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FEATURES
Complete E1 (CEPT) PCM-30/ISDN-PRI
Transceiver Functionality
On-Board Long- and Short-Haul Line
Interface for Clock/Data Recovery and
Waveshaping
32-Bit or 128-Bit Crystal-Less Jitter
Attenuator
Generates Line Build-Outs for Both 120
and 75 Lines
Frames to FAS, CAS, and CRC4 Formats
Dual On-Board Two-Frame Elastic Store Slip
Buffers That can Connect to Asynchronous
Backplanes Up to 8.192MHz
8-Bit Parallel Control Port That can be Used
Directly on Either Multiplexed or
Nonmultiplexed Buses (Intel or Motorola)
Extracts and Inserts CAS Signaling
Detects and Generates Remote and AIS
Alarms
Programmable Output Clocks for Fractional
E1, H0, and H12 Applications
Fully Independent Transmit and Receive
Functionality
Full Access to Both Si and Sa Bits Aligned
with CRC Multiframe
Four Separate Loopbacks for Testing
Functions
Large Counters for Bipolar and Code
Violations, CRC4 Codeword Errors, FAS
Errors, and E Bits
Pin Compatible with DS2152 T1 Enhanced
Single-Chip Transceiver
5V Supply; Low-Power CMOS
100-Pin, 14mm2 LQFP Package
PIN CONFIGURATION
ORDERING INFORMATION
PART TEMP
RANGE
PIN-
PACKAGE
DS2154L 0°C to +70°C 100 LQFP
DS2154L+ 0°C to +70°C 100 LQFP
DS2154LN -40°C to +85°C 100 LQFP
DS2154LN+ -40°C to +85°C 100 LQFP
+Denotes lead-free/RoHS-compliant package.
DS2154
Enhanced E1 Single-Chip Transceive
r
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1
100
DS2154
LQFP
(14mm x 14mm)
TOP VIEW
DS2154
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TABLE OF CONTENTS
1 DETAILED DESCRIPTION....................................................................................................6
1.1 INTRODUCTION .............................................................................................................................6
1.1.1 New Features......................................................................................................................................... 6
1.2 FUNCTIONAL DESCRIPTION ........................................................................................................... 7
1.3 READERS NOTE ...........................................................................................................................7
2 PIN DESCRIPTION................................................................................................................9
2.1 TRANSMIT SIDE DIGITAL PINS...................................................................................................... 11
2.2 RECEIVE SIDE DIGITAL PINS........................................................................................................12
2.3 PARALLEL CONTROL PORT PINS .................................................................................................13
2.4 LINE INTERFACE PINS ................................................................................................................. 14
2.5 SUPPLY PINS..............................................................................................................................14
3 PARALLEL PORT ...............................................................................................................20
4 CONTROL, ID, AND TEST REGISTERS ............................................................................20
4.1 FRAMER LOOPBACK....................................................................................................................29
4.2 LOCAL LOOPBACK.......................................................................................................................29
4.3 REMOTE LOOPBACK....................................................................................................................29
4.4 POWER-UP SEQUENCE ...............................................................................................................30
4.5 AUTOMATIC ALARM GENERATION ................................................................................................ 30
5 STATUS AND INFORMATION REGISTERS ......................................................................31
5.1 CRC4 SYNC COUNTER...............................................................................................................33
6 ERROR COUNT REGISTERS.............................................................................................39
6.1 BPV OR CODE VIOLATION COUNTER...........................................................................................39
6.2 CRC4 ERROR COUNTER ............................................................................................................40
6.3 E-BIT COUNTER .........................................................................................................................40
6.4 FAS ERROR COUNTER ............................................................................................................... 41
7 DS0 MONITORING FUNCTION ..........................................................................................42
8 SIGNALING OPERATION...................................................................................................46
8.1 PROCESSOR-BASED SIGNALING..................................................................................................46
8.2 HARDWARE-BASED SIGNALING ...................................................................................................49
8.2.1 Receive Side ........................................................................................................................................ 49
8.2.2 Transmit Side ....................................................................................................................................... 49
9 PER-CHANNEL CODE (IDLE) GENERATION AND LOOPBACK .....................................51
9.1 TRANSMIT SIDE CODE GENERATION............................................................................................51
9.1.1 Simple Idle Code Insertion and Per-Channel Loopback...................................................................... 51
9.1.2 Per-Channel Code Insertion ................................................................................................................ 52
9.2 RECEIVE SIDE CODE GENERATION ..............................................................................................53
10 CLOCK BLOCKING REGISTERS..................................................................................55
11 ELASTIC STORES OPERATION ...................................................................................57
11.1 RECEIVE SIDE ............................................................................................................................57
11.2 TRANSMIT SIDE ..........................................................................................................................57
12 ADDITIONAL (Sa) AND INTERNATIONAL (Si) BIT OPERATION................................58
12.1 HARDWARE SCHEME ..................................................................................................................58
12.2 INTERNAL REGISTER SCHEME BASED ON DOUBLE-FRAME ........................................................... 58
12.3 INTERNAL REGISTER SCHEME BASED ON CRC4 MULTIFRAME .....................................................61
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13 LINE INTERFACE FUNCTION .......................................................................................63
13.1 RECEIVE CLOCK AND DATA RECOVERY .......................................................................................64
13.2 TRANSMIT WAVESHAPING AND LINE DRIVING...............................................................................64
13.3 JITTER ATTENUATOR .................................................................................................................. 65
14 TIMING DIAGRAMS .......................................................................................................69
15 DC CHARACTERISTICS................................................................................................76
16 AC CHARACTERISTICS................................................................................................77
17 PACKAGE INFORMATION ............................................................................................87
17.1 100-PIN LQFP (56-G5002-000).................................................................................................87
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LIST OF FIGURES
Figure 1-1. DS2154 Enhanced E1 Single-Chip Transceiver ......................................................................8
Figure 13-1. External Analog Connections...............................................................................................66
Figure 13-2. Jitter Tolerance ....................................................................................................................67
Figure 13-3. Transmit Waveform Template..............................................................................................67
Figure 13-4. Jitter Attenuation ..................................................................................................................68
Figure 14-1. Receive Side Timing ............................................................................................................69
Figure 14-2. Receive Side Boundary Timing (with Elastic Store Disabled).............................................. 69
Figure 14-3. Receive Side 1.544MHz Boundary Timing (with Elastic Store Enabled) .............................70
Figure 14-4. Receive Side 2.048MHz Boundary Timing (with Elastic Store Enabled) .............................70
Figure 14-5. Transmit Side Timing ...........................................................................................................71
Figure 14-6. Transmit Side Boundary Timing...........................................................................................71
Figure 14-7. Transmit Side 1.544MHz Boundary Timing (with Elastic Store Enabled) ............................72
Figure 14-8. Transmit Side 2.048MHz Boundary Timing (with Elastic Store Enabled) ............................72
Figure 14-9. G.802 Timing........................................................................................................................73
Figure 14-10. Synchronization Flow Chart ...............................................................................................74
Figure 14-11. Transmit Data Flow ............................................................................................................75
Figure 16-1. Intel Bus Read AC Timing (BTS = 0/MUX = 1) ....................................................................77
Figure 16-2. Intel Bus Write AC Timing (BTS = 0/MUX = 1).....................................................................78
Figure 16-3. Motorola Bus AC Timing (BTS = 1/MUX = 1).......................................................................78
Figure 16-4. Receive Side AC Timing ......................................................................................................80
Figure 16-5. Receive System Side AC Timing .........................................................................................81
Figure 16-6. Receive Line Interface AC Timing........................................................................................81
Figure 16-7. Transmit Side AC Timing .....................................................................................................83
Figure 16-8. Transmit System Side AC Timing ........................................................................................84
Figure 16-9. Transmit Line Interface Side AC Timing...............................................................................84
Figure 16-10. Intel Bus Read AC Timing (BTS = 0/MUX = 0) ..................................................................85
Figure 16-11. Intel Bus Write AC Timing (BTS=0/MUX=0).......................................................................86
Figure 16-12. Motorola Bus Read AC Timing (BTS = 1/MUX = 0) ........................................................... 86
Figure 16-13. Motorola Bus Write AC Timing (BTS = 1/MUX = 0) ...........................................................86
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LIST OF TABLES
Table 2-1. Register Map ...........................................................................................................................15
Table 4-1. Sync/Resync Criteria...............................................................................................................21
Table 5-1. Alarm Criteria ..........................................................................................................................35
Table 13-1. Line Build-Out Select in LICR................................................................................................64
Table 13-2. Transformer Specifications....................................................................................................65
Table 15-1. Recommended DC Operating Conditions ............................................................................. 76
Table 15-2. Capacitance ..........................................................................................................................76
Table 15-3. DC Characteristics ................................................................................................................76
Table 16-1. AC Characteristics—Multiplexed Parallel Port (MUX = 1)..................................................... 77
Table 16-2. AC Characteristics—Receive Side........................................................................................79
Table 16-3. AC Characteristics—Transmit Side.......................................................................................82
Table 16-4. AC Characteristics—Nonmultiplexed Parallel Port (MUX = 0) ..............................................85
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1 DETAILED DESCRIPTION
The DS2154 enhanced single-chip transceiver (SCT) contains all the necessary functions for connection
to E1 lines. The device is an upward compatible version of the DS2153 single-chip transceiver. The on-
board clock/data recovery circuitry coverts the AMI/HDB3 E1 waveforms to an NRZ serial stream. The
DS2154 automatically adjusts to E1 22 AWG (0.6mm) twisted-pair cables from 0 to over 2km in length.
The device can generate the necessary G.703 waveshapes for both 75 coax and 120 twisted cables.
The on-board jitter attenuator (selectable to either 32 bits or 128 bits) can be placed in either the transmit
or receive data paths. The framer locates the frame and multiframe boundaries and monitors the data
stream for alarms. It is also used for extracting and inserting signaling data, Si, and Sa bit information.
The device contains a set of internal registers that the user can access to control the operation of the unit.
Quick access via the parallel control port allows a single controller to handle many E1 lines. The device
fully meets all the latest E1 specifications including ITU G.703, G.704, G.706, G.823, G.932, and I.431
as well as ETS 300 011, 300 233, 300 166, TBR 12 and TBR 13.
1.1 Introduction
The DS2154 is a superset version of the popular DS2153Q E1 single-chip transceiver offering the new
features listed below. All the original features of the DS2153Q have been retained and software created
for the original devices is transferable into the DS2154.
1.1.1 New Features
Option for nonmultiplexed bus operation
Crystal-less jitter attenuation
Additional hardware signaling capability including:
Receive signaling reinsertion to a backplane multiframe sync
Availability of signaling in a separate PCM data stream
– Signaling freezing
Interrupt generated on change of signaling data
Improved receive sensitivity: 0dB to -43dB
Per-channel code insertion in both transmit and receive paths
Expanded access to Sa and Si bits
RCL, RLOS, RRA, and RAIS alarms now interrupt on change of state
8.192MHz clock synthesizer
Per-channel loopback
Addition of hardware pins to indicate carrier loss and signaling freeze
Line interface function can be completely decoupled from the framer/formatter to allow:
Interface to optical, HDSL, and other NRZ interfaces
Ability to “tap” the transmit and receive bipolar data streams for monitoring purposes
Ability to corrupt data and insert framing errors, CRC errors, etc.
Transmit and receive elastic stores now have independent backplane clocks
Ability to monitor one DS0 channel in both the transmit and receive paths
Access to the data streams in between the framer/formatter and the elastic stores
AIS generation in the line interface that is independent of loopbacks
Transmit current limiter to meet the 50mA short circuit requirement
Option to extend carrier loss criteria to a 1ms period as per ETS 300 233
Automatic RAI generation to ETS 300 011 specifications
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1.2 Functional Description
The analog AMI/HDB3 waveform off the E1 line is transformer-coupled into the RRING and RTIP pins
of the DS2154. The device recovers clock and data from the analog signal and passes it through the jitter
attenuation mux to the receive side framer where the digital serial stream is analyzed to locate the
framing/multiframe pattern. The DS2154 contains an active filter that reconstructs the analog received
signal for the nonlinear losses that occur in transmission. The device has a usable receive sensitivity of
0dB to -43dB, which allows the device to operate on cables over 2km in length. The receive side framer
locates the FAS frame and CRC and CAS multiframe boundaries as well as detects incoming alarms,
including carrier loss, loss of synchronization, AIS, and remote alarm. If needed, the receive side elastic
store can be enabled in order to absorb the phase and frequency differences between the recovered E1
data stream and an asynchronous backplane clock that is provided at the RSYSCLK input. The clock
applied at the RSYSCLK input can be either a 2.048MHz clock or a 1.544MHz clock. The RSYSCLK
can be a bursty clock with speeds up to 8.192MHz.
The transmit side of the DS2154 is totally independent from the receive side in both the clock
requirements and characteristics. Data off of a backplane can be passed through a transmit side elastic
store if necessary. The transmit formatter will provide the necessary frame/multiframe data overhead for
E1 transmission. Once the data stream has been prepared for transmission, it is sent via the jitter
attenuation mux to the waveshaping and line driver functions. The DS2154 will drive the E1 line from the
TTIP and TRING pins via a coupling transformer. The line driver contains a current limiter that restricts
the maximum current into a 1 load to less than 50mA (RMS).
1.3 Reader’s Note
This data sheet assumes a particular nomenclature of the E1 operating environment. There are 32 8-bit
time slots in an E1 system numbered 0 to 31. Time slot 0 is transmitted first and received first. These 32
time slots are also referred to as channels with a numbering scheme of 1 to 32. Time slot 0 is identical to
channel 1, time slot 1 is identical to Channel 2, and so on. Each time slot (or channel) is made up of 8 bits
numbered 1 to 8. Bit number 1 is the MSB and is transmitted first. Bit number 8 is the LSB and is
transmitted last. Throughout this data sheet, the following abbreviations are used:
FAS Frame Alignment Signal
CRC4 Cyclical Redundancy Check
CCS Common Channel Signaling
CAS Channel Associated Signaling
MF Multiframe
Sa Additional Bits
Si International Bits
E-Bit CRC4 Error Bits
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Figure 1-1. DS2154 Enhanced E1 Single-Chip Transceiver
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2 PIN DESCRIPTION
PIN NAME TYPE FUNCTION
1 RCHBLK O Receive Channel Block
2, 4, 5,
7–10, 15, 23,
26, 27, 28,
36, 54, 76
N.C. —
No Connection. These pins should be left open circuited.
3 8MCLK O 8.192MHz Clock
6 RCL O Receive Carrier Loss
11 BTS I Bus Type Select
12 LIUC I Line Interface Connect
13 8XCLK O Eight Times Clock
14 TEST I Test
16 RTIP I Receive Analog Tip Input
17 RRING I Receive Analog Ring Input
18 RVDD Receive Analog Positive Supply
19, 20, 24 RVSS Receive Analog Signal Ground
21 MCLK I Master Clock Input
22 XTALD O Quartz Crystal Driver
25 INT O Active-Low Interrupt
29 TTIP O Transmit Analog Tip Output
30 TVSS Transmit Analog Signal Ground
31 TVDD Transmit Analog Positive Supply
32 TRING O Transmit Analog Ring Output
33 TCHBLK O Transmit Channel Block
34 TLCLK O Transmit Link Clock
35 TLINK I Transmit Link Data
37 TSYNC I/O Transmit Sync
38 TPOSI I Transmit Positive Data Input
39 TNEGI I Transmit Negative Data Input
40 TCLKI I Transmit Clock Input
41 TCLKO O Transmit Clock Output
42 TNEGO O Transmit Negative Data Output
43 TPOSO O Transmit Positive Data Output
44, 61, 81,
83 DVDD Digital Positive Supply
45, 60, 80,
84 DVSS Digital Signal Ground
46 TCLK I Transmit Clock
47 TSER I Transmit Serial Data
48 TSIG I Transmit Signaling Input
49 TESO O Transmit Elastic Store Output
50 TDATA I Transmit Data
51 TSYSCLK I Transmit System Clock
52 TSSYNC I Transmit System Sync
53 TCHCLK O Transmit Channel Clock
55 MUX I Bus Operation
56 D0/AD0 I/O Data Bus Bit 0/Address/Data Bus Bit 0
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PIN NAME TYPE FUNCTION
57 D1/AD1 I/O Data Bus Bit 1/Address/Data Bus Bit 1
58 D2/AD2 I/O Data Bus Bit 2/Address/Data Bus Bit 2
59 D3/AD3 I/O Data Bus Bit 3/Address/Data Bus Bit 3
62 D4/AD4 I/O Data Bus Bit 4/Address/Data Bus Bit 4
63 D5/AD5 I/O Data Bus Bit 5/Address/Data Bus Bit 5
64 D6/AD6 I/O Data Bus Bit 6/Address/Data Bus Bit 6
65 D7/AD7 I/O Data Bus Bit 7/Address/Data Bus Bit 7
66–72 A0–A6 I Address Bus Bit 0
73 A7/ALE I Address Bus Bit 7/Address Latch Enable
74 RD(DS) I Active-Low Read Input (Data Strobe)
75 CS I Active-Low Chip Select
77 WR(R/W) I Active-Low Write Input (Read/Write)
78 RLINK O Receive Link Data
79 RLKCLK O Receive Link Clock
82 RCLK O Receive Clock
85 RDATA O Receive Data
86 RPOSI I Receive Positive Data Input
87 RNEGI I Receive Negative Data Input
88 RCLKI I Receive Clock Input
89 RCLKO O Receive Clock Output
90 RNEGO O Receive Negative Data Output
91 RPOSO O Receive Positive Data Output
92 RCHCLK O Receive Channel Clock
93 RSIGF O Receive Signaling Freeze Output
94 RSIG O Receive Signaling Output
95 RSER O Receive Serial Data
96 RMSYNC O Receive Multiframe Sync
97 RFSYNC O Receive Frame Sync
98 RSYNC I/O Receive Sync
99 RLOS/LOTC O Receive Loss of Sync/Loss of Transmit Clock
100 RSYSCLK I Receive System Clock
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2.1 Transmit Side Digital Pins
PIN NAME FUNCTION
46 TCLK
Transmit Clock. A 2.048MHz primary clock. Used to clock data through the transmit
side formatter. Must be present for the parallel control port to operate properly. If not
present, the Loss of Transmit Clock (LOTC) function can provide a clock.
47 TSER
Transmit Serial Data. Transmit NRZ serial data. Sampled on the falling edge of
TCLK when the transmit side elastic store is disabled. Sampled on the falling edge of
TSYSCLK when the transmit side elastic store is enabled.
53 TCHCLK
Transmit Channel Clock. A 256kHz clock that pulses high during the LSB of each
channel. Synchronous with TCLK when the transmit side elastic store is disabled.
Synchronous with TSYSCLK when the transmit side elastic store is enabled. Useful for
parallel to serial conversion of channel data.
33 TCHBLK
Transmit Channel Block. A user-programmable output that can be forced high or low
during any of the 32 E1 channels. Synchronous with TCLK when the transmit side
elastic store is disabled. Synchronous with TSYSCLK when the transmit side elastic
store is enabled. Useful for blocking clocks to a serial UART or LAPD controller in
applications where not all E1 channels are used such as Fractional E1, 384kbps (H0),
768kbps, 1920kbps (H12), or ISDN-PRI. Also useful for locating individual channels in
drop-and-insert applications, for external per-channel loopback, and for per-channel
conditioning. See Section 10 for details.
51 TSYSCLK
Transmit System Clock. 1.544MHz or 2.048MHz clock. Only used when the transmit
side elastic store function is enabled. Should be tied low in applications that do not use
the transmit side elastic store. Can be burst at rates up to 8.192MHz.
34 TLCLK
Transmit Link Clock. 4 kHz or 20kHz demand clock (Sa bits) for the TLINK input.
See Section 12 for details.
35 TLINK
Transmit Link Data. If enabled, this pin will be sampled on the falling edge of TCLK
for data insertion into any combination of the Sa bit positions (Sa4 to Sa8). See Section
12 for details.
37 TSYNC
Transmit Sync. A pulse at this pin will establish either frame or multiframe boundaries
for the transmit side. This pin can also be programmed to output either a frame or
multiframe pulse. It is always synchronous with TCLK. See Section 14 for details.
52 TSSYNC
Transmit System Sync. Only used when the transmit side elastic store is enabled. A
pulse at this pin will establish either frame or multiframe boundaries for the transmit
side. Should be tied low in applications that do not use the transmit side elastic store.
Always synchronous with TSYSCLK.
48 TSIG
Transmit Signaling Input. When enabled, this input will sample signaling bits for
insertion into outgoing PCM E1 data stream. Sampled on the falling edge of TCLK
when the transmit side elastic store is disabled. Sampled on the falling edge of
TSYSCLK when the transmit side elastic store is enabled. See Section 14 for details.
49 TESO
Transmit Elastic Store Data Output. Updated on the rising edge of TCLK with data
out of the transmit side elastic store whether the elastic store is enabled or not. This pin
is normally tied to TDATA.
50 TDATA
Transmit Data. Sampled on the falling edge of TCLK with data to be clocked through
the transmit side formatter. This pin is normally tied to TESO.
43 TPOSO
Transmit Positive Data Output. Updated on the rising edge of TCLKO with the
bipolar data out of the transmit side formatter. Can be programmed to source NRZ data
via the Output Data Format (TCR1.7) control bit. This pin is normally tied to TPOSI.
42 TNEGO
Transmit Negative Data Output. Updated on the rising edge of TCLKO with the
bipolar data out of the transmit side formatter. This pin is normally tied to TNEGI.
41 TCLKO
Transmit Clock Output. Buffered clock that is used to clock data through the transmit
side formatter (i.e., either TCLK or RCLKO if Loss of Transmit Clock is enabled and in
effect, or RCLKI if remote loopback is enabled). This pin is normally tied to TCLKI.
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PIN NAME FUNCTION
38 TPOSI
Transmit Positive Data Input. Sampled on the falling edge of TCLKI for data to be
transmitted out onto the E1 line. Can be internally connected to TPOSO by tying the
LIUC pin high.
39 TNEGI
Transmit Negative Data Input. Sampled on the falling edge of TCLKI for data to be
transmitted out onto the E1 line. Can be internally connected to TNEGO by tying the
LIUC pin high.
40 TCLKI
Transmit Clock Input. Line interface transmit clock. Can be internally connected to
TCLKO by tying the LIUC pin high.
2.2 Receive Side Digital Pins
PIN NAME FUNCTION
78 RLINK
Receive Link Data. Updated with the full recovered E1 datastream on the rising edge
of RCLK.
79 RLCLK
Receive Link Clock. A 4kHz to 20kHz clock (Sa bits) for the RLINK output. See
Section 12 for details.
82 RCLK
Receive Clock. 2.048MHz clock that is used to clock data through the receive side
framer.
92 RCHCLK
Receive Channel Clock. A 256kHz clock that pulses high during the LSB of each
channel. Synchronous with RCLK when the receive side elastic store is disabled.
Synchronous with RSYSCLK when the receive side elastic store is enabled. Useful for
parallel to serial conversion of channel data.
1 RCHBLK
Receive Channel Block. A user-programmable output that can be forced high or low
during any of the 32 E1 channels. Synchronous with RCLK when the receive side elastic
store is disabled. Synchronous with RSYSCLK when the receive side elastic store is
enabled. Useful for blocking clocks to a serial UART or LAPD controller in applications
where not all E1 channels are used, such as Fractional E1, 384kbps service, 768kbps, or
ISDN-PRI. Also useful for locating individual channels in drop-and-insert applications,
for external per-channel loopback, and for per-channel conditioning. See Section 10 for
details.
95 RSER
Receive Serial Data. Received NRZ serial data. Updated on rising edges of RCLK
when the receive side elastic store is disabled. Updated on the rising edges of
RSYSCLK when the receive side elastic store is enabled.
98 RSYNC
Receive Sync. An extracted pulse, one RCLK wide, is output at this pin, which
identifies either frame or CAS/CRC4 multiframe boundaries. If the receive side elastic
store is enabled, then this pin can be enabled to be an input at which a frame or
multiframe boundary pulse synchronous with RSYSCLK is applied.
97 RFSYNC
Receive Frame Sync. An extracted 8kHz pulse, one RCLK wide, is output at this pin
that identifies frame boundaries.
96 RMSYNC
Receive Multiframe Sync. An extracted pulse, one RSYSCLK wide, is output at this
pin, which identifies multiframe boundaries. If the receive side elastic store is disabled,
then this output will output multiframe boundaries associated with RCLK.
85 RDATA
Receive Data. Updated on the rising edge of RCLK with the data out of the receive side
framer.
100 RSYSCLK
Receive System Clock. 1.544MHz or 2.048MHz clock. Only used when the elastic
store function is enabled. Should be tied low in applications that do not use the elastic
store. Can be burst at rates up to 8.192MHz.
94 RSIG
Receive Signaling Output. Outputs signaling bits in a PCM format. Updated on rising
edges of RCLK when the receive side elastic store is disabled. Updated on the rising
edges of RSYSCLK when the receive side elastic store is enabled. See Section 14.
99 RLOS/LOTC
Receive Loss of Sync/Loss of Transmit Clock. A dual function output that is
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PIN NAME FUNCTION
controlled by the TCR2.0 control bit. This pin can be programmed to either toggle high
when the synchronizer is searching for the frame and multiframe or to toggle high if the
TCLK pin has not been toggled for 5µs.
6 RCL
Receive Carrier Loss. Set high when the line interface detects a loss of carrier. Note: A
test mode exists to allow the DS2154 to detect carrier loss at RPOSI and RNEGI in
place of detection at RTIP and RRING.
93 RSIGF
Receive Signaling Freeze. Set high when the signaling data is frozen via either
automatic or manual intervention. Used to alert downstream equipment of the condition.
3 8MCLK
8MHz Clock. A 8.192MHz output clock that is referenced to the clock that is output at
the RCLK pin.
91 RPOSO
Receive Positive Data Output. Updated on the rising edge of RCLKO with the bipolar
data out of the line interface. This pin is normally tied to RPOSI.
90 RNEGO
Receive Negative Data Output. Updated on the rising edge of RCLKO with the bipolar
data out of the line interface. This pin is normally tied to RNEGI.
89 RCLKO
Receive Clock Output. Buffered recovered clock from the E1 line. This pin is normally
tied to RCLKI.
86 RPOSI
Receive Positive Data Input. Sampled on the falling edge of RCLKI for data to be
clocked through the receive side framer. RPOSI and RNEGI can be tied together for a
NRZ interface. Can be internally connected to RPOSO by tying the LIUC pin high.
87 RNEGI
Receive Negative Data Input. Sampled on the falling edge of RCLKI for data to be
clocked through the receive side framer. RPOSI and RNEGI can be tied together for a
NRZ interface. Can be internally connected to RNEGO by tying the LIUC pin high.
88 RCLKI
Receive Clock Input. Clock used to clock data through the receive side framer. This pin
is normally tied to RCLKO. Can be internally connected to RCLKO by tying the LIUC
pin high. RCLKI must be present for the parallel control port to operate properly.
2.3 Parallel Control Port Pins
PIN NAME FUNCTION
25 INT Interrupt. Flags host controller during conditions and change of conditions defined in
the Status Registers 1 and 2. Active-low, open-drain output.
14 TEST
Tri-State Control. Set high to tri-state all output and I/O pins (including the parallel
control port). Set low for normal operation. Useful in board-level testing.
55 MUX
Bus Operation. Set low to select nonmultiplexed bus operation. Set high to select
multiplexed bus operation.
56–65 D0–D7/
AD0–AD7
Data Bus or Address/Data Bus. In nonmultiplexed bus operation (MUX = 0), serves as
the data bus. In multiplexed bus operation (MUX = 1), serves as an 8-bit multiplexed
address/data bus.
66–72 A0–A6 Address Bus. In nonmultiplexed bus operation (MUX = 0), serves as the address bus. In
multiplexed bus operation (MUX = 1), these pins are not used and should be tied low.
11 BTS
Bus Type Select. Strap high to select Motorola bus timing; strap low to select Intel bus
timing. This pin controls the function of the RD (DS ), ALE(AS), and WR (R/ W) pins.
If BTS = 1, then these pins assume the function listed in parentheses.
74 RD(DS) Read Input (Data Strobe). RD and DS are active-low signals when MUX = 1. DS is
active high when MUX = 0. See the bus timing diagrams.
75 CS Chip Select. Must be low to read or write to the device. CS is an active-low signal.
73 ALE(AS)
A7 or Address Latch Enable (Address Strobe). In nonmultiplexed bus operation
(MUX = 0), serves as the upper address bit. In multiplexed bus operation (MUX = 1),
serves to demultiplex the bus on a positive-going edge.
77 WR(R/W) Write Input (Read/Write). WR is an active-low signal.
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2.4 Line Interface Pins
PIN NAME FUNCTION
21 MCLK
Master Clock Input. A 2.048MHz (±50ppm) clock source with TTL levels is applied at
this pin. This clock is used internally for both clock/data recovery and for jitter
attenuation. A quartz crystal of 2.048MHz may be applied across MCLK and XTALD
instead of the TTL level clock source.
22 XTALD
Quartz Crystal Driver. A quartz crystal of 2.048MHz may be applied across MCLK
and XTALD instead of a TTL level clock source at MCLK. Leave open circuited if a
TTL clock source is applied at MCLK.
13 8XCLK
Eight Times Clock. A 16.384MHz clock that is frequency locked to the 2.048MHz
clock provided from the clock/data recovery block (if the jitter attenuator is enabled on
the receive side) or from the TCLKI pin (if the jitter attenuator is enabled on the transmit
side). Can be internally disabled via the TEST2 register if not needed.
12 LIUC
Line Interface Connect. Tie low to separate the line interface circuitry from the
framer/formatter circuitry and activate the TPOSI/TNEGI/TCLKI/RPOSI/RNEGI/
RCLKI pins. Tie high to connect the line interface circuitry to the framer/formatter
circuitry and deactivate the TPOSI/TNEGI/TCLKI/RPOSI/RNEGI/RCLKI pins. When
LIUC is tied high, the TPOSI/TNEGI/TCLKI/RPOSI/RNEGI/RCLKI pins should be
tied low.
16, 17 RTIP,
RRING
Receive Tip and Ring. Analog inputs for clock recovery circuitry. These pins connect
via a 1:1 transformer to the E1 line. See Section 13 for details.
29, 32 TTIP,
TRING
Transmit Tip and Ring. Analog line driver outputs. These pins connect via a 1:1.15 or
1:1.36 step-up transformer to the E1 line. See Section 13 for details.
2.5 Supply Pins
PIN NAME FUNCTION
44, 61,
81, 83 DVDD Digital Positive Supply. 5.0V ±5%. Should be tied to the RVDD and TVDD pins.
18 RVDD
Receive Analog Positive Supply. 5.0V ±5%. Should be tied to the DVDD and TVDD
pins.
31 TVDD
Transmit Analog Positive Supply. 5.0V ±5%. Should be tied to the RVDD and DVDD
pins.
45, 60,
80, 84 DVSS Digital Signal Ground. Should be tied to the RVSS and TVSS pins.
19, 20,
24 RVSS Receive Analog Signal Ground. 0V. Should be tied to the DVSS and TVSS pins.
30 TVSS Transmit Analog Ground. 0V. Should be tied to the RVSS and DVSS pins.
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Table 2-1. Register Map
REGISTER
ADDRESS R/W DESCRIPTION NAME
00 R BPV or Code Violation Count 1 VCR1
01 R BPV or Code Violation Count 2 VCR2
02 R CRC4 Error Count 1/FAS Error Count 1 CRCCR1
03 R CRC4 Error Count 2 CRCCR2
04 R E-Bit Count 1/FAS Error Count 2 EBCR1
05 R E-Bit Count 2 EBCR2
06 R/W Status 1 SR1
07 R/W Status 2 SR2
08 R/W Receive Information RIR
09, 0A–0E,
1D
Not Present
0F R Device ID Register IDR
10 R/W Receive Control 1 RCR1
11 R/W Receive Control 2 RCR2
12 R/W Transmit Control 1 TCR1
13 R/W Transmit Control 2 TCR2
14 R/W Common Control 1 CCR1
15 R/W Test 1 TEST1 (set to 00h)
16 R/W Interrupt Mask 1 IMR1
17 R/W Interrupt Mask 2 IMR2
18 R/W Line Interface Control LICR
19 R/W Test 2 TEST2 (set to 00h)
1A R/W Common Control 2 CCR2
1B R/W Common Control CCR3
1C R/W Transmit Sa Bit Control TSaCR
1E R Synchronizer Status SSR
1F R Receive Non-Align Frame RNAF
20 R/W Transmit Align Frame TAF
21 R/W Transmit Non-Align Frame TNAF
22 R/W Transmit Channel Blocking 1 TCBR1
23 R/W Transmit Channel Blocking 2 TCBR2
24 R/W Transmit Channel Blocking 3 TCBR3
25 R/W Transmit Channel Blocking 4 TCBR4
26 R/W Transmit Idle 1 TIR1
27 R/W Transmit Idle 2 TIR2
28 R/W Transmit Idle 3 TIR3
29 R/W Transmit Idle 4 TIR4
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REGISTER
ADDRESS R/W DESCRIPTION NAME
2A R/W Transmit Idle Definition TIDR
2B R/W Receive Channel Blocking 1 RCBR1
2C R/W Receive Channel Blocking 2 RCBR2
2D R/W Receive Channel Blocking 3 RCBR3
2E R/W Receive Channel Blocking 4 RCBR4
2F R Receive Align Frame RAF
30 R Receive Signaling 1 RS1
31 R Receive Signaling 2 RS2
32 R Receive Signaling 3 RS3
33 R Receive Signaling 4 RS4
34 R Receive Signaling 5 RS5
35 R Receive Signaling 6 RS6
36 R Receive Signaling 7 RS7
37 R Receive Signaling 8 RS8
38 R Receive Signaling 9 RS9
39 R Receive Signaling 10 RS10
3A R Receive Signaling 11 RS11
3B R Receive Signaling 12 RS12
3C R Receive Signaling 13 RS13
3D R Receive Signaling 14 RS14
3E R Receive Signaling 15 RS15
3F R Receive Signaling 16 RS16
40 R/W Transmit Signaling 1 TS1
41 R/W Transmit Signaling 2 TS2
42 R/W Transmit Signaling 3 TS3
43 R/W Transmit Signaling 4 TS4
44 R/W Transmit Signaling 5 TS5
45 R/W Transmit Signaling 6 TS6
46 R/W Transmit Signaling 7 TS7
47 R/W Transmit Signaling 8 TS8
48 R/W Transmit Signaling 9 TS9
49 R/W Transmit Signaling 10 TS10
4A R/W Transmit Signaling 11 TS11
4B R/W Transmit Signaling 12 TS12
4C R/W Transmit Signaling 13 TS13
4D R/W Transmit Signaling 14 TS14
4E R/W Transmit Signaling 15 TS15
4F R/W Transmit Signaling 16 TS16
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REGISTER
ADDRESS R/W DESCRIPTION NAME
50 R/W Transmit Si Bits Align Frame TSiAF
51 R/W Transmit Si Bits Non-Align Frame TSiNAF
52 R/W Transmit Remote Alarm Bits TRA
53 R/W Transmit Sa4 Bits TSa4
54 R/W Transmit Sa5 Bits TSa5
55 R/W Transmit Sa6 Bits TSa6
56 R/W Transmit Sa7 Bits TSa7
57 R/W Transmit Sa8 Bits TSa8
58 R Receive Si Bits Align Frame RSiAF
59 R Receive Si Bits Non-Align Frame RSiNAF
5A R Receive Remote Alarm Bits RRA
5B R Receive Sa4 Bits RSa4
5C R Receive Sa5 Bits RSa5
5D R Receive Sa6 Bits RSa6
5E R Receive Sa7 Bits RSa7
5F R Receive Sa8 Bits RSa8
60 R/W Transmit Channel 1 TC1
61 R/W Transmit Channel 2 TC2
62 R/W Transmit Channel 3 TC3
63 R/W Transmit Channel 4 TC4
64 R/W Transmit Channel 5 TC5
65 R/W Transmit Channel 6 TC6
66 R/W Transmit Channel 7 TC7
67 R/W Transmit Channel 8 TC8
68 R/W Transmit Channel 9 TC9
69 R/W Transmit Channel 10 TC10
6A R/W Transmit Channel 11 TC11
6B R/W Transmit Channel 12 TC12
6C R/W Transmit Channel 13 TC13
6D R/W Transmit Channel 14 TC14
6E R/W Transmit Channel 15 TC15
6F R/W Transmit Channel 16 TC16
70 R/W Transmit Channel 17 TC17
71 R/W Transmit Channel 18. TC18
72 R/W Transmit Channel 19 TC19
73 R/W Transmit Channel 20 TC20
74 R/W Transmit Channel 21 TC21
75 R/W Transmit Channel 22 TC22
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REGISTER
ADDRESS R/W DESCRIPTION NAME
76 R/W Transmit Channel 23 TC23
77 R/W Transmit Channel 24 TC24
78 R/W Transmit Channel 25 TC25
79 R/W Transmit Channel 26 TC26
7A R/W Transmit Channel 27 TC27
7B R/W Transmit Channel 28 TC28
7C R/W Transmit Channel 29 TC29
7D R/W Transmit Channel 30 TC30
7E R/W Transmit Channel 31 TC31
7F R/W Transmit Channel 32 TC32
80 R/W Receive Channel 1 RC1
81 R/W Receive Channel 2 RC2
82 R/W Receive Channel 3 RC3
83 R/W Receive Channel 4 RC4
84 R/W Receive Channel 5 RC5
85 R/W Receive Channel 6 RC6
86 R/W Receive Channel 7 RC7
87 R/W Receive Channel 8 RC8
88 R/W Receive Channel 9 RC9
89 R/W Receive Channel 10 RC10
8A R/W Receive Channel 11 RC11
8B R/W Receive Channel 12 RC12
8C R/W Receive Channel 13 RC13
8D R/W Receive Channel 14 RC14
8E R/W Receive Channel 15 RC15
8F R/W Receive Channel 16 RC16
90 R/W Receive Channel 17 RC17
91 R/W Receive Channel 18 RC18
92 R/W Receive Channel 19 RC19
93 R/W Receive Channel 20 RC20
94 R/W Receive Channel 21 RC21
95 R/W Receive Channel 22 RC22
96 R/W Receive Channel 23 RC23
97 R/W Receive Channel 24 RC24
98 R/W Receive Channel 25 RC25
99 R/W Receive Channel 26 RC26
9A R/W Receive Channel 27 RC27
9B R/W Receive Channel 28 RC28
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REGISTER
ADDRESS R/W DESCRIPTION NAME
9C R/W Receive Channel 29 RC29
9D R/W Receive Channel 30 RC30
9E R/W Receive Channel 31 RC31
9F R/W Receive Channel 32 RC32
A0 R/W Transmit Channel Control 1 TCC1
A1 R/W Transmit Channel Control 2 TCC2
A2 R/W Transmit Channel Control 3 TCC3
A3 R/W Transmit Channel Control 4 TCC4
A4 R/W Receive Channel Control 1 RCC1
A5 R/W Receive Channel Control 2 RCC2
A6 R/W Receive Channel Control 3 RCC3
A7 R/W Receive Channel Control 4 RCC4
A8 R/W Common Control 4 CCR4
A9 R Transmit DS0 Monitor TDS0M
AA R/W Common Control 5 CCR5
AB R Receive DS0 Monitor RDS0M
AC R/W Test 3 TEST3 (set to 00h)
AD R/W Not Used (set to 00h)
AE R/W Not Used (set to 00h)
AF R/W Not Used (set to 00h)
Note 1: Test Registers 1, 2, and 3 are used only by the factory; these registers must be cleared (set to all 0s) on power-up initialization to ensure proper
operation.
Note 2: Register banks Bxh, Cxh, Dxh, Exh, and Fxh are not accessible.
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3 PARALLEL PORT
The DS2154 is controlled via either a nonmultiplexed (MUX = 0) or a multiplexed (MUX = 1) bus by an
external microcontroller or microprocessor. The DS2154 can operate with either Intel or Motorola bus
timing configurations. If the BTS pin is tied low, Intel timing will be selected; if tied high, Motorola
timing will be selected. All Motorola bus signals are listed in parentheses. See the timing diagrams in the
AC Electrical Characteristics in Section 16 for more details.
4 CONTROL, ID, AND TEST REGISTERS
The operation of the DS2154 is configured via a set of nine control registers. Typically, the control
registers are only accessed when the system is first powered up. Once the DS2154 has been initialized,
the control registers will only need to be accessed when there is a change in the system configuration.
There are two Receive Control Registers (RCR1 and RCR2), two Transmit Control Registers (TCR1 and
TCR2), and five Common Control Registers (CCR1 to CCR5). Each of the nine registers is described in
this section.
There is a device Identification Register (IDR) at address 0Fh. The MSB of this read-only register is fixed
to a 1 indicating that the DS2154 is present. The pin-for-pin compatible T1 version of the DS2154 is the
DS2152, which also has an ID register at address 0Fh. The user can read the MSB to determine which
chip is present because the MSB is set to 1 in the DS2154, and is set to 0 in the DS2152. The lower 4 bits
of the IDR are used to display the die revision of the chip.
The Test Registers at addresses 15, 19, and AC hex are used by the factory in testing the DS2154. On
power-up, the Test Registers should be set to 00 hex for the DS2154 to operate properly.
IDR: DEVICE IDENTIFICATION REGISTER (Address = 0F Hex)
(MSB) (LSB)
T1E1 0 0 0 ID3 ID2 ID1 ID0
SYMBOL
POSITION NAME AND DESCRIPTION
T1E1 IDR.7
T1 or E1 Chip Determination Bit.
0 = T1 chip
1 = E1 chip
ID3 IDR.3 Chip Revision Bit 3. MSB of a decimal code that represents the
chip revision.
ID2 IDR.1
Chip Revision Bit 2.
ID1 IDR.2
Chip Revision Bit 1.
ID0 IDR.0 Chip Revision Bit 0. LSB of a decimal code that represents the
chip revision.
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RCR1: RECEIVE CONTROL REGISTER 1 (Address = 10 Hex)
(MSB) (LSB)
RSMF RSM RSIO FRC SYNCE RESYNC
SYMBOL POSITION NAME AND DESCRIPTION
RSMF RCR1.7 RSYNC Multiframe Function. Only used if the RSYNC pin is
programmed in the multiframe mode (RCR1.6 = 1).
0 = RSYNC outputs CAS multiframe boundaries
1 = RSYNC outputs CRC4 multiframe boundaries
RSM RCR1.6
RSYNC Mode Select.
0 = frame mode (see the timing in Section 14)
1 = multiframe mode (see the timing in Section 14)
RSIO RCR1.5 RSYNC I/O Select. (Note: This bit must be set to 0 when
RCR2.1 = 0.)
0 = RSYNC is an output (depends on RCR1.6)
1 = RSYNC is an input (only valid if elastic store enabled)
— RCR1.4,
RCR1.3
Not Assigned. Should be set to 0 when written.
FRC RCR1.2
Frame Resync Criteria.
0 = resync if FAS received in error three consecutive times
1 =resync if FAS or bit 2 of non-FAS is received in error three
consecutive times
SYNCE RCR1.1
Sync Enable.
0 = auto resync enabled
1 = auto resync disabled
RESYNC RCR1.0 Resync. When toggled from low to high, a resync is initiated.
Must be cleared and set again for a subsequent resync.
Table 4-1. Sync/Resync Criteria
FRAME OR
MULTIFRAME
LEVEL
SYNC CRITERIA RESYNC CRITERIA ITU SPEC.
FAS
FAS present in frame N and N + 2, and
FAS not present in frame N + 1
Three consecutive incorrect
FAS received
Alternate (RCR1.2 = 1) the
above criteria is met or three
consecutive incorrect bit 2 of
non-FAS received
G.706
4.1.1
4.1.2
CRC4
Two valid MF alignment words found
within 8ms
915 or more CRC4 code
words out of 1000 received in
error
G.706
4.2 and 4.3.2
CAS
Valid MF alignment word found and
previous time slot 16 contains code
other than all 0s
Two consecutive MF
alignment words received in
error
G.732
5.2
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RCR2: RECEIVE CONTROL REGISTER 2 (Address = 11 Hex)
(MSB) (LSB)
Sa8S Sa7S Sa6S Sa5S Sa4S RBCS RESE
SYMBOL POSITION NAME AND DESCRIPTION
Sa8S RCR2.7 Sa8 Bit Select. Set to 1 to have RLCLK pulse at the Sa8 bit
position; set to 0 to force RLCLK low during Sa8 bit position.
See Section 14 for timing details.
Sa7S RCR2.6 Sa7 Bit Select. Set to 1 to have RLCLK pulse at the Sa7 bit
position; set to 0 to force RLCLK low during Sa7 bit position.
See Section 14 for timing details.
Sa6S RCR2.5 Sa6 Bit Select. Set to 1 to have RLCLK pulse at the Sa6 bit
position; set to 0 to force RLCLK low during Sa6 bit position.
See Section 14 for timing details.
Sa5S RCR2.4 Sa5 Bit Select. Set to 1 to have RLCLK pulse at the Sa5 bit
position; set to 0 to force RLCLK low during Sa5 bit position.
See Section 14 for timing details.
Sa4S RCR2.3 Sa4 Bit Select. Set to 1 to have RLCLK pulse at the Sa4 bit
position; set to 0 to force RLCLK low during Sa4 bit position.
See Section 14 for timing details.
RBCS RCR2.2
Receive Side Backplane Clock Select.
0 = if RSYSCLK is 1.544MHz
1 = if RSYSCLK is 2.048MHz
RESE RCR2.1
Receive Side Elastic Store Enable.
0 = elastic store is bypassed
1 = elastic store is enabled
— RCR2.0 Not Assigned. Should be set to 0 when written.
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TCR1: TRANSMIT CONTROL REGISTER 1 (Address = 12 Hex)
(MSB) (LSB)
ODF TFPT T16S TUA1 TSiS TSA1 TSM TSIO
SYMBOL POSITION NAME AND DESCRIPTION
ODF TCR1.7
Output Data Format.
0 = bipolar data at TPOSO and TNEGO
1 = NRZ data at TPOSO; TNEGO = 0
TFPT TCR1.6
Transmit Time Slot 0 Pass Through.
0 = FAS bits/Sa bits/Remote Alarm sourced internally from the
TAF and TNAF registers
1 = FAS bits/Sa bits/Remote Alarm sourced from TSER
T16S TCR1.5
Transmit Time Slot 16 Data Select.
0 = sample time slot 16 at TSER pin
1 = source time slot 16 from TS0 to TS15 registers
TUA1 TCR1.4
Transmit Unframed All 1s.
0 = transmit data normally
1 = transmit an unframed all 1’s code at TPOSO and TNEGO
TSiS TCR1.3
Transmit International Bit Select.
0 = sample Si bits at TSER pin
1 = source Si bits from TAF and TNAF registers (in this mode,
TCR1.6 must be set to 0)
TSA1 TCR1.2
Transmit Signaling All 1s.
0 = normal operation
1 = force time slot 16 in every frame to all 1s
TSM TCR1.1 TSYNC Mode Select.
0 = frame mode (see the timing in Section 14)
1 = CAS and CRC4 multiframe mode (see the timing in Section
14)
TSIO TCR1.0
TSYNC I/O Select.
0 = TSYNC is an input
1 = TSYNC is an output
Note: See Figure 14-11 for more details about how the Transmit Control Registers affect the operation of the DS2154.
DS2154
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TCR2: TRANSMIT CONTROL REGISTER 2 (Address = 13 Hex)
(MSB) (LSB)
Sa8S Sa7S Sa6S Sa5S Sa4S ODM AEBE PF
SYMBOL POSITION NAME AND DESCRIPTION
Sa8S TCR2.7 Sa8 Bit Select. Set to 1 to source the Sa8 bit from the TLINK
pin; set to 0 to not source the Sa8 bit. See Section 14 for timing
details.
Sa7S TCR2.6 Sa7 Bit Select. Set to 1 to source the Sa7 bit from the TLINK
pin; set to 0 to not source the Sa7 bit. See Section 14 for timing
details.
Sa6S TCR2.5 Sa6 Bit Select. Set to 1 to source the Sa6 bit from the TLINK
pin; set to 0 to not source the Sa6 bit. See Section 14 for timing
details.
Sa5S TCR2.4 Sa5 Bit Select. Set to 1 to source the Sa5 bit from the TLINK
pin; set to 0 to not source the Sa5 bit. See Section 14 for timing
details.
Sa4S TCR2.3 Sa4 Bit Select. Set to 1 to source the Sa4 bit from the TLINK
pin; set to 0 to not source the Sa4 bit. See Section 14 for timing
details.
ODM TCR2.2
Output Data Mode.
0 = pulses at TPOSO and TNEGO are one full TCLKO period
wide
1 = pulses at TPOSO and TNEGO are 1/2 TCLKO period wide
AEBE TCR2.1
Automatic E-Bit Enable.
0 = E-bits not automatically set in the transmit direction
1 = E-bits automatically set in the transmit direction
PF TCR2.0
Function of RLOS/LOTC Pin.
0 = Receive Loss of Sync (RLOS)
1 = Loss of Transmit Clock (LOTC)
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CCR1: COMMON CONTROL REGISTER 1 (Address = 14 Hex)
(MSB) (LSB)
FLB THDB3 TG802 TCRC4 RSM RHDB3 RG802 RCRC4
SYMBOL POSITION NAME AND DESCRIPTION
FLB CCR1.7
Framer Loopback.
0 = loopback disabled
1 =loopback enabled
THDB3 CCR1.6
Transmit HDB3 Enable.
0 = HDB3 disabled
1 = HDB3 enabled
TG802 CCR1.5 Transmit G.802 Enable. See Section 14 for details.
0 = do not force TCHBLK high during bit 1 of time slot 26
1 = force TCHBLK high during bit 1 of time slot 26
TCRC4 CCR1.4
Transmit CRC4 Enable.
0 = CRC4 disabled
1 = CRC4 enabled
RSM CCR1.3
Receive Signaling Mode Select.
0 = CAS signaling mode
1 = CCS signaling mode
RHDB3 CCR1.2
Receive HDB3 Enable.
0 = HDB3 disabled
1 = HDB3 enabled
RG802 CCR1.1 Receive G.802 Enable. See Section 14 for details.
0 = do not force RCHBLK high during bit 1 of time slot 26
1 = force RCHBLK high during bit 1 of time slot 26
RCRC4 CCR1.0
Receive CRC4 Enable.
0 = CRC4 disabled
1 = CRC4 enabled
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CCR2: COMMON CONTROL REGISTER 2 (Address = 1A Hex)
(MSB) (LSB)
ECUS VCRFS AAIS ARA RSERC LOTCMC RFF RFE
SYMBOL POSITION NAME AND DESCRIPTION
ECUS CCR2.7 Error Counter Update Select. See Section 6 for details.
0 = update error counters once a second
1 = update error counters every 62.5ms (500 frames)
VCRFS CCR2.6 VCR Function Select. See Section 6 for details.
0 = count Bipolar Violations (BPVs)
1 = count Code Violations (CVs)
AAIS CCR2.5
Automatic AIS Generation.
0 = disabled
1 = enabled
ARA CCR2.4
Automatic Remote Alarm Generation.
0 = disabled
1 = enabled
RSERC CCR2.3
RSER Control.
0 = allow RSER to output data as received under all conditions
1 = force RSER to 1 under loss of frame alignment conditions
LOTCMC CCR2.2 Loss of Transmit Clock Mux Control. Determines whether the
transmit side formatter should switch to the ever-present
RCLKO if the TCLK should fail to transition (see Figure 1-1).
0 = do not switch to RCLKO if TCLK stops
1 = switch to RCLKO if TCLK stops
RFF CCR2.1 Receive Force Freeze. Freezes receive side signaling at RSIG
(and RSER if CCR3.3 = 1); will override Receive Freeze Enable
(RFE). See Section 8.2 for details.
0 = do not force a freeze event
1 = force a freeze event
RFE CCR2.0 Receive Freeze Enable. See Section 8.2 for details.
0 = no freezing of receive signaling data will occur
1 = allow freezing of receive signaling data at RSIG (and RSER
if CCR3.3 = 1).
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CCR3: COMMON CONTROL REGISTER 3 (Address = 1B Hex)
(MSB) (LSB)
TESE TCBFS TIRFS ESR RSRE THSE TBCS RCLA
SYMBOL POSITION NAME AND DESCRIPTION
TESE CCR3.7
Transmit Side Elastic Store Enable.
0 = elastic store is bypassed
1 = elastic store is enabled
TCBFS CCR3.6
Transmit Channel Blocking Registers (TCBR) Function
Select.
0 = TCBRs define the operation of the TCHBLK output pin
1 = TCBRs define which signaling bits are to be inserted
TIRFS CCR3.5 Transmit Idle Registers (TIR) Function Select. See Section 9
for details.
0 = TIRs define in which channels to insert idle code
1 = TIRs define in which channels to insert data from RSER
(i.e., Per-Channel Loopback function)
ESR CCR3.4 Elastic Stores Reset. Setting this bit from a 1 to a 0 will force
the elastic stores to a known depth. ESR is level triggered.
Should be toggled after RSYSCLK and TSYSCLK have been
applied and are stable. Must be set and cleared again for a
subsequent reset. Do not leave this bit set high.
RSRE CCR3.3 Receive Side Signaling Re-Insertion Enable. See Section 8.2
for details.
0 = do not reinsert signaling bits into the data stream presented
at the RSER pin
1 = reinsert the signaling bits into data stream presented at the
RSER pin
THSE CCR3.2 Transmit Side Hardware Signaling Insertion Enable. See
Section 8.2 for details.
0 = do not insert signaling from the TSIG pin into the data
stream presented at the TSER pin
1 = insert signaling from the TSIG pin into the data stream
presented at the TSER pin
TBCS CCR3.1
Transmit Side Backplane Clock Select.
0 = if TSYSCLK is 1.544MHz
1 = if TSYSCLK is 2.048MHz
RCLA CCR3.0
Receive Carrier Loss (RCL) Alternate Criteria.
0 = RCL declared upon 255 consecutive 0s (125µs)
1 = RCL declared upon 2048 consecutive 0s (1ms)
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CCR4: COMMON CONTROL REGISTER 4 (Address = A8 Hex)
(MSB) (LSB)
RLB LLB LIAIS TCM4 TCM3 TCM2 TCM1 TCM0
SYMBOL POSITION NAME AND DESCRIPTION
RLB CCR4.7
Remote Loopback.
0 = loopback disabled
1 = loopback enabled
LLB CCR4.6
Local Loopback.
0 = loopback disabled
1 = loopback enabled
LIAIS CCR4.5 Line Interface AIS Generation Enable. See Figure 1-1 for
details.
0 = allow normal data from TPOSI/TNEGI to be transmitted at
TTIP and TRING
1 = force unframed all 1s to be transmitted at TTIP and TRING
TCM4 CCR4.4 Transmit Channel Monitor Bit 4. MSB of a channel decode
that determines which transmit channel data will appear in the
TDS0M register. See Section 7 for details.
TCM3 CCR4.3
Transmit Channel Monitor Bit 3.
TCM2 CCR4.2
Transmit Channel Monitor Bit 2.
TCM1 CCR4.1
Transmit Channel Monitor Bit 1.
TCM0 CCR4.0 Transmit Channel Monitor Bit 0. LSB of the channel decode.
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CCR5: COMMON CONTROL REGISTER 5 (Address = AA Hex)
(MSB) (LSB)
LIRST RCM4 RCM3 RCM2 RCM1 RCM0
SYMBOL POSITION NAME AND DESCRIPTION
LIRST CCR5.7 Line Interface Reset. Setting this bit from a 0 to a 1 will initiate
an internal reset that affects the clock recovery state machine and
jitter attenuator. Normally this bit is only toggled on power-up.
Must be cleared and set again for a subsequent reset.
— CCR5.6,
CCR5.5
Not Assigned. Should be set to 0 when written.
RCM4 CCR5.4 Receive Channel Monitor Bit 4. MSB of a channel decode that
determines which receive channel data will appear in the
RDS0M register. See Section 7 for details.
RCM3 CCR5.3
Receive Channel Monitor Bit 3.
RCM2 CCR5.2
Receive Channel Monitor Bit 2.
RCM1 CCR5.1
Receive Channel Monitor Bit 1.
RCM0 CCR5.0 Receive Channel Monitor Bit 0. LSB of the channel decode.
4.1 Framer Loopback
When CCR1.7 is set to 1, the DS2154 enters a Framer Loopback (FLB) mode. See Figure 1-1 for details.
This loopback is useful in testing and debugging applications. In FLB, the DS2154 loops data from the
transmit side back to the receive side. When FLB is enabled, the following occurs:
1) Data is transmitted as normal at TPOSO and TNEGO.
2) Data input via RPOSI and RNEGI is ignored.
3) The RCLK output is replaced with the TCLK input.
4.2 Local Loopback
When CCR4.6 is set to 1, the DS2154 is forced into Local Loopback (LLB). In this loopback, data
continues to be transmitted as normal through the transmit side of the DS2154. Data being received at
RTIP and RRING is replaced with the data being transmitted. Data in this loopback passes through the
jitter attenuator. See Figure 1-1 for more details.
4.3 Remote Loopback
When CCR4.7 is set to 1, the DS2154 is forced into Remote Loopback (RLB). In this loopback, data
input via the RPOSI and RNEGI pins is transmitted back to the TPOSO and TNEGO pins. Data continues
to pass through the receive side framer of the DS2154 as it would normally, and the data from the
transmit side formatter is ignored. See Figure 1-1 for more details.
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4.4 Power-Up Sequence
On power-up, after the supplies are stable, the DS2154 should be configured for operation by writing to
all of the internal registers (this includes the Test Registers) since the contents of the internal registers
cannot be predicted on power-up. Next, the LIRST (CCR5.7) bit should be toggled from 0 to 1 to reset
the line interface circuitry (it will take the DS2154 about 40ms to recover from the LIRST bit being
toggled). Finally, after the RSYSCLK and TSYSCLK inputs are stable, the ESR bit should be toggled
from a 0 to a 1 and then back to 0 (this step can be skipped if the elastic stores are not being used). Both
TCLK and RCLKI must be present for the parallel control port to operate properly.
4.5 Automatic Alarm Generation
When either CCR2.4 or CCR2.5 is set to 1, the DS2154 monitors the receive side to determine if any of
the following conditions are present: loss of receive frame synchronization, AIS alarm (all 1s) reception,
or loss of receive carrier (or signal). If any one (or more) of the above conditions is present, then the
DS2154 will either force an AIS alarm (if CCR2.5 = 1) or a Remote Alarm (CCR2.4 = 1) to be
transmitted via the TPOSO and TNEGO pins. It is an illegal state to have both CCR2.4 and CCR2.5 set to
1 at the same time. If CCR2.4 = 1, then RAI will be transmitted according to ETS 300 011 specifications
and a constant Remote Alarm will be transmitted if the DS2154 cannot find CRC4 multiframe
synchronization within 400ms as per G.706.
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5 STATUS AND INFORMATION REGISTERS
There is a set of four registers that contain information on the current real-time status of the DS2154:
Status Register 1 (SR1), Status Register 2 (SR2), Receive Information Register (RIR), and Synchronizer
Status Register (SSR). When a particular event has occurred (or is occurring), the appropriate bit in one
of these four registers is set to 1. All the bits in these registers operate in a latched fashion (except for the
SSR). This means that if an event or an alarm occurs and a bit is set to a 1 in any of the registers, it
remains set until the user reads that bit. The bit is cleared when it is read and it is not set again until the
event has occurred again (or in the case of the RSA1, RSA0, RDMA, RUA1, RRA, RCL, and RLOS
alarms, the bit remains set if the alarm is still present).
The user always precedes a read of the SR1, SR2, and RIR registers with a write. The byte written to the
register informs the DS2154 which bits the user wishes to read and have cleared. The user writes a byte to
one of these three registers, with a 1 in the bit positions he or she wishes to read and a 0 in the bit
positions he or she does not wish to obtain the latest information on. When a 1 is written to a bit location,
the read register is updated with the latest information. When a 0 is written to a bit position, the read
register is not updated and the previous value is held. A write to the status and information registers is
immediately followed by a read of the same register. The read result should be logically ANDed with the
mask byte that was just written, and this value should be written back into the same register to ensure that
bit does indeed clear. This second write step is necessary because the alarms and events in the status
registers occur asynchronously in respect to their access via the parallel port. This write-read-write
scheme allows an external microcontroller or microprocessor to individually poll certain bits without
disturbing the other bits in the register. This operation is key in controlling the DS2154 with higher-order
software languages.
The SSR register operates differently than the other three. It is a read-only register and it reports the status
of the synchronizer in real time. This register is not latched and it is not necessary to precede a read of
this register with a write.
The SR1 and SR2 registers have the unique ability to initiate a hardware interrupt via the INT output pin.
Each of the alarms and events in the SR1 and SR2 can be either masked or unmasked from the interrupt
pins via the Interrupt Mask Register 1 (IMR1) and Interrupt Mask Register 2 (IMR2), respectively.
The interrupts caused by RUA1, RRA, RCL, and RLOS act differently than the interrupts caused by
RSA1, RDMA, RSA0, RSLIP, RMF, RAF, TMF, SEC, TAF, LOTC, RCMF, and TSLIP. The four
interrupts force the INT pin low whenever the alarm changes state (i.e., the alarm goes active or inactive
according to the set/clear criteria in Table 5-1). The INT pin is allowed to return high (if no other
interrupts are present) when the user reads the alarm bit that caused the interrupt to occur. If the alarm is
still present, the register bit remains set.
The event-caused interrupts force the INT pin low when the event occurs. The INT pin is allowed to
return high (if no other interrupts are present) when the user reads the event bit that caused the interrupt to
occur.
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RIR: RECEIVE INFORMATION REGISTER (Address = 08 Hex)
(MSB) (LSB)
TESF TESE JALT RESF RESE CRCRC FASRC CASRC
SYMBOL POSITION NAME AND DESCRIPTION
TESF RIR.7 Transmit Side Elastic Store Full. Set when the transmit side
elastic store buffer fills and a frame is deleted.
TESE RIR.6 Transmit Side Elastic Store Empty. Set when the transmit side
elastic store buffer empties and a frame is repeated.
JALT RIR.5 Jitter Attenuator Limit Trip. Set when the jitter attenuator
FIFO reaches to within 4 bits of its limit; useful for debugging
jitter attenuation operation.
RESF RIR.4 Receive Side Elastic Store Full. Set when the receive side
elastic store buffer fills and a frame is deleted.
RESE RIR.3 Receive Side Elastic Store Empty. Set when the receive side
elastic store buffer empties and a frame is repeated.
CRCRC RIR.2 CRC Resync Criteria Met. Set when 915/1000 code words are
received in error.
FASRC RIR.1 FAS Resync Criteria Met. Set when 3 consecutive FAS words
are received in error.
CASRC RIR.0 CAS Resync Criteria Met. Set when 2 consecutive CAS MF
alignment words are received in error.
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SSR: SYNCHRONIZER STATUS REGISTER (Address = 1E Hex)
(MSB) (LSB)
CSC5 CSC4 CSC3 CSC2 CSC0 FASSA CASSA CRC4SA
SYMBOL POSITION NAME AND DESCRIPTION
CSC5 SSR.7 CRC4 Sync Counter Bit 5. MSB of the 6-bit counter.
CSC4 SSR.6
CRC4 Sync Counter Bit 4.
CSC3 SSR.5
CRC4 Sync Counter Bit 3.
CSC2 SSR.4
CRC4 Sync Counter Bit 2.
CSC0 SSR.3 CRC4 Sync Counter Bit 0. LSB of the 6-bit counter. The next
to LSB is not accessible.
FASSA SSR.2 FAS Sync Active. Set while the synchronizer is searching for
alignment at the FAS level.
CASSA SSR.1 CAS MF Sync Active. Set while the synchronizer is searching
for the CAS MF alignment word.
CRC4SA SSR.0 CRC4 MF Sync Active. Set while the synchronizer is searching
for the CRC4 MF alignment word.
5.1 CRC4 Sync Counter
The CRC4 sync counter increments each time the 8ms CRC4 multiframe search times out. The counter is
cleared when the DS2154 has successfully obtained synchronization at the CRC4 level. The counter can
also be cleared by disabling the CRC4 mode (CCR1.0 = 0). This counter is useful for determining the
amount of time the DS2154 has been searching for synchronization at the CRC4 level. ITU G.706
suggests that if synchronization at the CRC4 level cannot be obtained within 400ms, then the search
should be abandoned and proper action taken. The CRC4 sync counter will rollover.
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SR1: STATUS REGISTER 1 (Address = 06 Hex)
(MSB) (LSB)
RSA1 RDMA RSA0 RSLIP RUA1 RRA RCL RLOS
SYMBOL POSITION NAME AND DESCRIPTION
RSA1 SR1.7 Receive Signaling All 1s/Signaling Change. Set when the
contents of time slot 16 contains less than three 0s over 16
consecutive frames. This alarm is not disabled in the CCS
signaling mode. Both RSA1 and RSA0 will be set if a change in
signaling is detected.
RDMA SR1.6 Receive Distant MF Alarm. Set when bit 6 of timeslot 16 in
frame 0 has been set for two consecutive multiframes. This
alarm is not disabled in the CCS signaling mode.
RSA0 SR1.5 Receive Signaling All 0s/Signaling Change. Set when over a
full MF, time slot 16 contains all 0s. Both RSA1 and RSA0 will
be set if a change in signaling is detected.
RSLIP SR1.4 Receive Side Elastic Store Slip. Set when the elastic store has
either repeated or deleted a frame of data.
RUA1 SR1.3 Receive Unframed All 1s. Set when an unframed all 1s code is
received at RPOSI and RNEGI.
RRA SR1.2 Receive Remote Alarm. Set when a remote alarm is received at
RPOSI and RNEGI.
RCL SR1.1 Receive Carrier Loss. Set when 255 (or 2048 if CCR3.0 = 1)
consecutive 0s have been detected at RTIP and RRING. (Note: a
test mode exists to allow the DS2154 to detect carrier loss at
RPOSI and RNEGI in place of detection at RTIP and RRING).
RLOS SR1.0 Receive Loss of Sync. Set when the device is not synchronized
to the receive E1 stream.
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Table 5-1. Alarm Criteria
ALARM SET CRITERIA CLEAR CRITERIA ITU SPEC.
RSA1
(receive signaling all 1s)
Over 16 consecutive frames
(one full MF) time slot 16
contains less than three 0s
Over 16 consecutive frames
(one full MF) time slot 16
contains three or more 0s
G.732
4.2
RSA0
(receive signaling all 0s)
Over 16 consecutive frames
(one full MF) timeslot 16
contains all 0s
Over 16 consecutive frames
(one full MF) time slot 16
contains at least a single 1
G.732
5.2
RDMA
(receive distant multiframe
alarm)
Bit 6 in time slot 16 of frame
0 set to 1 for two consecutive
MF
Bit 6 in time slot 16 of frame 0
set to 0 for a two consecutive
MF
O.162
2.1.5
RUA1
(receive unframed all 1s)
Less than three 0s in two
frames (512 bits)
More than two 0s in two
frames (512 bits)
O.162
1.6.1.2
RRA
(receive remote alarm)
Bit 3 of non-align frame set to
1 for three consecutive
occasions
Bit 3 of non-align frame set to
0 for three consecutive
occasions
O.162
2.1.4
RCL
(receive carrier loss)
255 (or 2048) consecutive 0s
received
In 255-bit times, at least 32 1s
are received
G.775 /
G.962
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SR2: STATUS REGISTER 2 (Address = 07 Hex)
(MSB) (LSB)
RMF RAF TMF SEC TAF LOTC RCMF TSLIP
SYMBOL POSITION NAME AND DESCRIPTION
RMF SR2.7 Receive CAS Multiframe. Set every 2ms (regardless if CAS
signaling is enabled or not) on receive multiframe boundaries.
Used to alert the host that signaling data is available.
RAF SR2.6
Receive Align Frame. Set every 250µs at the beginning of align
frames. Used to alert the host that Si and Sa bits are available in
the RAF and RNAF registers.
TMF SR2.5 Transmit Multiframe. Set every 2ms (regardless if CRC4 is
enabled) on transmit multiframe boundaries. Used to alert the
host that signaling data needs to be updated.
SEC SR2.4 1-Second Timer. Set on increments of 1 second based on
RCLK. If CCR2.7 = 1, then this bit will be set every 62.5 ms
instead of once a second.
TAF SR2.3
Transmit Align Frame. Set every 250µs at the beginning of
align frames. Used to alert the host that the TAF and TNAF
registers need to be updated.
LOTC SR2.2 Loss of Transmit Clock. Set when the TCLK pin has not
transitioned for one channel time (or 3.9µs). Will force the
LOTC pin high if enabled via TCR2.0.
RCMF SR2.1 Receive CRC4 Multiframe. Set on CRC4 multiframe
boundaries; will continue to be set every 2ms on an arbitrary
boundary if CRC4 is disabled.
TSLIP SR2.0 Transmit Elastic Store Slip. Set when the elastic store has
either repeated or deleted a frame of data.
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IMR1: INTERRUPT MASK REGISTER 1 (Address = 16 Hex)
(MSB) (LSB)
RSA1 RDMA RSA0 RSLIP RUA1 RRA RCL RLOS
SYMBOL POSITION NAME AND DESCRIPTION
RSA1 IMR1.7
Receive Signaling All 1s/Signaling Change.
0 = interrupt masked
1 = interrupt enabled
RDMA IMR1.6 Receive Distant MF Alarm.
0 = interrupt masked
1 = interrupt enabled
RSA0 IMR1.5
Receive Signaling All 0s/Signaling Change.
0 = interrupt masked
1 = interrupt enabled
RSLIP IMR1.4 Receive Elastic Store Slip Occurrence.
0 = interrupt masked
1 = interrupt enabled
RUA1 IMR1.3 Receive Unframed All 1s.
0 = interrupt masked
1 = interrupt enabled
RRA IMR1.2 Receive Remote Alarm.
0 = interrupt masked
1 = interrupt enabled
RCL IMR1.1 Receive Carrier Loss.
0 = interrupt masked
1 = interrupt enabled
RLOS IMR1.0 Receive Loss of Sync.
0 = interrupt masked
1 = interrupt enabled
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IMR2: INTERRUPT MASK REGISTER 2 (Address = 17 Hex)
(MSB) (LSB)
RMF RAF TMF SEC TAF LOTC RCMF TSLIP
SYMBOL POSITION NAME AND DESCRIPTION
RMF IMR2.7
Receive CAS Multiframe.
0 = interrupt masked
1 = interrupt enabled
RAF IMR2.6
Receive Align Frame.
0 = interrupt masked
1 = interrupt enabled
TMF IMR2.5
Transmit Multiframe.
0 = interrupt masked
1 = interrupt enabled
SEC IMR2.4
1-Second Timer.
0 = interrupt masked
1 = interrupt enabled
TAF IMR2.3
Transmit Align Frame.
0 = interrupt masked
1 = interrupt enabled
LOTC IMR2.2
Loss Of Transmit Clock.
0 = interrupt masked
1 = interrupt enabled
RCMF IMR2.1 Receive CRC4 Multiframe.
0 = interrupt masked
1 = interrupt enabled
TSLIP IMR2.0
Transmit Side Elastic Store Slip Occurrence.
0 = interrupt masked
1 = interrupt enabled
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6 ERROR COUNT REGISTERS
There are a set of four counters in the DS2154 that record bipolar or code violations, errors in the CRC4
SMF codewords, E bits as reported by the far end, and word errors in the FAS. Each of these four
counters is automatically updated on either 1-second boundaries (CCR2.7 = 0) or every 62.5ms (CCR2.7
= 1) as determined by the timer in Status Register 2 (SR2.4). Hence, these registers contain performance
data from either the previous second or the previous 62.5ms. The user can use the interrupt from the timer
to determine when to read these registers. The user has a full second (or 62.5ms) to read the counters
before the data is lost.
6.1 BPV or Code Violation Counter
Violation Count Register 1 (VCR1) is the most significant word and VCR2 is the least significant word of
a 16-bit counter that records either Bipolar Violations (BPVs) or Code Violations (CVs). If CCR2.6 = 0,
then the VCR counts bipolar violations. Bipolar violations are defined as consecutive marks of the same
polarity. In this mode, if the HDB3 mode is set for the receive side via CCR1.2, then HDB3 codewords
are not counted as BPVs. If CCR2.6 = 1, then the VCR counts code violations as defined in ITU O.161.
Code violations are defined as consecutive bipolar violations of the same polarity. In most applications,
the DS2154 should be programmed to count BPVs when receiving AMI code and to count CVs when
receiving HDB3 code. This counter increments at all times and is not disabled by loss of sync conditions.
The counter saturates at 65,535 and will not rollover. The bit error rate on an E1 line would have to be
greater than 10**-2 before the VCR would saturate.
VCR1: UPPER BIPOLAR VIOLATION COUNT REGISTER 1
(Address = 00 Hex)
VCR2: LOWER BIPOLAR VIOLATION COUNT REGISTER 2
(Address = 01 Hex)
(MSB) (LSB)
V15 V14 V13 V12 V11 V10 V9 V8 VCR1
V7 V6 V5 V4 V3 V2 V1 V0 VCR2
SYMBOL POSITION NAME AND DESCRIPTION
V15 VCR1.7
MSB of the 16-bit bipolar or code violation count .
V0 VCR2.0
LSB of the 16-bit bipolar or code violation count.
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6.2 CRC4 Error Counter
CRC4 Count Register 1 (CRCCR1) is the most significant word and CRCCR2 is the least significant
word of a 10-bit counter that records word errors in the Cyclic Redundancy Check 4 (CRC4). Since the
maximum CRC4 count in a 1-second period is 1000, this counter cannot saturate. The counter is disabled
during loss of sync at either the FAS or CRC4 level; it will continue to count if loss of multiframe sync
occurs at the CAS level.
CRCCR1: CRC4 COUNT REGISTER 1 (Address = 02 Hex)
CRCCR2: CRC4 COUNT REGISTER 2 (Address = 03 Hex)
(MSB) (LSB)
(Note 1) (Note 1) (Note 1) (Note 1) (Note 1) (Note 1) CRC9 CRC8 CRCCR1
CRC7 CRC6 CRC5 CRC4 CRC3 CRC2 CRC1 CRC0 CRCCR2
SYMBOL POSITION NAME AND DESCRIPTION
CRC9 CRCCR1.1
MSB of the 10-bit CRC4 error count.
CRC0 CRCCR2.0
LSB of the 10-bit CRC4 error count.
Note 1: The upper 6 bits of CRCCR1 at address 02 are the most significant bits of the 12-bit FAS error counter.
6.3 E-Bit Counter
E-bit Count Register 1 (EBCR1) is the most significant word and EBCR2 is the least significant word of
a 10-bit counter that records Far End Block Errors (FEBE) as reported in the first bit of frames 13 and 15
on E1 lines running with CRC4 multiframe. These count registers will increment once each time the
received E-bit is set to 0. Since the maximum E-bit count in a 1-second period is 1000, this counter
cannot saturate. The counter is disabled during loss of sync at either the FAS or CRC4 level; it will
continue to count if loss of multiframe sync occurs at the CAS level.
EBCR1: E-BIT COUNT REGISTER 1 (Address = 04 Hex)
EBCR2: E-BIT COUNT REGISTER 2 (Address = 05 Hex)
(MSB) (LSB)
(Note 1) (Note 1) (Note 1) (Note 1) (Note 1) (Note 1) EB9 EB8 EBCR1
EB7 EB6 EB5 EB4 EB3 EB2 EB1 EB0 EBCR2
SYMBOL POSITION NAME AND DESCRIPTION
EB9 EBCR1.1
MSB of the 10-bit E-Bit count.
EB0 EBCR2.0
LSB of the 10-bit E-Bit count.
Note 1: The upper 6 bits of EBCR1 at address 04 are the least significant bits of the 12-bit FAS error counter.
DS2154
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6.4 FAS Error Counter
FAS Count Register 1 (FASCR1) is the most significant word and FASCR2 is the least significant word
of a 12-bit counter that records word errors in the Frame Alignment Signal in time slot 0. This counter is
disabled during loss of synchronization conditions, (RLOS = 1). Since the maximum FAS word error
count in a 1-second period is 4000, this counter cannot saturate.
FASCR1: FAS BIT COUNT REGISTER 1 (Address = 02 Hex)
FASCR2: FAS BIT COUNT REGISTER 2 (Address = 04 Hex)
(MSB) (LSB)
FAS11 FAS10 FAS9 FAS8 FAS7 FAS6 (Note 1) (Note 1) FASCR1
FAS5 FAS4 FAS3 FAS2 FAS1 FAS0 (Note 2) (Note 2) FASCR2
SYMBOL POSITION NAME AND DESCRIPTION
FAS11 FASCR1.7
MSB of the 12-bit FAS error count.
FAS0 FASCR2.2
LSB of the 12-bit FAS error count.
Note 1: The lower 2 bits of FASCR1 at address 02 are the most significant bits of the 10-bit CRC4 error counter.
Note 2: The lower 2 bits of FASCR2 at address 04 are the most significant bits of the 10-bit E-bit counter.
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7 DS0 MONITORING FUNCTION
The DS2154 can monitor one DS0 64kbps channel in the transmit direction and one DS0 channel in the
receive direction at the same time. In the transmit direction, the user determines which channel is to be
monitored by properly setting the TCM0 to TCM4 bits in the CCR4 register. In the receive direction, the
RCM0 to RCM4 bits in the CCR5 register need to be properly set. The DS0 channel pointed to by the
TCM0 to TCM4 bits will appear in the Transmit DS0 Monitor (TDS0M) register and the DS0 channel
pointed to by the RCM0 to RCM4 bits will appear in the Receive DS0 (RDS0M) register.
The TCM4 to TCM0 and RCM4 to RCM0 bits should be programmed with the decimal decode of the
appropriate E1 channel. For example, if DS0 channel 6 (time slot 5) in the transmit direction and DS0
channel 15 (time slot 14) in the receive direction needed to be monitored, then the following values would
be programmed into CCR4 and CCR5:
TCM4 = 0 RCM4 = 0
TCM3 = 0 RCM3 = 1
TCM2 = 1 RCM2 = 1
TCM1 = 0 RCM1 = 1
TCM0 = 1 RCM0 = 0
CCR4: DS0 MONITORING FUNCTION (Address = A8 Hex)
(Repeated here from Section 4 for convenience.)
(MSB) (LSB)
RLB LLB LIAIS TCM4 TCM3 TCM2 TCM1 TCM0
SYMBOL POSITION NAME AND DESCRIPTION
RLB CCR4.7 Remote Loopback. See Section 4 for details.
LLB CCR4.6 Local Loopback. See Section 4 for details.
LIAIS CCR4.5 Line Interface AIS Generation Enable. See Section 4 for
details.
TCM4 CCR4.4 Transmit Channel Monitor Bit 4. MSB of a channel decode
that determines which transmit channel data will appear in the
TDS0M register.
TCM3 CCR4.3
Transmit Channel Monitor Bit 3.
TCM2 CCR4.2
Transmit Channel Monitor Bit 2.
TCM1 CCR4.1
Transmit Channel Monitor Bit 1.
TCM0 CCR4.0 Transmit Channel Monitor Bit 0. LSB of the channel decode
that determines which transmit DS0 channel data will appear in
the TDS0M register.
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CCR5: COMMON CONTROL REGISTER 5 (Address = AA Hex)
(Repeated here from Section 4 for convenience.)
(MSB) (LSB)
LIRST RCM4 RCM3 RCM2 RCM1 RCM0
SYMBOL POSITION NAME AND DESCRIPTION
LIRST CCR5.7 Line Interface Reset. See Section 4 for details.
— CCR5.6,
CCR5.5
Not Assigned. Should be set to 0 when written.
RCM4 CCR5.4 Receive Channel Monitor Bit 4. MSB of a channel decode that
determines which receive channel data will appear in the
RDS0M register.
RCM3 CCR5.3
Receive Channel Monitor Bit 3.
RCM2 CCR5.2
Receive Channel Monitor Bit 2.
RCM1 CCR5.1
Receive Channel Monitor Bit 1.
RCM0 CCR5.0 Receive Channel Monitor Bit 0. LSB of the channel decode
that determines which receive DS0 channel data will appear in
the RDS0M register.
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TDS0M: TRANSMIT DS0 MONITOR REGISTER (Address = A9 Hex)
(MSB) (LSB)
B1 B2 B3 B4 B5 B6 B7 B8
SYMBOL POSITION NAME AND DESCRIPTION
B1 TDS0M.7 Transmit DS0 Channel Bit 8. MSB of the DS0 channel (first
bit to be transmitted).
B2 TDS0M.6
Transmit DS0 Channel Bit 7.
B3 TDS0M.5
Transmit DS0 Channel Bit 6.
B4 TDS0M.4
Transmit DS0 Channel Bit 5.
B5 TDS0M.3
Transmit DS0 Channel Bit 4.
B6 TDS0M.2
Transmit DS0 Channel Bit 3.
B7 TDS0M.1
Transmit DS0 Channel Bit 2.
B8 TDS0M.0 Transmit DS0 Channel Bit 1. LSB of the DS0 channel (last bit
to be transmitted).
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RDS0M: RECEIVE DS0 MONITOR REGISTER (Address = 1F Hex)
(MSB) (LSB)
B1 B2 B3 B4 B5 B6 B7 B8
SYMBOL
POSITION NAME AND DESCRIPTION
B1 RDS0M.7 Receive DS0 Channel Bit 1. MSB of the DS0 channel (first bit
to be received).
B2 RDS0M.6
Receive DS0 Channel Bit 2.
B3 RDS0M.5
Receive DS0 Channel Bit 3.
B4 RDS0M.4
Receive DS0 Channel Bit 4.
B5 RDS0M.3
Receive DS0 Channel Bit 5.
B6 RDS0M.2
Receive DS0 Channel Bit 6.
B7 RDS0M.1
Receive DS0 Channel Bit 7.
B8 RDS0M.0 Receive DS0 Channel Bit 8. LSB of the DS0 channel (last bit to
be received).
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8 SIGNALING OPERATION
The DS2154 contains provisions for both processor-based (i.e., software based) signaling bit access and
for hardware-based access. Both the processor-based access and the hardware-based access can be used
simultaneously if necessary. The processor-based signaling is covered in Section 8.1 and the hardware
based signaling is covered in Section 8.2.
8.1 Processor-Based Signaling
The Channel Associated Signaling (CAS) bits embedded in the E1 stream can be extracted from the
receive stream and inserted into the transmit stream by the DS2154. Each of the 30 voice channels has
four signaling bits (A to D) associated with it. The numbers in parentheses () are the voice channels
associated with a particular signaling bit. The voice channel numbers have been assigned as described in
the ITU documents. Note that this is different than the channel numbering scheme (1 to 32) that is used in
the rest of the data sheet. For example, voice channel 1 is associated with time slot 1 (Channel 2) and
voice Channel 30 is associated with time slot 31 (Channel 32). There is a set of 16 registers for the
receive side (RS1 to RS16) and 16 registers on the transmit side (TS1 to TS16). The signaling registers
are detailed below.
RS1 TO RS16: RECEIVE SIGNALING REGISTERS (Address = 30 to 3F Hex)
(MSB) (LSB)
0 0 0 0 X Y X X
RS1 (30)
A(1) B(1) C(1) D(1) A(16) B(16) C(16) D(16) RS2 (31)
A(2) B(2) C(2) D(2) A(17) B(17) C(17) D(17) RS3 (32)
A(3) B(3) C(3) D(3) A(18) B(18) C(18) D(18) RS4 (33)
A(4) B(4) C(4) D(4) A(19) B(19) C(19) D(19) RS5 (34)
A(5) B(5) C(5) D(5) A(20) B(20) C(20) D(20) RS6 (35)
A(6) B(6) C(6) D(6) A(21) B(21) C(21) D(21) RS7 (36)
A(7) B(7) C(7) D(7) A(22) B(22) C(22) D(22) RS8 (37)
A(8) B(8) C(8) D(8) A(23) B(23) C(23) D(23) RS9 (38)
A(9) B(9) C(9) D(9) A(24) B(24) C(24) D(24) RS10 (39)
A(10) B(10) C(10) D(10) A(25) B(25) C(25) D(25) RS11 (3A)
A(11) B(11) C(11) D(11) A(26) B(26) C(26) D(26) RS12 (3B)
A(12) B(12) C(12) D(12) A(27) B(27) C(27) D(27) RS13 (3C)
A(13) B(13) C(13) D(13) A(28) B(28) C(28) D(28) RS14 (3D)
A(14) B(14) C(14) D(14) A(29) B(29) C(29) D(29) RS15 (3E)
A(15) B(15) C(15) D(15) A(30) B(30) C(30) D(30) RS16 (3F)
SYMBOL POSITION NAME AND DESCRIPTION
X RS1.0/1/3
Spare Bits.
Y RS1.2
Remote Alarm Bit (integrated and reported in SR1.6).
A(1) RS2.7
Signaling Bit A for Channel 1.
D(30) RS16.0
Signaling Bit D for Channel 30.
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Each Receive Signaling Register (RS1 to RS16) reports the incoming signaling from two time slots. The
bits in the Receive Signaling Registers are updated on multiframe boundaries so the user can use the
Receive Multiframe Interrupt in the Receive Status Register 2 (SR2.7) to know when to retrieve the
signaling bits. The user has a full 2ms to retrieve the signaling bits before the data is lost. The RS
registers are updated under all conditions. Their validity should be qualified by checking for
synchronization at the CAS level. In CCS signaling mode, RS1 to RS16 can also be used to extract
signaling information. Via the SR2.7 bit, the user will be informed when the signaling registers have been
loaded with data. The user has 2ms to retrieve the data before it is lost. The signaling data reported in RS1
to RS16 is also available at the RSIG and RSER pins.
A change in the signaling bits from one multiframe to the next causes the RSA1 (SR1.7) and RSA0
(SR1.5) status bits to be set at the same time. The user can enable the INT pin to toggle low upon
detection of a change in signaling by setting either the IMR1.7 or IMR1.5 bit. Once a signaling change
has been detected, the user has at least 1.75ms to read the data out of the RS1 to RS16 registers before the
data will be lost.
TS1 TO TS16: TRANSMIT SIGNALING REGISTERS (Address = 40 to 4F Hex)
(MSB) (LSB)
0 0 0 0 X Y X X
TS1 (40)
A(1) B(1) C(1) D(1) A(16) B(16) C(16) D(16) TS2 (41)
A(2) B(2) C(2) D(2) A(17) B(17) C(17) D(17) TS3 (42)
A(3) B(3) C(3) D(3) A(18) B(18) C(18) D(18) TS4 (43)
A(4) B(4) C(4) D(4) A(19) B(19) C(19) D(19) TS5 (44)
A(5) B(5) C(5) D(5) A(20) B(20) C(20) D(20) TS6 (45)
A(6) B(6) C(6) D(6) A(21) B(21) C(21) D(21) TS7 (46)
A(7) B(7) C(7) D(7) A(22) B(22) C(22) D(22) TS8 (47)
A(8) B(8) C(8) D(8) A(23) B(23) C(23) D(23) TS9 (48)
A(9) B(9) C(9) D(9) A(24) B(24) C(24) D(24) TS10 (49)
A(10) B(10) C(10) D(10) A(25) B(25) C(25) D(25) TS11 (4A)
A(11) B(11) C(11) D(11) A(26) B(26) C(26) D(26) TS12 (4B)
A(12) B(12) C(12) D(12) A(27) B(27) C(27) D(27) TS13 (4C)
A(13) B(13) C(13) D(13) A(28) B(28) C(28) D(28) TS14 (4D)
A(14) B(14) C(14) D(14) A(29) B(29) C(29) D(29) TS15 (4E)
A(15) B(15) C(15) D(15) A(30) B(30) C(30) D(30) TS16 (4F)
SYMBOL POSITION NAME AND DESCRIPTION
X TS1.0/1/3
Spare Bits.
Y TS1.2
Remote Alarm Bit.
A(1) TS2.7
Signaling Bit A for Channel 1.
D(30) TS16.0
Signaling Bit D for Channel 30.
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Each Transmit Signaling Register (TS1 to TS16) contains the CAS bits for two timeslots that will be
inserted into the outgoing stream if enabled to do so via TCR1.5. On multiframe boundaries, the DS2154
will load the values present in the Transmit Signaling Register into an outgoing signaling shift register
that is internal to the device. The user can use the Transmit Multiframe bit in Status Register 2 (SR2.5) to
know when to update the signaling bits. The bit will be set every 2ms and the user has 2ms to update the
TSRs before the old data will be retransmitted. ITU specifications recommend that the ABCD signaling
not be set to all 0s because they will emulate a CAS multiframe alignment word.
The TS1 register is special because it contains the CAS multiframe alignment word in its upper nibble.
The upper nibble must always be set to 0000 or else the terminal at the far end will lose multiframe
synchronization. If the user wishes to transmit a multiframe alarm to the far end, then the TS1.2 bit
should be set to a 1. If no alarm is to be transmitted, then the TS1.2 bit should be cleared. The three
remaining bits in TS1 are the spare bits. If they are not used, they should be set to 1. In CCS signaling
mode, TS1 to TS16 can also be used to insert signaling information. Via the SR2.5 bit, the user will be
informed when the signaling registers need to be loaded with data. The user has 2ms to load the data
before the old data will be retransmitted.
Via the CCR3.6 bit, the user has the option to use the Transmit Channel Blocking Registers (TCBRs) to
determine, on a channel-by-channel basis, which signaling bits are to be inserted via the TSRs (the
corresponding bit in the TCBRs = 1) and which are to be sourced from the TSER or TSIG pin (the
corresponding bit in the TCBRs = 0). See the Transmit Data Flow diagram (Figure 14-11) for more
details.
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8.2 Hardware-Based Signaling
8.2.1 Receive Side
In the receive side of the hardware based signaling, there are two operating modes for the signaling
buffer: signaling extraction and signaling reinsertion. Signaling extraction involves pulling the signaling
bits from the receive data stream and buffering them over a 2-multiframe buffer and outputting them in a
serial PCM fashion on a channel-by-channel basis at the RSIG output pin. This mode is always enabled.
In this mode, the receive elastic store may be enabled or disabled. If the receive elastic store is enabled,
then the backplane clock (RSYSCLK) must be 2.048MHz. The ABCD signaling bits are output on RSIG
in the lower nibble of each channel. See the timing diagrams in Section 14 for an example. The RSIG
data is updated once a multiframe (2ms) unless a freeze is in effect.
The other hardware based signaling operating mode called signaling re-insertion can be invoked by
setting the RSRE control bit high (CCR3.3 = 1). In this mode, the user will provide a multiframe sync at
the RSYNC pin and the signaling data will be re-aligned in the PCM data stream provided at the RSER
output pin according to this applied multiframe boundary. In this mode, the elastic store must be enabled
and the backplane clock (RSYSCLK) must be 2.048MHz.
The signaling data in the two-multiframe buffer will be frozen in a known good state upon either a loss of
synchronization (OOF event), carrier loss, or frame slip. To allow this freeze action to occur, the RFE
control bit (CCR2.0) should be set high. The user can force a freeze by setting the RFF control bit
(CCR2.1) high. Setting the RFF bit high causes the same freezing action as if a loss of synchronization,
carrier loss, or slip has occurred. The RSIGF output pin provides a hardware indication that a freeze is in
effect. The RSIGF pin will go high immediately upon detection of any of the events that can cause a
freeze to occur. The RSIGF pin will return low 3ms to 5ms after the event subsides. The RSIGF pin
action cannot be disabled.
The two-multiframe buffer provides an approximate one-multiframe delay in the signaling bits provided
at the RSIG pin (and at the RSER pin if RSRE = 1 via CCR3.3). When freezing is enabled (RFE = 1), the
signaling data will be held in the last known good state until the corrupting error condition subsides.
When the error condition subsides, the signaling data will be held in the old state for an additional 3ms to
5ms before being allowed to be updated with new signaling data.
8.2.2 Transmit Side
Via the THSE control bit (CCR3.2), the DS2154 can be set up to take the signaling data presented at the
TSIG pin and insert the signaling data into the PCM data stream that is being input at the TSER pin. The
hardware signaling insertion capabilities of the DS2154 are available whether the transmit side elastic
store is enabled or disabled. If the transmit side elastic store is enabled, the backplane clock (TSYSCLK)
must be 2.048MHz.
When hardware signaling insertion is enabled on the DS2154 (TSRE = 1), then the user must enable the
Transmit Channel Blocking Register Function Select (TCBFS) control bit (CCR3.6 = 1). This is needed
so that the CAS multiframe alignment word, multiframe remote alarm, and spare bits can be added to
timeslot 16 in frame 0 of the multiframe. The TS1 register should be programmed with the proper
information. If CCR3.6 = 1, then a 0 in the TCBRs implies that signaling data is to be sourced from
TSER (or TSIG if CCR3.2 = 1) and a 1 implies that signaling data for that channel is to be sourced from
the Transmit Signaling (TS) registers. See the following definition.
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TCBR1/TCBR2/TCBR3/TCBR4: DEFINITION WHEN CCR3.6 = 1
(MSB) (LSB)
CH20 CH4 CH19 CH3 CH18 CH2 CH17* CH1* TCBR1(22)
CH24 CH8 CH23 CH7 CH22 CH6 CH21 CH5 TCBR2(23)
CH28 CH12 CH27 CH11 CH26 CH10 CH25 CH9 TCBR3(24)
CH32 CH16 CH31 CH15 CH30 CH14 CH29 CH13 TCBR4(25)
*CH1 and CH17 should be set to 1 to allow the internal TS1 register to create the CAS Multiframe Alignment Word and Spare/Remote
Alarm bits.
The user can also take advantage of this functionality to intermix signaling data from the TSIG pin and
from the internal Transmit Signaling Registers (TS1 to TS16). As an example, assume that the user
wishes to source all the signaling data except for voice channels 5 and 10 from the TSIG pin. In this
application, the following bits and registers would be programmed as follows:
CONTROL BITS REGISTER VALUES
TSRE = 1 (CCR3.2) TS1 = 0Bh (MF alignment word, remote alarm etc.)
TCBFS = 1 (CCR3.6) TCBR1 = 03h (source time slot 16, frame 1 data)
TCBR2 = 01h (source voice Channel 5 signaling data from TS6)
TCBR3 = 04h (source voice Channel 10 signaling data from TS11)
T16S = 1 (TCR1.5)
TCBR4 = 00h
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9 PER-CHANNEL CODE (IDLE) GENERATION AND LOOPBACK
The DS2154 can replace data on a channel-by-channel basis in both the transmit and receive directions.
The transmit direction is from the backplane to the E1 line and is covered in Section 9.1. The receive
direction is from the E1 line to the backplane and is covered in Section 9.2.
9.1 Transmit Side Code Generation
In the transmit direction there are two methods by which channel data from the backplane can be
overwritten with data generated by the DS2154. The first method, which is covered in Section 9.1.1, was
a feature contained in the original DS2153 while the second method, which is covered in Section 9.1.2, is
a new feature of the DS2154.
9.1.1 Simple Idle Code Insertion and Per-Channel Loopback
The first method involves using the Transmit Idle Registers (TIR1/2/3/4) to determine which of the 32 E1
channels should be overwritten with the code placed in the Transmit Idle Definition Register (TIDR).
This method allows the same 8-bit code to be placed into any of the 32 E1 channels. If this method is
used, then the CCR3.5 control bit must be set to 0.
The Transmit Idle Registers (TIRs) have an alternate function that allows them to define a Per-Channel
Loopback (PCLB). If the CCR3.5 control bit is set to 1, then the TIRs will determine which channels (if
any) from the backplane should be replaced with the data from the receive side or, in other words, off of
the E1 line. See Figure 1-1. If this mode is enabled, then transmit and receive clocks and frame syncs
must be synchronized. One method to accomplish this would be to tie RCLK to TCLK and RFSYNC to
TSYNC. There are no restrictions on which channels can be looped back or on how many channels can
be looped back.
TIR1/TIR2/TIR3/TIR4: TRANSMIT IDLE REGISTERS (Address = 26 to 29 Hex)
(Also used for Per-Channel Loopback.)
(MSB) (LSB)
CH8 CH7 CH6 CH5 CH4 CH3 CH2 CH1 TIR1 (26)
CH16 CH15 CH14 CH13 CH12 CH11 CH10 CH9 TIR2 (27)
CH24 CH23 CH22 CH21 CH20 CH19 CH18 CH17 TIR3 (28
CH32 CH31 CH30 CH29 CH28 CH27 CH26 CH25 TIR4 (29)
SYMBOL POSITION NAME AND DESCRIPTION
CH32 TIR4.7
Transmit Idle Registers.
0 = do not insert the Idle Code in the TIDR into this channel
CH1 TIR1.0 1 = insert the Idle Code in the TIDR into this channel
Note: If CCR3.5 = 1, then a 0 in the TIRs implies that channel data is to be sourced from TSER and a 1 implies that channel data is to be
sourced from the output of the receive side framer (i.e., Per-Channel Loopback; see Figure 1-1).
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TIDR: TRANSMIT IDLE DEFINITION REGISTER (Address = 2A Hex)
(MSB) (LSB)
TIDR7 TIDR6 TIDR5 TIDR4 TIDR3 TIDR2 TIDR1 TIDR0
SYMBOL POSITION NAME AND DESCRIPTION
TIDR7 TIDR.7
MSB of the Idle Code (this bit is transmitted first).
TIDR0 TIDR.0
LSB of the Idle Code (this bit is transmitted last).
9.1.2 Per-Channel Code Insertion
The second method involves using the Transmit Channel Control Registers (TCC1/2/3/4) to determine
which of the 32 E1 channels should be overwritten with the code placed in the Transmit Channel
Registers (TC1 to TC32). This method is more flexible than the first in that it allows a different 8-bit code
to be placed into each of the 32 E1 channels.
TC1 TO TC32: TRANSMIT CHANNEL REGISTERS (Address = 60 to 7F Hex)
(For brevity, only channel 1 is shown; see Table 2-1 for other register address.)
(MSB) (LSB)
C7 C6 C5 C4 C3 C2 C1 C0 TC1 (60)
SYMBOL POSITION NAME AND DESCRIPTION
C7 TC1.7
MSB of the Code (this bit is transmitted first).
C0 TC1.0
LSB of the Code (this bit is transmitted last).
TCC1/TCC2/TCC3/TCC4: TRANSMIT CHANNEL CONTROL REGISTER
(Address = A0 to A3 Hex)
(MSB) (LSB)
CH8 CH7 CH6 CH5 CH4 CH3 CH2 CH1 TCC1 (A0)
CH16 CH15 CH14 CH13 CH12 CH11 CH10 CH9 TCC2 (A1)
CH24 CH23 CH22 CH21 CH20 CH19 CH18 CH17 TCC3 (A2)
CH32 CH31 CH30 CH29 CH28 CH27 CH26 CH25 TCC4 (A3)
SYMBOL POSITION NAME AND DESCRIPTION
CH1 TCC1.0
Transmit Channel 1 Code Insertion Control Bit
0 = do not insert data from the TC1 register into the transmit data
stream
1 = insert data from the TC1 register into the transmit data stream
CH32 TCC4.7
Transmit Channel 32 Code Insertion Control Bit
0 = do not insert data from the TC32 register into the transmit data
stream
1 = insert data from the TC32 register into the transmit data stream
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9.2 Receive Side Code Generation
On the receive side, the Receive Channel Control Registers (RCC1/2/3/4) are used to determine which of
the 32 E1 channels off the E1 line and going to the backplane should be overwritten with the code placed
in the Receive Channel Registers (RC1 to RC32).
RC1 TO RC32: RECEIVE CHANNEL REGISTERS (Address = 80 to 9F)
(For brevity, only channel 1 is shown; see Table 2-1 for other register address.)
(MSB) (LSB)
C7 C6 C5 C4 C3 C2 C1 C0 RC1 (80)
SYMBOL POSITION NAME AND DESCRIPTION
C7 RC1.7
MSB of the Code (this bit is sent first to the backplane)
C0 RC1.0
LSB of the Code (this bit is sent last to the backplane)
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RCC1/RCC2/RCC3/RCC4: RECEIVE CHANNEL CONTROL REGISTER
(Address = A4 to A7 Hex)
(MSB) (LSB)
CH8 CH7 CH6 CH5 CH4 CH3 CH2 CH1 RCC1 (A4)
CH16 CH15 CH14 CH13 CH12 CH11 CH10 CH9 RCC2 (A5)
CH24 CH23 CH22 CH21 CH20 CH19 CH18 CH17 RCC3 (A6)
CH32 CH31 CH30 CH29 CH28 CH27 CH26 CH25 RCC4 (A7)
SYMBOL POSITION NAME AND DESCRIPTION
CH1 RCC1.0
Receive Channel 1 Code Insertion Control Bit
0 = do not insert data from the RC1 register into the receive data
stream
1 = insert data from the RC1 register into the receive data stream
CH32 RCC4.7
Receive Channel 32 Code Insertion Control Bit
0 = do not insert data from the RC32 register into the receive
data stream
1 = insert data from the RC32 register into the receive data
stream
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10 CLOCK BLOCKING REGISTERS
The Receive Channel Blocking Registers (RCBR1/RCBR2/RCBR3/RCBR4) and the Transmit Channel
Blocking Registers (TCBR1/TCBR2/TCBR3/TCBR4) control the RCHBLK and TCHBLK pins,
respectively. The RCHBLK and TCHCLK pins are user-programmable outputs that can be forced either
high or low during individual channels. These outputs can be used to block clocks to a USART or LAPD
controller in ISDN-PRI applications. When the appropriate bits are set to 1, the RCHBLK and TCHCLK
pins will be held high during the entire corresponding channel time. See the timing diagrams in Section
14 for an example. The TCBRs have alternate mode of use. Via the CCR3.6 bit, the user has the option to
use the TCBRs to determine, on a channel-by-channel basis, which signaling bits are to be inserted via
the TSRs (the corresponding bit in the TCBRs = 1) and which are to be sourced from the TSER or TSIG
pins (the corresponding bit in the TCBR = 0). See Section 8 for more details about this mode of
operation.
RCBR1/RCBR2/RCBR3/RCBR4: RECEIVE CHANNEL BLOCKING
REGISTERS (Address = 2B to 2E Hex)
(MSB) (LSB)
CH8 CH7 CH6 CH5 CH4 CH3 CH2 CH1 RCBR1 (2B)
CH16 CH15 CH14 CH13 CH12 CH11 CH10 CH9 RCBR2 (2C)
CH24 CH23 CH22 CH21 CH20 CH19 CH18 CH17 RCBR3 (2D)
CH32 CH31 CH30 CH29 CH28 CH27 CH26 CH25 RCBR4 (2E)
SYMBOL POSITION NAME AND DESCRIPTION
CH32 RCBR4.7
Receive Channel Blocking Registers.
0 = force the RCHBLK pin to remain low during this channel
time
CH1 RCBR1.0 1 = force the RCHBLK pin high during this channel time
TCBR1/TCBR2/TCBR3/TCBR4: TRANSMIT CHANNEL BLOCKING
REGISTERS (Address = 22 to 25 Hex)
(MSB) (LSB)
CH8 CH7 CH6 CH5 CH4 CH3 CH2 CH1 TCBR1 (22)
CH16 CH15 CH14 CH13 CH12 CH11 CH10 CH9 TCBR1 (23)
CH24 CH23 CH22 CH21 CH20 CH19 CH18 CH17 TCBR1 (24)
CH32 CH31 CH30 CH29 CH28 CH27 CH26 CH25 TCBR4 (25)
SYMBOL POSITION NAME AND DESCRIPTION
CH32 TCBR4.7
Transmit Channel Blocking Registers.
0 = force the TCHBLK pin to remain low during this channel
time
CH1 TCBR1.0 1 = force the TCHBLK pin high during this channel time
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Note: If CCR3.6 = 1, then a 0 in the TCBRs implies that signaling data is to be sourced from TSER (or
TSIG if CCR3.2 = 1) and a 1 implies that signaling data for that channel is to be sourced from the
Transmit Signaling (TS) registers. See the following definition.
TCBR1/TCBR2/TCBR3/TCBR4: DEFINITION WHEN CCR3.6 = 1
(MSB) (LSB)
CH20 CH4 CH19 CH3 CH18 CH2 CH17* CH1* TCBR1 (22)
CH24 CH8 CH23 CH7 CH22 CH6 CH21 CH5 TCBR2 (23)
CH28 CH12 CH27 CH11 CH26 CH10 CH25 CH9 TCBR3 (24)
CH32 CH16 CH31 CH15 CH30 CH14 CH29 CH13 TCBR4 (25)
*CH1 and CH17 should be set to 1 to allow the internal TS1 register to create the CAS Multiframe Alignment Word and Spare/Remote
Alarm bits.
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11 ELASTIC STORES OPERATION
The DS2154 contains dual two-frame (512 bits) elastic stores: one for the receive direction and one for
the transmit direction. These elastic stores have two main purposes. First, they can be used to rate convert
the E1 data stream to 1.544Mbps (or a multiple of 1.544Mbps), which is the T1 rate. Secondly, they can
be used to absorb the differences in frequency and phase between the T1 data stream and an
asynchronous (i.e., not frequency locked) backplane clock (which can be 1.544MHz or 2.048MHz). The
backplane clock can burst at rates up to 8.192MHz. Both elastic stores contain full controlled slip
capability, which is necessary for this second purpose. The elastic stores can be forced to a known depth
via the Elastic Store Reset bit (CCR3.4). Toggling the CCR3.4 bit forces the read and write pointers into
opposite frames. Both elastic stores within the DS2154 are fully independent and no restrictions apply to
the sourcing of the various clocks that are applied to them. The transmit side elastic store can be enabled
whether the receive elastic store is enabled or disabled and vice versa. Also, each elastic store can
interface to either a 1.544MHz or 2.048MHz backplane without regard to the backplane rate the other
elastic store is interfacing.
11.1 Receive Side
If the receive side elastic store is enabled (RCR2.1 = 1), then the user must provide either a 1.544MHz
(RCR2.2 = 0) or 2.048MHz (RCR2.2 = 1) clock at the RSYSCLK pin. The user has the option of either
providing a frame/multiframe sync at the RSYNC pin (RCR1.5 = 1) or having the RSYNC pin provide a
pulse on frame/multiframe boundaries (RCR1.5 = 0). If the user wishes to obtain pulses at the frame
boundary, then RCR1.6 must be set to 0; if the user wishes to have pulses occur at the multiframe
boundary, then RCR1.6 must be set to 1. The DS2154 will always indicate frame boundaries via the
RFSYNC output whether the elastic store is enabled or not. If the elastic store is enabled, then either CAS
(RCR1.7 = 0) or CRC4 (RCR1.7 = 1) multiframe boundaries will be indicated via the RMSYNC output.
If the user selects to apply a 1.544MHz clock to the RSYSCLK pin, then every fourth channel of the
received E1 data will be deleted and an F-bit position (which will be forced to 1) will be inserted. Hence
Channels 1, 5, 9, 13, 17, 21, 25, and 29 (time slots 0, 4, 8, 12, 16, 20, 24, and 28) will be deleted from the
received E1 data stream. Also, in 1.544MHz applications, the RCHBLK output will not be active in
Channels 25 through 32 (or in other words, RCBR4 is not active). See Section 14 for timing details. If the
512-bit elastic buffer either fills or empties, a controlled slip will occur. If the buffer empties, then a full
frame of data (256 bits) will be repeated at RSER and the SR1.4 and RIR.3 bits will be set to a 1. If the
buffer fills, then a full frame of data will be deleted and the SR1.4 and RIR.4 bits will be set to a 1.
11.2 Transmit Side
The operation of the transmit elastic store is very similar to the receive side. The transmit side elastic
store is enabled via CCR3.7. A 1.544MHz (CCR3.1 = 0) or 2.048MHz (CCR3.1 = 1) clock can be
applied to the TSYSCLK input. The TSYSCLK can be a bursty clock with rates up to 8.192MHz. If the
user selects to apply a 1.544MHz clock to the TSYSCLK pin, then the data sampled at TSER will be
stuffed with eight empty channels. The user must supply an 8kHz frame sync pulse to the TSSYNC input.
See Section 14 for timing details. Controlled slips in the transmit elastic store are reported in the SR2.0
bit and the direction of the slip is reported in the RIR.6 and RIR.7 bits.
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12 ADDITIONAL (Sa) AND INTERNATIONAL (Si) BIT OPERATION
The DS2154 provides for access to both the Sa and the Si bits via three different methods. The first is via
a hardware scheme using the RLINK/RLCLK and TLINK/ TLCLK pins. The first method is discussed in
Section 12.1. The second involves using the internal RAF/RNAF and TAF/TNAF registers and is
discussed in Section 12.2. The third method, which is covered in Section 12.3, involves an expanded
version of the second method and is one of the features added to the DS2154 from the original DS2153
definition.
12.1 Hardware Scheme
On the receive side, all the received data is reported at the RLINK pin. Via RCR2, the user can control
the RLCLK pin to pulse during any combination of Sa bits. This allows the user to create a clock that can
be used to capture the needed Sa bits. If RSYNC is programmed to output a frame boundary, it will
identify the Si bits. See Section 14 for detailed timing.
On the transmit side, the individual Sa bits can be either sourced from the internal TNAF register (see
Section 12.2 for details) or from the external TLINK pin. Via TCR2, the DS2154 can be programmed to
source any combination of the additional bits from the TLINK pin. If the user wishes to pass the Sa bits
through the DS2154 without them being altered, then the device should be set up to source all five Sa bits
via the TLINK pin and the TLINK pin should be tied to the TSER pin. Si bits can be inserted through the
TSER pin via the clearing of the TCR1.3 bit. See the timing diagrams and the transmit data flow diagram
in Section 14 for examples.
12.2 Internal Register Scheme Based on Double-Frame
On the receive side, the RAF and RNAF registers will always report the data as it received in the
Additional and International bit locations. The RAF and RNAF registers are updated with the setting of
the Receive Align Frame bit in Status Register 2 (SR2.6). The host can use the SR2.6 bit to know when to
read the RAF and RNAF registers. It has 250µs to retrieve the data before it is lost.
On the transmit side, data is sampled from the TAF and TNAF registers with the setting of the Transmit
Align Frame bit in Status Register 2 (SR2.3). The host can use the SR2.3 bit to know when to update the
TAF and TNAF registers. It has 250µs to update the data or else the old data will be retransmitted. Data
in the Si bit position will be overwritten if either the DS2154 is programmed: (1) to source the Si bits
from the TSER pin, (2) in the CRC4 mode, or (3) have automatic E-bit insertion enabled. Data in the Sa
bit position will be overwritten if any of the TCR2.3 to TCR2.7 bits are set to 1 (see Section 12.1 for
details). See the register descriptions for TCR1 and TCR2 and the Transmit Data Flow diagram
(Figure 14-11) for more details.
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RAF: RECEIVE ALIGN FRAME REGISTER (Address = 2F Hex)
(MSB) (LSB)
Si 0 0 1 1 0 1 1
SYMBOL POSITION NAME AND DESCRIPTION
Si RAF.7 International Bit.
0 RAF.6
Frame Alignment Signal Bit.
0 RAF.5
Frame Alignment Signal Bit.
1 RAF.4
Frame Alignment Signal Bit.
1 RAF.3
Frame Alignment Signal Bit.
0 RAF.2
Frame Alignment Signal Bit.
1 RAF.1
Frame Alignment Signal Bit.
1 RAF.0
Frame Alignment Signal Bit.
RNAF: RECEIVE NON-ALIGN FRAME REGISTER (Address = 1F Hex)
(MSB) (LSB)
Si 1 A Sa4 Sa5 Sa6 Sa7 Sa8
SYMBOL POSITION NAME AND DESCRIPTION
Si RNAF.7 International Bit.
1 RNAF.6
Frame Non-Alignment Signal Bit.
A RNAF.5
Remote Alarm.
Sa4 RNAF.4
Additional Bit 4.
Sa5 RNAF.3
Additional Bit 5.
Sa6 RNAF.2
Additional Bit 6.
Sa7 RNAF.1
Additional Bit 7.
Sa8 RNAF.0
Additional Bit 8.
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TAF: TRANSMIT ALIGN FRAME REGISTER (Address = 20 Hex)
(MSB) (LSB)
Si 0 0 1 1 0 1 1
(Note: Must be programmed with the 7-bit FAS word; the DS2154 does not automatically set these bits.)
SYMBOL POSITION NAME AND DESCRIPTION
Si TAF.7 International Bit.
0 TAF.6
Frame Alignment Signal Bit.
0 TAF.5
Frame Alignment Signal Bit.
1 TAF.4
Frame Alignment Signal Bit.
1 TAF.3
Frame Alignment Signal Bit.
0 TAF.2
Frame Alignment Signal Bit.
1 TAF.1
Frame Alignment Signal Bit.
1 TAF.0
Frame Alignment Signal Bit.
TNAF: TRANSMIT NON-ALIGN FRAME REGISTER (Address = 21 Hex)
(MSB) (LSB)
Si 1 A Sa4 Sa5 Sa6 Sa7 Sa8
(Note: Bit 2 must be programmed to 1; the DS2154 does not automatically set this bit.)
SYMBOL POSITION NAME AND DESCRIPTION
Si TNAF.7 International Bit.
1 TNAF.6
Frame Non-Alignment Signal Bit.
A TNAF.5
Remote Alarm (used to transmit the alarm).
Sa4 TNAF.4
Additional Bit 4.
Sa5 TNAF.3
Additional Bit 5.
Sa6 TNAF.2
Additional Bit 6.
Sa7 TNAF.1
Additional Bit 7.
Sa8 TNAF.0
Additional Bit 8.
DS2154
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12.3 Internal Register Scheme Based on CRC4 Multiframe
On the receive side, there is a set of eight registers (RSiAF, RSiNAF, RRA, RSa4 to RSa8) that report the
Si and Sa bits as they are received. These registers are updated with the setting of the Receive CRC4
Multiframe bit in Status Register 2 (SR2.1). The host can use the SR2.1 bit to know when to read these
registers. The user has 2ms to retrieve the data before it is lost. The MSB of each register is the first
received. See the register descriptions below and the Transmit Data Flow diagram (Figure 14-11) for
more details.
On the transmit side, there is also a set of eight registers (TSiAF, TSiNAF, TRA, TSa4 to TSa8) that can
be programmed to insert both Si and Sa data via the Transmit Sa Bit Control Register (TSaCR). Data is
sampled from these registers with the setting of the Transmit Multiframe bit in Status Register 2 (SR2.5).
The host can use the SR2.5 bit to know when to update these registers. It has 2ms to update the data or
else the old data will be retransmitted. The MSB of each register is the first bit transmitted. See the
register descriptions below and the Transmit Data Flow diagram (Figure 14-11) for more details.
REGISTER
NAME
ADDRESS
(HEX) FUNCTION
RSiAF 58 The 8 Si bits in the align frame
RSiNAF 59 The 8 Si bits in the non-align frame
RRA 5A
The 8 reportings of the receive remote alarm (RA)
RSa4 5B The 8 Sa4 reported in each CRC4 multiframe
RSa5 5C The 8 Sa5 reported in each CRC4 multiframe
RSa6 5D The 8 Sa6 reported in each CRC4 multiframe
RSa7 5E The 8 Sa7 reported in each CRC4 multiframe
RSa8 5F The eight Sa8 reported in each CRC4 multiframe
TSiAF 50 The 8 Si bits to be inserted into the align frame
TSiNAF 51 The 8 Si bits to be inserted into the non-align frame
TRA 52 The 8 settings of remote alarm (RA)
TSa4 53 The 8 Sa4 settings in each CRC4 multiframe
TSa5 54 The 8 Sa5 settings in each CRC4 multiframe
TSa6 55 The 8 Sa6 settings in each CRC4 multiframe
TSa7 56 The 8 Sa7 settings in each CRC4 multiframe
TSa8 57 The 8 Sa8 settings in each CRC4 multiframe
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TSaCR: TRANSMIT Sa BIT CONTROL REGISTER (Address = 1C Hex)
(MSB) (LSB)
SiAF SiNAF RA Sa4 Sa5 Sa6 Sa7 Sa8
SYMBOL POSITION NAME AND DESCRIPTION
SiAF TSaCR.7
International Bit in Align Frame Insertion Control Bit.
0 = do not insert data from the TSiAF register into the transmit data
stream
1 = insert data from the TSiAF register into the transmit data stream
SiNAF TSaCR.6
International Bit in Non-Align Frame Insertion Control Bit.
0 = do not insert data from the TSiNAF register into the transmit
data stream
1 = insert data from the TSiNAF register into the transmit data
stream
RA TSaCR.5
Remote Alarm Insertion Control Bit.
0 = do not insert data from the TRA register into the transmit data
stream
1 = insert data from the TRA register into the transmit data stream
Sa4 TSaCR.4
Additional Bit 4 Insertion Control Bit.
0 = do not insert data from the TSa4 register into the transmit data
stream
1 = insert data from the TSa4 register into the transmit data stream
Sa5 TSaCR.3
Additional Bit 5 Insertion Control Bit.
0 = do not insert data from the TSa5 register into the transmit data
stream
1 = insert data from the TSa5 register into the transmit data stream
Sa6 TSaCR.2
Additional Bit 6 Insertion Control Bit.
0 = do not insert data from the TSa6 register into the transmit data
stream
1 = insert data from the TSa6 register into the transmit data stream
Sa7 TSaCR.1
Additional Bit 7 Insertion Control Bit.
0 = do not insert data from the TSa7 register into the transmit data
stream
1 = insert data from the TSa7 register into the transmit data stream
Sa8 TSaCR.0
Additional Bit 8 Insertion Control Bit.
0 = do not insert data from the TSa8 register into the transmit data
stream
1 = insert data from the TSa8 register into the transmit data stream
DS2154
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13 LINE INTERFACE FUNCTION
The line interface function in the DS2152 contains three sections: the receiver, which handles clock and
data recovery; the transmitter, which waveshapes and drives the E1 line; and the jitter attenuator. Each of
these three sections is controlled by the Line Interface Control Register (LICR), which is described
below.
LICR: LINE INTERFACE CONTROL REGISTER (Address = 18 Hex)
(MSB) (LSB)
L2 L1 L0 EGL JAS JABDS DJA TPD LICR
SYMBOL POSITION NAME AND DESCRIPTION
L2 LICR.7 Line Build-Out Select Bit 2. Sets the transmitter build out; see
the Table 13-2.
L1 LICR.6 Line Build-Out Select Bit 1. Sets the transmitter build out; see
the Table 13-2.
L0 LICR.5 Line Build-Out Select Bit 0. Sets the transmitter build out; see
the Table 13-2.
EGL LICR.4
Receive Equalizer Gain Limit.
0 = -12dB
1 = -43dB
JAS LICR.3
Jitter Attenuator Select.
0 = place the jitter attenuator on the receive side
1 = place the jitter attenuator on the transmit side
JABDS LICR.2
Jitter Attenuator Buffer Depth Select
0 = 128 bits
1 = 32 bits (use for delay sensitive applications)
DJA LICR.1
Disable Jitter Attenuator.
0 = jitter attenuator enabled
1 = jitter attenuator disabled
TPD LICR.0
Transmit Power-Down.
0 = normal transmitter operation
1 = powers down the transmitter and tri-states the TTIP and
TRING pins
DS2154
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13.1 Receive Clock and Data Recovery
The DS2154 contains a digital clock recovery system. See Figure 1-1 and Figure 13-1 for more details.
The DS2154 couples to the receive E1 shielded twisted pair or coax via a 1:1 transformer. See Table 13-2
for transformer details. The 2.048MHz clock attached at the MCLK pin is internally multiplied by 16 via
an internal PLL and fed to the clock recovery system. The clock recovery system uses the clock from the
PLL circuit to form a 16 times oversampler, which is used to recover the clock and data. This
oversampling technique offers outstanding jitter tolerance (see Figure 13-2).
Normally, the clock that is output at the RCLKO pin is the recovered clock from the E1 AMI/B8ZS
waveform presented at the RTIP and RRING inputs. When no AMI signal is present at RTIP and RRING,
a Receive Carrier Loss (LRCL) condition will occur and the RCLKO will be sourced from the clock
applied at the MCLK pin. If the jitter attenuator is either placed in the transmit path or is disabled, the
RCLKO output can exhibit slightly shorter high cycles of the clock. This is due to the highly over-
sampled digital clock recovery circuitry. If the jitter attenuator is placed in the receive path (as is the case
in most applications), the jitter attenuator restores the RCLK to being close to 50% duty cycle. See the
Receive AC Timing Characteristics in Section 16 for more details.
13.2 Transmit Waveshaping and Line Driving
The DS2154 uses a set of laser-trimmed delay lines along with a precision Digital-to-Analog Converter
(DAC) to create the waveforms that are transmitted onto the E1 line. The waveforms created by the
DS2154 meet the ITU G.703 specifications. See Figure 13-3. The user will select which waveform is to
be generated by properly programming the L2/L1/L0 bits in the Line Interface Control Register (LICR).
The DS2154 can set up in a number of various configurations depending on the application. See
Table 13-1 and Figure 13-1.
Table 13-1. Line Build-Out Select in LICR
LLL
210 APPLICATION TRANSFORMER
RETURN
LOSS
(dB)
RT ()
(SEE Figure 13-1)
000 75 normal (See Note 1) 1:1.15 step-up N.M. 0
001 120 normal 1:1.15 step-up N.M. 0
010 75 with protection resistors 1:1.15 step-up N.M. 8.2
011 120 with protection resistors 1:1.15 step-up N.M. 8.2
100 75 with high return loss 1:1.15 step-up 21 27
110 75 with high return loss 1:1.36 step-up 21 18
100 120 with high return loss 1:1.36 step-up 21 27
N.M. = not meaningful
Note: This LBO is not recommended for use in the DS2154 A2 revision.
Due to the nature of the design of the transmitter in the DS2154, very little jitter (less than 0.005UIP-P
broadband from 10Hz to 100kHz) is added to the jitter present on TCLKI. Also, the waveforms that they
create are independent of the duty cycle of TCLK. The transmitter in the DS2154 couples to the E1
transmit shielded twisted pair or coax via a 1:1.15 or 1:1.36 step-up transformer as shown in Figure 13-1.
For the devices to create the proper waveforms, this transformer used must meet the specifications listed
DS2154
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in Table 13-2. The line driver in the DS2154 contains a current limiter that prevents more than 50mA
(RMS) from being sourced in a 1 load.
Table 13-2. Transformer Specifications
SPECIFICATION RECOMMENDED VALUE
Turns Ratio 1:1 (receive) and 1:1.15 or 1:1.36 (transmit) ±5%
Primary Inductance 600µH minimum
Leakage Inductance 1.0µH maximum
Intertwining Capacitance 40pF maximum
DC Resistance 1.2 maximum
13.3 Jitter Attenuator
The DS2154 contains an on-board jitter attenuator that can be set to a depth of either 32 or 128 bits via
the JABDS bit in the Line Interface Control Register (LICR). The 128-bit mode is used in applications
where large excursions of wander are expected. The 32-bit mode is used in delay sensitive applications.
The characteristics of the attenuation are shown in Figure 13-4. The jitter attenuator can be placed in
either the receive path or the transmit path by appropriately setting or clearing the JAS bit in the LICR.
Also, the jitter attenuator can be disabled (in effect, removed) by setting the DJA bit in the LICR. In order
for the jitter attenuator to operate properly, a 2.048MHz clock (±50ppm) must be applied at the MCLK
pin or a crystal with similar characteristics must be applied across the MCLK and XTALD pins. If a
crystal is applied across the MCLK and XTALD pins, then capacitors should be placed from each leg of
the crystal to the local ground plane as shown in Figure 13-1. On-board circuitry adjusts either the
recovered clock from the clock/data recovery block or the clock applied at the TCLKI pin to create a
smooth jitter-free clock that is used to clock data out of the jitter attenuator FIFO. It is acceptable to
provide a gapped/bursty clock at the TCLKI pin if the jitter attenuator is placed on the transmit side. If the
incoming jitter exceeds either 120UIP-P (buffer depth is 128 bits) or 28UIP-P (buffer depth is 32 bits), then
the DS2154 will divide the internal nominal 32.768MHz clock by either 15 or 17 instead of the normal 16
to keep the buffer from overflowing. When the device divides by either 15 or 17, it also sets the Jitter
Attenuator Limit Trip (JALT) bit in the Receive Information Register (RIR.5).
DS2154
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Figure 13-1. External Analog Connections
NOTE 1: RESISTOR VALUES ARE ±1%.
NOTE 2: THE RT RESISTORS ARE USED TO INCREASE THE TRANSMITTER RETURN LOSS OR TO PROTECT THE DEVICE FROM OVERVOLTAGE.
NOTE 3: THE RR RESISTORS ARE USED TO TERMINATE THE RECEIVE E1 LINE.
NOTE 4: FOR 75 TERMINATION, RR = 37.4; FOR 120 TERMINATION RR = 60.
NOTE 5: SEE THE SEPARATE APPLICATION NOTE FOR DETAILS ON HOW TO CONSTRUCT A PROTECTED INTERFACE.
NOTE 6: EITHER A CRYSTAL CAN BE APPLIED ACROSS THE MCLK AND XTALD PINS OR A TTL LEVEL CLOCK CAN BE APPLIED TO JUST MCLK.
NOTE 7: C1 AND C2 SHOULD BE 5PF LOWER THAN TWO TIMES THE NOMINAL LOADING CAPACITANCE OF THE CRYSTAL TO ADJUST FOR THE
INPUT CAPACITANCE OF THE DS2154.
DS2154
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Figure 13-2. Jitter Tolerance
Figure 13-3. Transmit Waveform Template
DS2154
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Figure 13-4. Jitter Attenuation
DS2154
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14 TIMING DIAGRAMS
Figure 14-1. Receive Side Timing
Figure 14-2. Receive Side Boundary Timing (with Elastic Store Disabled)
NOTE 1: RSYNC IN THE FRAME MODE (RCR1.6 = 0).
NOTE 2: RSYNC IN THE FRAME MODE (RCR1.6 = 0).
NOTE 3: RSYNC IS PROGRAMMED TO PULSE HIGH DURING THE Sa4 BIT POSITION.
NOTE 4: RLINK WILL ALWAYS OUTPUT ALL FIVE Sa BITS AS WELL AS THE REST OF THE RECEIVE DATASTREAM.
NOTE 5: THIS DIAGRAM ASSUMES THE CAS MF BEGINS WITH THE FAS WORD.
NOTE 1: RCHBLK IS PROGRAMMED TO BLOCK CHANNEL 2.
NOTE 2: RLCLK IS PROGRAMMED TO PULSE HIGH DURING THE Sa4 BITS POSITION.
NOTE 3: SHOWN IS A NON-ALIGN FRAME BOUNDARY.
NOTE 4: RSIG NORMALLY CONTAINS THE CAS MULTIFRAME ALIGNMENT NIBBLE (0000) IN CHANNEL 1.
DS2154
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Figure 14-3. Receive Side 1.544MHz Boundary Timing (with Elastic Store
Enabled)
Figure 14-4. Receive Side 2.048MHz Boundary Timing (with Elastic Store
Enabled)
NOTE 1: DATA FROM THE E1 CHANNELS 1, 5, 9, 13, 17, 21, 25, AND 29 IS DROPPED (CHANNEL 2 FROM THE E1 LINK IS
MAPPED TO CHANNEL 1 OF THE T1 LINK, ETC.) AND THE F-BIT POSITION IS ADDED (FORCED TO 1).
NOTE 2: RSYNC IS IN THE OUTPUT MODE (RCR1.5 = 0).
NOTE 3: RSYNC IS IN THE INPUT MODE (RCR1.5 = 1).
NOTE 4: RCHBLK IS PROGRAMMED TO BLOCK CHANNEL 24.
NOTE 1: RSYNC IS IN THE OUTPUT MODE (RCR1.5 = 0).
NOTE 2: RSYNC IS IN THE INPUT MODE (RCR1.5 = 1).
NOTE 3: RCHBLK IS PROGRAMMED TO BLOCK CHANNEL 1.
NOTE 4: RSIG NORMALLY CONTAINS THE CAS MULTIFRAME ALIGNMENT NIBBLE (0000) IN CHANNEL 1.
DS2154
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Figure 14-5. Transmit Side Timing
Figure 14-6. Transmit Side Boundary Timing
NOTE 1: TSYNC IN THE FRAME MODE (TCR1.1 = 0).
NOTE 2: TSYNC IN THE MULTIFRAME MODE (TCR1.1 = 1).
NOTE 4: TLINK IS PROGRAMMED TO SOURCE ONLY THE Sa4 BIT.
NOTE 5: THIS DIAGRAM ASSUMES BOTH THE CAS MF AND THE CRC4 BEGIN WITH THE ALIGN FRAME.
NOTE 1: TSYNC IS IN THE INPUT MODE (TCR1.0 = 0).
NOTE 2: TSYNC IS IN THE OUTPUT MODE (TCR1.0 = 1).
NOTE 3: TCHBLK IS PROGRAMMED TO BLOCK CHANNEL 2.
NOTE 4: TLINK IS PROGRAMMED TO SOURCE THE Sa4 BITS.
NOTE 5: THE SIGNALING DATA AT TSIG DURING CHANNEL 1 IS NORMALLY OVERWRITTEN IN THE TRANSMIT FORMATTER WITH THE
CAS MULTIFRAME ALIGNMENT NIBBLE (0000).
NOTE 4: SHOWN IS A NON-ALIGN FRAME BOUNDARY.
DS2154
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Figure 14-7. Transmit Side 1.544MHz Boundary Timing (with Elastic Store
Enabled)
Figure 14-8. Transmit Side 2.048MHz Boundary Timing (with Elastic Store
Enabled)
NOTE 1: TCHBLK IS PROGRAMMED TO BLOCK CHANNEL 24.
NOTE 2: THE F-BIT POSITION IS IGNORED BY THE DS2154.
NOTE 1: TCHBLK IS PROGRAMMED TO BLOCK CHANNEL 31.
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Figure 14-9. G.802 Timing
NOTE 1: RCHBLK OR TCHBLK IS PROGRAMMED TO PULSE HIGH DURING TIME SLOTS 1 TO 15, 17, 25, AND DURING BIT 1 OF TIME SLOT 26.
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Figure 14-10. Synchronization Flow Chart
DS2154
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Figure 14-11. Transmit Data Flow
NOTE 1: TCLK SHOULD BE TIED TO RCLK AND TSYNC SHOULD BE TIED TO RFSYNC FOR DATA TO BE PROPERLY SOURCED FROM RSER.
NOTE 2: AUTO REMOTE ALARM IF ENABLED WILL ONLY OVERWRITE BIT 3 OF TIME SLOT 0 IN THE NON-
A
LIGN FRAMES IN THE ALARM NEEDS
TO BE SENT.
DS2154
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15 DC CHARACTERISTICS
ABSOLUTE MAXIMUM RATINGS
Voltage Range on Any Pin Relative to Ground……………………………………………..-1.0V to +7.0V
Operating Temperature Range
Commercial……………………………………………………………………………0°C to +70°C
Industrial…………………………………………………………………………….-40°C to +85°C
Storage Temperature……………………………………………………………………….-55°C to +125°C
Soldering Temperature……………………………………………See IPC/JEDEC STD-020 Specification
This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operation
sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods of time may affect
reliability.
Table 15-1. Recommended DC Operating Conditions
(TA = 0°C to +70°C for DS2154L, TA = -40°C to +85°C for DS2154LN.)
PARAMETER SYMBOL MIN TYP MAX UNITS NOTES
Logic 1 VIH 2.0 VDD + 0.3 V
Logic 0 VIL -0.3 +0.8 V
Supply VDD 4.75 5.25 V 1
Table 15-2. Capacitance
(TA = +25°C)
PARAMETER SYMBOL MIN TYP MAX UNITS NOTES
Input Capacitance CIN 5 pF
Output Capacitance COUT 7 pF
Table 15-3. DC Characteristics
(VDD = 5V ±5%, TA = 0°C to +70°C for DS2154L, TA = -40°C to +85°C for DS2154LN.)
PARAMETER SYMBOL MIN TYP MAX UNITS NOTES
Supply Current at 5V IDD 75 mA 2
Input Leakage IIL -1.0 +1.0
µA 3
Output Leakage ILO 1.0
µA 4
Output Current (2.4V) IOH -1.0 mA
Output Current (0.4V) IOL +4.0 mA
NOTES:
1. Applies to RVDD, TVDD, and DVDD.
2. TCLK = RCLK = TSYSCLK = RSYSCLK = 2.048MHz; outputs open circuited.
3. 0V < VIN < VDD.
4. Applied to INT when tri-stated.
DS2154
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16 AC CHARACTERISTICS
Table 16-1. AC Characteristics—Multiplexed Parallel Port (MUX = 1)
(VDD = 5V ±5%, TA = 0°C to +70°C for DS2154L, TA = -40°C to +85°C for DS2154LN.)
(See Figure 16-1, Figure 16-2, and Figure 16-3.)
PARAMETER SYMBOL MIN TYP MAX UNITS NOTES
Cycle Time tCYC 200 ns
Pulse Width, DS Low or RD High PWEL 100 ns
Pulse Width, DS High or RD Low PWEH 100 ns
Input Rise/Fall Times tR, tF 20 ns
R/ W Hold Time tRWH 10 ns
R/ W Setup Time Before DS High tRWS 50 ns
CS Setup Time Before DS, WR or RD
active tCS 20 ns
CS Hold Time tCH 0 ns
Read Data Hold Time tDHR 10 50 ns
Write Data Hold Time tDHW 0 ns
Muxed Address Valid to AS or ALE Fall tASL 15 ns
Muxed Address Hold Time tAHL 10 ns
Delay Time, DS, WR or RD to AS or ALE
Rise tASD 20 ns
Pulse Width AS or ALE High PWASH 30 ns
Delay Time, AS or ALE to DS, WR or RD tASED 10 ns
Output Data Delay Time from DS or RD tDDR 20 80 ns
Data Setup Time tDSW 50 ns
Figure 16-1. Intel Bus Read AC Timing (BTS = 0/MUX = 1)
DS2154
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Figure 16-2. Intel Bus Write AC Timing (BTS = 0/MUX = 1)
Figure 16-3. Motorola Bus AC Timing (BTS = 1/MUX = 1)
DS2154
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Table 16-2. AC Characteristics—Receive Side
(VDD = 5V ±5%, TA = 0°C to +70°C for DS2154L, TA = -40°C to +85°C for DS2154LN.)
(See Figure 16-4, Figure 16-5, and Figure 16-6.)
PARAMETER SYMBOL MIN TYP MAX UNITS NOTES
RCLKO Period tLP 488 ns
tLH 200 244 ns 1
RCLKO Pulse Width tLL 200 244 ns 1
tLH 150 244 ns 2
RCLKO Pulse Width tCL 150 244 ns 2
RCLKI Period tCP 488 ns
tCH 75 ns
RCLKI Pulse Width tCL 75 ns
tSP 122 648 ns 3
RSYSCLK Period tSP 122 488 ns 4
tSH 50 ns
RSYSCLK Pulse Width tSL 50 ns
RSYNC Setup to RSYSCLK Falling tSU 20 tSH-5 ns
RSYNC Pulse Width tPW 50 ns
RPOSI/RNEGI Setup to RCLKI Falling tSU 20 ns
RPOSI/RNEGI Hold From RCLKI Falling tHD 20 ns
RSYSCLK/RCLKI Rise and Fall Times tR, tF 25 ns
Delay RCLKO to RPOSO, RNEGO Valid tDD 50 ns
Delay RCLK to RSER, RDATA, RSIG,
RLINK Valid tD1 50 ns
Delay RCLK to RCHCLK, RSYNC,
RCHBLK, RFSYNC, RLCLK tD2 50 ns
Delay RSYSCLK to RSER, RSIG Valid tD3 50 ns
Delay RSYSCLK to RCHCLK, RCHBLK,
RMSYNC, RSYNC tD4 50 ns
NOTES:
1) Jitter attenuator enabled in the receive path.
2) Jitter attenuator disabled or enabled in the transmit path.
3) RSYSCLK = 1.544MHz.
4) RSYSCLK = 2.048MHz.
DS2154
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Figure 16-4. Receive Side AC Timing
NOTE 1: RSYNC IS IN THE OUTPUT MODE (RCR1.5 = 0).
NOTE 2: RLCLK ONLY PULSES HIGH DURING Sa BIT LOCATIONS AS DEFINTED IN RCR2; NO
RELATIONSHIP BETWEEN RLCLK AND RSYNC OR RFSYNC IS IMPLIED.
DS2154
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Figure 16-5. Receive System Side AC Timing
Figure 16-6. Receive Line Interface AC Timing
NOTE 1: RSYNC IS IN THE OUTPUT MODE (RCR1.5 = 0).
NOTE 2: RSYNC IS IN THE INPUT MODE (RCR1.5 = 1).
DS2154
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Table 16-3. AC Characteristics—Transmit Side
(VDD = 5V ±5%, TA = 0°C to +70°C for DS2154L, TA = -40°C to +85°C for DS2154LN.)
(See Figure 16-7, Figure 16-8, and Figure 16-9.)
PARAMETER SYMBOL MIN TYP MAX UNITS NOTES
TCLK Period tCP 488 ns
tCH 75 ns
TCLK Pulse Width tCL 75 ns
TCLKI Period tLP 488 ns
tLH 75 ns
TCLKI Pulse Width tLL 75 ns
tSP 122 648 ns 1
TSYSCLK Period tSP 122 448 ns 2
tSH 50 ns
TSYSCLK Pulse Width tSL 50 ns
TSYNC or TSSYNC Setup to TCLK or
TSYSCLK Falling tSU 20
tCH-5
or
tSH-5
ns
TSYNC or TSSYNC Pulse Width tPW 50 ns
TSER, TSIG, TDATA, TLINK, TPOSI,
TNEGI Setup to TCLK, TSYSCLK,
TCLKI Falling
tSU 20 ns
TSER, TSIG, TDATA, TLINK, TPOSI,
TNEGI Hold from TCLK, TSYSCLK,
TCLKI Falling
tHD 20 ns
TCLK, TCLKI, or TSYSCLK Rise and
Fall Times tR, tF 25 ns
Delay TCLKO to TPOSO, TNEGO Valid tDD 50 ns
Delay TCLK to TESO Valid tD1 50 ns
Delay TCLK to TCHBLK, TCHBLK,
TSYNC, TLCLK tD2 50 ns
Delay TSYSCLK to TCHCLK, TCHBLK tD3 75 ns
NOTES:
1) TSYSCLK = 1.544MHz.
2) TSYSCLK = 2.048MHz.
DS2154
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Figure 16-7. Transmit Side AC Timing
NOTE 1: TSYNC IS IN THE OUTPUT MODE (TCR1.0 = 1).
NOTE 2: TSYNC IS IN THE INPUT MODE (TCR1.0 = 0).
NOTE 3: TSER IS SAMPLED ON THE FALLING EDGE OF TCLK WHEN THE TRANSMIT SIDE ELASTIC STORE IS DISABLED.
NOTE 4: TCHCLK AND TCHBLK ARE SYNCHRONOUS WITH TCLK WHEN THE TRANSMIT SIDE ELASTIC STORE IS DISABLED.
NOTE 5: TLINK IS ONLY SAMPLED DURING Sa-BIT LOCATIONS AS DEFINED IN TCR2. NO RELATIONSHIP BETWEEN TLCLK/TLINK AND
TSYNC IS IMPLIED.
DS2154
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Figure 16-8. Transmit System Side AC Timing
Figure 16-9. Transmit Line Interface Side AC Timing
NOTE 1: TSER IS ONLY SAMPLED ON THE FALLING EDGE OF TSYSCLK WHEN THE TRANSMIT SIDE ELASTIC STORE IS ENABLED.
NOTE 2: TCHCLK AND TCHBLK ARE SYNCHRONOUS WITH TSYSCLK WHEN THE TRANSMIT SIDE ELASTIC STORE IS ENABLED.
DS2154
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Table 16-4. AC Characteristics—Nonmultiplexed Parallel Port (MUX = 0)
(VDD = 5V ±5%, TA = 0°C to +70°C for DS2154L, TA = -40°C to +85°C for DS2154LN.)
(See Figure 16-10, Figure 16-11, Figure 16-12, and Figure 16-13.)
PARAMETER SYMBOL MIN TYP MAX UNITS NOTES
Setup Time for A0 to A7 Valid to CS
Active t1 0 ns
Setup Time for CS Active to Either RD ,
WR , or DS Active t2 0 ns
Delay Time from Either RD or DS
Active to Data Valid t3 75 ns
Hold Time from Either RD , WR , or DS
Inactive to CS Inactive t4 0 ns
Hold Time from CS Inactive to Data
Bus Tri-State t5 5 20 ns
Wait Time from Either WR or DS
Active to Latch Data t6 75 ns
Data Setup Time to Either WR or DS
Inactive t7 10 ns
Data Hold Time to Either WR or DS
Inactive t8 10 ns
Address Hold from Either WR or DS
Inactive t9 10 ns
Figure 16-10. Intel Bus Read AC Timing (BTS = 0/MUX = 0)
DS2154
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Figure 16-11. Intel Bus Write AC Timing (BTS=0/MUX=0)
Figure 16-12. Motorola Bus Read AC Timing (BTS = 1/MUX = 0)
Figure 16-13. Motorola Bus Write AC Timing (BTS = 1/MUX = 0)
DS2154
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Maxim/Dallas Semiconductor cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim/Dallas Semiconductor product.
No circuit patent licenses are implied. Maxim/Dallas Semiconductor reserves the right to change the circuitry and specifications without notice at any time.
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© 2006 Maxim Integrated Products Printed USA
The Maxim logo is a registered trademark of Maxim Integrated Products, Inc. The Dallas logo is a registered trademark of Dallas Semiconductor.
17 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.)
17.1 100-Pin LQFP (56-G5002-000)
Mouser Electronics
Authorized Distributor
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