted.

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12.6.2 Receive Side Line Encoder/Decoder Register Map

The receive side uses six registers.

Table 12-26. Receive Side B3ZS/HDB3 Line Encoder/Decoder Register Map

ADDRESS REGISTER REGISTER DESCRIPTION

(0,2,4,6)90h LINE.RCR Line Receive Control Register

(0,2,4,6)92h — Unused

(0,2,4,6)94h LINE.RSR Line Receive Status Register

(0,2,4,6)96h LINE.RSRL Line Receive Status Register Latched

(0,2,4,6)98h LINE.RSRIE Line Receive Status Register Interrupt Enable

(0,2,4,6)9Ah — Unused

(0,2,4,6)9Ch LINE.RBPVCR Line Receive Bipolar Violation Count Register

(0,2,4,6)9Eh LINE.REXZCR Line Receive Excessive Zero Count Register

12.6.2.1 Register Bit Descriptions

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — — — E3CVE REZSF RDZSF RZSD

Default 0 0 0 0 0 0 0 0

Bit 3: E3 Code Violation Enable (E3CVE) – When 0, the bipolar violation count will be a count of bipolar

violations. When 1, the bipolar violation count will be a count of E3 line coding violations. Note: E3 line coding

violations are defined as consecutive bipolar violations of the same polarity in ITU O.161. This bit is ignored in

B3ZS mode.

Bit 2: Receive BPV Error Detection Zero Suppression Code Format (REZSF) – When 0, BPV error detection

detects a B3ZS signature if a zero is followed by a bipolar violation (BPV), and an HDB3 signature if two zeros are

followed by a BPV. When 1, BPV error detection detects a B3ZS signature if a zero is followed by a BPV that has

the opposite polarity of the BPV in the previous B3ZS signature, and an HDB3 signature if two zeros are followed

by a BPV that has the opposite polarity of the BPV in the previous HDB3 signature. Note: Immediately after a reset,

this bit is ignored. The first B3ZS signature is defined as a zero followed by a BPV, and the first HDB3 signature is

defined as two zeros followed by a BPV. All subsequent B3ZS/HDB3 signatures will be determined by the setting of

this bit.

Note: The default setting (REZSF = 0) conforms to ITU O.162. The default setting may falsely decode actual BPVs

that are not codewords. It is recommended that REZSF be set to one for most applications. This setting is more

robust to accurately detect codewords.

Bit 1: Receive Zero Suppression Decoding Zero Suppression Code Format (RDZSF) – When 0, zero

suppression decoding detects a B3ZS signature if a zero is followed by a bipolar violation (BPV), and an HDB3

signature if two zeros are followed by a BPV. When 1, zero suppression decoding detects a B3ZS signature if a

zero is followed by a BPV that has the opposite polarity of the BPV in the previous B3ZS signature, and an HDB3

signature if two zeros are followed by a BPV that has the opposite polarity of the BPV in the previous HDB3

signature. Note: Immediately after a reset (DRST or RST low), this bit is ignored. The first B3ZS signature is defined

as a zero followed by a BPV, and the first HDB3 signature is defined as two zeros followed by a BPV. All

subsequent B3ZS/HDB3 signatures will be determined by the setting of this bit.

Bit 0: Receive Zero Suppression Decoding Disable (RZSD) – When 0, the B3ZS/HDB3 Decoder performs zero

suppression (B3ZS or HDB3) and AMI decoding. When 1, zero suppression (B3ZS or HDB3) decoding is disabled,

and only AMI decoding is performed.

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Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Bit # 7 6 5 4 3 2 1 0

Name — — — — EXZC — BPVC LOS

Bit 3: Excessive Zero Count (EXZC) – When 0, the excessive zero count is zero. When 1, the excessive zero

count is one or more.

Bit 1: Bipolar Violation Count (BPVC) – When 0, the bipolar violation count is zero. When 1, the bipolar violation

count is one or more.

Bit 0: Loss Of Signal (LOS) – When 0, the receive line is not in a loss of signal (LOS) condition. When 1, the

receive line is in an LOS condition. See Section 10.14.5.

Note: When zero suppression (B3ZS or HDB3) decoding is disabled, the LOS condition is cleared, and cannot be

detected.

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Bit # 7 6 5 4 3 2 1 0

Name — — ZSCDL EXZL EXZCL BPVL BPVCL LOSL

Bit 5: Zero Suppression Code Detect Latched (ZSCDL) – This bit is set when a B3ZS or HDB3 signature is

detected.

Bit 4: Excessive Zero Latched (EXZL) – This bit is set when an excessive zero event is detected on the incoming

bipolar data stream.

Bit 3: Excessive Zero Count Latched (EXZCL) – This bit is set when the LINE.RSR.EXZC bit transitions from

zero to one.

Bit 2: Bipolar Violation Latched (BPVL) – This bit is set when a bipolar violation (or E3 LCV if enabled) is

detected on the incoming bipolar data stream.

Bit 1: Bipolar Violation Count Latched (BPVCL) – This bit is set when the LINE.RSR.BPVC bit transitions from

zero to one.

Bit 0: Loss of Signal Change Latched (LOSL) – This bit is set when the LINE.RSR.LOS bit changes state.

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Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — ZSCDIE EXZIE EXZCIE BPVIE BPVCIE LOSIE

Default 0 0 0 0 0 0 0 0

Bit 5: Zero Suppression Code Detect Interrupt Enable (ZSCDIE) – This bit enables an interrupt if the

LINE.RSRL.ZSCDL bit is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 4: Excessive Zero Interrupt Enable (EXZIE) – This bit enables an interrupt if the LINE.RSRL.EXZL bit is set

and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 3: Excessive Zero Count Interrupt Enable (EXZCIE) – This bit enables an interrupt if the LINE.RSRL.EXZCL

bit is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 2: Bipolar Violation Interrupt Enable (BPVIE) – This bit enables an interrupt if the LINE.RSRL.BPVL bit is set

and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 1: Bipolar Violation Count Interrupt Enable (BPVCIE) – This bit enables an interrupt if the

LINE.RSRL.BPVCL bit and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set. is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 0: Loss Of Signal Interrupt Enable (LOSIE) – This bit enables an interrupt if the LINE.RSRL.LOSL bit is set

and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

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Bit # 15 14 13 12 11 10 9 8

Name BPV15 BPV14 BPV13 BPV12 BPV11 BPV10 BPV9 BPV8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name BPV7 BPV6 BPV5 BPV4 BPV3 BPV2 BPV1 BPV0

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Bipolar Violation Count (BPV[15:0]) – These 16 bits indicate the number of bipolar violations

detected on the incoming bipolar data stream. This register is updated via the PMU signal (see Section 10.4.5)

Bit # 15 14 13 12 11 10 9 8

Name EXZ15 EXZ14 EXZ13 EXZ12 EXZ11 EXZ10 EXZ9 EXZ8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name EXZ7 EXZ6 EXZ5 EXZ4 EXZ3 EXZ2 EXZ1 EXZ0

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Excessive Zero Count (EXZ[15:0]) – These 16 bits indicate the number of excessive zero conditions

detected on the incoming bipolar data stream. This register is updated via the PMU signal (see Section 10.4.5)

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12.7 HDLC

12.7.1 HDLC Transmit Side Register Map

The transmit side uses five registers.

Table 12-27. Transmit Side HDLC Register Map

ADDRESS REGISTER REGISTER DESCRIPTION

(0,2,4,6)A0h HDLC.TCR HDLC Transmit Control Register

(0,2,4,6)A2h HDLC.TFDR HDLC Transmit FIFO Data Register

(0,2,4,6)A4h HDLC.TSR HDLC Transmit Status Register

(0,2,4,6)A6h HDLC.TSRL HDLC Transmit Status Register Latched

(0,2,4,6)A8h HDLC.TSRIE HDLC Transmit Status Register Interrupt Enable

(0,2,4,6)AAh — Unused

(0,2,4,6)ACh — Unused

(0,2,4,6)AEh — Unused

12.7.1.1 Register Bit Descriptions

Bit # 15 14 13 12 11 10 9 8

Name — — — TDAL4 TDAL3 TDAL2 TDAL1 TDAL0

Default 0 0 0 0 1 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — TPSD TFEI TIFV TBRE TDIE TFPD TFRST

Default 0 0 0 0 0 0 0 0

Bits 12 to 8: Transmit HDLC Data Storage Available Level (TDAL[4:0]) – These five bits indicate the minimum

number of bytes ([TDAL*8]+1) that must be available for storage (do not contain data) in the Transmit FIFO for

HDLC data storage to be available. For example, a value of 21 (15h) results in HDLC data storage being available

(THDA = 1) when the Transmit FIFO has 169 (A9h) bytes or more available for storage, and HDLC data storage

not being available (THDA = 0) when the Transmit FIFO has 168 (A8h) bytes or less available for storage. Default

value (after reset) is 128 bytes minimum available.

Bit 6: Transmit Packet Start Disable (TPSD) – When 0, the Transmit Packet Processor will continue sending

packets after the current packet end. When 1, the Transmit Packet Processor will stop sending packets after the

current packet end.

Bit 5: Transmit FCS Error Insertion (TFEI) – When 0, the calculated FCS (inverted CRC-16) is appended to the

packet. When 1, the inverse of the calculated FCS (non-inverted CRC-16) is appended to the packet causing a

FCS error. This bit is ignored if transmit FCS processing is disabled (TFPD = 1).

Bit 4: Transmit Inter-frame Fill Value (TIFV) – When 0, inter-frame fill is done with the flag sequence (7Eh).

When 1, inter-frame fill is done with all ‘1’s.

Bit 3: Transmit Bit Reordering Enable (TBRE) – When 0, bit reordering is disabled (The first bit transmitted is the

LSB of the Transmit FIFO Data byte TFD[0]). When 1, bit reordering is enabled (The first bit transmitted is the MSB

of the Transmit FIFO Data byte TFD[7]).

Bit 2: Transmit Data Inversion Enable (TDIE) – When 0, the outgoing data is directly output from packet

processing. When 1, the outgoing data is inverted before being output from packet processing.

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Bit 1: Transmit FCS Processing Disable (TFPD) – This bit controls whether or not a FCS is calculated and

appended to the end of each packet. When 0, the calculated FCS bytes are appended to the end of the packet.

When 1, the packet is transmitted without a FCS.

Bit 0: Transmit FIFO Reset (TFRST) – When 0, the Transmit FIFO will resume normal operations, however, data

is discarded until a start of packet is received after RAM power-up is completed. When 1, the Transmit FIFO is

emptied, any transfer in progress is halted, the FIFO RAM is powered down, and all incoming data is discarded (all

TFDR register writes are ignored).

Bit # 15 14 13 12 11 10 9 8

Name TFD7 TFD6 TFD5 TFD4 TFD3 TFD2 TFD1 TFD0

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — — — — — — TDPE

Default 0 0 0 0 0 0 0 0

Note: The FIFO data and status are loaded into the Transmit FIFO when the Transmit FIFO Data (TFD[7:0]) is written (upper byte write). When

read, the value of these bits is always zero.

Bits 15 to 8: Transmit FIFO Data (TFD[7:0]) – These eight bits are the packet data to be stored in the Transmit

FIFO. TFD[7] is the MSB, and TFD[0] is the LSB. If bit reordering is disabled, TFD[0] is the first bit transmitted, and

TFD[7] is the last bit transmitted. If bit reordering is enabled, TFD[7] is the first bit transmitted, and TFD[0] is the

last bit transmitted.

Bit 0: Transmit FIFO Data Packet End (TDPE) – When 0, the Transmit FIFO data is not a packet end. When 1,

the Transmit FIFO data is a packet end.

Bit # 15 14 13 12 11 10 9 8

Name — — TFFL5 TFFL4 TFFL3 TFFL2 TFFL1 TFFL0

Bit # 7 6 5 4 3 2 1 0

Name — — — — — TFF TFE THDA

Bits 13 to 8: Transmit FIFO Fill Level (TFFL[5:0]) – These six bits indicate the number of eight byte groups

available for storage (do not contain data) in the Transmit FIFO. E.g., a value of 21 (15h) indicates the FIFO has

168 (A8h) to 175 (AFh) bytes are available for storage.

Bit 2: Transmit FIFO Full (TFF) – When 0, the Transmit FIFO contains 255 or less bytes of data. When 1, the

Transmit FIFO is full.

Bit 1: Transmit FIFO Empty (TFE) – When 0, the Transmit FIFO contains at least one byte of data. When 1, the

Transmit FIFO is empty.

Bit 0: Transmit HDLC Data Storage Available (THDA) – When 0, the Transmit FIFO has less storage space

available in the Transmit FIFO than the Transmit HDLC data storage available level (TDAL[4:0]). When 1, the

Transmit FIFO has the same or more storage space available than the Transmit FIFO HDLC data storage available

level.

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Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Bit # 7 6 5 4 3 2 1 0

Name — — TFOL TFUL TPEL — TFEL THDAL

Bit 5: Transmit FIFO Overflow Latched (TFOL) – This bit is set when a Transmit FIFO overflow condition occurs.

Bit 4: Transmit FIFO Underflow Latched (TFUL) – This bit is set when a Transmit FIFO underflow condition

occurs. An underflow condition results in a loss of data.

Bit 3: Transmit Packet End Latched (TPEL) – This bit is set when an end of packet is read from the Transmit

FIFO.

Bit 1: Transmit FIFO Empty Latched (TFEL) – This bit is set when the TFE bit transitions from 0 to 1.

Note: This bit is also set when HDLC.TCR.TFRST is deasserted.

Bit 0: Transmit HDLC Data Available Latched (THDAL) – This bit is set when the THDA bit transitions from 0 to

1. Note: This bit is also set when HDLC.TCR.TFRST is deasserted.

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Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — TFOIE TFUIE TPEIE — TFEIE THDAIE

Default 0 0 0 0 0 0 0 0

Bit 5: Transmit FIFO Overflow Interrupt Enable (TFOIE) – This bit enables an interrupt if the TFOL bit is set and

the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 4: Transmit FIFO Underflow Interrupt Enable (TFUIE) – This bit enables an interrupt if the TFUL bit is set

and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 3: Transmit Packet End Interrupt Enable (TPEIE) – This bit enables an interrupt if the TPEL bit is set and the

bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 2: Transmit FIFO Full Interrupt Enable (TFFIE) – This bit enables an interrupt if the TFFL bit is set and the bit

in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 1: Transmit FIFO Empty Interrupt Enable (TFEIE) – This bit enables an interrupt if the TFEL bit is set and the

bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 0: Transmit HDLC Data Available Interrupt Enable (THDAIE) – This bit enables an interrupt if the THDAL bit

is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

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12.7.2 HDLC Receive Side Register Map

The receive side uses five registers.

Table 12-28. Receive Side HDLC Register Map

ADDRESS REGISTER REGISTER DESCRIPTION

(0,2,4,6)B0h HDLC.RCR HDLC Receive Control Register

(0,2,4,6)B2h — Unused

(0,2,4,6)B4h HDLC.RSR HDLC Receive Status Register

(0,2,4,6)B6h HDLC.RSRL HDLC Receive Status Register Latched

(0,2,4,6)B8h HDLC.RSRIE HDLC Receive Status Register Interrupt Enable

(0,2,4,6)BAh — Unused

(0,2,4,6)BCh HDLC.RFDR HDLC Receive FIFO Data Register

(0,2,4,6)BEh — Unused

12.7.2.1 Register Bit Descriptions

Bit # 15 14 13 12 11 10 9 8

Name — — — RDAL4 RDAL3 RDAL2 RDAL1 RDAL0

Default 0 0 0 0 1 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — — — RBRE RDIE RFPD RFRST

Default 0 0 0 0 0 0 0 0

Bits 12 to 8: Receive HDLC Data Available Level (RDAL[4:0]) – These five bits indicate the minimum number of

eight byte groups that must be stored (contain data) in the Receive FIFO before HDLC data is considered to be

available (RHDA=1). For example, a value of 21 (15h) results in HDLC data being available when the Receive

FIFO contains 168 (A8h) bytes or more.

Bit 3: Receive Bit Reordering Enable (RBRE) – When 0, bit reordering is disabled (The first bit received is in the

LSB of the Receive FIFO Data byte RFD[0]). When 1, bit reordering is enabled (The first bit received is in the MSB

of the Receive FIFO Data byte RFD[7]).

Bit 2: Receive Data Inversion Enable (RDIE) – When 0, the incoming data is directly passed on for packet

processing. When 1, the incoming data is inverted before being passed on for packet processing.

Bit 1: Receive FCS Processing Disable (RFPD) – When 0, FCS processing is performed (the packets have a

FCS appended). When 1, FCS processing is disabled (the packets do not have a FCS appended).

Bit 0: Receive FIFO Reset (RFRST) – When 0, the Receive FIFO will resume normal operations, however, data is

discarded until a start of packet is received after RAM power-up is completed. When 1, the Receive FIFO is

emptied, any transfer in progress is halted, the FIFO RAM is powered down, the RHDA bit is forced low, and all

incoming data is discarded.

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Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Bit # 7 6 5 4 3 2 1 0

Name — — — — — RFF RFE RHDA

Bit 2: Receive FIFO Full (RFF) – When 0, the Receive FIFO contains 255 or less bytes of data. When 1, the

Receive FIFO is full.

Bit 1: Receive FIFO Empty (RFE) – When 0, the Receive FIFO contains at least one byte of data. When 1, the

Receive FIFO is empty.

Bit 0: Receive HDLC Data Available (RHDA) – When 0, the Receive FIFO contains less data than the Receive

HDLC data available level (RDAL[4:0]). When 1, the Receive FIFO contains the same or more data than the

Receive HDLC data available level.

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Bit # 7 6 5 4 3 2 1 0

Name RFOL — — RPEL RPSL RFFL — RHDAL

Bit 7: Receive FIFO Overflow Latched (RFOL) – This bit is set when a Receive FIFO overflow condition occurs.

An overflow condition results in a loss of data.

Bit 4: Receive Packet End Latched (RPEL) – This bit is set when an end of packet is stored in the Receive FIFO.

Bit 3: Receive Packet Start Latched (RPSL) – This bit is set when a start of packet is stored in the Receive FIFO.

Bit 2: Receive FIFO Full Latched (RFFL) – This bit is set when the RFF bit transitions from 0 to 1.

Bit 0: Receive HDLC Data Available Latched (RHDAL) – This bit is set when the RHDA bit transitions from

0 to 1.

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Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RFOIE — — RPEIE RPSIE RFFIE — RHDAIE

Default 0 0 0 0 0 0 0 0

Bit 7: Receive FIFO Overflow Interrupt Enable (RFOIE) – This bit enables an interrupt if the RFOL bit is set and

the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 4: Receive Packet End Interrupt Enable (RPEIE) – This bit enables an interrupt if the RPEL bit is set and the

bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 3: Receive Packet Start Interrupt Enable (RPSIE) – This bit enables an interrupt if the RPSL bit is set and the

bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 2: Receive FIFO Full Interrupt Enable (RFFIE) – This bit enables an interrupt if the RFFL bit is set and the bit

in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 0: Receive HDLC Data Available Interrupt Enable (RHDAIE) – This bit enables an interrupt if the RHDAL bit

is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

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Bit # 15 14 13 12 11 10 9 8

Name RFD7 RFD6 RFD5 RFD4 RFD3 RFD2 RFD1 RFD0

Default X X X X X X X X

Bit # 7 6 5 4 3 2 1 0

Name — — — — RPS2 RPS1 RPS0 RFDV

Default 0 0 0 0 X X X 0

Note: The FIFO data and status are updated when the Receive FIFO Data (RFD[7:0]) is read (upper byte read).

When this register is read eight bits at a time, a read of the lower byte will reflect the status of the next read of the

upper byte, and reading the upper byte when RFDV=0 may result in a loss of data.

Bits 15 to 8: Receive FIFO Data (RFD[7:0]) – These eight bits are the packet data stored in the Receive FIFO.

RFD[7] is the MSB, and RFD[0] is the LSB. If bit reordering is disabled, RFD[0] is the first bit received, and RFD[7]

is the last bit received. If bit reordering is enabled, RFD[7] is the first bit received, and RFD[0] is the last bit

received.

Bits 3 to 1: Receive Packet Status (RPS[2:0]) – These three bits indicate the status of the received packet and

packet data.

000 = packet middle

001 = packet start.

010 = reserved

011 = reserved

100 = packet end: good packet

101 = packet end: FCS errored packet.

110 = packet end: invalid packet (a non-integer number of bytes).

111 = packet end: aborted packet.

Bit 0: Receive FIFO Data Valid (RFDV) – When 0, the Receive FIFO data (RFD[7:0]) is invalid (the Receive FIFO

is empty). When 1, the Receive FIFO data (RFD[7:0]) is valid.

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12.8 FEAC Controller

12.8.1 FEAC Transmit Side Register Map

The transmit side uses five registers.

Table 12-29. FEAC Transmit Side Register Map

ADDRESS REGISTER REGISTER DESCRIPTION

(0,2,4,6)C0h FEAC.TCR FEAC Transmit Control Register

(0,2,4,6)C2h FEAC.TFDR FEAC Transmit Data Register

(0,2,4,6)C4h FEAC.TSR FEAC Transmit Status Register

(0,2,4,6)C6h FEAC.TSRL FEAC Transmit Status Register Latched

(0,2,4,6)C8h FEAC.TSRIE FEAC Transmit Status Register Interrupt Enable

(0,2,4,6)CAh — Unused

(0,2,4,6)CCh — Unused

(0,2,4,6)CEh — Unused

12.8.1.1 Register Bit Descriptions

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 1 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — — — — TFCL TFS1 TFS0

Default 0 0 0 0 0 0 0 0

Bit 2: Transmit FEAC Codeword Load (TFCL) – A 0 to 1 transition on this bit loads the transmit FEAC processor

mode select bits (TFS[1:0]), and transmit FEAC codes (TFCA[5:0] and TFCB[5:0]). Note: Whenever a FEAC

codeword is loaded, any current FEAC codeword transmission in progress will be immediately halted, and the new

FEAC codeword transmission will be started based on the new values for TFS[1:0], TFCA[5:0], and TFCB[5:0]..

Bits 1 to 0: Transmit FEAC Codeword Select (TFS[1:0]) – These two bits control the transmit FEAC processor

mode. The TFCL bit loads the mode set by this bit.

00 = Idle (all ones)

01 = single code (send code TFCA ten times and send all ones)

10 = dual code (send code TFCA ten times, send code TFCB ten times, and send all ones)

11 = continuous code (send code TFCA continuously)

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Bit # 15 14 13 12 11 10 9 8

Name — — TFCB5 TFCB4 TFCB3 TFCB2 TFCB1 TFCB0

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — TFCA5 TFCA4 TFCA3 TFCA2 TFCA1 TFCA0

Default 0 0 0 0 0 0 0 0

Bits 13 to 8: Transmit FEAC Code B (TFCB[5:0]) – These six bits are the transmit FEAC code B data to be

stored inserted into codeword B. TFCB[5] is the LSB (last bit transmitted) of the FEAC code (C[6]), and TFCB[0] is

the MSB (first bit transmitted) of the FEAC code (C[1]).

Bits 5 to 0: Transmit FEAC Code A (TFCA[5:0]) – These six bits are the transmit FEAC code A data to be stored

inserted into codeword A. TFCA[5] is the LSB (last bit transmitted) of the FEAC code (C[6]), and TFCA[0] is the

MSB (first bit transmitted) of the FEAC code (C[1]).

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Bit # 7 6 5 4 3 2 1 0

Name — — — — — — — TFI

Bit 0: Transmit FEAC Idle (TFI) – When 0, the Transmit FEAC processor is sending a FEAC codeword. When 1,

the Transmit FEAC processor is sending an Idle signal (all ones).

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Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Bit # 7 6 5 4 3 2 1 0

Name — — — — — — — TFIL

Bit 0: Transmit FEAC Idle Latched (TFIL) – This bit is set when the TFI bit transitions from 0 to 1. Note:

Immediately after a reset, this bit will be set to one.

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — — — — — — TFIIE

Default 0 0 0 0 0 0 0 0

Bit 0: Transmit FEAC Idle Interrupt Enable (TFIIE) – This bit enables an interrupt if the TFIL bit is set and the bit

in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

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12.8.2 FEAC Receive Side Register Map

The receive side uses five registers.

Table 12-30. FEAC Receive Side Register Map

ADDRESS REGISTER REGISTER DESCRIPTION

(0,2,4,6)D0h FEAC.RCR FEAC Receive Control Register

(0,2,4,6)D2h — Unused

(0,2,4,6)D4h FEAC.RSR FEAC Receive Status Register

(0,2,4,6)D6h FEAC.RSRL FEAC Receive Status Register Latched

(0,2,4,6)D8h FEAC.RSRIE FEAC Receive Status Register Interrupt Enable

(0,2,4,6)DAh — Unused

(0,2,4,6)DCh FEAC.RFDR FEAC Receive FIFO Data Register

(0,2,4,6)DEh — Unused

12.8.2.1 Register Bit Descriptions

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 1 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — — — — — — RFR

Default 0 0 0 0 0 0 0 0

Bit 0: Receive FEAC Reset (RFR) –When 0, the Receive FEAC Processor and Receive FEAC FIFO will resume

normal operations. When 1, the Receive FEAC controller is reset. The FEAC FIFO is emptied, any transfer in

progress is halted, and all incoming data is discarded.

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Bit # 7 6 5 4 3 2 1 0

Name — — — — RFFE — RFCD RFI

Bit 3: Receive FEAC FIFO Empty (RFFE) – When 0, the Receive FIFO contains at least one code. When 1, the

Receive FIFO is empty.

Bit 1: Receive FEAC Codeword Detect (RFCD) – When 0, the Receive FEAC Processor is not currently receiving

a FEAC codeword. When 1, the Receive FEAC Processor is currently receiving a FEAC codeword.

Bit 0: Receive FEAC Idle (RFI) – When 0, the Receive FEAC processor is not receiving a FEAC Idle signal (all

ones). When 1, the Receive FEAC processor is receiving a FEAC Idle signal.

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Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Bit # 7 6 5 4 3 2 1 0

Name — — — — — RFFOL RFCDL RFIL

Bit 2: Receive FEAC FIFO Overflow Latched (RFFOL) – This bit is set when a Receive FIFO overflow condition

occurs. An overflow condition results in a loss of data.

Bit 1: Receive FEAC Codeword Detect Latched (RFCDL) – This bit is set when the RFCD bit transitions from 0

to 1.

Bit 0: Receive FEAC Idle Latched (RFIL) – This bit is set when the RFI bit transitions from 0 to 1. Note:

Immediately after a reset, this bit will be set to one.

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — — — — RFFOIE RFCDIE RFIIE

Default 0 0 0 0 0 0 0 0

Bit 2: Receive FEAC FIFO Overflow Interrupt Enable (RFFOIE) – This bit enables an interrupt if the RFFOL bit

is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 1: Receive FEAC Codeword Detect Interrupt Enable (RFCDIE) – This bit enables an interrupt if the RFCDL

bit is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 0: Receive FEAC Idle Interrupt Enable (RFIIE) – This bit enables an interrupt if the RFIL bit is set and the bit

in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

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Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RFFI — RFF5 RFF4 RFF3 RFF2 RFF1 RFF0

Default 0 0 0 0 0 0 0 0

Bit 7: Receive FEAC FIFO Data Invalid (RFFI) – When 0, the Receive FIFO data (RFF[5:0]) is valid. When 1, the

Receive FIFO data is invalid (Receive FIFO is empty).

Bits 5 to 0: Receive FEAC FIFO Data (RFF[5:0]) – These six bits are the FEAC code data stored in the Receive

FIFO. RFF[5] is the LSB (last bit received) of the FEAC code (C[6]), and RFF[0] is the MSB (first bit received) of the

FEAC code (C[1]). The Receive FEAC FIFO data (RFF[5:0]) is updated when it is read (lower byte read).

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12.9 Trail Trace

12.9.1 Trail Trace Transmit Side

The transmit side uses three registers.

Table 12-31. Transmit Side Trail Trace Register Map

ADDRESS REGISTER REGISTER DESCRIPTION

(0,2,4,6)E8h TT.TCR Trail Trace Transmit Control Register

(0,2,4,6)EAh TT.TTIAR Trail Trace Transmit Identifier Address Register

(0,2,4,6)ECh TT.TIR Trail Trace Transmit Identifier Register

(0,2,4,6)EEh — Unused

12.9.1.1 Register Bit Descriptions

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — — Reserved TMAD TIDLE TDIE TBRE

Default 0 0 0 0 0 0 0 0

Bit 3: Transmit Multiframe Alignment Insertion Disable (TMAD) – When 0, multiframe alignment signal (MAS)

insertion is enabled, and the first bit transmitted of each trail trace byte is overwritten with an MAS bit. When 1,

MAS insertion is disabled, and the trail trace bytes from the Transmit Data Storage are output without being

modified.

Bit 2: Transmit Trail Trace Identifier Idle (TIDLE) – When 0, the programmed transmit trail trace identifier will be

transmitted. When 1, all zeros will be transmitted.

Bit 1: Transmit Data Inversion Enable (TDIE) – When 0, the outgoing data from trail trace processing is output

directly. When 1, the outgoing data from trail trace processing is inverted before being output.

Bit 0: Transmit Bit Reordering Enable (TBRE) – When 0, bit reordering is disabled (The first bit transmitted is the

MSB TT.TIR.TTD[7] of the byte). When 1, bit reordering is enabled (The first bit transmitted is the LSB

TT.TIR.TTD[0] of the byte).

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Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — Reserved Reserved TTIA3 TTIA2 TTIA1 TTIA0

Default 0 0 0 0 0 0 0 0

Bits 3 to 0: Transmit Trail Trace Identifier Address (TTIA[3:0]) – These four bits indicate the transmit trail trace

identifier byte to be read/written by the next memory access. Address 0h indicates the first byte of the transmit trail

trace identifier. Note: The value of these bits increments with each transmit trail trace identifier memory access

(when these bits are Fh, a memory access will return them to 0h).

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name TTD7 TTD6 TTD5 TTD4 TTD3 TTD2 TTD1 TTD0

Default 0 0 0 0 0 0 0 0

Bits 7 to 0: Transmit Trail Trace Identifier Data (TTD[7:0]) – These eight bits are the transmit trail trace identifier

data. The transmit trail trace identifier address will be incremented whenever these bits are read or written (when

address location Fh is read or written, the address will return to 0h).

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12.9.2 Trail Trace Receive Side Register Map

The receive side uses seven registers.

Table 12-32. Trail Trace Receive Side Register Map

ADDRESS REGISTER REGISTER DESCRIPTION

(0,2,4,6)F0h TT.RCR Trail Trace Receive Control Register

(0,2,4,6)F2h TT.RTIAR Trail Trace Receive Identifier Address Register

(0,2,4,6)F4h TT.RSR Trail Trace Receive Status Register

(0,2,4,6)F6h TT.RSRL Trail Trace Receive Status Register Latched

(0,2,4,6)F8h TT.RSRIE Trail Trace Receive Status Register Interrupt Enable

(0,2,4,6)FAh — Unused

(0,2,4,6)FCh TT.RIR Trail Trace Receive Identifier Register

(0,2,4,6)FEh TT.EIR Trail Trace Expected Identifier Register

12.9.2.1 Register Bit Descriptions

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — Reserved Reserved RMAD RETCE RDIE RBRE

Default 0 0 0 0 0 0 0 0

Bit 3: Receive Multiframe Alignment Disable (RMAD) – When 0, multiframe alignment is performed. When 1,

multiframe alignment is disabled and the trail trace bytes are stored starting with a random byte.

Bit 2: Receive Expected Trail Trace Comparison Enable (RETCE) – When 0, expected trail trace comparison is

disabled. When 1, expected trail trace comparison is performed. Note: When the RMAD bit is one, expected trail

trace comparison is disabled regardless of the setting of this bit.

Bit 1: Receive Data Inversion Enable (RDIE) – When 0, the incoming data is directly passed on for trail trace

processing. When 1, the incoming data is inverted before being passed on for trail trace processing.

Bit 0: Receive Bit Reordering Enable (RBRE) – When 0, bit reordering is disabled (The first bit received is the

MSB TT.RIR.RTD[7] of the byte). When 1, bit reordering is enabled (The first bit received is the LSB

TT.RIR.RTD[0] of the byte).

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Bit # 15 14 13 12 11 10 9 8

Name — — Reserved Reserved ETIA3 ETIA2 ETIA1 ETIA0

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — Reserved Reserved RTIA3 RTIA2 RTIA1 RTIA0

Default 0 0 0 0 0 0 0 0

Bits 11 to 8: Expected Trail Trace Identifier Address (ETIA[3:0]) – These four bits indicate the expected trail

trace identifier byte to be read/written by the next memory access. Address 0h indicates the first byte of the

expected trail trace identifier. Note: The value of these bits increments with each expected trail trace identifier

memory access (when these bits are Fh, a memory access will return them to 0h).

Bits 3 to 0: Receive Trail Trace Identifier Address (RTIA[3:0]) – These four bits indicate the receive trail trace

identifier byte to be read by the next memory access. Address 0h indicates the first byte of the receive trail trace

identifier. Note: The value of these bits increments with each receive trail trace identifier memory access (when

these bits are Fh, a memory access will return them to 0h).

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Bit # 7 6 5 4 3 2 1 0

Name — — — — — RTIM RTIU RIDL

Bit 2: Receive Trail Trace Identifier Mismatch (RTIM)

0 = Received and expected trail trace identifiers match.

1 = Received and expected trail trace identifiers do not match; trail trace identifier

mismatch (TIM) declared.

Bit 1: Receive Trail Trace Identifier Unstable (RTIU)

0 = Received trail trace identifier is not unstable

1 = Received trail trace identifier is in an unstable condition (TIU); TIU is declared when eight

consecutive trail trace identifiers are received that do not match either the receive trail trace

identifier or the previously stored current trail trace identifier.

Bit 0: Receive Trail Trace Identifier Idle (RIDL)

0 = Received trail trace identifier is not in idle condition.

1 = Received trail trace identifier is in idle condition. Idle condition is declared upon the reception of

an all zeros trail trace identifier five consecutive times.

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Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Bit # 7 6 5 4 3 2 1 0

Name — — — — RTICL RTIML RTIUL RIDLL

Bit 3: Receive Trail Trace Identifier Change Latched (RTICL) – This bit is set when the receive trail trace

identifier is updated.

Bit 2: Receive Trail Trace Identifier Mismatch Latched (RTIML) – This bit is set when the TT.RSR.RTIM bit

transitions from 0 to 1.

Bit 1: Receive Trail Trace Identifier Unstable Latched (RTIUL) – This bit is set when the TT.RSR.RTIU bit

transitions from 0 to 1.

Bit 0: Receive Trail Trace Identifier Idle Latched (RIDLL) – This bit is set when the TT.RSR.RIDL bit transitions

from 0 to 1.

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — — — RTICIE RTIMIE RTIUIE RIDLIE

Default 0 0 0 0 0 0 0 0

Bit 3: Receive Trail Trace Identifier Change Interrupt Enable (RTICIE) – This bit enables an interrupt if the

TT.RSRL.RTICL bit is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 2: Receive Trail Trace Identifier Mismatch Interrupt Enable (RTIMIE) – This bit enables an interrupt if the

TT.RSRL.RTIML bit is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 1: Receive Trail Trace Identifier Unstable Interrupt Enable (RTIUIE) – This bit enables an interrupt if the

TT.RSRL.RTIUL bit is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 0: Receive Trail Trace Identifier Idle Interrupt Enable (RIDLIE) – This bit enables an interrupt if the

TT.RSRL.RIDLL bit is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

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Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RTD7 RTD6 RTD5 RTD4 RTD3 RTD2 RTD1 RTD0

Default 0 0 0 0 0 0 0 0

Bits 7 to 0: Receive Trail Trace Identifier Data (RTD[7:0]) – These eight bits are the receive trail trace identifier

data. The receive trail trace identifier address will be incremented whenever these bits are read (when byte Fh is

read, the address will return to 0h).

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name ETD7 ETD6 ETD5 ETD4 ETD3 ETD2 ETD1 ETD0

Default 0 0 0 0 0 0 0 0

Bits 7 to 0: Expected Trail Trace Identifier Data (ETD[7:0]) – These eight bits are the expected trail trace

identifier data. The expected trail trace identifier address will be incremented whenever these bits are read or

written (when byte Fh is read or written, the address will return to 0h).

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12.10 DS3/E3 Framer

12.10.1 Transmit DS3

The transmit DS3 uses two registers.

Table 12-33. Transmit DS3 Framer Register Map

ADDRESS REGISTER REGISTER DESCRIPTION

(1,3,5,7)18h T3.TCR T3 Transmit Control Register

(1,3,5,7)1Ah T3.TEIR T3 Transmit Error Insertion Register

(1,3,5,7)1Ch — Reserved

(1,3,5,7)1Eh — Reserved

12.10.1.1 Register Bit Descriptions

Bit # 15 14 13 12 11 10 9 8

Name — — — PBGE TIDLE CBGD — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — TFEBE AFEBED TRDI ARDID TFGC TAIS

Default 0 0 0 0 0 0 0 0

Bit 12: P-bit Generation Enable (PBGE) – When 0, Transmit Frame Processor P-bit generation is disabled. If

transmit frame generation is also disabled, the P-bit overhead periods in the incoming DS3 signal will be passed

through to overhead insertion. When 1, Transmit Frame Processor P-bit generation is enabled. The P-bit overhead

periods in the incoming DS3 signal will be overwritten even if transmit frame generation is disabled

Bit 11: Transmit DS3 Idle Signal (TIDLE) –

0 = Transmit DS3 Idle signal is not inserted

1 = Transmit DS3 Idle signal is inserted into the DS3 frame.

Bit 10: C-bit Generation Disable (CBGD) (M23 mode only) – When 0, Transmit Frame Processor C-bit

generation is enabled. The C-bit overhead periods in the incoming M23 DS3 signal will be overwritten with zeros.

When 1, Transmit Frame Processor C-bit generation is disabled. The C-bit overhead periods in the incoming M23

DS3 signal will be treated as payload, and passed through to overhead insertion. This bit is ignored in C-bit DS3

mode. Note: If CBGD = 1, PORT.CR1.NAD must also be set to 1.

Bit 5: Transmit FEBE Error (TFEBE) – When automatic far-end block error generation is defeated (AFEBED = 1),

the inverse of this bit is inserted into the bits C41, C42, and C43. Note: a far-end block error value of zero (TFEBE=1)

indicates a far-end block error. This bit is ignored in M23 DS3 mode.

Bit 4: Automatic FEBE Defeat (AFEBED) – When 0, a far-end block error is automatically generated based upon

the receive parity errors. When 1, a far-end block error is inserted from the register bit TFEBE. This bit is ignored in

M23 DS3 mode.

Bit 3: Transmit RDI Alarm (TRDI) – When automatic RDI generation is defeated (ARDID = 1), the inverse of this

bit is inserted into the X-bits (X1 and X2). Note: an RDI value of zero (TRDI=1) indicates an alarm.

Bit 2: Automatic RDI Defeat (ARDID) – When 0, the RDI is automatically generated based received DS3 alarms.

When 1, the RDI is inserted from the register bit TRDI.

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Bit 1: Transmit Frame Generation Control (TFGC) – When this bit is zero, the Transmit Frame Processor frame

generation is enabled. The DS3 overhead positions in the incoming DS3 payload will be overwritten with the

internally generated DS3 overhead. When this bit is one, the Transmit Frame Processor frame generation is

disabled. The DS3 overhead positions in the incoming DS3 payload will be passed through to error insertion. Note:

Frame generation will still overwrite the P-bits if PBGE = 1. Also, the DS3 overhead periods can still be overwritten

by overhead insertion.

Bit 0: Transmit Alarm Indication Signal (TAIS) –

0 = Transmit Alarm Indication Signal is not inserted

1 = Transmit Alarm Indication Signal is inserted into data stream payload

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Bit # 15 14 13 12 11 10 9 8

Name — — — — CCPEIE CPEI CFBEIE FBEI

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name Reserved CPEIE PEI FEIC1 FEIC0 FEI TSEI MEIMS

Default 0 0 0 0 0 0 0 0

Bit 11: Continuous C-bit Parity Error Insertion Enable (CCPEIE) – When 0, single C-bit parity error insertion is

enabled. When 1, continuous C-bit parity error insertion is enabled, and C-bit parity errors will be transmitted

continuously if CPEI is high.

Bit 10: C-bit Parity Error Insertion Enable (CPEI) – When 0, C-bit parity error insertion is disabled. When 1, C-bit

parity error insertion is enabled.

Bit 9: Continuous Far-End Block Error Insertion Enable (CFBEIE) – When 0, single far-end block error

insertion is enabled. When 1, continuous far-end block error insertion is enabled, and far-end block errors will be

transmitted continuously if FBEI is high.

Bit 8: Far-End Block Error Insertion Enable (FBEI) – When 0, far-end block error insertion is disabled. When 1,

far-end block error insertion is enabled.

Bit 6: Continuous P-bit Parity Error Insertion Enable (CPEIE) – When 0, single P-bit parity error insertion is

enabled. When 1, continuous P-bit parity error insertion is enabled, and P-bit parity errors will be transmitted

continuously if PEI is high.

Bit 5: P-bit Parity Error Insertion Enable (PEI) – When 0, P-bit parity error insertion is disabled. When 1, P-bit

parity error insertion is enabled.

Bits 4 to 3: Framing Error Insertion Control (FEIC[1:0]) – These two bits control the framing error event to be

inserted.

00 = F-bit error.

01 = M-bit error.

10 = SEF error.

11 = OOMF error.

Bit 2: Framing Error Insertion Enable (FEI) – When 0, framing error insertion is disabled. When 1, framing error

insertion is enabled.

Bit 1: Transmit Single Error Insert (TSEI) – This bit causes an error of the enabled type(s) to be inserted in the

transmit data stream if manual error insertion is disabled (MEIMS = 0). A 0 to 1 transition causes a single error to

be inserted. For a second error to be inserted, this bit must be set to 0, and back to 1. Note: If MEIMS is low, and

this bit transitions more than once between error insertion opportunities, only one error will be inserted.

Bit 0: Manual Error Insert Mode Select (MEIMS) – When 0, error insertion is initiated by the TSEI register bit.

When 1, error insertion is initiated by the transmit manual error insertion signal (TMEI). Note: If TMEI or TSEI is

one, changing the state of this bit may cause an error to be inserted.

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12.10.2 Receive DS3 Register Map

The receive DS3 uses 11 registers. Two registers are shared for C-Bit and M23 DS3 modes. The M23 DS3 mode

does not use the RFEBER or RCPECR count registers.

Table 12-34. Receive DS3 Framer Register Map

ADDRESS REGISTER REGISTER DESCRIPTION

(1,3,5,7)20h T3.RCR T3 Receive Control Register

(1,3,5,7)22h — Reserved

(1,3,5,7)24h T3.RSR1 T3 Receive Status Register 1

(1,3,5,7)26h T3.RSR2 T3 Receive Status Register 2

(1,3,5,7)28h T3.RSRL1 T3 Receive Status Register Latched 1

(1,3,5,7)2Ah T3.RSRL2 T3 Receive Status Register Latched 2

(1,3,5,7)2Ch T3.RSRIE1 T3 Receive Status Register Interrupt Enable 1

(1,3,5,7)2Eh T3.RSRIE2 T3 Receive Status Register Interrupt Enable 2

(1,3,5,7)30h — Reserved

(1,3,5,7)32h — Reserved

(1,3,5,7)34h T3.RFECR T3 Receive Framing Error Count Register

(1,3,5,7)36h T3.RPECR T3 Receive P-Bit Parity Error Count Register

(1,3,5,7)38h T3.RFBECR T3 Receive Far-End Block Error Count Register

(1,3,5,7)3Ah T3.RCPECR T3 Receive C-Bit Parity Error Count Register

(1,3,5,7)3Ch — Unused

(1,3,5,7)3Eh — Unused

12.10.2.1 Register Bit Descriptions

Bit # 15 14 13 12 11 10 9 8

Name Reserved COVHD MAOD MDAISI AAISD ECC FECC1 FECC0

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RAILE RAILD RAIOD RAIAD ROMD LIP1 LIP0 FRSYNC

Default 0 0 0 0 0 0 0 0

Bit 14: C-bit Overhead Masking Disable (COVHD) – When 0, the C-bit positions will be marked as overhead

(RDENn=0). When 1, the C-bit positions will be marked as data (RDENn=1). This bit is ignored in C-bit DS3 mode

or when the ROMD bit is set to one.

Bit 13: Multiframe Alignment OOF Disable (MAOD) – When 0, an OOF condition is declared whenever an

OOMF or SEF condition is declared. When 1, an OOF condition is declared only when an SEF condition is

declared.

Bit 12: Manual Downstream AIS Insertion (MDAISI) – When 0, manual downstream AIS insertion is disabled.

When 1, manual downstream AIS insertion is enabled.

Bit 11: Automatic Downstream AIS Disable (AAISD) – When 0, the presence of a LOS, OOF, or AIS condition

will cause downstream AIS to be inserted. When 1, the presence of a LOS, OOF, or AIS condition will not cause

downstream AIS to be inserted.

Bit 10: Error Count Control (ECC) – When 0, framing errors, P-bit parity errors, C-bit parity errors, and far-end

block errors will not be counted if an OOF or AIS condition is present. P-bit parity errors, C-bit parity errors, and far-

end block errors will also not be counted during the DS3 frame in which an OOF condition is terminated, and the

next DS3 frame. When 1, framing errors, P-bit parity errors, C-bit parity errors, and far-end block errors will be

counted regardless of the presence of an OOF or AIS condition.

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Bits 9 to 8: Framing Error Count Control (FECC[1:0]) – These two bits control the type of framing error events

that are counted.

00 = count OOF occurrences (counted regardless of the setting of the ECC bit).

01 = count M bit and F bit errors.

10 = count only F bit errors.

11 = count only M bit errors.

Bit 7: Receive Alarm Indication on LOF Enable (RAILE) – When 0, an LOF condition does not affect the receive

alarm indication signal (RAI). When 1, an LOF condition will cause the transmit DS3 X-bits to be set to zero if

transmit automatic RDI is enabled.

Bit 6: Receive Alarm Indication on LOS Disable (RAILD) – When 0, an LOS condition will cause the transmit

DS3 X-bits to be set to zero if transmit automatic RDI is enabled. When 1, an LOS condition does not affect the RAI

signal.

Bit 5: Receive Alarm Indication on SEF Disable (RAIOD) – When 0, an SEF condition will cause the transmit

DS3 X-bits to be set to zero if transmit automatic RDI is enabled. When 1, an SEF condition does not affect the RAI

signal.

Bit 4: Receive Alarm Indication on AIS Disable (RAIAD) – When 0, an AIS condition will cause the transmit DS3

X-bits to be set to zero if transmit automatic RDI is enabled. When 1, an AIS condition does not affect the RAI

signal.

Bit 3: Receive Overhead Masking Disable (ROMD) – When 0, the DS3 overhead positions in the outgoing DS3

payload will be marked as overhead by RDENn. When 1, the DS3 overhead positions in the outgoing DS3 payload

will be marked as payload data by RDENn. When this bit is set to one, the COVHD bit is ignored.

Bits 2 to 1: LOF Integration Period (LIP[1:0]) – These two bits determine the OOF integration period for

declaring LOF.

00 = OOF is integrated for 3 ms before declaring LOF

01 = OOF is integrated for 2 ms before declaring LOF

10 = OOF is integrated for 1 ms before declaring LOF.

11 = LOF is declared at the same time as OOF.

Bit 0: Force Framer Re-synchronization (FRSYNC) – A 0 to 1 transition forces an OOF, SEF, and OOMF

condition. The bit must be cleared and set to one again to force another re-synchronization

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Bit # 15 14 13 12 11 10 9 8

Name Reserved Reserved — Reserved T3FM AIC IDLE RUA1

Bit # 7 6 5 4 3 2 1 0

Name OOMF SEF — LOF RDI AIS OOF LOS

Bit 11: T3 Framing Format Mismatch (T3FM) – This bit indicates the DS3 framer is programmed for a framing

format (C-bit or M23) that is different than the format indicated by the incoming DS3 signal.

Bit 10: Application Identification Channel (AIC) – This bit indicates the current state of the Application

Identification Channel (AIC) from the C11 bit. AIC = 1 is C-bit mode, AIC = 0 is M23 mode.

Bit 9: DS3 Idle Signal (IDLE) – When 0, the receive frame processor is not in a DS3 idle signal (Idle) condition.

When 1, the receive frame processor is in an Idle condition.

Bit 8: Receive Unframed All 1’s (RUA1) – When 0, the receive frame processor is not in a receive unframed all

1’s (RUA1) condition. When 1, the receive frame processor is in an RUA1 condition.

Bit 7: Out Of Multiframe (OOMF) – When 0, the receive frame processor is not in an out of multiframe (OOMF)

condition. When 1, the receive frame processor is in an OOMF condition.

Bit 6: Severely Errored Frame (SEF) – When 0, the receive frame processor is not in a severely errored frame

(SEF) condition. When 1, the receive frame processor is in an SEF condition.

Bit 4: Loss Of Frame (LOF) – When 0, the receive framer is not in a loss of frame (LOF) condition. When 1, the

receive frame processor is in an LOF condition.

Bit 3: Remote Defect Indication (RDI) – This bit indicates the current state of the remote defect indication (RDI)

Bit 2: Alarm Indication Signal (AIS) – When 0, the receive frame processor is not in an alarm indication signal

(AIS) condition. When 1, the receive frame processor is in an AIS condition.

Bit 1: Out Of Frame (OOF) – When 0, the receive framer is not in an out of frame (OOF) condition. When 1, the

receive frame processor is in an OOF condition.

Bit 0: Loss Of Signal (LOS) – When 0, the receive framer is not in a loss of signal (LOS) condition. When 1, the

receive framer is in an LOS condition.

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Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Bit # 7 6 5 4 3 2 1 0

Name — — — — CPEC FBEC PEC FEC

Bit 3: C-bit Parity Error Count (CPEC) – When 0, the C-bit parity error count is zero. When 1, the C-bit parity

error count is one or more. This bit is set to zero in M23 DS3 mode.

Bit 2: Remote Error Indication Count (FBEC) – When 0, the remote error indication count is zero. When 1, the

remote error indication count is one or more. This bit is set to zero in M23 DS3 mode.

Bit 1: P-bit Parity Error Count (PEC) – When 0, the P-bit parity error count is zero. When 1, the P-bit parity error

count is one or more.

Bit 0: Framing Error Count (FEC) – When 0, the framing error count is zero. When 1, the framing error count is

one or more. The type of framing error event counted is determined by T3.RCR.FECC[1:0]

Bit # 15 14 13 12 11 10 9 8

Name Reserved Reserved Reserved Reserved T3FML AICL IDLEL RUA1L

Bit # 7 6 5 4 3 2 1 0

Name OOMFL SEFL COFAL LOFL RAIL AISL OOFL LOSL

Bit 11: T3 Framing Format Mismatch Latched (T3FML) – This bit is set when the T3FM bit transitions from zero

to one.

Bit 10: Application Identification Channel Change Latched (AICL) – This bit is set when the AIC bit changes

state.

Bit 9: DS3 Idle Signal Change Latched (IDLEL) – This bit is set when the IDLE bit changes state.

Bit 8: Receive Unframed All 1’s Change Latched (RUA1L) – This bit is set when the RUA1 bit changes state.

Bit 7: Out Of Multiframe Change Latched (OOMFL) – This bit is set when the OOMF bit changes state.

Bit 6: Severely Errored Frame Change Latched (SEFL) – This bit is set when the SEF bit changes state.

Bit 5: Change Of Frame Alignment Latched (COFAL) – This bit is set when the data path frame counters are

updated with a new DS3 frame alignment that is different from the previous DS3 frame alignment.

Bit 4: Loss Of Frame Change Latched (LOFL) – This bit is set when the LOF bit changes state.

Bit 3: Remote Defect Indication Change Latched (RDIL) – This bit is set when the RDI bit changes state.

Bit 2: Alarm Indication Signal Change Latched (AISL) – This bit is set when the AIS bit changes state.

Bit 1: Out Of Frame Change Latched (OOFL) – This bit is set when the OOF bit changes state.

Bit 0: Loss Of Signal Change Latched (LOSL) – This bit is set when the LOS bit changes state.

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Bit # 15 14 13 12 11 10 9 8

Name — — — — CPEL FBEL PEL FEL

Bit # 7 6 5 4 3 2 1 0

Name — — — — CPECL FBECL PECL FECL

Bit 11: C-bit Parity Error Latched (CPEL) – This bit is set when a C-bit parity error is detected. This bit is set to

zero in M23 DS3 mode.

Bit 10: Remote Error Indication Latched (FBEL) – This bit is set when a far-end block error is detected. This bit

is set to zero in M23 DS3 mode.

Bit 9: P-bit Parity Error Latched (PEL) – This bit is set when a P-bit parity error is detected.

Bit 8: Framing Error Latched (FEL) – This bit is set when a framing error is detected. The type of framing error

event that causes this bit to be set is determined by T3.RCR.FECC[1:0]

Bit 3: C-bit Parity Error Count Latched (CPECL) – This bit is set when the CPEC bit transitions from zero to one.

This bit is set to zero in M23 DS3 mode.

Bit 2: Remote Error Indication Count Latched (FBECL) – This bit is set when the FBEC bit transitions from zero

to one. This bit is set to zero in M23 DS3 mode.

Bit 1: P-bit Parity Error Count Latched (PECL) – This bit is set when the PEC bit transitions from zero to one.

Bit 0: Framing Error Count Latched (FECL) – This bit is set when the FEC bit transitions from zero to one.

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Bit # 15 14 13 12 11 10 9 8

Name Reserved Reserved Reserved Reserved T3FMIE AICIE IDLEIE RUA1IE

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name OOMFIE SEFIE COFAIE LOFIE RAIIE AISIE OOFIE LOSIE

Default 0 0 0 0 0 0 0 0

Bit 11: T3 Framing Format Mismatch Interrupt Enable (T3FMIE) – This bit enables an interrupt if the T3FML bit

is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 10: Application Identification Channel Interrupt Enable (AICIE) – This bit enables an interrupt if the AICL bit

is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 9: DS3 Idle Signal Change Interrupt Enable (IDLEIE) – This bit enables an interrupt if the IDLEL bit is set and

the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 8: Receive Unframed All 1’s Interrupt Enable (RUA1IE) – This bit enables an interrupt if the RUA1L bit is set

and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 7: Out Of Multiframe Interrupt Enable (OOMFIE) – This bit enables an interrupt if the OOMFL bit is set and

the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 6: Severely Errored Frame Interrupt Enable (SEFIE) – This bit enables an interrupt if the SEFL bit is set and

the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 5: Change Of Frame Alignment Interrupt Enable (COFAIE) – This bit enables an interrupt if the COFAL bit is

set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 4: Loss Of Frame Interrupt Enable (LOFIE) – This bit enables an interrupt if the LOFL bit is set and the bit in

GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 3: Remote Defect Indication Interrupt Enable (RDIIE) – This bit enables an interrupt if the RDIL bit is set and

the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

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Bit 2: Alarm Indication Signal Interrupt Enable (AISIE) – This bit enables an interrupt if the AISL bit is set and

the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 1: Out Of Frame Interrupt Enable (OOFIE) – This bit enables an interrupt if the OOFL bit is set and the bit in

GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 0: Loss Of Signal Interrupt Enable (LOSIE) – This bit enables an interrupt if the LOSL bit is set and the bit in

GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

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Bit # 15 14 13 12 11 10 9 8

Name — — — — CPEIE FBEIE PEIE FEIE

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — — — CPECIE FBECIE PECIE FECIE

Default 0 0 0 0 0 0 0 0

Bit 11: C-bit Parity Error Interrupt Enable (CPEIE) – This bit enables an interrupt if the CPEL bit is set and the bit

in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 10: Remote Error Interrupt Enable (FBEIE) – This bit enables an interrupt if the FBEL bit is set and the bit in

GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 9: P-bit Parity Error Interrupt Enable (PEIE) – This bit enables an interrupt if the PEL bit is set and the bit in

GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 8: Framing Error Interrupt Enable (FEIE) – This bit enables an interrupt if the FEL bit is set and the bit in

GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 3: C-bit Parity Error Count Interrupt Enable (CPECIE) – This bit enables an interrupt if the CPECL bit is set

and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 2: Far-End Block Error Count Interrupt Enable (FBECIE) – This bit enables an interrupt if the FBECL bit is

set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 1: P-bit Parity Error Count Interrupt Enable (PECIE) – This bit enables an interrupt if the PECL bit is set and

the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 0: Framing Error Count Interrupt Enable (FECIE) – This bit enables an interrupt if the FECL bit is set and the

bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

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Bit # 15 14 13 12 11 10 9 8

Name FE15 FE14 FE13 FE12 FE11 FE10 FE9 FE8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name FE7 FE6 FE5 FE4 FE3 FE2 FE1 FE0

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Framing Error Count (FE[15:0]) – These 16 bits indicate the number of framing error events on the

incoming DS3 data stream. This register is updated via the PMU signal (see Section 10.4.5)

Bit # 15 14 13 12 11 10 9 8

Name PE15 PE14 PE13 PE12 PE11 PE10 PE9 PE8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name PE7 PE6 PE5 PE4 PE3 PE2 PE1 PE0

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: P-bit Parity Error Count (PE[15:0]) – These 16 bits indicate the number of P-bit parity errors

detected on the incoming DS3 data stream. This register is updated via the PMU signal (see Section 10.4.5)

Bit # 15 14 13 12 11 10 9 8

Name FBE15 FBE14 FBE13 FBE12 FBE11 FBE10 FBE9 FBE8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name FBE7 FBE6 FBE5 FBE4 FBE3 FBE2 FBE1 FBE0

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Far-End Block Error Count (FBE[15:0]) – These 16 bits indicate the number of far-end block errors

detected on the incoming DS3 data stream. The associated counter will not increment in M23 DS3 mode. This

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Bit # 15 14 13 12 11 10 9 8

Name CPE15 CPE14 CPE13 CPE12 CPE11 CPE10 CPE9 CPE8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name CPE7 CPE6 CPE5 CPE4 CPE3 CPE2 CPE1 CPE0

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: C-bit Parity Error Count (CPE[15:0]) – These 16 bits indicate the number of C-bit parity errors

detected on the incoming DS3 data stream. The associated counter will not increment in M23 DS3 mode. This

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12.10.3 Transmit G.751 E3

The transmit G.751 E3 uses two registers.

12.10.3.1 Register Map

Table 12-35. Transmit G.751 E3 Framer Register Map

ADDRESS REGISTER REGISTER DESCRIPTION

(1,3,5,7)18h E3G751.TCR E3 G.751 Transmit Control Register

(1,3,5,7)1Ah E3G751.TEIR E3 G.751 Transmit Error Insertion Register

(1,3,5,7)1Ch — Reserved

(1,3,5,7)1Eh — Reserved

12.10.3.2 Register Bit Descriptions

Bit # 15 14 13 12 11 10 9 8

Name Reserved — — Reserved Reserved Reserved TNBC1 TNBC0

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — Reserved Reserved TABC1 TABC0 TFGC TAIS

Default 0 0 0 0 0 0 0 0

Bits 9 to 8: Transmit N Bit Control (TNBC[1:0]) – These two bits control the source of the N bit.

00 = 1

01 = transmit data from HDLC controller.

10 = transmit data from FEAC controller.

11 = 0

Note: If TNBC[1:0] is 10 and TABC[1:0] is 01, both the N bit and A bit will carry the same transmit FEAC controller

(one bit per frame period), however, the N bit and A bit in the same frame may or may not be equal.

Bits 3 to 2: Transmit A Bit Control (TABC[1:0]) – These two bits control the source of the A bit.

00 = automatically generated based upon received E3 alarms.

01 = transmit from the FEAC controller.

10 = 0

11 = 1

Note: If TABC[1:0] is 01 and TNBC[1:0] is 10, both the A bit and N bit will carry the same transmit FEAC controller

(one bit per frame period), however, the A bit and N bit in the same frame may or may not be equal.

Bit 1: Transmit Frame Generation Control (TFGC) – When this bit is zero, the Transmit Frame Processor frame

generation is enabled. The E3 overhead positions in the incoming E3 payload will be overwritten with the internally

generated E3 overhead. When this bit is one, the Transmit Frame Processor frame generation is disabled. The E3

overhead positions in the incoming E3 payload will be passed through to error insertion. Note: The E3 overhead

periods can still be overwritten by overhead insertion.

Bit 0: Transmit Alarm Indication Signal (TAIS) – When 0, the normal signal is transmitted. When 1, the output

E3 data stream is forced to all ones (AIS).

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Bit # 15 14 13 12 11 10 9 8

Name — — — — Reserved Reserved Reserved Reserved

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name Reserved Reserved Reserved FEIC1 FEIC0 FEI TSEI MEIMS

Default 0 0 0 0 0 0 0 0

Bits 4 to 3: Framing Error Insert Control (FEIC[1:0]) – These two bits control the framing error event to be

inserted.

00 = single bit error in one frame.

01 = word error in one frame.

10 = single bit error in four consecutive frames.

11 = word error in four consecutive frames.

Bit 2: Framing Error Insertion Enable (FEI) – When 0, framing error insertion is disabled. When 1, framing error

insertion is enabled.

Bit 1: Transmit Single Error Insert (TSEI) – This bit causes an error of the enabled type(s) to be inserted in the

transmit data stream if manual error insertion is disabled (MEIMS = 0). A 0 to 1 transition causes a single error to

be inserted. For a second error to be inserted, this bit must be set to 0, and back to 1. Note: If MEIMS is low, and

this bit transitions more than once between error insertion opportunities, only one error will be inserted.

Bit 0: Manual Error Insert Mode Select (MEIMS) – When 0, error insertion is initiated by the TSEI register bit.

When 1, error insertion is initiated by the transmit manual error insertion signal (TMEI). Note: If TMEI or TSEI is

one, changing the state of this bit may cause an error to be inserted.

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12.10.4 Receive G.751 E3 Register Map

The receive G.751 E3 uses eight registers.

Table 12-36. Receive G.751 E3 Framer Register Map

ADDRESS REGISTER REGISTER DESCRIPTION

(1,3,5,7)20h E3G751.RCR E3 G.751 Receive Control Register

(1,3,5,7)22h — Reserved

(1,3,5,7)24h E3G751.RSR1 E3 G.751 Receive Status Register 1

(1,3,5,7)26h E3G751.RSR2 E3 G.751 Receive Status Register 2

(1,3,5,7)28h E3G751.RSRL1 E3 G.751 Receive Status Register Latched 1

(1,3,5,7)2Ah E3G751.RSRL2 E3 G.751 Receive Status Register Latched 2

(1,3,5,7)2Ch E3G751.RSRIE1 E3 G.751 Receive Status Register Interrupt Enable 1

(1,3,5,7)2Eh E3G751.RSRIE2 E3 G.751 Receive Status Register Interrupt Enable 2

(1,3,5,7)30h — Reserved

(1,3,5,7)32h — Reserved

(1,3,5,7)34h E3G751.RFECR E3 G.751 Receive Framing Error Count Register

(1,3,5,7)36h — Reserved

(1,3,5,7)38h — Reserved

(1,3,5,7)3Ah — Reserved

(1,3,5,7)3Ch — Unused

(1,3,5,7)3Eh — Unused

12.10.4.1 Register Bit Descriptions

Bit # 15 14 13 12 11 10 9 8

Name Reserved Reserved DLS MDAISI AAISD ECC FECC1 FECC0

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RAILE RAILD RAIOD RAIAD ROMD LIP1 LIP0 FRSYNC

Default 0 0 0 0 0 0 0 0

Bit 13: Receive FEAC Data Link Source (DLS) – When 0, the receive FEAC controller will be sourced from the N

bit. When 1, the receive FEAC controller will be sourced from the A bit.

Bit 12: Manual Downstream AIS Insertion (MDAISI) – When 0, manual downstream AIS insertion is disabled.

When 1, manual downstream AIS insertion is enabled.

Bit 11: Automatic Downstream AIS Disable (AAISD) – When 0, the presence of an LOS, OOF, or AIS condition

will cause downstream AIS to be inserted. When 1, the presence of an LOS, OOF, or AIS condition will not cause

downstream AIS to be inserted.

Bit 10: Error Count Control (ECC) – When 0, framing errors will not be counted if an OOF or AIS condition is

present. When 1, framing errors will be counted regardless of the presence of an OOF or AIS condition.

Bits 9 to 8: Framing Error Count Control (FECC[1:0]) – These two bits control the type of framing error events

that are counted.

00 = count OOF occurrences (counted regardless of the setting of the ECC bit).

01 = count each bit error in the FAS (up to 10 per frame).

10 = count frame alignment signal (FAS) errors (up to one per frame).

11 = reserved

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Bit 7: Receive Alarm Indication on LOF Enable (RAILE) – When 0, an LOF condition does not affect the receive

alarm indication signal (RAI). When 1, an LOF condition will cause the transmit E3 A bit to be set to one if transmit

automatic RAI is enabled.

Bit 6: Receive Alarm Indication on LOS Disable (RAILD) – When 0, an LOS condition will cause the transmit E3

A bit to be set to one if transmit automatic RAI is enabled. When 1, an LOS condition does not affect the RAI

signal.

Bit 5: Receive Alarm Indication on OOF Disable (RAIOD) – When 0, an OOF condition will cause the transmit

E3 A bit to be set to one if transmit automatic RAI is enabled. When 1, an OOF condition does not affect the RAI

signal.

Bit 4: Receive Alarm Indication on AIS Disable (RAIAD) – When 0, an AIS condition will cause the transmit E3

A bit to be set to one if transmit automatic RAI is enabled. When 1, an AIS condition does not affect the RAI signal.

Bit 3: Receive Overhead Masking Disable (ROMD) – When 0, the E3 overhead positions in the outgoing E3

payload will be marked as overhead by RDENn. When 1, the E3 overhead positions in the outgoing E3 payload will

be marked as data by RDENn.

Bits 2 to 1: LOF Integration Period (LIP[1:0]) – These two bits determine the OOF integration period for

declaring LOF.

00 = OOF is integrated for 3 ms before declaring LOF

01 = OOF is integrated for 2 ms before declaring LOF.

10 = OOF is integrated for 1 ms before declaring LOF

11 = LOF is declared at the same time as OOF

Bit 0: Force Framer Re-synchronization (FRSYNC) – A 0 to 1 transition forces an OOF condition at the FAS

check. This bit must be cleared and set to one again to force another re-synchronization

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Bit # 15 14 13 12 11 10 9 8

Name Reserved Reserved — Reserved Reserved Reserved Reserved RUA1

Bit # 7 6 5 4 3 2 1 0

Name RAB RNB — LOF RDI AIS OOF LOS

Bit 8: Receive Unframed All 1’s (RUA1) – When 0, the receive frame processor is not in a receive unframed all

1’s (RUA1) condition. When 1, the receive frame processor is in an RUA1 condition.

Bit 7: Receive A Bit (RAB) – This bit is the integrated A bit extracted from the E3 frame.

Bit 6: Receive N Bit (RNB) – This bit is the integrated N bit extracted from the E3 frame.

Bit 4: Loss Of Frame (LOF) – When 0, the receive frame processor is not in a loss of frame (LOF) condition.

When 1, the receive frame processor is in an LOF condition.

Bit 3: Remote Alarm Indication (RDI) – This bit indicates the current state of the remote alarm indication (RDI).

Bit 2: Alarm Indication Signal (AIS) – When 0, the receive frame processor is not in an alarm indication signal

(AIS) condition. When 1, the receive frame processor is in an AIS condition.

Bit 1: Out Of Frame (OOF) – When 0, the receive frame processor is not in an out of frame (OOF) condition.

When 1, the receive frame processor is in an OOF condition.

Bit 0: Loss Of Signal (LOS) – When 0, the receive loss of signal (LOS) input (RLOS) is low. When 1, RLOS is

high.

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Bit # 7 6 5 4 3 2 1 0

Name — — — — Reserved Reserved Reserved FEC

Bit 0: Framing Error Count (FEC) – When 0, the framing error count is zero. When 1, the framing error count is

one or more.

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Bit # 15 14 13 12 11 10 9 8

Name Reserved Reserved Reserved Reserved Reserved Reserved Reserved RUA1L

Bit # 7 6 5 4 3 2 1 0

Name ACL NCL COFAL LOFL RDIL AISL OOFL LOSL

Bit 8: Receive Unframed All 1’s Change Latched (RUA1L) – This bit is set when the RUA1 bit changes state.

Bit 7: A Bit Change Latched (ACL) – This bit is set when the RAB bit changes state.

Bit 6: N Bit Change Latched (NCL) – This bit is set when the RNB bit changes state.

Bit 5: Change Of Frame Alignment Latched (COFAL) – This bit is set when the data path frame counters are

updated with a new frame alignment that is different from the previous frame alignment.

Bit 4: Loss Of Frame Change Latched (LOFL) – This bit is set when the LOF bit changes state.

Bit 3: Remote Alarm Indication Change Latched (RDIL) – This bit is set when the RDI bit changes state.

Bit 2: Alarm Indication Signal Change Latched (AISL) – This bit is set when the AIS bit changes state.

Bit 1: Out Of Frame Change Latched (OOFL) – This bit is set when the OOF bit changes state.

Bit 0: Loss Of Signal Change Latched (LOSL) – This bit is set when the LOS bit changes state.

Bit # 15 14 13 12 11 10 9 8

Name — — — — Reserved Reserved Reserved FEL

Bit # 7 6 5 4 3 2 1 0

Name — — — — Reserved Reserved Reserved FECL

Bit 8: Framing Error Latched (FEL) – This bit is set when a framing error is detected.

Bit 0: Framing Error Count Latched (FECL) – This bit is set when the FEC bit transitions from zero to one.

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Bit # 15 14 13 12 11 10 9 8

Name Reserved Reserved Reserved Reserved Reserved Reserved Reserved RUA1IE

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name ACIE NCIE COFAIE LOFIE RDIIE AISIE OOFIE LOSIE

Default 0 0 0 0 0 0 0 0

Bit 8: Receive Unframed All 1’s Interrupt Enable (RUA1IE) – This bit enables an interrupt if the RUA1L bit is set

and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 7: A Bit Change Interrupt Enable (ACIE) – This bit enables an interrupt if the ACL bit is set and the bit in

GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 6: N Bit Change Interrupt Enable (NCIE) – This bit enables an interrupt if the NCL bit is set and the bit in

GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 5: Change Of Frame Alignment Interrupt Enable (COFAIE) – This bit enables an interrupt if the COFAL bit

and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port are set. set.

0 = interrupt disabled

1 = interrupt enabled

Bit 4: Loss Of Frame Interrupt Enable (LOFIE) – This bit enables an interrupt if the LOFL bit is set and the bit in

GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 3: Remote Alarm Indication Interrupt Enable (RDIIE) – This bit enables an interrupt if the RDIL bit is set and

the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 2: Alarm Indication Signal Interrupt Enable (AISIE) – This bit enables an interrupt if the AISL bit is set and

the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 1: Out Of Frame Interrupt Enable (OOFIE) – This bit enables an interrupt if the OOFL bit is set and the bit in

GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 0: Loss Of Signal Interrupt Enable (LOSIE) – This bit enables an interrupt if the LOSL bit is set and the bit in

GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

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Bit # 15 14 13 12 11 10 9 8

Name — — — — Reserved Reserved Reserved FEIE

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — — — Reserved Reserved Reserved FECIE

Default 0 0 0 0 0 0 0 0

Bit 8: Framing Error Interrupt Enable (FEIE) – This bit enables an interrupt if the FEL bit is set and the bit in

GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 0: Framing Error Count Interrupt Enable (FECIE) – This bit enables an interrupt if the FECL bit is set and the

bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit # 15 14 13 12 11 10 9 8

Name FE15 FE14 FE13 FE12 FE11 FE10 FE9 FE8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name FE7 FE6 FE5 FE4 FE3 FE2 FE1 FE0

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Framing Error Count (FE[15:0]) – These 16 bits indicate the number of framing error events on the

incoming E3 data stream. This register is updated via the PMU signal (see Section 10.4.5).

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12.10.5 Transmit G.832 E3 Register Map

The transmit G.832 E3 uses four registers.

Table 12-37. Transmit G.832 E3 Framer Register Map

ADDRESS REGISTER REGISTER DESCRIPTION

(1,3,5,7)18h E3G832.TCR E3 G.832 Transmit Control Register

(1,3,5,7)1Ah E3G832.TEIR E3 G.832 Transmit Error Insertion Register

(1,3,5,7)1Ch E3G832.TMABR E3 G.832 Transmit MA Byte Register

(1,3,5,7)1Eh E3G832.TNGBR E3 G.832 Transmit NR and GC Byte Register

12.10.5.1 Register Bit Descriptions

Bit # 15 14 13 12 11 10 9 8

Name Reserved — — Reserved Reserved TGCC TNRC1 TNRC0

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — TFEBE AFEBED TRDI ARDID TFGC TAIS

Default 0 0 0 0 0 0 0 0

Bit 10: Transmit GC Byte Control (TGCC) – When 0, the GC byte is inserted from the transmit HDLC controller.

When 1, the GC byte is inserted from the GC byte register.

Note: If bit TGCC is 0 and TNRC[1:0] is 01, both the GC byte and NR byte will carry the same transmit HDLC

controller (eight bits per frame period), however, the GC byte and NR byte in the same frame may or may not be

equal.

Bits 9 to 8: Transmit NR Byte Control (TNRC[1:0]) – These two bits control the source of the NR byte. Note: If

TNRC[1:0] is 01 and TGCC is 0, both the NR byte and GC byte will carry the same transmit HDLC controller (eight

bits per frame period), however, the NR byte and GC byte in the same frame may or may not be equal.

00 = all ones.

01 = transmit from the HDLC controller.

10 = transmit from the FEAC controller.

11 = NR byte register.

Bit 5: Transmit REI Error (TFEBE) – When automatic REI generation is defeated (AFEBED = 1), this bit is

inserted into the second bit of the MA byte.

Bit 4: Automatic REI Defeat (AFEBED) – When 0, the REI is automatically generated based upon the transmit

remote error indication (TREI) signal. When 1, the REI is inserted from the register bit TFEBE.

Bit 3: Transmit RDI Alarm (TRDI) – When automatic RDI generation is defeated (ARDID = 1), this bit is inserted

into the first bit of the MA byte.

Bit 2: Automatic RDI Defeat (ARDID) – When 0, the RDI is automatically generated based upon the received E3

alarms. When 1, the RDI is inserted from the register bit TRDI.

Bit 1: Transmit Frame Generation Control (TFGC) – When this bit is zero, the Transmit Frame Processor frame

generation is enabled. The E3 overhead positions in the incoming E3 payload will be overwritten with the internally

generated E3 overhead. When this bit is one, the Transmit Frame Processor frame generation is disabled. The E3

overhead positions in the incoming E3 payload will be passed through to error insertion. Note: The E3 overhead

periods can still be overwritten by overhead insertion.

Bit 0: Transmit Alarm Indication Signal (TAIS) – When 0, the normal signal is transmitted. When 1, the E3

output data stream is forced to all ones (AIS).

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Bit # 15 14 13 12 11 10 9 8

Name — — — — Reserved Reserved CFBEIE FBEI

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name PBEE CPEIE PEI FEIC1 FEIC0 FEI TSEI MEIMS

Default 0 0 0 0 0 0 0 0

Bit 9: Continuous Remote Error Indication Error Insertion Enable (CFBEIE) – When 0, single remote error

indication (REI) error insertion is enabled. When 1, continuous REI error insertion is enabled, and REI errors will be

transmitted continuously if FEBI is high.

Bit 8: Remote Error Indication Error Insertion Enable (FBEI) – When 0, REI error insertion is disabled. When 1,

REI error insertion is enabled.

Bit 7: Parity Block Error Enable (PBEE) – When 0, a parity error is generated by inverting a single bit in the EM

byte. When 1, a parity error is generated by inverting all eight bits in the EM byte.

Bit 6: Continuous Parity Error Insertion Enable (CPEIE) – When 0, single parity (BIP-8) error insertion is

enabled. When 1, continuous parity error insertion is enabled, and parity errors will be transmitted continuously if

PEI is high.

Bit 5: Parity Error Insertion Enable (PEI) – When 0, parity error insertion is disabled. When 1, parity error

insertion is enabled.

Bits 4 to 3: Framing Error Control (FEIC[1:0]) – These two bits control the framing error event to be inserted.

00 = single bit error in one frame.

01 = word error in one frame.

10 = single bit error in four consecutive frames.

11 = word error in four consecutive frames.

Bit 2: Framing Error Insertion Enable (FEI) – When 0, framing error insertion is disabled. When 1, framing error

insertion is enabled.

Bit 1: Transmit Single Error Insert (TSEI) – This bit causes an error of the enabled type(s) to be inserted in the

transmit data stream if manual error insertion is disabled (MEIMS = 0). A 0 to 1 transition causes a single error to

be inserted. For a second error to be inserted, this bit must be set to 0, and back to 1. Note: If MEIMS is low, and

this bit transitions more than once between error insertion opportunities, only one error will be inserted.

Bit 0: Manual Error Insert Mode Select (MEIMS) – When 0, error insertion is initiated by the TSEI register bit.

When 1, error insertion is initiated by the transmit manual error insertion signal (TMEI). Note: If TMEI or TSEI is

one, changing the state of this bit may cause an error to be inserted.

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Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name TPT2 TPT1 TPT0 TTIGD TTI3 TTI2 TTI1 TTI0

Default 0 0 0 0 0 0 0 0

Bits 7 to 5: Transmit Payload Type (TPT[2:0]) – These bits determines the value transmitted in the payload type

(third, fourth, and fifth bits in the MA byte).

Bit 4: Transmit Timing Source Indicator Bit Generation Disable (TTIGD) – When 0, the last three bits of the MA

byte (MA[6:8]) are generated from the four timing source indicator bits TTI[3:0]. When 1, TTI[3] is ignored and

TTI[2:0] are directly inserted into the last three bits of the MA byte.

Bits 3 to 0: Transmit Timing Source Indication (TTI[3:0]) – These four bits make up the timing source indicator

bits.

Bit # 15 14 13 12 11 10 9 8

Name TGC7 TGC6 TGC5 TGC4 TGC3 TGC2 TGC1 TGC0

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name TNR7 TNR6 TNR5 TNR4 TNR3 TNR2 TNR1 TNR0

Default 0 0 0 0 0 0 0 0

Bits 15 to 8: Transmit GC Byte (TGC[7:0]) – These eight bits are the GC byte to be inserted into the E3 frame.

Bits 7 to 0: Transmit NR Byte (TNR[7:0]) – These eight bits are the NR byte to be inserted into the E3 frame.

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12.10.6 Receive G.832 E3 Register Map

The receive G.832 E3 uses 13 registers.

Table 12-38. Receive G.832 E3 Framer Register Map

ADDRESS REGISTER REGISTER DESCRIPTION

(1,3,5,7)20h E3G832.RCR E3 G.832 Receive Control Register

(1,3,5,7)22h E3G832.RMACR E3 G.832 Receive MA Byte Control Register

(1,3,5,7)24h E3G832.RSR1 E3 G.832 Receive Status Register 1

(1,3,5,7)26h E3G832.RSR2 E3 G.832 Receive Status Register 2

(1,3,5,7)28h E3G832.RSRL1 E3 G.832 Receive Status Register Latched 1

(1,3,5,7)2Ah E3G751.RSRL2 E3 G.832 Receive Status Register Latched 2

(1,3,5,7)2Ch E3G832.RSRIE1 E3 G.832 Receive Status Register Interrupt Enable 1

(1,3,5,7)2Eh E3G832.RSRIE2 E3 G.832 Receive Status Register Interrupt Enable 2

(1,3,5,7)30h E3G832.RMABR E3 G.832 Receive MA Byte Register

(1,3,5,7)32h E3G832.RNGBR E3 G.832 Receive NR and GC Byte Register

(1,3,5,7)34h E3G832.RFECR E3 G.832 Receive Framing Error Count Register

(1,3,5,7)36h E3G832.RPECR E3 G.832 Receive Parity Error Count Register

(1,3,5,7)38h E3G832.RFBER E3 G.832 Receive Remote Error Indication Count Register

(1,3,5,7)3Ah — Reserved

(1,3,5,7)3Ch — Unused

(1,3,5,7)3Eh — Unused

12.10.6.1 Register Bit Descriptions

Bit # 15 14 13 12 11 10 9 8

Name Reserved PEC DLS MDAISI AAISD ECC FECC1 FECC0

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RDILE RDILD RDIOD RDIAD ROMD LIP1 LIP0 FRSYNC

Default 0 0 0 0 0 0 0 0

Bit 14: Parity Error Count (PEC) – When 0, BIP-8 block errors (EM byte) are detected (no more than one per

frame). When 1, BIP-8-bit errors are detected (up to 8 per frame).

Bit 13: Receive HDLC Data Link Source (DLS) – When 0, the receive HDLC data link will be sourced from the

GC byte. When 1, the receive HDLC data link will be sourced from the NR byte.

Bit 12: Manual Downstream AIS Insertion (MDAISI) – When 0, manual downstream AIS insertion is disabled.

When 1, manual downstream AIS insertion is enabled.

Bit 11: Automatic Downstream AIS Disable (AAISD) – When 0, the presence of an LOS, OOF, or AIS condition

will cause downstream AIS to be inserted. When 1, the presence of an LOS, OOF, or AIS condition will not cause

downstream AIS to be inserted.

Bit 10: Error Count Control (ECC) – When 0, framing errors, parity errors, and REI errors will not be counted if an

OOF or AIS condition is present. Parity errors and REI errors will also not be counted during the E3 frame in which

an OOF or AIS condition is terminated, and the next E3 frame. When 1, framing errors, parity errors, and REI

errors will be counted regardless of the presence of an OOF or AIS condition.

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Bits 9 to 8: Framing Error Count Control (FECC[1:0]) – These two bits control the type of framing error events

that are counted.

00 = count OOF occurrences (counted regardless of the setting of the ECC bit)..

01 = count each bit error in FA1 and FA2 (up to 16 per frame).

10 = count frame alignment word (FA1 and FA2) errors (up to one per frame).

11 = count FA1 byte errors and FA2 byte errors (up to 2 per frame).

Bit 7: Receive Defect Indication on LOF Enable (RDILE) – When 0, an LOF condition does not affect the receive

defect indication signal (RDI). When 1, an LOF condition will cause the transmit E3 RDI bit to be set to one if

transmit automatic RDI is enabled.

Bit 6: Receive Defect Indication on LOS Disable (RDILD) – When 0, an LOS condition will cause the transmit E3

RDI bit to be set to one if transmit automatic RDI is enabled. When 1, an LOS condition does not affect the RDI

signal.

Bit 5: Receive Defect Indication on OOF Disable (RDIOD) – When 0, an OOF condition will cause the transmit

E3 RDI bit to be set to one if transmit automatic RDI is enabled. When 1, an OOF condition does not affect the RDI

signal.

Bit 4: Receive Defect Indication on AIS Disable (RDIAD) – When 0, an AIS condition will cause the transmit E3

RDI bit to be set to one if transmit automatic RDI is enabled. When 1, an AIS condition does not affect the RDI

signal.

Bit 3: Receive Overhead Masking Disable (ROMD) – When 0, the E3 overhead positions in the outgoing E3

payload will be marked as overhead by RDENn. When 1, the E3 overhead positions in the outgoing E3 payload will

be marked as data by RDENn.

Bits 2 to 1: LOF Integration Period (LIP[1:0]) – These two bits determine the OOF integration period for

declaring LOF.

00 = OOF is integrated for 3 ms before declaring LOF.

01 = OOF is integrated for 2 ms before declaring LOF.

10 = OOF is integrated for 1 ms before declaring LOF.

11 = LOF is declared at the same time as OOF.

Bit 0: Force Framer Re-synchronization (FRSYNC) – A 0 to 1 transition forces. an OOF condition at the next

framing word check. This bit must be cleared and set to one again to force another re-synchronization.

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — — — EPT2 EPT1 EPT0 TIED

Default 0 0 0 0 0 0 0 0

Bits 3 to 1: Expected Payload Type (EPT[2:0]) – These three bits contain the expected value of the payload

type.

Bit 0: Timing Source Indicator Bit Extraction Disable (TIED) – When 0, the four timing source indications bits

are extracted from the last three bits of the MA byte (MA[6:8]), and stored in a register. When 1, timing source

indicator bit extraction is disabled, and the last three bits of the MA byte are integrated and stored in a register.

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Bit # 15 14 13 12 11 10 9 8

Name Reserved — — RPTU RPTM Reserved Reserved RUA1

Bit # 7 6 5 4 3 2 1 0

Name Reserved Reserved — LOF RAI AIS OOF LOS

Bit 12: Receive Payload Type Unstable (RPTU) – When 0, the receive payload type is stable. When 1, the

receive payload type is unstable.

Bit 11: Receive Payload Type Mismatch (RPTM) – When 0, the receive payload type and expected payload type

match. When 1, the receive payload type and expected payload type do not match.

Bit 8: Receive Unframed All 1’s (RUA1) – When 0, the receive frame processor is not in a receive unframed all

1’s (RUA1) condition. When 1, the receive frame processor is in an RUA1 condition.

Bit 4: Loss Of Frame (LOF) – When 0, the receive frame processor is not in a loss of frame (LOF) condition.

When 1, the receive frame processor is in an LOF condition.

Bit 3: Remote Defect Indication (RDI) – This bit indicates the current state of the remote defect indication (RDI).

Bit 2: Alarm Indication Signal (AIS) – When 0, the receive frame processor is not in an alarm indication signal

(AIS) condition. When 1, the receive frame processor is in an AIS condition.

Bit 1: Out Of Frame (OOF) – When 0, the receive frame processor is not in an out of frame (OOF) condition.

When 1, the receive frame processor is in an OOF condition.

Bit 0: Loss Of Signal (LOS) – When 0, the receive loss of signal (LOS) input (RLOS) is low. When 1, RLOS is

high.

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Bit # 7 6 5 4 3 2 1 0

Name — — — — Reserved FBEC PEC FEC

Bit 2: Remote Error Indication Count (FBEC) – When 0, the remote error indication count is zero. When 1, the

remote error indication count is one or more.

Bit 1: Parity Error Count (PEC) – When 0, the parity error count is zero. When 1, the parity error count is one or

more.

Bit 0: Framing Error Count (FEC) – When 0, the framing error count is zero. When 1, the framing error count is

one or more.

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Bit # 15 14 13 12 11 10 9 8

Name Reserved — TIL RPTUL RPTML RPTL Reserved RUA1L

Bit # 7 6 5 4 3 2 1 0

Name GCL NRL COFAL LOFL RDIL AISL OOFL LOSL

Bit 13: Timing Source Indication Change Latched (TIL) – This bit is set when the TI[3:0] bits change state.

Bit 12: Receive Payload Type Unstable Latched (RPTUL) – This bit is set when the RPTU bit transitions from

zero to one.

Bit 11: Receive Payload Type Mismatch Latched (RPTML) – This bit is set when the RPTM bit transitions from

zero to one.

Bit 10: Receive Payload Type Change Latched (RPTL) – This bit is set when the RPT[2:0] bits change state.

Bit 8: Receive Unframed All 1’s Change Latched (RUA1L) – This bit is set when the RUA1 bit changes state.

Bit 7: GC Byte Change Latched (GCL) – This bit is set when the RGC byte changes state.

Bit 6: NR Byte Change Latched (NRL) – This bit is set when the RNR byte changes state.

Bit 5: Change Of Frame Alignment Latched (COFAL) – This bit is set when the data path frame counters are

updated with a new frame alignment that is different from the previous frame alignment.

Bit 4: Loss Of Frame Change Latched (LOFL) – This bit is set when the LOF bit changes state.

Bit 3: Remote Defect Indication Change Latched (RDIL) – This bit is set when the RDI bit changes state.

Bit 2: Alarm Indication Signal Change Latched (AISL) – This bit is set when the AIS bit changes state.

Bit 1: Out Of Frame Change Latched (OOFL) – This bit is set when the OOF bit changes state.

Bit 0: Loss Of Signal Change Latched (LOSL) – This bit is set when the LOS bit changes state.

Bit # 15 14 13 12 11 10 9 8

Name — — — — Reserved FBEL PEL FEL

Bit # 7 6 5 4 3 2 1 0

Name — — — — Reserved FBECL PECL FECL

Bit 10: Remote Error Indication Latched (FBEL) – This bit is set when a remote error indication is detected.

Bit 9: Parity Error Latched (PEL) – This bit is set when a BIP-8 parity error is detected.

Bit 8: Framing Error Latched (FEL) – This bit is set when a framing error is detected.

Bit 2: Remote Error Indication Count Latched (FBECL) – This bit is set when the FBEC bit transitions from zero

to one.

Bit 1: Parity Error Count Latched (PECL) – This bit is set when the PEC bit transitions from zero to one.

Bit 0: Framing Error Count Latched (FECL) – This bit is set when the FEC bit transitions from zero to one.

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Bit # 15 14 13 12 11 10 9 8

Name Reserved — TIIE RPTUIE RPTMIE RPTIE Reserved RUA1IE

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name GCIE NRIE COFAIE LOFIE RAIIE AISIE OOFIE LOSIE

Default 0 0 0 0 0 0 0 0

Bit 13: Timing Indication Interrupt Enable (TIIE) – This bit enables an interrupt if the TIL bit is set and the bit in

GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 12: Receive Payload Type Unstable Interrupt Enable (RPTUIE) – This bit enables an interrupt if the RPTUL

bit is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 11: Receive Payload Type Mismatch Interrupt Enable (RPTMIE) – This bit enables an interrupt if the RPTML

bit is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 10: Receive Payload Type Interrupt Enable (RPTIE) – This bit enables an interrupt if the RPTL bit is set and

the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 8: Receive Unframed All 1’s Interrupt Enable (RUA1IE) – This bit enables an interrupt if the RUA1L bit is set

and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 7: GC Byte Interrupt Enable (GCIE) – This bit enables an interrupt if the GCL bit is set and the bit in

GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 6: NR Byte Interrupt Enable (NRIE) – This bit enables an interrupt if the NRL bit is set and the bit in

GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 5: Change Of Frame Alignment Interrupt Enable (COFAIE) – This bit enables an interrupt if the COFAL bit is

set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 4: Loss Of Frame Interrupt Enable (LOFIE) – This bit enables an interrupt if the LOFL bit is set and the bit in

GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

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Bit 3: Remote Defect Indication Interrupt Enable (RDIIE) – This bit enables an interrupt if the RDIL bit is set and

the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 2: Alarm Indication Signal Interrupt Enable (AISIE) – This bit enables an interrupt if the AISL bit is set and

the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 1: Out Of Frame Interrupt Enable (OOFIE) – This bit enables an interrupt if the OOFL bit is set and the bit in

GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 0: Loss Of Signal Interrupt Enable (LOSIE) – This bit enables an interrupt if the LOSL bit is set and the bit in

GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

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Bit # 15 14 13 12 11 10 9 8

Name — — — — Reserved FBEIE PEIE FEIE

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — — — Reserved FBECIE PECIE FECIE

Default 0 0 0 0 0 0 0 0

Bit 10: Remote Error Indication Interrupt Enable (FBEIE) – This bit enables an interrupt if the FBEL bit is set

and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 9: Parity Error Interrupt Enable (PEIE) – This bit enables an interrupt if the PEL bit is set and the bit in

GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 8: Framing Error Interrupt Enable (FEIE) – This bit enables an interrupt if the FEL bit is set and the bit in

GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 2: Remote Error Indication Count Interrupt Enable (FBECIE) – This bit enables an interrupt if the FBECL bit

is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 1: Parity Error Count Interrupt Enable (PECIE) – This bit enables an interrupt if the PECL bit is set and the

bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 0: Framing Error Count Interrupt Enable (FECIE) – This bit enables an interrupt if the FECL bit is set and the

bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

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Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — RPT2 RPT1 RPT0 TI3 TI2 TI1 TI0

Default 0 0 0 0 0 0 0 0

Bits 6 to 4: Receive Payload Type (RPT[2:0]) – These three bits are the integrated version of the payload type

(MA[3:5]) from the MA byte.

Bits 3 to 0: Receive Timing Source Indication (TI[3:0]) – When timing source indicator extraction is enabled,

these four bits are the integrated version of the four timing source indicator bits extracted from the last three bits of

the MA byte (MA[6:8]). When timing source indicator bit extraction is disabled, TI[3] is zero, and TI[2:0] contain the

integrated version of the last three bits of the MA byte.

Bit # 15 14 13 12 11 10 9 8

Name RGC7 RGC6 RGC5 RGC4 RGC3 RGC2 RGC1 RGC0

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RNR7 RNR6 RNR5 RNR4 RNR3 RNR2 RNR1 RNR0

Default 0 0 0 0 0 0 0 0

Bits 15 to 8: Receive GC Byte (RGC[7:0]) – These eight bits are the integrated version of the GC byte as

extracted from the E3 frame.

Bits 7 to 0: Receive NR Byte (RNR[7:0]) – These eight bits are the integrated version of the NR byte as extracted

from the E3 frame.

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Bit # 15 14 13 12 11 10 9 8

Name FE15 FE14 FE13 FE12 FE11 FE10 FE9 FE8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name FE7 FE6 FE5 FE4 FE3 FE2 FE1 FE0

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Framing Error Count (FE[15:0]) – These 16 bits indicate the number of framing error events on the

incoming E3 data stream. This register is updated via the PMU signal (see Section 10.4.5).

Bit # 15 14 13 12 11 10 9 8

Name PE15 PE14 PE13 PE12 PE11 PE10 PE9 PE8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name PE7 PE6 PE5 PE4 PE3 PE2 PE1 PE0

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Parity Error Count (PE[15:0]) – These 16 bits indicate the number of parity (BIP-8) errors detected

on the incoming E3 data stream. This register is updated via the PMU signal (see Section 10.4.5).

Bit # 15 14 13 12 11 10 9 8

Name FBE15 FBE14 FBE13 FBE12 FBE11 FBE10 FBE9 FBE8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name FBE7 FBE6 FBE5 FBE4 FBE3 FBE2 FBE1 FBE0

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Remote Error Indication Count (FBE[15:0]) – These 16 bits indicate the number of remote error

indications detected on the incoming E3 data stream. This register is updated via the PMU signal (see Section

10.4.5).

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12.10.7 Transmit Clear Channel

The transmit clear-channel mode uses one register.

12.10.7.1 Register Map

Table 12-39. Transmit Clear-Channel Register Map

ADDRESS REGISTER REGISTER DESCRIPTION

(1,3,5,7)18h CC.TCR Clear-Channel Transmit Control Register

(1,3,5,7)1Ah — Reserved

(1,3,5,7)1Ch — Reserved

(1,3,5,7)1Eh — Reserved

12.10.7.2 Register Bit Descriptions

Bit # 15 14 13 12 11 10 9 8

Name Reserved — — Reserved Reserved Reserved Reserved Reserved

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — Reserved Reserved Reserved Reserved Reserved TAIS

Default 0 0 0 0 0 0 0 0

Bit 0: Transmit Alarm Indication Signal (TAIS) – When 0, the normal signal is transmitted. When 1, the output

clear-channel data stream is forced to all ones (AIS). Note: This bit is logically ORed with the TAIS input signal.

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12.10.8 Receive Clear Channel

The receive clear-channel mode uses four registers.

12.10.8.1 Register Map

Table 12-40. Receive Clear-Channel Register Map

ADDRESS REGISTER REGISTER DESCRIPTION

(1,3,5,7)20h CC.RCR Clear-Channel Receive Control Register

(1,3,5,7)22h — Reserved

(1,3,5,7)24h CC.RSR1 Clear-Channel Receive Status Register 1

(1,3,5,7)26h — Reserved

(1,3,5,7)28h CC.RSRL1 Clear-Channel Receive Status Register Latched 1

(1,3,5,7)2Ah — Reserved

(1,3,5,7)2Ch CC.RSRIE1 Clear-Channel Receive Status Register Interrupt Enable 1

(1,3,5,7)2Eh — Reserved

(1,3,5,7)30h — Reserved

(1,3,5,7)32h — Reserved

(1,3,5,7)34h — Reserved

(1,3,5,7)36h — Reserved

(1,3,5,7)38h — Reserved

(1,3,5,7)3Ah — Reserved

(1,3,5,7)3Ch — Unused

(1,3,5,7)3Eh — Unused

12.10.8.2 Register Bit Descriptions

Bit # 15 14 13 12 11 10 9 8

Name Reserved Reserved Reserved MDAISI AAISD Reserved Reserved Reserved

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved

Default 0 0 0 0 0 0 0 0

Bit 12: Manual Downstream AIS Insertion (MDAISI) – When 0, manual downstream AIS insertion is disabled.

When 1, manual downstream AIS insertion is enabled.

Bit 11: Automatic Downstream AIS Disable (AAISD) – When 0, the presence of a LOS condition will cause

downstream AIS to be inserted. When 1, the presence of a LOS condition will not cause downstream AIS to be

inserted.

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Bit # 15 14 13 12 11 10 9 8

Name Reserved Reserved — Reserved Reserved Reserved Reserved RUA1

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name Reserved Reserved — Reserved Reserved Reserved Reserved LOS

Default 0 0 0 0 0 0 0 0

Bit 8: Receive Unframed All 1’s (RUA1) – When 0, the receive frame processor is not in a receive unframed all

1’s (RUA1) condition. When 1, the receive frame processor is in an RUA1 condition.

Bit 0: Loss Of Signal (LOS) – When 0, the receive loss of signal (LOS) input (RLOS) is low. When 1, RLOS is

high.

Bit # 15 14 13 12 11 10 9 8

Name Reserved Reserved Reserved Reserved Reserved Reserved Reserved RUA1L

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name Reserved Reserved Reserved Reserved Reserved Reserved Reserved LOSL

Default 0 0 0 0 0 0 0 0

Bit 8: Receive Unframed All 1’s Latched (RUA1L) – This bit is set when the RUA1 bit changes state.

Bit 0: Loss Of Signal Change Latched (LOSL) – This bit is set when the LOS bit changes state.

Bit # 15 14 13 12 11 10 9 8

Name Reserved Reserved Reserved Reserved Reserved Reserved Reserved RUA1IE

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name Reserved Reserved Reserved Reserved Reserved Reserved Reserved LOSIE

Default 0 0 0 0 0 0 0 0

Bit 8: Receive Unframed All 1’s Interrupt Enable (RUA1IE) – This bit enables an interrupt if the RUA1L bit is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 0: Loss Of Signal Interrupt Enable (LOSIE) – This bit enables an interrupt if the LOSL bit is set.

0 = interrupt disabled

1 = interrupt enabled

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12.11 Fractional DS3/E3

12.11.1 Fractional Transmit Side Register Map

The transmit side uses three registers.

Table 12-41. Fractional Transmit Side Register Map

ADDRESS REGISTER REGISTER DESCRIPTION

(1,3,5,7)40h FRAC.TCR Fractional Transmit Control Register

(1,3,5,7)42h FRAC.TDGSR Fractional Transmit Data Group Size Register

(1,3,5,7)44h FRAC.TSASR Fractional Transmit Section A Size Register

(1,3,5,7)46h — Unused

12.11.1.1 Register Bit Descriptions

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — — — — TFOSC1 TFOSC0 TSASS

Default 0 0 0 0 0 0 0 0

Bits 2 to 1: Transmit Fractional Overhead Source Control (TFOSC[1:0]) – These two bits control the source of

the transmit fractional overhead.

00 = all zeros.

01 = all ones.

10 = 1010 pattern.

11 = external (TFOH).

Bit 0: Transmit Section A Source Select (TSASS)

0 = Section A contains fractional overhead

1 = Section A contains payload data

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Bit # 15 14 13 12 11 10 9 8

Name — — — TDGS12 TDGS11 TDGS10 TDGS9 TDGS8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name TDGS7 TDGS6 TDGS5 TDGS4 TDGS3 TDGS2 TDGS1 TDGS0

Default 0 0 0 0 0 0 0 0

Bits 12 to 0: Transmit Data Group Size (TDGS[12:0]) – These 13 bits indicate the number of bits contained

within each transmit data group. A values of 0000h and 0001h both result in a transmit data group size of one bit.

Bit # 15 14 13 12 11 10 9 8

Name — — — TSAS12 TSAS11 TSAS10 TSAS9 TSAS8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name TSAS7 TSAS6 TSAS5 TSAS4 TSAS3 TSAS2 TSAS1 TSAS0

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Transmit Section A Size (TSAS[12:0]) – These 13 bits indicate the number of bits contained within

Section A of each transmit data group. If TSAS[12:0] is equal to or greater than the data group size

(TDGSR.TDGS[12:0]), only “Section A” data will be transmitted.

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12.11.2 Fractional Receive Side Register Map

The receive side uses three registers.

Table 12-42. Receive Side Register Map

ADDRESS REGISTER REGISTER DESCRIPTION

(1,3,5,7)48h FRAC.RCR Fractional Receive Control Register

(1,3,5,7)4Ah FRAC.RDGSR Fractional Receive Data Group Size Register

(1,3,5,7)4Ch FRAC.RSASR Fractional Receive Section A Size Register

(1,3,5,7)4Eh — Unused

12.11.2.1 Register Bit Descriptions

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — — — — — — RSASS

Default 0 0 0 0 0 0 0 0

Bit 0: Receive Section A Source Select (RSASS) – When 0, Section A of each receive data group will contain

fractional overhead. When 1, Section A of each receive data group will contain payload data.

Bit # 15 14 13 12 11 10 9 8

Name — — — RDGS12 RDGS11 RDGS10 RDGS9 RDGS8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RDGS7 RDGS6 RDGS5 RDGS4 RDGS3 RDGS2 RDGS1 RDGS0

Default 0 0 0 0 0 0 0 0

Bits 12 to 0: Receive Data Group Size (RDGS[12:0]) – These 13 bits indicate the number of bits contained within

each receive data group. A values of 0000h and 0001h both result in a receive data group size of one bit.

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Bit # 15 14 13 12 11 10 9 8

Name — — — RSAS12 RSAS11 RSAS10 RSAS9 RSAS8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RSAS7 RSAS6 RSAS5 RSAS4 RSAS3 RSAS2 RSAS1 RSAS0

Default 0 0 0 0 0 0 0 0

Bits 12 to 0: Receive Section A Size (RSAS[12:0]) – These 13 bits indicate the number of bits contained within

Section A of each receive data group. If RSAS[12:0] is equal to or greater than the data group size

(FRAC.RDGSR.RDGS[12:0]), all data will be marked as “Section A” data.

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12.12 DS3/E3 PLCP

12.12.1 Transmit Side PLCP

The transmit side uses seven registers.

12.12.1.1 Register Map

Table 12-43. Transmit Side PLCP Register Map

ADDRESS REGISTER REGISTER DESCRIPTION

(1,3,5,7)50h PLCP.TCR PLCP Transmit Control Register

(1,3,5,7)52h PLCP.TEIR PLCP Transmit Error Insertion Register

(1,3,5,7)54h PLCP.TFGBR PLCP Transmit F1 and G1 Byte Register

(1,3,5,7)56h PLCP.TM12BR PLCP Transmit M1 and M2 Byte Register

(1,3,5,7)58h PLCP.TZ12BR PLCP Transmit Z1 and Z2 Byte Register

(1,3,5,7)5Ah PLCP.TZ34BR PLCP Transmit Z3 and Z4 Byte Register

(1,3,5,7)5Ch PLCP.TZ56BR PLCP Transmit Z5 and Z6 Byte Register

(1,3,5,7)5Eh — Unused

12.12.1.2 Register Bit Descriptions

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — — TMC1 TMC0 TF1C1 TF1C0 AREID

Default 0 0 0 0 0 0 0 0

Bits 4 to 3: Transmit M2 and M1 Byte Control (TMC[1:0]) – These two bits control the source of the transmit M2

and M1 bytes.

00 = concatenated M1 and M2 (128 kHz) from transmit HDLC controller.

01 = M2 (64kHz) from transmit HDLC controller; M1 from M1 byte register (PLCP.TM12BR).

10 = M2 from M2 byte register; M1 (64 kHz) from transmit HDLC controller.

11 = M2 from M2 byte register; M1 from M1 byte register

Bits 2 to 1: Transmit F1 Byte Control (TF1C[1:0]) – These two bits control the source of the transmit F1 byte.

00 = transmit Trail Trace controller.

01 = transmit HDLC controller.

10 = F1 byte register (PLCP.TFGBR).

11 = reserved

Note: If TMC[1:0] is 00 and TF1C[1:0] is 01, the F1 byte will be invalid. If TMC[1:0] is 01 and TF1C[1:0] is 01, both

M2 and F1 will carry the transmit HDLC data link. If TMC[1:0] is 10 and TF1C[1:0] is 01, both M1 and F1 will carry

the transmit HDLC data link. When F1 and M# both carry the transmit HDLC data link, the F1 byte and M# byte in

the same frame may or may not be equal.

Bit 0: Automatic REI Defeat (AREID) – When 0, the REI is automatically generated based upon the parity (BIP-8)

errors detected in the receive PLCP Frame Processor. When 1, the REI is inserted from the G1 register bits

TREI[3:0].

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Bit # 15 14 13 12 11 10 9 8

Name — — REIME CREIIE REIEI PBEE CPEIE PEI

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — FEE FEIC1 FEIC0 FEI TSEI MEIMS

Default 0 0 0 0 0 0 0 0

Bit 13: Remote Error Indication Maximum Error (REIME) – When 0, an REI error is generated by inserting a

value of 1h (single error) into the REI bits (G1[1:4]). When 1, an REI error is generated by inserting a value of 8h

(eight errors) into the REI bits.

Bit 12: Continuous Remote Error Indication Error Insertion Enable (CREIIE) – When 0, single remote error

indication (REI) error insertion is enabled. When 1, continuous REI error insertion is enabled, and REI errors will be

continuously transmitted if REIEI is high.

Bit 11: Remote Error Indication Error Insertion Enable (REIEI) – When 0, REI error insertion is disabled. When

1, REI error insertion is enabled.

Bit 10: Parity Block Error Enable (PBEE) – When 0, a parity error is generated by inverting a single bit in the B1

byte. When 1, a parity error is generated by inverting all eight bits in the B1 byte.

Bit 9: Continuous Parity Error Insertion Enable (CPEIE) – When 0, single parity (BIP-8) error insertion is

enabled. When 1, continuous parity error insertion is enabled, and parity errors will be transmitted continuously if

PEI is high.

Bit 8: Parity Error Insertion Enable (PEI) – When 0, parity (BIP-8) error insertion is disabled. When 1, parity (BIP-

8) error insertion is enabled.

Bit 5: Framing Byte Error Enable (FEE) – When 0, a framing bit error is generated by inverting a single bit in the

indicated byte. When 1, a framing byte error is generated by inverting all eight bits of the indicated byte.

Bits 4 to 3: Framing Error Control (FEIC[1:0]) – These two bits control the type of framing error event to be

inserted.

00 = single A1 or A2 error (1 per sub-frame maximum).

01 = single POI (P#) error (1 per 2 sub-frames maximum).

10 = both an A1 and an A2 error in the same sub-frame.

11 = two POI (P#) errors in consecutive sub-frames.

Bit 2: Framing Error Insertion Enable (FEI) – When 0, framing error insertion is disabled. When 1, framing error

insertion is enabled.

Bit 1: Transmit Single Error Insert (TSEI) – This bit causes an error of the enabled type(s) to be inserted in the

transmit data stream if manual error insertion is disabled (MEIMS = 0). A 0 to 1 transition causes a single error to

be inserted. For a second error to be inserted, this bit must be set to 0, and back to 1. Note: If MEIMS is low, and

this bit transitions more than once between error insertion opportunities, only one error will be inserted.

Bit 0: Manual Error Insert Mode Select (MEIMS) – When 0, error insertion is initiated by the TSEI register bit.

When 1, error insertion is initiated by the transmit manual error insertion signal (TMEI). Note: If TMEI or TSEI is

one, changing the state of this bit may cause an error to be inserted.

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Bit # 15 14 13 12 11 10 9 8

Name TF17 TF16 TF15 TF14 TF13 TF12 TF11 TF10

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name TREI3 TREI2 TREI1 TREI0 TRAI TLSS2 TLSS1 TLSS0

Default 0 0 0 0 0 0 0 0

Bits 15 to 8: Transmit F1 Byte (TF1[7:0]) – These eight bits are the F1 byte to be inserted into the transmit PLCP

frame.

Bits 7 to 4: Transmit REI Setting (TREI[3:0]) – When automatic REI generation is defeated (PLCP.TCR.AREID =

0), these bits are inserted into the REI bits (G1[1:4]).

Bit 3: Transmit RAI Setting (TRAI) –This bit is inserted into the RAI bits (G1[5]).

Bits 2 to 0: Transmit Link Status Signal (TLSS[2:0]) – These three bits are the transmit link status signal

(G1[6:8]) to be inserted into the transmit PLCP frame.

Bit # 15 14 13 12 11 10 9 8

Name TM27 TM26 TM25 TM24 TM23 TM22 TM21 TM20

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name TM17 TM16 TM15 TM14 TM13 TM12 TM11 TM10

Default 0 0 0 0 0 0 0 0

Bits 15 to 8: Transmit M2 Byte (TM2[7:0]) – These eight bits are the M2 byte to be inserted into the transmit

PLCP frame.

Bits 7 to 0: Transmit M1 Byte (TM1[7:0]) – These eight bits are the M1 byte to be inserted into the transmit PLCP

frame.

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Bit # 15 14 13 12 11 10 9 8

Name TZ27 TZ26 TZ25 TZ24 TZ23 TZ22 TZ21 TZ20

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name TZ17 TZ16 TZ15 TZ14 TZ13 TZ12 TZ11 TZ10

Default 0 0 0 0 0 0 0 0

Bits 15 to 8: Transmit Z2 Byte (TZ2[7:0]) – These eight bits are the Z2 byte to be inserted into the transmit PLCP

frame.

Bits 7 to 0: Transmit Z1 Byte (TZ1[7:0]) – These eight bits are the Z1 byte to be inserted into the transmit PLCP

frame.

Bit # 15 14 13 12 11 10 9 8

Name TZ47 TZ46 TZ45 TZ44 TZ43 TZ42 TZ41 TZ40

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name TZ37 TZ36 TZ35 TZ34 TZ33 TZ32 TZ31 TZ30

Default 0 0 0 0 0 0 0 0

Bits 15 to 8: Transmit Z4 Byte (TZ4[7:0]) – These eight bits are the Z4 byte to be inserted into the transmit PLCP

frame (This bits are unused in E3 mode).

Bits 7 to 0: Transmit Z3 Byte (TZ3[7:0]) – These eight bits are the Z3 byte to be inserted into the transmit PLCP

frame.

Bit # 15 14 13 12 11 10 9 8

Name TZ67 TZ66 TZ65 TZ64 TZ63 TZ62 TZ61 TZ60

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name TZ57 TZ56 TZ55 TZ54 TZ53 TZ52 TZ51 TZ50

Default 0 0 0 0 0 0 0 0

Bits 15 to 8: Transmit Z6 Byte (TZ6[7:0]) – These eight bits are the Z6 byte to be inserted into the transmit PLCP

frame (This bits are unused in E3 mode).

Bits 7 to 0: Transmit Z5 Byte (TZ5[7:0]) – These eight bits are the Z5 byte to be inserted into the transmit PLCP

frame (This bits are unused in E3 mode).

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12.12.2 Receive Side PLCP Register Map

The receive side uses 13 registers.

Table 12-44. Receive Side PLCP Register Map

ADDRESS REGISTER REGISTER DESCRIPTION

(1,3,5,7)60h PLCP.RCR PLCP Receive Control Register

(1,3,5,7)62h — Unused

(1,3,5,7)64h PLCP.RSR1 PLCP Receive Status Register 1

(1,3,5,7)66h PLCP.RSR2 PLCP Receive Status Register 2

(1,3,5,7)68h PLCP.RSRL1 PLCP Receive Status Register Latched 1

(1,3,5,7)6Ah PLCP.RSRL2 PLCP Receive Status Register Latched 2

(1,3,5,7)6Ch PLCP.RSRIE1 PLCP Receive Status Register Interrupt Enable 1

(1,3,5,7)6Eh PLCP.RSRIE2 PLCP Receive Status Register Interrupt Enable 2

(1,3,5,7)70h PLCP.RFECR PLCP Receive Framing Error Count Register

(1,3,5,7)72h PLCP.RPECR PLCP Receive P-Bit Parity Error Count Register

(1,3,5,7)74h PLCP.RREICR PLCP Receive Remote Error Indication Count Register

(1,3,5,7)76h PLCP.RFGBR PLCP Receive F1 and G1 Byte Register

(1,3,5,7)78h PLCP.RM12BR PLCP Receive M1 and M2 Byte Register

(1,3,5,7)7Ah PLCP.RZ12BR PLCP Receive Z1 and Z2 Byte Register

(1,3,5,7)7Ch PLCP.RZ34BR PLCP Receive Z3 and Z4 Byte Register

(1,3,5,7)7Eh PLCP.RZ56BR PLCP Receive Z5 and Z6 Byte Register

12.12.2.1 Register Bit Descriptions

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — RHSC1 RHSC0

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — RLIE — PECC FEPD FECC ECC FRSYNC

Default 0 0 0 0 0 0 0 0

Bits 9 to 8: Receive HDLC Source Control (RHSC[1:0]) – These two bits control the source of the receive HDLC

controller.

00 = F1 byte.

01 = M1 byte.

10 = M2 byte.

11 = M2 and M1 byte.

Bit 6: Receive LOF Integration Enable (RLIE) – When 0, the receive Loss Of Frame (LOF) integration counter is

disabled. When 1, the receive LOF integration counter is enabled.

Bit 4: Parity Error Count Control (PECC) – When 0, BIP-8 (B1 byte) bit errors are detected (up to 8 per frame).

When 1, BIP-8 block errors are detected (no more than one per frame). Note: The transmit REI bits are affected by

the setting of this bit as the REI bits reflect the number of BIP-8 errors detected/counted.

Bit 3: Framing Error POI Disable (FEPD) – When 0, Path Overhead Indicator (POI) byte (P#) and framing

alignment byte (A1 & A2) errors are detected. When 1, only A1 & A2 errors are detected. Note: This bit is ignored

when OOF events are counted (FECC=1)

Bit 2: Framing Error Count Control (FECC) – This bit controls the type of framing error events that are counted.

When 0, A1 byte errors, A2 byte errors, and P# byte errors (up to 3 per sub-frame) are counted. When 1, OOF

events are counted.

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Bit 1: Error Count Control (ECC) – When 0, framing errors, BIP-8 parity errors, and REI errors will not be counted

during an OOF condition (BIP-8 parity error counting will resume in the second full frame after an OOF condition is

cleared). When 1, framing errors, BIP-8 parity errors, and REI errors will be counted during an OOF condition.

Bit 0: Force Framer Re-synchronization (FRSYNC) – A 0 to 1 transition forces the framer into the “Search state.

Once the framer acquires lock, the data path frame counters will be updated regardless of whether an OOF

condition exists or not. The bit must be cleared and set to one again to force another re-synchronization

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — LOF

Bit # 7 6 5 4 3 2 1 0

Name — — REIC PEC FEC RAI — OOF

Bit 8: Loss Of Frame (LOF) – When 0, the receive line interface is not in a loss of frame (LOF) condition. When 1,

the receive line interface is in an LOF condition.

Bit 5: Remote Error Indication Count (REIC) – When 0, the remote error indication count is zero. When 1, the

remote error indication count is one or more.

Bit 4: Parity Error Count (PEC) – When 0, the parity error count is zero. When 1, the parity error count is one or

more.

Bit 3: Framing Error Count (FEC) – When 0, the framing error count is zero. When 1, the framing error count is

one or more.

Bit 2: Remote Alarm Indication (RAI) – This bit indicates the current state of the remote alarm indication (RAI),

which is the fifth bit of the G1 byte (G1[5]).

Bit 0: Out Of Frame (OOF) – When 0, the receive frame processor is not in an out of frame (OOF) condition.

When 1, the receive frame processor is in an OOF condition.

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Bit # 7 6 5 4 3 2 1 0

Name — — — — — — — LSSU

Bit 0: Receive Link Status Signal Unstable (LSSU) – When 0, the receive link states signal is stable. When 1,

the receive link states signal is unstable.

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Bit # 15 14 13 12 11 10 9 8

Name — — REIL PEL FEL — — LOFL

Bit # 7 6 5 4 3 2 1 0

Name — — REICL PECL FECL RAIL COFAL OOFL

Bit 13: Remote Error Indication Latched (REIL) – This bit is set when a far-end block error is detected.

Bit 12: Parity Error Latched (PEL) – This bit is set when a BIP-8 parity error is detected.

Bit 11: Framing Error Latched (FEL) – This bit is set when a framing error is detected.

Bit 8: Loss Of Frame Change Latched (LOFL) – This bit is set when the LOF bit changes state.

Bit 5: Remote Error Indication Count Latched (REICL) – This bit is set when the REIC bit transitions from zero

to one.

Bit 4: Parity Error Count Latched (PECL) – This bit is set when the PEC bit transitions from zero to one.

Bit 3: Framing Error Count Latched (FECL) – This bit is set when the FEC bit transitions from zero to one.

Bit 2: Remote Defect Indication Change Latched (RAIL) – This bit is set when the RAI bit changes state.

Bit 1: Change Of Frame Alignment Latched (COFAL) – This bit is set when the data path frame counters are

updated with a new frame alignment that is different from the previous frame alignment.

Bit 0: Out Of Frame Change Latched (OOFL) – This bit is set when the OOF bit changes state.

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Bit # 15 14 13 12 11 10 9 8

Name — — — — — RZ6L RZ5L RZ4L

Bit # 7 6 5 4 3 2 1 0

Name RZ3L RZ2L RZ1L RM2L RM1L RF1L LSSL LSSUL

Bit 10: Receive Z6 Byte Change Latched (RZ6L) – This bit is set when the RZ6[7:0] bits change state (This bit is

zero in E3 mode).

Bit 9: Receive Z5 Byte Change Latched (RZ5L) – This bit is set when the RZ5[7:0] bits change state (This bit is

zero in E3 mode).

Bit 8: Receive Z4 Byte Change Latched (RZ4L) – This bit is set when the RZ4[7:0] bits change state (This bit is

zero in E3 mode).

Bit 7: Receive Z3 Byte Change Latched (RZ3L) – This bit is set when the RZ3[7:0] bits change state.

Bit 6: Receive Z2 Byte Change Latched (RZ2L) – This bit is set when the RZ2[7:0] bits change state.

Bit 5: Receive Z1 Byte Change Latched (RZ1L) – This bit is set when the RZ1[7:0] bits change state.

Bit 4: Receive M2 Byte Change Latched (RM2L) – This bit is set when the RM2[7:0] bits change state.

Bit 3: Receive M1 Byte Change Latched (RM1L) – This bit is set when the RM1[7:0] bits change state.

Bit 2: Receive F1 Byte Change Latched (RF1L) – This bit is set when the RF1[7:0] bits change state.

Bit 1: Receive Link Status Signal Change Latched (LSSL) – This bit is set when the LSS[2:0] bits change state.

Bit 0: Receive Link Status Signal Unstable Change Latched (LSSUL) – This bit is set when the LSSU bit

changes state.

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Bit # 15 14 13 12 11 10 9 8

Name — — REIIE PEIE FEIE — — LOFIE

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — REICIE PECIE FECIE RAIIE COFAIE OOFIE

Default 0 0 0 0 0 0 0 0

Bit 13: Remote Error Indication Interrupt Enable (REIIE) – This bit enables an interrupt if the REIL bit is set and

the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 12: Parity Error Interrupt Enable (PEIE) – This bit enables an interrupt if the PEL bit is set and the bit in

GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 11: Framing Error Interrupt Enable (FEIE) – This bit enables an interrupt if the FEL bit is set and the bit in

GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 8: Loss Of Frame Interrupt Enable (LOFIE) – This bit enables an interrupt if the LOFL bit is set and the bit in

GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 5: Remote Error Indication Count Interrupt Enable (REICIE) – This bit enables an interrupt if the REICL bit

is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 4: Parity Error Count Interrupt Enable (PECIE) – This bit enables an interrupt if the PECL bit is set and the

bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 3: Framing Error Count Interrupt Enable (FECIE) – This bit enables an interrupt if the FECL bit is set and the

bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 2: Remote Defect Indication Interrupt Enable (RAIIE) – This bit enables an interrupt if the RAIL bit is set and

the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 1: Change Of Frame Alignment Interrupt Enable (COFAIE) – This bit enables an interrupt if the COFAL bit is

set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

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Bit 0: Out Of Frame Interrupt Enable (OOFIE) – This bit enables an interrupt if the OOFL bit is set and the bit in

GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

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Bit # 15 14 13 12 11 10 9 8

Name — — — — — RZ6IE RZ5IE RZ4IE

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RZ3IE RZ2IE RZ1IE RM2IE RM1IE RF1IE LSSIE LSSUIE

Default 0 0 0 0 0 0 0 0

Bit 10: Receive Z6 Byte Interrupt Enable (RZ6IE) – This bit enables an interrupt if the RZ6L bit is set and the bit

in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set. (This bit is unused in E3 mode).

0 = interrupt disabled

1 = interrupt enabled

Bit 9: Receive Z5 Byte Interrupt Enable (RZ5IE) – This bit enables an interrupt if the RZ5L bit is set and the bit in

GL.ISRIE.PSRIE[4:1] that corresponds to this port is set. (This bit is unused in E3 mode).

0 = interrupt disabled

1 = interrupt enabled

Bit 8: Receive Z4 Byte Interrupt Enable (RZ4IE) – This bit enables an interrupt if the RZ4L bit is set and the bit in

GL.ISRIE.PSRIE[4:1] that corresponds to this port is set. (This bit is unused in E3 mode).

0 = interrupt disabled

1 = interrupt enabled

Bit 7: Receive Z3 Byte Interrupt Enable (RZ3IE) – This bit enables an interrupt if the RZ3L bit is set and the bit in

GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 6: Receive Z2 Byte Interrupt Enable (RZ2IE) – This bit enables an interrupt if the RZ2L bit is set and the bit in

GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 5: Receive Z1 Byte Interrupt Enable (RZ1IE) – This bit enables an interrupt if the RZ1L bit is set and the bit in

GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 4: Receive M2 Byte Interrupt Enable (RM2IE) – This bit enables an interrupt if the RM2L bit is set and the bit

in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 3: Receive M1 Byte Interrupt Enable (RM1IE) – This bit enables an interrupt if the RM1L bit is set and the bit

in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 2: Receive F1 Byte Interrupt Enable (RF1IE) – This bit enables an interrupt if the RF1L bit is set and the bit in

GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

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Bit 1: Receive Link Status Signal Interrupt Enable (LSSIE) – This bit enables an interrupt if the LSSL bit is set

and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 0: Receive Link Status Signal Unstable Interrupt Enable (LSSUIE) – This bit enables an interrupt if the

LSSUL bit is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

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Bit # 15 14 13 12 11 10 9 8

Name FE15 FE14 FE13 FE12 FE11 FE10 FE9 FE8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name FE7 FE6 FE5 FE4 FE3 FE2 FE1 FE0

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Framing Error Count (FE[15:0]) – These 16 bits indicate the number of framing error events on the

incoming PLCP data stream. This register is updated via the PMU signal (see Section 10.4.5).

Bit # 15 14 13 12 11 10 9 8

Name PE15 PE14 PE13 PE12 PE11 PE10 PE9 PE8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name PE7 PE6 PE5 PE4 PE3 PE2 PE1 PE0

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Parity Error Count (PE[15:0]) – These 16 bits indicate the number of parity (BIP-8) errors detected

on the incoming PLCP data stream. This register is updated via the PMU signal (see Section 10.4.5).

Bit # 15 14 13 12 11 10 9 8

Name REI15 REI14 REI13 REI12 REI11 REI10 REI9 REI8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name REI7 REI6 REI5 REI4 REI3 REI2 REI1 REI0

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Remote Error Indication Count (REI[15:0]) – These 16 bits indicate the number of remote error

indication errors detected on the incoming PLCP data stream. This register is updated via the PMU signal (see

Section 10.4.5).

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Bit # 15 14 13 12 11 10 9 8

Name RF17 RF16 RF15 RF14 RF13 RF12 RF11 RF10

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — — — — LSS2 LSS1 LSS0

Default 0 0 0 0 0 0 0 0

Bits 15 to 8: Receive F1 Byte (RF1[7:0]) – These eight bits are the integrated version of the F1 byte as extracted

from the receive PLCP frame.

Bits 2 to 0: Receive Link Status Signal (LSS[2:0]) – These three bits are the integrated version of the receive

link status signal (G1[6:8]) as extracted from the receive PLCP frame.

Bit # 15 14 13 12 11 10 9 8

Name RM27 RM26 RM25 RM24 RM23 RM22 RM21 RM20

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RM17 RM16 RM15 RM14 RM13 RM12 RM11 RM10

Default 0 0 0 0 0 0 0 0

Bits 15 to 8: Receive M2 Byte (RM2[7:0]) – These eight bits are the integrated version of the M2 byte as

extracted from the receive PLCP frame.

Bits 7 to 0: Receive M1 Byte (RM1[7:0]) – These eight bits are the integrated version of the M1 byte as extracted

from the receive PLCP frame.

Bit # 15 14 13 12 11 10 9 8

Name RZ27 RZ26 RZ25 RZ24 RZ23 RZ22 RZ21 RZ20

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RZ17 RZ16 RZ15 RZ14 RZ13 RZ12 RZ11 RZ10

Default 0 0 0 0 0 0 0 0

Bits 15 to 8: Receive Z2 Byte (RZ2[7:0]) – These eight bits are the integrated version of the Z2 byte as extracted

from the receive PLCP frame.

Bits 7 to 0: Receive Z1 Byte (RZ1[7:0]) – These eight bits are the integrated version of the Z1 byte as extracted

from the receive PLCP frame.

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Bit # 15 14 13 12 11 10 9 8

Name RZ47 RZ46 RZ45 RZ44 RZ43 RZ42 RZ41 RZ40

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RZ37 RZ36 RZ35 RZ34 RZ33 RZ32 RZ31 RZ30

Default 0 0 0 0 0 0 0 0

Bits 15 to 8: Receive Z4 Byte (RZ4[7:0]) – These eight bits are the integrated version of the Z4 byte as extracted

from the receive PLCP frame (This bits are zero in E3 mode).

Bits 7 to 0: Receive Z3 Byte (RZ3[7:0]) – These eight bits are the integrated version of the Z3 byte as extracted

from the receive PLCP frame.

Bit # 15 14 13 12 11 10 9 8

Name RZ67 RZ66 RZ65 RZ64 RZ63 RZ62 RZ61 RZ60

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RZ57 RZ56 RZ55 RZ54 RZ53 RZ52 RZ51 RZ50

Default 0 0 0 0 0 0 0 0

Bits 15 to 8: Receive Z6 Byte (RZ6[7:0]) – These eight bits are the integrated version of the Z6 byte as extracted

from the receive PLCP frame (This bits are zero in E3 mode).

Bits 7 to 0: Receive Z5 Byte (RZ5[7:0]) – These eight bits are the integrated version of the Z5 byte as extracted

from the receive PLCP frame (This bits are zero in E3 mode).

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12.13 FIFO Registers

12.13.1 Transmit FIFO Register Map

The transmit FIFO block has five registers.

Table 12-45. Transmit FIFO Register Map

ADDRESS REGISTER REGISTER DESCRIPTION

(1,3,5,7)80h FF.TCR FIFO Transmit Control Register

(1,3,5,7)82h FF.TLCR FIFO Transmit Level Control Register

(1,3,5,7)84h FF.TPAC FIFO Transmit Port Address Control Register

(1,3,5,7)86h — Unused

(1,3,5,7)88h FF.TSRL FIFO Transmit Status Register Latched Register

(1,3,5,7)8Ah FF.TSRIE FIFO Transmit Status Register Interrupt Enable Register

(1,3,5,7)8Ch — Unused

(1,3,5,7)8Eh — Unused

12.13.1.1 Register Bit Descriptions

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — — — — — — TFRST

Default 0 0 0 0 0 0 0 1

Bit 0: Transmit FIFO Reset (TFRST) – When 0, the Transmit FIFO will resume normal operations, however, data

is discarded until a start of packet/cell is received after RAM power-up is completed. When 1, the Transmit FIFO is

emptied, any transfer in progress is halted, the FIFO RAM is powered down, the associated TDXA is forced low,

and all incoming data is discarded. If the port was selected when the reset was initiated, the port will be deselected,

and must be reselected (TEN deasserted with address on TADR or TSX asserted with address on TDATA) before

any transfer will occur.

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Bit # 15 14 13 12 11 10 9 8

Name — — TFAE5 TFAE4 TFAE3 TFAE2 TFAE1 TFAE0

Default 0 0 0 1 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — TFAF5 TFAF4 TFAF3 TFAF2 TFAF1 TFAF0

Default 0 0 0 1 0 0 0 0

Bits 13 to 8: Transmit FIFO Almost Empty Level (TFAE[5:0]) – In POS-PHY packet processing mode, these six

bits indicate the maximum number of four byte groups that can be stored in the Transmit FIFO for it to be

considered "almost empty". E.g., a value of 30 (1Eh) results in the FIFO being "almost empty" when it contains 120

(78h) bytes or less. In cell processing mode, these bits are ignored.

Bits 5 to 0: Transmit FIFO Almost Full Level (TFAF[5:0]) – In POS-PHY packet processing mode, these six bits

indicate the maximum number of four byte groups that can be available in the Transmit FIFO for it to be considered

"almost full". E.g., a value of 30 (1Eh) results in the FIFO being "almost full" when it has 120 (78h) bytes or less

available. In cell processing mode, TFAF[5:2] are ignored, and TFAF[1:0] indicate the maximum number of cells

that can be available in the Transmit FIFO for it to be considered "almost full".

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — — TPA4 TPA3 TPA2 TPA1 TPA0

Default 0 0 0 0 0 0 0 0

Bits 4 to 0: Transmit FIFO System Port Address (TPA[4:0]) – These five bits set the Transmit FIFO system

interface port address used to poll the Transmit FIFO for fill status, and select it for data transfer. In Level 2 mode,

if bits TPA[4:0] are set to a value of 1Fh, the port is disabled.

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Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Bit # 7 6 5 4 3 2 1 0

Name — — — TFATL TFSTL TFITL TFUL TFOL

Bit 4: Transmit FIFO Aborted Transfer Latched (TFATL) – This bit is set when a transfer is aborted. An aborted

transfer does not occur in UTOPIA mode. In POS-PHY mode, an aborted transfer occurs when a packet error (a

transfer with TERR and TEOP asserted) occurs. An aborted transfer is stored in the transmit FIFO with an abort

indication.

Bit 3: Transmit FIFO Short Transfer Latched (TFSTL) – This bit is set when a "short transfer" is received. In

UTOPIA mode, a "short transfer" occurs when a start of cell (a transfer with TSOC asserted) occurs before the

previous cell transfer has been completed. In POS-PHY mode, a "short transfer" occurs when a start of packet (a

transfer with TSOP asserted) occurs after a previous start of packet, but before an end of packet (a transfer with

TEOP asserted). In UTOPIA mode, the short transfer data is discarded. In POS-PHY mode, a short transfer is

stored in the transmit FIFO with an abort indication.

Bit 2: Transmit FIFO Invalid Transfer Latched (TFITL) – This bit is set when an "invalid transfer" is initiated. In

UTOPIA mode, an "invalid transfer" occurs when additional cell data is transferred after the last transfer of a cell

and before a transfer with TSOC asserted. In POS-PHY mode, an "invalid transfer" occurs when packet data is

transferred after an end of packet, but before a start of packet (this includes another end of packet transfer). The

invalid transfer data is discarded.

Bit 1: Transmit FIFO Underflow Latched (TFUL) – This bit is set when a Transmit FIFO underflow condition

occurs. An underflow condition results in a loss of data.

Bit 0: Transmit FIFO Overflow Latched (TFOL) – This bit is set when a Transmit FIFO overflow condition occurs.

An overflow condition results in a loss of data.

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Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — — TFATIE TFSTIE TFITIE TFUIE TFOIE

Default 0 0 0 0 0 0 0 0

Bit 4: Transmit FIFO Aborted Transfer Interrupt Enable (TFATIE) – This bit enables an interrupt if the TFATL bit

in the FF.TSRL register is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 3: Transmit FIFO Short Transfer Interrupt Enable (TFSTIE) – This bit enables an interrupt if the TFSTL bit in

the FF.TSRL register is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 2: Transmit FIFO Invalid Transfer Interrupt Enable (TFITIE) – This bit enables an interrupt if the TFITL bit in

the FF.TSRL register is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 1: Transmit FIFO Underflow Interrupt Enable (TFUIE) – This bit enables an interrupt if the TFUL bit in the

FF.TSRL register is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 0: Transmit FIFO Overflow Interrupt Enable (TFOIE) – This bit enables an interrupt if the TFOL bit in the

FF.TSRL register is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

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12.13.2 Receive FIFO Register Map

The receive FIFO block has five registers.

Table 12-46. Receive FIFO Register Map

ADDRESS REGISTER REGISTER DESCRIPTION

(1,3,5,7)90h FF.RCR FIFO Receive Control Register

(1,3,5,7)92h FF.RLCR FIFO Receive Level Control Register

(1,3,5,7)94h FF.RFPAC FIFO Receive Port Address Control Register

(1,3,5,7)96h — Unused

(1,3,5,7)98h FF.RSRL FIFO Receive Status Register Latched

(1,3,5,7)9Ah FF.RSRIE FIFO Receive Status Register Interrupt Enable

(1,3,5,7)9Ch -— Unused

(1,3,5,7)9Eh — Unused

12.13.2.1 Register Bit Descriptions

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — — — — — — RFRST

Default 0 0 0 0 0 0 0 1

Bit 0: Receive FIFO Reset (RFRST) – When 0, the Receive FIFO will resume normal operations, however, data is

discarded until a start of packet/cell is received after RAM power-up is completed. When 1, the Receive FIFO is

emptied, any transfer in progress is halted, the FIFO RAM is powered down, the associated RDXA signal is forced

low, and all incoming data is discarded. If the port was selected when the reset was initiated, the port will be

deselected, and must be reselected (REN) deasserted with address on RADR or RSX asserted with address on

RDATA) before any transfer will occur.

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Bit # 15 14 13 12 11 10 9 8

Name — — RFAE5 RFAE4 RFAE3 RFAE2 RFAE1 RFAE0

Default 0 0 0 1 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — RFAF5 RFAF4 RFAF3 RFAF2 RFAF1 RFAF0

Default 0 0 0 1 0 0 0 0

Bits 13 to 8: Receive FIFO Almost Empty Level (RFAE[5:0]) – In POS-PHY packet processing mode, these six

bits indicate the maximum number of four byte groups that can be stored in the Receive FIFO for it to be

considered "almost empty". E.g., a value of 30 (1Eh) results in the FIFO being "almost empty" when it contains 120

(78h) bytes or less. In cell processing mode, RFAE[5:2] are ignored, and RFAE[1:0] indicate the maximum number

of cells that can be stored in the Receive FIFO for it to be considered "almost empty".

Bits 5 to 0: Receive FIFO Almost Full Level (RFAF[5:0]) – In POS-PHY packet processing mode, these six bits

indicate the maximum number of four byte groups that can be available in the Receive FIFO for it to be considered

"almost full". E.g., a value of 30 (1Eh) results in the FIFO being "almost full" when it has 120 (78h) bytes or less

available. In cell processing mode, these bits are ignored.

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — — RPA4 RPA3 RPA2 RPA1 RPA0

Default 0 0 0 0 0 0 0 0

Bits 4 to 0: Receive FIFO System Port Address (RPA[4:0]) – These five bits set the Receive FIFO system

interface port address used to poll the Receive FIFO for fill status, and select it for data transfer. Each port in the

device must have a different port address. In Level 2 mode, if bits RPA[4:0] are set to a value of 1Fh, the port is

disabled.

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Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Bit # 7 6 5 4 3 2 1 0

Name — — — — — — — RFOL

Bit 0: Receive FIFO Overflow Latched (RFOL) – This bit is cleared when a logic one is written to this bit, and set

when a Receive FIFO overflow condition occurs. An overflow condition results in a loss of data.

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — — — — — — RFOIE

Default 0 0 0 0 0 0 0 0

Bit 0: Receive FIFO Overflow Interrupt Enable (RFOIE) – This bit enables an interrupt if the RFOL bit in the

FF.RSRL register is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

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12.14 Cell/Packet Processor

12.14.1 Transmit Cell Processor Register Map

The transmit cell processor block has 11 registers. Note: These registers are shared with the transmit packet

processors.

Table 12-47. Transmit Cell Processor Register Map

ADDRESS REGISTER REGISTER DESCRIPTION

(1,3,5,7)A0h CP.TCR Cell Processor Transmit Control Register

(1,3,5,7)A2h — Reserved

(1,3,5,7)A4h CP.TECC Cell Processor Transmit Errored Cell Control Register

(1,3,5,7)A6h CP.THMRC Cell Processor Transmit HEC Error Mask Control Register

(1,3,5,7)A8h CP.THPC1 Cell Processor Transmit Header Pattern Control Register 1

(1,3,5,7)AAh CP.THPC2 Cell Processor Transmit Header Pattern Control Register 2

(1,3,5,7)ACh CP.TFPPC Cell Processor Transmit Fill Cell Payload Pattern Control Register

(1,3,5,7)AEh CP.TSR Cell Processor Transmit Status Register

(1,3,5,7)B0h CP.TSRL Cell Processor Transmit Status Register Latched

(1,3,5,7)B2h CP.TSRIE Cell Processor Transmit Status Register Interrupt Enable

(1,3,5,7)B4h CP.TCCR1 Cell Processor Transmit Cell Count Register 1

(1,3,5,7)B6h CP.TCCR2 Cell Processor Transmit Cell Count Register 2

(1,3,5,7)B8h — Reserved

(1,3,5,7)BAh — Reserved

(1,3,5,7)BCh — Unused

(1,3,5,7)BEh — Unused

12.14.1.1 Register Bit Descriptions

Bit # 15 14 13 12 11 10 9 8

Name — — — — TDSE TDHE THPE TCPAD

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — TFCH TFCP THSE TSD TBRE TCPD

Default 0 0 0 0 0 0 0 0

Bit 11: Transmit DSS Scrambling Enable (TDSE) – When 0, self-synchronous scrambling is enabled. When 1,

DSS scrambling is enabled DSS mode is only applicable for un-framed or clear channel framing and bit

synchronous modes. This bit is ignored if scrambling is disabled. Note: In byte synchronous and cell pass-through

modes, self-synchronous scrambling is enabled regardless of the setting of this bit.

Bit 10: Transmit DQDB HEC Processing Enable (TDHE) – When 0, the HEC is calculated over all four-header

bytes. When 1, only the last three header bytes are used for HEC calculation.

Bit 9: Transmit HEC Pass-through Enable (THPE) – When 0, the calculated HEC byte will overwrite the HEC

byte in the cell. When 1, the HEC byte in the cell is passed through. Note: The calculated HEC is always inserted

into cells that are received without a HEC byte.

Bit 8: Transmit HEC Coset Polynomial Addition Disable (TCPAD) – When 0, the HEC coset polynomial

addition is performed prior to inserting the HEC byte. When 1, HEC coset polynomial addition is disabled

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Bit 5: Transmit Fill Cell Header Type (TFCH) – When 0, an idle cell header (00 00 00 01h) will be used in fill

cells. When 1, a programmable header will be used in fill cells. The setting of this bit does not affect the contents of

the cell payload bytes.

Bit 4: Transmit Fill Cell Payload Type (TFCP) – When 0, an idle cell payload byte (6Ah) will be used in each

payload byte fill cells. When 1, a programmable cell payload byte will be used in each payload byte fill cells. The

setting of this bit does not affect the contents of the cell header bytes.

Bit 3: Transmit Cell Header Scrambling Enable (THSE) – When 0, only the cell payload will be scrambled. When

1, the entire data stream (cell header and payload) is scrambled. This bit is ignored if scrambling is disabled, or

DSS scrambling is enabled. When cell pass-through mode is enabled, the entire data stream will be scrambled if

scrambling is enabled.

Bit 2: Transmit Scrambling Disable (TSD) – When 0, scrambling is performed. When 1, scrambling is disabled.

Bit 1: Transmit Bit Reordering Enable (TBRE) – When 0, bit reordering is disabled (The first bit transmitted is

from the MSB of the transmit FIFO byte TFD[7]). When 1, bit reordering is enabled (The first bit transmitted is from

the LSB of the transmit FIFO byte TFD[0]).

Bit 0: Transmit Pass-Through Enable (TPTE) – When 0, pass-through mode is disabled and cell processing is

enabled. When 1, all cell processing functions except scrambling and bit reordering are disabled and the cell

processor is in pass-through mode.

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Bit # 15 14 13 12 11 10 9 8

Name MEIMS TCER6 TCER5 TCER4 TCER3 TCER2 TCER1 TCER0

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name TCEN7 TCEN6 TCEN5 TCEN4 TCEN3 TCEN2 TCEN1 TCEN0

Default 0 0 0 0 0 0 0 0

Bit 15: Manual Error Insert Mode Select (MEIMS) – When 0, the transmit manual error insertion signal (TMEI)

will not cause errors to be inserted. When 1, TMEI will causes an error to be inserted when it transitions from a 0 to

a 1. Note: Enabling TMEI does not disable error insertion using TCER[6:0] and TCEN[7:0].

Manual error insertion is available at the global level, but not on a per-port basis for the cell processor.

(PORT.CR1.MEIM must be set for global error insertion to insert a packet error.)

Bits 14 to 8: Transmit Errored Cell Insertion Rate (TCER[6:0]) – These seven bits indicate the rate at which

errored cells are to be output. One out of every x * 10y cells is to be an errored cell. TCER[3:0] is the value x, and

TCER[6:4] is the value y, which has a maximum value of 6. If TCER[3:0] has a value of 0h errored cell insertion is

disabled. If TCER[6:4] has a value of 6xh or 7xh the errored cell rate will be x * 106. A TCER[6:0] value of 01h

results in every cell being errored. A TCER[6:0] value of 0Fh results in every 15th cell being errored. A TCER[6:0]

value of 11h results in every 10th cell being errored. Errored cell insertion starts when the TECC register is written

with a TCER[3:0] value that is non-zero. If the TECC register is written to during the middle of an errored cell

insertion process, the current process is halted, and a new process will be started using the new values of

TCER[6:0] and TCEN[7:0}. Errored cell insertion ends when TCEN[7:0] errored cells have been transmitted.

TCER[3:0] - X TCER[6:4] - Y TCER[6:0] ERROR RATE (x * 10y )

0h XXh X0h DISABLED

1h 0Xh 01h 1 out of 1 cells

Fh 0Xh 0Fh 1 out of 15 cells

1h 1Xh 11h 1 out of 10 cells

1h 6Xh 61h 1 out of 106 cells

1h 7Xh 71h 1 out of 106 cells

Bits 7 to 0: Transmit Errored Cell Insertion Number (TCEN[7:0]) – These eight bits indicate the total number of

errored cells to be transmitted. A value of FFh results in continuous errored cell insertion at the specified rate.

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Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name THEM7 THEM6 THEM5 THEM4 THEM3 THEM2 THEM1 THEM0

Default 0 0 0 0 0 0 0 0

Bits 7 to 0: Transmit HEC Error Mask (THEM[7:0]) –These bits control the error insertion into the HEC byte.

Setting these bits will corrupt the associated HEC bit during cell error insertion. Based on the value set in this

register, the far end will detect three types of errors: an error in the HEC, a single bit error in the header, or multiple

bit errors in the header. Default (THEM[7:0] = 00h) is no error inserted. If a single bit error is selected, the table

below also shows which bit of the 32-bit HEC header will be corrupted. Table 12-48 indicates the type of error

inserted by a specific mask value. Note: If a single bit error is inserted in the HEC, and the far-end has single bit

error correction enabled, this will cause the indicated header bit to be corrupted.

Table 12-48. HEC Error Mask

VALUE ERROR

TYPE BIT VALUE ERROR

TYPE BIT

01h-02h HEC – 32h-37h Multi – 87h-88h Multi –

03h Multi - 38h Single 29 89h Single 25

04h HEC – 39h-3Fh Multi – 90h-9Ah Multi –

05h-06h Multi – 40h HEC – 9Bh Single 02

07h Single 32 41h-42h Multi – 9Ch-A1h Multi –

08h HEC – 43h Single 11 A2h Single 12

09h-0Ah Multi – 44h-50h Multi – A3h-A7h Multi –

0Bh Single 09 51h Single 13 A8h Single 21

0Ch-0Dh Multi – 52h-53h Multi – A9h-AAh Multi –

0Eh Single 31 54h Single 22 ABh Single 14

0Fh Multi – 55h-56h Multi – ACh-ADh Multi –

10h HEC – 57h Single 20 AEh Single 19

11h-14h Multi – 58h Single 06 AFh Multi –

15h Single 24 59h-5Ah Multi – B0h Single 05

16h Single 08 5Bh Single 18 B1h-B5h Multi –

17h-1Dh Multi – 5Ch-66h Multi – B6h Single 17

1Eh Single 30 67h Single 04 B7h-C6h Multi –

1Fh Multi – 68h-6Ah Multi – C7h Single 26

20h HEC – 6Bh Single 16 C8h-CDh Multi –

21h-29h Multi – 6Ch-6Fh Multi – CEh Single 03

2Ah Single 23 70h Single 28 CFh-D5h Multi –

2Bh Multi – 71h-7Fh Multi – D6h Single 15

2Ch Single 07 80h HEC – D7h-DFh Multi –

2Dh-30h Multi – 81h-85h Multi – E0h Single 27

31h Single 01 86h Single 10 E1h-FFh Multi –

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Bit # 15 14 13 12 11 10 9 8

Name THP15 THP14 THP13 THP12 THP11 THP10 THP9 THP8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name THP7 THP6 THP5 THP4 THP3 THP2 THP1 THP0

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Transmit Programmable Header Pattern (THP[15:0]) – Lower 16 bits of 32 bits. Register

description follows next register.

Bit # 15 14 13 12 11 10 9 8

Name THP31 THP30 THP29 THP28 THP27 THP26 THP25 THP24

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name THP23 THP22 THP21 THP20 THP19 THP18 THP17 THP16

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Transmit Programmable Header Pattern (THP[31:16]) Upper 16 bits of 32 bits.

Transmit Programmable Header Pattern (THP[31:0]) – These 32 bits indicate the header bit pattern to be used

in the header of fill cells when the CP.TCR register bit TFCH is set.

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name TFPP7 TFPP6 TFPP5 TFPP4 TFPP3 TFPP2 TFPP1 TFPP0

Default 0 0 0 0 0 0 0 0

Bits 7 to 0: Transmit Fill Cell Payload Pattern (TFPP[7:0]) – These eight bits indicate the value to be placed in

the payload bytes of the fill cells when the CP.TCR register bit TFCP is set..

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Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Bit # 7 6 5 4 3 2 1 0

Name — — — — — — — TECF

Bit 0: Transmit Errored Cell Insertion Finished (TECF) – This bit is set when the number of errored cells

indicated by the TCEN[7:0] bits in the TECC register have been transmitted. This bit is cleared when errored cell

insertion is disabled, or a new errored cell insertion process is initiated.

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Bit # 7 6 5 4 3 2 1 0

Name — — — — — — — TECFL

Bit 0: Transmit Errored Cell Insertion Finished Latched (TECFL) – This bit is set when the TECF bit in the

CP.TSR register transitions from zero to one.

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — — — — — — TECFIE

Default 0 0 0 0 0 0 0 0

Bit 0: Transmit Errored Cell Insertion Finished Interrupt Enable (TECFIE) – This bit enables an interrupt if the

TECFL bit in the CP.TSRL register is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

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Bit # 15 14 13 12 11 10 9 8

Name TCC15 TCC14 TCC13 TCC12 TCC11 TCC10 TCC9 TCC8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name TCC7 TCC6 TCC5 TCC4 TCC3 TCC2 TCC1 TCC0

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Transmit Cell Count (TCC[15:0]) – Lower 16 bits of 24 bits. Register description follows next

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name TCC23 TCC22 TCC21 TCC20 TCC19 TCC18 TCC17 TCC16

Default 0 0 0 0 0 0 0 0

Bits 7 to 0: Transmit Cell Count (TCC[23:16]) - Upper 8 bits of Register.

Transmit Cell Count (TCC[23:0]) – These 24 bits indicate the number of cells extracted from the Transmit FIFO

and output in the outgoing data stream. This register is updated via the PMU signal (see Section 10.4.5).

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12.14.2 Receive Cell Processor

The receive cell processor block has 18 registers.

12.14.2.1 Receive Cell Processor Register Map

Table 12-49. Receive Cell Processor Register Map

ADDRESS REGISTER REGISTER DESCRIPTION

(1,3,5,7)C0h CP.RCR1 Cell Processor Receive Control Register 1

(1,3,5,7)C2h — Reserved

(1,3,5,7)C4h CP.RHPC1 Cell Processor Receive Header Pattern Control Register 1

(1,3,5,7)C6h CP.RHPC2 Cell Processor Receive Header Pattern Control Register 2

(1,3,5,7)C8h CP.RHPMC1 Cell Processor Receive Header Pattern Mask Control Register 1

(1,3,5,7)CAh CP.RHPMC2 Cell Processor Receive Header Pattern Mask Control Register 2

(1,3,5,7)CCh CP.RLTC Cell Processor Receive LCD Threshold Control Register

(1,3,5,7)CEh CP.RSR Cell Processor Receive Status Register

(1,3,5,7)D0h CP.RSRL Cell Processor Receive Status Register Latched

(1,3,5,7)D2h CP.RSRIE Cell Processor Receive Status Register Interrupt Enable

(1,3,5,7)D4h CP.RCCR1 Cell Processor Receive Cell Count Register 1

(1,3,5,7)D6h CP.RCCR2 Cell Processor Receive Cell Count Register 2

(1,3,5,7)D8h CP.RECCR1 Cell Processor Receive Errored Header Count Register 1

(1,3,5,7)DAh CP.RECCR2 Cell Processor Receive Errored Header Count Register 2

(1,3,5,7)DCh CP.RHPCR1 Cell Processor Receive Header Pattern Cell Count Register 1

(1,3,5,7)DEh CP.RHPCR2 Cell Processor Receive Header Pattern Cell Count Register 2

(1,3,5,7)E0h CP.RCCCR1 Cell Processor Receive Corrected Cell Count Register 1

(1,3,5,7)E2h CP.RCCCR2 Cell Processor Receive Corrected Cell Count Register 2

(1,3,5,7)E4h CP.RFCCR1 Cell Processor Receive Filtered Idle/Unassigned/Invalid Cell Count Register 1

(1,3,5,7)E6h CP.RFCCR2 Cell Processor Receive Filtered Idle/Unassigned/Invalid Cell Count Register 2

(1,3,5,7)E8h — Reserved

(1,3,5,7)EAh — Reserved

(1,3,5,7)ECh — Reserved

(1,3,5,7)EEh — Reserved

(1,3,5,7)F0h — Unused

(1,3,5,7)F2h — Unused

(1,3,5,7)F4h — Unused

(1,3,5,7)F6h — Unused

(1,3,5,7)F8h — Unused

(1,3,5,7)FAh — Unused

(1,3,5,7)FCh — Unused

(1,3,5,7)FEh — Unused

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12.14.2.2 Register Bit Descriptions

Bit # 15 14 13 12 11 10 9 8

Name RDDE RDHE RECED RHPM1 RHPM0 RICFD RUCFE RICFE

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RROC1 RROC0 RCPAD RHECD RHDE RDD RBRE RPTE

Default 0 0 0 0 0 0 0 0

Bit 15: Receive DSS Descrambling Enable (RDDE) – When 0, self-synchronous descrambling is enabled. When

1, DSS descrambling is enabled. DSS mode is only applicable for un-framed or clear channel framing and bit

synchronous modes. This bit is ignored if descrambling is disabled. Note: In byte synchronous and cell pass-

through modes, self-synchronous descrambling is enabled regardless of the setting of this bit.

Bit 14: Receive DQDB HEC Processing Enable (RDHE) – When 0, the HEC is calculated over all four-header

bytes. When 1, only the last three header bytes are used for HEC calculation.

Bit 13: Receive Errored Cell Extraction Disable (RECED) – When 0, errored cells are extracted. When 1,

errored cells are passed on.

Bits 12 to 11: Receive Header Pattern Comparison Mode (RHPM[1:0]) – These two bits control the operation of

the header pattern comparison function.

00 = Count match: Cells that match the header pattern are counted.

01 = Count no match - Cells that do not match the header pattern are counted.

10 = Discard match - Cells that match the header pattern are counted and discarded.

11 = Discard no match - Cells that do not match the header pattern are counted and discarded.

Bit 10: Receive Idle Cell Filtering Disable (RICFD) – When 0, idle cells are discarded. When 1, idle cells are

passed on.

Bit 9: Receive Unassigned Cell Filtering Enable (RUCFE) – When 0, unassigned cells are passed on. When 1,

unassigned cells are counted and discarded.

Bit 8: Receive Invalid Cell Filtering Enable (RICFE) – When 0, invalid cells are passed on. When 1, invalid cells

are discarded.

Bits 7 to 6: Receive Error Monitoring Required OK Cells (RROC[1:0]) – These two bits indicate the number of

good cells required to transition from the "Detection" state to the "Correction" state, which enables single bit

correction of the header (see Figure 10-28).

00 = 1 good cell is required.

01 = 2 good cells are required.

10 = 4 good cells are required.

11 = 8 good cells are required.

Bit 5: Receive HEC Coset Polynomial Addition Disable (RCPAD) – When 0, the HEC coset polynomial addition

is performed prior to checking the HEC byte. When 1, HEC coset polynomial addition is disabled

Bit 4: Receive Header Error Correction Disable (RHECD) – When 0, single bit header error correction is

enabled. When 1, header error correction is disabled and all errors are treated as an un-correctable error.

Bit 3: Receive Cell Header Descrambling Enable (RHDE) – When 0, only the cell payload will be descrambled.

When 1, the entire data stream (cell header and payload) is descrambled. This bit is ignored if descrambling is

disabled or DSS descrambling is enabled. When cell pass-through mode is enabled, the entire data stream will be

descrambled if descrambling is enabled.

Bit 2: Receive Descrambling Disable (RDD) – When 0, descrambling is performed. When 1, descrambling is

disabled.

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Bit 1: Receive Bit Reordering Enable (RBRE) – When 0, bit reordering is disabled (The first bit received is stored

in the MSB of the receive FIFO byte). When 1, bit reordering is enabled (The first bit received is stored in the LSB

of the receive FIFO byte).

Bit 0: Receive Pass-Through Enable (RPTE) – When 0, pass-through mode is disabled and cell processing is

enabled. When 1, the cell processor is in pass-through mode, and all cell processing functions except

descrambling and bit reordering are disabled.

Bit # 15 14 13 12 11 10 9 8

Name RHP15 RHP14 RHP13 RHP12 RHP11 RHP10 RHP9 RHP8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RHP7 RHP6 RHP5 RHP4 RHP3 RHP2 RHP1 RHP0

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Receive Header Pattern (RHP[15:0]) – Lower 16 bits of 32 bits. Register description follows next

Bit # 15 14 13 12 11 10 9 8

Name RHP31 RHP30 RHP29 RHP28 RHP27 RHP26 RHP25 RHP24

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RHP23 RHP22 RHP21 RHP20 RHP19 RHP18 RHP17 RHP16

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Receive Header Pattern (RHP[31:16]) - Upper 16 bits of 32 bits.

Receive Header Pattern (RHP[31:0]) – These 32 bits indicate the receive header bit pattern to be detected by the

header pattern comparison function.

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Bit # 15 14 13 12 11 10 9 8

Name RHPD15 RHPD14 RHPD13 RHPD12 RHPD11 RHPD10 RHPD9 RHPD8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RHPD7 RHPD6 RHPD5 RHPD4 RHPD3 RHPD2 RHPD1 RHPD0

Default 0 0 0 0 0 0 0 0

Bit 15 to 0: Receive Header Pattern Comparison Disable (RHPD[15:0]) – Lower 16 bits of 32 bits. Register

description follows next register.

Bit # 15 14 13 12 11 10 9 8

Name RHPD31 RHPD30 RHPD29 RHPD28 RHPD27 RHPD26 RHPD25 RHPD24

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RHPD23 RHPD22 RHPD21 RHPD20 RHPD19 RHPD18 RHPD17 RHPD16

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Receive Header Pattern Comparison Disable (RHPD[31:16]) - Upper 16 bits of 32 bits.

Receive Header Pattern Comparison Disable (RHPD[31:0]) – These 32 bits indicate whether or not the

associated header bit is checked by the header pattern comparison function. If RHPD[x] is high, the header bit x is

ignored during the header pattern comparison (don't care). If RHPD[x] is low, the associated bit in the header must

match RHP[x] in the receive header pattern control register RHPC.

Bit # 15 14 13 12 11 10 9 8

Name RLT15 RLT14 RLT13 RLT12 RLT11 RLT10 RLT9 RLT8

Default 0 0 0 0 0 0 0 1

Bit # 7 6 5 4 3 2 1 0

Name RLT7 RLT6 RLT5 RLT4 RLT3 RLT2 RLT1 RLT0

Default 0 1 1 0 1 0 0 0

Bits 15 to 0: Receive LCD Threshold (RLT[15:0]) – These 16 bits indicate the number of consecutive cell periods

the cell delineation state machine must be in an Out of Cell Delineation (OCD) condition before it declares or

terminate a Loss of Cell Delineation (LCD) condition. A value of 0000h causes LCD to be declared at the same

time as OCD. The register has a default value after reset of 360 (decimal).

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Bit # 15 14 13 12 11 10 9 8

Name — — — — OOS — OCD LCD

Bit # 7 6 5 4 3 2 1 0

Name — — — — — RECC RHPC RCHC

Bit 11: Out Of Sync (OOS) – This read-only bit indicates that a DSS Out Of Sync (OOS) state exists. DSS OOS

occurs when the DSS Scrambler Synchronization state machine is in the "Load" or "Verify" state, and DSS

scrambling has been enabled.

Bit 9: Out Of Cell Delineation (OCD) – This read-only bit indicates that an Out of Cell Delineation condition (OCD)

exists. When DSS scrambling is disabled, OCD occurs when the HEC Error Monitoring state machine is in the

"OCD" state. When DSS scrambling is enable, OCD occurs when the DSS OCD Detection state machine is in the

"OCD" state.

Bit 8: Loss Of Cell Delineation (LCD) – This read-only bit indicate that a Loss of Cell Delineation state exists.

LCD occurs when OCD persists for the period programmed in the LCD threshold control register RLTC.

Bit 2: Receive Errored Header Cell Count (RECC) – This read-only bit indicates that the receive errored header

cell count is non-zero.

Bit 1: Receive Header Pattern Cell Count (RHPC) – This read-only bit indicates that the receive header pattern

comparison cell count is non-zero.

Bit 0: Receive Corrected Cell Count (RCHC) – This read-only bit indicates that the receive corrected header cell

count is non-zero.

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Bit # 15 14 13 12 11 10 9 8

Name — — — — OOSL COCDL OCDCL LCDCL

Bit # 7 6 5 4 3 2 1 0

Name RECL RCHL RIDL RUDL RIVDL RECCL RHPCL RCHCL

Bit 11: Out Of Sync Change Latched (OOSL) – This bit is set when the OOS bit in the CP.RSR register changes

state.

Bit 10: Change Of Cell Delineation Latched (COCDL) – This bit is set when the data path cell counters are

updated with a new cell delineation that is different from the previous cell delineation.

Bit 9: Out Of Cell Delineation Change Latched (OCDCL) – This bit is set when the OCD bit in the CP.RSR

Bit 8: Loss Of Cell Delineation Change Latched (LCDCL) – This bit is set when the LCD bit in the CP.RSR

Bit 7: Receive Errored Header Cell Latched (RECL) – This bit is set when a cell with an errored header is

discarded.

Bit 6: Receive Corrected Header Cell Latched (RCHL) – This bit is set when a cell with a single header error is

corrected.

Bit 5: Receive Idle Cell Detection Latched (RIDL) – This bit is set when an idle cell is discarded.

Bit 4: Receive Unassigned Cell Detection Latched (RUDL) – This bit is set when an unassigned cell is

discarded.

Bit 3: Receive Invalid Cell Detection Latched (RIVDL) – This bit is set when an invalid cell is discarded.

Bit 2: Receive Errored Header Cell Count Latched (RECCL) – This bit is set when the RECC bit in the CP.RSR

Bit 1: Receive Header Pattern Cell Count Latched (RHPCL) – This bit is set when the RHPC bit in the CP.RSR

Bit 0: Receive Corrected Header Cell Count Latched (RCHCL) – This bit is set when the RCHC bit in the

CP.RSR register transitions from zero to one.

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Bit # 15 14 13 12 11 10 9 8

Name — — — — OOSIE COCDIE OCDCIE LCDCIE

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RECIE RCHIE RIDIE RUDIE RIVDIE RECCIE RHPCIE RCHCIE

Default 0 0 0 0 0 0 0 0

Bit 11: Out Of Sync Change Interrupt Enable (OOSIE) – This bit enables an interrupt if the OOSL bit in the

CP.RSRL register is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 10: Change Of Cell Delineation Interrupt Enable (COCDIE) – This bit enables an interrupt if the COCDL bit

in the CP.RSRL register is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 9: Out Of Cell Delineation Change Interrupt Enable (OCDCIE) – This bit enables an interrupt if the OCDCL

bit in the CP.RSRL register is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 8: Loss Of Cell Delineation Change Interrupt Enable (LCDCIE) – This bit enables an interrupt if the LCDCL

bit in the CP.RSRL register is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 7: Receive Errored Header Cell Interrupt Enable (RECIE) – This bit enables an interrupt if the RECL bit in

the CP.RSRL register is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 6: Receive Corrected Header Cell Interrupt Enable (RCHIE) – This bit enables an interrupt if the RCHL bit in

the CP.RSRL register is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 5: Receive Idle Cell Detection Interrupt Enable (RIDIE) – This bit enables an interrupt if the RIDL bit in the

CP.RSRL register is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 4: Receive Unassigned Cell Detection Interrupt Enable (RUDIE) – This bit enables an interrupt if the RUDL

bit in the CP.RSRL register is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 3: Receive Invalid Cell Detection Interrupt Enable (RIVDIE) – This bit enables an interrupt if the RIVDL bit in

the CP.RSRL register is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 2: Receive Errored Header Cell Count Interrupt Enable (RECCIE) – This bit enables an interrupt if the

RECCL bit in the CP.RSRL register is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

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Bit 1: Receive Header Pattern Cell Count Interrupt Enable (RHPCIE) – This bit enables an interrupt if the

RHFCL bit in the CP.RSRL register is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 0: Receive Corrected Header Cell Count Interrupt Enable (RCHCIE) – This bit enables an interrupt if the

RCHCL bit in the CP.RSRL register is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit # 15 14 13 12 11 10 9 8

Name RCC15 RCC14 RCC13 RCC12 RCC11 RCC10 RCC9 RCC8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RCC7 RCC6 RCC5 RCC4 RCC3 RCC2 RCC1 RCC0

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Receive Cell Count (RCC[15:0]) – Lower 16 bits of 24 bits. Register description follows next register.

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RCC23 RCC22 RCC21 RCC20 RCC19 RCC18 RCC17 RCC16

Default 0 0 0 0 0 0 0 0

Bits 7 to 0: Receive Cell Count (RCC[23:16]) - Upper 8 bits of Register.

Receive Cell Count (RCC[23:0]) – These 24 bits indicate the number of cells stored in the receive FIFO. Note:

Cells discarded due to system loopback or an overflow condition will be included in this count. This register is

updated via the PMU signal (see Section 10.4.5).

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Bit # 15 14 13 12 11 10 9 8

Name RECC15 RECC14 RECC13 RECC12 RECC11 RECC10 RECC9 RECC8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RECC7 RECC6 RECC5 RECC4 RECC3 RECC2 RECC1 RECC0

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Receive Errored Header Count (RECC[15:0]) – Lower 16 bits of 24 bits. Register description

follows next register.

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RECC23 RECC22 RECC21 RECC20 RECC19 RECC18 RECC17 RECC16

Default 0 0 0 0 0 0 0 0

Bits 7 to 0: Receive Errored Header Count (RECC[23:16])

Receive Errored Header Count (RECC[23:0]) – These 24 bits indicate the number of cells received with

uncorrected header errors and discarded. If errored cell extraction is disabled, this count will be zero. Cells

included in this count will not be included in any other count. This register is updated via the PMU signal (see

Section 10.4.5).

Bit # 15 14 13 12 11 10 9 8

Name RHPC15 RHPC14 RHPC13 RHPC12 RHPC11 RHPC10 RHPC9 RHPC8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RHPC7 RHPC6 RHPC5 RHPC4 RHPC3 RHPC2 RHPC1 RHPC0

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Receive Header Pattern Comparison Cell Count (RHPC[15:0]) – Lower 16 bits of 24 bits. Register

description follows next register.

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Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RHPC23 RHPC22 RHPC21 RHPC20 RHPC19 RHPC18 RHPC17 RHPC16

Default 0 0 0 0 0 0 0 0

Bits 7 to 0: Receive Header Pattern Comparison Cell Count (RHPC[23:16]) - Upper 8 bits of Register.

Receive Header Pattern Comparison Cell Count (RHPC[23:0]) – These 24 bits indicate the number of cells

identified during the header pattern comparison processes. In the header pattern comparison count and discard

match modes, this will be a count of cells with a matching header. In the header pattern comparison count and

discard no match modes, this will be a count of cells without a matching header. In the header pattern comparison

count (match and no match) modes, this count will also be included in the receive cell count registers. In the

header pattern comparison discard (match or no match) modes, this count will not be included in any other count.

This register is updated via the PMU signal (see Section 10.4.5).

Bit # 15 14 13 12 11 10 9 8

Name RCHC15 RCHC14 RCHC13 RCHC12 RCHC11 RCHC10 RCHC9 RCHC8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RCHC7 RCHC6 RCHC5 RCHC4 RCHC3 RCHC2 RCHC1 RCHC0

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Receive Corrected Header Count (RCHC[15:0]) – Lower 16 bits of 24 bits. Register description

follows next register.

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Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RCHC23 RCHC22 RCHC21 RCHC20 RCHC19 RCHC18 RCHC17 RCHC16

Default 0 0 0 0 0 0 0 0

Bits 7 to 0: Receive Corrected Header Count (RCHC[23:16]) - Upper 8 bits of Register.

Receive Corrected Header Count (RCHC[23:0]) – These 24 bits indicate the number of cells that have had

header errors corrected. If header error correction is disabled, this count will be zero. This count will be included in

the receive cell count registers (CP.RCCR), receive filtered idle/unassigned/invalid cell count registers

(CP.RFCCR), or receive header pattern cell count registers (CP.RHPCR). This register is updated via the PMU

signal (see Section 10.4.5).

Bit # 15 14 13 12 11 10 9 8

Name RFCC15 RFCC14 RFCC13 RFCC12 RFCC11 RFCC10 RFCC9 RFCC8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RFCC7 RFCC6 RFCC5 RFCC4 RFCC3 RFCC2 RFCC1 RFCC0

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Receive Filtered Cell Count (RFCC[15:0]) – Lower 16 bits of 24 bits. Register description follows

next register.

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Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RFCC23 RFCC22 RFCC21 RFCC20 RFCC19 RFCC18 RFCC17 RFCC16

Default 0 0 0 0 0 0 0 0

Bits 7 to 0: Receive Filtered Cell Count (RFCC[23:16]) - Upper 8 bits of Register.

Receive Filtered Cell Count (RFCC[23:0]) – These 24 bits indicate the number of cells that were discarded during

the cell filtering processes (idle, unassigned, and/or invalid). If all cell filtering is disabled, this count will be zero.

Cells included in this count will not be included in any other count. This register is updated via the PMU signal (see

Section 10.4.5).

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12.14.3 Transmit Packet Processor Register Map

The transmit packet processor block uses 10 registers. Note: These registers are shared with the transmit cell

processor registers.

Table 12-50. Transmit Packet Processor Register Map

ADDRESS REGISTER REGISTER DESCRIPTION

(1,3,5,7)A0h PP.TCR Packet Processor Transmit Control Register

(1,3,5,7)A2h PP.TIFGC Packet Processor Transmit Inter-Frame Gapping Control Register

(1,3,5,7)A4h PP.TEPC Packet Processor Transmit Errored Packet Control Register

(1,3,5,7)A6h — Reserved

(1,3,5,7)A8h — Reserved

(1,3,5,7)AAh — Reserved

(1,3,5,7)ACh — Reserved

(1,3,5,7)AEh PP.TSR Packet Processor Transmit Status Register

(1,3,5,7)B0h PP.TSRL Packet Processor Transmit Status Register Latched

(1,3,5,7)B2h PP.TSRIE Packet Processor Transmit Status Register Interrupt Enable

(1,3,5,7)B4h PP.TPCR1 Packet Processor Transmit Packet Count Register 1

(1,3,5,7)B6h PP.TPCR2 Packet Processor Transmit Packet Count Register 2

(1,3,5,7)B8h PP.TBCR1 Packet Processor Transmit Byte Count Register 1

(1,3,5,7)BAh PP.TBCR2 Packet Processor Transmit Byte Count Register 2

(1,3,5,7)BCh — Unused

(1,3,5,7)BEh — Unused

12.14.3.1 Register Bit Descriptions

Bit # 15 14 13 12 11 10 9 8

Name — — — — Reserved Reserved Reserved Reserved

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — TFAD TF16 TIFV TSD TBRE TPTE

Default 0 0 0 0 0 0 0 0

Bit 5: Transmit FCS Append Disable (TFAD) – This bit controls whether or not a FCS is appended to the end of

each packet. When 0, the calculated FCS bytes are appended to the end of the packet. When 1, the packet is

transmitted without a FCS.

Bit 4: Transmit FCS-16 Enable (TF16) – When 0, the FCS processing uses a 32-bit FCS. When 1, the FCS

processing uses a 16-bit FCS

Bit 3: Transmit Bit Synchronous Inter-frame Fill Value (TIFV) – When 0, inter-frame fill is done with the flag

sequence (7Eh). When 1, inter-frame fill is done with all '1's. This bit is ignored in octet aligned mode.

Bit 2: Transmit Scrambling Disable (TSD) – When 0, scrambling is performed. When 1, scrambling is disabled.

Bit 1: Transmit Bit Reordering Enable (TBRE) – When 0, bit reordering is disabled (The first bit transmitted is

from the MSB of the transmit FIFO byte). When 1, bit reordering is enabled (The first bit transmitted is from the LSB

of the transmit FIFO byte).

Bit 0: Transmit Pass-Through Enable (TPTE) – When 0, pass-through mode is disabled and packet processing

is enabled. When 1, the packet processor is in pass-through mode and all packet-processing functions except

scrambling and bit reordering are disabled.

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Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name TIFG7 TIFG6 TIFG5 TIFG4 TIFG3 TIFG2 TIFG1 TIFG0

Default 0 0 0 0 0 0 0 1

Bits 7 to 0: Transmit Inter-Frame Gapping (TIFG[7:0]) – These eight bits indicate the number of additional flags

and bytes of inter-frame fill to be inserted between packets. The number of flags and bytes of inter-frame fill

between packets will be at least the value of TIFG[7:0] plus 1. Note: If inter-frame fill is set to all 1’s, a TFIG value

of 2 or 3 will result in a flag, at least two bytes of 1’s, and a flag between packets.

Bit # 15 14 13 12 11 10 9 8

Name MEIMS TPER6 TPER5 TPER4 TPER3 TPER2 TPER1 TPER0

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name TPEN7 TPEN6 TPEN5 TPEN4 TPEN3 TPEN2 TPEN1 TPEN0

Default 0 0 0 0 0 0 0 0

Bit 15: Manual Error Insert Mode Select (MEIMS) – When 0, the transmit manual error insertion signal (TMEI)

will not cause errors to be inserted. When 1, TMEI will causes an error to be inserted when it transitions from a 0 to

a 1. Note: Enabling TMEI does not disable error insertion using TPER[6:0] and TPEN[7:0].

Manual Error Insertion is available at the global level but not on a per-port basis for the packet processor.

(PORT.CR1.MEIM must be set for global error insertion to insert a packet error.)

Bits 14 to 8: Transmit Errored Packet Insertion Rate (TPER[6:0]) – These seven bits indicate the rate at which

errored packets are to be output. One out of every x * 10y packets is to be an errored packet. TPER[3:0] is the

value x, and TPER[6:4] is the value y, which has a maximum value of 6. If TPER[3:0] has a value of 0h errored

packet insertion is disabled. If TPER[6:4] has a value of 6xh or 7xh the errored packet rate will be x * 106. A

TPER[6:0] value of 01h results in every packet being errored. A TPER[6:0] value of 0Fh results in every 15th packet

being errored. A TPER[6:0] value of 11h result in every 10th packet being errored. Errored packet insertion starts

when the PP.TEPC register is written with a TPER[3:0] value that is non-zero. If the PP.TEPC register is written to

during the middle of an errored packet insertion process, the current process is halted, and a new process will be

started using the new values of TPER[6:0] and TPEN[7:0}. Errored packet insertion ends when TPEN[7:0] errored

packets have been transmitted.

Bits 7 to 0: Transmit Errored Packet Insertion Number (TPEN[7:0]) – These eight bits indicate the total number

of errored packets to be transmitted. A value of FFh results in continuous errored packet insertion at the specified

rate.

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Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Bit # 7 6 5 4 3 2 1 0

Name — — — — — — — TEPF

Bit 0: Transmit Errored Packet Insertion Finished (TEPF) – This bit is set when the number of errored packets

indicated by the TPEN[7:0] bits in the PP.TEPC register have been transmitted. This bit is cleared when errored

packet insertion is disabled, or a new errored packet insertion process is initiated.

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Bit # 7 6 5 4 3 2 1 0

Name — — — — — — — TEPFL

Bit 0: Transmit Errored Packet Insertion Finished Latched (TEPFL) – This bit is set when the TEPF bit in the

PP.TSR register transitions from zero to one.

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name — — — — — — — TEPFIE

Default 0 0 0 0 0 0 0 0

Bit 0: Transmit Errored Packet Insertion Finished Interrupt Enable (TEPFIE) – This bit enables an interrupt if

the TEPFL bit in the PP.TSRL register is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

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Bit # 15 14 13 12 11 10 9 8

Name TPC15 TPC14 TPC13 TPC12 TPC11 TPC10 TPC9 TPC8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name TPC7 TPC6 TPC5 TPC4 TPC3 TPC2 TPC1 TPC0

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Transmit Packet Count (TPC[15:0]) – Lower 16 bits of 24 bits. Register description follows next

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name TPC23 TPC22 TPC21 TPC20 TPC19 TPC18 TPC17 TPC16

Default 0 0 0 0 0 0 0 0

Bits 7 to 0: Transmit Packet Count (TPC[23:16]) - Upper 8 bits of Register.

Transmit Packet Count (TPC[23:0]) – These 24 bits indicate the number of packets extracted from the Transmit

FIFO and output in the outgoing data stream. This register is updated via the PMU signal (see Section 10.4.5).

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Bit # 15 14 13 12 11 10 9 8

Name TBC15 TBC14 TBC13 TBC12 TBC11 TBC10 TBC9 TBC8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name TBC7 TBC6 TBC5 TBC4 TBC3 TBC2 TBC1 TBC0

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Transmit Byte Count (TBC[15:0]) – Lower 16 bits of 32 bits. Register description follows next

Bit # 15 14 13 12 11 10 9 8

Name TBC31 TBC30 TBC29 TBC28 TBC27 TBC26 TBC25 TBC24

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name TBC23 TBC22 TBC21 TBC20 TBC19 TBC18 TBC17 TBC16

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Transmit Byte Count (TBC[31:16]) - Upper 16 bits of 32 bits.

Transmit Byte Count (TBC[31:0]) – These 32 bits indicate the number of packet bytes inserted in the outgoing

data stream. This register is updated via the PMU signal (see Section 10.4.5).

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12.14.4 Receive Packet Processor Register Map

The receive packet processor block has 17 registers.

Table 12-51. Receive Packet Processor Register Map

ADDRESS REGISTER REGISTER DESCRIPTION

(1,3,5,7)C0h PP.RCR Packet Processor Receive Control Register

(1,3,5,7)C2h PP.RMPSC Packet Processor Receive Maximum Packet Size Control Register

(1,3,5,7)C4h — Reserved

(1,3,5,7)C6h — Reserved

(1,3,5,7)C8h — Reserved

(1,3,5,7)CAh — Reserved

(1,3,5,7)CCh — Reserved

(1,3,5,7)CEh PP.RSR Packet Processor Receive Status Register

(1,3,5,7)D0h PP.RSRL Packet Processor Receive Status Register Latched

(1,3,5,7)D2h PP.RSRIE Packet Processor Receive Status Register Interrupt Enable

(1,3,5,7)D4h PP.RPCR1 Packet Processor Receive Packet Count Register 1

(1,3,5,7)D6h PP.RPCR2 Packet Processor Receive Packet Count Register 2

(1,3,5,7)D8h PP.RFPCR1 Packet Processor Receive FCS Errored Packet Count Register 1

(1,3,5,7)DAh PP.RFPCR2 Packet Processor Receive FCS Errored Packet Count Register 2

(1,3,5,7)DCh PP.RAPCR1 Packet Processor Receive Aborted Packet Count Register 1

(1,3,5,7)DEh PP.RAPCR2 Packet Processor Receive Aborted Packet Count Register 2

(1,3,5,7)E0h PP.RSPCR1 Packet Processor Receive Size Violation Packet Count Register 1

(1,3,5,7)E2h PP.RSPCR2 Packet Processor Receive Size Violation Packet Count Register 2

(1,3,5,7)E4h — Reserved

(1,3,5,7)E6h — Reserved

(1,3,5,7)E8h PP.RBCR1 Packet Processor Receive Byte Count Register 1

(1,3,5,7)EAh PP.RBCR2 Packet Processor Receive Byte Count Register 2

(1,3,5,7)ECh PP.REBCR1 Packet Processor Receive Errored Byte Count Register 1

(1,3,5,7)EEh PP.REBCR2 Packet Processor Receive Errored Byte Count Register 2

(1,3,5,7)F0h — Unused

(1,3,5,7)F2h — Unused

(1,3,5,7)F4h — Unused

(1,3,5,7)F6h — Unused

(1,3,5,7)F8h — Unused

(1,3,5,7)FAh — Unused

(1,3,5,7)FCh — Unused

(1,3,5,7)FEh — Unused

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12.14.4.1 Register Bit Descriptions

Bit # 15 14 13 12 11 10 9 8

Name RMNS7 RMNS6 RMNS5 RMNS4 RMNS3 RMNS2 RMNS1 RMNS0

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name Reserved Reserved RFPD RF16 RFED RDD RBRE RPTE

Default 0 0 0 0 0 0 0 0

Bits 15 to 8: Receive Minimum Packet Size (RMNS[7:0]) – These eight bits indicate the minimum allowable

packet size in bytes. The size includes the FCS bytes, but excludes bit/byte stuffing. Note: In FCS-32 mode,

packets with six bytes are the minimum packet size allowed, in FCS-16 mode, packets with four bytes are the

minimum packet size allowed, and when FCS processing is disabled, packets with two bytes are the minimum

packet size allowed. Packets less than the minimum size will be aborted.

Bit 5: Receive FCS Processing Disable (RFPD) – When 0, FCS processing is performed (the packets have an

FCS appended). When 1, FCS processing is disabled (the packets do not have an FCS appended).

Bit 4: Receive FCS-16 Enable (RF16) – When 0, the error checking circuit uses a 32-bit FCS. When 1, the error

checking circuit uses a 16-bit FCS. This bit is ignored when FCS processing is disabled.

Bit 3: Receive FCS Extraction Disable (RFED) – When 0, the FCS bytes are discarded. When 1, the FCS bytes

are passed on. This bit is ignored when FCS processing is disabled.

Bit 2: Receive Descrambling Disable (RDD) – When 0, descrambling is performed. When 1, descrambling is

disabled.

Bit 1: Receive Bit Reordering Enable (RBRE) – When 0, bit reordering is disabled (The first bit received is stored

in the MSB of the receive FIFO byte). When 1, bit reordering is enabled (The first bit received is stored in the LSB

of the receive FIFO byte).

Bit 0: Receive Pass-Through Enable (RPTE) – When 0, pass-through mode is disabled and packet processing is

enabled. When 1, pass-through mode is enabled, and all packet-processing functions except descrambling and bit

reordering are disabled.

Bit # 15 14 13 12 11 10 9 8

Name RMX15 RMX14 RMX13 RMX12 RMX11 RMX10 RMX9 RMX8

Default 0 0 0 0 0 1 1 0

Bit # 7 6 5 4 3 2 1 0

Name RMX7 RMX6 RMX5 RMX4 RMX3 RMX2 RMX1 RMX0

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Receive Maximum Packet Size (RMX[15:0]) – These 16 bits indicate the maximum allowable

packet size in bytes. The size includes the FCS bytes, but excludes bit/byte stuffing. Note: If the maximum packet

length is less than the minimum packet length, all packets will be aborted. When packet processing is disabled,

these 16 bits indicate the "packet" size the incoming data is to be broken into.

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Bit # 15 14 13 12 11 10 9 8

Name — — — — Reserved Reserved Reserved Reserved

Bit # 7 6 5 4 3 2 1 0

Name — — — — — REPC RAPC RSPC

Bit 2: Receive FCS Errored Packet Count (REPC) – This read-only bit indicates that the receive FCS errored

packet count is non-zero.

Bit 1: Receive Aborted Packet Count (RAPC) – This read-only bit indicates that the receive aborted packet count

is non-zero.

Bit 0: Receive Size Violation Packet Count (RSPC) – This read-only bit indicates that the receive size violation

packet count is non-zero.

Bit # 15 14 13 12 11 10 9 8

Name — — — — Reserved Reserved Reserved Reserved

Bit # 7 6 5 4 3 2 1 0

Name REPL RAPL RIPDL RSPDL RLPDL REPCL RAPCL RSPCL

Bit 7: Receive FCS Errored Packet Latched (REPL) – This bit is set when a packet with an errored FCS is

detected.

Bit 6: Receive Aborted Packet Latched (RAPL) – This bit is set when a packet with an abort indication is

detected.

Bit 5: Receive Invalid Packet Detected Latched (RIPDL) – This bit is set when a packet with a non-integer

number of bytes is detected.

Bit 4: Receive Small Packet Detected Latched (RSPDL) – This bit is set when a packet smaller than the

minimum packet size is detected.

Bit 3: Receive Large Packet Detected Latched (RLPDL) – This bit is set when a packet larger than the maximum

packet size is detected.

Bit 2: Receive FCS Errored Packet Count Latched (REPCL) – This bit is set when the REPC bit in the RPPSR

Bit 1: Receive Aborted Packet Count Latched (RAPCL) – This bit is set when the RAPC bit in the RPPSR

Bit 0: Receive Size Violation Packet Count Latched (RSPCL) – This bit is set when the RSPC bit in the RPPSR

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Bit # 15 14 13 12 11 10 9 8

Name — — — — Reserved Reserved Reserved Reserved

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name REPIE RAPIE RIPDIE RSPDIE RLPDIE REPCIE RAPCIE RSPCIE

Default 0 0 0 0 0 0 0 0

Bit 7: Receive FCS Errored Packet Interrupt Enable (REPIE) – This bit enables an interrupt if the REPL bit in the

PP.RSRL register is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 6: Receive Aborted Packet Interrupt Enable (RAPIE) – This bit enables an interrupt if the RAPL bit in the

PP.RSRL register is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 5: Receive Invalid Packet Detected Interrupt Enable (RIPDIE) – This bit enables an interrupt if the RIPDL bit

in the PP.RSRL register is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 4: Receive Small Packet Detected Interrupt Enable (RSPDIE) – This bit enables an interrupt if the RSPDL bit

in the PP.RSRL register is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 3: Receive Large Packet Detected Interrupt Enable (RLPDIE) – This bit enables an interrupt if the RLPDL bit

in the PP.RSRL register is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 2: Receive FCS Errored Packet Count Interrupt Enable (REPCIE) – This bit enables an interrupt if the

REPCL bit in the PP.RSRL register is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

Must be set low when the packets do not have a FCS appended.

0 = interrupt disabled

1 = interrupt enabled

Bit 1: Receive Aborted Packet Count Interrupt Enable (RAPCIE) – This bit enables an interrupt if the RAPCL bit

in the PP.RSRL register is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

Bit 0: Receive Size Violation Packet Count Interrupt Enable (RSPCIE) – This bit enables an interrupt if the

RSPCL bit in the PP.RSRL register is set and the bit in GL.ISRIE.PSRIE[4:1] that corresponds to this port is set.

0 = interrupt disabled

1 = interrupt enabled

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Bit # 15 14 13 12 11 10 9 8

Name RPC15 RPC14 RPC13 RPC12 RPC11 RPC10 RPC9 RPC8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RPC7 RPC6 RPC5 RPC4 RPC3 RPC2 RPC1 RPC0

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Receive Packet Count (RPC[15:0]) – Lower 16 bits of 24 bits. Register description follows next

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RPC23 RPC22 RPC21 RPC20 RPC19 RPC18 RPC17 RPC16

Default 0 0 0 0 0 0 0 0

Bits 7 to 0: Receive Packet Count (RPC[23:16]) - Upper 8 bits of Register.

Receive Packet Count (RPC[23:0]) – These 24 bits indicate the number of packets stored in the receive FIFO

without an abort indication. Note: Packets discarded due to system loopback or an overflow condition will be

included in this count. This register is updated via the PMU signal (see Section 10.4.5).

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Bit # 15 14 13 12 11 10 9 8

Name RFPC15 RFPC14 RFPC13 RFPC12 RFPC11 RFPC10 RFPC9 RFPC8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RFPC7 RFPC6 RFPC5 RFPC4 RFPC3 RFPC2 RFPC1 RFPC0

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Receive FCS Errored Packet Count (RFPC[15:0]) – Lower 16 bits of 24 bits. Register description

follows next register.

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RFPC23 RFPC22 RFPC21 RFPC20 RFPC19 RFPC18 RFPC17 RFPC16

Default 0 0 0 0 0 0 0 0

Bits 7 to 0: Receive FCS Errored Packet Count (RFPC[7:0])

Receive FCS Errored Packet Count (RFPC[23:0]) – These 24 bits indicate the number of packets received with a

FCS error. The byte count for these packets is included in the receive aborted byte count register PP.REBCR.

This register is updated via the PMU signal (see Section 10.4.5).

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Bit # 15 14 13 12 11 10 9 8

Name RAPC15 RAPC14 RAPC13 RAPC12 RAPC11 RAPC10 RAPC9 RAPC8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RAPC7 RAPC6 RAPC5 RAPC4 RAPC3 RAPC2 RAPC1 RAPC0

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Receive Aborted Packet Count (RAPC[15:0]) – Lower 16 bits of 24 bits. Register description

follows next register.

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RAPC23 RAPC22 RAPC21 RAPC20 RAPC19 RAPC18 RAPC17 RAPC16

Default 0 0 0 0 0 0 0 0

Bits 7 to 0: Receive Aborted Packet Count (RAPC[23:16]) - Upper 8 bits of Register.

Receive Aborted Packet Count (RAPC[23:0]) – These 24 bits indicate the number of packets received with a

packet abort indication. The byte count for these packets is included in the receive aborted byte count register

PP.REBCR.

This register is updated via the PMU signal (see Section 10.4.5).

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Bit # 15 14 13 12 11 10 9 8

Name RSPC15 RSPC14 RSPC13 RSPC12 RSPC11 RSPC10 RSPC9 RSPC8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RSPC7 RSPC6 RSPC5 RSPC4 RSPC3 RSPC2 RSPC1 RSPC0

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Receive Size Violation Packet Count (RSPC[15:0]) – Lower 16 bits of 24 bits. Register description

follows next register.

Bit # 15 14 13 12 11 10 9 8

Name — — — — — — — —

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RSPC23 RSPC22 RSPC21 RSPC20 RSPC19 RSPC18 RSPC17 RSPC16

Default 0 0 0 0 0 0 0 0

Bits 7 to 0: Receive Size Violation Packet Count (RSPC[23:16]) - Upper 8 bits of Register.

Receive Size Violation Packet Count (RSPC[23:0]) – These 24 bits indicate the number of packets received with

a packet size violation (below minimum, above maximum, or non-integer number of bytes). The byte count for

these packets is included in the receive aborted byte count register PP.REBCR.

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Bit # 15 14 13 12 11 10 9 8

Name RBC15 RBC14 RBC13 RBC12 RBC11 RBC10 RBC9 RBC8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RBC7 RBC6 RBC5 RBC4 RBC3 RBC2 RBC1 RBC0

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Receive Byte Count (RBC[15:0]) – Lower 16 bits of 32 bits. Register description follows next

Bit # 15 14 13 12 11 10 9 8

Name RBC31 RBC30 RBC29 RBC28 RBC27 RBC26 RBC25 RBC24

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name RBC23 RBC22 RBC21 RBC20 RBC19 RBC18 RBC17 RBC16

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Receive Byte Count (RBC[31:16]) - Upper 16 bits of 32 bits.

Receive Byte Count (RBC[31:0]) – These 32 bits indicate the number of bytes contained in packets stored in the

receive FIFO without an error indication. Note: Bytes discarded due to FCS extraction, system loopback, FIFO

reset, or an overflow condition may be included in this count. This register is updated via the PMU signal (see

Section 10.4.5).

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Bit # 15 14 13 12 11 10 9 8

Name REBC15 REBC14 REBC13 REBC12 REBC11 REBC10 REBC9 REBC8

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name REBC7 REBC6 REBC5 REBC4 REBC3 REBC2 REBC1 REBC0

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Receive Errored Byte Count (REBC[15:0]) – Lower 16 bits of 32 bits. Register description follows

next register.

Bit # 15 14 13 12 11 10 9 8

Name REBC31 REBC30 REBC29 REBC28 REBC27 REBC26 REBC25 REBC24

Default 0 0 0 0 0 0 0 0

Bit # 7 6 5 4 3 2 1 0

Name REBC23 REBC22 REBC21 REBC20 REBC19 REBC18 REBC17 REBC16

Default 0 0 0 0 0 0 0 0

Bits 15 to 0: Receive Errored Byte Count (REBC[31:16]) - Upper 16 bits of 32 bits.

Receive Errored Byte Count (REBC[31:0]) – These 32 bits indicate the number of bytes contained in packets

stored in the receive FIFO with an error indication. Note: Bytes discarded due to FCS extraction, system loopback,

FIFO reset, or an overflow condition may be included in this count. This register is updated via the PMU signal (see

Section 10.4.5).

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372

13 JTAG INFORMATION

13.1 JTAG Description

This device supports the standard instruction codes SAMPLE/PRELOAD, BYPASS, and EXTEST. Optional public

instructions included are HIGHZ, CLAMP, and IDCODE. The device contains the following items, which meet the

requirements set by the IEEE 1149.1 Standard Test Access Port (TAP) and Boundary Scan Architecture:

Test Access Port (TAP)

TAP Controller

Instruction Register

Bypass Register

Boundary Scan Register

Device Identification Register

The Test Access Port has the necessary interface pins, namely JTCLK, JTDI, JTDO, and JTMS, and the optional

JTRST input. Details on these pins can be found in Section 8. See IEEE 1149.1-1990, IEEE 1149.1a-1993, and

IEEE 1149.1b-1994 for details about the Boundary Scan Architecture and the Test Access Port.

Figure 13-1. JTAG Block Diagram

Boundary Scan

Identification

Bypass

Instruction

Test Access Port

Controller

Mux

Select

Tri-State

JTDI

10K

JTMS

10K

JTCLK JTRST*

10K

JTDO

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13.2 JTAG TAP Controller State Machine Description

This section covers the details on the operation of the Test Access Port (TAP) Controller State Machine. See

Figure 13-2 for details on each of the states described below. The TAP controller is a finite state machine that

responds to the logic level at JTMS on the rising edge of JTCLK.

Figure 13-2. JTAG TAP Controller State Machine

Test-Logic-Reset

Run-Test/Idle Select

DR-Scan

Capture-DR

Shift-DR

Exit1- DR 1

Pause-DR

Exit2-DR

Update-DR

Select

IR-Scan

Capture-IR

Shift-IR

Exit1-IR 1

Pause-IR

Exit2-IR

Update-IR

Test-Logic-Reset. When JTRST is changed from low to high, the TAP controller starts in the Test-Logic-Reset

state, and the Instruction Register is loaded with the IDCODE instruction. All system logic and I/O pads on the

device operate normally. This state can also be reached from any other state by holding JTMS high and clocking

JTCLK five times.

Run-Test-Idle. Run-Test-Idle is used between scan operations or during specific tests. The Instruction Register

and Test Register remain idle.

Select-DR-Scan. All test registers retain their previous state. With JTMS low, a rising edge of JTCLK moves the

controller into the Capture-DR state and initiates a scan sequence. JTMS high moves the controller to the Select-

IR-Scan state.

Capture-DR. Data may be parallel loaded into the Test Data register selected by the current instruction. If the

instruction does not call for a parallel load or the selected register does not allow parallel loads, the Test Register

remains at its current value. On the rising edge of JTCLK, the controller goes to the Shift-DR state if JTMS is low or

to the Exit1-DR state if JTMS is high.

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374

Shift-DR. The Test Data Register selected by the current instruction is connected between JTDI and JTDO and

shifts data one stage toward its serial output on each rising edge of JTCLK. If a Test Register selected by the

current instruction is not placed in the serial path, it maintains its previous state.

Exit1-DR. While in this state, a rising edge on JTCLK with JTMS high puts the controller in the Update-DR state

that terminates the scanning process. A rising edge on JTCLK with JTMS low puts the controller in the Pause-DR

state.

Pause-DR. Shifting of the Test registers is halted while in this state. All Test registers selected by the current

instruction retain their previous state. The controller remains in this state while JTMS is low. A rising edge on

JTCLK with JTMS high puts the controller in the Exit2-DR state.

Exit2-DR. While in this state, a rising edge on JTCLK with JTMS high puts the controller in the Update-DR state

and terminate the scanning process. A rising edge on JTCLK with JTMS low puts the controller in the Shift-DR

state.

Update-DR. A falling edge on JTCLK while in the Update-DR state latches the data from the shift register path of

the Test registers into the data output latches. This prevents changes at the parallel output due to changes in the

shift register. A rising edge on JTCLK with JTMS low, puts the controller in the Run-Test-Idle state. With JTMS

high, the controller enters the Select-DR-Scan state.

Select-IR-Scan. All Test registers retain their previous state. The Instruction register remains unchanged during

this state. With JTMS low, a rising edge on JTCLK moves the controller into the Capture-IR state and initiates a

scan sequence for the Instruction register. JTMS high during a rising edge on JTCLK puts the controller back into

the Test-Logic-Reset state.

Capture-IR. The Capture-IR state is used to load the shift register in the Instruction register with a fixed value of

001. This value is loaded on the rising edge of JTCLK. If JTMS is high on the rising edge of JTCLK, the controller

enters the Exit1-IR state. If JTMS is low on the rising edge of JTCLK, the controller enters the Shift-IR state.

Shift-IR. In this state, the shift register in the Instruction register is connected between JTDI and JTDO and shifts

data one stage for every rising edge of JTCLK toward the serial output. The parallel registers, as well as all Test

registers, remain at their previous states. A rising edge on JTCLK with JTMS high moves the controller to the Exit1-

IR state. A rising edge on JTCLK with JTMS low keeps the controller in the Shift-IR state while moving data one

stage through the Instruction shift register.

Exit1-IR. A rising edge on JTCLK with JTMS low puts the controller in the Pause-IR state. If JTMS is high on the

rising edge of JTCLK, the controller enters the Update-IR state and terminate the scanning process.

Pause-IR. Shifting of the Instruction register is halted temporarily. With JTMS high, a rising edge on JTCLK puts

the controller in the Exit2-IR state. The controller remains in the Pause-IR state if JTMS is low during a rising edge

on JTCLK.

Exit2-IR. A rising edge on JTCLK with JTMS high put the controller in the Update-IR state. The controller loops

back to the Shift-IR state if JTMS is low during a rising edge of JTCLK in this state.

Update-IR. The instruction shifted into the Instruction shift register is latched into the parallel output on the falling

edge of JTCLK as the controller enters this state. Once latched, this instruction becomes the current instruction. A

rising edge on JTCLK with JTMS low, puts the controller in the Run-Test-Idle state. With JTMS high, the controller

enters the Select-DR-Scan state.

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375

13.3 JTAG Instruction Register and Instructions

The instruction register contains a shift register as well as a latched parallel output and is 3 bits in length. When the

TAP controller enters the Shift-IR state, the instruction shift register is connected between JTDI and JTDO. While in

the Shift-IR state, a rising edge on JTCLK with JTMS low shifts data one stage toward the serial output at JTDO. A

rising edge on JTCLK in the Exit1-IR state or the Exit2-IR state with JTMS high moves the controller to the Update-

IR state. The falling edge of that same JTCLK latches the data in the instruction shift register to the instruction

parallel output. Instructions supported by the device and their respective operational binary codes are shown in

Table 13-1.

Table 13-1. JTAG Instruction Codes

INSTRUCTIONS SELECTED REGISTER INSTRUCTION CODES

EXTEST Boundary Scan 000

IDCODE Device Identification 001

SAMPLE/PRELOAD Boundary Scan 010

CLAMP Bypass 011

HIGHZ Bypass 100

—— Bypass 101

—— Bypass 110

BYPASS Bypass 111

SAMPLE/PRELOAD. This is a mandatory instruction for the IEEE 1149.1 specification. This instruction supports

two functions. The digital I/Os of the device can be sampled at the boundary scan register without interfering with

the normal operation of the device and the boundary scan register can be pre-loaded for the EXTEST instruction.

The positive edge of JTCLK in the Capture-DR state samples all digital input pins into the boundary scan register.

The boundary scan register is connected between JTDI and JTDO. The data on JTDI pin is clocked into the

boundary scan register and the data captured in the Capture-DR state is shifted out the TDO pin in the Shift-DR

state.

EXTEST. This is a mandatory instruction for the IEEE 1149.1 specification. This instruction allows testing of all

interconnections to the device. When the EXTEST instruction is latched in the instruction register, the following

actions occur. Once enabled by the Update-IR state, the parallel outputs of all digital output pins are driven

according to the values in the boundary scan registers on the positive edge of JTCLK. The boundary scan register

is connected between JTDI and JTDO. The positive edge of JTCLK in the Capture-DR state samples all digital

input pins into the boundary scan register. The negative edge of JTCLK in the Update-DR state causes all of the

digital output pins to be driven according to the values in the boundary scan registers that have been shifted in

during the Shift-DR state. The outputs are returned to their normal mode or HIZ mode at the positive edge of

JTCLK during the Update-IR state when an instruction other than EXTEST or CLAMP is activated.

BYPASS. This is a mandatory instruction for the IEEE 1149.1 specification. When the BYPASS instruction is

latched into the parallel instruction register, JTDI connects to JTDO through the 1-bit bypass test register. This

allows data to pass from JTDI to JTDO not affecting the device’s normal operation. This mode can be used to

bypass one or more chips in a system with multiple chips that have their JTAG scan chain connected in series. The

chips not in bypass can then be tested with the normal JTAG modes.

IDCODE. This is a mandatory instruction for the IEEE 1149.1 specification. When the IDCODE instruction is

latched into the parallel instruction register, the identification test register is selected. The device identification code

is loaded into the identification register on the rising edge of JTCLK following entry into the Capture-DR state. Shift-

DR can be used to shift the identification code out serially through JTDO. During Test-Logic-Reset, the

identification code is forced into the instruction register’s parallel output.

HIGHZ. All digital outputs are placed into a high-impedance state. The bypass register is connected between JTDI

and JTDO. The outputs are put into the HIZ mode when the HIZ instruction is loaded in the Update-IR state and on

the positive edge of JTCLK. The outputs are returned to their normal mode or driven from the boundary scan

CLAMP. All digital output pins output data from the boundary scan parallel output while connecting the bypass

instruction was not EXTEST, the outputs will be driven according to the values in the boundary scan register at the

DS3181/DS3182/DS3183/DS3184

376

positive edge of JTCLK in the Update-IR state. The typical use of this instruction is in a system that has the JTAG

scan chain of multiple chips connected in series, and all of the chips have their outputs initialized using the

EXTEST mode. Then some of the chips are left initialized using the CLAMP mode and others have their IO

controlled using the EXTEST mode. This reduces the size of the scan chain during the partial testing of the system.

13.4 JTAG ID Codes

Table 13-2. JTAG ID Codes

DEVICE REVISION

ID[31:28]

DEVICE CODE

ID[27:12]

MANUFACTURER’S CODE

ID[11:1]

REQUIRED

ID[0]

DS3181 Consult factory 0000000001001000 00010100001 1

DS3182 Consult factory 0000000001001001 00010100001 1

DS3183 Consult factory 0000000001001010 00010100001 1

DS3184 Consult factory 0000000001001011 00010100001 1

13.5 JTAG Functional Timing

This functional timing for the JTAG circuits shows:

• The JTAG controller starting from reset state.

• Shifting out the first 4 LSB bits of the IDCODE.

• Shifting in the BYPASS instruction (111) while shifting out the mandatory X01 pattern.

• Shifting the TDI pin to the TDO pin through the bypass shift register.

• An asynchronous reset occurs while shifting.

Figure 13-3. JTAG Functional Timing

JTCLK

JTRST

JTMS

JTDI

JTDO

(STATE) Reset

Run Test

Idle

Select DR

Scan

Capture

Shift

Exit1

Update

Select DR

Scan

Select IR

Scan

Capture

Shift IR Exit1

Update

Select DR

Scan

Capture

Shift

Test

Logic Idle

(INST) IDCODE BYPASS IDCODE

X X X

Output

Pin Output pin level change if in "EXTEST" instruction mode

13.6 IO Pins

All input, output, and in/out pins are in/out pins in JTAG mode.

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377

14 PIN ASSIGNMENT

Table 14-1 details the breakdown of the assigned pins for each device.

Table 14-1. Pin Assignment Breakdown

DS3184 DS3183 DS3182 DS3181

I/O Signals 275 245 215 185

Digital VDD 40 40 40 40

Analog VDD 13 13 13 13

VSS 68 68 68 68

Total 396 assigned

pins

366 assigned

pins

336 assigned

pins

306 assigned

pins

Figure 14-1. DS3184 Pin Assignments—400-Lead TE-PBGA

Note: Green indicates VSS, Red indicates VDD, and Yellow indicates system interface pins.

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20

AVSS VDD RPOS1 VDD_RX3 RXN3 TXN3 TSOFO1 TLCLK1

TPDENO

1 RPDAT3 RCLKO3 RLCLK3 TCLKO3 TCLKI3 RNEG3 TADR[1] TPRTY TADR[0] TEN* VSS

BMODE

ROHSOF

1 RNEG1 TCLKI1 RXP3 TXP3 TSOFI1 RLCLK1 TPDAT1

TPDENO

3 RSER3 RSOFO3 RPDENI3 TNEG3 RPOS3 RST* TMOD[0] TMOD[1] TDATA[9] VDD

CGPIO[5] GPIO[6] A[10] TPOS1 TPDENI1 VDD_JA3

TOHSOF

1 TOHCLK1 RPDAT1 TPDAT3 TLCLK3 TSOFO3 TSER3 TPOS3 TADR[4]

TDATA[21

]

TDATA[19

]

TDATA[20

]

TDATA[25

]TDATA[8]

DVDD_RX1 A[5] A[9] TNEG1

ROHCLK

1 RPDENI1 TCLKO1 TOH1 RCLKO1 ROH1 TOH3 TSOFI3 TPDENI3

ROHSOF

3 TADR[3]

TDATA[22

]

TDATA[26

]

TDATA[27

]TDXA[4]TDXA[2]

EA[1] A[4] A[8] JTRST* TOHEN1 TSER1 VDD_TX3 RSOFO1 RSER1 ROH3 TOHCLK3

TOHSOF

ROHCLK

3 TOHEN3 TADR[2]

TDATA[23

]

RDATA[2

0] TDXA[3] RDXA[4]

FRXN1 RXP1 JTCLK JTMS GPIO[1] VDD VDD VDD VSS VSS VSS VSS VDD VDD VDD

RDATA[3

RDATA[2

6] RDXA[3] RDXA[2]

TDATA[24

]

GVDD_JA1 A[3] A[7] JTDO GPIO[2] VDD VDD VDD VSS VSS VSS VSS VDD VDD VDD

RDATA[3

RDATA[2

5] REN*

RDATA[1

HA[0] A[2] A[6]

UNUSED

3 VDD VDD VDD VSS VSS VSS VSS VDD VDD VDD

RDATA[2

RDATA[1

JTXN1 TXP1 JTDI VDD_TX1 D[15] VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS

RDATA[2

1] RERR TSCLK

KCLKA RDY* RD* WR*

VDD_CLA

D VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS TSPA TDXA[1] RVAL RDXA[1] RPRTY

LCLKB CLKC CS* INT* WIDTH VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS REOP RSOX RMOD[0] RMOD[1] RDATA[0]

MTXN2 TXP2 TEST*

UNUSED

4 VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS

RDATA[1

1] RDATA[2] RDATA[1] RSCLK

NVDD_TX2 ALE D[6] D[11] VDD_JA2 VDD VDD VDD VSS VSS VSS VSS VDD VDD VDD

RDATA[1

0] RDATA[5] RDATA[4] RDATA[3]

PD[0] D[2] D[7] D[12] GPIO[4] VDD VDD VDD VSS VSS VSS VSS VDD VDD VDD

RDATA[1

3] RDATA[9] RDATA[8] RDATA[7] RDATA[6]

RRXN2 RXP2 HIZ* D[13] GPIO[3] VDD VDD VDD VSS VSS VSS VSS VDD VDD VDD

RDATA[1

TDATA[16

] RADR[2] RADR[1] RADR[0]

TVDD_RX2 D[3] D[8] D[14] TOHEN2 TSER2 VDD_TX4 RSOFO2 RSER2 ROH4 TOHCLK4

TOHSOF

ROHCLK

4TOHEN4

TDATA[30

]

TDATA[17

]

TDATA[18

] TDATA[1] RADR[4] RADR[3]

UD[1] D[4] D[9] TNEG2

ROHCLK

2 RPDENI2 TCLKO2 TOH2 RCLKO2 ROH2 TOH4 TSOFI4 TPDENI4

ROHSOF

TDATA[31

]

TDATA[29

]

TDATA[28

] TDATA[6] TDATA[3] TDATA[0]

VGPIO[7] GPIO[8] D[10] TPOS2 TPDENI2 VDD_JA4

TOHSOF

2 TOHCLK2 RPDAT2 TPDAT4 TLCLK4 TSOFO4 TSER4 TPOS4 TEOP

TDATA[15

]

TDATA[12

] TDATA[5] TDATA[4] TDATA[2]

WVDD D[5] RNEG2 TCLKI2 RXP4 TXP4 TSOFI2 RLCLK2 TPDAT2

TPDENO

4 RSER4 RSOFO4 RPDENI4 TNEG4 RPOS4 TSOX

TDATA[14

]

TDATA[11

]

TDATA[10

]TDATA[7]

VSS

ROHSOF

2 RPOS2 VDD_RX4 RXN4 TXN4 TSOFO2 TLCLK2

TPDENO

2 RPDAT4 RCLKO4 RLCLK4 TCLKO4 TCLKI4 RNEG4 TSX TERR

TDATA[13

] VDD VSS

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378

Figure 14-2. DS3183 Pin Assignments—400-Lead TE-PBGA

Note: Green indicates VSS, Red indicates VDD, Yellow indicates system interface pins, and blank cells indicate no connect balls.

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20

A VSS VDD RPOS1 VDD_RX3 RXN3 TXN3 TSOFO1 TLCLK1

TPDENO

1RPDAT3 RCLKO3 RLCLK3 TCLKO3 TCLKI3 RNEG3 TADR[1] TPRTY TADR[0] TEN* VSS

B MODE ROHSOF

1 RNEG1 TCLKI1 RXP3 TXP3 TSOFI1 RLCLK1 TPDAT1

TPDENO

3RSER3 RSOFO3 RPDENI3 TNEG3 RPOS3 RST* TMOD[0] TMOD[1] TDATA[9] VDD

C GPIO[5] GPIO[6] A[10] TPOS1 TPDENI1 VDD_JA3 TOHSOF

1 TOHCLK1 RPDAT1 TPDAT3 TLCLK3 TSOFO3 TSER3 TPOS3 TADR[4]

TDATA[21

] TDATA[19

] TDATA[20

] TDATA[25

]TDATA[8]

D VDD_RX1 A[5] A[9] TNEG1 ROHCLK

1 RPDENI1 TCLKO1 TOH1 RCLKO1 ROH1 TOH3 TSOFI3 TPDENI3

ROHSOF

3TADR[3]

TDATA[22

] TDATA[26

] TDATA[27

] TDXA[4] TDXA[2]

E A[1] A[4] A[8] JTRST* TOHEN1 TSER1 VDD_TX3 RSOFO1 RSER1 ROH3 TOHCLK3

TOHSOF

ROHCLK

3TOHEN3 TADR[2]

TDATA[23

] RDATA[2

7] RDATA[2

0] TDXA[3] RDXA[4]

F RXN1 RXP1 JTCLK JTMS GPIO[1] VDD VDD VDD VSS VSS VSS VSS VDD VDD VDD

RDATA[3

1] RDATA[2

6] RDXA[3] RDXA[2]

TDATA[24

]

G VDD_JA1 A[3] A[7] JTDO GPIO[2] VDD VDD VDD VSS VSS VSS VSS VDD VDD VDD

RDATA[3

0] RDATA[2

5] REN*

RDATA[1

H A[0] A[2] A[6] VDD VDD VDD VSS VSS VSS VSS VDD VDD VDD

RDATA[2

9] RDATA[2

4] RDATA[2

RDATA[1

J TXN1 TXP1 JTDI VDD_TX1 D[15] VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS

RDATA[2

8] RDATA[2

3] RDATA[2

1] RERR TSCLK

K CLKA RDY* RD* WR* VDD_CLA

D VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS TSPA TDXA[1] RVAL RDXA[1] RPRTY

L CLKB CLKC CS* INT* WIDTH VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS REOP RSOX RMOD[0] RMOD[1] RDATA[0]

M TXN2 TXP2 TEST* VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS

RDATA[1

5] RDATA[1

1] RDATA[2] RDATA[1] RSCLK

N VDD_TX2 ALE D[6] D[11] VDD_JA2 VDD VDD VDD VSS VSS VSS VSS VDD VDD VDD

RDATA[1

4] RDATA[1

0] RDATA[5] RDATA[4] RDATA[3]

P D[0] D[2] D[7] D[12] GPIO[4] VDD VDD VDD VSS VSS VSS VSS VDD VDD VDD

RDATA[1

3] RDATA[9] RDATA[8] RDATA[7] RDATA[6]

R RXN2 RXP2 HIZ* D[13] GPIO[3] VDD VDD VDD VSS VSS VSS VSS VDD VDD VDD

RDATA[1

2] TDATA[16

] RADR[2] RADR[1] RADR[0]

T VDD_RX2 D[3] D[8] D[14] TOHEN2 TSER2 RSOFO2 RSER2

TDATA[30

]

TDATA[17

] TDATA[18

] TDATA[1] RADR[4] RADR[3]

U D[1] D[4] D[9] TNEG2 ROHCLK

2 RPDENI2 TCLKO2 TOH2 RCLKO2 ROH2

TDATA[31

]

TDATA[29

] TDATA[28

] TDATA[6] TDATA[3] TDATA[0]

V GPIO[7] GPIO[8] D[10] TPOS2 TPDENI2 TOHSOF

2 TOHCLK2 RPDAT2 TEOP

TDATA[15

] TDATA[12

] TDATA[5] TDATA[4] TDATA[2]

W VDD D[5] RNEG2 TCLKI2 TSOFI2 RLCLK2 TPDAT2 TSOX TDATA[14

] TDATA[11

] TDATA[10

]TDATA[7]

VSS ROHSOF

2 RPOS2 TSOFO2 TLCLK2

TPDENO

2TSX TERR TDATA[13

] VDD VSS

Figure 14-3. DS3182 Pin Assignments—400-Lead TE-PBGA

Note: Green indicates VSS, Red indicates VDD, Yellow indicates system interface pins, and blank cells indicate no connect balls.

1234567891011121314151617181920

AVSS VDD RPOS1 TSOFO1 TLCLK1

TPDENO

1 TADR[1] TPRTY TADR[0] TEN* VSS

BMODE

ROHSOF

1 RNEG1 TCLKI1 TSOFI1 RLCLK1 TPDAT1 RST* TMOD[0] TMOD[1] TDATA[9] VDD

CGPIO[5] GPIO[6] A[10] TPOS1 TPDENI1

TOHSOF

1 TOHCLK1 RPDAT1 TADR[4]

TDATA[21

]

TDATA[19

]

TDATA[20

]

TDATA[25

]TDATA[8]

DVDD_RX1 A[5] A[9] TNEG1

ROHCLK

1 RPDENI1 TCLKO1 TOH1 RCLKO1 ROH1 TADR[3]

TDATA[22

]

TDATA[26

]

TDATA[27

]TDXA[4]TDXA[2]

EA[1] A[4] A[8] JTRST* TOHEN1 TSER1 RSOFO1 RSER1 TADR[2]

TDATA[23

]

RDATA[2

0] TDXA[3] RDXA[4]

FRXN1 RXP1 JTCLK JTMS GPIO[1] VDD VDD VDD VSS VSS VSS VSS VDD VDD VDD

RDATA[3

RDATA[2

6] RDXA[3] RDXA[2]

TDATA[24

]

GVDD_JA1 A[3] A[7] JTDO GPIO[2] VDD VDD VDD VSS VSS VSS VSS VDD VDD VDD

RDATA[3

RDATA[2

5] REN*

RDATA[1

HA[0] A[2] A[6] VDD VDD VDD VSS VSS VSS VSS VDD VDD VDD

RDATA[2

RDATA[1

JTXN1 TXP1 JTDI VDD_TX1 D[15] VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS

RDATA[2

1] RERR TSCLK

KCLKA RDY* RD* WR*

VDD

CLA

D VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS TSPA TDXA[1] RVAL RDXA[1] RPRTY

LCLKB CLKC CS* INT* WIDTH VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS REOP RSOX RMOD[0] RMOD[1] RDATA[0]

MTXN2 TXP2 TEST* VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS

RDATA[1

1] RDATA[2] RDATA[1] RSCLK

NVDD_TX2 ALE D[6] D[11] VDD_JA2 VDD VDD VDD VSS VSS VSS VSS VDD VDD VDD

RDATA[1

0] RDATA[5] RDATA[4] RDATA[3]

PD[0] D[2] D[7] D[12] GPIO[4] VDD VDD VDD VSS VSS VSS VSS VDD VDD VDD

RDATA[1

3] RDATA[9] RDATA[8] RDATA[7] RDATA[6]

RRXN2 RXP2 HIZ* D[13] GPIO[3] VDD VDD VDD VSS VSS VSS VSS VDD VDD VDD

RDATA[1

TDATA[16

] RADR[2] RADR[1] RADR[0]

TVDD_RX2 D[3] D[8] D[14] TOHEN2 TSER2 RSOFO2 RSER2

TDATA[30

]

TDATA[17

]

TDATA[18

] TDATA[1] RADR[4] RADR[3]

UD[1] D[4] D[9] TNEG2

ROHCLK

2 RPDENI2 TCLKO2 TOH2 RCLKO2 ROH2

TDATA[31

]

TDATA[29

]

TDATA[28

] TDATA[6] TDATA[3] TDATA[0]

VGPIO[7] GPIO[8] D[10] TPOS2 TPDENI2

TOHSOF

2 TOHCLK2 RPDAT2 TEOP

TDATA[15

]

TDATA[12

] TDATA[5] TDATA[4] TDATA[2]

WVDD D[5] RNEG2 TCLKI2 TSOFI2 RLCLK2 TPDAT2 TSOX

TDATA[14

]

TDATA[11

]

TDATA[10

]TDATA[7]

YVSS

ROHSOF

2 RPOS2 TSOFO2 TLCLK2

TPDENO

2 TSXTERR

TDATA[13

] VDD VSS

DS3181/DS3182/DS3183/DS3184

379

Figure 14-4. DS3181 Pin Assignments—400-Lead TE-PBGA

Note: Green indicates VSS, Red indicates VDD, Yellow indicates system interface pins, and blank cells indicate no connect balls.

1234567891011121314151617181920

AVSS VDD RPOS1 TSOFO1 TLCLK1

TPDENO

1 TADR[1] TPRTY TADR[0] TEN* VSS

BMODE

ROHSOF

1 RNEG1 TCLKI1 TSOFI1 RLCLK1 TPDAT1 RST* TMOD[0] TMOD[1] TDATA[9] VDD

CGPIO[5] GPIO[6] A[10] TPOS1 TPDENI1

TOHSOF

1 TOHCLK1 RPDAT1 TADR[4]

TDATA[21

]

TDATA[19

]

TDATA[20

]

TDATA[25

]TDATA[8]

DVDD_RX1 A[5] A[9] TNEG1

ROHCLK

1 RPDENI1 TCLKO1 TOH1 RCLKO1 ROH1 TADR[3]

TDATA[22

]

TDATA[26

]

TDATA[27

]TDXA[4]TDXA[2]

EA[1] A[4] A[8] JTRST* TOHEN1 TSER1 RSOFO1 RSER1 TADR[2]

TDATA[23

]

RDATA[2

0] TDXA[3] RDXA[4]

FRXN1 RXP1 JTCLK JTMS GPIO[1] VDD VDD VDD VSS VSS VSS VSS VDD VDD VDD

RDATA[3

RDATA[2

6] RDXA[3] RDXA[2]

TDATA[24

]

GVDD_JA1 A[3] A[7] JTDO GPIO[2] VDD VDD VDD VSS VSS VSS VSS VDD VDD VDD

RDATA[3

RDATA[2

5] REN*

RDATA[1

HA[0] A[2] A[6] VDD VDD VDD VSS VSS VSS VSS VDD VDD VDD

RDATA[2

RDATA[1

JTXN1 TXP1 JTDI VDD_TX1 D[15] VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS

RDATA[2

1] RERR TSCLK

KCLKA RDY* RD* WR*

VDD

CLA

D VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS TSPA TDXA[1] RVAL RDXA[1] RPRTY

LCLKB CLKC CS* INT* WIDTH VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS REOP RSOX RMOD[0] RMOD[1] RDATA[0]

MTXN2 TXP2 TEST* VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS

RDATA[1

1] RDATA[2] RDATA[1] RSCLK

N ALE D[6] D[11] VDD VDD VDD VSS VSS VSS VSS VDD VDD VDD

RDATA[1

0] RDATA[5] RDATA[4] RDATA[3]

PD[0] D[2] D[7] D[12] GPIO[4] VDD VDD VDD VSS VSS VSS VSS VDD VDD VDD

RDATA[1

3] RDATA[9] RDATA[8] RDATA[7] RDATA[6]

R HIZ* D[13] GPIO[3] VDD VDD VDD VSS VSS VSS VSS VDD VDD VDD

RDATA[1

TDATA[16

] RADR[2] RADR[1] RADR[0]

T D[3]D[8]D[14]

TDATA[30

]

TDATA[17

]

TDATA[18

] TDATA[1] RADR[4] RADR[3]

UD[1]D[4]D[9]

TDATA[31

]

TDATA[29

]

TDATA[28

] TDATA[6] TDATA[3] TDATA[0]

VGPIO[7]GPIO[8]D[10] TEOP

TDATA[15

]

TDATA[12

] TDATA[5] TDATA[4] TDATA[2]

WVDDD[5] TSOX

TDATA[14

]

TDATA[11

]

TDATA[10

]TDATA[7]

YVSS TSXTERR

TDATA[13

] VDD VSS

DS3181/DS3182/DS3183/DS3184

380

15 PACKAGE INFORMATION

(The package drawing(s) in this data sheet may not reflect the most current specifications. The package number provided for

each package is a link to the latest package outline information.)

15.1 400-Lead TE-PBGA (27mm x 27mm, 1.27mm Pitch) (56-G6003-003)

DS3181/DS3182/DS3183/DS3184

381

16 PACKAGE THERMAL INFORMATION

The 36 thermal VSS balls in the center 6X6 matrix must be thermally and electrically connected to the

internal GND plane of the PC board to achieve these thermal characteristics.

PARAMETER VALUE

Target Ambient Temperature Range -40°C to +85°C

Die Junction Temperature Range -40 to +125°C

Theta-JA, Still Air 12.6 °C/W (Note 1)

Note 1: Theta-JA is based on the package mounted on a 4-layer JEDEC board

and measured in a JEDEC test chamber.

DS3181/DS3182/DS3183/DS3184

382

17 DC ELECTRICAL CHARACTERISTICS

ABSOLUTE MAXIMUM RATINGS

Voltage Range on Any Input, Bidirectional, or Open-Drain

Output Lead with Respect to VSS…………………………………………………………………………..-0.3V to +5.5V

Supply Voltage (VDD) with Respect to VSS..………………………………………………………………....-0.3V to +3.63V

Ambient Operating Temperature Range……………………………………………………………………..-40°C to +85°C

Junction Operating Temperature Range……………………………………………………………………-40°C to +125°C

Storage Temperature Range………………………………………………………………………………...-55°C to +125°C

Soldering Temperature Range…..……………………………………………..See IPC/JEDEC J-STD-020 Specification

These are stress ratings only and functional operation of the device at these or any other conditions beyond those indicated in the operation

sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods of time can affect device

reliability. Ambient Operating Temperature Range is assuming the device is mounted on a JEDEC standard test board in a convection cooled

JEDEC test enclosure.

Note: The typical values listed below are not production tested.

Table 17-1. Recommended DC Operating Conditions

(VDD = 3.3V ±5%, Tj = -40°C to +85°C.)

PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS

Logic 1 VIH 2.0 5.5 V

Logic 0 VIL -0.3 +0.8 V

Supply ±5% VDD 3.135 3.300 3.465 V

Table 17-2. DC Electrical Characteristics

(Tj = -40°C to +85°C)

PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS

DS3184 760 850

DS3183 610

DS3182 448

Supply Current (VDD = 3.465V)

(Notes 1, 2) IDD

DS3181 280

DS3184 88 130

DS3183 96

DS3182 64

Power-Down Current (All DISABLE Bits

Set) (Note 2) IDDD

DS3181 32

Lead Capacitance CIO 7 pF

Input Leakage IIL -10 +10

µA

Input Leakage (Input Pins with Internal

Pullup Resistors) IILP -350 +10

µA

Output Leakage (when High Impedance) ILO -10 +10

µA

Output Voltage (IOH = -4.0mA) VOH 4mA outputs 2.4 V

Output Voltage (IOL = +4.0mA) VOL 4mA outputs 0.4 V

Output Voltage (IOH = -6.0mA) VOH 6mA outputs 2.4 V

Output Voltage (IOL = +6.0mA) VOL 6mA outputs 0.4 V

Note 1: Mode: STS-1 data rate, transmitting all ones on the LIU, all clocks = 52MHz, digital outputs without load.

Note 2: All outputs loaded with rated capacitance; all inputs between VDD and VSS; inputs with pullups connected to VDD.

DS3181/DS3182/DS3183/DS3184

383

Table 17-3. Output Pin Drive

PIN NAME TYPE DRIVE STRENGTH

(mA)

TLCLKn O 6

TPOSn /TDATn O 6

TNEGn/TOHMOn O 6

TXPn O N/A (analog)

TXNn O N/A (analog)

TOHCLKn O 4

TOHSOFn O 4

ROHn O 4

ROHCLKn O 4

ROHSOFn O 4

TPOHCLKn/

TCLKOn/TGCLKn O 6

TPOHSOFn/TSOFOn/

TDENn/TFOHENOn O 6

TPDATn O 6

TPDENOn O 6

RPOHn/RSERn O 6

RPOHCLKn/

RCLKOn/RGCLKn O 6

RPOHSOFn/RSOFOn/

RDENn/RFOHENOn O 6

TDXA[1]/TPXA Oz 6

TDXA[4:2] O 6

TSPA Oz 6

RDATA[31:0] Oz 6

RPRTY O 6

RDXA[1]/RPXA/RSX Oz 6

RDXA[4:2] O 6

RSOX Oz 6

REOP Oz 6

RVAL Oz 6

RMOD[1:0] Oz 6

RERR Oz 6

D[15:0] IO 4

RDY Oz 6

INT Oz 6

GPIO[7:0] IO 4

JTDO Oz 4

CLKB IO 6

CLKC IO 6

DS3181/DS3182/DS3183/DS3184

384

18 AC TIMING CHARACTERISTICS

There are several common AC characteristic definitions. These generic definitions are shown below in Figure 18-1,

Figure 18-2, Figure 18-3, and Figure 18-4. Definitions that are specific to a given interface are shown in that

interface’s subsection.

Figure 18-1. Clock Period and Duty Cycle Definitions

Clock

t2t2

Figure 18-2. Rise Time, Fall Time, and Jitter Definitions

Clock

t3 t3

t4/2

Figure 18-3. Hold, Setup, and Delay Definitions (Rising Clock Edge)

Clock

Din

t5 t6

Dout

DS3181/DS3182/DS3183/DS3184

385

Figure 18-4. Hold, Setup, and Delay Definitions (Falling Clock Edge)

Clock

Din

t5 t6

Dout

Figure 18-5. To/From High-Z Delay Definitions (Rising Clock Edge)

Clock

Dout

t8 t9

Figure 18-6. To/From High-Z Delay Definitions (Falling Clock Edge)

Clock

Dout

t8 t9

DS3181/DS3182/DS3183/DS3184

386

18.1 Fractional Port Characteristics

All AC timing characteristics are specified with a 25 pF capacitive load on all output pins, VIH = 2.4V and VIL = 0.8V.

The voltage threshold for all timing measurements is VDD/2. The generic timing definitions shown in Figure 18-1,

Figure 18-2, Figure 18-3, and Figure 18-6 apply to this interface.

Table 18-1. Fractional Port Timing

(VDD = 3.3V ±5%, Tj = -40°C to +85°C.)

PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS

CLK Period t1 (Note 1) 19.23 ns

CLK Clock Duty Cycle (t2/t1) t2/t1 (Note 2) 40 50 60 %

CLK Rise or Fall times (20% to 80%) t3 (Note 2) 4 ns

(Note 3) 3 ns

DIN to CLK Setup Time t5 (Note 4) 7 ns

(Note 3) 1 ns

CLK to DIN Hold Time t6 (Note 4) 1 ns

(Note 5) 2 11 ns

CLK to DOUT Delay t7 (Note 6) 2 9 ns

Note 1: Any mode, 52MHz TCLKIn, RLCLKn input clocks.

Note 2: Any mode, TCLKIn, RLCLKn input clocks.

Note 3: TCLKIn, RLCLKn clock inputs to TOHMIn/TSOFIn, TFOHn/TSERn, TFOHENIn, RFOHENIn inputs.

Note 4: TCLKOn, RCLKOn clock outputs to TOHMIn/TSOFIn, TFOHn/TSERn, TFOHENOn, RFOHENOn inputs.

Note 5: TCLKIn, RLCLKn clock input to TSOFOn/TDENn, RSERn, RSOFOn/RDENn, TPDENOn, TPDATn, and RPDATn outputs.

Note 6: TCLKOn, RCLKOn clock output to TSOFOn/TDENn, RSERn, RSOFOn/RDENn, TPDENOn, TPDATn and RPDATn outputs.

18.2 Line Interface AC Characteristics

All AC timing characteristics are specified with a 25 pF capacitive load on all output pins, VIH = 2.4V and VIL = 0.8V.

The voltage threshold for all timing measurements is VDD/2. The generic timing definitions shown in Figure 18-1,

Figure 18-2, Figure 18-3, and Figure 18-6 apply to this interface.

Table 18-2. Line Interface Timing

(VDD = 3.3V ±5%, Tj = -40°C to +85°C.)

PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS

CLK Period t1 (Note 1) 19.23 ns

CLK Clock Duty Cycle (t2/t1) t2/t1 (Note 2) 40 50 60 %

CLK Rise or Fall times (20% to 80 %) t3 (Note 2) 4 ns

DIN to CLK Setup Time t5 (Note 3) 4 ns

CLK to DIN Hold Time t6 (Note 3) 0 ns

(Note 4) 2 10 ns

CLK to DOUT Delay t7 (Note 5) 2 8 ns

Note 1: Any mode, 52MHz TCLKIn, RLCLKn input clocks.

Note 2: Any mode, TCLKIn, RLCLKn input clocks.

Note 3: RLCLKn clock inputs to RPOSn/RDATn, RNEGn/RLCVn/ROHMIn inputs.

Note 4: TCLKIn, RLCLKn clock input to TPOSn/TDATn, TNEGn/TOHMOn outputs.

Note 5: TLCLKn, TCLKOn, RCLKOn clock output to TPOSn/TDATn, TNEGn/TOHMOn outputs.

DS3181/DS3182/DS3183/DS3184

387

18.3 Miscellaneous Pin AC Characteristics

All AC timing characteristics are specified with a 25 pF capacitive load on all output pins, VIH = 2.4V and VIL = 0.8V.

The voltage threshold for all timing measurements is VDD/2. The generic timing definitions shown in

Figure 18-1 and Figure 18-2 apply to this interface.

Table 18-3. Miscellaneous Pin Timing

(VDD = 3.3V ±5%, Tj = -40°C to +85°C.)

PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS

Asynchronous Input High, Low Time t1, t2 (Note 1) 500 ns

Asynchronous Input Rise, Fall Time t3 (Note 1) 10 ns

Note 1: TMEI (GPIO), PMU (GPIO), 8KREFI(GPIO) and RST inputs.

18.4 Overhead Port AC Characteristics

All AC timing characteristics are specified with a 25 pF capacitive load on all output pins, VIH = 2.4V and VIL = 0.8.

The voltage threshold for all timing measurements is VDD/2. The generic timing definitions shown in Figure 18-1,

Figure 18-2, Figure 18-3, and Figure 18-6 apply to this interface.

Table 18-4. Overhead Port Timing

(VDD = 3.3V ±5%, Tj = -40°C to +125°C.)

PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS

CLK Period t1 (Note 1) 500 ns

CLK Clock High and Low Time t1, t2 (Note 1) 200 ns

DIN to CLK Setup Time t5 (Note 2) 20 ns

CLK to DIN Hold Time t6 (Note 2) 20 ns

CLK to DOUT Delay t7 (Note 3) -20 20 ns

Note 1: TOHCLKn, TPOHCLKn, ROHCLKn, RPOHCLKn output clocks.

Note 2: TOHCLKn, TPOHCLKn clock falling edge outputs to TOHn, TOHENn, TPOHn, TPOHENn inputs.

Note 3: TOHCLKn, TPOHCLKn, ROHCLKn, RPOHCLKn clock falling edge outputs to TOHSOFn, TPOHSOFn, ROHn, ROHSOF, RPOHn,

RPOHSOFn outputs.

DS3181/DS3182/DS3183/DS3184

388

18.5 System Interface AC Characteristics

The AC characteristics of the system interface depend upon the mode of the interface. While UTOPIA vs. POS-

PHY mode does not have an effect on the AC characteristics, L2 vs. L3 does. Therefore, there are two tables: one

for L2 (Table 18-5) and one for L3 (Table 18-6). The generic timing definitions shown in Figure 18-1, Figure 18-2,

Figure 18-3, and Figure 18-6 apply to this interface.

Table 18-5. System Interface L2 Timing

(VDD = 3.3V ±5%, Tj = -40°C to +125°C.)

SIGNAL NAME(S) SYMBOL DESCRIPTION MIN TYP MAX UNITS

RSCLK and TSCLK f1 Clock frequency (1/t1) (Note 1) 0 52 MHz

RSCLK and TSCLK t2/t1 Clock duty cycle (Note 1) 40 50 60 %

RSCLK and TSCLK t3 Rise/fall times (Notes 1, 2) 2 ns

RADR and REN t5 Hold time from RSCLK (Note 1) 0 ns

RADR and REN t6 Setup time to RSCLK (Note 1) 3.5 ns

RDATA, RPRTY, RPXA,

RSOX, REOP, RVAL,

RMOD, and RERR

t7 Delay from RSCLK (Notes 1, 3) 2 12 ns

RDATA, RPRTY, RPXA,

RSOX, REOP, RVAL,

RMOD, and RERR

t8 From high-Z delay from RSCLK

(Notes 1, 3) 2 12 ns

RDATA, RPRTY, RPXA,

RSOX, REOP, RVAL,

RMOD, and RERR

t9 To high-Z delay from RSCLK

(Notes 1, 3) 2 15 ns

TDATA, TPRTY, TADR,

TEN, TSOX, TEOP,

TMOD, and TERR

t5 Hold time from TSCLK (Note 1) 0 ns

TDATA, TPRTY, TADR,

TEN, TSOX, TEOP,

TMOD, and TERR

t6 Setup time to TSCLK (Note 1) 3.5 ns

TPXA and TSPA t7 Delay from TSCLK (Notes 1, 3) 2 12 ns

TPXA and TSPA t8 From high-Z delay from TSCLK

(Notes 1, 3) 2 12 ns

TPXA and TSPA t9 To high-Z delay from TSCLK

(Notes 1, 3) 2 15 ns

Note 1: The input/output timing reference level for all signals is VDD/2.

Note 2: Rise and fall times are measured at output side with the output unloaded. Rise time is measured from 20% to 80% VOH. Fall time

is measured from 80% to 20% VOH.

Note 3: These times are met with a 30pF, 300Ω load on the associated output pin.

DS3181/DS3182/DS3183/DS3184

389

Table 18-6. System Interface L3 Timing

(VDD = 3.3V ±5%, Tj = -40°C to +125°C.)

SIGNAL NAME(S) SYMBOL DESCRIPTION MIN TYP MAX UNITS

RSCLK and TSCLK f1 Clock frequency (1/t1) (Note 1) 0 66 MHz

RSCLK and TSCLK t2/t1 Clock duty cycle (Note 1) 40 50 60 %

RSCLK and TSCLK t3 Rise/fall times (Notes 1, 2) 2 ns

RADR and REN t5 Hold time from RSCLK (Note 1) 0 ns

RADR and REN t6 Setup time to RSCLK (Note 1) 3.5 ns

RDATA, RPRTY, RPXA,

RSOX, REOP, RVAL, RMOD,

and RERR

t7 Delay from RSCLK (Notes 1, 3) 2 9.5 ns

TDATA, TPRTY, TADR, TEN,

TSOX, TEOP, TMOD, and

TERR

t5 Hold time from TSCLK (Note 1) 0 ns

TDATA, TPRTY, TADR, TEN,

TSOX, TEOP, TMOD, and

TERR

t6 Setup time to TSCLK (Note 1) 3.5 ns

TPXA and TSPA t7 Delay from TSCLK (Notes 1, 3) 2 9.5 ns

Note 1: The input/output timing reference level for all signals is VDD/2.

Note 2: Rise and fall times are measured at output side with the output unloaded. Rise time is measured from 20% to 80% VOH. Fall time

is measured from 80% to 20% VOH.

Note 3: These times are met with a 30pF, 300Ω load on the associated output pin.

DS3181/DS3182/DS3183/DS3184

390

18.6 Micro Interface AC Characteristics

The AC characteristics for the external bus interface. This table references Figure 18-7and Figure 18-8.

Table 18-7. Micro Interface Timing

(VDD = 3.3 ±5%, Tj = -40°C to +125°C.)

SIGNAL NAME(S) SYMBOL DESCRIPTION MIN TYP MAX UNITS

A[N:0] t1a

Setup time to RD, WR, DS active (Note 1) 10 ns

ALE t1b

Setup time to RD, WR, DS active (Notes 1, 2) 10 ns

A[N:0] t2 Setup time to ALE inactive (Notes 1, 2) 2 ns

A[N:0] t3 Hold time from ALE inactive (Notes 1, 2) 2 ns

ALE t4 Pulse width (Notes 1, 2) 5 ns

A[N:0], ALE t5 Hold time from RD, WR, DS inactive (Note 1) 0 ns

CS, R/W t6 Setup time to RD, WR active (Note 1) 0 ns

D[15:0] t8

Output delay time from RD, DS active (Note 1) 30 ns

RD, WR, DS t9a Pulse width if not using RDY handshake

(Notes 1, 4) 35 ns

RD, WR, DS t9b Delay from RDY (Note 1) 15 ns

D[15:0] t10

Output deassert delay time from RD, DS

inactive (Notes 1, 3) 2 10 ns

CS, R/W t12 Hold time from RD, WR, DS inactive (Note 1) 0 ns

D[15:0] t13

Input setup time to WR, DS inactive (Note 1) 10 ns

D[15:0] t14

Input hold time from WR, DS inactive (Note 1) 5 ns

RDY t15

Delay time from RD, WR, DS active (Note 1) 5 ns

RDY t16

Delay time from RD, WR, DS inactive (Note 1) 0 ns

RDY t17

Enable delay time from CS active (Note 1) 12 ns

RDY t18

Disable delay time from CS inactive (Note 1) 10 ns

RDY t19 Ending high pulse width (Note 1) 1 ns

R/W t20 Setup time to DS active (Note 1) 2 ns

R/W t21 Hold time to DS inactive (Note 1) 2 ns

Note 1: The input/output timing reference level for all signals is VDD/2. Transition time (80/20%) on RD, WR and CS inputs is 5ns max.

Note 2: Multiplexed mode timing only.

Note 3: D[15:0] output valid until not driven.

Note 4: Timing required if not using RDY handshake.

DS3181/DS3182/DS3183/DS3184

391

Figure 18-7. Micro Interface Nonmultiplexed Read/Write Cycle

D[15:0]

RDY*

t8 t10

CS*

t6 t12

RD*

WR*

DS*

t9a

A[10:0]

t5t1a

D[15:0]

t13 t14

t15 t16

t17 t18

t19

R/W*

t20 t21

t9b

DS3181/DS3182/DS3183/DS3184

392

Figure 18-8. Micro Interface Multiplexed Read Cycle

D[15:0]

RDY*

t8 t10

CS* t6 t12

RD*

WR*

DS*

t9a

D[15:0]

t13 t14

t15 t16

t17 t18

t19

R/W*

t20 t21

A[10:0]

t1a

ALE

t2 t3

t1b

t9b

DS3181/DS3182/DS3183/DS3184

393

18.7 CLAD Jitter Characteristics

PARAMETER MIN TYP MAX UNITS

Intrinsic Jitter (UIP-P) 0.025 UIP-P

Intrinsic Jitter (UIRMS) 0.0045 UIRMS

Peak Jitter Transfer 1.75 dB

18.8 LIU Interface AC Characteristics

18.8.1 Waveform Templates

Table 18-8. DS3 Waveform Template

TIME (IN UNIT INTERVALS) NORMALIZED AMPLITUDE EQUATION

UPPER CURVE

-0.85 ≤ T ≤ -0.68 0.03

-0.68 ≤ T ≤ +0.36 0.5 {1 + sin[(π / 2)(1 + T / 0.34)]} + 0.03

0.36 ≤ T ≤ 1.4 0.08 + 0.407e-1.84(T - 0.36)

LOWER CURVE

-0.85 ≤ T ≤ -0.36 -0.03

-0.36 ≤ T ≤ +0.36 0.5 {1 + sin[(π / 2)(1 + T / 0.18)]} - 0.03

0.36 ≤ T ≤ 1.4 -0.03

Governing Specifications: ANSI T1.102 and Bellcore GR-499.

Table 18-9. DS3 Waveform Test Parameters and Limits

PARAMETER SPECIFICATION

Rate 44.736Mbps (±20ppm)

Line Code B3ZS

Transmission Medium Coaxial cable (AT&T 734A or equivalent)

Test Measurement Point At the end of 0 to 450ft of coaxial cable

Test Termination 75Ω (±1%) resistive

Pulse Amplitude Between 0.36V and 0.85V

Pulse Shape

An isolated pulse (preceded by two zeros and

followed by one or more zeros) falls within the

curves listed in Figure 18-9.

Unframed All-Ones Power Level at

22.368MHz Between -1.8dBm and +5.7dBm

Unframed All-Ones Power Level at

44.736MHz

At least 20dB less than the power measured at

22.368MHz

Pulse Imbalance of Isolated Pulses Ratio of positive and negative pulses must be

between 0.90 and 1.10.

DS3181/DS3182/DS3183/DS3184

394

Table 18-10. STS-1 Waveform Template

TIME (IN UNIT INTERVALS) NORMALIZED AMPLITUDE EQUATIONS

UPPER CURVE

-0.85 ≤ T ≤ -0.68 0.03

-0.68 ≤ T ≤ +0.26 0.5 {1 + sin[(π / 2)(1 + T / 0.34)]} + 0.03

0.26 ≤ T ≤ 1.4 0.1 + 0.61e-2.4(T - 0.26)

LOWER CURVE

-0.85 ≤ T ≤ -0.36 -0.03

-0.36 ≤ T ≤ +0.36 0.5 {1 + sin[(π / 2)(1 + T / 0.18)]} - 0.03

0.36 ≤ T ≤ 1.4 -0.03

Governing Specifications: Bellcore GR-253 and Bellcore GR-499 and ANSI T1.102.

Table 18-11. STS-1 Waveform Test Parameters and Limits

PARAMETER SPECIFICATION

Rate 51.840Mbps (±20ppm)

Line Code B3ZS

Transmission Medium Coaxial cable (AT&T 734A or equivalent)

Test Measurement Point At the end of 0 to 450ft of coaxial cable

Test Termination 75Ω (±1%) resistive

Pulse Amplitude 0.800V nominal (not covered in specs)

Pulse Shape

An isolated pulse (preceded by two zeros and

followed by one or more zeros) falls within the

curved listed in Table 18-10.

Unframed All-Ones Power Level

at 25.92MHz Between -1.8dBm and +5.7dBm

Unframed All-Ones Power Level

at 51.84MHz

At least 20dB less than the power measured at

25.92MHz.

DS3181/DS3182/DS3183/DS3184

395

Figure 18-9. E3 Waveform Template

-0.1

-0.2

0.1

0.2

0.3

0.4

0.5

0.6

0.7

0.8

0.9

1.0

1.1

1.2

TIME (ns)

G.703

TEMPLATE

OUTPUT LEVEL (V)

29.1

24.5

12.1

8.65

Table 18-12. E3 Waveform Test Parameters and Limits

PARAMETER SPECIFICATION

Rate 34.368Mbps (±20ppm)

Line Code HDB3

Transmission Medium Coaxial cable (AT&T 734A or equivalent)

Test Measurement Point At the transmitter

Test Termination 75Ω (±1%) resistive

Pulse Amplitude 1.0V (nominal)

Pulse Shape

An isolated pulse (preceded by two zeros and

followed by one or more zeros) falls within the

template shown in Figure 18-9.

Ratio of the Amplitudes of Positive and

Negative Pulses at the Center of the

Pulse Interval

0.95 to 1.05

Ratio of the Widths of Positive and

Negative Pulses at the Nominal Half

Amplitude

0.95 to 1.05

DS3181/DS3182/DS3183/DS3184

396

Figure 18-10. STS-1 Pulse Mask Template

DS3181/DS3182/DS3183/DS3184

397

Figure 18-11. DS3 Pulse Mask Template

18.8.2 LIU Input/Output Characteristics

Table 18-13. Receiver Input Characteristics—DS3 and STS-1 Modes

(VDD = 3.3V ±5%, TA = -40°C to +85°C.)

PARAMETER MIN TYP MAX UNITS

Receive Sensitivity (Length of Cable) 900 1200 ft

Signal-to-Noise Ratio, Interfering Signal Test (Notes 1, 2) 10

Input Pulse Amplitude, RMON = 0 (Notes 2, 3) 1000 mVpk

Input Pulse Amplitude, RMON = 1 (Notes 2, 3) 200 mVpk

Analog LOS Declare, RMON = 0 (Note 4) -24 -28 dB

Analog LOS Clear, RMON = 0 (Note 4) -16 -17 dB

Analog LOS Declare, RMON = 1 (Note 4) -38 dB

Analog LOS Clear, RMON = 1 (Note 4) -29 dB

Intrinsic Jitter Generation (Note 2) 0.03 UIP-P

DS3181/DS3182/DS3183/DS3184

398

Table 18-14. Receiver Input Characteristics—E3 Mode

(VDD = 3.3V ±5%, TA = -40°C to +85°C.)

PARAMETER MIN TYP MAX UNITS

Receive Sensitivity (Length of Cable) 900 1200 ft

Signal-to-Noise Ratio, Interfering Signal Test (Notes 1, 2) 12

Input Pulse Amplitude, RMON = 0 (Notes 2, 3) 1300 mVpk

Input Pulse Amplitude, RMON = 1 (Notes 2, 3) 260 mVpk

Analog LOS Declare, RMON = 0 (Note 4) -24 -28 dB

Analog LOS Clear, RMON = 0 (Note 4) -16 -17 dB

Analog LOS Declare, RMON = 1 (Note 4) -38 dB

Analog LOS Clear, RMON = 1 (Note 4) -29 dB

Intrinsic Jitter Generation (Note 2) 0.03 UIP-P

Note 1: An interfering signal (215 – 1 PRBS for DS3/STS-1, 223 – 1 PRBS for E3, B3ZS/HDB3 encoded, compliant waveshape, nominal bit

rate) is added to the wanted signal. The combined signal is passed through 0 to 900ft of coaxial cable and presented to the LIU.

This spec indicates the lowest signal-to-noise ratio that results in a bit error ratio <10-9.

Note 2: Not tested during production test.

Note 3: Measured on the line side (i.e., the BNC connector side) of the 1:2 receive transformer (Figure 1-1). During measurement, incoming

data traffic is unframed 215 – 1 PRBS for DS3/STS-1 and unframed 223 – 1 PRBS for E3.

Note 4: With respect to nominal 800mVpk signal for DS3/STS-1 and nominal 1000mVpk signal for E3.

Table 18-15. Transmitter Output Characteristics—DS3 and STS-1 Modes

(VDD = 3.3V ±5%, TA = -40°C to +85°C.)

PARAMETER MIN TYP MAX UNITS

DS3 Output Pulse Amplitude, TLBO = 0 (Note 5) 700 800 900 mVpk

DS3 Output Pulse Amplitude, TLBO = 1 (Note 5) 520 700 800 mVpk

CC52 Output Pulse Amplitude, TLBO = 0 (Note 5) 700 800 1100 mVpk

CC52 Output Pulse Amplitude, TLBO = 1 (Note 5) 520 700 850 mVpk

Ratio of Positive and Negative Pulse-Peak Amplitudes 0.9 1.1

DS3 Unframed All-Ones Power Level at 22.368MHz,

3kHz Bandwidth -1.8 +5.7 dBm

DS3 Unframed All-Ones Power Level at 44.736MHz vs.

Power Level at 22.368MHz, 3kHz Bandwidth -20 dB

Intrinsic Jitter Generation (Note 5) 0.02 0.05 UIP-P

Table 18-16. Transmitter Output Characteristics—E3 Mode

(VDD = 3.3V ±5%, TA = -40°C to +85°C.)

PARAMETER MIN TYP MAX UNITS

Output Pulse Amplitude (Note 5) 900 1000 1100 mVpk

Pulse Width 14.55 ns

Ratio of Positive and Negative Pulse Amplitudes

(at Centers of Pulses) 0.95 1.05

Ratio of Positive and Negative Pulse Widths

(at Nominal Half Amplitude) 0.95 1.05

Intrinsic Jitter Generation (Note 6) 0.02 0.05 UIP-P

Note 5: Measured on the line side (i.e., the BNC connector side) of the 2:1 transmit transformer (Figure 1-1).

Note 6: Measured with jitter-free clock applied to TCLK and a bandpass jitter filter with 10Hz and 800kHz cutoff frequencies. Not tested

during production test.

DS3181/DS3182/DS3183/DS3184

399

18.9 JTAG Interface AC Characteristics

All AC timing characteristics are specified with a 50pF capacitive load on JTDO pin and 25pF capacitive load on all

other digital output pins, VIH = 2.4V and VIL = 0.8. The voltage threshold for all timing measurements is VDD/2. The

generic timing definitions shown Figure 18-1, Figure 18-2, Figure 18-3, Figure 18-5, and Figure 18-6 apply to this

interface.

Table 18-17. JTAG Interface Timing

(VDD = 3.3V ±5%, Tj = -40°C to +125°C.)

SIGNAL NAME(S) SYMBOL DESCRIPTION MIN TYP MAX UNITS

JTCLK f1 Clock frequency (1/t1) 0 10 MHz

JTCLK t2 Clock high or low period 20 ns

JTCLK t3 Rise/fall times 5 ns

JTMS and JTDI t5 Hold time from JTCLK rising edge 10 ns

JTMS and JTDI t6 Setup time to JTCLK rising edge 10 ns

JTDO t7 Delay from JTCLK falling edge 0 30 ns

JTDO t8

Delay out of high-Z from JTCLK falling

edge 0 30 ns

JTDO t9 Delay to high-Z from JTCLK falling edge 0 30 ns

Any Digital Output t7 Delay from JTCLK falling edge (Note 1) 0 30 ns

Any Digital Output t7 Delay from JTCLK rising edge (Note 2) 0 30 ns

Any Digital Output t8 Delay out of high-Z from JTCLK falling

edge (Note 1) 0 30 ns

Any Digital Output t9 Delay into high-Z from JTCLK falling

edge (Note 1) 0 30 ns

Any Digital Output t8 Delay out of high-Z from JTCLK rising

edge (Notes 2, 3) 0 30 ns

Any Digital Output t9 Delay into high-Z from JTCLK rising

edge (Notes 2, 3) 0 30 ns

Note 1: Change during Update-DR state.

Note 2: Change during Update-IR state to or from EXTEST mode.

Note 3: Change during Update-IR state to or from HIZ mode.

DS3181/DS3182/DS3183/DS3184

400

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19 REVISION HISTORY

REVISION DESCRIPTION

061604 New product release (DS3184).

121704 New product release (DS3181).

010705 New product release (DS3182).

030205

New product release for DS3183 on 01/21/05.

Corrected register bit map (GL.RIORR).

Clarified CP.TCR.TDSE and RCR.RDDE to state that DSS mode is only applicable for unframed

modes and bit synchronous modes.

Added clarification to Receive LIU stating that the master reference clock will use TCLKIn if no

clock exists on CLKA, B, or C.

Removed Note 3 from the DC Electrical Characteristics table since A2 fixes the problem with

TEN and REN.

Changed Input leakage for inputs with internal pullups from -300µA to -350µA.

For DS3 and STS-1 and E3 Tables:

Changed "Analog LOS Declare, RMON = 0" from -24dB max to -24dB typ, and added

-28dB max.

Changed "Analog LOS Clear, RMON = 0" from -17dB min to -17dB typ, and added -16dB min.

Added TLCLK to reference clock sources for TPOS/TNEG in the Line Interface AC

Characteristics table.

Updated register bit map for PORT.INV.

Corrected wording of use of unused bits located in the Overall Register Map section.

Added IDD measurements for DS3181/DS3182/DS3183.

102406

Added lead-free package note to Ordering Information table (page 1).

Updated Package Information (Section 15).

Note: To obtain a revision history for the preliminary releases of this document, contact the factory at telecom.support@dalsemi.com.