EZ80F917050SBCG - Zilog, Inc.

PS027001-0707

Product Specification

eZ80AcclaimPlus!™ Connectivity ASSP

eZ80F91 ASSP

www.zilog.com

PS027001-0707

This publication is subject to replacement by a later edit ion. To de termine whether a later edition exists, or

to request copies of publications, please visit www.zilog.com.

Document Disclaimer

technology described is intended to suggest possible uses and may be superseded. Zilog, INC. DOES NOT ASSUME

LIABILITY FOR OR PROVIDE A REPRESENTATION OF ACCURACY OF THE INFORMATION, DEVICES,

OR TECHNOLOGY DESCRIBED IN THIS DOCUMENT. Zilog ALSO DOES NOT ASSUME LIABILITY FOR

INTELLECTUAL PROPERTY INFRINGEMENT RELATED IN ANY MANNER TO USE OF INFORMATION,

DEVICES, OR TECHNOLOGY DESCRIBED HEREIN OR OTHERWISE. Except with the express written

approval Zilog, use of information, devices, or techn ology as critical components of life support systems is not

authorized. No licenses or other rights are conveyed, implicitly or otherwise, by this document under any intellectual

property rights.

Zilog is a registered trademark of Zilog Inc. in the United States and in other countries. Z8, Z8 Encore!, Z8 Encore!

XP, Z8 Encore! MC, Crimzon, eZ80, and ZNEO are trademarks or registered trademarks of Zilog, Inc. All other

product or service names are the property of their respective owners.

PS027001-0707 Revision History

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iii

Revision History

Each instance in the Revision History reflects a change to this document from its previous

revision. For more details, refer to the corresponding pages or appropriate links given in

the table below.

Date Revision

Level Section Description Page

July 2007 1 All Original Issue. All

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Table of Contents

Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .iii

Table of Contents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . v

Architectural Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1

Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1

Block Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2

Pin Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4

Pin Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6

System Clock Source Options . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25

Register Map . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27

eZ80® CPU Core . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39

Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39

New Instructions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39

Reset . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 41

External Reset Input and Indicator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 41

Power-On Reset . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42

Voltage Brownout Reset . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42

Low-Power Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45

SLEEP Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45

HALT Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45

Clock Peripheral Power-Down Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 46

General Purpose Input/Output . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 49

GPIO Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 49

GPIO Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 54

GPIO Control Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 55

Interrupt Controller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 57

Maskable Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 57

GPIO Port Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 64

Chip Selects and Wait States . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 65

Memory and I/O Chip Selects . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 65

Memory Chip Select Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 65

Input/Output Chip Select Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 68

Wait States . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 68

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WAIT Input Signal . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 69

Chip Selects During Bus Request/Bus Acknowledge Cycles . . . . . . . . . . . . . . . 70

Bus Mode Controller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 70

eZ80® Bus Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 71

Z80 Bus Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 71

Intel Bus Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 73

Motorola Bus Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 80

Chip Select Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 85

Bus Arbiter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 89

Random Access Memory . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 93

RAM Control Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 94

Flash Memory . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 97

Flash Memory Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 98

Reading Flash Memory . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 98

Memory Read . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 99

Programming Flash Memory . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 99

Erasing Flash Memory . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 101

Information Page Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 102

Flash Control Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 102

Watchdog Timer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 115

Watchdog Timer Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 116

Watchdog Timer Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 117

Programmable Reload Timers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 121

Basic Timer Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 122

Specialty Timer Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 126

Timer Port Pin Allocation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 129

Timer Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 130

Multi-PWM Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 145

PWM Master Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 148

Modification of Edge Transition Values . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 148

AND/OR Gating of the PWM Outputs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 149

PWM Nonoverlapping Output Pair Delays . . . . . . . . . . . . . . . . . . . . . . . . . . . . 150

Multi-PWM Power-Trip Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 152

Multi-PWM Control Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 153

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Real-Time Clock . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 159

Real-Time Clock Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 159

Real-Time Clock Alarm . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 160

Real-Time Clock Oscillator and Source Selection . . . . . . . . . . . . . . . . . . . . . . . 160

Real-Time Clock Battery Backup . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 160

Real-Time Clock Recommended Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . 160

Real-Time Clock Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 161

Universal Asynchronous

Receiver/Transmitter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 175

UART Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 176

UART Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 176

UART Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 178

UART Recommended Usage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 179

Baud Rate Generator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 181

BRG Control Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 182

UART Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 183

Infrared Encoder/Decoder . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 197

Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 197

Transmit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 198

Receive . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 198

Jitter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 200

Infrared Encoder/Decoder Signal Pins . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 200

Loopback Testing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 200

Serial Peripheral Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 203

SPI Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 204

SPI Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 206

SPI Flags . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 206

SPI Baud Rate Generator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 207

Data Transfer Procedure with SPI Configured as a Master . . . . . . . . . . . . . . . 207

Data Transfer Procedure with SPI Configured as a Slave . . . . . . . . . . . . . . . . 208

SPI Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 208

I2C Serial I/O Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 213

I2C General Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 213

Transferring Data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 215

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Clock Synchronization . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 216

Operating Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 218

I2C Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 225

Zilog Debug Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 235

Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 235

ZDI-Supported Protocol . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 236

ZDI Clock and Data Conventions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 237

ZDI Start Condition . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 237

ZDI Register Addressing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 239

ZDI Write Operations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 240

ZDI Read Operations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 241

Operation of the eZ80F91 Device during ZDI Break Points . . . . . . . . . . . . . . . 242

Bus Requests During ZDI Debug Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 242

ZDI Write Only Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 243

ZDI Read Only Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 244

ZDI Register Definitions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 245

On-Chip Instrumentation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 261

Introduction to On-Chip Instrumentation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 261

OCI Activation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 262

OCI Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 262

JTAG Boundary Scan . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 263

Phase-Locked Loop . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 269

Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 269

PLL Normal Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 271

Power Requirement to the Phase-Locked Loop Function . . . . . . . . . . . . . . . . . 272

PLL Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 272

PLL Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 276

eZ80® CPU Instruction Set . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 279

Opcode Map . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 284

Ethernet Media Access Controller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 291

EMAC Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 292

EMAC Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 296

EMAC Shared Memory Organization . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 296

EMAC and the System Clock . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 300

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EMAC Operation in HALT Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 301

EMAC Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 301

EMAC Interpacket Gap . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 309

On-Chip Oscillators . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 339

Primary Crystal Oscillator Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 339

32 kHz Real-Time Clock Crystal Oscillator Operation . . . . . . . . . . . . . . . . . . . 341

Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 343

Absolute Maximum Ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 343

DC Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 344

POR and VBO Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 345

Flash Memory Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 345

Current Consumption Under Various Operating Conditions . . . . . . . . . . . . . . . 345

AC Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 348

External Memory Read Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 350

External Memory Write Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 351

External I/O Read Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 353

External I/O Write Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 354

Wait State Timing for Read Operations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 356

Wait State Timing for Write Operations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 357

General Purpose Input/Output Port Input Sample Timing . . . . . . . . . . . . . . . . . 358

General Purpose I/O Port Output Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 358

External Bus Acknowledge Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 359

Packaging . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 361

Ordering Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 363

Part Number Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 363

Index . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 365

Customer Support . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 379

PS027001-0707 Architectural Overview

eZ80F91 ASSP

Product Specification

Architectural Overview

Zilog’s eZ80F91 device is a member of Zilog’s family of eZ80AcclaimPlus!™ Flash

ASSPs. The eZ80F91 is an high-speed ASSP with a maximum clock speed of 50 MHz

and single-cycle instruction fetch. It operates in Z80®-compatible addressing mode (64

KB) or full 24 -bit addressing mode (16 MB). The rich peripheral set of the eZ80F91

makes it suitable for a variety of applications, including industrial control, embedded

communication, and po int-of-sale terminals.

Features

eZ80F91 device includes the following features :

•

Single-cycle instruction fetch, high-performance, pipelined eZ80® CPU core

(referred as The CPU in this document)

•

10/100 BaseT ethernet media access controller with Media-Independent

Interface (MII)

•

256 KB Flash memory

•

16 KB SRAM (8 KB user and 8 KB Ethernet)

•

Low-power features including SLEEP mode, HALT mode, and selective peripheral

power-down control

•

Two Universal Asynchronous Receiver/Transmitter (UART) with independent Baud

Rate Generators (BRG)

•

Serial Peripheral Interface (SPI) with independent clock ra te generator

•

I2C with independent clock rate generator

•

IrDA-compliant infrared encoder/decoder

•

Glueless external peripheral interface with 4 Chip Selects, individual Wait State

generators, an external WAIT input pin—supports Z80-, Intel-, and Motorola-style

buses

•

Fixed-priority vectored interrupts (both internal and external) and interrupt controller

•

Real-time clock with separate VDD pin for battery backup and selectable on-chi p

32 kHz oscillator or external 50/60 Hz input

•

Four 16-bit Counter/Timers with prescalers and direct input/output drive

•

Watchdog Timer with internal oscillator clocking option

•

32 bits of General Purpose Input/Output (GPIO)

•

On-Chip Instrumentation (OCI™) and Zilog Debug Interfaces (ZDI)

PS027001-0707 Architectural Overview

eZ80F91 ASSP

Product Specification

•

IEEE 1149.1-compatible JTAG

•

144-pin LQFP and BGA packages

•

3.0–3.6 V supply voltage with 5 V tolerant inputs

•

Operating Temperature Range:

–Standard: 0 ºC to +70 ºC

–Extended: –40 ºC to +105 ºC

All signals with an overline are active Low. For example, the signal DCD1 is active when

it is a logical 0 (Low) state.

Power connections follow these conventional descriptions:

Block Diagram

Figure 1 on page 3 illustrates a block diagram of the eZ80F91 ASSP.

Connection Circuit Device

Power VCC VDD

Ground GND VSS

Note:

PS027001-0707 Architectural Overview

eZ80F91 ASSP

Product Specification

Figure 1. eZ80F91 Block Diagram

Ethernet

MAC

256KB

Flash

Memory

IrDA

Encoder/

Decoder

GPIO

8-Bit General-

Purpose

I/O Port

(4)

Crystal

Oscillator

PLL, and

System Clock

Generator

Programmable

Reload

Timer/Counter

(4)

WDT

Watch-Dog

Timer

Internal

Osc.

WAIT

NMI

BUSACK

BUSREQ

INSTRD

IORQ

MREQ

HALT_SLP

JTAG/ZDI Signals (5)

CS0

CS1

CS2

CS3

DATA[7:0]

ADDR[23:0]

RESET

POR/VBO

8KB

SRAM Interrupt

Controller

Interrupt

Vector

(8:0)

eZ80

CPU

Bus

Controller

JTAG/ZDI

Debug

Interface

Real-Time

Clock and

32 KHz

Oscillator

SPI

Serial

Parallel

Interface

Chip Select

and

Wait State

Generator

UART

Universal

Asynchronous

Receiver/

Transmitter

(2)

I C

Serial

Interface

MII Interface

Signals (18)

Arbiter 8KB

SRAM

DATA[7:0]

ADDR[23:0]

RTC_V

SCL

SDA

SCK

MISO

MOSI

CTS0/1

DSR0/1

DCD0/1

DTR0/1

RI0/1

RTS0/1

RxD0/1

TxD0/1

RTC_X

OUT

TxD0/1

PA[7:0]

PB[7:0]

PC[7:0]

PD[7:0]

PHI

PLL_V

LOOP_FILT

IC0/1/2/3

EC0/1

TOUT0/2

OC0/1/2/3

PWM0/1/2/3

PS027001-0707 Architectural Overview

eZ80F91 ASSP

Product Specification

Pin Description

Table 1 lists the pin configuration of the eZ80F91 device in the 144-ball BGA package.

Table 1. eZ80F91 144-Ball BGA Pin Configuration

12 11 10 9 8 7 6 5 4 3 2 1

ASDA SCL PA0 PA4 PA7 COL TxD0 VDD Rx_DV MDC WPn A0

BVSS PHI PA1 PA3 VDD TxD3 Tx_EN VSS RxD1 MDIO A2 A1

CPB6 PB7 VDD PA5 VSS TxD2 Tx_CLK Rx_

CLK RxD3 A3 VSS VDD

DPB1 PB3 PB5 VSS CRS TxD1 Rx_ER RxD2 A4 A8 A6 A7

EPC7 VDD PB0 PB4 PA2 Tx_ER RxD0 A5 A11 VSS VDD A10

FPC3 PC4 PC5 VSS PB2 PA6 A9 A17 A15 A14 A13 A12

GVSS PC0 PC1 PC2 PC6 PLL_

VSS

VSS A23 A20 VSS VDD A16

HXOUT XIN PLL_

VDD

VDD PD7 TMS VSS D5 VSS A21 A19 A18

JVSS VDD LOOP

FILT_

OUT

PD4 TRIGOUT RTC_

VDD

NMIn WRn D2 CS0n VDD A22

KPD5 PD6 PD3 TDI VSS VDD RESETn RDn VDD D1 CS2n CS1n

LPD1 PD2 TRST

nTCK RTC_

XOUT BUSACKn WAITn MREQn D6 D4 D0 CS3n

MPD0 VSS TDO HALT

SLPn

RTC_

XIN BUSREQn INSTRDn IORQn D7 D3 VSS VDD

Note: Lowercase n suffix indicates an active-low signal in this table only

PS027001-0707 Architectural Overview

eZ80F91 ASSP

Product Specification

Figure 2 illustrates the pin layout of the eZ80F91 device in the 144-pin LQFP package.

Figure 2. 144-Pin LQFP Configuration of the eZ80F91

PB7/MOSI

PB6/MISO

PB5/IC3

PB4/IC2

PB3/SCK

PB2/SS

PB1/IC1

PB0/IC0/EC0

PC7/RI1

PC6/DCD1

PC5/DSR1

PC4/DTR1

PC3/CTS1

PC2/RTS1

PC1/RxD1

PC0/TxD1

PLL_V

MDIO

MDC

RxD3

RxD2

RxD1

RxD0

Rx_DV

Rx_CLK

Rx_ER

Tx_ER

Tx_EN

TxD0

TxD1

TxD2

COL

CRS

PA7/PWM3

PA6/PWM2/EC1

A10

A11

A12

A13

A14

A15

A16

A17

A18

IORQ

MREQ

INSTRD

WAIT

RESET

NMI

BUSREQ

BUSACK

RTC_

144-Pin LQFP

108

100

120

130

140

144

A19

A20

A21

A22

A23

CS0

CS1

CS2

CS3

RTC_X

OUT

RTC_

HALT_SLP

TMS

TCK

TRIGOUT

TDI

TDO

TRST

OUT

PLL_V

LOOP_FILT

PD7/RI0

PD6/DCD0

PD5/DSR0

PD4/DTR0

PD3/CTS0

PD0/TxD0/IR_TxD

PA5/PWM1/TOUT2

PA4/PWM0/TOUT0

PA3/PWM3/OC3

PA2/PWM2/OC2

PA1/PWM1/OC1

PA0/PWM0/OC0

PHI

SCL

SDA

110

PD2/RTS0

PD1/RxD0/IR_RxD

TxD3

Tx_CLK

PS027001-0707 Architectural Overview

eZ80F91 ASSP

Product Specification

Pin Characteristics

Table 2 describes the pins and functions of the eZ80F91 144-pin LQFP package and 144-

ball BGA packag e.

Table 2. Pin Identification on the eZ80F91 Device

LQFP

Pin No BGA

Pin No Symbol Function Signal Direction Description

1 A1 ADDR0 Address Bus Bidirectional Configured as an output in normal

operation. The address bus selects

a location in memory or I/O space to

be read or written. Configured as an

input during bus ac kno wle d ge

cycles. Drives the Chip Select/Wait

State Generator block to generate

Chip Selects.

2 B1 ADDR1 Address Bus Bidirectional

3 B2 ADDR2 Address Bus Bidirectional

4 C3 ADDR3 Address Bus Bidirectional

5 D4 ADDR4 Address Bus Bidirectional

6C1V

DD Power Supply Power Supply.

7C2V

SS Ground Ground.

8 E5 ADDR5 Address Bus Bidirectional Configured as an output in normal

operation. The address bus selects

a location in memory or I/O space to

be read or written. Configured as an

input during bus ac kno wle d ge

cycles. Drives the Chip Select/Wait

State Generator block to generate

Chip Selects.

9 D2 ADDR6 Address Bus Bidirectional

10 D1 ADDR7 Address Bus Bidirectional

11 D3 ADDR8 Address Bus Bidirectional

12 F6 ADDR9 Address Bus Bidirectional

13 E1 ADDR10 Address Bus Bidirectional

14 E2 VDD Power Supply Power Supply.

15 E3 VSS Ground Ground.

16 E4 ADDR11 Address Bus Bidirectional Configured as an output in normal

operation. The address bus selects

a location in memory or I/O space to

be read or written. Configured as an

input during bus ac kno wle d ge

cycles. Drives the Chip Select/Wait

State Generator block to generate

Chip Selects.

PS027001-0707 Architectural Overview

eZ80F91 ASSP

Product Specification

17 F1 ADDR12 Address Bus Bidirectional Configured as an output in normal

operation. The address bus selects

a location in memory or I/O space to

be read or written. Configured as an

input during bus ac kno wle d ge

cycles. Drives the Chip Select/Wait

State Generator block to generate

Chip Selects.

18 F2 ADDR13 Address Bus Bidirectional

19 F3 ADDR14 Address Bus Bidirectional

20 F4 ADDR15 Address Bus Bidirectional

21 G1 ADDR16 Address Bus Bidirectional

22 G2 VDD Power Supply Power Supply.

23 G3 VSS Ground Ground.

24 F5 ADDR17 Address Bus Bidirectional Configured as an output in normal

operation. The address bus selects

a location in memory or I/O space to

be read or written. Configured as an

input during bus ac kno wle d ge

cycles. Drives the Chip Select/Wait

State Generator block to generate

Chip Selects.

25 H1 ADDR18 Address Bus Bidirectional

26 H2 ADDR19 Address Bus Bidirectional

27 G4 ADDR20 Address Bus Bidirectional

28 H3 ADDR21 Address Bus Bidirectional

29 J1 ADDR22 Address Bus Bidirectional

30 G5 ADDR23 Address Bus Bidirectional

31 J2 VDD Power Supply Power Supply.

32 H4 VSS Ground Ground.

33 J3 CS0 Chip Select 0 Output, Active

Low CS0 Low indicates that an access is

occurring in the defined CS0

memory or I/O address space.

34 K1 CS1 Chip Select 1 Output, Active

Low CS1 Low indicates that an access is

occurring in the defined CS1

memory or I/O address space.

35 K2 CS2 Chip Select 2 Output, Active

Low CS2 Low indicates that an access is

occurring in the defined CS2

memory or I/O address space.

36 L1 CS3 Chip Select 3 Output, Active

Low CS3 Low indicates that an access is

occurring in the defined CS3

memory or I/O address space.

37 M1 VDD Power Supply Power Supply.

38 M2 VSS Ground Ground.

Table 2. Pin Identification on the eZ80F91 Device (Continued)

LQFP

Pin No BGA

Pin No Symbol Function Signal Direction Description

PS027001-0707 Architectural Overview

eZ80F91 ASSP

Product Specification

39 L2 DATA0 Data Bus Bidirectional The data bus transfers data to and

from I/O and memory devices. The

eZ80F91 drives these lines only

during Write cycles when the

eZ80F91 is the bus master.

40 K3 DAT A1 Data Bus Bidirectional

41 J4 DAT A 2 Data Bus Bidirectional

42 M3 DATA3 Data Bus Bidirectional

43 L3 DATA4 Data Bus Bidirectional

44 H5 DATA5 Data Bus Bidirectional

45 L4 DATA6 Data Bus Bidirectional

46 M4 DATA7 Data Bus Bidirectional

47 K4 VDD Power Supply Power Supply.

48 G6 VSS Ground Ground.

49 M5 IORQ Input/Output

Request Bidirectional,

Active Low IORQ indicates that the CPU is

accessing a location in I/O space.

RD and WR indicate the type of

access. The eZ80F91 device does

not drive this line during RESET. It is

an input during bus acknowledge

cycles.

50 L5 MREQ Memory

Request Bidirectional,

Active Low MREQ Low indicates that the CPU

is accessing a location in memory.

The RD, WR, and INSTRD signals

indicate the type of access. The

eZ80F91 device does not drive this

line during RESET. It is an input

during bus acknowledge cycles.

51 K5 RD Read Output,

Active Low RD Low indicates that the eZ80F91

device is reading from the current

address location. This pin is in a

high-impedance state during bus

acknowledge cycles.

52 J5 WR Write Output, Active

Low WR indicates that the CPU is writing

to the current addre ss l ocation. This

pin is in a high-impedance state

during bus acknowledge cycles.

Table 2. Pin Identification on the eZ80F91 Device (Continued)

LQFP

Pin No BGA

Pin No Symbol Function Signal Direction Description

PS027001-0707 Architectural Overview

eZ80F91 ASSP

Product Specification

53 M6 INSTRD Instruction

Read Indicator Output, Active

Low INSTRD (with MREQ and RD)

indicates the eZ8 0F 9 1 de vice is

fetching an instruction from memory.

This pin is in a high-impedance state

during bus acknowledge cycles.

54 L6 WAIT WAIT Request Schmitt-trigger

input, Active Low Driving the WAIT pin Low forces the

CPU to wait additional clock cycles

for an external peripheral or external

memory to complete its Read or

Write operation.

55 K6 RESET Reset Bidirectional,

Active Low

Schmitt-trigger

input or open

drain outp ut

This signal is used to initialize the

eZ80F91, and/or allow the ez80F91

to signal when it resets. See reset

section for the timing details. This

Schmitt-trigger input allows for RC

rise times.

56 J6 NMI Nonmaskable

Interrupt Schmitt-trigger

input, Active Low,

edge-triggered

interrupt

The NMI input is a higher priority

input than the maskable interrupts. It

is always recognized at th e end of

an instruction, regardless of the

state of the inter ru pt enable con tr ol

bits. This input includes a Schmitt-

trigger to allow for RC rise times.

57 M7 BUSREQ Bus Request Schmitt-trigger

input, Active Low External devices request the

eZ80F91 device to release the

memory interface bus for their use

by driving this pin Low.

58 L7 BUSACK Bus

Acknowledge Output, Active

Low The eZ80F91 device responds to a

Low on BUSREQ making the

address, data, and control signals

high impedance, and by driving the

BUSACK line Low. During bus

acknowledge cycles ADDR[23:0],

IORQ, and MREQ are inputs.

59 K7 VDD Power Supply Power Supply.

60 H6 VSS Ground Ground.

Table 2. Pin Identification on the eZ80F91 Device (Continued)

LQFP

Pin No BGA

Pin No Symbol Function Signal Direction Description

PS027001-0707 Architectural Overview

eZ80F91 ASSP

Product Specification

61 M8 RTC_XIN Real-Time

Clock Crystal

Input

Input This pin is the input to the low-po wer

32 kHz crystal oscillator for the

Real-time clock. If the Real-time

clock is disabled or not used, this

input must be left floating or tied to

VSS to minimize any input current

leakage.

62 L8 RTC_XOUT Real-Time

Clock Crystal

Output

Bidirectional This pin is the output from the low-

power 32 kHz crystal oscillator for

the Real-Time Clock. This pin is an

input when the RTC is configured to

operate from 50/60 Hz input clock

signals and the 32 kHz crystal

oscillator is disabled.

63 J7 RTC_VDD Real-Time

Clock Power

Supply

Power supply for the Real-Time

Clock and associated 32 kHz

oscillator. Isolated from the power

supply to the remainder of the chip.

A battery is connec te d to this pin to

supply constant power to the Real-

Time Clock and 32 kHz oscillator. If

the Real-time clock is disabled or

not used this output must be tied to

Vdd.

64 K8 VSS Ground Ground.

65 M9 HALT_SL P HALT and

SLEEP

Indicator

Output, Active

Low A Low on this pin indicates that the

CPU has entered either HALT or

SLEEP mode because of execution

of either a HALT or SLP instruction.

66 H7 TMS JTAG Test

Mode Select Input JTAG Mode Select Input.

67 L9 TCK JTAG Test

Clock Input JTAG and ZDI clock input.

68 J8 TRIGOUT JTAG Test

Trigger Output Output Active High trigger event indicator.

69 K9 TDI JTAG Test

Data In Bidirectional JTAG data input pin. Functions as

ZDI data I/O pin when JTAG is

disabled. This pin has an internal

pull-up resistor in the pad.

Table 2. Pin Identification on the eZ80F91 Device (Continued)

LQFP

Pin No BGA

Pin No Symbol Function Signal Direction Description

PS027001-0707 Architectural Overview

eZ80F91 ASSP

Product Specification

70 M10 TDO JTAG Test

Data Out Output JTAG data output pin.

71 L10 TRST JTAG Reset Schmitt-trigger

input, Active Low JTAG reset input pin.

72 M11 VSS Ground Ground.

73 M12 PD0 GPIO Port D Bidirectional This pin is used for GPIO. It is

individually programmed as input or

output and is also used individually

as an interrupt input. Each Port D

pin, when programmed a s output is

selected to be an open-drain or

open-source outp ut. Port D is

multiplexed with one UART.

TxD0 UART

Transmit Data Output This pin is used by the UART to

transmit asynchronous serial data.

This signal is multiplexed with PD0.

IR_TxD IrDA Transmit

Data Output This pin is used by the IrDA

encoder/decoder to transmit serial

data. This signal is multiplexed with

PD0.

74 L12 PD1 GPIO Port D Bidirectional This pin is used for GPIO. It is

individually programmed as input or

output and is also used individually

as an interrupt input. Each Port D

pin, when programmed a s output is

selected to be an open-drain or

open-source outp ut. Port D is

multiplexed with one UART.

RxD0 Receive Data Input This pin is used by the UART to

receive asynchronous serial data.

This signal is multiplexed with PD1.

IR_RxD IrDA Receive

Data Input This pin is used by the IrDA

encoder/decoder to receive serial

data. This signal is multiplexed with

PD1.

Table 2. Pin Identification on the eZ80F91 Device (Continued)

LQFP

Pin No BGA

Pin No Symbol Function Signal Direction Description

PS027001-0707 Architectural Overview

eZ80F91 ASSP

Product Specification

75 L11 PD2 GPIO Port D Bidirectional This pin is used for GPIO. It is

individually programmed as input or

output and is also used individually

as an interrupt input. Each Port D

pin, when programmed a s output is

selected to be an open-drain or

open-source outp ut. Port D is

multiplexed with one UART.

RTS0 Request to

Send Output,

Active Low Modem control signal from UART.

This signal is multiplexed with PD2.

76 K10 PD3 GPIO Port D Bidirectional This pin is used for GPIO. It is

individually programmed as input or

output and is also used individually

as an interrupt input. Each Port D

pin, when programmed a s output is

selected to be an open-drain or

open-source outp ut. Port D is

multiplexed with one UART.

CTS0 Clear to Send Input, Active Low Modem status signal to the UART.

This signal is multiplexed with PD3.

77 J9 PD4 GPIO Port D Bidirectional This pin is used for GPIO. It is

individually programmed as input or

output and is also used individually

as an interrupt input. Each Port D

pin, when programmed a s output is

selected to be an open-drain or

open-source outp ut. Port D is

multiplexed with one UART.

DTR0 Data Terminal

Ready Output,

Active Low Modem control signal to the UART.

This signal is multiplexed with PD4.

Table 2. Pin Identification on the eZ80F91 Device (Continued)

LQFP

Pin No BGA

Pin No Symbol Function Signal Direction Description

PS027001-0707 Architectural Overview

eZ80F91 ASSP

Product Specification

78 K12 PD5 GPIO Port D Bidirectional This pin is used for GPIO. It is

individually programmed as input or

output and is also used individually

as an interrupt input. Each Port D

pin, when programmed a s output is

selected to be an open-drain or

open-source outp ut. Port D is

multiplexed with one UART.

DSR0 Data Set

Ready Input, Active Low Modem status signal to the UART.

This signal is multiplexed with PD5.

79 K11 PD6 GPIO Port D Bidirectional This pin is used for GPIO. It is

individually programmed as input or

output and is also used individually

as an interrupt input. Each Port D

pin, when programmed a s output is

selected to be an open-drain or

open-source outp ut. Port D is

multiplexed with one UART.

DCD0 Data Carrier

Detect Input, Active Low Modem status signal to the UART.

This signal is multiplexed with PD6.

80 H8 PD7 GPIO Port D Bidirectional This pin is used for GPIO. It is

individually programmed as input or

output and is also used individually

as an interrupt input. Each Port D

pin, when programmed a s output is

selected to be an open-drain or

open-source outp ut. Port D is

multiplexed with one UART.

RI0 Ring Indicator Input, Active Low Modem status signal to the UART.

This signal is multiplexed with PD7.

81 J11 VDD Power Supply Power Supply.

82 J12 VSS Ground Ground.

83 J10 LOOP_FILT PLL Loop Filter Analog Loop Filter pin for the Analog PLL.

84 G7 PLL_VSS Ground Ground for Analog PLL.

85 H12 XOUT System Clock

Oscillator

Output

Output This pin is th e output of the o nboard

crystal oscillator. When used, a

crystal must be connected betwee n

XIN and XOUT.

Table 2. Pin Identification on the eZ80F91 Device (Continued)

LQFP

Pin No BGA

Pin No Symbol Function Signal Direction Description

PS027001-0707 Architectural Overview

eZ80F91 ASSP

Product Specification

86 H11 XIN System Clock

Oscillator Input Input This pin is the input to the onboard

crystal oscillator for the primary

system clock. If an external

oscillator is used, its clock output

must be connected to this pin. When

a crystal is used, it must be

connected between XIN and XOUT.

87 H10 PLL_VDD Power Supply Power Supply for Analog PLL.

88 H9 VDD Power Supply Power Supply.

89 G12 VSS Ground Ground.

90 G11 PC0 GPIO Port C Bidirectional with

Schmitt-trigger

input

This pin is used for GPIO. It is

individually programmed as input or

output and is also used individually

as an interrupt input. Each Port C

pin, when programmed a s output is

selected to be an open-drain or

open-source outp ut. Port C is

multiplexed with one UART.

TxD1 Transmit Data Output This pin is used by the UART to

transmit asynchronous serial data.

This signal is multiplexed with PC0.

91 G10 PC1 GPIO Port C Bidirectional with

Schmitt-trigger

input

This pin is used for GPIO. It is

individually programmed as input or

output and is also used individually

as an interrupt input. Each Port C

pin, when programmed a s output is

selected to be an open-drain or

open-source outp ut. Port C is

multiplexed with one UART.

RxD1 Receive Data Schmitt-trigger

input This pin is used by the UART to

receive asynchronous serial data.

This signal is multiplexed with PC1.

Table 2. Pin Identification on the eZ80F91 Device (Continued)

LQFP

Pin No BGA

Pin No Symbol Function Signal Direction Description

PS027001-0707 Architectural Overview

eZ80F91 ASSP

Product Specification

92 G9 PC2 GPIO Port C Bidirectional with

Schmitt-trigger

input

This pin is used for GPIO. It is

individually programmed as input or

output and is also used individually

as an interrupt input. Each Port C

pin, when programmed a s output is

selected to be an open-drain or

open-source outp ut. Port C is

multiplexed with one UART.

RTS1 Request to

Send Output, Active

Low Modem control signal from UART.

This signal is multiplexed with PC2.

93 F12 PC3 GPIO Port C Bidirectional with

Schmitt-trigger

input

This pin is used for GPIO. It is

individually programmed as input or

output and is also used individually

as an interrupt input. Each Port C

pin, when programmed a s output is

selected to be an open-drain or

open-source outp ut. Port C is

multiplexed with one UART.

CTS1 C lea r to Send Schmitt-trig ge r

input, Active Low Modem status signal to the UART.

This signal is multiplexed with PC3.

94 F11 PC4 GPIO Port C Bidirectional with

Schmitt-trigger

input

This pin is used for GPIO. It is

individually programmed as input or

output and is also used individually

as an interrupt input. Each Port C

pin, when programmed a s output is

selected to be an open-drain or

open-source outp ut. Port C is

multiplexed with one UART.

DTR1 Data Terminal

Ready Output, Active

Low Modem control signal to the UART.

This signal is multiplexed with PC4.

Table 2. Pin Identification on the eZ80F91 Device (Continued)

LQFP

Pin No BGA

Pin No Symbol Function Signal Direction Description

PS027001-0707 Architectural Overview

eZ80F91 ASSP

Product Specification

95 F10 PC5 GPIO Port C Bidirectional with

Schmitt-trigger

input

This pin is used for GPIO. It is

individually programmed as input or

output and is also used individually

as an interrupt input. Each Port C

pin, when programmed a s output is

selected to be an open-drain or

open-source outp ut. Port C is

multiplexed with one UART.

DSR1 Data Set

Ready Schmitt-trigger

input, Active Low Modem status signal to the UART.

This signal is multiplexed with PC5.

96 G8 PC6 GPIO Port C Bidirectional with

Schmitt-trigger

input

This pin is used for GPIO. It is

individually programmed as input or

output and is also used individually

as an interrupt input. Each Port C

pin, when programmed a s output is

selected to be an open-drain or

open-source outp ut. Port C is

multiplexed with one UART.

DCD1 Data Carrier

Detect Schmitt-trigger

input, Active Low Modem status signal to the UART.

This signal is multiplexed with PC6.

97 E12 PC7 GPIO Port C Bidirectional with

Schmitt-trigger

input

This pin is used for GPIO. It is

individually programmed as input or

output and is also used individually

as an interrupt input. Each Port C

pin, when programmed a s output is

selected to be an open-drain or

open-source outp ut. Port C is

multiplexed with one UART.

RI1 Ring Indicator Schmitt-trigger

input, Active Low Modem status signal to the UART.

This signal is multiplexed with PC7.

98 E11 VDD Power Supply Power Supply.

99 F9 VSS Ground Ground.

Table 2. Pin Identification on the eZ80F91 Device (Continued)

LQFP

Pin No BGA

Pin No Symbol Function Signal Direction Description

PS027001-0707 Architectural Overview

eZ80F91 ASSP

Product Specification

100 E10 PB0 GPIO Port B Bidirectional with

Schmitt-trigger

input

This pin is used for GPIO. It is

individually programmed as input or

output and is also used individually

as an interrupt input. Each Port B

pin, when programmed a s output is

selected to be an open-drain or

open-source output.

IC0 Input Capture Schmitt-trigger

input Input Capture A Signal to Timer 1.

This signal is multiplexed with PB0.

EC0 E ve nt Co unte r Schmitt-trigge r

input Event Counter Signal to Timer 1.

This signal is multiplexed with PB0.

101 D12 PB1 GPIO Port B Bidirectional with

Schmitt-trigger

input

This pin is used for GPIO. It is

individually programmed as input or

output and is also used individually

as an interrupt input. Each Port B

pin, when programmed a s output is

selected to be an open-drain or

open-source output.

IC1 Input Capture Schmitt-trigger

input Input Capture B Signal to Timer 1.

This signal is multiplexed with PB1.

102 F8 PB2 GPIO Port B Bid irectional with

Schmitt-trigger

input

This pin is used for GPIO. It is

individually programmed as input or

output and is also used individually

as an interrupt input. Each Port B

pin, when programmed a s output is

selected to be an open-drain or

open-source output.

SS SPI Slave

Select Schmitt-trigger

input, Active Low Th e slave select input line is used to

select a slave device in SPI mode.

This signal is multiplexed with PB2.

Table 2. Pin Identification on the eZ80F91 Device (Continued)

LQFP

Pin No BGA

Pin No Symbol Function Signal Direction Description

PS027001-0707 Architectural Overview

eZ80F91 ASSP

Product Specification

103 D11 PB3 GPIO Port B Bidirectional with

Schmitt-trigger

input

This pin is used for GPIO. It is

individually programmed as input or

output and is also used individually

as an interrupt input. Each Port B

pin, when programmed a s output is

selected to be an open-drain or

open-source output.

SCK SPI Serial

Clock Bidirectional with

Schmitt-trigger

input

SPI serial clock. This signal is

multiplexed with PB3.

104 E9 PB4 GPIO Port B Bidirectional with

Schmitt-trigger

input

This pin is used for GPIO. It is

individually programmed as input or

output and is also used individually

as an interrupt input. Each Port B

pin, when programmed a s output is

selected to be an open-drain or

open-source output.

IC2 Input Capture Schmitt-trigger

input Input Capture A Signal to Timer 3.

This signal is multiplexed with PB4.

105 D10 PB5 GPIO Port B Bidirectional with

Schmitt-trigger

input

This pin is used for GPIO. It is

individually programmed as input or

output and is also used individually

as an interrupt input. Each Port B

pin, when programmed a s output is

selected to be an open-drain or

open-source output.

IC3 Input Capture Schmitt-trigger

input Input Capture B Signal to Timer 3.

This signal is multiplexed with PB5.

Table 2. Pin Identification on the eZ80F91 Device (Continued)

LQFP

Pin No BGA

Pin No Symbol Function Signal Direction Description

PS027001-0707 Architectural Overview

eZ80F91 ASSP

Product Specification

106 C12 PB6 GPIO Port B Bidirectional with

Schmitt-trigger

input

This pin is be used for GPIO. It is

individually programmed as input or

output and is also used individually

as an interrupt input. Each Port B

pin, when programmed a s output is

selected to be an open-drain or

open-source output.

MISO SPI Master-In/

Slave-Out Bidirectional with

Schmitt-trigger

input

The MISO line is configured as an

input when the eZ80F91 device is

an SPI master device an d as an

output when eZ80F91 is an SPI

slave device. This signal is

multiplexed with PB6.

107 C11 PB7 GPIO Port B Bidirectional with

Schmitt-trigger

input

This pin is used for GPIO. It is

individually programmed as input or

output and is also used individually

as an interrupt input. Each Port B

pin, when programmed a s output is

selected to be an open-drain or

open-source output.

MOSI SPI Master Out

Slave In Bidirectional with

Schmitt-trigger

input

The MOSI line is configured as an

output when the eZ80 F91 device is

an SPI master device an d as an

input when the eZ80F91 device is

an SPI slave device. This signal is

multiplexed with PB7.

108 B12 VSS Ground Ground.

109 A12 SDA I2C Serial Data Bidir ec tio na l T his pin ca rrie s the I 2C data signal.

110 A11 SCL I2C Serial

Clock Bidirectional This pin is used to receive and

transmit the I2C clock.

111 B11 PHI System Clock Output This pin is an output driven by the

internal system clock. It is used by

the system for synchronization with

the eZ80F91 device.

112 C10 VDD Power Supply Power Supply.

113 D9 VSS Ground Ground.

Table 2. Pin Identification on the eZ80F91 Device (Continued)

LQFP

Pin No BGA

Pin No Symbol Function Signal Direction Description

PS027001-0707 Architectural Overview

eZ80F91 ASSP

Product Specification

114 A10 PA0 GPIO Port A Bidirectional This pin is used for GPIO. It is

individually programmed as input or

output and is also used individually

as an interrupt input. Each Port A

pin, when programmed a s output is

selected to be an open-drain or

open-source output.

PWM0 PWM

Output 0 Output This pin is used by Ti mer 3 for PWM

0. This signal is multiplexed with

PA0.

OC0 Output

Compar e 0 Output This pin is used by Timer 3 for

Output Compare 0. This signal is

multiplexed with PA0.

115 B10 PA1 GPIO Port A Bidirectional This pin is used for GPIO. It is

individually programmed as input or

output and is also used individually

as an interrupt input. Each Port A

pin, when programmed a s output is

selected to be an open-drain or

open-source output.

PWM1 PWM

Output 1 Output This pin is used by Ti mer 3 for PWM

1. This signal is multiplexed with

PA1.

OC1 Output

Compar e 1 Output This pin is used by Timer 3 for

Output Compare 1. This signal is

multiplexed with PA1.

116 E8 PA2 GPIO Port A Bidirectional This pin is used for GPIO. It is

individually programmed as input or

output and is also used individually

as an interrupt input. Each Port A

pin, when programmed a s output is

selected to be an open-drain or

open-source output.

PWM2 PWM

Output 2 Output This pin is used by Ti mer 3 for PWM

2. This signal is multiplexed with

PA2.

OC2 Output

Compar e 2 Output This pin is used by Timer 3 for

Output Compare 2. This signal is

multiplexed with PA2.

Table 2. Pin Identification on the eZ80F91 Device (Continued)

LQFP

Pin No BGA

Pin No Symbol Function Signal Direction Description

PS027001-0707 Architectural Overview

eZ80F91 ASSP

Product Specification

117 B9 PA3 GPIO Port A Bidirectional This pin is used for GPIO. It is

individually programmed as input or

output and is also used individually

as an interrupt input. Each Port A

pin, when programmed a s output is

selected to be an open-drain or

open-source output.

PWM3 PWM Output 3 Output This pin is used by Timer 3 for PWM

3. This signal is multiplexed with

PA3.

OC3 Output

Compar e 3 Output This pin is used by Timer 3 for

Output Comp ar e 3 Th is sig na l is

multiplexed with PA3.

118 A9 PA4 GPIO Port A Bidirectional This pin is used for GPIO. It is

individually programmed as input or

output and is also used individually

as an interrupt input. Each Port A

pin, when programmed a s output is

selected to be an open-drain or

open-source output.

PWM0 PWM Output 0

Inverted Output This pin is used by Timer 3 for

negative PWM 0. This signal is

multiplexed with PA4.

TOUT0 Timer Out Output This pin is use d by Timer 0 timer-out

signal. This signal is multiplexed

with PA4.

119 C9 PA5 GPIO Port A Bidirectional This pin is used for GPIO. It is

individually programmed as input or

output and is also used individually

as an interrupt input. Each Port A

pin, when programmed a s output is

selected to be an open-drain or

open-source output.

PWM1 PWM Output 1

Inverted Output This pin is used by Timer 3 for

negative PWM 1. This signal is

multiplexed with PA5.

TOUT2 Timer Out Output This pin is used by the Timer 2

timer-out signal. This signal is

multiplexed with PA5.

Table 2. Pin Identification on the eZ80F91 Device (Continued)

LQFP

Pin No BGA

Pin No Symbol Function Signal Direction Description

PS027001-0707 Architectural Overview

eZ80F91 ASSP

Product Specification

120 F7 PA6 GPIO Port A Bidirectional This pin is used for GPIO. It is

individually programmed as input or

output and is also used individually

as an interrupt input. Each Port A

pin, when programmed a s output is

selected to be an open-drain or

open-source output.

PWM2 PWM Output 2

Inverted Output This pin is used by Timer 3 for

negative PWM 2. This signal is

multiplexed with PA6.

EC1 Event Counter Input Event Counter Signal to Timer 2.

This signal is multiplexed with PA6.

121 A8 PA7 GPIO Port A Bidirectional This pin is used for GPIO. It is

individually programmed as input or

output and is also used individually

as an interrupt input. Each Port A

pin, when programmed a s output is

selected to be an open-drain or

open-source output.

PWM3 PWM Output 3

Inverted Output This pin is used by Timer 3 for

negative PWM 3. This signal is

multiplexed with PA7.

122 B8 VDD Power Supply Power Supply.

123 C8 VSS Ground Ground.

124 D8 CRS MII Carrier

Sense Input This pin is used by the EMAC for the

MII Interface to the PHY (physical

layer). Carrier Sense is an

asynchronous signal.

125 A7 COL MII Collision

Detect Input This pi n is used by the EMAC for the

MII Interface to the PHY. Collision

Detect is an asynchronous signal.

126 B7 TxD3 MII Transmit

Data Output This pin is used by the EMAC for the

MII Interface to the PHY. Transmit

Data is synchronous to the rising-

edge of Tx_CLK.

Table 2. Pin Identification on the eZ80F91 Device (Continued)

LQFP

Pin No BGA

Pin No Symbol Function Signal Direction Description

PS027001-0707 Architectural Overview

eZ80F91 ASSP

Product Specification

127 C7 TxD2 MII Transmit

Data Output This pin is used by the Ethernet

MAC for the MII Interface to the

PHY. Transmit Data is synchronous

to the rising-edge of Tx_CLK.

128 D7 TxD1 MII Transmit

Data Output This pin is used by the Ethernet

MAC for the MII Interface to the

PHY. Transmit Data is synchronous

to the rising-edge of Tx_CLK.

129 A6 TxD0 MII Transmit

Data Output This pin is used by the Ethernet

MAC for the MII Interface to the

PHY. Transmit Data is synchronous

to the rising-edge of Tx_CLK.

130 B6 Tx_EN MII Transmit

Enable Output This pin is used by the Ethernet

MAC for the MII Interface to the

PHY. Transmit Enable is

synchronous to the rising-edge of

Tx_CLK.

131 C6 Tx_CLK MII Transmit

Clock Input This pin is used by the Ethernet

MAC for the MII Interface to the

PHY. Transmit Clock is the Nibble or

Symbol Clock prov ide d by the MII

PHY interface.

132 E7 Tx_ER MII Transmit

Error Output This pin is used by the Ethernet

MAC for the MII Interface to the

PHY. Transmit Error is synchronous

to the rising-edge of Tx_CLK.

133 A5 VDD Power Supply Power Supply.

134 B5 VSS Ground Ground.

135 D6 Rx_ER MII Receive

Error Input This pin is used by the Ethernet

MAC for the MII Interface to the

PHY. Receive Error is provided by

the MII PHY interface synchronous

to the rising-edge of Rx_CLK.

136 C5 Rx_CLK MII Receive

Clock Input This pin is used by the Ethernet

MAC for the MII Interface to the

PHY. Receive Clock is the Nibble or

Symbol Clock prov ide d by the MII

PHY interface.

Table 2. Pin Identification on the eZ80F91 Device (Continued)

LQFP

Pin No BGA

Pin No Symbol Function Signal Direction Description

PS027001-0707 Architectural Overview

eZ80F91 ASSP

Product Specification

137 A4 Rx_DV MII Receive

Data Valid Input This pin is used by the Ethernet

MAC for the MII Interface to the

PHY. Receive Data Valid is provided

by the MII PHY interface

synchronous to the rising-edge of

Rx_CLK.

138 E6 RxD0 MII Receive

Data Input This pin is used by the Ethernet

MAC for the MII Interface to the

PHY. Receive Data is provided by

the MII PHY interface synchronous

to the rising-edge of Rx_CLK.

139 B4 RxD1 MII Receive

Data Input This pin is used by the Ethernet

MAC for the MII Interface to the

PHY. Receive Data is provided by

the MII PHY interface synchronous

to the rising-edge of Rx_CLK.

140 D5 RxD2 MII Receive

Data Input This pin is used by the Ethernet

MAC for the MII Interface to the

PHY. Receive Data is provided by

the MII PHY interface synchronous

to the rising-edge of Rx_CLK.

141 C4 RxD3 MII Receive

Data Input This pin is used by the Ethernet

MAC for the MII Interface to the

PHY. Receive Data is provided by

the MII PHY interface synchronous

to the rising-edge of Rx_CLK.

142 A3 MDC MII

Management

Data Clock

Output This pin is used by the Ethernet

MAC for the MII Management

Interface to th e PHY. T he Ethe rn et

MAC provides the MII Management

Data Clock to the MII PHY interface.

Table 2. Pin Identification on the eZ80F91 Device (Continued)

LQFP

Pin No BGA

Pin No Symbol Function Signal Direction Description

PS027001-0707 Architectural Overview

eZ80F91 ASSP

Product Specification

System Clock Source Options

The following section describes the syst em clock source option s .

System Clock— The eZ80F91 device’s internal clock, SCLK, is responsible for clocking

all internal logic. The SCLK source can be an external crystal oscillator, an internal PLL,

or an internal 32 kHz RTC oscillator. The SCLK source is selected by PLL Control Regis-

ter 0. RESET default is provided by the external crystal oscillator. For more details on

CLK_MUX values in the PLL Control Register 0, see Table 154 on page 273.

PHI—PHI is a device output driven by SCLK that is used for system synchronization to

the eZ80F91 device. PHI is used as the reference clock for all AC chara cteristics, see

page 348.

External Crystal Oscillator—An externally-driven oscillator operates in two modes. In

one mode, the XIN pin is driven by a oscillator from DC up to 50 MHz when the XOUT pin

is not connected. In the other mode, the XIN and XOUT pins are driven by a crystal circuit.

Crystals recommended by Zilog are defined to be a 50 MHz–3 overtone circuit or 1–10

MHz range fundamental for PLL operation. For details, see On-Chip Oscillators on page

339.

Real Time Clock—An internal 32 kHz real-time clock crystal oscillator driven by either

the on-chip 32768 Hz crystal oscillator or a 50/60 Hz power-line frequency input. While

intended for timekeeping, the RTC 32 kHz oscillator is selected as an SCLK. RTC_VDD

and RTC_VSS provides an isolated power supply to ensure RTC operation in the event of

loss of line power when a battery is provided. For more details, see On-Chip Oscillators on

page 339.

143 B3 MDIO MII

Management

Data

Bidirectional This pin is used by the Ethernet

MAC for the MII Management

Interface to th e PHY. T he Ethe rn et

MAC sends and receives the MII

Management Data to and from the

MII PHY interface.

144 A2 WP Write Protect Schmitt-trigger

input, Active Low The Write Protect input is used by

the Flash Controller to protect the

Boot Block from Write and ERASE

operations.

Table 2. Pin Identification on the eZ80F91 Device (Continued)

LQFP

Pin No BGA

Pin No Symbol Function Signal Direction Description

PS027001-0707 Architectural Overview

eZ80F91 ASSP

Product Specification

PLL Clock—The eZ80F91 internal PLL driven by external crystals or external crystal

oscillators in the range of 1 MHz to 10 MHz generates an SCLK up to 50 MHz. For more-

details, see Phase-Locked Loop on page 269.

SCLK Source Selection Example

For additional SCLK source selection examples, refer to Crystal Oscillator Guidelines f or

eZ80 and eZ80Acclaim! Devices Technical Note (TN0013) available on www.zilog.com.

PS027001-0707 Register Map

eZ80F91 ASSP

Product Specification

All on-chip peripheral registers are accessed in the I/O address space. All I/O operations

employ 16-bit addresses. The upper byte of the 24-bit address bus is undefined during all

I/O operations (ADDR[23:16] = XX). All I/O operations using 16-bit addresses within the

0000h–00FFh range are routed to the on-chip peripherals. External I/O chip selects are

not generated if the addr ess space programmed for the I/O chip se lects overlap the

0000h–00FFh address range.

Registers at unused addresses within the 0000h–00FFh range assigned to on-ch ip periph-

erals are not implemented. Read access to such addresses returns unpredictable values and

Write access produces no effect. Table 3 describes the register map for the eZ80F91

device.

Table 3. Register Map

Address

(hex) Mnemonic Name Reset

(hex) CPU

Access Page

Product ID

0000 ZDI_ID_L eZ80 Product ID Low Byte Register 08 R 256

0001 ZDI_ID_H eZ80 Product ID High Byte Register 00 R 256

0002 ZDI_ID_REV eZ80 Product ID Revision Register XX R 256

Interrupt Priority

0010 INT_P0 Interrupt Priority Register—Byte 0 00 R/W 61

0011 INT_P1 Interrupt Priority Register—Byte 1 00 R/W 61

0012 INT_P2 Interrupt Priority Register—Byte 2 00 R/W 61

0013 INT_P3 Interrupt Priority Register—Byte 3 00 R/W 61

0014 INT_P4 Interrupt Priority Register—Byte 4 00 R/W 61

0015 INT_P5 Interrupt Priority Register—Byte 5 00 R/W 61

Ethernet Media Access Controller

0020 EMAC_TEST EMAC Test Register 00 R/W 302

0021 EMAC_CFG1 EMAC Configuration Register 00 R/W 303

0022 EMAC_CFG2 EMAC Configuration Register 37 R/W 305

0023 EMAC_CFG3 EMAC Configuration Register 0F R/W 306

0024 EMAC_CFG4 EMAC Configuration Register 00 R/W 307

PS027001-0707 Register Map

eZ80F91 ASSP

Product Specification

0025 EMAC_STAD_0 EMAC Station Address—Byte 0 00 R/W 307

0026 EMAC_STAD_1 EMAC Station Address—Byte 1 00 R/W 307

0027 EMAC_STAD_2 EMAC Station Address—Byte 2 00 R/W 307

0028 EMAC_STAD_3 EMAC Station Address—Byte 3 00 R/W 307

0029 EMAC_STAD_4 EMAC Station Address—Byte 4 00 R/W 307

002A EMAC_STAD_5 EMAC Station Address—Byte 5 00 R/W 307

002B EMAC_TPTV_L EMAC Transmit Pause

Timer Value—Low Byte 00 R/W 309

002C EMAC_TPTV_H EMAC Transmit Pause

Timer Value—High Byte 00 R/W 309

002D EMAC_IPGT EMAC Inter-Packet Gap 15 R/W 309

002E EMAC_IPGR1 EMAC Non-Back-Back IPG 0C R/W 312

002F EMAC_IPGR2 EMAC Non-Back-Back IPG 12 R/W 312

0030 EMAC_MAXF_L EMAC Maximum Frame

Length—Low Byte 00 R/W 313

0031 EMAC_MAXF_H EMAC Maximum Frame

Length—High Byte 06 R/W 314

0032 EMAC_AFR EMAC Address Filter Register 00 R/W 315

0033 EMAC_HTBL_0 EMAC Hash Table—Byte 0 00 R/W 316

0034 EMAC_HTBL_1 EMAC Hash Table—Byte 1 00 R/W 316

0035 EMAC_HTBL_2 EMAC Hash Table—Byte 2 00 R/W 316

0036 EMAC_HTBL_3 EMAC Hash Table—Byte 3 00 R/W 316

0037 EMAC_HTBL_4 EMAC Hash Table—Byte 4 00 R/W 316

0038 EMAC_HTBL_5 EMAC Hash Table—Byte 5 00 R/W 316

0039 EMAC_HTBL_6 EMAC Hash Table—Byte 6 00 R/W 316

003A EMAC_HTBL_7 EMAC Hash Table—Byte 7 00 R/W 316

003B EMAC_MIIMGT EMAC MII Management Register 00 R/W 317

003C EMAC_CTLD_L EMAC PHY Configuration

Data—Low Byte 00 R/W 318

003D EMAC_CTLD_H EMAC PHY Configuration

Data—High Byte 00 R/W 319

Table 3. Register Map (Continued)

Address

(hex) Mnemonic Name Reset

(hex) CPU

Access Page

PS027001-0707 Register Map

eZ80F91 ASSP

Product Specification

003E EMAC_RGAD EMAC PHY Register Address Register 00 R/W 319

003F EMAC_FIAD EMAC PHY Unit Select Address

0040 EMAC_PTMR EMAC Transmit Polling Timer Register 00 R/W 320

0041 EMAC_RST EMAC Reset Control Register 20 R/W 321

0042 EMAC_TLBP_L EMAC Transmit Lower Boundary

Pointer—Low Byte 00 R/W 322

0043 EMAC_TLBP_H EMAC Transmit Lower Boundary

Pointer—High Byte 00 R/W 322

0044 EMAC_BP_L EMAC Boundary Pointer—Low Byte 00 R/W 323

0045 EMAC_BP_H EMAC Boundary Pointer—High Byte C0 R/W 323

0046 EMAC_BP_U EMAC Boundary Pointer—Upper Byte FF R/W 323

0047 EMAC_RHBP_L EMAC Receive High Boundary

Pointer—Low Byte 00 R/W 324

0048 EMAC_RHBP_H EMAC Receive High Boundary

Pointer—High Byte 00 R/W 325

0049 EMAC_RRP_L EMAC Receive Read

Pointer—Low Byte 00 R/W 325

004A EMAC_RRP_H EMAC Receive Read

Pointer—High Byte 00 R/W 326

004B EMAC_BUFSZ EMAC Buffer Size Register 00 R/W 326

004C EMAC_IEN EMAC Interrupt Enable Register 00 R/W 327

004D EMAC_ISTAT EMAC Interrupt Status Register 00 R/W 329

004E EMAC_PRSD_L EMAC PHY Read Status

Data—Low Byte 00 R/W 330

004F EMAC_PRSD_H EMAC PHY Read Status

Data—High Byte 00 R/W 331

0050 EMAC_MIISTAT EMAC MII Status Register 00 R/W 331

0051 EMAC_RWP_L EMAC Receive Write

Pointer—Low Byte 00 R/W 332

0052 EMAC_RWP_H EMAC Receive Write

Pointer—High Byte 00 R/W 333

Table 3. Register Map (Continued)

Address

(hex) Mnemonic Name Reset

(hex) CPU

Access Page

PS027001-0707 Register Map

eZ80F91 ASSP

Product Specification

Ethernet Media Access Controller, continued

0053 EMAC_TRP_L EMAC Transmit Read

Pointer—Low Byte 00 R/W 333

0054 EMAC_TRP_H EMAC Transmit Read

Pointer—High Byte 00 R/W 334

0055 EMAC_BLKSLFT_L EMAC Receive Blocks Left

0056 EMAC_BLKSLFT_H EMAC Receive Blocks Left

0057 EMAC_FDATA_L EMAC FIFO Data—Low Byte XX R/W 336

0058 EMAC_FDATA_H EMAC FIFO Data—High Byte 0X R/W 336

0059 EMAC_FFLAGS EMAC FIFO Flags Register 33 R/W 337

PLL

005C PLL_DIV_L PLL Divider Register—Low Byte 00 W 272

005D PLL_DIV_H PLL Divider Register—High Byte 00 W 273

005E PLL_CTL0 PLL Control Register 0 00 R/W 273

005F PLL_CTL1 PLL Control Register 1 00 R/W 275

Timers and PWM

0060 TMR0_CTL Timer 0 Control Register 00 R/W 132

0061 TMR0_IER Timer 0 Interrupt Enable Register 00 R/W 133

0062 TMR0_IIR Timer 0 Interrupt Identification Register 00 R/W 135

0063 TMR0_DR_L Timer 0 Data Register—Low Byte XX R 136

TMR0_RR_L Timer 0 Reload Register—Low Byte XX W 138

0064 TMR0_DR_H Timer 0 Data Register—High Byte XX R 137

TMR0_RR_H Timer 0 Reload Register—High Byte XX W 139

0065 TMR1_CTL Timer 1 Control Register 00 R/W 132

0066 TMR1_IER Timer 1 Interrupt Enable Register 00 R/W 133

0067 TMR1_IIR Timer 1 Interrupt Identification Register 00 R/W 135

0068 TMR1_DR_L Timer 1 Data Register—Low Byte XX R 136

TMR1_RR_L Timer 1 Reload Register—Low Byte XX W 138

Table 3. Register Map (Continued)

Address

(hex) Mnemonic Name Reset

(hex) CPU

Access Page

PS027001-0707 Register Map

eZ80F91 ASSP

Product Specification

0069 TMR1_DR_H Timer 1 Data Register—High Byte XX R 137

TMR1_RR_H Timer 1 Reload Register—High Byte XX W 139

006A TMR1_CAP_CTL Timer 1 Input Capture Control Register XX R/W 139

006B TMR1_CAPA_L Timer 1 Capture Value A

006C TMR1_CAPA_H Timer 1 Capture Value A

006D TMR1_CAPB_L Timer 1 Capture Value B

006E TMR1_CAPB_H Timer 1 Capture Value B

006F TMR2_CTL Timer 2 Control Register 00 R/W 132

0070 TMR2_IER Timer 2 Interrupt Enable Register 00 R/W 133

0071 TMR2_IIR Timer 2 Interrupt Identification Register 00 R/W 135

0072 TMR2_DR_L Timer 2 Data Register—Low Byte XX R 136

TMR2_RR_L Timer 2 Reload Register—Low Byte XX W 138

0073 TMR2_DR_H Timer 2 Data Register—High Byte XX R 137

TMR2_RR_H Timer 2 Reload Register—High Byte XX W 139

0074 TMR3_CTL Timer 3 Control Register 00 R/W 132

0075 TMR3_IER Timer 3 Interrupt Enable Register 00 R/W 133

0076 TMR3_IIR Timer 3 Interrupt Identification Register 00 R/W 135

0077 TMR3_DR_L Timer 3 Data Register—Low Byte XX R 136

TMR3_RR_L Timer 3 Reload Register—Low Byte XX W 138

0078 TMR3_DR_H Timer 3 Data Register—High Byte XX R 137

TMR3_RR_H Timer 3 Reload Register—High Byte XX W 139

0079 PWM_CTL1 PWM Control Register 1 00 R/W 153

007A PWM_CTL2 PWM Control Register 2 00 R/W 154

007B PWM_CTL3 PWM Control Register 3 00 R/W 156

TMR3_CAP_CTL Timer 3 Input Capture Control Register 00 R/W 139

Table 3. Register Map (Continued)

Address

(hex) Mnemonic Name Reset

(hex) CPU

Access Page

PS027001-0707 Register Map

eZ80F91 ASSP

Product Specification

007C PWM0R_L PW M 0 Rising-Edge

TMR3_CAPA_L Timer 3 Capture Value A

007D PWM0R_H PWM 0 Rising-Edge

TMR3_CAPA_H Timer 3 Capture Value A

007E PWM1R_L PWM 1 Rising-Edge

TMR3_CAPB_L Timer 3 Capture Value B

007F PWM1R_H PW M 1 Rising-Edge

TMR3_CAPB_H Timer 3 Capture Value B

0080 PWM2R_L PWM 2 Rising-Edge

TMR3_OC_CTL1 Timer 3 Output Compare Control

0081 PWM2R_H PWM 2 Rising-Edge

TMR3_OC_CTL2 Timer 3 Output Compare Control

0082 PWM3R_L PWM 3 Rising-Edge

TMR3_OC0_L Timer 3 Output Compare 0 Value

0083 PWM3R_H PWM 3 Rising-Edge

TMR3_OC0_H Timer 3 Output Compare 0 Value

Table 3. Register Map (Continued)

Address

(hex) Mnemonic Name Reset

(hex) CPU

Access Page

PS027001-0707 Register Map

eZ80F91 ASSP

Product Specification

0084 PWM0F_L PWM 0 Falling-Edge

TMR3_OC1_L Timer 3 Output Compare 1 Value

0085 PWM0F_H PW M 0 Falling-Edge

TMR3_OC1_H Timer 3 Output Compare 1 Value

0086 PWM1F_L PWM 1 Falling-Edge

TMR3_OC2_L Timer 3 Output Compare 2 Value

0087 PWM1F_H PW M 1 Falling-Edge

TMR3_OC2_H Timer 3 Output Compare 2 Value

0088 PWM2F_L PWM 2 Falling-Edge

TMR3_OC3_L Timer 3 Output Compare 3 Value

0089 PWM2F_H PW M 2 Falling-Edge

TMR3_OC3_H Timer 3 Output Compare 3 Value

008A PWM3F_L PWM 3 Falling-Edge

008B PWM3F_H PWM 3 Falling-Edge

Watchdog Ti mer

0093 WDT_CTL Watchdog Timer Control Register 08/28 R/W 118

0094 WDT_RR Watchdog Timer Reset Register XX W 120

General-Purpose Input/Output Ports

0096 PA_DR Port A Data Register XX R/W 55

Table 3. Register Map (Continued)

Address

(hex) Mnemonic Name Reset

(hex) CPU

Access Page

PS027001-0707 Register Map

eZ80F91 ASSP

Product Specification

0097 PA_DDR Port A Data Direction Register FF R/W 55

0098 PA_ALT1 Port A Alternate Register 1 00 R/W 56

0099 PA_ALT2 Port A Alternate Register 2 00 R/W 56

009A PB_DR Port B Data Register XX R/W 55

009B PB_DDR Port B Data Direction Register FF R/W 55

009C PB_ALT1 Port B Alternate Register 1 00 R/W 56

009D PB_ALT2 Port B Alternate Register 2 00 R/W 56

009E PC_DR Port C Data Register XX R/W 55

009F PC_DDR Port C Data Direction Register FF R/W 55

00A0 PC_ALT1 Po rt C Altern at e Register 1 00 R/W 56

00A1 PC_ALT2 Po rt C Altern at e Register 2 00 R/W 56

00A2 PD_DR Port D Data Register XX R/W 55

00A3 PD_DDR Port D Data Direction Register FF R/W 55

00A4 PD_ALT1 Po rt D Altern at e Register 1 00 R/W 56

00A5 PD_ALT2 Po rt D Altern at e Register 2 00 R/W 56

00A6 PA_ALT0 Port A Alternate Register 0 00 W 56

00A7 PB_ALT0 Port B Alternate Register 0 00 W 56

Chip Select/Wait State Generator

00A8 CS0_LBR Chip Select 0 Lower Bound Register 00 R/W 85

00A9 CS0_UBR Chip Select 0 Upper Bound Register FF R/W 86

00AA CS0_CTL Chip Select 0 Control Register E8 R/W 87

00AB CS1_LBR Chip Select 1 Lower Bound Register 00 R/W 85

00AC CS1_UBR Chip Select 1 Upper Bound Register 00 R/W 86

00AD CS1_CTL Chip Select 1 Control Register 00 R/W 87

00AE CS2_LBR Chip Select 2 Lower Bound Register 00 R/W 85

00AF CS2_UBR Chip Select 2 Upper Bound Register 00 R/W 86

00B0 CS2_CTL Chip Select 2 Control Register 00 R/W 87

00B1 CS3_LBR Chip Select 3 Lower Bound Register 00 R/W 85

00B2 CS3_UBR Chip Select 3 Upper Bound Register 00 R/W 86

Table 3. Register Map (Continued)

Address

(hex) Mnemonic Name Reset

(hex) CPU

Access Page

PS027001-0707 Register Map

eZ80F91 ASSP

Product Specification

00B3 CS3_CTL Chip Select 3 Control Register 00 R/W 87

Random Access Memory Control

00B4 RAM_CTL RAM Control Register C0 R/W 94

00B5 RAM_ADDR_U RAM Address Upper Byte Register FF R/W 95

00B6 MBIST_GPR General Purpose RAM MBIST Control 00 R/W 96

00B7 MBIST_EMR Ethernet MAC RAM MBIST Control 00 R/W 96

Serial Peripheral Interface

00B8 SPI_BRG_L SPI Baud Rate Generator

00B9 SPI_BRG_H SPI Baud Rate Generat or

00BA SPI_CTL SPI Control Register 04 R/W 210

00BB SPI_SR SPI Status Register 00 R 211

00BC SPI_TSR SPI Transmit Shift Register XX W 212

SPI_RBR SPI Receive Buffer Register XX R 212

Infrared Encoder/Decoder

00BF IR_CTL Infrared Encoder/Decoder Control 00 R/W 201

Universal Asynchronous Receiver/Transmitter 0 (UART0)

00C0 UART0_RBR UART 0 Receive Buffer Register XX R 184

UART0_THR UART 0 Transmit Holding Register XX W 184

UART0_BRG_L UART 0 Baud Rate Generator

00C1 UART0_IER UART 0 Interrupt Enable Register 00 R/W 185

UART0_BRG_H UART 0 Baud Rate Generator

00C2 UART0_IIR UART 0 Interrupt Identification Register 01 R 186

UART0_FCTL UART 0 FIFO Control Register 00 W 187

Universal Asynchronous Receiver/Transmitter 0 (UART0)

00C3 UART0_LCTL UART 0 Line Control Register 00 R/W 188

Table 3. Register Map (Continued)

Address

(hex) Mnemonic Name Reset

(hex) CPU

Access Page

PS027001-0707 Register Map

eZ80F91 ASSP

Product Specification

00C4 UART0_MCTL UART 0 Modem Control Register 00 R/W 191

00C5 UART0_LSR UART 0 Line Status Register 60 R 192

00C6 UART0_MSR UART 0 Modem Status Register XX R 194

00C7 UART0_SPR UART 0 Scratch Pad Register 00 R/W 195

I<SuperscriptBold>2C

00C8 I2C_SAR I2C Slave Address Register 00 R/W 226

00C9 I2C_XSAR I2C Extended Slave Address Register 00 R/W 226

00CA I2C_DR I2C Data Register 00 R/W 227

00CB I2C_CTL I2C Control Register 00 R/W 229

General-Purpose Input/Output Ports

00CE PC_ALT0 Port C Alternate Regist er 0 00 W 56

00CF PD _AL T0 Port D Altern at e Re gist er 0 00 W 56

00CC I2C_SR I2C Status Register F8 R 230

I2C_CCR I2C Clock Control Register 00 W 232

00CD I2C_SRR I2C Software Reset Register XX W 233

Universal Asynchronous Receiver/Transmitter 1 (UART1)

00D0 UART1_RBR UART 1 Receive Buffer Register XX R 184

UART1_THR UART 1 Transmit Holding Register XX W 184

UART1_BRG_L UART 1 Baud Rate Generator

00D1 UART1_IER UART 1 Interrupt Enable Register 00 R/W 185

UART1_BRG_H UART 1 Baud Rate Generator

00D2 UART1_IIR UART 1 Interrupt Identification Register 01 R 186

UART1_FCTL UART 1 FIFO Control Register 00 W 187

00D3 UART1_LCTL UART 1 Line Control Register 00 R/W 188

Universal Asynchronous Receiver/Transmitter 0 (UART0)

00D4 UART1_MCTL UART 1 Modem Control Register 00 R/W 191

00D5 UART1_LSR UART 1 Line Status Register 60 R/W 192

Table 3. Register Map (Continued)

Address

(hex) Mnemonic Name Reset

(hex) CPU

Access Page

PS027001-0707 Register Map

eZ80F91 ASSP

Product Specification

00D6 UART1_MSR UART 1 Modem Status Register XX R/W 194

00D7 UART1_SPR UART 1 Scratch Pad Register 00 R/W 195

Low-Power Control

00DB CLK_PPD1 Clock Peripheral Power-Down

00DC CLK_PPD2 Clock Peripheral Power-Down

Real-Time Clock

00E0 RTC_SEC RTC Seconds Register XX R/W 161

00E1 RTC_MIN RTC Minutes Register XX R/W 162

00E2 RTC_HRS RTC Hours Register XX R/W 163

00E3 RTC_DOW RTC Day-of-the-Week Register 0X R/W 164

00E4 RTC_DOM RTC Day-of-the-Month Register XX R/W 165

00E5 RTC_MON RTC Month Register XX R/W 166

00E6 RTC_YR RTC Year Register XX R/W 167

00E7 RTC_CEN RTC Century Register XX R/W 168

00E8 RTC_ASEC RTC Alarm Seconds Register XX R/W 169

00E9 RTC_AMIN RTC Alarm Minutes Register XX R/W 170

00EA RTC_AHRS RTC Alarm Hours Register XX R/W 171

00EB RTC_ADOW RTC Alarm Day-of-the-Week Register 0X R/W 172

00EC RTC_ACTRL RTC Alarm Control Register 00 R/W 173

00ED RTC_CTRL RTC Control Register x0xxxx00

x0xxxx10

R/W 174

Chip Select Bus Mode Control

00F0 CS0_BMC Chip Select 0 Bus Mode Control

00F1 CS1_BMC Chip Select 1 Bus Mode Control

Table 3. Register Map (Continued)

Address

(hex) Mnemonic Name Reset

(hex) CPU

Access Page

PS027001-0707 Register Map

eZ80F91 ASSP

Product Specification

00F2 CS2_BMC Chip Select 2 Bus Mode Control

00F3 CS3_BMC Chip Select 3 Bus Mode Control

Flash Memory Control

00F5 FLASH_KEY Flash Key Register 00 W 102

00F6 FLASH_DATA Flash Data Register XX R/W 103

00F7 FLASH_ADDR_U Flash Address Upper Byte Register 00 R/W 104

00F8 FLASH_CTL Flash Control Register 88 R/W 105

00F9 FLASH_FDIV Flash Frequency Divider Register 01 R/W 106

00FA FLASH_PROT Flash Write/Erase Protection Register FF R/W 107

00FB FLASH_IRQ Flash Interrupt Control Register 00 R/W 108

00FC FLASH_PAGE Flash Page Select Register 00 R/W 109

00FD FLASH_ROW Flash Row Select Register 00 R/W 111

00FE FLASH_COL Flash Column Select Register 00 R/W 112

00FF FLASH_PGCTL Flash Program Control Register 00 R/W 112

Table 3. Register Map (Continued)

Address

(hex) Mnemonic Name Reset

(hex) CPU

Access Page

PS027001-0707 eZ80® CPU Core

eZ80F91 ASSP

Product Specification

eZ80® CPU Core

The eZ80 CPU is the first 8-bit CPU to support 16 MB linear addressing. Each software

module or task under a real-time executive or operating system operates in Z80®

compatible (64 KB) mode or full 24-bit (16 MB) address mode.

The CPU instruction set is a superset of the instruction sets for the Z80 and Z180® CPUs.

Z80 and Z180 programs are executed on an eZ80 CPU with little or no modification.

Features

The eZ80 CPU includes the following features:

•

Code-compatible with Z80 and Z180 products.

•

24-bit linear address space.

•

Single-cycle instruction fetch.

•

Pipelined fetch, decode, and execute.

•

Dual Stack Pointers for ADL (24-bit) and Z80 (16-bit) memory modes.

•

24-bit CPU registers and Arithmetic Logic Unit (ALU).

•

Debug support.

•

Nonmaskable Interrupt (NMI), plus support for 128 maskable vectored interrupts.

New Instructions

The new instructions are listed below:

•

Loads/unloads the I register with a 16-bit value. These new instructions are:

–LD I,HL (ED C7)

–LD HL,I (ED D7)

For more information on the CPU, its instruction set, and eZ80 programming, refer to

eZ80 CPU User Manual (UM0077), available on www.zilog.com.

PS027001-0707 eZ80® CPU Core

eZ80F91 ASSP

Product Specification

PS027001-0707 Reset

eZ80F91 ASSP

Product Specification

Reset

The Reset controller within the eZ80F91 device features a consistent reset function for all

types of resets that affects the system. A system reset, referred in this document as RESET,

returns the eZ80F91 to a defined state. All internal registers af fected by a RESET return to

their default conditions. RESET configures the GPIO port pins as inputs and clears the

CPU’s Program Counter to 000000h. Program code execution ceases during RESET.

The events that cause a RESET are:

•

Power-on reset (POR).

•

Low-Voltage Brownout (VBO).

•

External RESET pin assertion.

•

Watchdog Timer (WDT) time-out when configured to generate a RESET.

•

Real-Time Clock alarm with the CPU in low-power SLEEP mode.

•

Execution of a Debug RESET command.

During RESET, an internal RESET mode timer holds the system in RESET for 1025

system clock (SCLK) cycles to allow sufficient time for the primary crystal oscillator to

stabilize. For internal RESET sources, the RESET mode timer begins i ncrementing on the

next rising edge of SCLK following deactivation of the signal t hat is initiating the RESET

event. For external RESET pin assertion, the RESET mode timer begins on the next rising

edge of SCLK following assertion of the RESET pin for three consecutive SCLK cycles.

The default clock source for SCLK on RESET is the crystal input (XIN). See the

CLK_MUX values in the PLL Control Register 0, (see Table 154 on page 273).

External Reset Input and Indicator

The eZ80F91 RESET pin functions as bot h open-drain (active Low) RESET mode indica-

tor and active Low RESET input. When a RESET event occurs, the internal circuitry

begins driving the RESET pin Low. The RESET pin is held Low by the internal circuitry

until the internal RESET mode timer times out. If the external reset signal is released prior

to the end of the 1025 count time-out, program execution begins following the RESET

mode time-out. If the external reset signal is released after the end of the 1025 count time-

out, then program execution begins following release of the RESET input (the RESET pin

is High for four consecutive SCLK cycles).

Note:

PS027001-0707 Reset

eZ80F91 ASSP

Product Specification

Power-On Reset

A POR occurs every time the supply voltage to the part rises from below the Voltage

Brownout threshold (VVBO) to above the POR voltage threshold (VPOR). The internal

bandgap-referenced voltage detector sends a continuous RESET signal to the Reset con-

troller until the supply voltage (VCC) exceeds the POR voltage threshold. After VCC rises

above VPOR, an on-chip analog delay element briefly maintains the RESET signal to the

Reset controller. After this analog delay element times out, the Reset controller holds the

eZ80F91 in RESET until the RESET mode timer expires. POR operation is illustrated in

Figure 3. The signals in Figure 3 are not drawn to scale but for illustration purposes only.

Voltage Brownout Reset

If the supply voltage (VCC) drops below the VVBO after program execution begins, the

eZ80F91 device resets. The VBO protection c ircuitry detects the low supply voltage and

initiates a RESET via the Reset controller. The eZ80F91 remains in RESET until the sup-

ply voltage again returns above the POR voltage threshold (VPOR) and the Reset controller

releases the internal RESET signal. The VBO circuitry rejects short negative brown-out

pulses to prevent spurious RESET events.

VBO operation is illustrated in Figure 4 on page 43. The signals in the figure are not

drawn to scale but for illustration purposes only.

Figure 3. Power-On Reset Operation

VPOR

TANA

VVBO

V = 0.0V

V = 3.3V

System Clock

Internal RESET

Signal

Oscillator

Startup

Program Execution

RESET mode timer delay

PS027001-0707 Reset

eZ80F91 ASSP

Product Specification

Figure 4. Voltage Brownout Reset Operation

VPOR

TANA

VVBO

V = 3.3V

V = 3.3V CC

System Clock

Internal RESET

Signal

Voltage

Brown-out

Program Execution Program Execution

RESET mode

timer delay

PS027001-0707 Reset

eZ80F91 ASSP

Product Specification

PS027001-0707 Low-Power Modes

eZ80F91 ASSP

Product Specification

Low-Power Modes

The eZ80F91 device provides a range of power-saving features. The highest level of

power reduction is provided by SLEEP mode with all peripherals disabled, including

VBO. The next level of power reduction is provided by the HALT instruction. The most

basic level of power reduction is provided by the clock peripheral power-down registers.

SLEEP Mode

Execution of the CPU’s SLP instruction puts the eZ80F91 device into SLEEP mode. In

SLEEP mode, the operating characteristics are:

•

The primary crystal oscillator is disabled.

•

The system clock is disabled.

•

The CPU is idle.

•

The Program Counter (PC) stops incrementing.

•

The 32 kHz crystal oscillator continues to operate and drives the real-time clock and

WDT (if WDT is configured to operate from the 32 kHz oscillator).

The CPU is brought out of SLEEP mode by any of the following operations:

•

A RESET via the external RESET pin driven Low.

•

A RESET via a real-time clock alarm.

•

A RESET via a WDT time-out (if running out of the 32 kHz oscillator and configured

to generate a RESET on time-out).

•

A RESET via execution of a Debug RESET command.

•

A RESET via the Low-Voltage Brownout (VBO) detection circuit, if enabled.

After exiting SLEEP mode, the standard RESET delay occurs to allow the primary crystal

oscillator to stabilize. For more information, see Figure 4 on page 43.

HALT Mode

Execution of the CPU’s HALT instruction puts the eZ80F91 devic e into HALT mode.

In HALT mode, the operating characteristics are:

•

The primary crystal oscillator is enabled and continues to operate.

•

The system clock is enabled and continues to operate.

•

The CPU is idle.

PS027001-0707 Low-Power Modes

eZ80F91 ASSP

Product Specification

•

The PC stops incrementing.

The CPU is brought out of HALT mo de by any of the following op eratio ns:

•

A nonmaskable interrupt (NMI).

•

A maskable interrupt.

•

A RESET via the external RESET pin driven Low.

•

A Watchdog Timer time-out (if, configured to generate either an NMI or RESET upon

time-out).

•

A RESET via execution of a Debug RESET command.

•

A RESET via the Low-Voltage Brownout detection circuit, if enabled.

To minimize current in HALT mo de, the system clock must be gated-off for all unused

on-chip peripherals via the Clock Peripheral Power-Down Registers.

HALT Mode and the EMAC Function

When the CPU is in HALT mode, the eZ80F91 device’s EMAC block cannot be disabled

as other peripherals can. On receipt of an Ethernet packet, a maskable Receive interrupt is

generated by the EMAC block, just as it would be in a non-halt mode. Accordingly, the

processor wakes up and continues with the user-defined application.

Clock Peripheral Power-Down Registers

To reduce power, the Clock Peripheral Power-Down Registers allow the system clock to

be blocked to unused on-chip peripherals. On RESET, all periph erals are enabled. The

clock to unused peripherals are gated off by setting the appropriate bit in the Clock Periph-

eral Power-Down Registers to 1. When powered down, the peripherals are completely dis-

abled. To re-enable, the bit in the Clock Peripheral Power-Down Registers must be cleared

to 0.

Additionally, the VBO_OFF bit of CLK_PPD2 is used to disable the VBO detection cir-

cuit and thereby significantly reduce DC current consumption (see Table 234 on page 345)

when this function is not required.

Many peripherals features separate enable/disable control bits that must be appropriately

set for operation. These peripheral specific enable/disable bits do not prov ide the same

level of power reduction as the Clock Peripheral Power-Down Registers. When powered

down, the individual peripheral control register is not accessible for Read or Write access,

(see Table 4 on page 47 and Table 5 on page 48).

PS027001-0707 Low-Power Modes

eZ80F91 ASSP

Product Specification

Table 4. Clock Peripheral Power-Down Register 1 (CLK_PPD1 = 00DBh)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit Position Value Description

GPIO_D_OFF 1 System clock to GPIO Port D is powered down.

Port D alternate functions do not operate correctly.

0 System clock to GPIO Port D is powered up.

GPIO_C_OFF 1 System clock to GPIO Port C is powered down.

Port C alternate functions do not operate correctly.

0 System clock to GPIO Port C is powered up.

GPIO_B_OFF 1 System clock to GPIO Port B is powered down.

Port B alternate functions do not operate correctly.

0 System clock to GPIO Port B is powered up.

GPIO_A_OFF 1 System clock to GPIO Port A is powered down.

Port A alternate functions do not operate correctly.

0 System clock to GPIO Port A is powered up.

SPI_OFF 1 System clock to SPI is powered down.

0 System clock to SPI is powered up.

I2C_OFF 1 System clock to I2C is powered do wn .

0 System clock to I2C is powered up .

UART1_OFF 1 System clock to UART1 is powered down.

0 System clock to UART1 is powered up.

UART0_OFF 1 System clock to UART0 and IrDA endec is powered down.

0 System clock to UART0 and IrDA endec is powered up.

PS027001-0707 Low-Power Modes

eZ80F91 ASSP

Product Specification

Table 5. Clock Peripheral Power-Down Register 2 (CLK_PPD2 = 00DCh)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R R R/W R/W R/W R/W

Note: R = Read Only; R/W = Read/Write.

Bit Position Value Description

PHI_OFF 1 PHI Clock output is disabled (output is high-impedance).

0 PHI Clock output is enabled.

6 VBO_OFF 1 Voltage Brownout detection circuit is disabled. This reduces

DC current consumption in situations where VBO detection is

not necessary. Power-On Reset functionality is not affected by

this setting.

0 VBO detection circuit is enabled.

[5:4] 000 Reserved.

TIMER3_OFF 1 System clock to TIMER3 is powered down.

0 System clock to TIMER3 is powered up.

TIMER2_OFF 1 System clock to TIMER2 is powered down.

0 System clock to TIMER2 is powered up.

TIMER1_OFF 1 System clock to TIMER1 is powered down.

0 System clock to TIMER1 is powered up.

TIMER0_OFF 1 System clock to TIMER0 is powered down.

0 System clock to TIMER0 is powered up.

PS027001-0707 General Purpose In put/Output

eZ80F91 ASSP

Product Specification

General Purpose Input/Output

The eZ80F91 device features 32 General Purpose Input/Outp ut (GPIO) pins. The GPIO

pins are assembled as four 8-bit ports—Port A, Port B, Port C, and Port D. All port signals

are configured as either inputs or outputs. In addition, all the port pins are used as vectored

interrupt sources for the CPU.

The eZ80F91 ASSP’s GPIO ports are slightly different from its eZ80® predecessors.

Specifically, Port A pins source 8 mA and sink 10 mA. In addition, the

Port B and C inputs now feature Schmitt-trigger input buffers.

GPIO Operation

GPIO operation is the same for all four GPIO ports (Ports A, B, C, and D). Each port

features eight GPIO port pins. The operating mode for each pin is controlled by four bits

that are divided between four 8-bit registers. The GPIO mode control registers are:

•

Port x Data Register (Px_DR)

•

Port x Data Direction Register (Px_DDR)

•

Port x Alternate Register 1 (Px_ALT1)

•

Port x Alternate Register 2 (Px_ALT2)

where x can be A, B, C, or D representing any of the four GPIO ports. The mode for each

pin is controlled by setting each register bit pertinent to the pin to be configured. For

example, the operating mode for port B pin 7 (PB7) is set by the values contained in

PB_DR[7], PB_DDR[7], PB_ALT1[7], and PB_ALT2[7].

The combinatio n of the GPIO co ntrol register bits allows indiv idual config uration o f each

port pin for nine modes. In all mode s, reading of the Port x Data register returns the

sampled state or level of the signal on the corresponding pin. Table 6 on page 50 indicates

the function of each port signal based on these four register bits. After a RESET event, all

GPIO port pins are configured as standard digital inputs with the interrupts disabled.

In addition to the four mode control registers, each port has an 8-bit register , which is used

for clearing edge triggered interrupts. This register is the Port x Alternate register

0(Px_ALT0) where x can be A, B, C or D representing the four GPIO ports. When a GPIO

pin is configured as an edge triggered interrupt, writing 1 to the corresponding bit of the

Px_ALT0 register clears the interrupt.

PS027001-0707 General Purpose In put/Output

eZ80F91 ASSP

Product Specification

Figure 5 and Figure 6 on page 53 display the simplified block diagrams of the GPIO port

pin for the various modes.

GPIO Mode 1—Output

The port pin is configured as a standard digital output pin. The value written to the Port x

Data register (Px_DR) is driven on the pin.

GPIO Mode 2—Input

The port pin is configured as a standard digital input pin. The output is high impedance.

The value stored in the Port x Data register produces no effect. As in all modes, a read

from the Port x Data register returns the pin’s value. GPIO mode 2 is the default operating

mode following a RESET.

Table 6. GPIO Mode Selection

GPIO

Mode Px_ALT2

Bits7:0 Px_ALT1

Bits7:0 Px_DDR

Bits7:0 Px_DR

Bits7:0 Port Mode Output

10000

Output 0

0001

Output 1

20010

Input from pin High impedance

0011

Input from pin High impedance

30100

Open-drain output 0

0101

Open-drain I/O High impedance

40110

Open-source I/O High impedance

0111

Open-source output 1

51000

Reserved High impedance

61001

Interrupt—dual edge-triggered High impedance

71010

Alternate function controls port I/O.

1011

Alternate function controls port I/O.

81100

Interrupt—active Low High impedance

1101

Interrupt—active High High impedance

91110

Interrupt—falling edge-triggered High impedance

1111

Interrupt—rising edge-triggered High impedance

PS027001-0707 General Purpose In put/Output

eZ80F91 ASSP

Product Specification

GPIO Mode 3—Open Drain

The port pin is configured as open-drain Input/Output. The GPIO pins do not feature an

internal pull-up to the supply voltage. To employ the GPIO pin in OPEN-DRAIN mode,

an external pull-up resistor must connect the pin to the supply voltage. Writing 0 to the

Port x Data register outputs a Low at the pin. W riting 1 to the Port x Data register results in

high-impedance output.

GPIO Mode 4—Open Source

The port pin is configured as open-source I/O. The GPIO pins do not feature an internal

pull-down to the supply ground. To employ the GPIO pin in OPEN-SOURCE mode, an

external pull-down resistor must connect the pin to the supply ground. Writing 1 to the

Port x Data register outputs a High at the pin. Writing 0 to the Port x Data register results

in a high-impedance output.

GPIO Mode 5—Reserved

This mode produces a high-impedance output.

GPIO Mode 6—Dual Edge Triggered

The port pin is configured for dual edge-triggered interrupt mode. Both a rising and a

falling edge on this pin cause an interrupt request to be sent to the CPU. To select this

mode from the default mode (mode 2), you must:

1. Set Px_DR=1

2. Set Px_ALT2=1

3. Set Px_ALT1=0

4. Set Px_DDR=0

Writing a 1 to the Port x ALT0 register bit position corresponding to the interrupt request

clears the interrupt.

GPIO Mode 7—Alternate Functions

The port pin is configured to pass control over to the alternate (secondary) functions

assigned to the pin. For example, the alternate mode function for PC5 is the DSR1 input

signal to UART1 and the alternate mode function for PB4 is the timer 3 input capture.

When GPIO mode 7 is enable d, the pin output data and pin high-im pedance control is

obtained from the alternate function's data output and high-impeda nce control,

respectively. The value in the Port x Data register produces no effect on operation. Input

signals are sampled by the system clock before being passed to the alternate input

function.

If the alternate function of a pin is an input and alternate function mode for that pin is not

enabled, the input is driven to a default non-asserted value. For example, in alternate mode

PS027001-0707 General Purpose In put/Output

eZ80F91 ASSP

Product Specification

function, PC5 drives the DSR1 signal to UART1. As this signal is Low level true, the

DSR1 signal to UART1 is driven to 1 when PC5 is not in alternate mode function.

GPIO Mode 8—Level Sensitive Interrupt

The port pin is configured for level-sensitive interrupt mode. The value in the Port x Data

is generated when the level at the pin is the same as the level stored in the Port x Data

the selected interrupt level for a minimum of two system clock periods to initiate an

interrupt. The interrupt request remains active as long as this condition is maintained at the

external source. For example, if a port pin is configured as a low-level-sensitive interrupt,

the interrupt request will be asserted when the pin has been low for two system clocks and

remains active until the pin goes high.

Configuring a pin for mode 8 requires a transition through mode 9 (edge triggered mode).

To avoid the possibility of an unwanted interrupt while transition through mode 9, the

following steps must be taken to select mode 8 when starting from the default mode (mode

2):

1. Disable interrupts

2. Set Px_DR = 0 (low level interrupt) or 1 (high level interrupt)

3. Set Px_ALT2 = 1

4. Set Px_ALT1 =1 (mode 9)

5. Set Px_DDR = 0 (mode 8)

6. Set Px_ALT0 = 1 (to clear possible mode 9 interrupt)

7. Enable interrupts

GPIO Mode 9—Edge Triggered Interrupt

The port pin is configured for single edge triggered interrupt mode. The value in the Port x

Data register determines whether a positive or negative edge causes an interrupt request.

Writing 0 to the Port x Data register bit sets the selected pin to generate an interrupt

request for falling edges. Writing 1 to the Port x Data register bit sets the selected pin to

generate an interrupt request for rising edges. The interrupt request remains active until 1

is written to the corresponding bit of the Port x Alternate register 0. To select mode 9 from

the default mode (mode 2), you must:

1. Set the Port x Data register

2. Set Px_ALT2 = 1

3. Set Px_ALT1 = 1

4. Set Px_DDR=1

PS027001-0707 General Purpose In put/Output

eZ80F91 ASSP

Product Specification

Figure 5. GPIO Port Pin Block Diagram for Input and Interrupt Modes

Figure 6. GPIO Port Pin Block Diagram for Output and Input/Output Mode

Mode 2

Mode 6

Mode 8

Mode 9

Mode 7(Input)

GPIO

Output Buffer

ENB

Tristated

for

modes 2,6,8,9

and 7(Input)

SysClock

Input to chip

GPIO

Port Pin

_DR*

Alternate

Function

Input

Interrupt

Logic

Interrupt

Default Value

Mode 7(Input)

Clear Interrupt

Modes 6,8,9

* Reading from the

_DR returns

the value stored in this register

Mode 4

Mode 3

Mode 1

Mode 7 (Output)

Alternate Function Output

Data

System Clock

_DR*

GPIO

Output Buffer

ENB

GPIO

Port

VDD

External

Pull-up

Required for

Mode 3

(open drain)

External Pull-up

Required for

Mode 4

(Open source)

* Writing to the

_DR stores

the value in this register

Simplified

GPIO

Port Block Diagram for Modes 1, 3, 4 and 7 (Output)

PS027001-0707 General Purpose In put/Output

eZ80F91 ASSP

Product Specification

GPIO Interrupts

Each port pin is used as an interrupt source. Interrupts are either level- or edge-triggered.

Level-Triggered Interrupts

When the port is configured for level-triggered interrupts (mode 8), the corresponding

port pin is open-drain. An interrupt request is generated when the level at the pin is the

same as the level stored in the Port x Data register. The port pin value is sampled by the

system clock. The input pin must be held at the selected interrupt level for a minimum of

two clock periods to initiate an interrupt. The interrupt request remains active as long as

this condition is maintained at the external source.

For example, if PA3 is programmed for low-level interrupt and the pin is forced Low for

two clock cycles, an interrupt request signal is generated from that port pin and sent to the

CPU. The interrupt request signal remains active until the external device driving PA3

forces the pin high. The CPU must be enabled to respond to interrupts for the interrupt

request signal to be acted up on.

Edge Triggered Interrupts

When the port is configured for edge triggered interrupts, the corresponding port pin is

open-drain. If the pin receives the correct edge from an external device, the port pin

generates an interrupt request signal to the CPU.

When configured for dual-edge triggered interrupt mode (GPI O mode 6), both a rising and

a falling edge on the pin cause an interrupt request to be sent to the CPU. To select mode 6

from the default mode (mode 2), you must:

1. Set Px_DR = 1

2. Set Px_ALT2 =1

3. Set Px_ALT1= 0

4. Set Px_DDR = 0

When configured for single-edge triggered interrupt mode (GPIO mode 9), the value in

the Port x Data register determines whether a positive or negative edge causes an interrupt

request. 0 in the Port x Data register bit sets the selected pin to generate an interrupt

request for falling edges. 1 in the Port x Data register bit sets the selected pin to generate

an interrupt request for rising edges. To select mode 9 from the default mode (mode 2),

you must:

1. Set Px_DR = 1

2. Set Px_ALT2 = 1

3. Set Px_ALT = 1

4. Set Px_DDR = 1

PS027001-0707 General Purpose In put/Output

eZ80F91 ASSP

Product Specification

Edge triggered interrupts are cleared by writing 1 to the corresponding bit of the Px_ALT0

interrupt is cleared by writing a 1 to Px_ALT0[4].

GPIO Control Registers

Each GPIO port has four registers that controls its operation. The operating mode of each

bit within a port is selected by writing to the corresponding bits of these four registers as

shown in Table 6 on page 50. These four registers are Port Data register(Px_DR), Port

Data Direction register(Px_DDR), Port Alternate register 1(PX_ALT1), and Port Alternate

Alternate register 0(Px_ALT0), which is used for clearing edge triggered interrupts.

Port x Data Registers

When the port pins are configured for one of the output modes, the data written to the

Port x Data registers (see Table 7) is driven on the corresponding pins. In all modes,

reading from the Port x Data registers always returns the sampled current value of the

corresponding pins. When th e port pins are configured for edge triggered interrupts or

level-sensitive interrupts, the value written to the Port x Data register bit selects the

interrupt edge or interrupt level (for more details on GPIO mode selection, see Table 6 on

page 50).

Port x Data Direction Registers

In conjunction with the other GPIO Control registers, the Port x Data Direction registers

(see Table 8) control the operating modes of the GPIO port pins. For more details on GPIO

mode selection, see Table 6 on page 50.

Table 7. Port x Data Registers

(PA_DR = 0096h, PB_DR = 009Ah, PC_DR = 009Eh, PD_DR = 00A2h)

Bit 76543210

Reset XXXXXXXX

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: X = Undefined; R/W = Read/Write.

Table 8. Port x Data Direction Registers

(PA_DDR = 0097h, PB_DDR = 009Bh, PC_DDR = 009Fh, PD_DDR = 00A3h)

Bit 76543210

Reset 11111111

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

PS027001-0707 General Purpose In put/Output

eZ80F91 ASSP

Product Specification

Port x Alternate Register 0

The Port x Alternate register 0 is used to clear edge triggered interrupts. If an edge

triggered interrupt occurs, writing 1 to the corresponding bit of this register will clear it.

Port x Alternate Register 1

In conjunction with the other GPIO Control registers, the Port x Alternate Register 1 (see

Table 10) controls the operating modes of the GPIO port pins. For more details on GPIO

mode selection, see Table 6 on page 50.

Port x Alternate Register 2

In conjunction with the other GPIO Control registers, the Port x Alternate Register 2 (see

Table 11) controls the operating modes of the GPIO port pins. For more details on GPIO

mode selection, see Table 6 on page 50.

Table 9. Port x Alternate Registers 0

(PA_ALT0 = 00A6h, PB_ALT0 = 00A7h, PC_ALT0 = 00CEh, PD_ALT0 = 00CFh)

Bit 76543210

Reset 00000000

CPU Access WWWWWWWW

Note: W = Write only

Table 10. Port x Alternate Registers 1

(PA_ALT1 = 0098h, PB_ALT1 = 009Ch, PC_ALT1 = 00A0h, PD_ALT1 = 00A4h)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Table 11. Port x Alternate Registers 2

(PA_ALT2 = 0099h, PB_ALT2 = 009Dh, PC_ALT2 = 00A1h, PD_ALT2 = 00A5h)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

PS027001-0707 Interrupt Controller

eZ80F91 ASSP

Product Specification

Interrupt Controller

The interrupt controller on the eZ8 0F9 1 device routes the interrupt request signals from

the internal peripherals, external devices (via the internal port I/O), and the nonmaskable

interrupt (NMI) pin to the CPU.

Maskable Interrupts

On the eZ80F91 device, all maskable interrupts use the CPU’s vectored interrupt function.

The size of I register is modified to 16 bits in the eZ80F91 device differing from the previ-

ous versions of eZ80® CPU, to allow for a 16 MB range of interrupt vector table place-

ment. Additionally, the size of the IVECT register is increased from 8 bits to 9 bits to

provide an interrupt vector table that is expanded and more easily integrated with other

interrupts.

The vectors are 4 bytes (32 bits) apart, even though only 3 bytes (24 bits) are required.

A fourth byte is implemented for both programmability and expansion purposes.

Starting the interrupt vectors at 40h allows for easy implementation of the interrupt con-

troller vectors with the RST vectors. Table 12 lists the interrupt vector sources by priority

for each of the maskable interrupt sources. The maskable interrupt sources are listed in

order of their priority, with vector 40h being the highest-priority interrupt. In ADL mode,

the full 24-bit interrupt vector is located at starting address {I[15:1], IVECT[8:0]}, where

I[15:0] is the CPU’s Interrupt Page Address register.

Table 12. Interrupt Vector Sources by Priority

Priority Vector Source Priority Vector Source

0 040h EMAC Rx 24 0A0h Port B 0

1 044h EMAC Tx 25 0A4h Port B 1

2 048h EMAC SYS 26 0A8h Port B 2

3 04Ch PLL 27 0ACh Port B 3

4 050h Flash 28 0B0h Port B 4

5 054h Timer 0 29 0B4h Port B 5

6 058h Timer 1 30 0B8h Port B 6

7 05Ch Timer 2 31 0BCh Port B 7

8 060h Timer 3 32 0C0h Port C 0

9 064h Unused* 33 0C4h Port C 1

10 068h Unused* 34 0C8h Port C 2

PS027001-0707 Interrupt Controller

eZ80F91 ASSP

Product Specification

The user’s program must store the interrupt service routine starting address in the

four-byte interrupt vector locations. For exam ple in ADL mode, the three-byte address for

the SPI interrupt service routine is stored at {I[15:1], 07Ch}, {I[15:1], 07Dh}, and {I[15:1],

07Eh}. In Z80® mode, the two-byte address for the SPI interrupt service routine is stored at

{MBASE[7:0], I[7:1], 07Ch} and {MBASE, I[7:1], 07Dh}. The least-significant byte is

stored at the lower address.

When one or more interrupt requests (IRQs) become active, an interrupt request is

generated by the interrupt controller and sent to the CPU. The corresponding 9-bit

interrupt vector for the highest-priority interrupt is placed on the 9-bit interrupt vector bus,

IVECT[8:0]. The interrupt vector bus is internal to the eZ80F91 device and is therefore

externally not visible. The response time of the CPU to an interrupt request is a function of

the current instruction being executed as well as the number of wait state s being asserted.

The interrupt vector, {I[15:1], IVECT[8:0]} is visible on the address bus (ADDR[23:0]),

when the interrupt service routine begins. The response of the CPU to a vectored interrupt

on the eZ80F91 device is explained in Table 13 on page 59. Interrupt sources are required

to be active until the Interrupt Service Routine (ISR) starts.

The lower bit of the I register is replaced with the MSB of the IVECT from the interrupt

controller. As a result, the interrupt vector table is required to be placed onto a 512-byte

11 06Ch RTC 35 0CCh Port C 3

12 070h UART 0 36 0D0h Port C 4

13 074h UART 1 37 0D4h Port C 5

14 078h I2C380D8hPort C 6

15 07Ch SPI 39 0DCh Port C 7

16 080h Port A 0 40 0E0h Port D 0

17 084h Port A 1 41 0E4h Port D 1

18 088h Port A 2 42 0E8h Port D 2

19 08Ch Port A 3 43 0ECh Port D 3

20 090h Port A 4 44 0F0h Port D 4

21 094h Port A 5 45 0F4h Port D 5

22 098h Port A 6 46 0F8h Port D 6

23 09Ch Port A 7 47 0FCh Port D 7

Note: *The vector addresses 064h and 068h are left unused to avoid conflict with the nonmaskable

interrupt (NMI) address 066h. The NMI is priori tized higher than all maskable interrupts.

Table 12. Interrupt Vector Sources by Priority (Continued)

Priority Vector Source Priority Vector Source

Note:

PS027001-0707 Interrupt Controller

eZ80F91 ASSP

Product Specification

boundary. Setting the LSB of the I register produces no ef fect on the interrupt vector

address.

Table 13. Vectored Interrupt Operation

Memory

Mode ADL

Bit MADL

Bit Operation

Z80 Mode 0 0 Read the LSB of the interrupt vector placed on the internal vecto red interrupt

bus, IVECT [8:0], by the interrupting peripheral.

IEF1 ← 0

IEF2 ← 0

The Starting Program Counter is effective {MBASE, PC[15:0]}.

Push the 2-byte return address PC[15:0] onto the ({MBASE,SPS}) stack.

The ADL mode bit remains cleared to 0.

The interrupt vector address is located at { MBASE, I[7:1], IVECT[8:0] }.

PC[23:0] ← ( { MBASE, I[7:1], IVECT[8:0] } ).

The interrupt service routine mu st en d with RETI.

ADL Mode 1 0 Read the LSB of the interrupt vector placed on the internal vectored interrupt

bus, IVECT [8:0], by the interrupting peripheral.

IEF1 ← 0

IEF2 ← 0

The Starting Program Counter is PC[23:0].

Push the 3-byte return address, PC[23:0], onto the SPL stack.

The ADL mode bit remains set to 1.

The interrupt vector address is located at { I[15:1], IVECT[8:0] }.

PC[23:0] ← ( { I[15:1], IVECT[8:0] } ).

The interrupt service routine mu st en d with RETI.

Z80 Mode 0 1 Read the LSB of the interrupt vector placed on the internal vectored interr upt

bus, IVECT[8:0], bus by the interrupting peripheral.

•IEF1 ← 0

•IEF2 ← 0

• The Starting Program Counter is effective {MBASE, PC[15:0]}.

• Push the 2-byte return address, PC[15:0], onto the SPL stack.

• Push a 00h byte onto the SPL st ack to indicate an interrupt from Z80 mode

(because ADL = 0).

• Set the ADL mode bit to 1.

• The interrupt vector address is located at { I[15:1], IVECT[8:0] }.

• PC[23:0] ← ( { I[15:1], IVECT[8:0] } ).

• The interrupt service routine must end with RETI.L

PS027001-0707 Interrupt Controller

eZ80F91 ASSP

Product Specification

Interrupt Priority Registers

The eZ80F91 provides two interrupt priority levels for the maskable interrupts. The default

priority (or Level 0) is indicated in Table 14 on page 61. The default priority of any

maskable interrupt increases to Level 1 (a higher priority than any Level 0 interrupt) by

setting the appropriate bit in the Interrupt Priority registers as shown in Table 14 on page 61.

ADL Mode 1 1 Read the LSB of the interrupt vector place d on the internal vectored interrupt

bus, IVECT [8:0], by the interrupting peripheral.

•IEF1 ← 0

•IEF2 ← 0

• The Starting Program Counter is PC[23:0].

• Push the 3-byte return address, PC[23:0], onto the SPL stack.

• Push a 01h byte onto the SPL stack to indicate a resta rt from ADL mode

(because ADL = 1).

• The ADL mode bit remains set to 1.

• The interrupt vector address is located at {I[15:1], IVECT[8:0]}.

• PC[23:0] ← ( { I[15:1], IVECT[8:0] } ).

• The interrupt service routine must end with RETI.L

Table 13. Vectored Interrupt Operation (Continued)

Memory

Mode ADL

Bit MADL

Bit Operation

PS027001-0707 Interrupt Controller

eZ80F91 ASSP

Product Specification

Table 14. Interrupt Priority Registers (INT_P0 = 0010h, INT_P1 = 0011h, INT_P2 = 0012h, INT_P3

= 0013h, INT_P4 = 0014h, INT_P5 = 0015h)

Bit 76543210

INT_P0 Reset 00000000

INT_P1 Reset 000000*0*0

INT_P2 Reset 00000000

INT_P3 Reset 00000000

INT_P4 Reset 00000000

INT_P5 Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: X = Undefined; R/W = Read/Write, *Unused.

Bit

Position Value Description

INT_PX 0 Default Interrupt Priority

1 Level One In te rrupt Priority

INT_PX 0 Default Interrupt Priority

1 Level One In te rrupt Priority

INT_PX 0 Default Interrupt Priority

1 Level One In te rrupt Priority

INT_PX 0 Default Interrupt Priority

1 Level One In te rrupt Priority

INT_PX 0 Default Interrupt Priority

1 Level One In te rrupt Priority

INT_PX 0 Default Interrupt Priority

1 Level One In te rrupt Priority

INT_PX 0 Default Interrupt Priority

1 Level One In te rrupt Priority

INT_PX 0 Default Interrupt Priority

1 Level One In te rrupt Priority

PS027001-0707 Interrupt Controller

eZ80F91 ASSP

Product Specification

The Interrupt Vector Priority Control bits are listed in Table 15.

If more than one maskable interrupt is prioritized to a higher level (Level 1), the higher-

priority interrupts follow the priority order as described in Table 14 on page 61. For

Table 15. Interrupt Vector Priority Control Bits

Priority Control

Bit Vector Source Priority Control

Bit Vector Source

INT_P0[0] 040h EMAC Rx INT_P3[0] 0A0h Port B 0

INT_P0[1] 044h EMAC Tx INT_P3[1] 0A4h Port B 1

INT_P0[2] 048h EMAC SYS INT_P3[2] 0A8h Port B 2

INT_P0[3] 04Ch PLL INT_P3[3] 0ACh Port B 3

INT_P0[4] 050h Flash INT_P3[4] 0B0h Port B 4

INT_P0[5] 054h Timer 0 INT_P3[5] 0B4h Port B 5

INT_P0[6] 058h Timer 1 INT_P3[6] 0B8h Port B 6

INT_P0[7] 05Ch Timer 2 INT_P3[7] 0BCh Port B 7

INT_P1[0] 060h Timer 3 INT_P4[0] 0C0h Port C 0

INT_P1[1] 064h Unused* INT_P4[1] 0C4h Port C 1

INT_P1[2] 068h Unused* INT_P4[2] 0C8h Port C 2

INT_P1[3] 06Ch RTC INT_P4[3] 0CCh Port C 3

INT_P1[4] 070h UART 0 INT_P4[4] 0D0h Port C 4

INT_P1[5] 074h UART 1 INT_P4[5] 0D4h Port C 5

INT_P1[6] 078h I2C INT_P4[6] 0D8h Port C 6

INT_P1[7] 07Ch SPI INT_P4[7] 0DCh Port C 7

INT_P2[0] 080h Port A 0 INT_P5[0] 0E0h Port D 0

INT_P2[1] 084h Port A 1 INT_P5[1] 0E4h Port D 1

INT_P2[2] 088h Port A 2 INT_P5[2] 0E8h Port D 2

INT_P2[3] 08Ch Port A 3 INT_P5[3] 0ECh Port D 3

INT_P2[4] 090h Port A 4 INT_P5[4] 0F0h Port D 4

INT_P2[5] 094h Port A 5 INT_P5[5] 0F4h Port D 5

INT_P2[6] 098h Port A 6 INT_P5[6] 0F8h Port D 6

INT_P2[7] 09Ch Port A 7 INT_P5[7] 0FCh Port D 7

Note: *The vector addresses 064h and 068h are left unused to avoid conflict with the NMI vector address 066h.

PS027001-0707 Interrupt Controller

eZ80F91 ASSP

Product Specification

example, Table 16 shows the maskable interrupts 044h (EMAC Tx), 084h (Port A 1), and

06Ch (RTC) as elevated to priority Level 1. Table 17 shows the new interrupt priority for

the top ten maskable interrupts.

Table 16. Example: Maskable Interrupt Priority

Priority

INT_P0 02h Increase 044h (EMAC Tx) to Priority Level 1

INT_P1 08h Increase 06Ch (RTC) to Priority Level 1

INT_P2 02h Increase 084h (Po rt A1) to Priority Level 1

INT_P3 00h Default priority

INT_P4 00h Default priority

INT_P5 00h Default priority

Table 17. Example: Priority Levels for Maskable Interrupts

Priority Vector Source

0 044h EMAC Tx

1 06Ch RTC

2 084h Port A 1

3 040h EMAC Rx

4 048h EMAC SYS

5 04Ch PLL

6 050h Flash

7 054h Timer 0

8 058h Timer 1

9 05Ch Timer 2

PS027001-0707 Interrupt Controller

eZ80F91 ASSP

Product Specification

GPIO Port Interrupts

All interrupts are latched. In effect, an interrupt is held even if the interrupt occurs while

another interrupt is being serviced and interrupts are disabled, or if the interrupt is of a

lower priority. However, before the latched ISR completes its task or re-enables interrupts,

the ISR must clear the interrupt. For on-chip peripherals, the interrupt is cleared when the

data register is accessed. For GPIO-level interrupts, the interrupt signal must be removed

before the ISR completes its task. For GPIO-edge interrupts (single and dual), the interrupt

is cleared by writing a 1 to the corresponding bit position in the Px_ALT0 register. See

Edge Triggered Interrupts on page 54.

For F91 devices with a ZDI or JTAG revision less than 2, care must be taken using a GPIO

data register when it is configured for interrupts. For edge-interrupt modes (modes 6 and 9)

as discussed earlier, writing 1 clears the interrupt. However, 1 in the data register also con-

veys a particular configuration. For example, when the data register Px_DR is set first fol-

lowed by the Px_ALT2, Px_ALT1, and Px_DDR registers, then the configuration is

performed correctly. Writing 1 to the register later to clear interrupts does not change the

configuration. For F91 devices with a ZDI or JTAG revision 2 or later , the clearing of inter-

rupts is accomplished through the new Px_ALT0 registers and the above problem does not

exist.

In mode 9 operation, if the GPIO is already configured for mode 9 and if the trigger edge

must be changed (from falling to rising or from rising to falling), then the configuration

must be changed to anoth er mo de, such as Mode 2, and th en changed b ack to mode 9 . For

example, enter mode 2 by writing the registers in the sequence PxDR, Px_ALT2,

Px_ALT1, Px_DDR. Next, change back to mode 9 by writing the registers i n the sequence

PxDR, Px_ALT2, Px_ALT1, Px_DDR.

In Mode 8 operation, if the GPIO is configured for level-sensitive interrupts, a Write value

to Px_DR after configuration must be the same Write value used when configuring the

GPIO.

Note:

PS027001-0707 Chip Selects and Wait States

eZ80F91 ASSP

Product Specification

Chip Selects and Wait States

The eZ80F91 generates four chip selects for external devices. Each chip select is pro-

grammed to access either the memory space or the I/O space. The memory chip selects are

individually programmed on a 64 KB boundary. Each I/O chip selects choose a 256-byte

section of I/O space. In addition, each chip select is programmed for up to 7 Wait states.

Memory and I/O Chip Selects

Each of the chip selects are enabled either for the memory address space or the I/O address

space, but not both. To select the memory address space for a particular chip select,

CSX_IO (CSx_CTL[4]) must be reset to 0. To select the I/O address space for a particular

chip select, CSX_IO must be set to 1. After RESET, the default is for all chip selects to be

configured for the memory address space. For either the memory address space or the I/O

address space, the individual chip selects must be enabled by setting CSX_EN

(CSx_CTL[3]) to 1.

Memory Chip Select Operation

Operation of each of the memory chip select is controlled by three control registers. To

enable a particular memory chip select, the following conditions must be satisfied:

•

The chip select is enabled by setting CSx_EN to 1.

•

The chip select is configured for memory by clearing CSX_IO to 0.

•

The address is in the associated chip select range:

CSx_LBR[7:0] ≤ ADDR[23:16] ≤ CSx_UBR[7:0].

•

On-chip Flash is not configured for the same address space, because on-chip Flash is

prioritized higher than all memory chip selects.

•

On-chip RAM is not configured for the same address space, because on-chip RAM is

prioritized higher than Flash and all memory chip selects.

•

No higher priority (lower number) chip select meets the above conditions.

•

A memory access instruction must be executing.

If all the preceding conditions are satisfied to generate a memory chip select, then the fol-

lowing results occur:

•

The appropriate chip select—CS0, CS1, CS2, or CS3 is asserted (driven Low).

•

MREQ is asserted (driven Low).

•

Depending on the instruction either RD or WR is asserted (driven Low).

PS027001-0707 Chip Selects and Wait States

eZ80F91 ASSP

Product Specification

If the upper and lower bounds are set to the same value (CSx_UBR = CSx_LBR), then a

particular chip select is valid for a single 64 KB page.

Memory Chip Select Priority

A lower-numbered chip select is granted priority over a higher-numbered chip select. For

example, if the address space of chip select 0 overlaps the chip select 1 address space, then

chip select 0 is active. If the address range programmed for any chip select signal overlaps

with the address of internal memory, the internal memory is accorded higher priority. If

the particular chip select(s) are configured with an address range that overlaps with an

internal memory address and when the internal memory is accessed, the chip select signal

is not asserted.

Reset States

On RESET, chip select 0 is active for all addresses, because its Lower Bound register

resets to 00h and its Upper Bound register resets to FFh. All the other chip select Lower

and Upper Bound registers reset to 00h.

Memory Chip Select Example

The use of Memory chip selects is demonstrat ed in Figure 7on page 67. The associated

control register values are indicated in Table 18 on page 67. In this example, all 4 chip

selects are enabled and configured for memory addresses. Also, CS1 overlaps with CS0.

Because CS0 is prioritized higher than CS1, CS1 is not active for much of its defined

address space.

PS027001-0707 Chip Selects and Wait States

eZ80F91 ASSP

Product Specification

Figure 7. Example: Memory Chip Select

Table 18. Example: Register Values for Figure 7 Memory Chip Select

Chip

Select CSx_CTL[3]

CSx_EN CSx_CTL[4]

CSx_IO CSx_LBR CSx_UBR Description

CS0 1 0 00h 7Fh CS0 is enabled as a Memory chip

select. Valid addresses range from

000000h–7FFFFFh.

CS1 1 0 00h 9Fh CS1 is enabled as a Memory chip

select. Valid addresses range from

800000h–9FFFFFh.

CS2 1 0 A0h CFh CS2 is enabled as a Memory chip

select. Valid addresses range from

A00000h–CFFFFFh.

CS3 1 0 D0h FFh CS3 is enabled as a Memory chip

select. Valid addresses range from

D00000h–FFFFFFh.

Memory

Location

FFFFFFh

D00000h

CFFFFFh

A00000h

9FFFFFh

7FFFFFh

800000h

000000h

CS3_UBR = FFh

CS3_LBR = D0h

CS2_UBR = CFh

CS2_LBR = A0h

CS1_UBR = 9Fh

CS0_UBR = 7Fh

CS0_LBR = CS1_LBR = 00h

CS3 Active

3 MB Address Space

CS2 Active

3 MB Address Space

CS1 Active

2 MB Address Space

CS0 Active

8 MB Address Space

PS027001-0707 Chip Selects and Wait States

eZ80F91 ASSP

Product Specification

Input/Output Chip Select Operation

I/O chip selects will be active only when the CPU is performing I/O instructions. Because

the I/O space is separate from the memory space in the eZ80F91 device, a conflict

between I/O and memory addresses never occurs.

The eZ80F91 supports a 16-bit I/O address. The I/O chip select logic decodes the High

byte of the I/O address, ADDR[15:8]. Because the upper byte of the address bus,

ADDR[23:16], is ignored, the I/O devices are always accessed from memory mode (ADL

or Z80). The MBASE offset value used for setting the Z80 MEMORY mode page is also

always ignored.

Four I/O chip selects are available with the eZ80F91 device. To generate a particular I/O

chip select, the following conditions must be satisfied:

•

The chip select is enabled by setting CSx_EN to 1.

•

The chip select is configured for I/O by setting CSX_IO to 1.

•

An I/O chip select address match occurs—ADDR[15:8] = CSx_LBR[7:0].

•

No higher-priority (lower-number) chip select meets the above conditions.

•

The I/O address is not within the on-chip peripheral address range 0000h–00FFh.

On-chip peripheral registers assume priority for all addresses where:

0000h

≤

ADDR[15:0]

≤

00FFh

•

An I/O instruction must be executing.

If all of the foregoing conditions are met to generate an I/O chip select, then the following

results occur:

•

The appropriate chip select—CS0, CS1, CS2, or CS3 is asserted (driven Low).

•

IORQ is asserted (driven Low).

•

Depending on the instruction, either RD or WR is asserted (driven Low).

Wait States

For each of the chip selects, programmable Wait states are asserted to provide external

devices with additional clock cycles to complete their Read or Write operations. The

number of wait states for a particular chip select is controlled by the 3-bit field

CSx_WAIT (CSx_CTL[7:5]). The Wait states are independently prog rammed to provide 0

to 7 Wait states for each chip select. The Wait states idle the CPU for the specified number

of system clock cycles.

PS027001-0707 Chip Selects and Wait States

eZ80F91 ASSP

Product Specification

WAIT Input Signal

Similar to the programmable wait states, an external peripheral drives the WAIT input pin

to force the CPU to provide additional clock cycles to complete its Read or Write opera-

tion. Driving the WAIT pin Low stalls the CPU. The CPU resumes operation on the first

rising edge of the internal system clock following deassertion of the WAIT pin.

If the WAIT pin is to be driven by an external device, the corresponding chip select for

the device must be programmed to provide at least one wait state. Due to input sampling

of the WAIT input pin (see Figure 8), one programmable wait state is required to allow

the external peripheral sufficient time to assert the WAIT pin. It is recommended that

the corresponding chip select for the external device be programmed to provide the

maximum number of wait states (seven).

An example of wait state operation is illustrated in Figure 9 on page 70. In this example,

the chip select is configured to provide a single wait state. The external peripheral

accessed drives the WAIT pin Low to request assertion of an additional wait state. If the

WAIT pin is asserted for additional system clock cycles, wait states are added until the

WAIT pin is deasserted (active High).

Figure 8. Wait Input Sampling Block Diagram

Caution:

System Clock

Wait

Pin eZ80

CPU

PS027001-0707 Chip Selects and Wait States

eZ80F91 ASSP

Product Specification

Chip Selects During Bus Request/Bus Acknowledge Cycles

When the CPU relinquishes the address bus to an external peripheral in response to an

external bus request (BUSREQ), it drives the bus acknowledge pin (BUSACK) Low. The

external peripheral then drives the address bus (and data bus). The CPU continues to gen-

erate chip select signals in response to the address on the bus. External devices cannot

access the internal registers of the eZ80F91.

Bus Mode Controller

The bus mode controller allows the address and data bus timing and signal formats of the

eZ80F91 to be configured to connect with external devices compatible with eZ80®,

Z80(®), Intel™ and Motorola microcontrollers. Bus modes for each of the chip selects are

configured independently using the Chip Select Bus Mode Control Registers. The number

Figure 9. Example: Wait State Read Operation

TCLK TWAIT

SCLK

ADDR[23:0]

DATA[7:0]

(output)

CSx

MREQ

INSTRD

PS027001-0707 Chip Selects and Wait States

eZ80F91 ASSP

Product Specification

of CPU system clock cycles per bus mode state is also independently programmable. For

Intel bus mode, multiplexed address and data are selected in which both the lower byte of

the address and the data byte use the data bus, DATA[7:0]. Each of the bus modes are

explained in the following sections.

eZ80® Bus Mode

Chip selects configured for eZ80 bus mode do not modify the bus signals from the CPU.

The timing diagrams for external Memory and I/O Read and W rite operations are shown in

the AC Characteristics on page 348. The default mode for each chip select is eZ80 mode.

Z80 Bus Mode

Chip selects configured for Z80 mode modify the eZ80 bus signals to match the Z80 micro-

processor address and data bus interface signal format and timing. During Read operations,

the Z80 Bus mode employs three states—T1, T2, and T3 as described in Table 19.

During W rite operations, Z80 Bus mode employs 3 states—T1, T2, and T3 as described in

Table 20.

Table 19. Z80 Bus Mode Read States

STATE T1 The Read cycle begins in State T1. The CPU drives the address onto the address bus and

the associated chip select signal is asserted.

STATE T2 During State T2, the RD signal is asserted. Depending on the instruction, either the MREQ

or IORQ signal is asserted. If the external W A IT pin is driven Low at least one CPU system

clock cycle prior to the end of State T2, additiona l Wait states (TWAIT) are asserte d un til the

WAIT pin is driven High.

STATE T3 During State T3, no bus signals are altere d. The data is latched by the eZ80F91 at the ri sing

edge of the CPU system clock at the end of State T3.

Table 20. Z80 Bus Mode Write States

STATE T1 The Write cycle begins in State T1. The CPU drives the address onto th e address bus, and

the associated chip select signal is asserted.

STATE T2 During State T2, the WR signal is asserted. Depending upon the instruction, either the

MREQ or IORQ signal is asserted. If the external WAIT pin is driven Low at least one CPU

system clock cycle prior to the end of State T2, additional wait states (TWAIT) are asser te d

until the WAIT pin is driven High.

STATE T3 During State T3, no bus signals are altered.

PS027001-0707 Chip Selects and Wait States

eZ80F91 ASSP

Product Specification

Z80 bus mode Read and W rit e timing is illustrated in Figu re 10 and Figure 11 on page 73.

The Z80 bus mode states are configured for 1 to 15 CPU system clock cycles. In the fig-

ures, each Z80 bus mode state is two CPU system clock cycles in duration. The figures

also illustrate the assertion of 1 wait state (TWAIT) by the external peripheral during each

Z80 bus mode cycle.

Figure 10. Example: Z80 Bus Mode Read Timing

System Clock

ADDR[23:0]

DATA[7:0]

CSx

MREQ

or IORQ

WAIT

TCLK

T1 T2 T3

PS027001-0707 Chip Selects and Wait States

eZ80F91 ASSP

Product Specification

Intel Bus Mode

Chip selects configured for Intel bus mode modify the CPU bus signals to duplicate a

four-state memory transfer similar to that found on Intel-style microcontrollers. The bus

signals and eZ80F91 pins are mapped as illustrated in Figure 12 on page 74. In Intel bus

mode, you select either multiplexed or nonmultiplexed address and data buses. In

nonmultiplexed operation, the address and data buses are separate. In multiplexed

operation, the lower byte of the address, ADDR[7:0], also appears on the data bus,

DATA[7:0], during State T1 of the Intel bus mode cycle.

Figure 11. Example: Z80 Bus Mode Write Timing

System Clock

ADDR[23:0]

DATA[7:0]

CSx

MREQ

or IORQ

WAIT

TCLK

T1 T2 T3

PS027001-0707 Chip Selects and Wait States

eZ80F91 ASSP

Product Specification

Intel Bus Mode—Separate Address and Data Buses

During Read operations with separate address and data buses, the Intel bus mo de employs

4 states—T1, T2, T3, and T4 as described in Table 21.

Figure 12. Intel Bus Mode Signal and Pin Mapping

Table 21. Intel Bus Mode Read States—Separate Address and Data Buses

STATE T1 The Read cycle begins in State T1. The CPU drives the address onto the address bus and

the associated chip select signal is asserted. The CPU drives the ALE signal High at the

beginning of T1. In the middle of T1, the CPU drives ALE Low to facilitate the latching of the

address.

STATE T2 During State T2, the CPU asserts the RD signal. Depending on the instruction, either the

MREQ or IORQ signal is asserted.

eZ80 Bus Mode

Signals (Pins)

INSTRD

WAIT

MREQ

IORQ

ADDR[23:0]

DATA[7:0] Multiplexed

Bus

Controller

ADDR[7:0]

Intel Bus

Signal Equvalents

ALE

READY

MREQ

IORQ

ADDR[23:0]

DATA[7:0]

Bus Mode

Controller

PS027001-0707 Chip Selects and Wait States

eZ80F91 ASSP

Product Specification

During W rite operations with separate address and data buses, the Intel bus mode employs

4 states—T1, T2, T3, and T4 as described in Table 22.

Intel bus mode timing is illustrated for a Read operation in Figure 13 on page 76 and for a

Write operation in Figure 14 on page 76. If the READY si gnal (external WAIT pin) is

driven Low prior to the beginning of State T3, additional wait states (TWAIT) are asserted

until the READY signal is driven High. The Intel bus mode states are configured for 2 to

15 CPU system clock cycles. In the Figure 13 on page 76 and Figure 14 on page 77, each

Intel bus mode state is 2 CPU system clock cycles in duration. Figure 13 on page 76 and

Figure 14 on page 77 also illustrate the assertion of one Wait state (T WAIT) by the selected

peripheral.

STATE T3 During State T3, no bus signals are altered. If the external READY (WAIT) pin is driven Low

at least one CPU system clock cycle prior to the beg inning of State T3, additional wait st ates

(TWAIT) are asserted until the READY pin is driven High.

STATE T4 The CPU latches the Read data at the beginning of State T4. The CPU deasserts the RD

signal and completes the Intel bus mode cycle.

Table 22. Intel Bus Mode Write States—Separate Address and Data Buses

STATE T1 The Write cycle begins in State T1. The CPU drives the address onto the address bus, the

associated chip select signal is asserted, and the data is driven onto the data bus. Th e CPU

drives the ALE signal High at the beginning of T1. During the middle of T1, the CPU drives

ALE Low to facilitate the latching of the address.

STATE T2 During State T2, the CPU asserts the WR signal. Depending on the instruction, either the

MREQ or IORQ signal is asserted.

STATE T3 During State T3, no bus signals are altered. If the external READY (WAIT) pin is driven Low

at least one CPU system clock cycle prior to the beg inning of State T3, additional wait st ates

(TWAIT) are asserted until the READY pin is driven High.

STATE T4 The CPU deasserts the WR signal at the beginning of State T4. The CPU holds the data

and address buses till the end of T4. The bus cycle is completed at the end of T4.

Table 21. Intel Bus Mode Read States—Separate Address and Data Buses (Continued)

PS027001-0707 Chip Selects and Wait States

eZ80F91 ASSP

Product Specification

Figure 13. Example: Intel Bus Mode Read Timing—Separate Address and Data Buses

System Clock

ADDR[23:0]

DATA[7:0]

CSx

MREQ

or IORQ

ALE

TWAIT

READY

T1 T2 T3 T4

PS027001-0707 Chip Selects and Wait States

eZ80F91 ASSP

Product Specification

Figure 14. Example: Intel Bus Mode Write Timing—Separate Address and Data Buses

System Clock

ADDR[23:0]

DATA[7:0]

CSx

MREQ

or IORQ

ALE

WAIT

READY

T1 T2 T3 T4

PS027001-0707 Chip Selects and Wait States

eZ80F91 ASSP

Product Specification

Intel™ Bus Mode—Multiplexed Address and Data Bus

During Read operations with multiplexed addr ess and data, the Intel™ bus mode employs

4 states—T1, T2, T3, and T4 as described in Table 23.

During W rite operations with multiplexed address and data, the Intel™ bus mode empl oys

4 states—T1, T2, T3, and T4 as described in Table 24.

Signal timing for Intel bus mode with multiplexed address and data is illustrated for a

Read operation in Figure 15 on page 79 and for a W rite op eration in Figure 16 on page 80.

In Figure 15 on page 79 and Figure 16 on page 80, each Intel bus mode state is 2 CPU sys-

tem clock cycles in duration. Figure 15 on page 79 and Figure 16 on page 80 also illustrate

the assertion of one wait state (TWAIT) by the selected peripheral.

Table 23. Intel Bus Mode Read States—Multiplexed Address and Data Bus

STATE T1 The Read cycle begins in State T1. The CPU drive s the address onto the DATA b us and the

associated chip select signal is asserted. The CPU drives the ALE signal High at the

beginning of T1. In the middle of T1, the CPU drives ALE Low to facilitate the latching of the

address.

STATE T2 During State T2, the CPU removes the address from the DATA bus and asserts the RD

signal. Depending upon the instruction, either the MREQ or IORQ signal is asserted.

STATE T3 During State T3, no bus signals are altered. If the external READY (WAIT) pin is driven Low

at least one CPU system clock cycle prior to the beg inning of State T3, additional wait st ates

(TWAIT) are asserted until the READY pin is driven High.

STATE T4 The CPU latches the Read data at the beginning of State T4. The CPU deasserts the RD

signal and completes the Intel™ bus mode cycle.

Table 24. Intel Bus Mode Write States—Multiplexed Address and Data Bus

STATE T1 The Write cycle begins in State T1. The CPU drives the addre ss onto the DATA bus and

drives the ALE signal High at the beginning of T1. During the middle of T1, the CPU drives

ALE Low to facilitate the latching of the address.

STATE T2 During State T2, the CPU removes the address from the DATA bus and drives the Write

data onto the DATA bus. The WR signal is asserted to indicate a Write operation.

STATE T3 During State T3, no bus signals are altered. If the external READY (WAIT) pin is driven Low

at least one CPU system clock cycle prior to the beg inning of State T3, additional wait st ates

(TWAIT) are asserted until the READY pin is driven High.

STATE T4 The CPU deasserts the Write signal at the beginning of T4 identifying the end of the Write

operation. The CPU hold s the data and addr ess buses through the end of T4. The b us cycle

is completed at th e en d of T4.

PS027001-0707 Chip Selects and Wait States

eZ80F91 ASSP

Product Specification

Figure 15. Example: Intel Bus Mode Read Timing—Multiplexed Address and Data Bus

DATA[7:0]

System Clock

ADDR[23:0]

CSx

MREQ

or IORQ

ALE

TWAIT

READY

T1 T2 T3 T4

PS027001-0707 Chip Selects and Wait States

eZ80F91 ASSP

Product Specification

Motorola Bus Mode

Chip selects configured for Motorola bus mode modify the CPU bus signals to duplicate

an eight-state memory transfer similar to that on the Motorola-style microcontrollers. The

bus signals (and eZ80F91 I/O pins) are mapped as illustrated in Figure 17 on page 81.

Figure 16. Example: Intel Bus Mode Write Timing—Multiplexed Address and Data Bus

System Clock

ADDR[23:0]

DATA[7:0]

CSx

MREQ

or IORQ

ALE

WAIT

READY

T1 T2 T3 T4

PS027001-0707 Chip Selects and Wait States

eZ80F91 ASSP

Product Specification

During Write operations, the Motorola bus mode employs 8 states—S0, S1, S2, S3, S4,

S5, S6, and S7 as described in Table 25.

Figure 17. Motorola Bus Mode Signal and Pin Mapping

Table 25. Motorola Bus Mode Read States

STATE S0 The Read cycle starts in state S0. The CPU drives R/W High to identify a Read cycle.

STATE S1 Entering state S1, the CPU drives a valid address on the address bus, ADDR[23:0].

STATE S2 On the rising edge of state S2, the CPU asserts AS and DS.

STATE S3 During state S3, no bus signals are altered.

STATE S4 During state S4, the CPU waits for a cycle termination signal DTACK (WAIT), a peripheral

signal. If the termination signal is not asserted at least one full CPU clock period prior to the

rising clock edge at the end of S4, the CPU inserts WAIT (TWAIT) states until DTACK is

asserted. Each wait state is a full bus mode cycle.

STATE S5 During state S5, no bus signals are altered.

eZ80 Bus Mode

Signals (Pins)

INSTRD

WAIT

MREQ

IORQ

ADDR[23:0]

DATA[7:0]

Motorola Bus

Signal Equvalents

R/W

DTACK

MREQ

IORQ

ADDR[23:0]

DATA[7:0]

Bus Mode

Controller

PS027001-0707 Chip Selects and Wait States

eZ80F91 ASSP

Product Specification

The eight states for a Write operation in Motorola bus mode are described in Table 26.

Signal timing for Motorola bus mode is illustrated for a Read operation in Figure 18 on

page 83 and for a Write operation in Figure 19 on page 84. In these two figures, each

Motorola bus mode state is 2 CPU system clock cycles in duration.

STATE S6 During state S6, data from the external peripheral device is driven onto the data bus.

STATE S7 On the rising edge of the clock entering state S7, the CPU latches data from the addressed

peripheral device and deasserts AS and DS. The peripheral device deasserts DTACK at

this time.

Table 26. Motorola Bus Mode Write States

STATE S0 The Write cycle starts in S0. The CPU drives R/W High (if a p receding Write cycle le aves R/

W Low).

STATE S1 Entering S1, the CPU drives a valid address on the address bus.

STATE S2 On the rising edge of S2, the CPU asserts AS and drives R/W Low.

STATE S3 During S3, the data bus is driven out o f the high-impedance state as the data to be written is

placed on the bu s.

STATE S4 At the rising edge of S4, the CPU asserts DS. The CPU waits for a cycle termination signal

DTACK (WAIT). If the termination signal is not asserted at least one full CPU clock period

prior to the rising clock edge at the end of S4, the CPU inserts WAIT (TWAIT) states until

DTACK is asserted. Each wait state is a full bus mode cycle.

STATE S5 During S5, no bus signals are altered.

STATE S6 During S6, no bus signals are altered.

STATE S7 On entering S7, the CPU deasserts AS and DS. As the clock rises at the end of S7, the CPU

drives R/W High. The peripheral device deasserts DTACK at this time.

Table 25. Motorola Bus Mode Read States (Continued)

PS027001-0707 Chip Selects and Wait States

eZ80F91 ASSP

Product Specification

Figure 18. Example: Motorola Bus Mode Read Timing

System Clock

ADDR[23:0]

DATA[7:0]

CSx

MREQ

or IORQ

DTACK

R/W

S0 S1 S2 S4 S6

S5 S7

PS027001-0707 Chip Selects and Wait States

eZ80F91 ASSP

Product Specification

Switching Between Bus Modes

When switching bus modes between Intel™ to Motorola, Motorola to Intel™, eZ80 to

Motorola, or eZ80 to Intel™, there is one extra SCLK cycle added to the bus access. An

extra clock cycle is not required for repeated access in any of the bus modes (for example,

Intel™ to Intel™). An extra clock cycle is not required for Intel™ (or Motorola) to eZ80

bus mode (under normal operation). The extra clock cycle is not shown in the timing

examples. Due to the asynchronous nature of these bus protocols, the extra delay does not

impact peripheral communication.

Figure 19. Example: Motorola Bus Mode Write Timing

System Clock

ADDR[23:0]

DATA[7:0]

CSx

MREQ

or IORQ

DTACK

R/W

S0 S1 S2 S4 S6

S5 S7

PS027001-0707 Chip Selects and Wait States

eZ80F91 ASSP

Product Specification

Chip Select Registers

Chip Select x Lower Bound Register

For Memory chip selects, the chip select x Lower Bound register (see Table 27) defines

the lower bound of the address range for which the corresponding Memory chip select (if

enabled) is active. For I/O chip selects, the chip select x Lower Bound register defines the

address to which ADDR[15:8] is compa red to generate an I/O chip select. All chip select

lower bound registers reset to 00h.

Table 27. Chip Select x Lower Bound Register (CS0_LBR = 00A8h, CS1_LBR = 00ABh,

CS2_LBR = 00AEh, CS3_LBR = 00B1h)

Bit 76543210

CS0_LBR Reset 00000000

CS1_LBR Reset 00000000

CS2_LBR Reset 00000000

CS3_LBR Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit

Position Value Description

[7:0]

CSX_LBR 00h–

FFh For Memory Chip Selects (CSx_IO = 0)

This byte specifies the lower bound of the chip select address

range. The upper byte of the address bus, ADDR[23:16], is

compared to the values contained in these registers for

determining whether a Memory chip select signal must be

generated.

For I/O Chip Selects (CSx_IO = 1)

This byte specifies the chip select address value. ADDR[15:8] is

compared to the values contained in these registers for

determining whether an I/O chip select signal must be generated.

PS027001-0707 Chip Selects and Wait States

eZ80F91 ASSP

Product Specification

Chip Select x Upper Bound Register

For Memory chip selects, the Chip Select x Upper Bound registers, detailed in Table 28,

defines the upper bound of the address range for which the corresponding Chip Select (if

enabled) are active. For I/O chip selects, this register produces no effect. The reset state for

the Chip Select 0 Upper Bound register is FFh when the reset state for the other Chip

Select Upper Bound registers is 00h.

Table 28. Chip Select x Upper Bound Register (CS0_UBR = 00A9h, CS1_UBR = 00ACh,

CS2_UBR = 00AFh, CS3_UBR = 00B2h)

Bit 76543210

CS0_UBR Reset 11111111

CS1_UBR Reset 00000000

CS2_UBR Reset 00000000

CS3_UBR Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit

Position Value Description

[7:0]

CSX_UBR 00h–

FFh For Memory Chip Selects (CSx_IO = 0)

This byte specifies the upper bound of the chip select address

range. The upper byte of the address bus, ADDR[23:16], is

compared to the values contained in these registers for

determining whether a chip select signal must be generated.

For I/O Chip Selects (CSx_IO = 1)

No effect.

PS027001-0707 Chip Selects and Wait States

eZ80F91 ASSP

Product Specification

Chip Select x Control Register

The Chip Select x Control register (see Table 29) enables the chip selects, specifies the

type of chip select, and sets the number of wait states. The reset state for the Chip Select 0

Control register is E8h when the re set state for t he 3 other Chip Select Control registers is

00h.

Table 29. Chip Select x Control Register (CS0_CTL = 00AAh, CS1_CTL = 00ADh,

CS2_CTL = 00B0h, CS3_CTL = 00B3h)

Bit 76543210

CS0_CTL Reset 11101000

CS1_CTL Reset 00000000

CS2_CTL Reset 00000000

CS3_CTL Reset 00000000

CPU Access R/W R/W R/W R/W R/W R R R

Note: R/W = Read/Write; R = Read Only.

Bit

Position Value Description

[7:5]

CSX_WAIT 000 0 wait states are asserted when this chip select is active.

001 1 wait state is asserted when this chip select is active.

010 2 wait states are asserted when this chip select is active.

011 3 wait states are asserted when this chip select is active.

100 4 wait states are asserted when this chip select is active.

101 5 wait states are asserted when this chip select is active.

110 6 wait states are asserted when this chip select is active.

111 7 wait states are asserted when this chip select is active.

CSX_IO 0 Chip select is configured as a memory chip select.

1 Chip select is configured as an I/O chip select.

CSX_EN 0 Chip select is disabled.

1 Chip select is enabled.

[2:0] 000 Reserved.

PS027001-0707 Chip Selects and Wait States

eZ80F91 ASSP

Product Specification

Chip Select x Bus Mode Control Register

The Chip Select Bus Mode register (see Table 30) configures the chip select for eZ80,

Z80, Intel™, or Motorola bus modes. Changing the bus mode allows the eZ80F91 device

to interface to peripherals based on the Z80, Intel™, or Motorola style asynchronous bus

interfaces. When a bus mode other than eZ80 is programmed for a particular chip select,

the CSx_WAIT setting in that Chip Select Control Register is ignored.

Table 30. Chip Select x Bus Mode Control Register (CS0_BMC = 00F0h, CS1_BMC =

00F1h, CS2_BMC = 00F2h, CS3_BMC = 00F3h)

Bit 76543210

CS0_BMC Reset 00000010

CS1_BMC Reset 00000010

CS2_BMC Reset 00000010

CS3_BMC Reset 00000010

CPU Access R/W R/W R/W R R/W R/W R/W R/W

Note: R/W = Read/Write; R = Read Only.

Bit

Position Value Description

[7:6]

BUS_MODE 00 eZ80 bus mode

01 Z80 bu s mo de

10 Intel™ bus mode

11 Motorola bus mode

AD_MUX 0 Separat e ad dr ess and data

1 Multiplexed address and data—appears on data bus

DATA[7:0]

40Reserved

PS027001-0707 Chip Selects and Wait States

eZ80F91 ASSP

Product Specification

Bus Arbiter

The Bus Arbiter within the eZ80F91 allows external bus masters to gain control of the

CPU memory interface bus. During normal operation, the eZ80F91 device is the bus mas-

ter. External devices request master use of the bus by asserting the BUSREQ pin. The Bus

Arbiter forces the CPU to release the bus after completing the current instruction. When

the CPU releases the bus, the Bus Arbiter asserts the BUSACK pin to notify the external

device that it can master the bus. When an external device assumes control of the memory

interface bus, the bus acknowledge cycle is complete. Table 31 on page 90 shows the sta-

tus of the pins on the eZ80F91 device during bus acknowledge cycles.

During a bus acknowledge cycle, the bus interface pins of the eZ80F91 device are used by

an external bus master to control the memory and I/O chip selects.

[3:0]

BUS_CYCLE 0000 Not valid.

0001 Each bus mode state is 1 eZ80 clock cycle in duration.1, 2, 3

0010 Each bus mode state is 2 eZ80 clock cycles in duration.

0011 Each bus mode state is 3 eZ80 clock cycles in duration.

0100 Each bus mode state is 4 eZ80 clock cycles in duration.

0101 Each bus mode state is 5 eZ80 clock cycles in duration.

0110 Each bus mode state is 6 eZ80 clock cycles in duration.

0111 Each bus mode state is 7 eZ80 clock cycles in duration.

1000 Each bus mode state is 8 eZ80 clock cycles in duration.

1001 Each bus mode state is 9 eZ80 clock cycles in duration.

1010 Each bus mode state is 10 eZ80 clock cycles in duration.

1011 Each bus mode state is 11 eZ80 clock cycles in duration.

1100 Each bus mode state is 12 eZ80 clock cycles in duration.

1101 Each bus mode state is 13 eZ80 clock cycles in duration.

1110 Each bus mode state is 14 eZ80 clock cycles in duration.

1111 Each bus mode state is 15 eZ80 clock cycles in duration.

Notes

1. Setting the BUS_CYCLE to 1 in Intel bus mode causes the ALE pin to not function properly.

2. Use of the external WAIT input pin in Z80 mode requires that BUS_CYCLE is set to a value

greater than 1.

3. BUS_CYCLE produces no effect in eZ80 mode.

Bit

Position Value Description

PS027001-0707 Chip Selects and Wait States

eZ80F91 ASSP

Product Specification

Normal bus operation of the eZ80F91 device using CS0 to communicate to an external

peripheral is illustrated in Figure 20 on page 91. Figure 21 on page 91 illustrates an exter-

nal bus master communicating with an external peripheral during bus acknowledge cycles.

Table 31. eZ80F91 Pin Status During Bus Acknowledge Cycles

Pin Symbol Signal Direction Description

ADDR23..ADDR0 Input Allows external bus master to utilize the chip

select logic of the eZ80F91.

CS0 Output Normal oper at ion .

CS1 Output Normal oper at ion .

CS2 Output Normal oper at ion .

CS3 Output Normal oper at ion .

DATA7..0 Tristate Allows external bus master to communicate

with external periphe rals.

IORQ Input Allows external bus master to utilize the chip

select logic of the eZ80F91.

MREQ Input Allows external bus master to utilize the chip

select logic of the eZ80F91.

RD Tristate Allows external bus master to communicate

with external periphe rals.

WR Tristate Allows external bus master to communicate

with external periphe rals.

INSTRD Tristate Allows external bus master to communicate

with external periphe rals.

PS027001-0707 Chip Selects and Wait States

eZ80F91 ASSP

Product Specification

During bus acknowledge cycles, the Memory and I/O chip select logic is controlled by the

external addres s bu s an d ext ern al IORQ and MREQ signals.

Figure 20. Memory Interface Bus Operation During CPU Bus Cycles, Normal Operation

Figure 21. Memory Interface Bus Operation During Bus Acknowledge Cycles

WAIT

DATA

ADDRESS

IORQ

MREQ

CS0

CS1

CS2

CS3

External

Master

External

Peripheral

eZ80F91

Chip Select

Wait State

Generator

WAIT

DATA

ADDRESS

IORQ

MREQ

CS0

CS1

CS2

CS3

External

Master External

Peripheral

eZ80F91

Chip Select

Wait State

Generator

PS027001-0707 Chip Selects and Wait States

eZ80F91 ASSP

Product Specification

The following chip se le c t featu r e s are not av aila b l e dur ing bus acknowledg e cy c l es :

•

The chip select logic does not insert wait states during bus acknowledge cycles regard-

less of the WAIT configuration for the decoded chip select.

•

The bus mode controller does not function during bus acknowledge cycles.

•

Internal registers and memory addresses in the eZ80F91 device are not accessible dur-

ing bus acknowledge cycles.

PS027001-0707 Random Access Memory

eZ80F91 ASSP

Product Specification

Random Access Memory

The eZ80F91 device features 8 KB (8192 bytes) of single-port data Random Access

Memory (RAM) for general-purpose use and 8 KB of RAM for the EMAC. RAM is

enabled or disabled, and it is relocated to the top of any 64 KB page in memory. Data is

passed to and from RAM via the 8-bit data bus. On-chip RAM ope r ates with zero wait

states. EMAC RAM is accessed via the bus arbiter and executes with zero or one Wait

states.

General purpose RAM occupies memory addresses in the RAM Address Upper Byte reg-

ister in the range {RAM_ADDR_U[7:0], E000h} to {RAM_ADDR_U[7:0], FFFFh}.

EMAC RAM occupies memory addresses in the range {RAM_ADDR_U[7:0], C000h}

to {RAM_ADDR_U[7:0], DFFFh}. Following a RESET, RAM is enabled when

RAM_ADDR_U is set to FFh. Figure 22 illustrates a memory map for on-chip RAM. In

this example, RAM_ADDR_U is set to 7Ah. Figure 22 is not drawn to scale, as RAM

occupies only a very small fraction of the available 16 MB address space.

When enabled, on-chip RAM assumes priority over on-chip Flash memory and any mem-

ory chip selects that is also enabled in the same address space. If an address is generated in

a range that is covered by both the RAM address space and a particular memory chip

Figure 22. Example: eZ80F91 On-Chip RAM Memory Addressing

Memory

Location

FFFFFFh

7AFFFFh

7AE000h RAM_ADDR_U

7Ah

7ADFFFh

7AC000h

000000h

8 KB

General-Purpose

RAM

8 KB

EMAC SRAM

PS027001-0707 Random Access Memory

eZ80F91 ASSP

Product Specification

select address space, the memory chip select is not activated. On-chip RAM is not accessi-

ble to external devices during bus acknowledge cycles.

RAM Control Registers

RAM Control Register

Internal general purpose RAM is disabled by clearing the GPRAM_EN bit. The default on

RESET is for general purpose RAM to be enabled. See Table 32.

Table 32. RAM Control Register (RAM_CTL = 00B4h)

Bit 76543210

Reset 11000000

CPU Access R/WR/WRRRRRR

Note: R/W = Read/Write; R = Read Only.

Bit

Position Value Description

GPRAM_EN 0 On-chip general-purpose RAM is disabled.

1 On-chip general-purpose RAM is enabled.

ERAM_EN 0 On-chip EMAC RAM is disabled.

1 On-chip EMAC RAM is enabled.

[5:0] 000000 Reserved

PS027001-0707 Random Access Memory

eZ80F91 ASSP

Product Specification

RAM Address Upper Byte Register

The RAM_ADDR_U register defines the upper byte of the address for on-chip RAM.

If enabled, RAM addresses assume priority over all Chip Selects. The external Chip Select

signals are not asserted if the corresponding RAM address is enabled. See Table 33.

Table 33. RAM Address Upper Byte Register (RAM_ADDR_U = 00B5h)

Bit 76543210

Reset 11111111

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit

Position Value Description

[7:0]

RAM_ADDR_U 00h–

FFh This byte defines the upper byte of the RAM address. When

enabled, the general-purpose RAM address space ranges from

{RAM_ADDR_U, E000h} to {RAM_ADDR_U, FFFFh}. When

enabled, the EMAC RAM address space ranges from

{RAM_ADDR_U, C000h} to {RAM_ADDR_U, DFFFh}.

PS027001-0707 Random Access Memory

eZ80F91 ASSP

Product Specification

MBIST Control

There are two Memory Built-In Self-Test (MBIST) controllers for the RAM blocks on the

eZ80F91. MBIST_GPR is for General Purpose RAM and MBIST_EMR is for EMAC

RAM. Writing a 1 to MBIST_ON starts the MBIST testing. Writing a 0 to MBIST_ON

stops the MBIST testing. On completion of the MBIST testing, MBIST_ON is

automatically reset to 0. If RAM passes MBIST testing, MBIST_PASS is 1. The value in

MBIST_PASS is only valid when MBIST_DONE is High. See Table 34.

Table 34. MBIST Control Register (MBIST_GPR = 00B6h, MBIST_EMR = 00B7h)

Bit 76543210

Reset 00000000

CPU Access R/WRRRRRRR

Note: R/W = Read/Write; R = Read Only.

Bit Position Value Description

MBIST_ON 0 MBIST Testing of the RAM is disabled.

1 MBIST Testing of the RAM is enabled.

MBIST_DONE 0 MBIST Testing has not completed.

1 MBIST Testing has completed.

MBIST_PASS 0 MBIST Testing has failed.

1 MBIST Testing has passed.

[4:0] 00000 Reserved

PS027001-0707 Flash Memory

eZ80F91 ASSP

Product Specification

Flash Memory

The eZ80F91 device features 256 KB (262,144 bytes) of non-volatile Flash memory with

Read/Write/Erase capability. The main Flash memory array is arranged in 128 pages with

8 rows per page and 256 bytes per row. In addition to main Flash memory, there are two

separately addressable rows which comprise a 512-byte information page.

In eight 32 KB blocks, 256 KB of main storage is protected. Protecting a 32 KB block

prevents Write or Erase operations. The lower 32 KB block (00000h

–

07FFFh) is pro-

tected using the external WP pin. T his portion of memory is called the Bo ot block because

the CPU always starts executing code from this location at startup. If the application

requires external program memory, then the Boot block must at least contain a jump

instruction to move the Program Counter outside of the Flash memory space.

The Flash memory arrangement is illustrated in Figure 23.

Figure 23. eZ80F91 Flash Memory Arrangement

32 KB blocks

2 KB pages

per block

256-byte rows

per page

256

single-byte columns

per row

0255 254 1 0

PS027001-0707 Flash Memory

eZ80F91 ASSP

Product Specification

Flash Memory Overview

The eZ80F91 device includes a Flash memory controller that automatically converts

standard CPU Read and Write cycles to the specific protocol required for the Flash

memory array. As such, standard memory Read and Write instructions access the Flash

memory array as if it is internal RAM. The controller also supports I/O access to the Flash

memory array, in effect presenting it as an indirectly addressable bank of I/O registers.

These access methods are also supported via the ZDI and OCI™ interfaces.

In addition, eZ80AcclaimPlus!™ Flash Microcontrollers support a Flash Read–While–

Write methodology. In other words, the eZ80 CPU co ntin ue s to read and ex ec u t e co de

from an area of Flash memory when a nonconflicting area of Flash memory is being pro-

grammed.

The Flash memory controller contains a frequency divider , a Flash register interface, and a

Flash control state machine. A simplified block diagram of the Flash controller is

illustrated in Figure 24.

Reading Flash Memory

The main Flash memory array is read using both memory and I/O operations. As an auxil-

iary storage area, the information page is only accessible via I/O operations. In all cases,

Wait states are automatically inserted to allow for read access time.

Figure 24. Flash Memory Block Diagram

FLASH_IRQ

System Clock

eZ80 Core

Interface

ADDR

CPUD

FADDR

OUT

817

OUT

FCNTL

MAIN_INFO

Clock Divider

8-bit downcounter

Flash

Control

Registers

Flash

State

Machine

Flash

256 KB

512 bytes

PS027001-0707 Flash Memory

eZ80F91 ASSP

Product Specification

Memory Read

A memory Read operation uses the address bus and data bus of the eZ80F91 device to

read a single data byte from Flash memory. This Read operation is similar to reads from

RAM. To perform Flash memory reads, the FLASH_CTRL register must be configured to

enable memory access to Flash with the appropriate number of wait states. See Table 38

on page 105.

Only the main area of Flash memory is accessible via memory reads. The information

page must be read using I/O access.

I/O Read

A single-byte I/O Read operation uses I/O registers for setting the column, page, and row

address to be read. A Read of the FLASH_DATA register returns the contents of Flash

memory at the designated address. Each access to the FLASH_DATA register causes an

autoincrement of the Flash address stored in the Flash address registers (FLASH_PAGE,

FLASH_ROW, FLASH_COL). To allow for Flash memory access time, the

FLASH_CTRL register must be configured with the appropriate number of wait states.

See Table 38 on page 105.

Programming Flash Memory

Flash memory is programmed using standard I/O or memory Write operations that the

Flash memory controller automatically translates to the detailed timing and protocol

required for Flash memory. The more efficient multibyte (ro w) programming mode is only

available via I/O Writes.

To ensure data integrity and device rel iability, two main restrictions exist on programming

of Flash memory:

1. The cumulative programming time since the last erase cannot

exceed 31 ms for any given row.

2. The same byte canno t be programmed more than once since the last erase.

Single-Byte I/O Write

A single-byte I/O Write operation uses I/O registers for setting the column, page, and row

address to be written. The FLASH_DATA register stores the data to be written. While the

CPU executes an I/O instruction to load the data into the FLASH_DATA register, the

Flash controller asserts the internal WAIT signal to stall the CPU until the Flash Write

operation is complete. A single-byte Write takes between 66 µs and 85 µs to complete.

Programming an entire row (256 bytes) using single-byte Writes therefore takes no more

than 21.8 ms. This duration of time does not include the time required by the CPU to

transfer data to the registers which is a function of the instructions employed and the

system clock frequency. Each access to the FLASH_DATA register causes an

Note:

PS027001-0707 Flash Memory

eZ80F91 ASSP

Product Specification

100

autoincrement of the Flash address stored in the Flash Address registers (FLASH_PAGE,

FLASH_ROW, FLASH_COL).

A typical sequence that performs a single-byte I/O Write is shown below. Because the

Write is self-timed, step 2 of the seq uence is repeated back-to -back withou t requiring poll-

ing or interrupts.

1. Write the FLASH_PAGE, FLASH_ROW, and FLASH_COL registers with the

address of the byte to be written.

2. Write the data value to the FLASH_DATA register.

Multibyte I/O Write (Row Programming)

Multibyte I/O Write operations use the same I/O registers as single-byte Writes.

Multibyte I/O Writes allow the programming of full row and are enabled by setting the

ROW_PGM bit of the Flash Program Control Register. For multibyte I/O W rites, the CPU

sets the address registers, enables row programming, and then executes an I/O instruction

(with repeat) to load the block of data into the FLASH_DATA register . For each individual

byte written to the FLASH_DATA register during the block move, the Flash controller

asserts the internal WAIT signal to stall the CPU until the current byte is programmed.

Each access to the FLASH_DATA register causes an autoincrement of the Flash address

stored in the Flash Address registers (FLASH_PAGE, FLASH_ROW, FLASH_COL).

During row programming, the Flash controller continuously asserts the Flash memory’s

high voltage signal until all bytes are programmed (column address < 255). As a result, the

row programs more quickly than if the high-voltage signal is toggled for each byte. The

per -byte programming time during row programming is between 41 µs and 52 µs. As such,

programming 256 bytes of a row in this mode takes not more than 13.4 ms, leaving 17.6

ms for CPU instruction overhead to fetch the 256 bytes.

A typical sequence that performs a multibyte I/O Write is shown below:

1. Check the FLASH_IRQ register to ensure that any previous row program is

completed.

2. Write the FLASH_PAGE, FLASH_ROW, and FLASH_COL registers with the

address of the first byte to be written.

3. Set the ROW_PGM bit in the FLASH_PGCTL register to enable row programming

mode.

4. Write the next data value to the FLASH_DATA register.

5. If the end of the row has not been reached, return to step 4.

During row programming, software must monitor the row time-out error bit either by

enabling this interrupt or via polling. If a row time-out occurs, the Flash controller aborts

the row programming operation, and software must assure that no further Writes are

performed to the row without it first being erased. It is suggested that row programmi ng is

be used one time per row and not in combination with single-byte Writes to the same row

PS027001-0707 Flash Memory

eZ80F91 ASSP

Product Specification

101

without first erasing it. Otherwise, the burden is on software to ensure that the 31 ms

maximum cumulative programming time between erases is not exceeded for a row.

Memory Write

A single-byte memory Write operation uses the address bus and data bus of the eZ80F91

device for programming a single data byte to Flash memory. While the CPU execut es a

Load instruction, the Flash controller asserts the internal WAIT signal to stall the CPU

until the Write is complete. A single-byte Write takes between 66 µs and 85 µs to

complete. Programming an entire row using memory Writes therefore takes no more than

21.8 ms. This duration of time does not include time required by the CPU to transfer data

to the registers, which is a function of the instructions employed and the system clock

frequency.

The memory Write function does not support multibyte row programming. Because mem-

ory Writes are self-timed, they are performed back-to-back without requiring polling or

interrupts.

Erasing Flash Memory

Erasing bytes in Flash memory returns them to a value of FFh. Both the MASS and PAGE

ERASE operations are self-timed by the Flash controller, leaving the CPU free to execute

other operations in parallel. The DONE status bit in the Flash Interrupt Control Register

are polled by software or used as an interrupt source to signal completion of an Erase oper-

ation. If the CPU attempts to access Flash memory while an erase is in progress, the Flash

controller forces a wait state until the Erase operation is completed.

Mass Erase

Performing a MASS ERASE operation on Flash memory erases all bits contained in the

main Flash memory array. The information page remains unaffected unless the

FLASH_PAGE register bit 7(INFO_EN) is set. This self-timed operation takes

approximately 200 ms to complete.

Page Erase

The smallest erasable unit in Flash memory is a page. The pages to be erased, whether they

are the 128 main Flash memo ry pages or the information pa ge, are determined by the set-

ting of the FLASH_PAGE register . This self-timed operation takes approximately 10 ms to

complete.

PS027001-0707 Flash Memory

eZ80F91 ASSP

Product Specification

102

Information Page Characteristics

As noted earlier, the information page is not accessible using memory access instructions

and must be accessed via the FLASH_DATA I/O register. The Flash Page Select Register

contains a bit which selects the information page for I/O access.

There are two ways to erase the information page. You must set the FLASH_PAGE regis-

ter(0x00FC) bit7(INFO_EN) and then you execute either a MASS ERASE (which also

erases the entire main Flash memory array) operation or a PAGE ERASE operation.

Flash Control Registers

The Flash Control Register interface contains all the registers used in Flash memory. The

definitions in this section describe each register.

Flash Key Register

Writing the two-byte sequence B6h, 49h in immediate succession to this register unlocks

the Flash Divider and Flash Write/Erase Protection registers. If these values are not

written by consecutive CPU I/O Writes (I/O reads and memory Read/Writes have no

effect), the Flash Divider and Flash Write/Erase Protection registers remain locked. This

prevents accidental overwrites of these critical Flash control register settings. Writing a

value to either the Flash Frequency Divider Register or the Flash Write/Erase Protec tion

Table 35. Flash Key Register (FLASH_KEY = 00F5h)

Bit 76543210

Reset 00000000

CPU Access WWWWWWWW

Note: W = Write Only.

Bit

Position Value Description

[7:0]

FLASH_KEY B6h,

49h Sequential Write operations of the values B6h, 49h to this

Write/Erase Pro tection registers.

PS027001-0707 Flash Memory

eZ80F91 ASSP

Product Specification

103

Flash Data Register

The Flash Data register stores the data values to be programmed into Flash memory via

I/O Write operations. An I/O read of the Flash Data register returns data from Flash

memory. The Flash memory address used for I/O access is de termined by the contents of

the page, row, and column registers. Each access to the FLASH_DATA register causes an

autoincrement of the Flash address stored in the Flash Address registers (FLASH_PAGE,

FLASH_ROW, FLASH_COL). See Table 36.

Table 36. Flash Data Register (FLASH_DATA = 00F6h)

Bit 76543210

Reset XXXXXXXX

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit Position Value Description

[7:0]

FLASH_DATA 00h-FFh Data value to be written to Flash memory during an I/O Write

operation, or the data value that is read in Flash memory ,

indicated by the Flash Add re ss registers (FLASH_ PAGE,

FLASH_ROW, FLASH_COL).

PS027001-0707 Flash Memory

eZ80F91 ASSP

Product Specification

104

Flash Address Upper Byte Register

The FLASH_ADDR_U register defines the upper 6 bits of the Flash memory address

space. Changing the value of FLASH_ADDR_U allows on-chip 256 KB Flash memory

to be mapped to any location within the 16 MB linea r address spac e of the eZ80F91

device. If on-chip Flash memory is enabled, the Flash address assumes priority over any

external Chip Selects. The external Chip Select signals are not asserted if the corre-

sponding Flash address is enabled. Internal Flash memory does not hold priority over

internal SRAM. See Table 37.

Table 37. Flash Address Upper Byte Register (FLASH_ADDR_U = 00F7h)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R R

Note: R/W = Read/Write; R = Read Only.

Bit Position Value Description

[7:2]

FLASH_ADDR_U 00h–FCh These bits define the upper byte of the Flash address.

When on-chip Flash is enabled, the Flash address space

begins at address {FLASH_ADDR_U, 00b, 0000h}. On-chip

Flash has priority over all external Chip Selects.

[1:0] 00 Reserved (enforces alignment on a 256 KB boundar y).

PS027001-0707 Flash Memory

eZ80F91 ASSP

Product Specification

105

Flash Control Register

The Flash Control register enables or disables memory access to Flash memory . I/O access

to the Flash control registers and to Flash memory is still possible while Flash memory

space access is disabled.

The minimum access time of internal Flash memory is 60 ns. The Flash Control Re gis-

ter must be configured to provide the appropriate number of wait states based on the sys-

tem clock frequency of the eZ80F91 device. Because the maximum SCLK frequency is

50 MHz (20 ns), the default on RESET is for four Wait states to be inserted for Flash

memory access (Flash memory ac cess + one eZ80® Bus Cycle = 60 ns + 20 ns = 80 ns;

80 ns ÷ 20 ns = 4 Wait states). See Table 38.

Table 38. Flash Control Register (FLASH_CTRL = 00F8h)

Bit 76543210

Reset 10001000

CPU Access R/W R/W R/W R R/W R R R

Note: R/W = Read/Write, R = Read Only.

Bit Position Value Description

[7:5]

FLASH_WAIT 000 0 wait states are inserted when the Flash is active.

001 1 wait state is inserted when the Flash is active.

010 2 wait states are inserted when the Flash is active.

011 3 wait states are inserted when the Flash is active.

100 4 wait states are inserted when the Flash is active.

101 5 wait states are inserted when the Flash is active.

110 6 wait states are inserted when the Flash is active.

111 7 wait states are inserted when the Flash is active.

[4] 0 Reserved.

[3]

FLASH_EN 0 Flash memory access is disabled.

1 Flash memory access is enabled.

[2:0] 000 Reserved.

PS027001-0707 Flash Memory

eZ80F91 ASSP

Product Specification

106

Flash Frequency Divider Register

The 8-bit frequency divider allows the programming of Flash memory over a range of

system clock frequencies. Flash is programmed with system clock frequencies ranging

from 154 kHz to 50 MHz. The Flash controller requires an input clock with a period that

falls within the range of 5.1−6.5 µs. The period of the Flash controller clock is set in the

Flash Frequency Divider Register. Writes to this register is allowed only after it is

unlocked via the FLASH_KEY regis te r. The Flash Frequency Divider Register value

required versus the system clock frequency is displayed in Table 39. System clock

frequencies outside of the ranges shown are not supported. Register values for the Flash

Frequency Divider are displayed in Table 40.

Table 39. Flash Frequency Divider Values

System Clock Frequency Flash Frequency Divider Value

154–196 kHz 1

308–392 kHz 2

462–588 kHz 3

616 kHz–50 MHz CEILING [System Clock Frequency (MHz) x 5.1 (µs)]*

Note: *The CEILING function rounds fractional values up to the next whole number. For example,

CEILING(3.01) is 4.

Table 40. Flash Frequency Divider Register (FLASH_FDIV = 00F9h)

Bit 76543210

Reset 00000001

CPU Access R/W* R/W* R/W* R/W* R/W* R/W* R/W* R/W

Note: R/W = Read/Write, R = Read Only. *Key sequence required to enable Writes

Bit Position Value Description

[7:0]

FLASH_FDIV 01h–FFh Divider value for generating the required 5.1-6.5 µs Flash

controller clock period.

PS027001-0707 Flash Memory

eZ80F91 ASSP

Product Specification

107

Flash Write/Erase Protection Register

The Flash Write/Erase Protection register prevents accidental Write or Erase operations.

The protection is limited to a resolution of eight 32 KB blocks. Setting a bit to 1 protects

that 32 KB block of Flash memory from accidental Writes or Erases. The default upon

RESET is for all Flash memory blocks to be protected.

The WP pin works in conjunction with FLASH_PROT[0] to protect the lowest block (also

called the Boot block) of Flash memory. If either the WP is held asserted or

FLASH_PROT[0] is set, the Boot block is protected from Write and Erase operations.

A protect bit is not available for the information page. The information page is, however,

protected excluded from a MASS ERASE by clearing the FLASH_PAGE register

(0x00FC) bit7(INFO_EN).

Writes to this register is allowed only after it is unlocked via the FLASH_KEY register.

Any attempted W rites to this register while locked will set it to FFh, thereby protecting all

blocks. See Table 41.

Table 41. Flash Write/Erase Protection Register (FLASH_PROT = 00FAh)

Bit 76543210

Reset 11111111

CPU Access R/W* R/W* R/W* R/W* R/W* R/W* R/W* R/W*

Note: R/W = Read/Write if unlocked, R = Read Only if locked. *Key sequence required to unlock.

Bit Position Value Description

[7]

BLK7_PROT 0 Disable Write/Erase Protect on block 38000h to 3FFFFh.

1 Enable Write/Erase Protect on block 38000h to 3FFFFh.

[6]

BLK6_PROT 0 Disable Write/Erase Protect on block 30000h to 37FFFh.

1 Enable Write/Erase Protect on block 30000h to 37FFFh.

[5]

BLK5_PROT 0 Disable Write/Erase Protect on block 28000h to 2FFFFh.

1 Enable Write/Erase Protect on block 28000h to 2FFFFh.

[4]

BLK4_PROT 0 Disable Write/Erase Protect on block 20000h to 27FFFh.

1 Enable Write/Erase Protect on block 20000h to 27FFFh.

[3]

BLK3_PROT 0 Disable Write/Erase Protect on block 18000h to 1FFFFh.

1 Enable Write/Erase Protect on block 18000h to 1FFFFh.

[2]

BLK2_PROT 0 Disable Write/Erase Protect on block 10000h to 17FFFh.

1 Enable Write/Erase Protect on block 10000h to 17FFFh.

Note:

PS027001-0707 Flash Memory

eZ80F91 ASSP

Product Specification

108

Flash Interrupt Control Register

There are two sources of interrupts from the Flash controller. These two sources are:

•

Page Erase, Mass Erase, or Row Program completed successfully.

•

An error condition occurred.

Either or both of these two interrupt sources are enabled by setting the appropriate bits in

the Flash Interrupt Control register.

The Flash Interrupt Control register contains four status bits to indicate the following error

conditions:

Row Program Time-Out—This bit signals a time-out during Row Programming. If the

current row program operation does not complete within 4864 Flash controller clocks,

the Flash controller terminates the row program operation by clearing bit 2 of the Flash

Program Control Register and sets the RP_TM0 error bit to 1.

Write Violation—This bit indicates an attempt to write to a protected block of Flash

memory (the Write was not performed).

Page Erase Violation—This bit indicates an attempt to erase a protected block of Flash

memory (the requested page was not erased).

Mass Erase Violation—This bit indicates an attempt to MASS ERASE when there are

one or more protected blocks in Flash memory (the MASS ERASE was not performed).

If the error condition interrupt is enabled, any of these four error conditions result in an

interrupt request being sent to the eZ80F91device’s interrupt controller. Reading the Flash

Interrupt Control register clears all error condition flags and the DONE flag. See Table 42

on page 109.

[1]

BLK1_PROT 0 Disable Write/Erase Protect on block 08000h to 0FFFFh.

1 Enable Write/Erase Protect on block 08000h to 0FFF Fh.

[0]

BLK0_PROT 0 Disable Write/Erase Protect on block 00000h to 07FFFh.

1 Enable Write/Erase Protect on block 00000h to 07F FFh.

Note: The lower 32 KB block (00000h to 07FFFh—BLK0) is called the Boot block and is protected

using the external WP pin.

Bit Position Value Description

PS027001-0707 Flash Memory

eZ80F91 ASSP

Product Specification

109

Flash Page Select Register

The msb of this register is used to select whether I/O Flash access and PAGE ERASE

operations are directed to the 512-byte information page or to the main Flash memory

array , and also whether the information page is included in MASS ERASE operations. The

lower 7 bits are used to select one of the main 128 pages for PAGE ERASE or I/O

operations.

To perform a PAGE ERASE, the software must set the proper page value prior to setting

the page erase bit in the Flash Control Register. In addition, each access to the

Table 42. Flash Interrupt Control Register (FLASH_IRQ = 00FBh)

Bit 76543210

Reset 00000000

CPU Access R/WR/WRRRRRR

Note: R/W = Read/Write, R = Read Only. Read resets bits [5] and [3:0].

Bit Position Value Description

[7]

DONE_IEN 0 Flash Erase/Row Program Done Interrupt is disabled.

1 Flash Erase/Row Program Done Interrupt is enabled.

[6]

ERR_IEN 0 Error Condition Interrupt is disabled.

1 Error Condition Interrupt is enabled.

[5]

DONE 0 Erase/Row Program Done Flag is not set.

1 Erase/Row Program Done Flag is set.

[4] 0 Reserved.

[3]

WR_VIO 0 The Write Violation Error Flag is no t set.

1 The Write Violation Err or Fla g is set.

[2]

RP_TMO 0 The Row Program Time-Out Error Flag is not set.

1 The Row Program Time-Out Error Flag is set.

[1]

PG_VIO 0 The Page Erase Violation Error Flag is not set.

1 The Page Erase Violation Error Flag is set.

[0]

MASS_VIO 0 The Mass Erase Violation Error Flag is not set.

1 The Mass Erase Violation Error Flag is set.

Note: The lower 32 KB block (00000h to 07FFFh) is called the Boot Block and is protected using

the external WP pin. Attempts to page erase BLK0 or mass erase Flash when WP is asserted

result in failure and signal an erase violation.

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Product Specification

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FLASH_DATA register causes an autoincrement of the Flash address stored in the Flash

Address registers (FLASH_PAGE, FLASH_ROW, FLASH_COL). See Table 43.

Table 43. Flash Page Select Register (FLASH_PAGE = 00FCh)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write, R = Read Only.

Bit

Position Value Description

[7]

INFO_EN 0 Flash I/O access to PAGE ERASE operations are directed to

main Flash memory. Info page is NOT affected by a MASS

ERASE operation.

1 Flash I/O access to PAGE ERASE operations are directed to

the information page. PAGE ERASE operations only affect

the information page. Info page is included during a MASS

ERASE operation

[6:0]

FLASH_PAGE 00h–7Fh Page address of Flash memory to be used during the PAGE

ERASE or I/O access of main Flash memory. When

INFO_EN is set to 1, this field is ignored.

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Flash Row Select Register

The Flash Row Select Register is a 3-bit value used to define one of the 8 rows of Flash

on a single page. This register is used for all I/O access to Flash memory. In addition,

each access to the FLASH_DATA register causes an autoincre ment of the Flash address

stored in the Flash Address registers (FLASH_PAGE, FLASH_ROW, FLASH_COL).

See Table 44.

Table 44. Flash Row Select Register (FLASH_ROW = 00FDh)

Bit 76543210

Reset XXXXX000

CPU Access RRRRRR/WR/WR/W

Note: R/W = Read/Write, R = Read Only.

Bit

Position Value Description

[7:3] 00h Reserved.

[2:0]

FLASH_ROW 0h–7h Ro w address of Flash memory to be used during an I/O access

of Flash memory. When INFO_EN is 1 in the Flash Page Select

selects between the two rows in the information page.

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Flash Column Select Register

The Flash Column Select Register is an 8-bit value used to define one of the 256 bytes of

Flash memory contained in a single row. This register is used for all I/O access to Flash

memory. In addition, each access to the FLASH_DATA register causes an autoincrement

of the Flash address stored in the Flash Address registers (FLASH_PAGE, FLASH_ROW,

FLASH_COL). See Table 45.

Flash Program Control Register

The Flash Program Control Register is used to perform the functions of MASS ERASE,

PAGE ERASE, and ROW PROGRAM. MASS ERASE and PAGE ERASE are

self-clearing functions.

MASS ERASE requires approximately 200 ms to completely erase the full 256 KB of

main Flash and the 512-byte information page if the FLASH_PAGE register(0x00FC)

bit7(INFO_EN) is set. The 200 ms time is not reduced by excluding the 512 byte

information page.

PAGE ERASE requires approximately 10 ms to erase a 2 KB page.

On completion of either a MASS ERASE or PAGE ERASE, the value of each

corresponding bit is reset to 0.

When Flash is being erased, any Read or Write access to Flash forces the CPU into a Wait

state until the Erase operation is complete and the Flash is accessed. Reads and Writes to

areas other than Flash memory proceeds as usual while an Erase operation is

underway.

During row programming, any reads of Flash memory force a WAIT condition until the

row programming operation completes or times out. See Table 46.

Table 45. Flash Column Select Register (FLASH_COL = 00FEh)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write, R = Read Only.

Bit

Position Value Description

[7:0]

FLASH_COL 00h–FFh Column address of Flash memory to be used during an I/O

access of Flash memory.

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Table 46. Flash Program Control Register (FLASH_PGCTL = 00FFh)

Bit 76543210

Reset 00000000

CPU Access RRRRRR/WR/WR/W

Note: R/W = Read/Write, R = Read Only.

Bit

Position Value Description

[7:3] 00h Reserved.

[2]

ROW_PGM 0 Row Program Disable or Row Program completed.

1 Row Program Enable. This bit automatically resets to 0 when

the row address reaches 256 or when the Row Program

operation times out.

[1]

PG_ERASE 0 Page Erase Disable (Page Erase completed).

1 Page Erase Enable. T his bit auto matically resets to 0 when the

PAGE ERASE operation is complete.

[0]

MASS_ERASE 0 Mass Erase Disable (Mass Erase completed).

1 Mass Erase Enable. This bit auto matically resets to 0 when the

MASS ERASE operation is complete.

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PS027001-0707 Watchdog Timer

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Watchdog Timer

The Watchdog Timer (WDT) helps protect against corrupt or unreliable software, power

faults, and other system-level problems whic h places the CPU into unsuitable operating

states. The eZ80F91 WDT features:

•

Four programmable time-ou t ranges (depending on the WDT clo ck source). The four

ranges are:

–03.2–5.20 ms

–51.2–83.9 ms

–0.50–0.82 sec

–2.68–4.00 sec

•

Three selectable WDT clock sources:

–Internal RC oscillator

–System clock

–Real-Time Clock source (on-chip 32 kHz crystal oscillator or 50/60 Hz signal)

•

A selectable time-out response: a time-out is configured to generate either a RESET or

a nonmaskable interrupt (NMI)

•

A WDT time-out RESET indicator flag

Figure 25 on page 116 illustrates a block diagram of the Watchdog Timer.

PS027001-0707 Watchdog Timer

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Product Specification

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Watchdog Timer Operation

Enabling and Disabling the Watchdog Timer

The WDT is disabled on a RESET. To enable the WDT, the application program must set

WDT_EN, which is bit 7 of the WDT_CTL register. After WDT_EN is set, no Writes are

allowed to the WDT_CTL register. When enabled, the WDT cannot be disabled except by

a RESET.

Time-Out Period Selection

There are four choices of time-out periods for the WDT. The WDT time-out period is

defined by the WDT_PERIOD WDT_CTL[1:0] field and WDT_CLK WDT_CTL[3:2]

field of the Watchdog Timer control register (WDT_CTL = 0093h). The approximate

time-out period an d correspon ding clock cycl es for three dif fere nt WDT clock so urces are

listed in Table 47 on page 117.

The WDT time-out period divider is set to one of the four available settings for the

selected frequency of the WDT clock source. Basing the divider settings on the clock

source values provides a time-out range from few seconds to few milliseconds, regardless

of the frequency setting.

Figure 25. Watchdog Timer Block Diagram

RESET

NMI to eZ80 CPU

28-Bit

Upcounter

WDT

Oscillator

Control Register/

Reset Register

WDT Control Logic

WDT_CLK

System Clock

RTC Clock

Time-out Compare Logic

(WDT_PERIOD)

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RESET or NMI Generation

A WDT time-out causes a RESET or sends a NMI signal to the CPU. The default opera-

tion is for the WDT to cause a RESET.

If the NMI_OUT bit in the WDT_CTL register is set to 0, then on a WDT time-out, the

RST_FLAG bit in the WDT_CTL register is set to 1. The RST_FLAG bit is polled by the

CPU to determine the source of the RESET event.

If the NMI_OUT bit in the WDT_CTL register is set to 1, then on time-out, the WDT

asserts an NMI for CPU processing. The NMI_FLAG bit is polled by the CPU to deter-

mine the source of the NMI event.

Watchdog Timer Registers

Watchdog Timer Control Register

The Watchdog Timer Control register (see Table 48 ) is an 8-bit

Read/Write register used to enable the Watchdog Timer, set the time-out period, indicate

the source of the most recent RESET or NMI, and select the required operation on WDT

time-out.

The default clock source for the WDT is the WDT oscillator (WDT_CLK = 10b).

To power-down the WDT oscillator, another clock source must be selected. The power-

up sequence of the WDT oscillator takes approximately 20 ms.

Table 47. WDT Approximate Time-Out Delays for Possible Clock Sources

WDT_CLK[

3:2] 00 01 10 11

50 MHz system

clock 32.768 kHz RTC

clock Internal RC

oscillator (~10

kHz)

Reserved

WDT_PERI

OD[1:0] Divider Timeout Divider Timeout Divider Timeout Divider Timeout

00 227 2.68 s 217 4.00 s 215 3.28 s - -

01 225 0.67 s 214 0.5 s 213 0.82 s - -

10 222 83.9 ms 211 62.5 ms 2951.2 ms - -

11 218 5.2 ms 273.9 ms 253.2 ms - -

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Table 48. Watchdog Timer Control Register (WDT_CTL = 0093 h)

Bit 76543210

Reset 000/101000

CPU Access R/W R/W R R R/W R/W R/W R/W

Note: R = Read only; R/W = Read/Write.

Bit

Position Value Description

WDT_EN 0 WDT is disabled.

1 WDT is enabled. When enabled, the WDT cannot be disabled

without a RESET.

NMI_OUT 0 WDT time-out resets the CPU.

1 WDT time-out generates a NMI to the CPU.

RST_FLAG 0 RESET caused by external full-chip reset or ZDI reset.

1 RESET caused by WDT time-out. This flag is set by the WDT

time-out, only if the NMI_OUT flag is set to 0. The CPU polls

this bit to determine the source of the RESET. This flag is

cleared by a non-WDT generate d reset.

NMI_FLAG 0 NMI caused by external source.

1 NMI caused by WDT time-out. This flag is set by the WDT time-

out, only if the NMI_OUT flag is set to 1. The CPU polls this bit

to determine the source of the NMI. This flag is cleared by a

non-WDT NMI.

[3:2]

WDT_CLK 00 WDT clock source is system clock.

01 WDT clock source is Real-Time Clock source (32 kHz on-chip

oscillator or 50/60 Hz input as set by RTC_CTRL[4]).

10 WDT clock source is internal RC oscillator (10 kHz typical).

11 Reserved

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[1:0]

WDT_PERIOD 00 WDT_CLK = 00 WDT time-out period is 227 clock cycles.

WDT_CLK = 01 WDT time-out period i s 217 clock cycles.

WDT_CLK = 10 WDT time-out period i s 215 clock cycles.

WDT_CLK = 11 Reserved.

01 WDT_CLK = 00 WDT time-out period i s 225 clock cycles.

WDT_CLK = 01 WDT time-out period i s 214 clock cycles.

WDT_CLK = 10 WDT time-out period i s 213 clock cycles.

WDT_CLK = 11 Reserved.

10 WDT_CLK = 00 WDT time-out period i s 222 clock cycles.

WDT_CLK = 01 WDT time-out period i s 211 clock cycles.

WDT_CLK = 10 WDT time-out period i s 29 clock cycles.

WDT_CLK = 11 Reserved.

11 WDT_CLK = 00 WDT time-out period i s 218 clock cycles.

WDT_CLK = 01 WDT time-out period i s 27 clock cycles.

WDT_CLK = 10 WDT time-out period i s 25 clock cycles.

WDT_CLK = 11 Reserved.

Note: When the WDT is enabled, no Writes are allowed to the WDT_CTL register.

Bit

Position Value Description

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Watchdog Timer Reset Register

The WDT Reset register (see Table 49 ) is an 8-bit Write only register. The WDT is reset

when an A5h value followed by a 5Ah value is written t o this register. Any amount of time

occurs between the writing of A5h value and the 5Ah value, so long as the WDT time-out

does not occur prior to completion. Any value other than 5Ah written to the WDT Reset

the timer to be reset.

Table 49. Watchdog Timer Reset Register (WDT_RR = 0094h)

Bit 76543210

Reset XXXXXXXX

CPU Access WWWWWWWW

Note: X = Undefined; W = Write Only.

Bit

Position Value Description

[7:0]

WDT_RR A5h The first Write value required to reset the WDT prior to a time-

out.

5Ah The second Write value required to reset the WDT prior to a

time-out. If an A5h, 5A h se qu en ce is written to WDT_RR, the

WDT timer is reset to its initial count value and counting

resumes.

PS027001-0707 Programmable Reload Timers

eZ80F91 ASSP

Product Specification

121

Programmable Reload Timers

The eZ80F91 device features four programmable reload timers. The core of each timer is a

16-bit downcounter. In addition, each timer features a selectable clock source, adjustable

prescaling and operates in either SINGLE PASS or CONTINUOUS mode.

In addition to the basic timer functionality, some of the timers support specialty modes

that performs event counting, input capture, output compare, and PWM generation

functions. PWM mode supports four individually-configurable outputs and a power trip

function.

Each of the four timers available on the eZ80F91 device are controlled individually. They

do not share the same counters, re load registers, control registers, or interrupt signals. A

simplified block diagram of a programmable reload timer is illustrated in Figure 26.

Each timer features its own interrupt which is triggered either by the timer reaching zero

or after a successful comparison occurs. As with the other eZ80F91 interrupts, the priority

is fully programmable.

Figure 26. Programmable Reload Timer Block Diagram

PWM

SCLK

RTC CLK

ECx

OCx

ICx

16-Bit

Down Counter

CONTROL

Output Compare

Registers

PWM

Control

IRQ Control

Input Capture

Registers

EOC IC

IRQ

OC PWM

PWR Trip

DIV

Comparator

PS027001-0707 Programmable Reload Timers

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Product Specification

122

Basic Timer Operation

Basic timer operation is controlled by a timer control register and a programmable reload

value. The CPU uses the control register to setup the prescaling, the input clock source,

the end-of-count beha vior, and to start the timer. The 16-bit reload value is used to

determine the duration of the timer’s count before either halting or reloading.

After choosing a timer period and writing the appropriate values to the reload registers, the

CPU must set the timer enable bit (TMRx_CTL[TIM_EN]) by allowing the count to

begin. The reload bit (TMRx_CTL[RLD]) must also be asserted so that the timer counts

down from the reload value rather than from 0000h. On the system clock cycle, after the

assertion of the reload bit, the timer loads with the 16-bit reload value and begins counting

down. The reload bit is automatically cleared after the loading operation. The timer is

enabled and reloaded on the same cycle; however, the timer does not require disabling to

reload and reloading is performed at any time. It is also possible to halt the timer by deas-

serting the timer enable bit and resuming the count at a later time from the same point by

reasserting the bit.

Reading the Current Count Value

The CPU reads the current count value when the timer is running. Because the count is a

16-bit value, the hardware latches the value of the upper byte into temporary storage when

the lower byte is read. This value in temporary storage is the value returned when the

upper byte is read. Therefore, the software must read the lower byte first. If it attempts to

read the upper byte first, it does not obtain the current upper byte of the count. Instead, it

obtains the last latched value. This Read operation does not affect timer operation.

Setting Timer Duration

There are three factors to consider while determining Programmable Reload Timer

duration: clock frequency, clo ck divider ratio, and initial count value. Minimum duration

of the timer is achieved by loading 0001h. Maximum duration is achieved by loading

0000h, because the timer first rolls over to FFFFh and then continues counting down to

0000h before the end-of-count is signaled. Depending on the TMRx_CTL[CLK_SEL]

bits of the control register, the clock is either the system clock, or an on-chip RC oscillator

output or an input from a pin.

The time-out period of the timer is returned by the following equation:

To calculate the time-out period with the above equation while using an initial value of

0000h, enter a reload value of 65536 (FFFFh + 1).

Time-Out Period = Clock Divider Ratio x Reload Value

System Clock Frequency

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Product Specification

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Minimum time-out duration is four times longer than the input clock period and is gener-

ated by setting the clock divider ratio to 1:4 and the reload value to 0001h. Maximum

time-out duration is 224 (16,777,216) times longer than the input clock period and is gen-

erated by setting the clock divider ratio to 1:256 and the reload value to 0000h.

SINGLE PASS Mode

In SINGLE PASS mode when the end-of-count value (0000h) is reached; counting halts,

the timer is disabled, and TMRx_CTL[TIM_EN] bit resets to 0. To re-enable the timer , the

CPU must set the TIM_EN bit to 1. An example of a PRT operating in SINGLE PASS

mode is illustrated in Figure 27. Timer register information is indicated in Table 50.

CONTINUOUS Mode

In CONTINUOUS mode, when the end-of-count value, 0000h, is reached, the timer

automatically reloads the 16-bit start value from the Timer Reload registers,

Figure 27. Example: PRT SINGLE PASS Mode Operation

Table 50. Example: PRT SINGLE PASS Mode Parameters

Parameter Control Register(s) Value

Timer Enable TMRx_CTL[TIM_EN] 1

Reload TMRx_CTL[RLD] 1

Prescaler Divider = 4 TMRx_CTL[CLK_DIV] 00b

SINGLE PASS Mode TMRx_CTL[TIM_CONT] 0

End of Count Interrupt Enable TMRx_IER[IRQ_EOC_EN] 1

Timer Reload Value {TMRx_RR_H, TMRx_RR_L} 0004h

System Clock

Clock Enable

TMR3_CTL Write

(Timer Enable)

Interrupt Request

432 1

T3 Count

PS027001-0707 Programmable Reload Timers

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Product Specification

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TMRx_RR_H and TMRx_RR_L. Downcounting continues on the next clock edge and

the timer continues to count until disabled. An example of the timer operating in

CONTINUOUS mode is illustrated in Figure 28 on page 124. Timer register informa-

tion is indicated in Table 51on page 124.

Timer Interrupts

The terminal count flag (TMRx_IIR[EOC]) is set to 1 whenever the timer reaches 0000h,

its end-of-count value in SINGLE PASS mode, or when the timer reloads the start value in

CONTINUOUS mode. The terminal count flag is only set when the timer reaches 0000h

(or reloads) from 0001h. The timer interrupt flag is not set to 1 when the timer is loaded

with the value 0000h, which selects the maximum time-out period.

The CPU is programmed to poll the EOC bit for the time-out event. Alternatively, an inter-

rupt service request signal is sent to the CPU by setting the TMRx_IER[EOC] bit to 1.

Figure 28. Example: PRT CONTINUOUS Mode Operation

Table 51. Example: PRT CONTINUOUS Mode Parameters

Parameter Control Register(s) Value

Timer Enable TMRx_CTL[TIM_EN] 1

Reload TMRx_CTL[RLD] 1

Prescaler Divider = 4 TMRx_CTL[CLK_DIV] 00b

CONTINUOUS Mode TMRx_CTL[TIM_CONT] 1

End of Count Interrupt Enable TMRx_IER[IRQ_EOC_EN] 1

Timer Reload Value {TMRx_RR_H, TMRx_RR_L} 0004h

System Clock

Clock Enable

TMR3_CTL Write

(Timer Enable)

T3 Count

Interrupt

Request

X43214321

PS027001-0707 Programmable Reload Timers

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125

And when the end-of-count value (0000h) is reached, the EOC bit is set to 1 and an inter-

rupt service request signal is passed to the CPU. The interrupt service request signal is

deactivated by a CPU read of the timer interrupt identification register, TMRx_IIR.

All bits in that register are reset by the Read.

The response of the CPU to this interrupt service request is a function of the CPU’s inter-

rupt enable flag, IEF1. For more information about this flag, refer to the eZ80® CPU User

Manual (UM0077) available on www.zilog.com.

Timer Input Source Selection

Timers 0–3 features programmable input source selection. By default, the input is taken

from the eZ80F91’s system clock. The timers also use the Real-Time Clock source (50,

60, or 32768 Hz) as their clock sources. The input source for these timers is set using the

timer control register. (TMRx_CTL[CLK_SEL])

Timer Output

The timer count is directed to the GPIO output pins, if required. To enable the Timer

Output feature, the GPIO port pin must be configured as an output and for alternate func-

tions. The GPIO output pin toggles each time the timer reaches its end-of-count value.

In CONTINUOUS mode operation, enabling the Timer Output feature results in a Timer

Output signal period which is twice the timer time-out period. Examples of Timer Output

operation are illustrated in Figure 29 and Table 52 on page 126. The initial value for the

timer output is zero.

Logic to support timer output exists in all timers; but for the eZ80F91 device, only Timer

0 and 2 route the actual timer output to the pins. Because Ti mer 3 uses the TOUT pins for

PWMxN signals, the timer outputs are not available when using complementary PWM

outputs. See Table 52 on page 126 for details.

PS027001-0707 Programmable Reload Timers

eZ80F91 ASSP

Product Specification

126

Break Point Halting

When the eZ80F91 device is running in DEBUG mode, encountering a break point causes

all CPU functions to halt. However, the timers keep running. This instance makes debug-

ging timer-related software much more difficult. Therefore, the control

debug break points.

Specialty Timer Modes

The features described above are common to all timers in the eZ80F91 device. In addition

to these common features, some of the timers have additional functionality.

Figure 29. Example: PRT Timer Output Operation

Table 52. Example: PRT Timer Out Parameters

Parameter Control Register(s) Value

Timer Enable TMRx_CTL[TIM_EN] 1

Reload TMRx_CTL[RLD] 1

Prescaler Divider = 4 TMRx_CTL[CLK_DIV] 00b

CONTINUOUS Mode TMRx_CTL[TIM_CONT] 1

Timer Reload Value {TMRx_RR_H, TMRx_RR_L} 0003h

System Clock

Clock Enable

TMR3_CTL Write

(Timer Enable)

T3 Count

Timer Out

(internal)

Timer Out

(at pad)

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The following is a list of the special features for each timer:

•

Timer 0

–No special functions

•

Timer 1

–One event counter (EC0)

–Two input captures (IC0 and IC1)

•

Timer 2

–One event counter (EC1)

•

Timer 3

–Two input captures (IC2 and IC3)

–Four output compares (OC0, OC1, OC2, and OC3)

–Four PWM outputs (PWM0, PWM1, PWM2, and PWM3)

Timer 3 consists of three specialty modes. Each of these modes are enabled using bits in

their respective control registers (TMR3_CAP_CTL, TMR3_OC_CTL1,

TMR3_PWM_CTL1). When PWM mode is enabled, the OUTPUT COMPARE and

INPUT CAPTURE modes are not available. This instance is due to address space sharing

requirements. However, INPUT CAPTURE and OUTPUT COMPARE modes run

simultaneously.

Timers with specialty modes offer multiple ways to generate an interrupt. When the inter-

rupt controller services a timer interrupt, the software must read the timers interrupt iden-

tification register (TMRx_IIR) to determine the causes for an interrupt request. This

interference from prior events.

Event Counter

When a timer is configured to take its input from a port input pin (ECx), it functions as an

event counter. For event counting, the clock prescaler is automatically bypassed and edges

(events) cause the timer to decrement. You must select the rising or the falling edge for

counting. Also, the po rt pins must be configured as inputs.

Input sampling on the port pins results in the counter being updated on the third rising

edge of the system clock after the edge event occurs at the port pin. Due to sampling, the

frequency of the event input is limited to one-half the system clock frequency under ideal

conditions. In practice, the event frequency must be less than this value due to duty cycle

variation and system clock jitter.

This EVENT COUNT mode is identical to basic timer operation, except for the clock

source. Therefore, interrupts are managed in the same manner.

PS027001-0707 Programmable Reload Timers

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128

RTC Oscillator Input

When the timer clock source is the Real-Time Clock signal, the timer functions just as it

does in EVENT COUNT mode, except that it samples the internal RTC clock rather than

the ECx pin.

Input Capture

INPUT CAPTURE mode allows the CPU to determine the timing of specified events on a

set of external pins.

A timer intended for use in INPUT CAPTURE mode is setup the same way as in BASIC

mode, with one exception. The CPU must also write the TMRx_CAP_CTL register to

select the edge on which to capture: rising, falling, or both. When one of these events

occurs on an input captu r e pin, the current 16 bit timer value is latched into the capture

value register pair (TMRx_CAP_A or TMRx_CAP_B depending on the IC pin exhibiting

the event).

Reading the Low byte of the register pair causes the timer to ignore other capture events

on the associated external pin until the High byte is read. This instance prevents a

subsequent capture event from overwriting the High byte between the two Reads and

generating an invalid capture value. The capture value registers are Read Only.

A capture flag (ICA or ICB) in the TMRx_IIR register is set whenever a capture event

occurs. Setting the interrupt identification register bit TMRx_IER[IRQ_ICx_EN] enables

the capture event to generate a timer interrupt. The port pins must be configured as

alternate functions, see GPIO Mode 7—Alternate Functions on page 51.

Output Compare

The output compare function reverses the input capture function. Rather than store a timer

value when an external event occurs, OUTPUT COMPARE mode waits until the timer

reaches a specified value, then generates an external event. Although the same bas e timer

is used, up to four separate external pins are driven each with its own compare value.

To use OUTPUT COMPARE mode, the CPU must first configure the basic timer

parameters. Then it must load up to four 16-bit compare values into the four TMR3_OCx

occurs on comparison. You can select the following events: SET, CLEAR, and TOGGLE.

Finally, the CPU must enable OUTPUT COMPARE mode by asserting

TMR3_OC_CTL1[OC_EN].

The initial value for the OCx pins in OUTPUT COMPARE mode is 0 by default. It is

possible to initialize this value to 1 or force a value at a later time. Setting the

TMR3_OC_CTL2[OCx_MODE] value to 0 forces the OCx pin to the selected state

provided by the TMR3_OC_CTL1[OCx_INIT] bits. Regardless of any compare events,

the pin stays at the forced value until OCx_MODE is changed. After release, it retains the

forced value until modified by an OUTPUT COMPARE event.

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Asserting TMR3_OC_CTL1[MAST_MODE] selects MASTER MODE for all OUTPUT

COMPARE events and sets output 0 as the master. As a result, outputs 1, 2, and 3 are

caused to disregard output-specific configuration and comparison values and instead

mimic the current settings for output 0.

The OCx bits in the TMR3_IIR register are set whenever the corresponding timer com-

pares occur. TMR3_IER[IRQ_OCx_EN] allows the compare event to generate a timer

interrupt.

Timer Port Pin Allocation

The eZ80F91 device timers interface to the outside world via Ports A and B. These

ports are also used for GPIO as well as other assorted functions. Table 53 on page 129

lists the timer pins and their respective functions.

Table 53. GPIO Mode Selection Using Timer Pins

Port GPIO Port

Bits GPIO Port

Mode

Timer Function

PWM_CTL1

MPWM_EN = 0 PWM_CTL1

MPWM_EN = 1

APA0 7 OC0 PWM0

PA1 7 OC1 PWM1

PA2 7 OC2 PWM2

PA3 7 OC3 PWM3

PWM_CTL1

PAIR_EN = 0 PWM_CTL1

PAIR_EN = 1

PA4 7 TOUT0 PWM0

PA5 7 TOUT2 PWM1

PA6 7 EC1 PWM2

PA7 7 PWM3

B PB0 7 IC0/EC0

PB1 7 IC1

PB4 7 IC2

PB5 7 IC3

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Timer Registers

The CPU monitors and co ntrols the timer using seven 8-bit registers. These registers are

the control register, the interrupt identification register, the interrupt enable register and

the reload regist er pair (High an d Low byte). Th ere are also a pair of data registers used to

read the current timer count value.

The variable x can be 0, 1, 2, or 3 to represent each of the 4 available timers.

Basic Timer Register Set

Each timer requires a different set of registers for configuration and control. However,

all timers contain the following seven registers, each of which is necessary for basic

operation:

•

Timer Control Register (TMRx_CTL)

•

Interrupt Identification Register (TMRx_IIR)

•

Interrupt Enable Register (TMRx_IER)

•

Timer Data Registers (TMRx_DR_H and TMRx_DR_L)

•

Timer Reload Registers (TMRx_RR_H and TMRx_RR_L)

The Timer Data Register is Read Only, when the Timer Reload Register is Write Only.

The address space for these two registers is shared.

In addition to the basic register set, T imer 1 uses the following five registers for its INPUT

CAPTURE mode:

•

Capture Control Register (TMR1_CAP_CTL)

•

Capture Value Registers (TMR1_CAP_B_H, TMR1_CAP_B_L, TMR1_CAP_A_H,

TMR1_CAP_A_L)

In addition to the basic register set, Timer 3 uses 19 registers for INPUT CAPTURE,

OUTPUT COMPARE, and PWM modes. PWM and capture/compare functions cannot be

used simultaneously so, their register address space is shared. INPUT CAPTURE and

OUTPUT COMPARE are used concurrently and their address space is not shared.

The INPUT CAPTURE mode registers are equivalent to those used in Timer 1 above

(substitute TMR3 for TMR1).

OUTPUT COMPARE mode uses the following nine registers:

•

Output Compare Control Registers

–TMR3_OC_CTL1

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–TMR3_OC_CTL2

•

Compare Value Registers

–TMR3_OC3_H

–TMR3_OC3_L

–TMR3_OC2_H

–TMR3_OC2_L

–TMR3_OC1_H

–TMR3_OC1_L

–TMR3_OC0_H

–TMR3_OC0_L

Multiple PWM mode uses the following 19 registers:

•

PWM Control Registers

–TMR3_PWM_CTL1

–TMR3_PWM_CTL2

–TMR3_PWM_CTL3

•

PWM Rising Edge Values

–TMR3_PWM3R_H

–TMR3_PWM3R_L

–TMR3_PWM2R_H

–TMR3_PWM2R_L

–TMR3_PWM1R_H

–TMRx_PWM1R_L

–TMR3_PWM0R_H

–TMR3_PWM0R_L

•

PWM Falling Edge Values

–TMR3_PWM3F_H

–TMRx_PWM3F_L

–TMR3_PWM2F_H

–TMR3_PWM2F_L

–TMR3_PWM1F_H

–TMR3_PWM1F_L

–TMR3_PWM0F_H

–TMR3_PWM0F_L

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Timer Control Register

The Timer x Control Register (see Table 54) is used to control timer operations including

enabling the timer, selecting the clock source, selecting the clock divider, selecting

between CONTINUOUS and SINGLEPASS modes, and enabling the auto-reload

feature.

Table 54. Timer Control Register (TMR0_CTL = 0060h, TMR1_CTL = 0065h,

TMR2_CTL = 006Fh, TMR3_CTL = 0074h)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R = Read only; R/W = Read/Write.

Bit

Position Value Description

BRK_STOP

0 The timer continues to operate during debug break poin ts.

1The timer stops operation and holds count value during debug

break points.

[6:5]

CLK_SEL

00 Timer source is the system clock divided by the prescaler.

01 Timer source is the Real Time Clock Input.

10 Timer source is the Event Count ( ECx) input—falling edge.

For Timer 1 this is EC0.

For Timer 2, this is EC1.

11 Timer source is the Event Count (ECx) input—rising edge.

For Timer 1 this is EC0.

For Timer 2, this is EC1.

[4:3]

CLK_DIV

00 System clock divider = 4.

01 System clock divider = 16.

10 System clock divider = 64.

11 System clock divider = 256.

TIM_CONT

0The timer operates in SINGLE PASS mode. TIM_EN (bit 0) is

reset to 0 and coun ting stops when the end-of-count value is

reached.

1The timer operates in CONTINUOUS mode. The timer reload

value is written to the counter when the end-o f-count value is

reached.

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Timer Interrupt Enable Register

The Timer x Interrupt Enable Register (see Table 55) is used to control timer interrupt

operations. Only bits related to functions present in a given timer are active.

RLD

0 Reload function is not forced.

1Force reload. When 1 is written to this bit, the values in the

reload registers are loaded into the downcounter.

TIM_EN 0 The programmable reload timer is disabled.

1 The programmable reload timer is enabled.

Table 55. Timer Interrupt Enable (TMR0_IER = 0061h, TMR1_IER = 0066h,

TMR2_IER = 0070h, TMR3_IER = 0075h)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R = Read only; R/W = Read/Write.

Bit

Position Value Description

7 0 Unused.

IRQ_OC3_EN

0Interrupt reque sts for OC3 are disab led (va lid on ly in

OUTPUT COMPARE mode). OC oper ation s occur in Time r 3 .

1Interrupt re quests for OC3 are enabled (valid only in OUTPUT

COMPARE mode). OC operations occur in Timer 3.

IRQ_OC2_EN

0Interrupt reque sts for OC2 are disab led (va lid on ly in

OUTPUT COMPARE mode). OC oper ation s occur in Time r 3 .

1Interrupt re quests for OC2 are enabled (valid only in OUTPUT

COMPARE mode). OC operations occur in Timer 3.

IRQ_OC1_EN

0Interrupt reque sts for OC1 are disab led (va lid on ly in

OUTPUT COMPARE mode). OC oper ation s occur in Time r 3 .

1Interrupt re quests for OC1 are enabled (valid only in OUTPUT

COMPARE mode). OC operations occur in Timer 3.

IRQ_OC0_EN

0Interrupt reque sts for OC0 are disab led (va lid on ly in

OUTPUT COMPARE mode). OC oper ation s occur in Time r 3 .

1Interrupt re quests for OC0 are enabled (valid only in OUTPUT

COMPARE mode). OC operations occur in Timer 3.

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IRQ_ICB_EN

Interrupt requests for ICx are disabled (valid on ly in INPUT

CAPTURE mode).

Timer 1: the capture pin is IC1.

Timer 3: the capture pin is IC3.

Interrupt r equests for ICx are enabled (valid only in INPUT

CAPTURE mode).

For Timer 1: the capture pin is IC1.

For Timer 3: the capture pin is IC3.

IRQ_ICA_EN

Interrupt requests for ICA or PWM power trip are disabled

(valid only in INPUT CAPTURE and PWM modes).

For Timer 1: the capture pin is IC0.

For Timer 3: the capture pin is IC2.

Interrupt requests for ICA or PWM power trip are enabled

(valid only in INPUT CAPTURE and PWM modes).

For Timer 1: the capture pin is IC0.

For Timer 3: the capture pin is IC2.

IRQ_EOC_EN 0 Interrupt on end-of-count is disabled.

1 Interrupt on end-of-count is enabled.

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Timer Interrupt Identification Register

The TImer x Interrupt Identification Register (see Table 56) is used to flag timer events so

that the CPU determines the cause of a timer interrupt. This register is cleared by a CPU

Read.

Table 56. Timer Interrupt Identification Register (TMR0_IIR = 0062h, TMR1_IIR =

0067h, TMR2_IIR = 0071h, TMR3_IIR = 0076h)

Bit 76543210

Reset 00000000

CPU Access RRRRRRRR

Note: R = Read only;

Bit

Position Value Description

7 0 Unused.

OC3 0 Output compare, OC3, does not occur.

1 Output compare, OC3, occurs.

OC2 0 Output compare, OC2, does not occur.

1 Output compare, OC2, occurs.

OC1 0 Output compare, OC1, does not occur.

1 Output compare, OC1, occurs.

OC0 0 Output compare, OC0, does not occur.

1 Output compare, OC0, occurs.

ICB

0Input capture, ICB, does not occur .

For Timer 1, the capture pin is IC1.

For Timer 3, the capture pin is IC3.

1Input capture, ICB, occurs.

For Timer 1, the capture pin is IC1.

For Timer 3, the capture pin is IC3.

ICA

0Input capture, ICA, or PWM power trip does not occur.

For Timer 1, the capture pin is IC0.

For Timer 3, the capture pin is IC2.

1Input capture, ICA, or PWM power trip occurs.

For Timer 1, the capture pin is IC0.

For Timer 3, the capture pin is IC2.

EOC 0 End-of-count does not occur.

1 End-of-count occurs.

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Timer Data Register—Low Byte

The Timer x Data Register—Low Byte returns the Low byte of the current count value of

the selected timer. The Timer Data Register—Low Byte (see Table 57) is read when the

timer is in operation. Reading the current count value does not affect timer

operation. To read the 16-bit data of the current count value, {TMRx_DR_H[7:0],

TMRx_DR_L[7:0]}, first read the Timer Data Register—Low Byte, followed by the

Timer Data Register—High Byte. The Timer Data Register—High Byte value is latched

into temporary storage when a Read of the Timer Data Register—Low Byte occurs.

This register shares its address with the corresponding timer reload register.

Table 57. Timer Data Register—Low Byte (TMR0_DR_L = 0063h, TMR1_DR_L =

0068h, TMR2_DR_L = 0072h, TMR3_DR_L = 0077h)

Bit 76543210

Reset 00000000

CPU Access RRRRRRRR

Note: R = Read only.

Bit

Position Value Description

[7:0]

TMR_DR_L 00h–FFh

These bits represent the Low byte of the 2-byte timer data

value, {TMRx_DR_H[7:0], TMRx_DR_L[7:0]}. Bit 7 is bit 7

of the 16-bit timer da ta value. Bi t 0 is bit 0 (lsb) of the 16-bit

timer data valu e.

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Timer Data Register—High Byte

The Timer x Data Register—High Byte returns the High byte of the count value of the

selected timer as it existed at the time that the Low byte was read. The Timer Data

current count value does not affect timer operation. To read the 16-bit data of the

current count value, {TMRx_DR_H[7:0], TMRx_DR_L[7:0]}, first read the Timer Data

Data Register—Low Byte occurs.

This register shares its address with the corresponding timer reload register.

Table 58. Timer Data Register—High Byte (TMR0_DR_H = 0064h, TMR1_DR_H =

0069h, TMR2_DR_H = 0073h, TMR3_DR_H = 0078h)

Bit 76543210

Reset 00000000

CPU Access RRRRRRRR

Note: R = Read only.

Bit

Position Value Description

[7:0]

TMR_DR_H 00h–FFh

These bits represent the High byte of the 2-byte timer data

value, {TMRx_DR_H[7:0], TMRx_DR_L[7:0]}. Bit 7 is bit 15

(msb) of the 16-bit timer data value. Bit 0 is bit 8 of the 16-bit

timer data valu e.

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Timer Reload Register—Low Byte

The Timer x Reload Register—Low Byte (see Table 59) stores the least-significant byte

(LSB) of the 2-byte timer reload value. In CONTINUOUS mode, the timer reload value is

reloaded into the timer on end-of-count. When the reload bit (TMRx_CTL[RLD]) is set to

1 forcing the reload function, the timer reload value is written to the timer on the next ris-

ing edge of the clock.

This register shares its address with the corresponding timer data register.

Table 59. Timer Reload Register—Low Byte (TMR0_RR_L = 0063h, T MR1_RR_L

= 0068h, TMR2_RR_L = 0072h, TMR3_RR_L = 0077h)

Bit 76543210

Reset 00000000

CPU Access WWWWWWWW

Note: W = Write Only.

Bit

Position Value Description

[7:0]

TMR_RR_L 00h–FFh

These bits represent the Low byte of the 2-byte timer

reload value, {TMRx_RR_H[7:0], TMRx_RR_L[7:0]}. Bit 7

is bit 7 of the 16-bit timer reload value. Bit 0 is bit 0 (lsb) of

the 16-bit timer reload value.

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Timer Reload Register—High Byte

The Timer x Reload Register—High Byte (see Table 60) stores the most-significant byte

(MSB) of the 2-byte timer reload value. In CONTINUOUS mode, the timer reload value is

reloaded into the timer upon end-of-count. When the reload bit (TMRx_CTL[RLD]) is set

to 1, it forces the reload function, the timer reload value is written to the timer on the next

rising edge of the clock.

This register shares its address with the corresponding timer data register.

Timer Input Capture Control Register

The Timer x Input Capture Control Register (see Table 61) is used to select the edge or

edges to be captured. For Timer 1, CAP_EDGE_B is used for IC1 and CAP_EDGE_A is

for IC0. For T imer 3, CAP_EDGE_B is for IC3, and CAP_EDGE_A is for IC2.

Table 60. Timer Reload Register—High Byte (TMR0_RR_H = 0064h,

TMR1_RR_H = 0069h, TMR2_RR_H = 0073h, TMR3_RR_H = 0078h)

Bit 76543210

Reset 00000000

CPU Access WWWWWWWW

Note: W = Write Only.

Bit

Position Value Description

[7:0]

TMR_RR_H 00h–FFh

These bits represent the High byte of the 2-byte timer

reload value, {TMRx_RR_H[7:0], TMRx_RR_L[7:0]}. Bit 7

is bit 15 (msb) of the 16-bit timer reload value. Bit 0 is bit 8

of the 16-bit timer reload value.

Table 61. Timer Input Capture Control Register

(TMR1_CAP_CTL = 006Ah, TMR3_CAP_CTL = 007Bh)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R = Read only; R/W = Read/Write.

Bit

Position Value Description

[7:4] 0000 Reserved

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Timer Input Capture Value A Register—Low Byte

The Timer x Input Capture Value A Register—Low Byte (see Table 62) stores the Low

byte of the capture value for external input A. For Timer 1, the external input is IC0. For

Timer 3, it is IC2.

[3:2]

CAP_EDGE_B

00 Disable capture on ICB.

01 Enable capture only on the falling edge of ICB.

10 Enable capture only on the rising edge of ICB.

11 Enable capture on both edges of ICB.

[1:0]

CAP_EDGE_A

00 Disable capture on ICA.

01 Enable capture only on the falling edge of ICA

10 Enable capture only on the rising edge of ICA.

11 Enable capture on both edges of ICA.

Table 62. Timer Input Capture Value Register A—Low Byte (TMR1_CAPA_L =

006Bh, TMR3_CAPA_L = 007Ch)

Bit 76543210

Reset 00000000

CPU Access RRRRRRRR

Note: R = Read only.

Bit

Position Value Description

[7:0]

TMRx_CAPA_L 00h–FFh

These bits represent the Low byte of the 2-byte capture

value, {TMRx_CAPA_H[7:0], TMR x_CAPA_L[7:0]}. Bit 7 is

bit 7 of the 16-bit data value. Bit 0 is bit 0 (lsb) of th e 16-b it

timer data valu e.

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Timer Input Capture Value A Register—High Byte

The Timer x Input Capture Value A Register—High Byte (see Table 63) stores the High

byte of the capture value for external input A. For Timer 1, the external input is IC0. For

Timer 3, it is IC2.

Timer Input Capture Value B Register—Low Byte

The Timer x Input Capture Value B Register—Low Byte (see Table 64) stores the Low

byte of the capture value for external input B. For Timer 1, the external input is IC1. For

Timer 3, it is IC3.

Table 63. Timer Input Capture Value Register A—High Byte (TMR1_CAPA_H

= 006Ch, TMR3_CAPA_H = 007Dh)

Bit 76543210

Reset 00000000

CPU Access RRRRRRRR

Note: R = Read only.

Bit

Position Value Description

[7:0]

TMRx_CAPA_H 00h–FFh

These bits represent the High byte of the 2-byte capture

value, {TMRx_CAPA_H[7:0], TMR x_CAPA_L[7:0]}. Bit 7 is

bit 15 (msb) of the 16-bit data value. Bit 0 is bit 8 of the 16-

bit timer data value.

Table 64. Timer Input Capture Value Register B—Low Byte (TMR1_CAPB_L =

006Dh, TMR3_CAPB_L = 007Eh)

Bit 76543210

Reset 00000000

CPU Access RRRRRRRR

Note: R = Read only.

Bit

Position Value Description

[7:0]

TMRx_CAPB_L 00h–FFh

These bits represent the Low byte of the 2-byte capture

value, {TMRx_CAPB_H[7:0], TMR x_CAPB_L[7:0]}. Bit 7 is

bit 7 of the 16-bit data value. Bit 0 is bit 0 (lsb) of the

16-bit timer data value.

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Timer Input Capture Value B Register—High Byte

The Timer x Input Capture Value B Register—High Byte (see Table 65) stores the High

byte of the capture value for external input B. For Timer 1, the external input is IC0. For

Timer 3, it is IC3.

Timer Output Compare Control Register 1

The T imer3 Output Compare Control Register 1 (see Table 66) is used to select the Master

Mode and to provide initial values for the OC pins.

Table 65. Timer Input Capture Value Register B—High Byte (TMR1_CAPB_H

= 006Eh, TMR3_CAPB_H = 007Fh)

Bit 76543210

Reset 00000000

CPU Access RRRRRRRR

Note: R = Read only.

Bit

Position Value Description

[7:0]

TMRx_CAPB_H 00h–FFh

These bits represent the High byte of the 2-byte capture

value, {TMRx_CAPB_H[7:0], TMR x_CAPB_L[7:0]}. Bit 7 is

bit 15 (msb) of the 16-bit data value. Bit 0 is bit 8 of the 16-

bit timer data value.

Table 66. Timer Output Compare Control Register 1 (TMR3_OC_CTL1 = 0080h)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R = Read only; R/W = Read/Write.

Bit

Position Value Description

[7:6] 00 Unused

OC3_INIT 0 OC pin cleared when initialized.

1 OC pin set when initialized.

OC2_INIT 0 OC pin cleared when initialized.

1 OC pin set when initialized.

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Timer Output Compare Control Register 2

The Timer3 Output Compare Control Register 2 (see Table 67) is used to select the event

that occurs on the output compare pins when a timer compare happens.

OC1_INIT 0 OC pin cleared when initialized.

1 OC pin set when initialized.

OC0_INIT 0 OC pin cleared when initialized.

1 OC pin set when initialized.

MAST_MODE 0 OC pins are independent.

1 OC pins all mimic OC0.

OC_EN 0 OUTPUT COMPARE mode is disabled.

1 OUTPUT COMPARE mode is enabled.

Table 67. Timer Output Compare Control Register 2 (TMR3_OC_CTL2 = 0081h)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit

Position Value Description

[7:6]

OC3_MODE

00 Initialize OC pin to value specified in

TMR3_OC_CTL1[OC3_INT].

01 OC pin is cleared upon timer compare.

10 OC pin is set upon timer compa re.

11 OC pin toggles upon timer compare.

[5:4]

OC2_MODE

00 Initialize OC pin to value specified in

TMR3_OC_CTL1[OC2_INT].

01 OC pin is cleared upon timer compare.

10 OC pin is set upon timer compa re.

11 OC pin toggles upon timer compare.

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Timer Output Compare Value Register—Low Byte

The Timer 3 Out put Com pa re x Value Register—Low Byte (see Table 68) stores the Low

byte of the compare value for OC0–OC3.

[3:2]

OC1_MODE

00 Initialize OC pin to value specified in

TMR3_OC_CTL1[OC1_INT].

01 OC pin is cleared upon timer compare.

10 OC pin is set upon timer compa re.

11 OC pin toggles upon timer compare.

[1:0]

OC0_MODE

00 Initialize OC pin to value specified in

TMR3_OC_CTL1[OC0_INT].

01 OC pin is cleared upon timer compare.

10 OC pin is set upon timer compa re.

11 OC pin toggles upon timer compare.

Table 68. Compare Value Register—Low Byte (TMR3_OC0_L = 0082h,

TMR3_OC1_L = 0084h, TMR3_OC2_L = 0086h, TMR3_OC3_L = 0088h)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit

Position Value Description

[7:0]

TMR3_OCx_L 00h–FFh

These bits represent the Low byte of the 2-byte compare

value, {TMR3_OCx_H[7:0], TMR3_OCx_L[7:0]}. Bit 7 is bit

7 of the 16-bit data value. Bit 0 is bit 0 (lsb) of the 16-bit

timer compa re value.

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Timer Output Compare Value Register—High Byte

The Timer3 Output Compare x Value Register—High Byte (see Table 69) stores the High

byte of the compare value for OC0–OC3.

Multi-PWM Mode

The special Multi-PWM mode uses the Timer 3 16-bit counter as the primary timekeeper

to control up to 4 PWM generators. The 16-bit reload value for Timer 3 sets a common

period for each of the PWM signals. However , the duty cycle and phase for each generator

are independent that is, the High and Low periods for each PWM generator are set inde-

pendently. In addition, each of the 4 PWM generators are enabled independently.

The 8 PWM signals (4 PWM output signals and their inverses) are output via Port A. A

functional block diagram of the Multi-PWM is illustrated in Figure 30 on page 146.

Table 69. Compare Value Register—High Byte (TMR3_OC0_H = 0083h,

TMR3_OC1_H = 0085h, TMR3_OC2_ H = 008 7h, TMR3_OC3_H = 0089h)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit

Position Value Description

[7:0]

TMR3_OCx_H 00h–FFh

These bits represent the High byte of the 2- byte compare

value, {TMR3_OCx_H[7:0], TMR3_OCx_L[7:0]}. Bit 7 is bit

15 (msb) of the 16-bit data value. Bit 0 is bit 8

of the 16-bit timer compare value.

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Setting TMR3_PWM_CTL1[MPWM_EN] to 1 enables Multi-PWM mode. The

TMR3_PWM_CTL1 register bits enable the 4 individual PWM generators by adjusting

settings according to the list provided in Table 70.

Figure 30. Multi-PWM Simplified Block Diagram

Table 70. Enabling PWM Generators

Enable PWM generator 0 by setting TMR3_PWM_CTL1[PWM0_EN] to 1.

Enable PWM generator 1 by setting TMR3_PWM_CTL1[PWM1_EN] to 1.

Enable PWM generator 2 by setting TMR3_PWM_CTL1[PWM2_EN] to 1.

Enable PWM generator 3 by setting TMR3_PWM_CTL1[PWM3_EN] to 1.

PWM0 Output

PWM1 Output

PWM2 Output

PWM3 Output

Timer 3

Clock Input

PWM0

Generator

PWM1

Generator

PWM2

Generator

PWM3

Generator

Timer 3

16-Bit Binary

Downcounter

Count Value

PA0

PA4

PA1

PA5

PA2

PA6

PA3

PA7

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The inverted PWM outputs PWM0, PWM1 , PWM2, and PWM3 are globally enabled by

setting TMR3_PWM_CTL1[PAIR_EN] to 1. The individual PWM generators must be

enabled for the associated inverted PWM signals to be output.

For each of the 4 PWM generators, there is a 16-bit rising edge value

{TMR3_PWMxR_H[PWMxR_H], TMR3_PWMxR_L[PWMxR_L]} and a 16-bit falling

edge value {TMR3_PWMxF_H[PWMxF_H], TMR3_PWMxF_L[PWMxF_L]} for a total

of 16 registers. The rising-edge byte pairs define the timer count at which the PWMx

output transitions from Low to High. Conversely, the falling-edge byte pairs define the

timer count at which the PWMx output transitions from High to Low. On reset, all enabled

PWM outputs begin Low and all PWMx outputs begin High. When the PWMx output is

Low, the logic is looking for a match between the timer count and the rising edge value,

and vice versa. Therefore, in a case in which the rising edge value is the same as the falling

edge value, the PWM output frequency is one-half the rate at which the counter passes

through its entire count cycle (from reload value down to 0000h).

Figure 31and Figure 32 demonstrate a simple Multi-PWM output and an expanded view

of the timing, respectively. Associated control values are listed in Table 71.

Figure 31. Multi-PWM Operation

Figure 32. Multi-PWM Operation—Expanded View of Timing

0CBA987654321CBA987654321CBA CBA987654321

T3 Count

PWM0

PWM1

System Clock

Clock Enable

A987 6

T3 Count 54

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PWM Master Mode

In PWM Master mode, the pair of output signals generated from the PWM0 generator

(PWM0 and PWM0) are directed to all four sets of PWM output pairs. Setting

TMR3_PWM_CTL1[MM_EN] to 1 enables PWM Master mode. Assuming the outputs

are all enabled and no AND/OR gating is used, all four PWM output pairs transition

simultaneously under the dire ction of PWM0 and PWM0. In PWM Master mode,

the outputs still be gated individually using the AND/OR gating functions described in the

next section. Multi-PWM mode and the ind i vidual PWM outputs must be enabled alon g

with PWM Master mode. It is possible to enable or disable any combination of the 4 PWM

outputs while running in PWM Master mode.

Modification of Edge Transition Values

Special circuitry is included for the update of the PWM edge transition values. Normal use

requires that these values be updated while the PWM generator is running.

Under certain circumstances, electric motors driven by the PWM logic encounters rough

operation. In other words, cycles are skipped if the PWM waveform edge is not carefully

modified.

Without special consideration, if a PWM generator looks for a particular count to make a

state transition and if the edge transition value changes to a value that already occurred in

Table 71. Example: Multi-PWM Addressing

Parameter Control Register(s) Value

Timer Reload Value {TMR3_RR_H, TMR3_RR_L} 000Ch

PWM0 rising edge {TMR3_PWM0R_H,

TMR3_PWM0R_L} 0008h

PWM0 falling edge {TMR3_PWM0F_H, TMR3_PWM0F_L} 0004h

PWM1 rising edge {TMR3_PWM1R_H,

TMR3_PWM1R_L} 0006h

PWM1 falling edge {TMR3_PWM1F_H, TMR3_PWM1F_L} 0007h

PWM enable TMR3_PWM_CTL1[PAIR_EN] 1

PWM0 enable TMR3_PWM_CTL1[PWM0_EN] 1

PWM1 enable TMR3_PWM_CTL1[PWM1_EN] 1

Multi-PWM enable TMR3_PWM_CTL1[MP WM_EN ] 1

Prescaler Divider = 4 TMR3_CTL[CLK_DIV] 00b

PWM nonoverlapping delay = 0 TMR3_PWM_CTL2[PWM_DLY] 0000b

Note:

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the current counter count-down cycle, then the transition is missed. The PWM generator

holds the current output state until the counter reloads and cycles through to the

appropriat e edge transi tion value again. In effect, an entire cycle of the PWM waveform is

skipped with the signal held at a DC value. The change in PWM waveform duty cycle

from cycle to cycle must be limited to some fraction of a period to avoid rough running.

To avoid unintentional roughness due to timing of the load operation for the register val-

ues in question, the PWM edge transition values are double-buffered and exhibit the

following behavior:

•

When the PWM generators are disabled, PWM edge transition values written by the

CPU are immediately loaded into the PWM edge transition registers.

•

When the PWM generators are enabled, a PWM edge transition value is loaded into a

buffer register and transferred to its destination register only during a specific transition

event. A rising edge transition value is only loaded upon a falling edge transition event,

and a falling edge transition value is only loaded upon a rising edge transition event.

AND/OR Gating of the PWM Outputs

When in Multi-PWM mode, it is possible for you to turn of f PWM propagati on to the pins

without disabling the PWM generator. This feature is global and applies to all enabled

PWM generators. The function is implemented by applying digital logic (AND or OR

functions) to combine the corresponding bits in the port output register with the PWM and

PWM outputs.

The AND or OR functions are enabled on all PWM outputs by setting

TMR3_PWM_CTL2[AO_EN] to either a 01b (AND) or 10b (OR). Any other value

disables this feature. Likewise, the AND or OR functions are enabled on all PWM outputs

by setting TMR3_PWM_CTL2[AON_EN] to either a 01b (AND) or 10b (OR). Any

other value disables this feature. A functional block diagram for the AND/OR gating fea-

ture for PWM0 and PWM0 is illustrated in Figure 33 on page 150. The functionality for

the other three PWM pairs are identical.

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If you enable the OR function on all PWM outputs and PADR0 is set to 1, then the PWM0

output on PA0 is fo rced High. Similarly, if you select the AND function on all PWM

outputs and PADR 0 is set to a 0, then the PWM0 output on PA0 is forced Low.

PWM Nonoverlapping Output Pair Delays

A delay is added between the falling edge of the PWM (PWM) outputs and the rising edge

of the PWM (PWM) outputs. This delay is set to assure that even with load and output

drive variations there will be no overlap between the falling edge of a PWM (PWM) out-

put and the rising edge of its paired output. The selected delay is global to all four PWM

pairs. The delay duration is software-selectable using the 4-bit field

TMR3_PWM_CTL2[PWM_DLY]. The duration is programmable in units of the system

clock (SCLK), from 0 SCLK periods to 15 SCLK periods. The

TMR3_PWM_CTL2[PWM_DLY] bits are mapped directly to a counter, such that a

Figure 33. PWM AND/OR Gating Functional Diagram

PWM0 Signal PADR0

TMR3_PWM_CTL2[5:4]

PA0 PWM0 Output

PWM0 Signal PADR4

TMR3_PWM_CTL2[7:6]

PWM0 Output

PA4

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setting of 0000b represents a delay of 0 system clock periods and a setting of 1111b rep-

resents a delay of 15 system clock periods. The PWM delay feature is illustrated in

Figure 34 with associated addressing listed in Table 72.

The PWM nonoverlapping delay time must always be defined to be less than the delay

between the rising and falling edges (and the delay between the falling and rising edges) of

all Multi-PWM outputs. In other words, a rising (falling) edge cannot be delayed beyond

the time at which it is subsequently scheduled to fall (rise).

Figure 34. PWM Nonoverlapping Output Delay

Table 72. PWM Nonoverlapping Output Addressing

Parameter Control Register(s) Value

Timer clock is SCLK ÷ 4 TMR3_CTL[CLK_DIV] 00b

Timer reload value {TMR3_RR_H, TMR3_RR_L} 000Ch

PWM0 rising edge {TMR3_PWM0R_H, TMR3 _ P WM 0R _L } 0008 h

PWM0 falling edge {TMR3_PWM0F_H, TMR3_PWM0F_L} 0004h

Prescaler divider = 4 TMR3_CTL[CLK_DIV] 00b

PWM nonoverlapping delay = 3 TMR3_PWM_CTL2[PWM_DLY] 0011b

PWM enable TMR3_PWM_CT L 1[ PAIR_ EN] 1

PWM0 enable TMR3_PWM_CTL1[PWM0_EN] 1

Multi-PWM enable TMR3_PWM_CTL1[MPWN_EN] 1

Note:

876543

System Clock

Clock Enable

TMR3_Count

PWM0

21C

3 x SCLK 3 x SCLK

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Multi-PWM Power-Trip Mode

When enabled, the Multi-PWM power-trip feature forces the enabled PWM outputs to a

predetermined state when an interrupt is generated from an external source via IC0, IC1,

IC2, or IC3. One or multiple external interrupt sources are enabled at any given time. If

multiple sources are enabled, any of the selected external sources trigger an interrupt.

Configuring the PWM_CTL3 register enables or disables interrupt sources. See Table 75

on page 156.

The possible interrupt sources for a Multi-PWM power-trip are:

•

IC0—digital input

•

IC1—digital input

•

IC2—digital input

•

IC3—digital input

When the power-trip is detected, TMR3_PWM_CTL3[PTD] is set to 1 to indicate

detection of the power-trip. A value of 0 signifies that no power-trip is detected.

The PWMs are released only after a power-trip when TMR3_PWM_CTL3[PTD] is

written back to 0 by software. As a result, you are allowed to check the conditions of the

motor being controlled before releasing the PWMs. The explicit release also prevents

noise glitches after a power-trip from causing an accidental exit or re-entry of the PWM

power-trip state.

The programmable power-trip states of the PWMs are globally grouped for the PWM out-

puts and the inverting PWM outputs. Upon detection of a power-trip, the PWM outputs

are forced to either a High state, a Low state, or high-impedance. The settings for the

power-trip states are made with power-trip control bits TMR3_PWM_CTL3[PT_LVL],

TMR3_PWM_CTL3[PT_LVL_N], and TMR3_PWM_CTL3[PT_TRI].

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Multi-PWM Control Registers

Pulse-Width Modulation Control Register 1

The PWM Control Register 1 (see Table 73) controls PWM function enables.

Table 73. PWM Control Register 1 (PWM_CTL1 = 0079h)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit

Position Value Description

PAIR_EN 0Global disable of the PWM outputs (PWM outp uts enabled

only).

1 Global enable of the PWM and PWM output pairs.

PT_EN 0 Disable power-trip featur e.

1 Enable power-trip feature.

MM_EN 0 Disable Master mode.

1 Enable Master mode.

pwm3_en 0 Disable PWM generator 3.

1 Enable PWM generator 3.

pwm2_en 0 Disable PWM generator 2.

1 Enable PWM generator 2.

pwm1_en 0 Disable PWM generator 1.

1 Enable PWM generator 1.

PWM0_EN 0 Disable PWM generator 0.

1 Enable PWM generator 0.

mpwm_en 0 Disable Multi-PWM mode.

1 Enable Multi-PWM mode.

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Pulse-Width Modulation Control Register 2

The PWM Control Register 2 (see Table 74) controls pulse-width modulation AND/OR

and edge delay functions.

Table 74. PWM Control Register 2 (PWM_CTL2 = 007Ah)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit

Position Value Description

[7:6]

AON_EN

00 Disable AND/OR features on PWM.

01 Enable AND logic on PWM.

10 Enable OR logic on PWM.

11 Disable AND/OR features on PWM.

[5:4]

AO_EN

00 Disable AND/OR features on PWM.

01 Enable AND logic on PWM.

10 Enable OR logic on PWM.

11 Disable AND/OR features on PWM.

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[3:0]

PWM_DLY

0000 No delay between falling edge of PWM (PWM) and rising

edge of PWM (PWM)

0001 Delay of 1 SCLK periods between falling edge of PWM

(PWM) and rising edge of PWM (PWM)

0010 Delay of 2 SCLK periods between falling edge of PWM

(PWM) and rising edge of PWM (PWM)

0011 Delay of 3 SCLK periods between falling edge of PWM

(PWM) and rising edge of PWM (PWM)

0100 Delay of 4 SCLK periods between falling edge of PWM

(PWM) and rising edge of PWM (PWM)

0101 Delay of 5 SCLK periods between falling edge of PWM

(PWM) and rising edge of PWM (PWM)

0110 Delay of 6 SCLK periods between falling edge of PWM

(PWM) and rising edge of PWM (PWM)

0111 Delay of 7 SCLK periods between falling edge of PWM

(PWM) and rising edge of PWM (PWM)

1000 Delay of 8 SCLK periods between falling edge of PWM

(PWM) and rising edge of PWM (PWM)

1001 Delay of 9 SCLK periods between falling edge of PWM

(PWM) and rising edge of PWM (PWM)

1010 Delay of 10 SCLK periods between falling edge of PWM

(PWM) and rising edge of PWM (PWM)

1011 Delay of 11 SCLK periods between falling edge of PWM

(PWM) and rising edge of PWM (PWM)

1100 Delay of 12 SCLK periods between falling edge of PWM

(PWM) and rising edge of PWM (PWM)

1101 Delay of 13 SCLK periods between falling edge of PWM

(PWM) and rising edge of PWM (PWM)

1110 Delay of 14 SCLK periods between falling edge of PWM

(PWM) and rising edge of PWM (PWM)

1111 Delay of 15 SCLK periods between falling edge of PWM

(PWM) and rising edge of PWM (PWM)

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Pulse-Width Modulation Control Register 3

The PWM Control Register 3 (see Table 75) is used to configure the PWM power trip

functionality.

Table 75. PWM Control Register 3 (PWM_CTL3 = 007Bh)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R

Note: R/W = Read/Write; R = Read only.

Bit

Position Value Description

PT_IC3_EN 0 Power trip disabled on IC3.

1 Power trip enabled on IC3.

PT_IC2_EN 0 Power trip disabled on IC2.

1 Power trip enabled on IC2.

PT_IC1_EN 0 Power trip disabled on IC1.

1 Power trip enabled on IC1.

PT_IC0_EN 0 Power trip disabled on IC0.

1 Power trip enabled on IC0.

PT_TRI 0 All PWM trip levels are open-drain

1 All PWM trip levels are defined by PT_LVL and PT_LVL_N

PT_LVL 0 After power trip, PWMx outputs are set to one.

1 After power trip, PWMx outputs are set to zero.

PT_LVL_N 0 After power trip, PWMx outputs are set to one.

1 After power trip, PWMx outputs are set to zero.

PTD 0 Power trip has been cleared.

1 This bit is set after power trip event.

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Pulse-Width Modulation Rising Edge—Low Byte

A parallel 16-bit Write of {TMR3_PWMxR_H[7–0], TMR3_PWMxR_L[7–0]} occurs

when software initiates a Write to TMR3_PWMxR_L . The register is described in

Table 76.

Pulse-Width Modulation Rising Edge—High Byte

Writing to TMR3_PWMxR_H stores the value in a temporary holding register. A parallel

16-bit Write of {TMR3_PWMxR_H[7–0], TMR3_PWMxR_L[7–0]} occurs when soft-

ware initiates a Write to TMR3_PWMxR_L. The register is detailed in Table 77.

Table 76. PWMx Rising-Edge Register—Low Byte (TMR3_PWM0R_L = 007Ch,

TMR3_PWM1R_L = 007Eh, TMR3_PWM2R_L = 0080h, TMR3_PWM3R_L = 0082h)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit

Position Value Description

[7:0]

PWMXR_L 00h–FFh

These bits represent the Low byte of the 16-bit value to set the

rising edge COMPARE value for PWMx,

{TMR3_PWMXR_H[7:0], TMR3_PWMXR_L[7:0]}. Bit 7 is bit 7

of the 16-bit timer data value. Bit 0 is bit 0 (lsb) of the

16-bit timer data value.

Table 77. PWMx Rising-Edge Register—High Byte (TMR3_PWM0R_H = 007Dh,

TMR3_PWM1R_H = 007Fh, TMR3_PWM2R_H = 0081h, TMR3_PWM3R_H = 00 83 h )

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit

Position Value Description

[7:0]

PWMXR_H 00h–FFh

These bits represent the High byte of the 16-bit value to set the

rising edge COMPARE value for PWMx,

{TMR3_PWMXR_H[7:0], TMR3_PWMXR_L[7:0]}. Bit 7 is bit

15 (msb) of the 16-bit timer data value. Bit 0 is bit 8 of the

16-bit timer data value.

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Pulse-Width Modulation Falling Edge—Low Byte

A parallel 16-bit Write of {TMR3_PWMxF_H[7–0], TMR3_PWMxF_L[7–0]} occurs

when software initiates a Write to TMR3_PWMxF_L. The register is detailed in Table 78.

Pulse-Width Modulation Falling Edge—High Byte

Writing to TMR3_PWMxF_H stores the value in a temporary holding register. A parallel

16-bit Write of {TMR3_PWMxF_H[7–0], TMR3_PWMxF_L[7–0]} occurs whe n

software initiates a Write to TMR3_PWMxF_L. The register is detailed in Table 79.

Table 78. PWMx Falling-Edge Register—Low Byte (TMR3_PWM0F_L = 0084h,

TMR3_PWM1F_L = 0086h, TMR3_PWM2F_L = 0088h, TMR3_PWM3F_L = 008Ah)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit

Position Value Description

[7:0]

PWMXF_L 00h–FFh

These bits represent the Low byte of the 16-bit value to set the

falling edge COMPARE value for PWMx,

{TMR3_PWMXF_H[7:0], TMR3_PWMXF_L[7:0]}. Bit 7 is bit 7

of the 16-bit timer data value. Bit 0 is bit 0 (lsb) of the

16-bit timer data value.

Table 79. PWMx Falling-Edge Register—High Byte (TMR3_PWM0F_H = 0 085h,

TMR3_PWM1F_H = 0087h, TMR3_ PWM2F_H = 0089h, TMR3_PWM3F_H = 008Bh)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit

Position Value Description

[7:0]

PWMXF_H 00h–FFh

These bits represent the High byte of the 16-bit value to set the

falling edge COMPARE value for PWMx,

{TMR3_PWMXF_H[7:0], TMR3_PWMXF_L[7:0]}. Bit 7 is bit 15

(msb) of the 16-bit timer data value. Bit 0 is bit 8 of the

16-bit timer data value.

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Product Specification

159

Real-Time Clock

Real-Time Clock Overview

The Real-T i me Clock (RTC) maintains time by keeping count of seconds, minutes, hours,

day-of-the-week, day-of-the-month, year, and century. The current time is kept in 24-hour

format. The format for all count and alarm registers is selectable between binary and

binary-coded-decimal (BCD) operations. The calendar oper ation maintains the correct

day-of-the-month and automatically compensates for leap year. A simplified block

diagram of the R TC and the associated on-chip, low-power, 32 kHz oscillator is illustrated

in Figure 35. Connections to an external battery supply and 32 kHz crystal network is also

demonstrat ed in Figure 35.

For users NOT using the R TC th e following R TC signal pin s must be connected as follows

to avoid a 10 uA leakage within the RTC circuit block. RTC_Xin (pin 61) must be left

floating or connected to ground.

Figure 35. Real-Time Clock and 32 kHz Oscillator Block Diagram

Note:

RTC_V

RTC_X

Enable

CLK_SEL

(RTC_CTRL[4])

32 KHz

Crystal

Battery

IRQ

ADDR[15:0]

DATA[7:0]

RTC Clock

System Clock

VDD

Low-Power

32 KHz Oscillator

Real-Time Clock

to eZ80 CPU

RTC_XOUT

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Real-Time Clock Alarm

The clock is programmed to generate an alarm condition when the current count matches

the alarm set-point registers. Alarm registers are available for seconds, minutes, hours, and

day-of-the-week. Each alarm is independently enabled. To generate an alarm condition,

the current time must match all enabled alarm values. For example, if the day-of-the-week

and hour alarms are both enabled, the alarm only occurs at a specified hour on a specified

day. The alarm triggers an interrupt if the interrupt enable bit, INT_EN, is set to 1. The

alarm flag, ALARM, and corresponding interrupt to the CPU are cleared by reading the

RTC_CTRL register.

Alarm value registers and alarm control registers are written at any time. Alarm conditions

are generated when the count value matches the alarm value. The comparison of alarm and

count values occurs whenever the RTC count increments (one time every second). The

RTC is also forced to perform a comparison at any time by writing a 0 to the

RTC_UNLOCK bit (the RTC_UNLOCK bit is not required to be changed to a 1 first).

Real-Time Clock Oscillator and Source Selection

The RTC count is driven by either the on-chip 32 kHz RTC oscillator or an external

50/60 Hz CMOS-level clock signal (typically derived from the AC power line frequency).

The on-chip oscillator requires an external 32 kHz crystal connected to RTC_XIN and

RTC_XOUT as shown in Figure 35 on page 159. If an external 50/60 Hz clock signal is

used, connect it to RTC_XOUT.

The clock source and power-line frequencies are selected in the RTC_CTRL register.

Writing to the RTC_CTRL register resets the clock divider.

Real-Time Clock Battery Backup

The power supply pin (RTC_VDD) for the RTC and associated low-power 32 kHz

oscillator is isolated from the other power supply pins on the eZ80F91 device. To ensure

that the RTC continues to keep time in the event of loss of line power to the application, a

battery is used to supply power to the RTC and the oscillator via the RTC_VDD pin. All

VSS (ground) pins must be connected together on the printed circuit assembly.

Real-Time Clock Recommended Operation

Following a initial system reset from a p ower-down conditi on of VDD and VDD_RTC, the

counter values of the RTC are undefined and all alarms are disabled. The following proce-

dure is recommended to initialize the Real-Time Clock:

•

Write to RTC_CTRL to set RTC_UNLOCK and disable the RTC counter; this action

also clears the clock divider

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•

Write values to the RTC count registers to set the current time

•

Write values to the RTC alarm registers to set the appropriate alarm conditions

•

Write to RTC_CTRL to clear RTC_UNLOCK; clearing the RTC_UNLOCK bit resets

and enables the clock divider

Real-Time Clock Registers

The RTC registers are acc essed via the address and data buses using I/O instructions. The

RTC_UNLOCK control bit controls access to the RTC count registers. When unlocked

(RTC_UNLOCK = 1), the RTC count is disabled and the count registers are Read/Write.

When locked (RTC_UNLOCK = 0), the RTC count is enabled and the count registers are

Read Only. The default at RESET is for the RTC to be locked.

Real-Time Clock Seconds Register

This register contains the current seconds count. The value in the RTC_SEC register is

unchanged by a RESET. The current setting of BCD_EN determines whether the values

in this register are binary (BCD_EN = 0) or binary-coded decimal (BCD_EN = 1).

Access to this register is Read Only if the RTC is locked, and Read/Write if the RT C is

unlocked. See Table 80.

Table 80. Real-Time Clock Seconds Register (RTC_SEC = 00E0h)

Bit 76543210

Reset XXXXXXXX

CPU Access R/W* R/W* R/W* R/W* R/W* R/W* R/W* R/W*

Note: X = Unchanged by RESET; R/W* = Read Only if RTC locked, Read/Write if RTC unlocked.

Binary-Coded-Decimal Operation (BCD_EN = 1)

Bit Position Value Description

[7:4]

TEN_SEC 0–5 The tens digit of the current seconds count.

[3:0]

SEC 0–9 The ones digit of the current seconds count.

Binary Operation (BCD_EN = 0)

Bit Position Value Description

[7:0]

SEC 00h–3Bh The current seconds count.

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Real-Time Clock Minutes Register

This register contains the current minutes count. The value in the RTC_MIN register is

unchanged by a RESET. The current setting of BCD_EN determines whether the values

in this register are binary (BCD_EN = 0) or binary-coded decimal (BCD_EN = 1).

Access to this register is Read Only if the RTC is locked, and Read/Write if the RT C is

unlocked. See Table 81.

Table 81. Real-Time Clock Minutes Register (RTC_MIN = 00E1h)

Bit 76543210

Reset XXXXXXXX

CPU Access R/W* R/W* R/W* R/W* R/W* R/W* R/W* R/W*

Note: X = Unchanged by RESET; R/W* = Read Only if RTC locked, Read/Write if RTC unlocked.

Binary-Coded Decimal Operation (BCD_EN = 1)

Bit Position Value Description

[7:4]

TEN_MIN 0–5 The tens digit of the current minutes count.

[3:0]

MIN 0–9 The ones digit of the current minutes count.

Binary Operation (BCD_EN = 0)

Bit Position Value Description

[7:0]

MIN 00h–3Bh The current minutes count.

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Real-Time Clock Hours Register

This register contains the current hours count. The value in the RTC_HRS register is

unchanged by a RESET. The current setting of BCD_EN determines whether the values

in this register are binary (BCD_EN = 0) or binary-coded decimal (BCD_EN = 1).

Access to this register is Read Only if the RTC is locked, and Read/Write if the RT C is

unlocked. See Table 82.

Table 82. Real-Time Clock Hours Register (RTC_HRS = 00E2h)

Bit 76543210

Reset XXXXXXXX

CPU Access R/W* R/W* R/W* R/W* R/W* R/W* R/W* R/W*

Note: X = Unchanged by RESET; R/W* = Read Only if RTC locked, Read/Write if RTC unlocked.

Binary-Coded Decimal Operation (BCD_EN = 1)

Bit Position Value Description

[7:4]

TEN_HRS 0–2 The tens digit of the current hours count.

[3:0]

HRS 0–9 The ones digit of the current hours count.

Binary Operation (BCD_EN = 0)

Bit Position Value Description

[7:0]

HRS 00h–17h The current hours count.

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Real-Time Clock Day-of-the-Week Register

This register contains the current day-of-the-week count. The RTC_DOW register begins

counting at 01h. The value in the RTC_DOW register is unchanged by a RESET. The

current setting of BCD_EN determines whether the value in this register is binary

(BCD_EN = 0) or binary-coded decimal (BCD_EN = 1). Access to this register is Read

Only if the RTC is locked and Read/Write if the RTC is unlocked. See Table 83.

Table 83. Real-Time Clock Day-of-the-Week Register (RTC_DOW = 00E3h)

Bit 76543210

Reset 0000XXXX

CPU Access RRRRR/W*R/W*R/W*R/W*

Note: X = Unchanged by RESET; R = Read Onl y ; R/W* = Read Only if RTC locked, Read/Write

if RTC unlocked.

Binary-Coded Decimal Operation (BCD_EN = 1)

Bit Position Value Description

[7:4] 0000 Reserved.

[3:0]

DOW 1–7 The current day-of-the-week.count.

Binary Operation (BCD_EN = 0)

Bit Position Value Description

[7:4] 0000 Reserved.

[3:0]

DOW 01h–07h The current day-of-the-week count.

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Real-Time Clock Day-of-the-Month Register

This register contains the current day-of-the-month count. The R TC_DOM register begins

counting at 01h. The value in the RTC_DOM register is unchanged by a RESET. The

current setting of BCD_EN determines whether the values in this register are binary

(BCD_EN = 0) or binary-coded decimal (BCD_EN = 1). Access to this register is Read

Only if the RTC is locked, and Read/Write if the RTC is unlocked. See Table 84.

Table 84. Real-Time Clock Day-of-the-Month Register (RTC_DOM = 00E4h)

Bit 76543210

Reset XXXXXXXX

CPU Access R/W* R/W* R/W* R/W* R/W* R/W* R/W* R/W*

Note: X = Unchanged by RESET; R/W* = Read Only if RTC locked, Read/Write if RTC unlocked.

Binary-Coded Decimal Operation (BCD_EN = 1)

Bit Position Value Description

[7:4]

TENS_DOM 0–3 The tens digit of the current day-of-the-month count.

[3:0]

DOM 0–9 The ones digit of the current day-of-the-month count.

Binary Operation (BCD_EN = 0)

Bit Position Value Description

[7:0]

DOM 01h–1Fh The current day-of-the-month count.

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Real-Time Clock Month Register

This register contains the current month count. The R TC_MON register begins counting at

01h. The value in the RTC_MON register is unchanged by a RESET. The current setting

of BCD_EN determines whether the values in this register are binary (BCD_EN = 0) or

binary-coded decimal (BCD_EN = 1). Access to this register is Read Only if the RTC is

locked, and Read/Write if the RTC is unlocked. See Table 85.

Table 85. Real-Time Clock Month Register (RTC_MON = 00E5h)

Bit 76543210

Reset XXXXXXXX

CPU Access R/W* R/W* R/W* R/W* R/W* R/W* R/W* R/W*

Note: X = Unchanged by RESET; R/W* = Read Only if RTC locked, Read/Write if RTC unlocked.

Binary-Coded Decimal Operation (BCD_EN = 1)

Bit Position Value Description

[7:4]

TENS_MON 0–1 The tens digit of the current month count.

[3:0]

MON 0–9 The ones digit of the current month count.

Binary Operation (BCD_EN = 0)

Bit Position Value Description

[7:0]

MON 01h–0Ch The current month coun t.

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Real-Time Clock Year Register

This register contains the current year count. The value in the RTC_YR register is

unchanged by a RESET. The current setting of BCD_EN determines whether the values

in this register are binary (BCD_EN = 0) or binary-coded decimal (BCD_EN = 1).

Access to this register is Read Only if the RTC is locked, and Read/Write if the RT C is

unlocked. See Table 86.

Table 86. Real-Time Clock Year Register (RTC_YR = 00E6h)

Bit 76543210

Reset XXXXXXXX

CPU Access R/W* R/W* R/W* R/W* R/W* R/W* R/W* R/W*

Note: X = Unchanged by RESET; R/W* = Read Only if RTC locked, Read/Write if RTC unlocked.

Binary-Coded Decimal Operation (BCD_EN = 1)

Bit Position Value Description

[7:4]

TENS_YR 0–9 The tens digit of the current year count.

[3:0]

YR 0–9 The ones digit of the current year count.

Binary Operation (BCD_EN = 0)

Bit Position Value Description

[7:0]

YR 00h–63h The current year count.

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Real-Time Clock Century Register

This register contains the current century count. The value in the RTC_CEN register is

unchanged by a RESET. The current setting of BCD_EN determines whether the values

in this register are binary (BCD_EN = 0) or binary-coded decimal (BCD_EN = 1).

Access to this register is Read Only if the RTC is locked, and Read/Write if the RT C is

unlocked. See Table 87.

Table 87. Real-Time Clock Century Register (RTC_CEN = 00E7h)

Bit 76543210

Reset XXXXXXXX

CPU Access R/W* R/W* R/W* R/W* R/W* R/W* R/W* R/W*

Note: X = Unchanged by RESET; R/W* = Read Only if RTC locked, Read/Write if RTC unlocked.

Binary-Coded-Decimal Operation (BCD_EN = 1)

Bit Position Value Description

[7:4]

TENS_CEN 0–9 The tens digit of the current century count.

[3:0]

CEN 0–9 The ones digit of the current century count.

Binary Operation (BCD_EN = 0)

Bit Position Value Description

[7:0]

CEN 00h–63h The current century count.

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Real-Time Clock Alarm Seconds Register

This register contains the alarm seconds value. The value in the RTC_ASEC register is

unchanged by a RESET. The current setting of BCD_EN determines whether the values

in this register are binary (BCD_EN = 0) or binary-coded decimal (BCD_EN = 1). See

Table 88.

Table 88. Real-Time Clock Alarm Seconds Register (RTC_ASEC = 00E8h)

Bit 76543210

Reset XXXXXXXX

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: X = Unchanged by RESET; R/W = Read/Write.

Binary-Coded Decimal Operation (BCD_EN = 1)

Bit Position Value Description

[7:4]

ATEN_SEC 0–5 The tens digit of the alarm seconds value.

[3:0]

ASEC 0–9 The ones digit of the alarm seconds value.

Binary Operation (BCD_EN = 0)

Bit Position Value Description

[7:0]

ASEC 00h–3Bh The alarm seconds value.

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Real-Time Clock Alarm Minutes Register

This register contains the alarm minutes value. The value in the RTC_AMIN register is

unchanged by a RESET. The current setting of BCD_EN determines whether the

values in this register are binary (BCD_EN = 0) or binary-coded decimal (BCD_EN = 1).

See Table 89.

Table 89. Real-Time Clock Alarm Minutes Register (RTC_AMIN = 00E9h)

Bit 76543210

Reset XXXXXXXX

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: X = Unchanged by RESET; R/W = Read/Write.

Binary-Coded Decimal Operation (BCD_EN = 1)

Bit Position Value Description

[7:4]

ATEN_MIN 0–5 The tens digit of the alarm minutes value.

[3:0]

AMIN 0–9 The ones digit of the alarm minutes value.

Binary Operation (BCD_EN = 0)

Bit Position Value Description

[7:0]

AMIN 00h–3Bh The alarm minutes value.

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Real-Time Clock Alarm Hours Register

This register contains the alarm hours value. The value in the RT C_AHRS register is

unchanged by a RESET. The current setting of BCD_EN determines whether the

values in this register are binary (BCD_EN = 0) or binary-coded decimal (BCD_EN =

1). See Table 90.

Table 90. Real-Time Clock Alarm Hours Register (RTC_AHRS = 00EAh)

Bit 76543210

Reset XXXXXXXX

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: X = Unchanged by RESET; R/W = Read/Write.

Binary-Coded Decimal Operation (BCD_EN = 1)

Bit Position Value Description

[7:4]

ATEN_HRS 0–2 The tens digit of the alarm hours value.

[3:0]

AHRS 0–9 The ones digit of the alarm hours value.

Binary Operation (BCD_EN = 0)

Bit Position Value Description

[7:0]

AHRS 00h–17h The alarm hours value.

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Real-Time Clock Alarm Day-of-the-Week Register

This register contains the alarm day-of-the-week value. The value in the RTC_ADOW

the value in this register is binary (BCD_EN = 0) or binary-coded decimal (BCD_EN = 1).

See Table 91.

Table 91. Real-Time Clock Alarm Day-of-the-Week Register (RTC_ADOW = 00EBh)

Bit 76543210

Reset 0000XXXX

CPU Access RRRRR/W*R/W*R/W*R/W*

Note: X = Unchanged by RESET; R = Read Only; R/W* = Read Only if RTC locked, Read/Write if

RTC unlocked.

Binary-Coded Decimal Operation (BCD_EN = 1)

Bit Position Value Description

[7:4] 0000 Reserved.

[3:0]

ADOW 1–7 The alarm day-of-the-week value.

Binary Operation (BCD_EN = 0)

Bit Position Value Description

[7:4] 0000 Reserved.

[3:0]

ADOW 01h–07h The ala rm day-of-the-week value.

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Real-Time Clock Alarm Control Register

This register contains control bits for the Real-Time Clock. The RTC_ACTRL register is

cleared by a RESET. See Table 92.

Real-Time Clock Control Register

This register contains control and status bits for the Real-Time Clock. Some bits in the

RTC_CTRL register are cleared by a RESET. The ALARM bit flag and associated inter-

rupt (if INT_EN is enabled) are cleared by reading this register. The ALARM bit flag is

updated by clearing (locking) the RTC_UNLOCK bit or by an increment of the RTC

count. W riting to the RTC_CTRL register also resets the R T C count prescaler allowing the

RTC to be synchronized to another time source.

SLP_WAKE indicates if an RTC alarm condition initiated the CPU recovery from SLEEP

mode. This bit is checked after RESET to det ermine if a sleep-mode recovery is caused by

the RTC. SLP_WAKE is cleared by a Read of the RTC_CTRL register.

Setting the BCD_EN bit causes the RTC to use binary-coded decimal

(

BCD) counting in

all registers including the alarm set points.

The CLK_SEL and FREQ_SEL bits select the RTC clock source. If the 32 KHz crystal

option is selected, the oscillator is enabled and the internal prescaler is set to divide by

Table 92. Real-Time Clock Alarm Control Register (RTC_ACTRL = 00ECh)

Bit 76543210

Reset 00000000

CPU Access RRRRR/WR/WR/WR/W

Note: X = Unchanged by RESET; R = Read Only ; R/W = Read/Write

Bit Position Value Description

[7:4] 0000 Reserved.

ADOW_EN 0 The day-of-the-week alarm is disabled.

1 The day-of-the-week alarm is enabled.

AHRS_EN 0 The hours alarm is disabled.

1 The hours alarm is enabled.

AMIN_EN 0 The minutes alarm is disabled.

1 The minutes alarm is enabled.

ASEC_EN 0 The seconds alarm is disabled.

1 The seconds alarm is enabled.

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32768. If the power-line frequency option is selected, the prescale value is set by the

FREQ_SEL bit, and the 32 kHz oscillator is disabled. See Table 93.

Table 93. Real-Time Clock Control Register (RTC_CTRL = 00EDh)

Bit 76543210

Reset X0XXXX0/10

CPU Access R R/W R/W R/W R/W R/W R R/W

Note: X = Unchanged by RESET; R = Read Only ; R/W = Read/Write.

Bit Position Value Description

ALARM 0 Alarm interrupt is inactive.

1 Alarm interrupt is active.

INT_EN 0 Interrupt on alarm condition is disabled.

1 Interrupt on alarm condition is enabled.

BCD_EN 0 RTC count and alarm value registers are binary.

1 RTC count and alarm value registers are BCD.

CLK_SEL 0 RTC clock source is crystal oscillator output (32768 Hz).

On-chip 32768Hz oscillator is enabled.

1 RTC clock source is power-line frequency input.

On-chip 32768 Hz oscillator is disabled.

FREQ_SEL 0 Power-line frequency is 60 Hz.

1 Power-line frequency is 50 Hz.

DAY_SAV 0 Suggested value for Daylight Savings Time not selected.

1 Suggested value for Daylight Savings Time selected.

This register bit has been allocated as a storage location only

for software ap p licat ion s th at us e DST . N o ac tion is perfo rm ed

in the eZ80F91 when setting or clearing this bit.

SLP_WAKE 0 RTC did not generate a sleep-mode recovery reset.

1 RTC Alarm generated a sleep-mode recovery reset.

RTC_UNLOCK 0 RTC coun t re gis te rs ar e loc k ed to pr ev en t write acc ess.

RTC counter is enabled.

1 RTC count registers are unlock ed to allow writ e acc ess.

RTC counter is disabled.

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Universal Asynchronous

Receiver/Transmitter

The UART module implements all of the logic required to support the asynchronous com-

munications protocol. The module also implements two separate 16-byte-deep FIFOs for

both transmission and reception. A block diagram of the UART is illustrated in Figure 36.

The UART module provides the following asynchronous co mmun icatio ns proto c ol-

related features and functions:

•

5-, 6-, 7-, 8- or 9-bit data transmission.

•

Even/odd, space/mark, address/data, or no parity bit generation and detection.

•

Start and stop bit generation and detection (supports up to two stop bits).

•

Line break detection and generation.

•

Receiver overrun and framing errors detection.

•

Logic and associated I/O to provide modem handshake capability.

Figure 36. UART Block Diagram

System Clock

I/O Address

Data

Receive

Buffer

Transmit

Buffer

Modem

Control

Logic

Interrupt Signal

to eZ80 CPU

UART Control Interface and Baud Rate Generator

RxD0/RxD1

TxD0/TxD1

CTS0/CTS1

RTS0/RTS1

DSR0/DSR1

DTR0/DTR1

DCD0/DCD1

RI0/RI1

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UART Functional Description

The UART Baud Rate Generator (BRG) creates the clock for the serial transmit and

receive functions. The UART module supports all of the various options in the asynchro-

nous transmission and reception protocol including:

•

5- to 9-bit transmit/receive

•

Start bit generation and detection

•

Parity generation and detection

•

Stop bit generation and detection

•

Break generation and detection

The UART contains 16-byte-deep FIFOs in each direction. The FIFOs are enabled or dis-

abled by the application. The receive FIFO features trigger-level detection logic, which

enables the CPU to block-transfer data bytes from the receive FIFO.

UART Functions

The UART function implements:

•

The transmitter and associated control logic

•

The receiver and associated control logic

•

The modem interface and associated logic

UART Transmitter

The transmitter block controls the data transmitted on the TxD output. It implements the

FIFO, access via the UAR Tx_THR register , the transmit shift register , the parity generator ,

and control logic for the transmitter to control parameters for the asynchronous communi-

cations protocol.

The UARTx_THR is a W rite Only register . The CPU writes the data byte to be transmitted

into this register. In FIFO mode, up to 16 data bytes are written via the UARTx_THR reg-

ister. The data byte from the FIFO is transferred to the transmit shift register at the appro-

priate time and tran smitted via TxD output. After SYNC_RESET, the UARTx_THR

the UARTX_LSR register) is 1. An interrupt is sent to the CPU if interrupts are enabled.

The CPU resets this interrupt by loading data into the UARTx_THR register , which clears

the transmitter interrupt.

The transmit shift register places the byte to be transmitted on the TxD signal serially. The

least-significant bit of the byte to be transmitted is shifted out f irst and the most-significant

bit is shifted out last. The control logic within the block adds the asynchronous communi-

cations protocol bits to the data byte being transmitted. The transmitter block obtains the

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parameters for the protocol from the bits programmed via the UARTx_LCTL register.

When enabled, an interrupt is generated after the final protoc ol bit is transmitted which the

CPU resets by loading data into the UARTx_THR register. The TxD output is set to 1 if

the transmitter is idle (that is, the transmitter does not contain any data to be transmitted).

The transmitter operates with the BRG clock. The data bits are placed on the TxD output

one time every 16 BRG clock cycles. The transmitter block also implements a parity gen-

erator that attaches the parity bit to the byte, if programmed. For 9-bit data, the host CPU

programs the parity bit generator so that it marks the byte as either address (mark parity)

or data (space parity).

UART Receiver

The receiver block controls the data reception from the RxD signal. The receiver block

implements a receiver shift register, receiver line error condition monitoring logic and

receiver data ready logic. It also implements the parity checker.

The UARTx_RBR is a Read Only register of the module. The CPU reads received data

from this register. The condition of the UARTx_RBR register is monitored by the DR bit

(bit 0 of the UARTx_LSR register). The DR bit is 1 when a data byte is received and trans-

ferred to the UARTx_RBR register from the receiver shift register. The DR bit is reset

only when the CPU reads all of the received data bytes. If the number of bits received is

less than eight, the unused most-significant bits of the data byte Read are 0.

For 9-bit data, the receiver checks incoming bytes for space parity. A line status interrupt

is generated when an address byte is received, because address bytes maintain high parity

bits. The CPU clears the interrupt by determining if the address matches its own, then con-

figures the receiver to either accept the subsequent data bytes if the address matches, or

ignore the data if the address does not match.

The receiver uses the clock from the BRG for receiving the data. This clock must operate

at 16 times the appropriate baud rate. The receiver synchronizes the shift clock on the fall-

ing edge of the RxD input start bit. It then receives a complete byte according to the set

parameters. The receiver also implements logic to detect framing errors, parity errors,

overrun errors, and break signals.

UART Modem Control

The modem control logic provides two outputs and four inputs for handsh aking with the

modem. Any change in the modem status inputs, except RI, is detected and an interrupt is

generated. For RI, an interrupt is generated only when the trailing edge of the RI is

detected. The module also provides LOOP mode for self-diagnostics.

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UART Interrupts

There are six different sources of interrupts from the UART. The six sources of interrupts

are:

•

Transmitter (two different interrupts)

•

Receiver (three different interrupts)

•

Modem status

UART Transmitter Interrupt

A Transmitter Hold Register Empty interrupt is generated if there is no data available in

the hold register. By the same token, a transmission complete interrupt is generated after

the data in the shift register is sent. Both interrupts are disabled using individual interrupt

enable bits, or cleared by writing data into the UARTx_THR register.

UART Receiver Interrupts

A receiver interrupt is generated by three possible events. The first event, a receiver data

ready interrupt event, indicates that one or more data bytes are received and are ready to

be read. Next, this interrupt is generated if the number of bytes in the receiver FIFO is

greater than or equal to the trigger level. If the FIFO is not enabled, the interrupt is gener-

ated if the receive buffer contains a data byte. This interrupt is cleared by reading the

UARTx_RBR.

The second interrupt source is the receiver time-out. A receiver time-out interrupt is gen-

erated when there are fewer data bytes in the receiver FIFO than the trigger level and there

are no Reads and Writes to or from the receiver FIFO for four consecutive byte times.

When the receiver time-out interrupt is generated, it is cleared only after emptying the

entire receive FIFO.

The first two interrupt sources from the receiver (data ready and time-out) share an inter-

rupt enable bit. The third source of a receiver interrupt is a line status error, indicating an

error in byte reception. This error results from:

•

Incorrect received parity.

For 9-bit data, incorrect parity indicates detection of an address byte.

•

Incorrect framing (that is, the stop bit) is not detected by receiver at the end of the byte.

•

Receiver overrun condition.

•

A BREAK condition being detected on the receive data input.

Note:

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An interrupt due to one of the above conditions is cleared when the UARTx_LSR register

is read. In case of FIFO mode, a line status interrupt is generated only after the received

byte with an error reaches the top of the FIFO and is ready to be read.

A line status interrupt is activated (provided this interrupt is enabled) as long as the Read

pointer of the receiver FIFO points to the location of the FIFO that contains a byte with the

error. The interrupt is immediately cleared when the UARTx_LSR register is read. The

ERR bit of the UARTx_LSR register is active as long as an erroneous byte is present in the

receiver FIFO.

UART Modem Status Interrupt

The modem status interrupt is generated if there is any change in state of the modem status

inputs to the UART. This interrupt is cleared when the CPU reads the UARTx_MSR regis-

ter.

UART Recommended Usage

The following standard sequence of events occurs in the UART block of the eZ80F91

device. A description of each follows.

•

Module Reset

•

Control Transfers to Configure UART Operation

•

Data T ransfers

Module Reset

Upon reset, all internal registers are set to their default values. All command status regis-

ters are programmed with their default values, and the FIFOs are flushed.

Control Transfers to Configure UART Operation

Based on the requirements of the application, the data transfer baud rate is determined and

the BRG is configured to generate a 16X clock frequency. Interrupts are disabled and the

communication control parameters are programmed in the UARTx_LCTL register. The

FIFO configuration is determined and the receive trigger levels are set in the

UARTx_FCTL register. The status registers, UARTx_LSR and UARTx_MSR, are read to

ensure that none of the interrupt sources are active. The interrupts are enabled (except for

the transmit interrupt) and the application is ready to use the module for transmission/

reception.

Data Transfers

Transmit—To transmit data, the application enables the transmit interrupt. An interrupt is

immediately expected in response. The application reads the UARTx_IIR register and

determines whether the interrupt occurs due to either an empty UARTx_THR register or a

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completed transmission. When the application makes this determination, it writes the

transmit data bytes to the UARTx_THR register. The number of bytes that the application

writes depends on whether or not the FIFO is enabled. If the FIFO is enabled, the applica-

tion writes 16 bytes at a time. If not, the application writes one byte at a time. As a result

of the first Write, the interrupt is deactivated. The CPU then waits for the next interrupt.

When the interrupt is raised by the UART mo dule, the CPU repeats the same process until

it exhausts all of the data for transmission.

To control and check the modem status, the application sets up the modem by writing to

the UARTx_MCTL register and reading the UARTx_MCTL register before starting the

process described above.

In RS485 multidrop mode, the first byte of the message is the station address and the rest

of the message contains the data for that station. You must set the Even Parity Select (EPS

bit 4) and Parity Enable (PEN bit 3) in the UARTx_LCTL before sending the station

address. We recommend that in your UART initialization routine set up the

UARTx_LCTL register for your data transfer format and set the Parity Enable (PEN bit 3)

bit. Each time you want to send a new message you must perform these three steps:

1. Since the UART automatically clears the Even Parity Select (EPS bit 4) bit in the

UARTx_LCTL after a byte is sent, before starting a new message you have to wait for

the transmitter to go idle. The Transmit Em pty (TEMT bit 6) of the UARTx_LSR will

be set. If you set the EPS bit of the UARTx_LCTL before the last byte of the previous

message is transmitted, the EPS bit will be cleared and the new station address will be

sent as data instead of being used as an address.

2. Set the Even Parity Select (EPS bit 4) bit in the UARTx_LCTL register being careful

not to alter the other bits in the register sets the address mark. Write station address to

the UARTx_THR. The UART will automatically clear the EPS bit after the station

address byte is transmitted.

3. Send the rest of the message. Write data to the UART Transmit Holding Register

UARTx_THR whenever the Transmit Holding Register Empty (THRE bit 5) in the

UARTx_LSR is set.

In multidrop mode, during receiving start address marks, you will see a receive line inter-

rupt (INSTS bits[3:1]) in the IIR register. Read the LSR and check for receive errors only

and ignore any parity errors. The parity is only used for address marks in this multidrop

mode.

Receive—The receiver is always enabled, and it continually checks for the start bit on the

RxD input signal. When an interrupt is raised by the UART module, the application reads

the UARTx_IIR register and determines the cause for the interrupt. If the cause is a line

status interrupt, the application reads the UARTx_LSR register, reads the data byte and

then discards the byte or take other appropriate action. If the interrupt is caused by a

receive-data-ready condition, the application alternately reads the UARTx_LSR and

UARTx_RBR registers and removes all of the received data bytes. It reads the

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UARTx_LSR register before reading the UARTx_RBR register to determine that there is

no error in the received data.

To control and check modem status, the application sets up the modem by writing to the

UARTx_MCTL register and reading the UAR Tx_MSR register before starting the process

described above.

Poll Mode Transfers—When interrupts are disabled, all data transfers are referred to as

poll mode transfers. In poll mode transfers, the application must continually poll the

UARTx_LSR register to transmit or receive data without enabling the interrupts. The

same holds true for the UARTx_MSR register . If the interrupts are not enabled, the data in

the UARTx_IIR register cannot be used to determine the cause of interrupt.

Baud Rate Generator

The Baud Rate Generator consists of a 16-bit downcounter, two registers, and as sociated

decoding logic. The initial value of the Baud Rate Generator is defined by the two BRG

Divisor Latch registers, {UARTx_BRG_H, UARTx_BRG_L}. At the rising edge of each

system clock, the BRG decrements until it reaches the value 0001h. On the next system

clock rising edge, the BRG reloads the initial value from {UARTx_BRG_H,

UARTx_BRG_L) and outputs a pulse to indicate the end-of-count.

Calculate the UART data rate with the following equation:

Upon RESET, the 16-bit BRG divisor value resets to the smallest allowable value of

0002h. Therefore, the minimum BRG clock divisor ratio is 2. A software Write to either

the Low- or High-byte registers for the BRG Divisor Latch causes both the Low and High

bytes to load into the BRG counter, and causes the count to restart.

The divisor registers are accessed only if bit 7 of the UART Line Control register

(UARTx_LCTL) is set to 1. After reset, this bit is reset to 0.

Recommended Use of the Baud Rate Generator

The following is the normal sequence of operations that must occur after the eZ80F91 is

powered on to configure the BRG:

1. Assert and deassert RESET.

2. Set UARTx_LCTL[7] to 1 to enable access of the BRG divisor registers.

3. Program the UARTx_BRG_L and UARTx_BRG_H registers.

4. Clear UARTx_LCTL[7] to 0 to disable access of the BRG divisor registers.

UART Data Rate (bits/s) = System Clock Frequency

16 X UART Baud Rate Generator Divisor

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BRG Control Registers

UART Baud Rate Generator Register—Low and High Bytes

The registers hold the Low and High bytes of the 16-bit divisor count loaded by the CPU

for UART baud rate generation. The 16-bit clock divisor value is returned by

{UARTx_BRG_H, UAR T x_BRG_L}, where x is either 0 or 1 to identify the two available

UART devices. Upon RESET, the 16-bit BRG divisor value resets to 0002h. The initial

16-bit divisor value must be between 0002h and FFFFh, because the values 0000h and

0001h are invalid and proper operation is not guaranteed at these two values. As a result,

the minimum BRG clock d i visor ratio is 2.

A Write to either the Low- or High-byte registers for the BRG Divisor Latch causes both

bytes to be loaded into the BRG counter. The count is then restarted.

Bit 7 of the associated UART Line Control register (UARTx_LCTL) must be set to 1 to

access this register. See Table 94 and Table 95 on page 183. For more information, see

UART Line Control Register on page 188.

The UARTx_BRG_L registers share the same address space with the UARTx_RBR and

UARTx_THR registers. The UAR Tx_BRG_H registers share the same address space with

the UARTx_IER registers. Bit 7 of the associated UART Line Control register

(UARTx_LCTL) must be set to 1 to enable access to the BRG regis t ers.

Table 94. UART Baud Rate Generator Register—Low Bytes (UART0_BRG_L = 00C0h,

UART1_BRG_L = 00D0h)

Bit 76543210

Reset 00000010

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R = Read only; R/W = Read/Write.

Bit

Position Value Description

[7:0]

UART_BRG_L 00h–FFh These bits represent the L ow byte of the 16-bit BRG divider value. The

complete BRG divisor value is returned by {UART_BRG_H,

UART_BRG_L}.

Note:

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UART Registers

After a system reset, all UAR T registers are set to their default values. Any Writes to unused

registers or register bits are ignored and reads return a value of 0. For compatibility with

future revisions, unused bits within a register must always be written with a value of 0.

Read/W rite attributes, reset conditions, and bit descriptions of all of the UAR T registers are

provided in this section.

UART Transmit Holding Register

If less than eight bits are programmed for transmission, the lower bits of the byte written

to this register are selected for transmission. The T ransmit FIFO is mapped at this address.

You can write up to 16 bytes for transmission at one time to this address if the FIFO is

enabled by the application. If the FIFO is disabled, this buffer is only one byte deep.

These registers share the same address space as the UARTx_RBR and UARTx_BRG_L

registers. See Table 96 on page 184.

Table 95. UART Baud Rate Generator Register—High Bytes (UART0_BRG_H = 00C1h,

UART1_BRG_H = 00D1h)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R = Read only; R/W = Read/Write.

Bit

Position Value Description

[7:0]

UART_BRG_H 00h–FFh T hese bits represent th e High byte of the 16-bit BRG divider value. The

complete BRG divisor value is returned by {UART_BRG_H,

UART_BRG_L}.

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UART Receive Buffer Register

The bits in this register reflect the data received. If less than eight bits are programmed

for reception, the lower bits of the byte reflect the bits received, whereas upper unused

bits are 0. The Receive FIFO is mapped at this address. If the FIFO is disabled, this

buffer is only one byte deep.

These registers share the same address space as the UARTx_THR and UARTx_BRG_L

registers. See Table 97.

UART Interrupt Enable Register

The UARTx_IER register is used to enable and disable the UART interrupts. The

UARTx_IER registers share the same I/O addresses as the UAR Tx_BRG_H registers. See

Table 98 on page 185.

Table 96. UART Transmit Holding Registers (UART0_THR = 00C0h, UART1_THR = 00D0h)

Bit 76543210

Reset XXXXXXXX

CPU Access WWWWWWWW

Note: W = Write Only.

Bit

Position Value Description

[7:0]

TxD00h–FFh Transmit data byte.

Table 97. UART Receive Buffer Registers (UART0_RBR = 00C0h, UART1_RBR = 00 D0h)

Bit 76543210

Reset XXXXXXXX

CPU Access RRRRRRRR

Note: R = Read only.

Bit

Position Value Description

[7:0]

RxD00h–FFh Receive data byte.

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Table 98. UART Interrupt Enable Registers (UART0_IER = 00C1h, UART1_IER = 00D1h)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit

Position Value Description

[7:5] 000 Reserved

TCIE

0 Transmission complete interrupt is disabled

1Transmission complete interrupt is generated when both the transmit hold

MIIE 0 Modem interrupt on edge detect of status inputs is disabled.

1 Modem interrupt on edge detect of status inputs is enabled.

LSIE

0 Line status interrupt is disabled.

1Line status interrupt is enabled for receive data errors: incorrect parity bit

received, framing error, overrun error, or break detection.

TIE

0 Transmit interrupt is disabled.

1Transmit interrupt is enabled. Interrupt is generated when the transmit

FIFO/buffer is empty indicating no more bytes available for transmission.

RIE

0 Receive interrupt is disabled.

1Receive interrupt and receiver time-out interrupt are enabled. Interrupt is

generated if the FIFO/buffer contains data ready to be read or if the

receiver times out.

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UART Interrupt Identification Register

The Read Only UARTx_IIR register allows you to check whether the FIFO is enabled an d

the status of interrupts. These registers share the same I/O addresses as the UAR Tx_FCTL

registers. See Table 99 and Table 100.

Table 99. UART Interrupt Identification Registers (UART0_IIR = 00C2h, UART1_IIR = 00D2h)

Bit 76543210

Reset 00000001

CPU Access RRRRRRRR

Note: R = Read only.

Bit

Position Value Description

[7]

FSTS 0 FIFO is disabled.

1 FIFO is enabled.

[6:4] 000 Reserved

[3:1]

INSTS 000–

110

Interrupt Status Code

The code indicated in these three bits is valid only if INTBIT is

1. If two internal interrupt sources ar e active and their

respective enab le bits ar e Hig h, only the higher priority

interrupt is seen by the application. The lower-priority interrupt

code is indicated only after the higher-priority interrupt is

serviced. Table 100 lists the interrupt status codes.

INTBIT 0 There is an active interrupt source within the UART.

1 There is not an active interrupt source within the UART.

Table 100. UART Interrupt Status Codes

INSTS

Value Priority Interrupt Type

011 Highest Receiver Line Status

010 Second Receive Data Ready or Trigger Level

110 Third Character Time-out

101 Fourth Transmission Complete

001 Fifth Transmit Buffer Empty

000 Lowest Modem Status

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UART FIFO Control Register

This register is used to monitor trigger levels, clear FIFO pointers, and enable or disable

the FIFO. The UARTx_FCTL registers share the same I/O addresses as the UARTx_IIR

registers. See Table 101.

Table 101. UART FIFO Control Registers (UART0_FCTL = 00C2h, UART1_FCTL = 00D2h)

Bit 76543210

Reset 00000000

CPU Access WWWWWWWW

Note: W = Write Only.

Bit

Position Value Description

[7:6]

TRIG

00 Receive FIFO trigger level set to 1. Receive data interrupt is

generated when there is 1 byte in the FIFO. Valid only if FIFO

is enabled.

01 Receive FIFO trigger level set to 4. Receive data interrupt is

generated when there are 4bytes in the FIFO. Valid only if

FIFO is enabled.

10 Receive FIFO trigger level set to 8. Receive data interrupt is

generated when there are 8 bytes in the FIFO. Valid only if

FIFO is enabled.

11 Receive FIFO trigger level set to 14. Receive data interrupt is

generated when there are 14 byte s in the FIFO. Valid only if

FIFO is enabled.

[5:3] 000b Reserved—must be 000b.

CLRTxF 0

Transmit Disable. This register bit works diffe rently than the

standard 16550 UART. This bit must be set to transmit data.

When it is reset the transmit FI FO logic is reset along with the

associated transmit logic to keep them in sync. This bit is now

persistent–it does not self clear and it must remain at 1 to

transmit data.

1 Transmit Enable

CLRRxF 0

Receive Disable. This register bit works differently than the

standard 16550 UART. This bit must be set to receive data.

When it is reset the receive FIFO logic is reset along with the

associated receive logic to keep them in sync and avoid the

previous version’s lookup problem. This bit is now persistent–it

does not self clear and it must remain at 1 to receive data.

1 Receive Enable

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UART Line Control Register

This register is used to control the communication control parameters. See Table 102 and

Table 103 on page 189.

FIFOEN

0 FIFOs are not used.

Receive and transmit FIFOs are used–You must clear the

FIFO logic using bits 1 and 2. First enable th e FIFOs by setting

bit 0 to 1 then enable the receiver and transmitter by setting

bits 1 and 2.

Table 102. UART Line Control Registers (UART0_LCTL = 00C3h, UART1_LCTL = 00D3h)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit

Position Value Description

DLAB

0 Access to the UART registers at I/O addresses C0h, C1h, D0h and D1h is enabled.

1Access to the Baud Rate Generator registers at I/O addresses C0h, C1h, D0h and

D1h is enabled.

0 Do not send a BREAK signal.

Send Break

UART sends continuous zeroes on the transmit output from the next bit boundary.

The transmit data in the transmit shift register is ignored. After forcing this bit High,

the TxD output is 0 only afte r the b it bou ndary is rea ched. Just b efore fo rcing TxD to

0, the transmit FIFO is cleared. Any new data written to the transmit FIFO during a

break must be written only after the THRE bit of UARTx_LSR register goes High.

This new data is transmitted after the UART recovers from the break. After the br eak

is removed, the UART recovers from the break for the next BRG edge.

FPE

0 Do not force a parity error.

1Force a parity error. When this bit and the parity enable bit (pen) are both 1, an

incorrect parity bit is transmitted with the data byte.

Bit

Position Value Description

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EPS

Even Parity Select

Use odd parity for transmit and receive. The total numbe r of 1 bits in the transmit

data plus parity bit is odd. Used as SPACE bit in Multidrop Mode. See Table 104 on

page 189 for parity select definitions. Note: Receive Parity is set to SPACE in

multidrop mode.

1Use even parity for transmit and receive. The total number of 1 bits in the transmit

data plus parity bit is even. Used as MARK bit in Multidrop Mode. See Table 104 on

page 189 for parity select definition s.

PEN

0 Parity bit transmit and receive is disabled.

Parity bit transmit and receive is enabled. For transmit, a parity bit is generated and

transmitted with every data character. For receive, the parity is checked for every

incoming data character. In Multidrop Mode, receive parity is checked for space

parity.

[2:0]

CHAR 000–111 UART Character Parameter Selection

See Table 103 on page 189 for a description of the values.

Table 103. UART Character Parameter Definition

CHAR[2:0] Character Length (Tx/Rx Data Bits) Stop Bits (Tx Stop Bits)

000 5 1

001 6 1

010 7 1

011 8 1

100 5 2

101 6 2

110 7 2

111 8 2

Table 104. Parity Select Definition for Multidrop Communications

Multidrop Mode Even Parity Select Parity Type

00odd

0 1 even

Bit

Position Value Description

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1 0 space

11*mark

Note: *In Multidrop Mode, EPS resets to 0 after the first character is sent.

Table 104. Parity Select Definition for Multidrop Communications

(Continued)

Multidrop Mode Even Parity Select Parity Type

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UART Modem Control Register

This register is used to control and check the modem status. See Table 105.

Table 105. UART Modem Control Registers (UART0_MCTL = 00C4h, UART1_MCTL = 00D4h)

Bit 76543210

Reset 00000000

CPU Access R R/W R/W R/W R/W R/W R/W R/W

Note: R = Read Only; R/W = Read/Write.

Bit

Position Value Description

70Reserved

POLARITY 0 TxD and RxD signals—Normal Polarity.

1 Invert Polarity of TxD and RxD signals.

MDM

0 Multidrop Mode disabled.

1Multidrop Mode enabled. See Table 104 on page 189 fo r par ity

select definitions.

LOOP

0 LOOP BACK mode is not enabled.

LOOP BACK mode is enabled.

The UART operates in internal LOOP BACK mode. The

transmit data output por t is disconnected from the internal

transmit data output an d set to 1. The receive data input port is

disconnected and intern al receive data is conn ected to intern al

transmit data. The modem status input ports are disconnected

and the four bits of the modem control register are connected

as modem status inputs. The two modem control output ports

(OUT1&2) are set to their inactive state

OUT2 0–1 No function in normal operation.

In LOOP BACK mode, this bit is connected to the DCD bit in

the UART Status Register.

OUT1 0–1 No function in normal operation.

In LOOP BACK mode, this bit is connected to the RI bit in the

UART Status Register.

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UART Line Status Register

This register is used to show the status of UART interrupts and registers. See Table 106.

RTS 0–1

Request to Send

In normal operation, the RTS output port is the inverse of this

bit. In LOOP BACK mode, this bit is connected to the CTS bit in

the UART Status Register.

DTR 0–1

Data Terminal Ready.

In normal operation, the DTR output port is the inverse of this

bit. In LOOP BACK mode, this bit is connected to the DSR bit

in the UART Status Register.

Table 106. UART Line Status Registers (UART0_LSR = 00C 5h, UART1_LSR = 00 D5h)

Bit 76543210

Reset 01100000

CPU Access RRRRRRRR

Note: R = Read only.

Bit

Position Value Description

ERR

0Always 0 when operating in with the FIFO disabled. With the

FIFO enabled, this bit is reset when the UARTx_L SR register is

read and there are no more bytes with error status in the FIFO.

1Error detected in the FIFO. There is at least 1 pari ty, framing or

break indication error in the FIFO.

TEMT

0Transmit holding register/FIFO is not empty or transmit shift

Transmit holding register/FIFO and tran smit shift register are

empty; and the transmitter is idle. This bit cannot be set to 1

during the BREAK condition. This bit only becomes 1 after the

BREAK command is removed.

THRE

0 Transmit holding register/FIFO is not empty.

1Transmit holding register/FIFO. This bit cannot be set to 1

during the BREAK condition. This bit only becomes 1 after the

BREAK command is removed.

Bit

Position Value Description

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0Receiver does not detect a BREAK condition. This bit is reset

to 0 when the UARTx_LSR register is read.

Receiver detects a BREAK condition on the receive input line.

This bit is 1 if the duration of BREAK condition on the receive

data is longer than one character transmission time, the time

depends on the programming of the UARTx_LSR register. In

case of FIFO only one null character is loaded into the receiver

FIFO with the framing error. The framing error is revealed to

the eZ80 whenever that particular data is read from the

receiver FIFO.

0No framing error detected for character at the top of the FIFO.

This bit is reset to 0 when the UARTx_LSR register is read.

1Framing error detected for the character at the top of the FIFO.

This bit is set to 1 when the stop bit following the data/p arity bit

is logic 0.

The received character at th e top of the FIFO does no t con tain

a parity error. In multidrop mode, this indicates that the

received characte r is a data byte. This bit is reset to 0 when the

UARTx_LSR register is read.

1The received char acter at the top of the FIFO contains a parity

error. In multidrop mode, this indicates that the received

character is an address byte.

0The received character at th e top of the FIFO does no t con tain

an overrun error. This bit is reset to 0 when the UARTx_LSR

Overrun error is detected. If the FIFO is not enabled, this

indicates that the data in the receive buffer register was not

read before the next char acter was transferred into the receiver

buffer register. If the FIFO is enabled, this indicates the FIFO

was already full when an additional character was received by

the receiver shift register. The character in the receiver shift

0This bit is reset to 0 when the UARTx_RBR register is read or

all bytes are read f rom th e re ce iver FIF O .

Data ready. If the FIFO is not enabled, this bit is set to 1 when

a complete incoming character is transferr ed into the receiver

buffer register from the receiver shift register. If the FIFO is

enabled, this bit is set to 1 when a character is received and

transferred to the receiver FIFO.

Bit

Position Value Description

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UART Modem Status Register

This register is used to show the status of the UART signals. See Table 107.

Table 107. UART Modem Status Registers (UART0_MSR = 00C6h, UART1_MSR = 00 D6h)

Bit 76543210

Reset XXXXXXXX

CPU Access RRRRRRRR

Note: R = Read only.

Bit

Position Value Description

DCD 0–1

Data Carrier Detect

In NORMAL mode, this bit reflects the inverted state of the

DCDx input pin. In LOOP BACK mode, this bit reflects the

value of the UARTx_M CT L [3] = out2 .

RI 0–1

Ring Indicator

In NORMAL mode, this bit reflects the inverted state of the RIx

input pin. In LOOP BACK mode, this bit reflects the value of the

UARTx_MCTL[2] = out1.

DSR 0–1

Data Set Ready

In NORMAL mode, this bit reflects the inverted state of the

DSRx input pin. In LOOP BACK mode, this bit reflects the

value of the UARTx_MCTL[0] = DTR.

CTS 0–1

Clear to Send

In NORMAL mode, this bit reflects the inverted state of the

CTSx input pin. In LOOP BACK mode, this bit reflects the value

of the UARTx_MCTL[1] = RTS.

DDCD 0–1 Delta Status Change of DCD

This bit is set to 1 whenever the DCDx pin changes state. This

bit is reset to 0 when the UARTx_MSR register is read.

TERI 0–1

Trailing Edge Change on RI.

This bit is set to 1 whenever a falling edge is detected on the

RIx pin. This bit is reset to 0 when the UARTx_MSR register is

read.

DDSR 0–1 Delta Status Change of DSR

This bit is set to 1 whenever the DSRx pin changes state. This

bit is reset to 0 when the UARTx_MSR register is read.

DCTS 0–1 Delta Status Change of CTS

This bit is set to 1 whenever the CTSx pin changes state.

This bit is reset to 0 when the UARTx_MSR register is read.

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UART Scratch Pad Register

The UARTx_SPR register is used by the system as a general-purpose Read/W rite register.

See Table 108.

Table 108. UART Scratch Pad Registers (UART0_SPR = 00C7h, UART1_SPR = 00D7h)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit

Position Value Description

[7:0]

SPR 00h–FFh UART scratch pad re gister is available for use as a general-

purpose Read/Write register. In multi-drop 9 bit mode, this

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PS027001-0707 Infrared Encoder/Decoder

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Infrared Encoder/Decoder

The eZ80F91 de vice contains a UART to an infrared encoder/decoder (endec). The endec

is integrated with the on-chip UART0 to allow easy communication between the CPU and

IrDA Physical Layer Specification Version 1.4-compatible infrared transceivers, as illus-

trated in Figure 37. Infrared communication provides secure, reliable, high-speed, low-

cost, point-to-point communication between PCs, PDAs, mobile telephones, printers and

other infrared-enabled de vices.

Functional Description

When the endec is enabled, the transmit data from the on-chip UART is encoded as digital

signals in accordance with the IrDA standard and output to the infrared transceiver. Like-

wise, data receiv ed from the infrared transceiver is decoded by the endec and passed to the

UART. Communication is half-duplex, meaning that simultaneous data transmission and

reception is not allowed.

The baud rate is set by the UART Baud Rate Generator (BRG), which supports IrDA stan-

dard baud rates from 9600 bps to 115.2 kbps. Higher baud rates are possible, but do not meet

Figure 37. Infrared System Block Diagram

eZ80F91

To eZ80 CPU

System

Clock

UART0

RxD

TxD RxD

TxD

IR_RxD

IR_TxD

Baud Rate

Clock

Infrared

Encoder/Decoder

Interrupt

Signal I/O

Address Data I/O

Address Data

Infrared

Transceiver

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IrDA specifications. The UAR T must be enabled to use the endec. For more information on

the UART and its BRG, see Universal Asynchronous Receiver/Transmitter on page 175.

Transmit

The data to be transmitted via the IR transceiver is the data sent to UART0. The UART

transmit signal, TxD, and Baud Rate Clock are used by the endec to generate the

modulation signal, IR_TxD, that drives the infrared transceiver. Each UART bit is 16

clocks wide. If the data to be transmitted is a logical 1 (High), the IR_TxD signal remains

Low (0) for the full 16-clock period. If the data to be transmitted is a logical 0, a 3-clock

High (1) pulse is output following a 7-clock Low (0) period. Following the 3-clock High

pulse, a 6-clock Low pulse completes the full 16-clock data period. Data transmission is

illustrated in Figure 38. During data transmission, the IR receive function must be

disabled by clearing the IR_RxEN bit in the IR_CTL reg to 0 to prevent transmitter-to-

receiver crosstalk.

Receive

Data received from the IR transceiver via the IR_RxD signal is decoded by the endec and

passed to the UART. The IR_RxEN bit in the IR_CTL register must be set to enable the

receiver decoder. The IrDA serial infrared (SIR) data format uses half duplex communica-

tion. Therefore, the UART must not be allowed to transmit while the receiver decoder is

enabled. The UART Baud Rate Clock is used by the endec to generate the demodulated

signal, RxD, that drives the UART. Each UART bit is 16 clocks wide. If the data to be

received is a logical 1 (High), the IR_RxD signal remains High (1) for the full 16-clock

Figure 38. Infrared Data Transmission

16-clock

period

3-clock

pulse

7-clock

delay

Baud Rate

Clock

UART_TxD Start Bit = 0 Data Bit 0 = 1 Data Bit 1 = 0 Data Bit 2 = 1 Data Bit 3 = 1

IR_TxD

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period. If the data to be received is a logical 0, a delayed Low (0) pulse is output on RxD.

Data transmission is illustrated in Figure 39.

The IrDA endec is designed to ignore pulses on IR_RxD which do not comply with IrDA

pulse width specifications. Inp ut pu lses wider than five baud clocks (that is, 5/16 of a bit

period) are always ignored, as this would b e a violation of the maximum pu lse width spec-

ified for any standard baud rate up to 115.2 kbps. The check for minimum pulse widths is

optional, since using a slow system clock frequency limits the ability to accurately mea-

sure narrow pulse widths near the IrDA specification minimum of 1.41 us for the

2.4–115.2 kbps rate range.

To enable checks of minimum input pulse width on IR_RxD, a non-zero value must be

programmed into the MIN_PULSE field of IR_CTL (bits [7:4]). This field forms the

most-significant four bits of the 6-bit down-counter used to determine if an input pulse

will be ignored because it is too narrow. The lower two counter bits are hard-coded to load

with 0x3, resulting in a total down-count equal to ((MIN_PULSE* 4) + 3). To be accepted,

input pulses must have a width greater than or equal to the down-count value times the

system clock period.

The following equation is used to determine an appropriate setting for MIN_PULSE:

MIN_PULSE = INT( ((Fsys*Wmin) - 3) / 4 )

Where

Fsys is the frequency of the system clock, and,

Wmin is the minimum width of recognized input pulses.

Figure 39. Infrared Data Reception

16-clock

period

16-clock

period 16-clock

period

8-clock

delay

Baud Rate

Clock

IR_RxD

Start Bit = 0 Data Bit 0 = 1 Data Bit 1 = 0 Data Bit 2 = 1 Data Bit 3 = 1

UART_RxD

16-clock

period

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If this equation results in a value less than one, MIN_PULSE must be set to 0x0h which

enables edge detection and ensures that valid pulses wider than Wmin are accepted. The

field's maximum setting of 0xFh supports a Wmin of 1.25 us when Fsys is 50 MHz.

Jitter

Due to the inherent sampling of the received IR_RxD signal by the Bit Rate Clock, some

jitter is expected on the first bit in any sequence of data. However, all subsequent bits in

the received data stream are a fixed 16 clock periods wide.

Infrared Encoder/Decoder Signal Pins

The endec signal pins, IR_TxD and IR_RxD, are multiplexed with General Purpose

Input/Output (GPIO) pins. These GPIO pins must be configured for alternate function

operation for the endec to operate.

The remaining six UART0 pins, CTS0, DCD0, DSR0, DTR0, RTS and RI0, are not

required for use with the endec. The UART0 modem status interrupt must be disabled to

prevent unwanted interrupts from these pins. The GPIO pins corresponding to these six

unused UART0 pins are used for inputs, outputs, or interrupt sources. Rec ommended

GPIO Port D control register settings are provided in Table 109. See General Purpose

Input/Output on page 49 for additional information on setting the GPIO Port modes.

Loopback Testing

Both internal and external loopback testing is accomplished with the endec on the eZ80F91

device. Internal loopback testing is enabled by setting the LOOP_BACK bit to 1. During

internal loopback, the IR_TxD output signal is inverted and connected on-chip to the

IR_RxD input

External loopback testing of the of f-chip IrDA transceiver is accomplished

by transmitting data from the UART while the receiver is enabled (IR_RxEN set to 1).

Table 109. GPIO Mode Selection when using the IrDA Encoder/Decoder

GPIO Port D

Bits Allowable GPIO

Port Mode Allowable Port Mode Functions

PD0 7 Alternate Function

PD1 7 Alternate Function

PD2–PD7 Any other than GPIO Mode 7

(1, 2, 3, 4, 5, 6, 8, or 9) Output, Input, Open-Drain, Open-Source, Level-

sensitive Interrupt Inpu t, or Edge-Triggered Interrupt

Input

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Infrared Encoder/Decoder Register

After a RESET, the Infrared Encoder/Decoder Register is set to its default value. Any

Writes to unused register bits ar e igno red and reads return a value of 0. The IR_CTL regis-

ter is described in Table 110.

Table 110. Infrared Encoder/Decoder Control Registers (IR_CTL = 00BFh)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R R/W R/W R/W

Note: R = Read only; R/W = Read/Write.

Bit

Position Value Description

[7:4]

MIN_PULSE 0000 Minimum receive pulse width control. When this field is equal to

0x0, the IrDA decoder uses ed ge detection to accept arbitr arily

narrow (that is, short) input pulses.

1h-Fh When not equal to 0x0, this field forms the most-significant four

bits of the 6-bit down-counter used to determine if an input

pulse will be ignored because it is too narrow. The lower two

counter bits ar e hard-coded to loa d with 0x3, resulting in a total

down-count equal to ((IR_CTL[4:0]MIN_PULSE * 4) + 3). T o be

accepted, input pulses must have a width greater than or e qual

to the down-count value times the system clock period.

3 0 Reserved.

LOOP_BACK 0 Internal LOOP BACK mode is disabled.

1 Internal LOOP BACK mode is enabled.

IR_TxD output is inverted and connected to IR_RxD input for

internal loop back testing.

IR_RxEN 0 IR_RxD data is ignored.

1 IR_RxD data is passed to UART0 RxD.

IR_EN 0 Endec is disabled.

1 Endec is enabled.

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Serial Peripheral Interface

The Serial Peripheral Interface (SPI) is a synchronous interface allowing several SPI-type

devices to be interconnected. The SPI is a full-duplex, synchronous, character-o rien ted

communication channel that employs a four-wire interface. The SPI block consists of a

transmitter, receiver, baud rate generator, and control unit. During an SPI transfer, data is

sent and received simultaneously by both the master and the slave SPI devices.

In a serial peripheral interface, separate signals are required for data and clock. The SPI is

configured either as a master or as a slave. The connection of two SPI devices (one master

and one slave) and the direction of data transfer is demonstrated in Figure 40 and

Figure 41.

Figure 40. SPI Master Device

Figure 41. SPI Slave Device

MASTER

MISO DATAOUT

CLKOUT

Bit 0

8-Bit Shift Register

Baud Rate

Generator

Bit 7

SCK

DATAIN

SLAVE

MOSI MISO

SCK

DATAOUT

Bit 0

8-Bit Shift Register

Bit 7

DATAIN

ENABLE

CLKIN

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SPI Signals

The four basic SPI signals are:

•

MISO (Master In, Slave Out)

•

MOSI (Master Out, Slave In)

•

SCK (SPI Serial Clock)

•

SS (Slave Select)

These SPI signals are discussed in the following paragraphs. Each signal is described in

both MASTER and SLAVE modes.

Master In, Slave Out

The Master In, Slave Out (MISO) pin is configured as an input in a master device and as

an output in a slave device. It is one of the tw o lines that transfer serial data, with the most-

significant bit sent first. The MISO pin of a slave device is placed in a high-impedance

state if the slave is not selected. When the SPI is not enabled, this signal is in a high-

impedance state.

Master Out, Slave In

The Master Out, Slave In (MOSI) pin is configured as an output in a master device and as

an input in a slave device. It is one of the two lines that transfer serial data, with the most-

significant bit sent first. When the SPI is not enabled, this signal is in a high-impedance

state.

Slave Select

The active Low Slave Select (SS) input signal is used to select the SPI as a slave device. It

must be Low prior to all data communication and must stay Low for the duration of the

data transfer.

The SS input signal must be High for the SP I to operate as a master device. If the SS signal

goes Low in Master mode, a Mode Fault error flag (MODF) is set in the SPI_SR register.

For more information, see SPI Status Register on page 211.

When the clock phase (CPHA) is set to 0, the shift clock is the logical OR of SS with

SCK. In this clock phase mode, SS must go High between successive characters in an

SPI message. When CPHA is set to 1, SS remains Low for several SPI characters. In

cases where there is only one SPI slave, its SS line could be tied Low as long as CPHA

is set to 1. For more information on CPHA, see SPI Control Register on page 210.

Serial Clock

The Serial Clock (SCK) is used to synchronize data movement both in and out of the

device via its MOSI and MISO pins. The master and slave are each cap able of excha nging

a byte of data during a sequence of eight clock cycles. Because SCK is generated by the

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master, the SCK pin becomes an input on a slave device. The SPI contains an internal

divide-by-two clock divider. In MASTER mode, the SPI serial clock is one-half the fre-

quency of the clock signal created by the SPI’s Baud Rate Generator.

As demonstrated in Figure 42 and Table 111, four possible timing relations are chosen by

using the clock polarity (CPOL) and clock phase CPHA control bits in the SPI Control

with the identical timing, CPOL, and CPHA. The master device always places data on the

MOSI line a half-cycle before the clock edge (SCK signal), for the slave device to latch

the data.

Figure 42. SPI Timing

Table 111. SPI Clock Phase and Clock Polarity Operation

CPHA CPOL

SCK

Transmit

Edge

SCK

Receive

Edge

SCK

Idle

State

SS High

Between

Characters?

0 0 Falling Rising Low Yes

0 1 Rising Falling High Yes

1 0 Rising Falling Low No

1 1 Falling Rising High No

SCK (CPOL bit = 0)

SCK (CPOL bit = 1)

Sample Input

(CPHA bit = 0) Data Out

Sample Input

(CPHA bit = 1) Data Out

ENABLE (To Slave)

Number of Cycles on the SCK Signal

12345678

MSB 6 5 4 3 2 1 LSB

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SPI Functional Description

When a master transmits to a slave device via the MOSI signal, the slave device responds

by sending data to the master via the master's MISO signal. The result is a full-duplex

transmission, with both data out and data in synchronized with the same clock signal. The

byte transmitted is replaced by the byte received, eliminating the need for separate trans-

mit-empty and receive-full status bits. A single status bit, SPIF, is used to signify that the

I/O operation is complete. See SPI Status Register on page 211.

The SPI is double-buffered during reads, but not during Writes. If a Write is performed

during data tra nsfer, the transfer occurs uninterrupted, and the Write is unsuccessful. This

condition causes the write collision (WCOL) status bit in the SPI_SR register to be set.

After a data byte is shifted, the SPI flag of the SPI_SR register is set to 1.

In SPI MASTER mode, the SCK pin functions as an output. It idles High or Low depend-

ing on the CPOL bit in the SPI_CTL register until data is written to the shift register. Data

transfer is initiated by writing to the transmit shift register , SPI_TSR. Eight cl ocks are then

generated to shift the eight bits of transmit data out via the MOSI pin while shifting in

eight bits of data via the MISO pin. After transfer, the SCK signal becomes idle.

In SPI SLAVE mode, the start logic receives a logic Low from the SS pin and a clock

input at the SCK pin; as a result, the slave is synchronized to the master. Data from the

master is received serially from the slave MOSI signal and is loaded into the 8-bit shift

buffer. During a Write cycle, data is written into the shift register. Next, the slave waits for

the SPI master to initiate a data transfer , supply a clock signal , and shift the data out on the

slave's MISO signal.

If the CPHA bit in the SPI_CTL register is 0, a transfer begins when the SS pin signal goes

Low. The transfer ends when SS goes High after eight clock cycles on SCK. When the

CPHA bit is set to 1, a transfer begins the first time SCK becomes active while SS is Low.

The transfer ends when the SPI flag is set to 1.

SPI Flags

Mode Fault

The Mode Fault flag (MODF) indicates that there is a multimaster conflict in the system

control. The MODF bit is normally cleared to 0 and is only set to 1 when the master

device’s SS pin is pulled Low. When a mode fault is detected, the following sequence

occurs:

1. The MODF flag (SPI_SR[4]) is set to 1.

2. The SPI device is disabled by clearing the SPI_EN bit (SPI_CTL[5]) to 0.

3. The MASTER_EN bit (SPI_CTL[4]) is cleared to 0, forcing the device into SLAVE

mode.

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4. If the SPI interrupt is enabled by setting IRQ_EN (SPI_CTL[7]) High, an SPI inter-

rupt is generated.

Clearing the Mode Fault flag is performed by reading the SPI Status register. The other

SPI control bits (SPI_EN and MASTER_EN) must be restored to their original states by

user software after the Mode Fault Flag is cleared to 0.

Write Collision

The write collision flag, WCOL (SPI_SR[5]), is set to 1 when an attempt is made to write

to the SPI Transmit Shift register (SPI_TSR) while data transfer occurs. Clearing the

WCOL bit is performed by reading SPI_SR with the WCOL bit set to 1.

SPI Baud Rate Generator

The SPI’s Baud Rate Generator (BRG) creates a lower frequency clock from the high-fre-

quency system clock. The BRG output is used as the clock source by the SPI.

Baud Rate Generator Functional Description

The SPI’s BRG consists of a 16-bit downcounter, two 8-bit registers, and associated

decoding logic. The BRG’s initial value is defined by the two BRG Divisor Latch registers

{SPI_BRG_H, SPI_BRG_L}. At the rising edge of each system clock, the BRG decre-

ments until it reaches the value 0001h. On the next system clock rising edge, the BRG

reloads the initial value from {SPI_BRG_H, SPI_BRG_L) and outputs a pulse to indicate

the end of the count.

The SPI Data Rate is calculated using the following equation:

Upon RESET, the 16-bit BRG divisor value resets to 0002h. When the SPI is operating as

a Master, the BRG divisor value must be set to a value of 0003h or greater. When the SPI

is operating as a Slave, the BRG divisor value must be set to a value of 0004h or greater.

A software Write to either the Low- or High-byte registers for the BRG Divisor Latch

causes both the Low and High bytes to load into the BRG counter , and causes the count to

restart.

Data Transfer Procedure with SPI Configured as a Master

The following list describes the procedure for transferring data from a master SPI device

to a slave SPI device.

SPI Data Rate (bits/s) = System Clock Frequency

2 X SPI Baud Rate Generator Divisor

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1. Load the SPI BRG Registers, SPI_BRG_H and SPI_BRG_L. The external device

must deassert the SS pin if currently asserted.

2. Load the SPI Control Register, SPI_CTL.

3. Assert the ENABLE pin of the slave device using a GPIO pin.

4. Load the SPI Transmit Shift Register, SPI_TSR.

5. When the SPI data transfer is complete, deassert the ENABLE pin of the slave device.

Data Transfer Procedure with SPI Configured as a Slave

The following list describes the procedure for transferring data from a slave SPI device to

a master SPI device.

1. Load the SPI BRG Registers, SPI_BRG_H and SPI_BRG_L.

2. Load the SPI Transmit Shift Register, SPI_TSR. This load cannot occur while the SPI

slave is currently receiving data.

3. Wait for the external SPI Master device to initiate the data transfer by asserting SS.

SPI Registers

There are six registers in the Serial Peripheral Interface that provide control, status, and

data storage functions. The SPI registers are described in the following paragraphs.

SPI Baud Rate Generator Registers—Low Byte and High Byte

These registers hold the Low and High bytes of the 16-bit divisor cou nt loaded by the CPU

for baud rate generation. The 16-bit clock divisor value is returned by {SPI_BRG_H,

SPI_BRG_L}. Upon RESET, the 16-bit BRG divisor value resets to 0002h. When config-

ured as a Master, the 16-bit divisor value must be between 0003h and FFFFh, inclusive.

When configured as a Slave, the 16-bit divisor value must be between 0004h and FFFFh,

inclusive.

A Write to either the Low- or High-byte registers for the BRG Divisor Latch causes both

bytes to be loaded into the BRG counter and a restart of the count. See Table 112 and

Table 113 on page 209.

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Table 112. SPI Baud Rate Generator Register—Low Byte (SPI_BRG_L = 00B8h)

Bit 76543210

Reset 00000010

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit

Position Value Description

[7:0]

SPI_BRG_L 00h–

FFh

These bits represent the Low byte of the 16-bit BRG divider

value. Th e complete BRG divisor value is returned by

{SPI_BRG_H, SPI_BRG_L}.

Table 113. SPI Baud Rate Generator Register—High Byte (SPI_BRG_H = 00B9h)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit

Position Value Description

[7:0]

SPI_BRG_H 00h–

FFh

These bits represent the High byte of the 16-bit BRG divider

value. Th e complete BRG divisor value is returned by

{SPI_BRG_H, SPI_BRG_L}.

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SPI Control Register

This register is used to control and setup the serial peripheral interface. The SPI must be

disabled prior to making any changes to CPHA or CPOL. See Table 114.

Table 114. SPI Control Register (SPI_CTL = 00BAh)

Bit 76543210

Reset 00000100

CPU Access R/W R R/W R/W R/W R/W R R

Note: R = Read Only; R/W = Read/Write.

Bit

Position Value Description

IRQ_EN 0 SPI system interrupt is disabled.

1 SPI system interrupt is enabled.

6 0 Reserved.

SPI_EN 0 SPI is disabled.

1 SPI is enabled.

MASTER_EN 0 When enabled, the SPI operates as a slave.

1 When enabled, the SPI operates as a master.

CPOL 0 Master SCK pin idles in a Low (0) state.

1 Master SCK pin idles in a High (1) state.

CPHA 0SS

must go High after transfer of every byte of data.

1SS

remains Low to transfer any number of data bytes.

[1:0] 00 Reserved.

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SPI Status Register

The SPI Status Read Only register returns the status of data transmitted using the serial

peripheral interface. Reading the SPI_SR register clears Bits 7, 6, and 4 to a logical 0.

See Table 115.

SPI Transmit Shift Register

The SPI Transmit S hift register (SPI_TSR) i s used by the SPI master to transmit data over

SPI serial bus to the slave device. A W rite to the SPI_TSR register places data directly into

the shift register for transmission. A Write to this register within an SPI device configured

as a master initiates transmission of the byte of the data loaded into the register. At the

completion of transmitting a byte of data, the SPI Flag (SPI_SR[7]) is set to 1 in both the

master and slave devices.

The SPI Transmit Shift Write Only register shares the same address space as the SPI

Receive Buffer Read Only register. See Table 116 on page 212.

Table 115. SPI Status Register (SPI_SR = 00BBh)

Bit 76543210

Reset 00000000

CPU Access RRRRRRRR

Note: R = Read Only.

Bit

Position Value Description

SPIF

0 SPI data transfer is not finished.

1SPI data transfer is finished. If enabled, an interrupt is

generated. This bit flag is cleared to 0 by a Read of the

SPI_SR register.

WCOL

0 An SPI write collision is not detected.

1An SPI write collision is detected. This bit Flag is cleared to 0

by a Read of the SPI_SR registers.

5 0 Reserved.

MODF

0 A mode fault (multimaster conflict) is not detected.

1A mode fault (multimaster conflict) is detected. This bit Flag is

cleared to 0 by a Read of the SPI_SR register.

[3:0] 0000 Reserved.

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SPI Receive Buffer Register

The SPI Receive Buffer register (SPI_RBR) is used by the SPI slave to receive data from

the serial bus. The SPIF bit must be cleared prior to a second transfer of data from the shift

causes the overrun is lost.

The SPI Receive Buffer Read Only register shares the same address space as the SPI

Transmit Shift Write Only register. See Table 117.

Table 116. SPI Transmit Shift Register (SPI_TSR = 00BCh)

Bit 76543210

Reset XXXXXXXX

CPU Access WWWWWWWW

Note: W = Write Only.

Bit

Position Value Description

[7:0]

TX_DATA 00h–FFh SPI transmit data.

Table 117. SPI Receive Buffer Register (SPI_RBR = 00BCh)

Bit 76543210

Reset XXXXXXXX

CPU Access RRRRRRRR

Note: R = Read Only.

Bit

Position Value Description

[7:0]

RX_DATA 00h–FFh SPI received data.

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I2C Serial I/O Interface

I2C General Characteristics

The Inter-Integrated Circuit (I2C) serial I/O bus is a two-wire communication interface

that operates in four modes:

•

MASTER TRANSMIT

•

MASTER RECEIVE

•

SLAVE TRANSMIT

•

SLAVE RECEIVE

The I2C interface consists of a Serial Clock (SCL) and Serial Data (SDA). Both SCL and

SDA are bidirectional lines connected to a positive supply voltage via an external pull-up

resistor. When the bus is free, both lines are High. The output stages of devices connected

to the bus must be configured as open-drain outputs. Data on the I2C bus are transferred at

a rate of up to 100 kbps in STANDARD mode, or up to 400 kbps in FAST mode. One

clock pulse is generated for each data bit transferred.

Clocking Overview

If another device on the I2C bus drives the clock line when the I2C is in MASTER mode,

the I2C synchronizes its clock to the I2C bus clock. The High period of the clock is

determined by the device that generates the short est High clock period. The Low period of

the clock is determined by the device that generates the longest Low clock period.

The Low period of the clock is stretch ed by a slave to slow down th e bus master. The Low

period is also stretched for handsh aking purposes . This result is accomplished after each

bit transfer or each byte transfer. The I2C stretches the clock after each byte transfer until

the IFLG bit in the I2C_CTL register is cleared to 0.

Bus Arbitration Overview

In MASTER mode, the I2C checks that each transmitted logic 1 appears on the I2C bus as

a logic 1. If another device on the bus overrules and pulls the SDA signal Low, arbitration

is lost. If arbitration is lost during the transmission of a data byte or a Not Acknowledge

(NACK) bit, the I2C returns to an idle state. If arbitration is lost during the transmission of

an address, the I2C switches to SLAVE mode so that it recognizes its own slave address or

the general call address.

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Data Validity

The data on the SDA line mu st be stable during the Hig h pe riod of the clo ck. Th e High o r

Low state of the data line changes only when the clock signal on the SCL line is Low, as

illustrated in Figure 43.

START and STOP Conditions

Within the I2C bus protocol, unique situations arise which are defined as START and

STOP conditions. Figure 44 illustrates a High-to-Low transition on the SDA line while

SCL is High, indicating a START condition. A Low-to-High transition on the SDA line

while SCL is High defines a STOP condition.

STAR T and ST OP conditions are always generated by the master. The bus is considered to

be busy after a START condition. The bus is considered to be free for a defined time after

a STOP condition.

Figure 43. I2C Clock and Data Relationship

Figure 44. START and STOP Conditions In I2C Protocol

SDA Signal

SCL Signal

Data Line

Stable

Data Valid

Change of

Data Allowed

SDA Signal

START Condition STOP Condition

SCL Signal SP

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Transferring Data

Byte Format

Every character transferred on the SDA line must be a single 8-bit byte. The number of

bytes that is transmitted per transfer is unrestricted. Each byte must be followed by an

Acknowledge (ACK). Data is transferred with the most-significant bit (msb) first.

Figure 45 illustrates a receiver that holds the SCL line Low to force the transmitter into a

Wait state. Data transfer then continues when the receiver is ready for another byte of data

and releases SCL.

Acknowledge

Data transfer with an ACK function is obligatory. The ACK-related clock pulse is gen-

erated by the master. The transmitter releases the SDA line (High) during the ACK

clock pulse. The receiver must pull down the SDA line during the ACK clock pulse so

that it remains stable (Low) during the High period of this clock pulse. See Figure 46

on page 216.

A receiver that is addressed is obliged to generate an ACK after each byte is received.

When a slave receiver does not acknowledge the slave address (for example, unable to

receive because it is performing some real-time function), the data line must be left High

by the slave. The master then generates a STOP condition to abort the transfer.

If a slave receiver acknowledges the slave addre ss, but cannot receive any more data

bytes, the master must abort the transfer. The abort is indicated by the slave generating the

Not Acknowledge (NACK) on the first byte to follow. The slave leaves the data line High

and the master generates the STOP condition.

If a master receiver is involved in a transfer , it must signal the end of the data stream to the

slave transmitter by not generating an ACK on the final byte that is clocked out of the

slave. The slave transmitter must release the data line to allow the master to generate a

STOP or a repeated START condition.

Figure 45. I2C Frame Structure

SDA Signal

SCL Signal

START Condition

Clock Line Held Low By Receiver

STOP Condition

S P

Acknowledge from

Receiver

MSB

ACK

91912 8

Acknowledge from

Receiver

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Clock Synchronization

All masters generate their own clocks on the SCL line to transfer messages on the I2C bus.

Data is only valid during the High period of each clock.

Clock synchronization is performed using the wired AND connection of the I2C interfaces

to the SCL line, meaning that a High-to-Low transition on the SCL line causes the relevant

devices to start counting from their Low period. When a device clock goes Low, it holds

the SCL line in that state until the clock High state is reached. See Figure 47 on page 217.

The Low-to-High transition of this clock, however, cannot change the state of the SCL

line if another clock is still within its Low period. The SCL line is held Low by the device

with the longest Low period. Devices with shorter Low periods enter a High wait state

during this time.

When all devices count of f the Low period, the clock line is released and goes High. There

is no difference between the device clocks and the state of the SCL line; all of the devices

start counting the High periods. The first device to complete its High period again pulls

the SCL line Low. In this way, a synchronized SCL clock is generated with its Low period

determined by the device with the longest clock Low period, and its High period

determined by the device with the shortest clock High period.

Figure 46. I2C Acknowledge

Data Output

by Transmitter

Data Output

by Receiver

SCL Signal

from Master

START Condition

MSB

Clock Pulse for Acknowledge

912 8

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Arbitration

Any master initiates a transfer if the bus is free. As a result, multiple masters each gener-

ates a START condition if the bus is free within a minimum period. If multiple masters

generate a STAR T condition, a START is defined for the bus. However , arbitration defines

which MASTER controls the bus. Arbitration takes place on the SDA line. As mentioned,

STAR T conditions are initiated only while the SCL line is held High. If during this period,

a master (M1) initiates a High-to-Low transition—that is, a START condition—while a

second master (M2) transmits a Low signal on the line, then the first master, M1, cannot

take control of the bus. As a result, the data output stage for M1 is disabled.

Arbitration continues for many bits. Its first stage is comparison of the address bits. If the

masters are each trying to address the same device, arbitration continues with a compari-

son of the data. Because address and data information on the I2C bus is used for arbitra-

tion, no information is lost during this process. A master that loses the arbitration

generates clock pulses until the end of the byte in which it loses the arbitration.

If a master also incorporates a slave function and it loses arbitration during the addressing

stage, it is possible that the winning master is trying to address it. The losing master must

switch over immediately to its slave receiver mode. Figure 47 illustrates the arbitration

procedure for two masters. Of course, more masters can be involved, depending on how

many masters are connected to the bus. The moment there is a difference between the

internal data level of the master generating DATA 1 and the actual level on the SDA line,

its data output is switched off, which means that a High output level is then connected to

the bus. As a result, the data transfer initiated by the winning master is not affected.

Because control of the I2C bus is decided solely on the address and data sent by competing

masters, there is no central master, nor any order of priority on the bus.

Special attention must be paid if, during a serial transfer, the arbitration procedure is still

in progress at the moment when a repeated START condition or a STOP condition is trans-

mitted to the I2C bus. If it is possible for such a situation to occur, the masters involved

Figure 47. Clock Synchronization In I2C Protocol

CLK1 Signal

CLK2 Signal

SCL Signal

Counter

Reset

Wait

State Start Counting

High Period

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must send this repeated START condition or STOP condition at the same position in the

format frame. In other words, arbitration is not allowed between:

•

A repeated START condition and a data bit.

•

A STOP condition and a data bit.

•

A repeated START condition and a STOP condition.

Clock Synchronization for Handshake

The clock-synchronizing mechanism functions as a handshake, enabling receivers to cope

with fast data transfers, on either a byte or a bit level. The byte level allows a device to

receive a byte of data at a fast rate, but allows the device more time to store the received

byte or to prepare another byte for transmission. Slaves hold the SCL line Low after recep-

tion and acknowledge the byte, forcing the master into a Wait state until the slave is ready

for the next byte transfer in a handshake procedure.

Operating Modes

Master Transmit

In MASTER TRANSMIT mode, the I2C transmits a number of bytes to a slave receiver.

Enter MASTER TRANSMIT mode by setting the STA bit in the I2C_CTL register to 1.

The I2C then tests the I2C bus and transmits a START condition when the bus is free.

When a START condition is transmitted, the IFLG bit is 1 and the status code in the

I2C_SR register is 08h. Before this interrupt is serviced, the I2C_DR register must be

loaded with either a 7-bit slave address or the first part of a 10-bit slave address, with the

lsb cleared to 0 to specify TRANSMIT mode. The IFLG bit must now be cleared to 0 to

prompt the transfer to continue.

After the 7-bit slave address (or the first part of a 10-bit address) plus the Write bit are

transmitted, the IFLG is set again. A number of status codes are possible in the I2C_SR

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Table 118. I2C Master Transmit Status Codes

Code I2C State ASSP Response Next I2C Action

18h Addr+W transmitted

ACK received1For a 7-bit address: write byte to DATA,

clear IFLG Transmit data byte,

receive ACK

Or set STA, clear IFLG Transmit repeated

START

Or set STP, clear IFLG Transmit STOP

Or set STA & STP, clear IFLG Transmit STOP then

START

For a 10-bit address: wr ite extended

address byte to data, clear IFLG Transmit extended

address byte

20h Addr+W transmitted,

ACK not received Same as code 18h Same as code 18h

38h Arbitration lost Clear IFLG Return to idle

Or set STA, clear IFLG Transmit START when

bus is free

68h Arbitration lost,

+W received,

ACK transmitted

Clear IFLG, AAK = 02Rec eiv e data byte,

transmit NACK

Or clear IFLG, AAK = 1 Receive data byte,

transmit ACK

78h Arbitration lost,

General call address

received, ACK

transmitted

Same as code 68h Same as code 68h

B0h Arbitration lost,

SLA+R received,

ACK transmitted3

Write byte to DATA, clear IFLG, clear AAK

= 0 Transmit last byte,

receive ACK

Or write byte to DATA, clear IFLG, set AAK

= 1 Transmit data byte,

receive ACK

Notes

1. W is defin ed as the Write bit; that is, the lsb is cleared to 0.

2. AAK is an I2C control bit that identifies which ACK signal to transmit.

3. R is defined as the Read bit; that is, the lsb is set to 1.

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If 10-bit addressing is used, the status code is 18h or 20h after the first part of a 10-bit

address, plus the Write bit, are successfully transmitted.

After this interrupt is serviced and the second part of the 10-bit address is transmitted, the

I2C_SR register contains one of the codes listed in Table 119.

Table 119. I2C 10-Bit Master Transmit Status Codes

Code I2C State ASSP Response Next I2C Action

38h Arbitration lost Clear IFLG Return to idle

Or set STA, clear IFLG Transmit START when bus free

68h Arbitration lost,

SLA+W received,

ACK transmitted1

Clear IFLG, clear AAK = 02Receive data byte, transmit NACK

Or clear IFLG, set AAK = 1 Receive data byte, transmit ACK

B0h Arbitration lost,

SLA+R received,

ACK transmitted3

Write byte to DATA,

clear IFLG, clear AAK = 0 Transmit last byte,

receive ACK

Or write byte to DATA,

clear IFLG, set AAK = 1 Transmit data byte,

receive ACK

D0h Second address byte

+ W transmitted,

ACK received

Write byte to data,

clear IFLG Transmit data byte,

receive ACK

Or set STA, clear IFLG Transmit repeated STAR T

Or set STP, clear IFLG Transmit STOP

Or set STA & STP,

clear IFLG Transmit STOP then

START

D8h Second address byte

+ W transmitted,

ACK not received

Same as code D0h Same as code D0h

Notes

1. W is defin ed as the Write bit; that is, the lsb is cleared to 0.

2. AAK is an I2C control bit that identifies which ACK signal to transmit.

3. R is defined as the Read bit; that is, the lsb is set to 1.

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If a repeated START condition is transmitted, the status code is 10h instead of 08h.

After each data byte is transmitted, the IFLG is set to 1 and one of the st atus codes listed in

Table 120 is loaded into the I2C_SR register.

When all bytes are transmitted, the ASSP must write a 1 to the STP bit in the I2C_CTL

state.

Master Receive

In MASTER RECEIVE mode, the I2C receives a number of bytes from a slave

transmitter.

After the START condition is transmitted, the IFLG bit is 1 and the status code 08h is

loaded into the I2C_SR register. The I2C_DR register must be loaded with the slave

address (or the first part of a 10-bit slave address), with the lsb set to 1 to signify a Read.

The IFLG bit must be cleared to 0 as a prompt for the transfer to continue.

When the 7-bit slave address (or the first part of a 10-bit address) and the Read bit are

transmitted, the IFLG bit is set and one of the status codes listed in Table 121 on page 222

is loaded into the I2C_SR register.

Table 120. I2C Master Transmit Status Codes For Data Bytes

Code I2C State ASSP Response Next I2C Action

28h Data byte transmitted,

ACK received Write byte to data,

clear IFLG Transmit data byte,

receive ACK

Or set STA, clear IFLG Transmit repeated START

Or set STP, clear IFLG Transmit STOP

Or set STA & STP,

clear IFLG Transmit START then STOP

30h Data byte transmitted,

ACK not received Same as code 28h Same as code 28h

38h Arbitration lost Clear IFLG Return to idle

Or set STA, clear IFLG Transmit START when bus free

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If 10-bit addressing is being used, the slave is first addressed using the full 10-bit address,

plus the Write bit. The master then issues a restart followed by the first part of the 10-bit

Table 121. I2C Master Receive Status Codes

Code I2C State ASSP Response Next I2C Action

40h Addr + R transmitted,

ACK received For a 7-bit address,

clear IFLG, AAK = 01Receive data byte,

transmit NACK

Or clear IFLG, AAK = 1 Receive data byte,

transmit ACK

For a 10-bit address

Write extended address

byte to data, clear IFLG

Transmit extended address byte

48h Addr + R transmitted,

ACK not received2For a 7-bit address:

Set STA, clear IFLG Transmit repeated START

Or set STP, clear IFLG Transmit STOP

Or set STA & STP,

clear IFLG Transmit STOP then START

For a 10-bit address:

Write extended add ress byte to

data, clear IFLG

Transmit extended address byte

38h Arbitration lost Clear IFLG Return to idle

Or set STA, clear IFLG Transmit START when bus is free

68h Arbitration lost,

SLA+W received,

ACK transmitted3

Clear IFLG, clear AAK = 0 Receive data byte,

transmit NACK

Or clear IFLG, set AAK = 1 Receive data byte,

transmit ACK

78h Arbitration lost,

General call addr

received, ACK

transmitted

Same as code 68h Same as code 68h

B0h Arbitration lost,

SLA+R received,

ACK transmitted

Write byte to DATA,

clear IFLG, clear AAK = 0 Transmit last byte,

receive ACK

Or write byte to DATA,

clear IFLG, set AAK = 1 Transmit data byte,

receive ACK

Notes

1. AAK is an I2C control bit that identifies which ACK signal to transmit.

2. R is defined as the Read bit; that is, the lsb is set to 1.

3. W is defin ed as the Write bit; that is, the lsb is cleared to 0.

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address again, this time with the Read bit. The status code then becomes 40h or 48h. It is

the responsibility of the slave to remember that it had been selected prior to the restart.

If a repeated START condition is received, the status code is 10h instead of 08h.

After each data byte is received, the IFLG is set to 1 and one of the status codes listed in

Table 122 is loaded into the I2C_SR register.

When all bytes are received, a NACK must be sent, then the ASSP must write 1 to the STP

bit in the I2C_CTL register. The I2C then transmits a STOP condition, clears the STP bit

and returns to an idle state.

Slave Transmit

In SLAVE TRANSMIT mode, a number of bytes are transmitted to a master receiver.

The I2C enters SLAVE TRANSMIT mode when it receives its own slave address and a

Read bit after a START condition. The I2C then transmits an ACK bit (if the AAK bit is

set to 1); it then sets the IFLG bit in the I 2C_CTL register. As a result, the I2C_SR register

contains the status code A8h.

When I2C contains a 10-bit slave address (signified by the address range F0h–F7h in the

I2C_SAR register), it transmits an ACK when the first address byte is received after a

restart. An interrupt is generated and IFLG is set to 1; however , the status does not change.

No second address byte is sent by the master. It is up to the slave to remember it had been

selected prior to the restart.

Table 122. I2C Master Receive Status Codes For Data Bytes

Code I2C State ASSP Response Next I2C Action

50h Data byte received,

ACK transmitted Read data, clear IFLG,

clear AAK = 0* Receive data byte,

transmit NACK

Or read data, clear IFLG,

set AAK = 1 Receive data byte,

transmit ACK

58h Data byte received,

NACK transmitted Read data, set STA,

clear IFLG Transmit repeated

START

Or read data, set STP,

clear IFLG Transmit STOP

Or read data, set

STA & STP, clear IFLG Transmit STOP then

START

38h Arbitration lost in

NACK bit Same as master transmit Same as master

transmit

Note: AAK is an I2C control bit that identifies which ACK signal to transmit.

Note:

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I2C goes from MASTER mode to SLAVE TRANSMIT mode when arbitration is lost dur-

ing the transmission of an address, and the slave address and Read bit are received. This

action is represented by the status code B0h in the I2C_SR register.

The data byte to be transmitted is loaded into the I2C_DR register and the IFLG bit is

cleared to 0. After the I2C transmits the byte and receives an ACK, the IFLG bit is set to 1

and the I2C_SR register contains B8h. When the final byte to be transmitted is loaded into

the I2C_DR register, the AAK bit is cleared when the IFLG is cleared to 0. After the final

byte is transmitted, the IFLG is set and the I2C_SR register contains C8h and the I2C

returns to an idle state. The AAK bit must be set to 1 before reentering SLAVE mode.

If no ACK is received after transmitting a byte, the IFLG is set and the I2C_SR register

contains C0h. The I2C then returns to an idle state.

If a STOP condition is detected after an ACK bit, the I2C returns to an idle state.

Slave Receive

In SLAVE RECEIVE mode, a number of data bytes are received from a master transmit-

ter.

The I2C enters SLAVE RECEIVE mode when it receives its own slave address and a

Write bit (lsb = 0) after a START condition. The I2C transmits an ACK bit and sets the

IFLG bit in the I2C_CTL register and the I2C_SR register contains the status code 60h.

The I2C also enters SLAVE RECEIVE mode when it receives the general call address 00h

(if the GCE bit in the I2C_SAR register is set). The status code is then 70h.

When the I2C contains a 10-bit slave address (signified by F0h–F7h in the I2C_SAR reg-

ister), it transmits an acknowledge after the first address byte is received but no interrupt is

generated. IFLG is not set and the status does not change. The I2C generates an interrupt

only after the second address byte is received. The I2C sets the IFLG bit and loads the sta-

tus code as described above.

I2C goes from MASTER mode to SLAVE RECEIVE mode when arbitrati on is lost during

the transmission of an address, and the slave address and Write bit (or the general call

address if the CGE bit in the I2C_SAR regis ter is set to 1) a re receiv ed. The stat us co de in

the I2C_SR register is 68h if the slave address is received or 78h if the general call

address is received. The IFLG bit must be cleared to 0 to allow data transfer to continue.

If the AAK bit in the I2C_CTL register is set to 1 then an ACK bit (Low level on SDA) is

transmitted and the IFLG bit is set after each byte is received. The I2C_SR register con-

tains the two status codes 80h or 90h if SLAVE RECEIVE mode is entered with the gen-

eral call address. The received data byte are read from the I2C_DR register and the IFLG

bit must be cleared to allow the transfer to continue. If a STOP condition or a repeated

STAR T condi tion is detected after the acknowledge bit, the IFLG bit is set and the I2C_SR

Note:

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If the AAK bit is cleared to 0 during a transfer, the I2C transmits a NACK bit (High level

on SDA) after the next byte is received, and sets the IFLG bit to 1. The I2C_SR register

contains the two status codes 88h or 98h if SLAVE RECEIVE mode is entered with the

general call address. The I2C returns to an idle state when the IFLG bit is cleared to 0.

I2C Registers

The section that follows describes each of the eZ80F91 ASSP’s Inter-Integrated Circuit

(I2C) registers.

Addressing

The CPU interface provides access to six 8-bit registers: four Read/Write registers, one

Read Only register and two Write Only registers, as indicated in Table 123.

Resetting the I2C Registers

Hardware Reset—When the I2C is reset by a hardware reset of the eZ80F91 device, the

I2C_SAR, I2C_XSAR, I2C_DR, and I2C_CTL registers are cleared to 00h; while the

I2C_SR register is set to F8h.

Software Reset—Perform a software reset by writing any value to the I2C Software Reset

I2C Slave Address Register

The I2C_SAR register provides the 7-bit address of the I2C when in SLAVE mode and

allows 10-bit addressing in conjunction with the I2C_XSAR register. I2C_SAR[7:1] =

SLA[6:0] is the 7-bit address of the I2C when in 7-bit SLAVE mode. When the I2C

receives this address after a START condition, it enters SLAVE mode. I2C_SAR[7] corre-

sponds to the first bit received from the I2C bus.

Table 123. I2C Register Descriptions

I2C_SAR Slave address register

I2C_XSAR Extended slave address register

I2C_DR Data byte register

I2C_CTL Control register

I2C_SR Sta tus register (Read Only)

I2C_CCR Clock Control register (Write Only)

I2C_SRR Software reset register (Write Only)

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When the register receives an address starting with F7h to F0h (I2C_SAR[7:3] = 11110b),

the I2C recognizes that a 10-bit slave addressing mode is being selected. The I2C sends an

ACK after receiving the I2C_SAR byte (the device does not generate an interrupt at this

point). After the next byte of the address (I2C_XSAR) is received, the I2C generates an

interrupt an d enters SLAVE mode. Then I 2C_SAR[2:1] are u sed as the up per 2 bits for the

10-bit extended address. The full 10-bit address is supplied by {I2C_SAR[2:1],

I2C_XSAR[7:0]}. See Table 124.

I2C Extended Slave Address Register

The I2C_XSAR register is used in conjunction with the I2C_SAR register to provide 10-

bit addressing of the I2C when in SLAVE mode. The I2C_SAR value forms the lower 8

bits of the 10-bit slave address. The full 10-bit address is supplied by {I2C_SAR[2:1],

I2C_XSAR[7:0]}.

When the register receives an address starting with F7h to F0h (I2C_SAR[7:3] = 11110b),

the I2C recognizes that a 10-bit slave addressing mode is being selected. The I2C sends an

ACK after receiving the I2C_XSAR byte (the device does not generate an interrupt at this

point). After the next byte of the address (I2C_XSAR) is received, the I2C generates an

interrupt and enters SLAVE mode.Then I2C_SAR[2:1] are used as the upper 2 bits for the

10-bit extended address. The full 10-bit address is supplied by {I2C_SAR[2:1],

I2C_XSAR[7:0]}. See Table 125 on page 226.

Table 124. I2C Slave Address Register (I2C_SAR = 00C8h)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit

Position Value Description

[7:1]

SLA 00h–7Fh 7-bit slave address or upper 2 bits, I2C_SAR[2:1], of

address when operating in 10-bit mode.

GCE 0I

2C not enabled to recognize the General Call Address.

2C enabled to recognize the General Call Address.

Table 125. I2C Extended Slave Address Register (I2C_XSAR = 00C9h)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

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I2C Data Register

This register contains the data byte/slave address to be transmitted or the data byte just

received. In TRANSMIT mode, the most-significant bit of the byte is transmitted first. In

RECEIVE mode, the first bit received is placed in the most-significant bit of the register.

After each byte is transmitted, the I2C_DR register contains the byte that is present on the

bus in case a lost arbitration event occurs. See Table 126.

I2C Control Register

The I2C_CTL register is a control register that is used to control the interrupts and the

master slave relationships on the I2C bus.

When the Interrupt Enable bit (IEN) is set to 1, the interrupt line goes High when the IFLG

is set to 1. When IEN is cleared to 0, the interrupt line always remains Low.

When the Bus Enable bit (ENAB) is set to 0, the I2C bus inputs SCLx and SDAx are

ignored and the I2C module does not respond to any address on the bus. When ENAB is

set to 1, the I2C res ponds to ca lls to its slave address and to the general call address if the

GCE bit (I2C_SAR[0]) is set to 1.

When the Master Mode Start bit (STA) is set to 1, the I2C enters MASTER mode and

sends a START condition on the bus when the bus is free. If the STA bit is set to 1 when

the I2C module is already in MASTER mode and one or more bytes are transmitted, then a

repeated START condition is sent. If the STA bit is set to 1 when the I2C block is being

accessed in SLAVE mode, the I2C completes the data transfer in SLAVE mode and then

Bit

Position Value Description

[7:0]

SLAX 00h–FFh Least-significant 8 bits of the 1 0-bit extended slave address

Table 126. I2C Data Register (I2C_DR = 00CAh)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit

Position Value Description

[7:0]

DATA 00h–

FFh I2C data byte

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enters MASTER mode when the bus is released. The STA bit is automatically cleared after

a START condition is set. Writing 0 to the STA bit produces no effect.

If the Master Mode Stop bit (STP) is set to 1 in MASTER mode, a STOP condition is

transmitted on the I2C bus. If the STP bit is set to 1 in SLAVE mode, the I2C module oper-

ates as if a STOP condition is received, but no ST OP condition is transmitted. If both STA

and STP bits are set, the I2C block first transmits the STOP condition (if in MASTER

mode), then transmits the START condition. The STP bit is cleared to 0 automatically.

Writing a 0 to this bit produces no effect.

The I2C Interrupt Flag (IFLG) is set to 1 automatically when any of 30 of the possible 31

I2C states is entered. The only state that does not set the IFLG bit is state F8h. If IFLG is

set to 1 and the IEN bit is also set, an interrupt is generated. When IFLG is set by the I2C,

the Low period of the I2C bus clock line is stretched and the data transfer is suspended.

When a 0 is written to IFLG, the interrupt is cleared and the I2C clock line is released.

When the I2C Acknowledge bit (AAK) is set to 1, an acknowledge is sent during the

acknowledge clock pulse on the I2C bus if:

•

Either the whole of a 7-bit slave address or the first or second byte of a 10-bit slave ad-

dress is received.

•

The general call address is received and the General Call Enable bit in I2C_SAR is set

to 1.

•

A data byte is received while in MASTER or SLAVE modes.

When AAK is cleared to 0, a NACK is sent when a data byte is received in MASTER or

SLAVE mode. If AAK is cleared to 0 in SLAVE TRANSMIT mode, the byte in the

I2C_DR register is assumed to be the final byte. After this byte is transmitted, the I2C

block enters the C8h state, then returns to an idle state. The I2C module does not respond

to its slave address unless AAK is set to 1. See Table 127 on page 229.

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Table 127. I2C Control Register (I2C_CTL = 00CBh)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R R

Note: R/W = Read/Write; R = Read Only.

Bit

Position Value Description

IEN 0I

2C interrupt is disabled.

2C interrupt is enabled.

ENAB 0The I

2C bus (SCL/SDA) is disabled and all inp uts are ignor ed.

1The I

2C bus (SCL/SDA) is enabled.

STA 0 Master mode START condition is sent.

1 Master mode start-transmit START condition on the bus.

STP 0 Master mode STOP condition is sent.

1 Master mode stop-transmit STOP condition on the bus.

IFLG 0I

2C interrupt flag is not set.

2C interrupt flag is set.

AAK 0 Not Acknowledge.

1 Acknowledge.

[1:0] 00 Reserved.

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I2C Status Register

The I2C_SR register is a Read Only register that contains a 5-bit status code in the five

most-significant bits; the three least-significant bits are always 0. The Read Only

I2C_SR registers share the same I/O addresses as the Write Only I2C_CCR registers.

See Table 128.

There are 29 possible status codes, as listed in Table 129. When the I2C_SR register

contains the status code F8h, no relevant status information is available, no interrupt is

generated, and the IFLG bit in the I2C_CTL register is not set. All other status codes

correspond to a defined state of the I2C.

When each of these states is entered, the corresponding status code appears in this register

and the IFLG bit in the I2C_CTL register is set to 1. When the IFLG bit is cleared, the sta-

tus code returns to F8h.

Table 128. I2C Status Registers (I2C_SR = 00CCh)

Bit 76543210

Reset 11111000

CPU Access RRRRRRRR

Note: R = Read only.

Bit

Position Value Description

[7:3]

STAT 00000–

11111 5-bit I2C status code.

[2:0] 000 Reserved.

Table 129. I2C Status Codes

Code Status

00h Bus error.

08h START condition transmitted.

10h Repeated START condition transmitted.

18h Address and Write bit transm itt ed , ACK receive d .

20h Address and Write bit transmitted, ACK not received.

28h Data byte transmitted in MASTER mode, ACK received.

30h Data byte transmitted in MASTER mode, ACK not received.

38h Arbitration lost in address or data byte.

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If an illegal condition occurs on the I2C bus, the bus error state is entered (status code

00h). To recover from this state, the STP bit in the I2C_CTL register must be set and the

IFLG bit cleared. The I2C then returns to an idle state. No STOP condition is transmitted

on the I2C bus.

The STP and STA bits are set to 1 at the same time to recover from the bus error. The I2C

then sends a START condition.

40h Address and Read bit transmitted, ACK received.

48h Address and Read bit trans mit te d, ACK not re ce ived.

50h Data byte received in MASTER mode, ACK transmitted.

58h Data byte received in MASTER mode, NACK transmitted.

60h Slave address and Write bit rece ived, ACK transmitted.

68h Arbitration lost in address as master, slave address and Write bit received, ACK transmitted.

70h General Call address received, ACK transmitted.

78h Arbitration lost in address as master, General Call address received, ACK transmitted.

80h Data byte received after slave address received, ACK transmitted.

88h Data byte received after slave address received, NACK transmitted.

90h Data byte received after General Call received, ACK transmitted.

98h Data byte received after General Call received, NACK transmitted.

A0h STOP or repeated START condition received in SLAVE mode.

A8h Slave address and Read bit received, ACK transmitted.

B0h Arbitration lost in address as master, slave address and Read bit received, ACK transmitted.

B8h Data byte transmitted in SLAVE mode, ACK received.

C0h Data byte transmitted in SLAVE mode, ACK no t received.

C8h Last byte transmitted in SLAVE mode, ACK received.

D0h Second Address byte and Write bit transmitted, ACK received.

D8h Second Address byte and Write bit transmitted, ACK not received.

F8h No relevant status information, IFLG = 0.

Table 129. I2C Status Codes (Continued)

Code Status

Note:

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I2C Clock Control Register

The I2C_CCR register is a Write Only register. The seven LSBs control the frequency at

which the I2C bus is sampled and the frequency of the I2C clock line (SCL) when the I2C

is in MASTER mode. The Write Only I2C_CCR registers share the same I/O addresses as

the Read Only I2C_SR registers. See Table 130.

The I2C clocks are derived from the system clock of the eZ80F91 device. The frequency

of this system clock is fSCK. The I2C bus is sampled by the I2C block at the frequency

fSAMP supplied by the following equation:

In MASTER mode, the I2C clock output frequency on SCL (fSCL) is supplied by the fol-

lowing equation:

The use of two separately-programmable dividers allows the MASTER mode output

frequency to be set independently of the frequency at which the I2C bus is sampled. This

feature is particularly useful in multimaster systems because the frequency at which the

I2C bus is sampled must be at least 10 times the frequency of the fastest master on the bus

to ensure that START and STOP conditions are always detected. By using two

Table 130. I2C Clock Control Registers (I2C_CCR = 00CCh)

Bit 76543210

Reset 00000000

CPU Access WWWWWWWW

Note: W = Read only.

Bit

Position Value Description

7 0 Reserved.

[6:3]

M0000–1111 I2C clock divider scalar value.

[2:0]

N000–111 I2C clock divider exponent.

fSAMP =fSCLK

fSCL =fSCLK

10 • (M + 1)(2)N

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programmable clock divider stages, a high sampling frequency is ensured while allowing

the MASTER mode output to be set to a lower frequency.

Bus Clock Speed

The I2C bus is defined for bus clock speeds up to 100 kbps (400 kbps in FAST mode).

To ensure correct detection of START and STOP conditions on the bus, the I2C must sam-

ple the I2C bus at least ten times faster than the bus clock speed of the fastest master on the

bus. The sampling frequency must therefore be at least 1 MHz (4 MHz in FAST mode) to

guarantee corre ct ope ra tion with other bus ma s ters .

The I2C sampling frequency is determined by the frequency of the eZ80F91 system clock

and the value in the I2C_CCR bits 2 to 0. The bus clock speed generated by the I2C in

MASTER mode is determined by the frequency of the input clock and the values in

I2C_CCR[2:0] and I2C_CCR[6:3].

I2C Software Reset Register

The I2C_SRR register is a Write Only register. Writing any value to this register performs

a software reset of the I2C module. See Table 131.

Table 131. I2C Software Reset Register (I2C_SRR = 00CDh)

Bit 76543210

Reset

XXXXXXXX

CPU Access

WWWWWWWW

Note: W = Write Only.

Bit

Position Value Description

[7:0]

SRR 00h–FFh Writing any value to this register performs a software reset

of the I2C module.

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Zilog Debug Interface

Introduction

The Zilog Debug Interface (ZDI) provides a built-in debugging interface to the CPU. ZDI

provides basic in-circuit emulation features including:

•

Examining and modifying internal regi sters.

•

Examining and modifyi ng memo ry.

•

Starting and stopping the user program.

•

Setting program and data break points.

•

Single-stepping the user program.

•

Executing user-supplied instructions.

•

Debugging the final product with the inclusion of one small connector.

•

Downloading code into SRAM.

•

C source-level debugging using Zilog Developer Studio II (ZDS II).

The above features are built into the silicon. Control is provided via a two-wire interface

that is connected to the ZPAK II emulator. Figure 48 illustrates a typical setup using a a

target board, ZPAK II, and the host PC running Zilog Developer Studio II. For more infor-

mation on ZPAK II and ZDS II, refer to www.zilog.com.

ZDI allows reading and writing of most internal registers without disturbing the state of

the machine. Reads and Writes to memory occurs as fast as the ZDI downloads and

Figure 48. Typical ZDI Debug Setup

ZiLOG

Developer

Studio ZPAK

Emulator eZ80

Product

Target Board

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uploads data, with a maximum supported ZDI clock frequency of 0 .4 times the eZ80F91

system clock frequency. Also, regardless of the ZDI clock frequency, the duration of the

low-phase of the ZDI clock (that is, ZCL = 0) must be at least 1.25 times the system clock

period.

For the description on how to enable the ZDI interface on the exit of RESET, see the OCI

Activation on page 262.

ZDI-Supported Protocol

ZDI supports a bidirectional serial protocol. The protocol defines any device that sends

data as the transmitter and any receiving device as the receiver. The device controlling the

transfer is the master and the device being controlled is the slave. The master always ini-

tiates the data transfers and provides the clock for both receive and transmit operations.

The ZDI block on the eZ80F91 device is considered a slave in all data transfers.

Figure 49 on page 237 illustrates the schematic for building a connector on a target board.

This connector allows you to connect directly to the ZPAK emulator using a six-pin

header.

Table 132. Recommend ZDI Clock versus System Clock Frequency

System Clock Frequency ZDI Clock Frequency

3–10 MHz 1 MHz

8–16 MHz 2 MHz

12–24 MHz 4 MHz

20–50 MHz 8 MHz

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ZDI Clock and Data Conventions

The two pins used for communication with the ZDI block are the ZDI clock pin (ZCL) and

the ZDI data pin (ZDA). On eZ80F91, the ZCL pin is shared with the TCK pin while the

ZDA pin is shared with the TDI pin. The ZCL and ZDA pin functions are only available

when the On-Chip Instrumentation is disabled and the ZDI is therefore enabled. For gen-

eral data communication, the data value on the ZDA pin changes only when ZCL is Low

(0). The only exception is the ZDI START bit, which is indicated by a High-to-Low transi-

tion (falling edge) on the ZDA pin while ZCL is High.

Data is shifted into and out of ZDI, with the most-significant bit (bit 7) of each byte being

first in time, and the least-significant bit (bit 0) last in time. All information is passed

between the master and the slave in 8-bit (single-byte) units. Each byte is transferred with

nine clock cycles; eight to shift the data, and the ninth for internal operations.

ZDI START Condition

All ZDI commands are preceded by the ZDI START signal, which is a High-to-Low tran-

sition of ZDA when ZCL is High. The ZDI slave on the eZ80F91 device continually mon-

itors the ZDA and ZCL lines for the START signal and does not respond to any command

until this condition is met. The master pulls ZDA Low, with ZCL High, to indicate the

beginning of a data transfer with the ZDI block. Figure 50 and Figure 51on page 238 illus-

trates a valid ZDI START signal prior to writing and reading data, respectively. A Low-to-

High transition of ZDA while the ZCL is High produces no effect.

Figure 49. Schematic For Building a Target Board ZPAK Connector

6-Pin Target Connector

eZ80F91

10 Kohm 10 Kohm

TCK (ZCL)

TDI (ZDA)

TVDD

(Target V )

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Data is shifted in during a Write to the ZDI block on the rising edge of ZCL, as illustrated

in Figure 50. Data is shifted out during a Read from the ZDI block on the falling edg e of

ZCL as illustrated in Figure 51. When an operation is completed, the master stops during

the ninth cycle and holds the ZCL signal High.

ZDI Single-Bit Byte Separator

Following each 8-bit ZDI data transfer, a single-bit byte separator is used. To initiate a

new ZDI command, the single-bit byte separator must be High (logical 1) to allow for a

new ZDI START command to be sent. For all other cases, the single-bit byte separator is

either Low (logical 0) or High (logical 1). When ZDI is configured to allow the CPU to

Figure 50. ZDI Write Timing

Figure 51. ZDI Read Timing

ZDI Data In

(Write) ZDI Data In

(Write)

Start Signal

ZCL

ZDA

ZDI Data Out

(Read) ZDI Data Out

(Read)

Start Signal

ZCL

ZDA

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accept external bus requests, the single-bit byte separator must be Low (logical 0) during

all ZDI commands. This Low value indicates that ZDI is still operating and is not ready to

relinquish the bus. The CPU does not accept the external bus requests until the single-bit

byte separator is a High (logical 1). For more information on accepting bus requests in

ZDI DEBUG mode, see Bus Requests During ZDI Debug Mode on page 242.

ZDI Register Addressing

Following a START signal the ZDI master must output the ZDI register address. All data

transfers with the ZDI block use special ZDI registers. The ZDI control registers that

reside in the ZDI register address space must not be c on f used with the eZ80F91 device

peripheral registers that reside in the I/O address space.

Many locations in the ZDI control register address space are shared by two registers—one

for Read Only access and one for Write Only access. For example, a Read from ZDI regis-

ter address 00h returns the eZ80® Product ID Low Byte, while a Write to this same loca-

tion, 00h, stores the Low byte of one of the address match values used for generating

break points.

The format for a ZDI address is seven bits of address, fo llowed by one bit for Read or

Write control, and completed by a single-bit byte separator. The ZDI executes a Read or

Write operation depending on the state of the R/W bit (0 = Write, 1 = Read). If no new

START command is issued at completion of the Read or Write operation, the operation is

repeated. This allows repeated Read or Write operations without having to resend the ZDI

command. A START signal must follow to initiate a new ZDI command. Figure 52 illus-

trates the timing for address Writes to ZDI registers.

Figure 52. ZDI Address Write Timing

ZDI Address Byte

Single-Bit

Byte Separator

or new ZDI

START Signal

START

Signal 0 = WRITE

1 = READ

lsbmsb

ZCLS 123456789

A6 A5 A4 A3 A2 A1 A0 R/W 0/1ZDA

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ZDI Write Operations

ZDI Single-Byte Write

For single-byte Write operations, the address and write control bit are first written to the

ZDI block. Following the single-bit byte separator, the data is shifted into the ZDI block

on the next 8 rising edges of ZCL. The master terminates activity after 8 clock cycles.

Figure 53 illustrates the timing for ZDI single-byte Write operations.

ZDI Block Write

The block Write operation is initiated in the same manner as the single-byte Write opera-

tion, but instead of terminating the Write operation after the first data byte is transferred,

the ZDI master continues to transmit additional bytes of data to the ZDI slave on the

eZ80F91 device. After the receipt of each by te of data the ZDI register address increments

by 1. If the ZDI register address reaches the end of the Write Only ZDI register address

space (30h), the address stops incremen ting. Figure 54 illustrates the timing for ZDI block

Write operations.

Figure 53. ZDI Single-Byte Data Write Timing

ZDI Data Byte

lsb of

ZDI Address Single-Bit

Byte Separator

lsb

of DATA

msb

of DATA

End of Data

or New ZDI

START Signal

ZCL789123456789

A0 Write 0/1 D7 D6 D5 D4 D3 D2 D1 D0 1

ZDA

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ZDI Read Operations

ZDI Single-Byte Read

Single-byte Read operations are initiated in the same manner as single-byte Write opera-

tions, with the exception that the R/W bit of the ZDI register address is set to 1. Upon

receipt of a slave address with the R/W bit set to 1, the eZ80F91 device’s ZDI block loads

the selected data into the shifter at the beginning of the first cycle following the single-bit

data separator. The most-significant bit (msb) is shifted out first. Figure 55 illustrates the

timing for ZDI single-byte Read operations.

In ZDI single-byte read operations, after each read operation, the Program Counter (PC)

address is incremented by two bytes. For example, if the current PC address is 0x00, then

Figure 54. ZDI Block Data Write Timing

Figure 55. ZDI Single-Byte Data Read Timing

ZDI Data Bytes

lsb of

ZDI Address Single-Bit

Byte Separator

msb

of DATA

Byte 2

msb

of DATA

Byte 1

lsb

of DATA

Byte 1

Single-Bit

Byte Separator

ZCL789123789129

A0 Write 0/1 D7 D6 D5 D1 D0 0/1 D7 D6 1

ZDA

ZDI Data Byte

lsb of

ZDI Address Single-Bit

Byte Separator

lsb

of DATA

msb

of DATA

End of Data

or New ZDI

START Signal

ZCL789123456789

A0 Read 0/1 D7 D6 D5 D4 D3 D2 D1 D0 1

ZDA

Note:

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a read operation at 0x00 increments the PC to 0x02 . To read the next byte, the PC must be

decremented by one.

ZDI Block Read

A block Read operation is initiated in the same manner as a single-byte Read; however,

the ZDI master continues to clock in the next byte from the ZDI slave as the ZDI slave

continues to output data. The ZDI register address counter increments with each Read. If

the ZDI register address reaches the end of the Read Only ZDI register address space

(20h), the address stops incrementing. Figure 56 illustrates the ZDI’s block Read timing.

Operation of the eZ80F91 Device during ZDI Break Points

If the ZDI forces the CPU to break, only the CPU suspends operation. The system clock

continues to operate and drive other peripherals. Those peripherals that operate autono-

mously from the CPU continues to operate, if so enabled. For example, the Watchdog

Timer and Programmable Reload Time rs continue to count during a ZDI break point.

When using the ZDI interface, any Write or Read operations of peripheral registers in the

I/O address space produces the same effect as Read or W rite operations using the CPU. As

many register Read/Write operations exhibit secondary effects, such as clearing flags or

causing operations to commence, the effects of the Read/Write operations during a ZDI

break must be taken into consideration.

Bus Requests During ZDI Debug Mode

The ZDI block on the eZ80F91 device allows an external device to take control of the

address and data bus while the eZ80F91 device is in DEBUG mode. ZDI_BUSACK_EN

causes ZDI to allow or prevent acknowledgement of bus requests by external peripherals.

The bus acknowledge occu rs only at the end of the current ZDI operation (indicated by a

High during the single-bit byte separator). The default reset condition is for bus acknowl-

Figure 56. ZDI Block Data Read Timing

ZDI Data Bytes

lsb of

ZDI Address Single-Bit

Byte Separator

msb

of DATA

Byte 2

msb

of DATA

Byte 1

lsb

of DATA

Byte 1

Single-Bit

Byte Separator

ZCL 789123789129

A0 Read 0/1 D7 D6 D5 D1 D0 0/1 D7 D6 1

ZDA

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edgement to be disabled. To allow bus acknowledgement, the ZDI_BUSACK_EN must be

written.

When an external bus request (BUSREQ pin asserted) is detected, ZDI waits until comple-

tion of the current operation before responding. ZDI acknowledges the bu s request by

asserting the bus acknowledge (BUSACK) signal. If the ZDI block is not currently shift-

ing data, it acknowledges the bus request immediately. ZDI uses the single-bit byte separa-

tor of each data word to determine if it is at the end of a ZDI operation. If the bit is a

logical 0, ZDI does not assert BUSACK to allow additional data Read or W rite operations.

If the bit is a logical 1, indicating completion of the ZDI commands, BUSACK is asserted.

Potential Hazards of Enabling Bus Requests During DEBUG Mode

There are some potential hazards that you must be aware of when enabling external bus

requests during ZDI DEBUG mode. First, when the address and data bus are being used

by an external source, ZDI must only access ZDI registers and internal CPU registers to

prevent possible bus contention. The bus acknowledge status is reported in the

ZDI_BUS_STAT register. The BUSACK output pin also indicates the bus acknowledge

state.

A second hazard is that when a bus acknowledge is granted, the ZDI is subject to any wait

states that are assigned to the device currently being accessed by the external peripheral.

To prevent data errors, ZDI must avoid data transmission while another device is

controlling the bus.

Finally, exiting ZDI DEBUG mode while an external peripheral controls the address and

data buses, as indicated by BUSACK assertion produces unpredictable results.

ZDI Write Only Registers

Table 133 lists the ZDI Write Only registers. Many of the ZDI Write Only addresses are

shared with ZDI Read Only registers.

Table 133. ZDI Write Only Registers

ZDI Address ZDI Register Name ZDI Register Function Reset

Value

00h ZDI_ADDR0_L Address Match 0 Low Byte XXh

01h ZDI_ADDR0_H Address Matc h 0 High Byte XXh

02h ZDI_ADDR0_U Address Match 0 Upper Byte XXh

04h ZDI_ADDR1_L Address Match 1 Low Byte XXh

05h ZDI_ADDR1_H Address Matc h 1 High Byte XXh

06h ZDI_ADDR1_U Address Match 1 Upper Byte XXh

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ZDI Read Only Registers

Table 134 lists the ZDI Read Only registers. Many of the ZDI Read Only addresses are

shared with ZDI Write Only registers.

08h ZDI_ADDR2_L Address Match 2 Low Byte XXh

09h ZDI_ADDR2_H Address Matc h 2 High Byte XXh

0Ah ZDI_ADDR2_U Address Match 2 Upper Byte XXh

0Ch ZDI_ADDR3_L Address Match 3 Low Byte XXh

0Dh ZDI_AD DR3 _H Add re ss Match 3 High Byte XXh

0Eh ZDI_ADDR3_U Address Match 4 Upper Byte XXh

10h ZDI_BRK_CTL Break Control Register 00h

11h ZDI_MASTER_CTL Master Control Register 00h

13h ZDI_WR_DATA_L Write Data Low Byte XXh

14h ZDI_WR_DATA_H Write Data High Byt e XXh

15h ZDI_WR_DATA_U Write Data Upper Byte XXh

16h ZDI_RW_CTL Rea d/ Writ e Co nt ro l Regis te r 00h

17h ZDI_BUS_CTL Bus Control Register 00h

21h ZDI_IS4 Instruction Store 4 XXh

22h ZDI_IS3 Instruction Store 3 XXh

23h ZDI_IS2 Instruction Store 2 XXh

24h ZDI_IS1 Instruction Store 1 XXh

25h ZDI_IS0 Instruction Store 0 XXh

30h ZDI_WR_MEM Write Memory Register XXh

Table 134. ZDI Read Only Registers

ZDI Address ZDI Register Name ZDI Register Function Reset

Value

00h ZDI_ID_L eZ80 Product ID Low Byte Register 08h

01h ZDI_ID_H eZ80 Product ID High Byte Register 00h

02h ZDI_ID_REV eZ80 Product ID Revision Register XXh

Table 133. ZDI Write Only Registers (Continued)

ZDI Address ZDI Register Name ZDI Register Function Reset

Value

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ZDI Register Definitions

ZDI Address Match Registers

The four sets of address match registers are used for setting the addresses for generating

break points. When the accompanying BRK_ADDRX bit is set in the ZDI Break Control

with the 3-byte address set, {ZDI_ADDRx_U, ZDI_ADDRx_H, and ZDI_ADDR_x_L}.

If the CPU is operating in ADL mode, the address is supplied by ADDR[23:0]. If the CPU

is operating in Z80 mode, the address is supplied by {MBASE[7:0], ADDR[15:0]}. If a

match is found, ZDI issues a break to the eZ80F91 device placing the CPU in ZDI mode

pending further instructions from the ZDI interface block. If the address is not t he first op-

code fetch, the ZDI break is executed at the end of the instruction in which it is executed.

There are four sets of address match registers. They are used in conjunction with each

other to break on branching instructions. See Table 135 on page 245.

03h ZDI_STAT Status Register 00h

10h ZDI_RD_L Read Memory Address Low Byte Register XXh

11h ZDI_RD_H Read Memory Address High Byte Register XXh

12h ZDI_RD_U Read Memory Address Upper Byte Register XXh

17h ZDI_BUS_STAT Bus Status Register 00h

20h ZDI_RD_MEM Read Memory Data Value XXh

Table 135. ZDI Address Match Registers

Bit 76543210

Reset XXXXXXXX

CPU Access WWWWWWWW

Note: W = Write Only.

Bit

Position Value Description

[7:0]

zdi_addrx_l,

zdi_addrx_h,

zdi_addrx_u

00h–FFh The four sets of ZDI addre ss match registers are used for

setting the addresses for generating break points. The 24

bit addresses are su pp lie d by {ZDI _ADDRx_U,

ZDI_ADDRx_H, ZDI_ADDRx_L, where x is 0, 1, 2, or 3.

Table 134. ZDI Read Only Registers (Continued)

ZDI Address ZDI Register Name ZDI Register Function Reset

Value

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Address Information for ZDI Address Match Registers

ZDI_ADDR0_L = 00h, ZDI_ADDR0_H = 01h, ZDI_ADDR0_U = 02h, ZDI_ADDR1_L =

04h, ZDI_ADDR1_H = 05h, ZDI_ADDR1_U = 06h, ZDI_ADDR2_L = 08h, ZDI_ADDR2_H

= 09h, ZDI_ADDR2_U = 0Ah, ZDI_ADDR3_L = 0Ch, ZDI_ADDR3_H = 0Dh, and

ZDI_ADDR3_U = 0Eh in the ZDI Register Write Only Address Space.

ZDI Break Control Register

The ZDI Break Control register is used to enable break points. ZDI asserts a break when

the CPU instruction address, ADDR[23:0], matches the value in the ZDI Address Match 3

registers, {ZDI_ADDR3_U, ZDI_ADDR3_H, ZDI_ADDR3_L}. BREAKs occurs only

on an instruction boundary. If the instruction address is not the beginning o f an instruction

(that is, for multibyte instructions), then the break occurs at the end of the current instruc-

tion. The brk_next bit is set to 1. The brk_next bit must be reset to 0 to release the break.

See Table 136 on page 247.

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Table 136. ZDI Break Control Register (ZDI_BRK_CTL = 10h in the ZDI Write Only Register

Address Space)

Bit 76543210

Reset 00000000

CPU Access WWWWWWWW

Note: W = Write Only.

Bit

Position Value Description

brk_next 0 The ZDI break on the next CPU instruction is disabled.

Clearing this bit releases the CPU from its current BREAK

condition.

1 The ZDI break on the ne xt CPU instruction is enab led. The

CPU uses multibyte Op Codes and multibyte operands.

Break points only occur on the first Op Code in a multibyte

Op Code instruction. If the ZC L pin is High and the ZDA pi n

is Low at the end of RESET, this bit is set to 1 and a break

occurs on the first instruction following the RESET. This bit

is set automatically during ZDI break on address match. A

break is also forced by writin g a 1 to th is bit.

brk_addr3 0 The ZDI break, upon matching break address 3, is

disabled.

1 The ZDI break, upon matching break address 3, is

enabled.

brk_addr2 0 The ZDI break, upon matching break address 2, is

disabled.

1 The ZDI break, upon matching break address 2, is

enabled.

brk_addr1 0 The ZDI break, upon matching break address 1, is

disabled.

1 The ZDI break, upon matching break address 1, is

enabled.

brk_addr0 0 The ZDI break, upon matching break address 0, is

disabled.

1 The ZDI break, upon matching break address 0, is

enabled.

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ign_low_1 0The Ignore the Low Byte function of the ZDI Address Match

1 registers is disabled. If brk_addr1 is set to 1, ZDI initiates

a break when the entire 24-bit address, ADDR[23:0],

matches the 3-byte value {ZDI_ADDR1_U,

ZDI_ADDR1_H, ZDI_ADDR1_L}.

1The Ignore the Low Byte function of the ZDI Address Match

1 registers is enabled. If brk_addr1 is set to 1, ZDI initiates

a break when only the upper 2 bytes of the 24-bit addre ss,

ADDR[23:8], match the 2-byte value {ZDI_ADDR1_U,

ZDI_ADDR1_H}. As a result, a break occurs anywhere

within a 256-byte page.

ign_low_0 0The Ignore the Low Byte function of the ZDI Address Match

1 registers is disabled. If brk_addr0 is set to 1, ZDI initiates

a break when the entire 24-bit address, ADDR[23:0],

matches the 3-byte value {ZDI_ADDR0_U,

ZDI_ADDR0_H, ZDI_ADDR0_L}.

1The Ignore the Low Byte function of the ZDI Address Match

1 registers is enabled. If the brk_addr1 is set to 0, ZDI

initiates a break when only the upper 2 bytes of the 24-bit

address, ADDR[23:8], match the 2 bytes value

{ZDI_ADDR0_U, ZDI_ADDR0_H}. As a result, a break

occurs anywhere within a 256-byte page.

single_step 0 ZDI single step mode is disabled.

1 ZDI single step mode is enabled. ZDI asserts a break

following execution of each instruction.

Bit

Position Value Description

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ZDI Master Control Register

The ZDI Master Control register provides control of the eZ80F91 device. It is capable of

forcing a RESET and waking up the eZ80F91 from the LOW-POWER modes (HALT or

SLEEP). See Table 137.

Table 137. ZDI Master Control Register (ZDI_MASTER_CTL = 11h in ZDI Register Write

Address Spaces)

Bit 76543210

Reset 00000000

CPU Access WWWWWWWW

Note: W = Write Only.

Bit

Position Value Description

ZDI_RESET 0 No action.

1 Initiate a RESET of the eZ80F91. This bit is automatically

cleared at the end of the RESET event.

[6:0] 0000000 Reserved.

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ZDI Write Data Registers

These three registers are used in the ZDI Write Only register address space to store the

data that is written when a W rite instruction is sent to the ZDI Read/Write Control register

(ZDI_RW_CTL). The ZDI Read/Write Control register is located at ZDI address 16h

immediately following the ZDI Write Data registers. As a result, the ZDI Master is

allowed to write the data to {ZDI_WR_U, ZDI_WR_H, ZDI_WR_L} and the Write

command in one data transfer operation. See Table 138.

Table 138. ZDI Write Data Registers (ZDI_WR_U = 13h, ZDI_WR_H = 14h, and ZDI_WR_L =

15h in the ZDI Register Write Only Address Space)

Bit 76543210

Reset XXXXXXXX

CPU Access WWWWWWWW

Note: X = Undefined ; W = Write.

Bit

Position Value Description

[7:0]

zdi_wr_l,

zdi_wr_h,

zdi_wr_l

00h–FFh These registers contain the data that is written during

execution of a Write operation defined by the

ZDI_RW_CTL register. The 24-bit data value is stored

as {ZDI_WR_U, ZDI_WR_H, ZDI_WR_L}. If less than

24 bits of data are required to complete the required

operation, the data is taken from the least-significant

byte(s).

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ZDI Read/Write Control Register

The ZDI Read/Write Control register is used in the ZDI Write Only Register address to

read data from, write data to, and manipulate the CPU’s registers or memory locations.

When this register is written, the eZ80F91 device immediately performs the operation

corresponding to the data value written as described in Table 139. When a Read operation

is executed via this register, the requested data values are placed in the ZDI Read Data

registers {ZDI_RD_U, ZDI_RD_H, ZDI_RD_L}. When a W rite operation is executed via

this register, the Write data is taken from the ZDI Write Data registers {ZDI_WR_U,

ZDI_WR_H, ZDI_WR_L}. See Table 139. For information on the CPU registers, refer to

eZ80® CPU User Manual (UM0077) available on www.zilog.com.

The CPU’s alternate register set (A’, F’, B’, C’, D’, E’, HL’) cannot be read directly. The

ZDI programmer must execute the exchange instruction (EXX) to gain access to the alter-

nate CPU register set.

Table 139. ZDI Read/Write Control Register Functions (ZDI_RW_CTL = 16h in the ZDI

Hex

Value Command Hex

Value Command

00 Read {MBASE, A, F}

ZDI_RD_U ← MBASE

ZDI_RD_H ← F

ZDI_RD_L ← A

80 Write AF

MBASE ← ZDI_WR_U

F ← ZDI_WR_H

A ← ZDI_WR_L

01 Read BC

ZDI_RD_U ← BCU

ZDI_RD_H ← B

ZDI_RD_L ← C

81 Write BC

BCU ← ZDI_WR_U

B ← ZDI_WR_H

C ← ZDI_WR_L

02 Read DE

ZDI_RD_U ← DEU

ZDI_RD_H ← D

ZDI_RD_L ← E

82 Write DE

DEU ← ZDI_WR_U

D ← ZDI_WR_H

E ← ZDI_WR_L

03 Read HL

ZDI_RD_U ← HLU

ZDI_RD_H ← H

ZDI_RD_L ← L

83 Write HL

HLU ← ZDI_WR_U

H ← ZDI_WR_H

L ← ZDI_WR_L

04 Read IX

ZDI_RD_U ← IXU

ZDI_RD_H ← IXH

ZDI_RD_L ← IXL

84 Write IX

IXU ← ZDI_WR_U

IXH ← ZDI_WR_H

IXL ← ZDI_WR_L

Note:

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05 Read IY

ZDI_RD_U ← IYU

ZDI_RD_H ← IYH

ZDI_RD_L ← IYL

85 Write IY

IYU ← ZDI_WR_U

IYH ← ZDI_WR_H

IYL ← ZDI_WR_L

06 Read SP

In ADL mode, SP = SPL.

In Z80 mode, SP = SPS.

86 Write SP

In ADL mode, SP = SPL.

In Z80 mode, SP = SPS.

07 Read PC

ZDI_RD_U ← PC[23:16]

ZDI_RD_H ← PC[15:8]

ZDI_RD_L ← PC[7:0]

87 Write PC

PC[23:16] ← ZDI_WR_U

PC[15:8] ← ZDI_WR_H

PC[7:0] ← ZDI_WR_L

08 Set ADL

ADL ← 188 Reserved

09 Reset ADL

ADL ← 089 Reserved

0A Exchange CPU register sets

AF ← AF’

BC ← BC’

DE ← DE’

HL ← HL’

8A Reserved

0B Read memory from curr ent PC

value, increment PC 8B Write memory from current PC

value, increment PC

Table 139. ZDI Read/Write Control Register Functions (ZDI_RW_CTL = 16h in the ZDI

Hex

Value Command Hex

Value Command

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ZDI Bus Control Register

The ZDI Bus Control register controls bus requests during DEBUG mode. It enables or

disables bus acknowledge in ZDI DEBUG mode and allows ZDI to force assertion of the

BUSACK signal. This register must only be written during ZDI Debug mode (that is, fol-

lowing a break). See Table 140.

Instruction Store 4:0 Registers

The ZDI Instruction Store registers are located in the ZDI Register Write Only address

space. They are written with instruction data for direct execution by the CPU. When the

ZDI_IS0 register is written, the eZ80F91 device exits the ZDI break state and executes a

single instruction. The opcodes and operands for the instruction come from these Instruc-

tion Store registers. The Instruction Store Register 0 is the first byte fetched, followed by

Instruction Store registers 1, 2, 3, and 4, as necessary. Only the bytes the CPU requires to

execute the instruction must be stored in these registers. Some CPU instructions, when

combined with the MEMORY mode suffixes (.SIS, .SIL, .LIS , or .LIL), require 6 bytes to

operate. These 6-byte instructions cannot be executed directly using the ZDI Instruction

Store registers. See Table 141.

Table 140. ZDI Bus Control Register (ZDI_BUS_CTL = 17h in the ZDI Register Write Only

Address Space)

Bit 76543210

Reset 00000000

CPU Access WWWWWWWW

Note: W = Write Only.

Bit

Position Value Description

ZDI_BUSAK_EN 0 Bus requests by external peripherals using the BUSREQ

pin are ignored . The bus acknowledge signal, BUSACK, is

not asserted in response to any bus requests.

1 Bus requests by external peripherals using the BUSREQ

pin are accepted. A bus acknowledge occurs at the end of

the current ZDI operation. The bus acknowledg e is

indicated by asserting the BUSACK pin in response to a

bus request.

ZDI_BUSAK 0 Deassert the bus acknowledge pin (BUSACK) to return

control of the address and data buses back to ZDI.

1 Assert the bus acknowledge pin (BUSACK) to pass control

of the address and data buses to an external peripheral.

[5:0] 000000 Reserved.

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The Instruction Store 0 register is located at a higher ZDI address than the other Instruc-

tion Store registers. This feature allows the use of the ZDI auto-address increment function

to load and execute a multibyte instruction with a single data stream from the ZDI master.

Execution of the instruction commences with writing the final byte to ZDI_IS0.

ZDI Write Memory Register

A Write to the ZDI Write Memory register causes the eZ80F91 device to write the 8-bit

data to the memory location specified by the current address in the Program Counter. In

Z80 MEMORY mode, this address is {MBASE, PC[15:0]}. In ADL MEMORY mode,

this address is PC[23:0]. The Program Counter, PC, increments after each data Write.

However, the ZDI register address does not increment automatically when this register

is accessed. As a result, the ZDI master is allowed to write any number of data bytes by

writing to this address one time followed by any number of data bytes. See Table 142

on page 255.

Table 141. Instruction Store 4:0 Registers (ZDI_IS4 = 21h, ZDI_IS3 = 22h, ZDI_IS2 = 23h,

ZDI_IS1 = 24h, and ZDI_IS0 = 25h in the ZDI Register Write Only Address Space)

Bit 76543210

Reset XXXXXXXX

CPU Access WWWWWWWW

Note: X = Undefined ; W = Write.

Bit

Position Value Description

[7:0]

zdi_is4,

zdi_is3,

zdi_is2,

zdi_is1,

zdi_is0

00h–FFh These registers contain the Op Codes and operands for

immediate execution by the CPU following a Write to

ZDI_IS0. The ZDI_IS0 register contains the first Op Code

of the instruction. The remaining ZDI_ISx registers

contain any addition al Op Codes or operand dates

required for execution of the required instruction.

Note:

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eZ80® Product ID Low and High Byte Registers

The eZ80 Product ID Low and High Byte registers combine to provide a means for an

external device to determine the particular eZ80 product being addressed. See Table 143

and Table 144 on page 256.

Table 142. ZDI Write Memory Register (ZDI_WR_MEM = 30h in the ZDI Register Write Only

Address Space)

Bit 76543210

Reset XXXXXXXX

CPU Access WWWWWWWW

Note: X = Undefined ; W = Write.

Bit

Position Value Description

[7:0]

zdi_wr_mem 00h–FFh The 8-bit data that is transferred to the ZDI slave

following a Write to this ad dr ess is written to the addr ess

indicated by the current Program Counter. The Program

Counter is incremented following each 8 bits of data. In

Z80 MEMORY mode, ({MBASE, PC[15:0]}) ← 8 bits of

transferred data. In ADL MEMORY mode, (PC[23:0]) ←

8-bits of transferred data.

Table 143. eZ80 Product ID Low Byte Register (ZDI_ID_L = 00h in the ZDI Register Read Only

Address Space, ZDI_ID_L = 0000h in the I/O Register Address Space)

Bit 76543210

Reset 00001000

CPU Access RRRRRRRR

Note: R = Read Only.

Bit

Position Value Description

[7:0]

zdi_id_l 08h {ZDI_ID_H, ZDI_ID_L} = {00h, 08h} indicates the eZ80F91

product.

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eZ80® Product ID Revision Register

The eZ80 Product ID Revision register identifies the current revision of the eZ80F91

product. See Table 145.

Table 144. eZ80 Product ID High Byte Register (ZDI_ID_H = 01h in the ZDI Register Read Only

Address S pace, ZDI_ID_H = 0001h in the I/O Register Address Space)

Bit 76543210

Reset 00000000

CPU Access RRRRRRRR

Note: R = Read Only.

Bit

Position Value Description

[7:0]

zdi_id_H 00h {ZDI_ID_H, ZDI_ID_L} = {00h, 08h} indicates the eZ80F91

device.

Table 145. eZ80 Product ID Revision Register (ZDI_ID_REV = 02h in the ZDI Register Read

Only Address Space, ZDI_ID_REV = 0002h in the I/O Register Address Space)

Bit 76543210

Reset XXXXXXXX

CPU Access RRRRRRRR

Note: X = Undetermi ned; R = Read Only.

Bit

Position Value Description

[7:0]

zdi_id_rev 00h–FFh Identifies the current revision of the eZ80F91 prod uct.

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ZDI Status Register

The ZDI S tatus register provides cu rrent information on the eZ80F91 device and the CPU.

See Table 146.

Table 146. ZDI Status Register (ZDI_STAT = 03h in the ZDI Register Read Only Address Space)

Bit 76543210

Reset 00000000

CPU Access RRRRRRRR

Note: R = Read Only.

Bit

Position Value Description

zdi_active 0 The CPU is not functioning in ZDI mode.

1 The CPU is currently functioning in ZDI mode.

6 0 Reserved.

halt_SLP 0 The CPU is not currently in HALT or SLEEP mode.

1 The CPU is currently in HALT or SLEEP mode.

ADL 0 The CPU is operating in Z80 MEMORY mode.

(ADL bit = 0)

1 The CPU is operating in ADL MEMORY mode.

(ADL bit = 1)

MADL 0 The CPU’s Mixed-Memory mode (MADL) bit is reset to 0.

1 The CPU’s Mixed-Memory mode (MADL) bit is set to 1.

IEF1 0 The CPU’s Interrupt Enable Flag 1 is reset to 0. Maskable

interrupts are disabled.

1 The CPU’s Interrupt Enable Flag 1 is set to 1. Maskable

interrupts are enabled.

[1:0]

Reserved 00 Reserved.

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ZDI Read Register Low, High, and Upper

The ZDI register Read Only address space offers Low, High, and Upper functions, which

contain the value read by a Read operation from the ZDI Read/Write Control register

(ZDI_RW_CTL). This data is valid only while in ZDI BREAK mode and only if the

instruction is read by a request from the ZDI Read/Write Control register. See Table 147.

Table 147. ZDI Read Register Low, High, and Upper (Z DI_RD_L = 10h, ZDI_RD_H = 11h, and

ZDI_RD_U = 12h in the ZDI Register Read Only Address Space)

Bit 76543210

Reset 00000000

CPU Access RRRRRRRR

Note: R = Read Only.

Bit

Position Value Description

[7:0]

zdi_rd_l,

zdi_rd_h,

zdi_rd_u

00h–FFh Values r ead from th e memory loca tion as re quested by the

ZDI Read Control register during a ZDI Read operation.

The 24-bit value is supplied by {ZDI_RD_U, ZDI_RD_H,

ZDI_RD_L}.

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ZDI Bus Status Register

The ZDI Bus Status register monitors BUSACKs during DEBUG mode. See Table 148.

ZDI Read Memory Register

When a Read is executed from the ZDI Read Memory register, the eZ80F91 device

fetches the data from the memory address currently pointed to by the Program

Counter, PC; the Program Counter is then incremented. In Z80 MEMORY mode, the

memory address is {MBASE, PC[15:0]}. In ADL MEMORY mode, the memory

address is PC[23:0]. For more information on Z80 and ADL MEMORY modes, refer

to the eZ80® CPU User Manual (UM0077) available on www.zilog.com. The Pro-

gram Counter, PC, increments after each data Read. However, the ZDI register address

does not increment automatically when this register is accessed. As a result, the ZDI

master reads any number of data bytes out of memory via the ZDI Read Memory reg-

ister. See Table 149 on page 260.

Table 148. ZDI Bus Control Register (ZDI_BUS_STAT = 17h in the ZDI Register Read Only

Address Space)

Bit 76543210

Reset 00000000

CPU Access RRRRRRRR

Note: R = Read Only.

Bit

Position Value Description

ZDI_BUSAcK_En 0 Bus requests by external peripherals using the

BUSREQ pin are ignored. The bus acknowledge signal,

BUSACK, is not asserted.

1 Bus requests by external peripherals using the

BUSREQ pin are accepted. A bus acknowledge occurs

at the end of the current ZDI operation. The bus

acknowledge is indicated by asserting the BUSACK pin.

ZDI_BUS_STAT 0 Address and data buses are not relinquished to an

external peripheral. bus acknowledge is deasserted

(BUSACK pin is High).

1 Address and data buses are r elinquished to an external

peripheral. bus acknowledge is asserted (BUSACK pin

is Low).

[5:0] 000000 Reserved.

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Note that the delay between issuing a memory read request and the return of the corre-

sponding data amount to multiple ZDI clock cycles. This delay is a function of the wait

state configuration of the memory space being accessed as well as the relative frequencies

of the ZDI clock and the system cl ock. If the ZDI master begins clocking the read data out

of the eZ80F91 soon after issuing the memory read request, invalid data will be returned.

Since no data-valid handshake mechanism exists in the ZDI protocol, the ZDI master must

account for expected memory read delay in some way.

A technique exists to mask this delay in almost all situations. It always reads at least two

consecutive bytes, starting one address lower than the address of interest. In this situation,

the eZ80F91 internally prefetches the data from the second address while the ZDI master

is sending the second read request. This allows enough time for the second ZDI memory

read to return valid data. The first data byte returned to the ZDI master must be discarded

since it is invalid. Memory reads of more than two consecutive bytes will also return cor-

rect data for all but the first address.

Table 149. ZDI Read Memory Register (ZDI_RD_MEM = 20h in the ZDI Register Read Only

Address Space)

Bit 76543210

Reset 00000000

CPU Access RRRRRRRR

Note: R = Read Only.

Bit

Position Value Description

[7:0]

zdi_rd_mem 00h–FFh 8-bit data Read from the memory address indicated by

the CPU’s Program Counter. In Z80 Memory mode, 8-bit

data is transferred out from address {MBASE, PC[15:0]}.

In ADL Memory mode, 8-bit data is transferred out from

address PC[23:0].

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On-Chip Instrumentation

Introduction to On-Chip Instrumentation

On-Chip Instrumentation1 (OCI™) for the eZ80 CPU core enables powerful debugging

features. The OCI provides run control, memory and register visibility, complex break

points, and trace history features.

The OCI employs all of the functions of the Zilog Debug Interface (ZDI) as described in

the ZDI section. It also adds the following debug fea tures:

•

Control via a 4-pin Joint Test Action Group (JTAG) port that conforms to IEEE Stan-

dard 1149.1 (Test Access Port and Boundary Scan Architecture).

•

Complex break point trigger functions.

•

Break point enhancements, such as the ability to:

–Define two break point addresses that form a range.

–Break on masked data values.

–Start or stop trace.

–Assert a trigger output signal.

•

Trace history buffer.

•

Software break point instruction.

There are four sections to the OCI:

•

JTAG interface

•

ZDI debug control

•

Trace buffer memory

•

Complex triggers

This document contains information to activate the OCI for JTAG boundary scan register

operations. For additional information regarding OCI features, or to order OCI debug

tools, contact:

First Silicon Solutions, Inc.

www.fs2.com

1. On-Chip Instrumentation and OCI are trademarks of First Silicon Solutions, Inc.

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OCI Activation

OCI features clock initialization circuitry so that external debug hardware is detected dur-

ing power-up. The external debugger must drive the OCI clock pin (TCK) Low at least

two system clock cycles prior to the end of the RESET to activate the OCI block. If TCK

is High at the end of the RESET, the OCI block shuts down so that it does no t draw power

in normal product operation. When the OCI is shut down, ZDI is enabled directly and is

accessed via the clock (TCK) and data (TDI) pins. For more information on ZDI, see Zilog

Debug Interface on page 235.

OCI Interface

There are six dedicated pins on the eZ80F91 for the OCI interface. Four pins—TCK,

TMS, TDI, and TDO—are required for IEEE Standard 1149.1-compliant JTAG ports. A

fifth pin, TRSTn, is optional for IEEE 1149.1 and utilized by the eZ80F91 device. The

TRIGOUT pin provides additional testability features. These six OCI pins are described in

Table 150.

Table 150. OCI Pins

Symbol Name Type Description

TCK Clock Input Asynchronous to the primary eZ80F91 system clock.

The TCK period must be at least twice the system

clock period. During RESET, this pin is sampled to

select either OCI or ZDI DEBUG modes. If Low

during RESET, the OCI is enabled. If High during

RESET, the OCI is powered down and ZDI DEBUG

mode is enabled. When ZDI DEBUG mode is active,

this pin is the ZDI clock. On-chip pull-up ensures a

default value of 1 (High).

TRSTn TAP Reset Input Active Low asynchronous reset for the Test Access

Port state register. On-chip pull-up ensures a default

value of 1 (High).

TMS Test Mode Select Input This serial test mode input controls JTAG mode

selection. On-chip pull-up ensu res a default value of

1 (High). The TMS signal is sampled on the rising

edge of the TCK signal.

TDI Data In Input

(OCI enabled) Serial test data input. This pin is input-only when the

OCI is enabled. The input data is sampled on the

rising edge of the TCK signal.

I/O

(OCI disabled) W he n th e OCI is disab led , th is pin fu nct i on s as the

ZDA (ZDI Data) I/O pin. NORMAL mode, following

RESET, configures TDI as an input.

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JTAG Boundary Scan

Introduction

This section describes coverage, implementation, and usage of the eZ80F91 boundary

scan register based on the JTAG standard. A working knowledge of the IEEE 1 149.1 spec-

ification, particularly Clause 11, is required.

Pin Coverage

All pins are included in the boundary scan chain, except the following:

•

TCK

•

TMS

•

TDI

•

TDO

•

TRSTN

•

VDD

•

VSS

•

PLL_VDD

•

PLL_VSS

•

RTC_VDD

•

XIN

•

XOUT

•

RTC_XIN

•

RTC_XOUT

•

LOOP_FILT

TDO Data Out Output The output data changes on the falling edge of the

TCK signal.

TRIGOUT Trigger Output Output Generates an active High trigger pulse when valid

OCI trigger events occur. Output is open-drain when

no data is being driven out.

Table 150. OCI Pins (Continued)

Symbol Name Type Description

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Boundary Scan Cell Functionality

The boundary scan cells implemented are analogous to cell BC_1, defined in the Standard

VHDL Package STD_1149_1_2001.

All boundary scan cells are of the type control-and-observe; they provide both controlla-

bility and observability for the pins to which they are connected. For open-drain outputs

and bidirectional pins, this type includes controllability and observability of output

enables.

Chain Sequence and Length

When enabled to shift data, the boundary scan shift register is connected to TDI at the

input line for TRIGOUT and to TDO at PD0. The shift register is arranged so that data is

shifted via the pins starting to the left of the OCI interface pins and proceeding clockwise

around the chip. If a pin features multiple scannable bits (example: bidirectional pins or

open-drain output pins), the data is shifted first into the input signal, then the output, then

the output enable (OEN).

The boundary scan register is 213 bits wide. Table 151 shows the ordering of bits in the

shift register, numbering them in clockwise order.

Table 151. Pin to Boundary Scan Cell Mapping

Pin Direction Scan Cell No Pin Direction Scan Cell No

TRIGOUT Input 0 MII_TxD2 Output 107

TRIGOUT Output 1 MII_TxD3 Output 108

TRIGOUT OEN 2 MII_COL Input 109

HALT_SLP Output 3 MII_CRS Input 110

BUSACK Output 4 PA7 Input 111

BUSREQ Input 5 PA7 Output 112

NMI Input 6 PA7 OEN 113

RESET Input 7 PA6 Input 114

RESET_OUT Output 8 PA6 Output 115

WAIT Input 9 PA6 OEN 116

INSTRD Output 10 PA5 Input 117

WR Output 11 PA5 Output 118

WR OEN 12 PA5 OEN 119

RD Output 13 PA4 Input 120

MREQ Input 14 PA4 Output 121

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MREQ Output 15 PA4 OEN 122

IORQ Input 16 PA3 Input 123

IORQ Output 17 PA3 Output 124

D7 Input 18 PA3 OEN 125

D7 Output 19 PA2 Input 126

D6 Input 20 PA2 Output 127

D6 Output 21 PA2 OEN 128

D5 Input 22 PA1 Input 129

D5 Output 23 PA1 Output 130

D4 Input 24 PA1 OEN 131

D4 Output 25 PA0 Input 132

D3 Input 26 PA0 Output 133

D3 Output 27 PA0 OEN 134

D2 Input 28 PHI Output 135

D2 Output 29 PHI OEN 136

D1 Input 30 SCL Input 137

D1 Output 31 SCL Output 138

D0 Input 32 SDA Input 139

D0 Output 33 SDA Output 140

D0 OEN 34 PB7 Input 141

CS3 Output 35 PB7 Output 142

CS2 Output 36 PB7 OEN 143

CS1 Output 37 PB6 Input 144

CS0 Output 38 PB6 Output 145

A23 Input 39 PB6 OEN 146

A23 Output 40 PB5 Input 147

A22 Input 41 PB5 Output 148

A22 Output 42 PB5 OEN 149

A21 Input 43 PB4 Input 150

Table 151. Pin to Boundary Scan Cell Mapping (Continued)

Pin Direction Scan Cell No Pin Direction Scan Cell No

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A21 Output 44 PB4 Output 151

A20 Input 45 PB4 OEN 152

A20 Output 46 PB3 Input 153

A19 Input 47 PB3 Output 154

A19 Output 48 PB3 OEN 155

A18 Input 49 PB2 Input 156

A18 Output 50 PB2 Output 157

A17 Input 51 PB2 OEN 158

A17 Output 52 PB1 Input 159

A16 Input 53 PB1 Output 160

A16 Output 54 PB1 OEN 161

A16 OEN 55 PB0 Input 162

A15 Input 56 PB0 Output 163

A15 Output 57 PB0 OEN 164

A14 Input 58 PC7 Input 165

A14 Output 59 PC7 Output 166

A13 Input 60 PC7 OEN 167

A13 Output 61 PC6 Input 168

A12 Input 62 PC6 Output 169

A12 Output 63 PC6 OEN 170

A11 Input 64 PC5 Input 171

A11 Output 65 PC5 Output 172

A10 Input 66 PC5 OEN 173

A10 Output 67 PC4 Input 174

A9 Input 68 PC4 Output 175

A9 Output 69 PC4 OEN 176

A8 Input 70 PC3 Input 177

A8 Output 71 PC3 Output 178

A8 OEN 72 PC3 OEN 179

Table 151. Pin to Boundary Scan Cell Mapping (Continued)

Pin Direction Scan Cell No Pin Direction Scan Cell No

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A7 Input 73 PC2 Input 180

A7 Output 74 PC2 Output 181

A6 Input 75 PC2 OEN 182

A6 Output 76 PC1 Input 183

A5 Input 77 PC1 Output 184

A5 Output 78 PC1 OEN 185

A4 Input 79 PC0 Input 186

A4 Output 80 PC0 Output 187

A3 Input 81 PC0 OEN 188

A3 Output 82 PD7 Input 189

A2 Input 83 PD7 Output 190

A2 Output 84 PD7 OEN 191

A1 Input 85 PD6 Input 192

A1 Output 86 PD6 Output 193

A0 Input 87 PD6 OEN 194

A0 Output 88 PD5 Input 195

A0 OEN 89 PD5 Output 196

WP Input 90 PD5 OEN 197

MII_MDIO Input 91 PD4 Input 198

MII_MDIO Output 92 PD4 Output 199

MII_MDIO OEN 93 PD4 OEN 200

MII_MDC Output 94 PD3 Input 201

MII_RxD3 Input 95 PD3 Output 202

MII_RxD2 Input 96 PD3 OEN 203

MII_RxD1 Input 97 PD2 Input 204

MII_RxD0 Input 98 PD2 Output 205

MII_Rx_DV Input 99 PD2 OEN 206

MII_Rx_CLK Input 100 PD1 Input 207

MII_Rx_ER Input 101 PD1 Output 208

Table 151. Pin to Boundary Scan Cell Mapping (Continued)

Pin Direction Scan Cell No Pin Direction Scan Cell No

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Usage

Boundary scan functionality is utilized by issuing the appropriate Test Access Port (TAP)

instruction and shifting data accordingly. Both of these steps are accomplished using the

JTAG interface. To activate the TAP (see OCI Activation on page 262), the TCK pin must

be driven Low at least two CPU system clock cycles prior to the deassertion of the RESET

pin. Otherwise the OCI-JTAG features are disabled.

As per the IEEE 1149.1 specification, the boundary scan cells capture system I/O on the

rising edge of TCK during the CAPTURE_DR state. This captured data is shifted on the

rising edge of TCK while in the SHIFT_DR state. Pins and logic receive shifted data only

when enabled, and only on the falling edge of TCK during the UPDATE_DR state, after

shifting is completed.

For more information about eZ80F91 boundary scan support, refer to Using BSDL Files

with eZ80 and eZ80Acclaim! Devices (AN0114).

Boundary Scan Instructions

The eZ80F91 device’s boundary scan architecture supports the following instructions:

•

BYPASS (required)

•

SAMPLE (required)

•

EXTEST (required)

•

PRELOAD (required)

•

IDCODE (optional)

MII_Tx_ER Output 102 PD1 OEN 209

MII_Tx_CLK Input 103 PD0 Input 210

MII_Tx_EN Output 104 PD0 Output 211

MII_TxD0 Output 105 PD0 OEN 212

MII_TxD1 Output 106

Notes

1. Th e address bits 0–7, 8–15, and 16–23 each share a single output enable. In this table, the output enables are

associated with the least-significant bit that they control.

2. Directio n on the data bus is controlled by a single output enable. It is associated in this table with D[0].

3. MREQ, IORQ, INSTRDN, RD, and WR share an output enable; it is associated in this table with WR.

Table 151. Pin to Boundary Scan Cell Mapping (Continued)

Pin Direction Scan Cell No Pin Direction Scan Cell No

PS027001-0707 Phase-Locked Loop

eZ80F91 ASSP

Product Specification

269

Phase-Locked Loop

Overview

The Phase-Locked-Loop (PLL) is a programmable frequency multiplier that satisfies the

equation SCLK (Hz) = N * FOSC(Hz). Figure 57 illustrates the PLL block diagram.

PLL includes seven ma in blocks as listed below:

•

Phase Frequency Detector

•

Charge Pump

•

Voltage Controlled Oscillator

•

Loop Filter

•

Divider

•

MUX/CLK Sync

•

Lock Detect

Figure 57. Phase-Locked Loop Block Diagram

RPLL

PLL_CTL1[0] = PLL Enable

PLL_INT

PLL_CTL0[3:2]

PLL_CTL0[7:6]

RTC_CLK

(1MHz < F < 10MHz)

{PLL_DIV_H, PLL_DIV_L}

PLL1 CPLL2

Off-Chip

Loop Filter

VCO

SCLK-MUX

System Clock

Charge

Pump

PFDOscillator

Lock

Detect

Div N

OSC

(F < SCLK < F * N)

OSC OSC

PS027001-0707 Phase-Locked Loop

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Product Specification

270

Phase Frequency Detector

The Phase Frequency Detector (PFD) is a digital block. The two inputs are the reference

clock (XTAL oscillator; see On-Chip Oscillat ors on page 339) and the P LL divider output.

The two outputs drive the internal charge pump and represent the error (or difference)

between the falling edges of the PFD inputs.

Charge Pump

The Charg e Pump is an analog block that is dr iven by two digital inputs from the PFD that

control its programmable current sources. The internal current source contains four

programmable values: 1.5 mA, 1 mA, 500 µA, and 100 µA. These values are selected by

PLL_CTRL1[7:6]. The selected current drive is sinked/sourced onto the loop-filter node

according to the error (or difference) between the falling edges of the PFD inputs. Ideally,

when the PLL is locked, there are no errors (error = 0) and no current is sourced/sinked

onto the loop-filter node.

Voltage Control led Oscillator

The Voltage Controlled Oscillator (VCO) is an analog block that exhibits an output

frequency proportional to its input voltage. The VCO input is driven from the charge

pump and filtered via the off-chip loop filter.

Loop Filter

The Loop Filter comprises off-chip passive components (usually 1 resistor and 2

capacitors) that filter/integrate charge from the internal charge pump. The filtered node

also drives the VCO input, which creates a proportional frequency output. When PLL is

not used, the Loop Filter pin must not be connected.

Divider

The Divider is a digital, programmable downco unter. The divider input is driven by the

VCO. The divider output drives the PFD. The function of the Divider is to divide the

frequency of its input signal by a programmable factor N and supply the result in its

output.

MUX/CLK Sync

The MUX/CLK Sync is a digital, software-controllable multiplexer that selects between

PLL or the XTAL oscillator as the system clock (SCLK). A PLL source is selected only

after the PLL is locked (via the lock detect block) to allow glitch-free clock switching.

Lock Detect

The Lock Detect digital block analyzes the PFD output for a locked condition. The PLL

block of the eZ80F91 device is considered locked when the error (or difference) between

the reference clock and divided-down VCO is less than the minimum timing lock criteria

PS027001-0707 Phase-Locked Loop

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Product Specification

271

for the number of consecutive reference clock cycles. The lock criteria is selected in the

PLL Control Register, PLL_CTL0[LDS_CTL]. When the locked condition is met, this

block outputs a logic High signal (lock) that interrupts the CPU.

PLL Normal Operation

By default (after system reset) the PLL is disabled and SCLK = XTAL oscillator. Ensuring

proper loop filter , supply voltages and external oscillator are correctly confi gured, the PLL

is enabled. The SCLK/Timer cannot choose the PLL as its source until the PLL is locked,

as determined by the lock detect block. By forcing the PLL to be locked prior to enabling

the PLL as a SCLK/Timer source, it is assured to be stable and accurate.

Figure 58 displays the programming flow for normal PLL operation.

Figure 58. Normal PLL Programming Flow

POR/System

Reset

Execute Application Code

Execute instructions with

SCLK = XTAL Oscillator

Enable:

{Interrupts & PLL}

PLL_CTL1

Program:

{PLL Divider}

PLL_DIV_L then PLL_DIV_H

{Charge Pump & Lock criteria}

PLL_CTL0

Upon Lock Interrupt:

Set SCLK MUX to PLL (PLL_CTL0)

Disable Lock Interrupt Mask

(PLL_CTL1)

PS027001-0707 Phase-Locked Loop

eZ80F91 ASSP

Product Specification

272

Power Requirement to the Phase-Locked Loop Function

Regardless of whether or not you chooses to use the PLL module block as a clock source

for the eZ80F91 device, the PLL_VDD (pin 87) must be connected to a VDD supply and

the PLL_VSS (pin 84) must be connected to a VSS supply for proper operation of the

eZ80F91 using any system clock source.

PLL Registers

PLL Divider Control Register—Low and High Bytes

This register is designed such that the 11 bit divider value is loaded into the divider mod-

ule whenever the PLL_DIV_H register is written. Therefore, the procedure must be to

load the PLL_DIV_L register, followed by the PLL_DIV_H register, for the divider to

receive the appropriate value.

The divider is design ed such that any divider va lue less than two is i gnored; a value of two

is used in its place.

The least-significant byte of PLL divider N is set via the corresponding bits in the

PLL_DIV_L register. See Table 152 and Table 153 on page 273.

The PLL divider register are written only when the PLL is disabled. A read-back of the

PLL Divider registers returns 0.

Table 152. PLL Divider Register—Low Bytes (PLL_DIV_L = 005Ch)

Bit 76543210

Reset 00000010

CPU Access WWWWWWWW

Note: W = Write only.

Bit

Position Value Description

[7:0]

PLL_DIV_L 00h–FFh These bits represent the Low byte of the 11 bit PLL divider

value. The complete PLL divider value is returned by

{PLL_DIV_H, PLL_DIV_L}.

Note:

PS027001-0707 Phase-Locked Loop

eZ80F91 ASSP

Product Specification

273

PLL Control Register 0

The charge pump program, lock detect sensitivity, and system clock source selections are

set using this register. A brief description of each of these PLL Control Register 0

attributes is listed below, and further described in Table 154.

Charge Pump Program (CHRP_CTL)—Selects one of four values of charge pump

current.

Lock Detect Sensitivity (LDS_CTL)—Determines the lock criteria for the PLL.

System Clock Sourc e (CLK _M UX) — Selects the system clock source from a choice of

the external crystal oscillator (XTAL), PLL, or Real-Time Clock crystal oscillator.

Table 153. PLL Divider Register—High Bytes (PLL_DIV_H = 005Dh)

Bit 76543210

Reset 00000000

CPU Access WWWWWWWW

Note: R = Read only; R/W = Read/Write.

Bit

Position Value Description

[7:3] 00h Reserved

[2:0]

PLL_DIV_H 0h–7h These bits represent the High byte of the 11 bit PLL divider

value. The complete PLL divider value is returned by

{PLL_DIV_H, PLL_DIV_L}.

Table 154. PLL Control Register 0 (PLL_CTL0 = 005Eh)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R R R/W R/W R/W R/W

Note: R = Read Only; R/W = Read/Write.

Bit

Position Value Description

[7:6]

CHRP_CTL1 00 Charge pump current = 100 µA

01 Charge pump current = 500 µA

10 Charge pump current = 1.0 mA

11 Charge pump current = 1.5 mA

PS027001-0707 Phase-Locked Loop

eZ80F91 ASSP

Product Specification

274

PLL Control Register 1

The PLL is enabled using this register. PLL lock-detect status, the PLL interrupt signals

and the PLL interrupt enables are accessed via this register. A brief description of each of

these PLL Control Register 1 attributes is listed below, and further described in Table 155

on page 275.

Lock Status (LCK_STATUS)—The current lock bit out of the PLL is synchronized and

read via this bit.

Interrupt Lock (INT_LOCK)—This signal feeds the interrupt line out of the CLKGEN

module and indicates that a rising edge on the lock signal out of the PLL has been

observed.

Interrupt U n lock (INT_UNLOCK)—This signal feeds the interrupt line out of the clkgen

module and indicates that a falling edge on the lock signal out of the PLL has been

observed.

Interrupt Lock Enable (INT_LOCK_EN)—This signal enables the interrupt lock bit.

Interrupt Unlock Enable (INT_UNLOCK_EN)—This signal enables the interrupt unlock

bit.

PLL Enable (PLL_ENABLE)—Enables/disables the PLL.

[5:4] 00 Reserved

[3:2]

LDS_CTL1 00 Lock criteria—8 consecutive cycles of 20 ns

01 Lock criteria—16 consecutive cycles of 20 ns

10 Lock criteria—8 consecutive cycles of 400 ns

11 Lock criteria—16 consecutive cycles of 400 ns

[1:0]

CLK_MUX 00 System clock source is the external crystal oscillator

01 System clock source is the PLL2

10 System clock source is the Real-Time Clock crystal oscillator

11 Reserved (previous select is preserved)

Notes

1. Bits are programmed only when the PLL is disabled. The PLL is disabled when PLL_CTL1 bit

0 is equal to 0.

2. PLL cannot be selected when disable d or out of lock.

Bit

Position Value Description

PS027001-0707 Phase-Locked Loop

eZ80F91 ASSP

Product Specification

275

Table 155. PLL Control Register 1 (PLL_CTL1 = 005Fh)

Bit 76543210

Reset 00000000

CPU Access R R R R/W R/W R/W R/W R/W

Note: R = Read Only; R/W = Read/Write.

Bit

Position Value Description

[7:6] 00 Reserved.

LCK_STATUS 0 PLL is currently out of lock.

1 PLL is currently locked.

INT_LOCK 0 Lock signal from PLL ha s not ris en since last time r egister was

read.

1 Interrupt generated when PLL enters LOCK mode. Held until

INT_UNLOCK 0 Lock signal from PLL has not fallen since last tim e register was

read

1 Interrupt generated when PLL goes out of lock. Held until

INT_LOCK_EN 0 Interrupt generation for PLL locked co ndi tio n (B it 4) is disab led .

1 Interrupt generation for PLL locked condition is enabled.

INT_UNLOCK_

0 Interrupt gen er at ion for PLL un loc ke d co nd itio n (Bit 3) is

disabled.

1 Interrupt generation for PLL unlocked condition is enabled.

PLL_ENABLE 0 PLL is disabled.1

1 PLL is enabled.

Note

1. PLL cannot be disabled if the CLK_MUX bit of PLL_CTL0[1:0] is set to 01, because the PLL is

selected as the clock source.

PS027001-0707 Phase-Locked Loop

eZ80F91 ASSP

Product Specification

276

PLL Characteristics

The operating and testing characteristics for the PLL are described in Table 156.

Not all conditions are tested in production test. The values in Table 156 are for design and

characterization only.

Table 156. PLL Characteristics

Symbol Parameter Test Condition Min Typ Max Units

oHCP_OUT

High level output current for

CP_OUT pin (programmed

value ±42%)

3.0 < V

< 3.6

0.6 < PD_OUT < V

– 0.6

PLL_CTL0[7:6] = 11

–0.86 –1.50 –2.13 mA

oLCP_OUT

Low level output current for

CP_OUT pin (programmed

value ±42%)

3.0 < V

<3.6

0.6 < PD_OUT < V

– 0.6

PLL_CTL0[7:6] = 11

0.86 1.50 2.13 mA

oHCP_OUT

High level output current for

CP_OUT pin (programmed

value ±42%)

3.0 < V

<3.6

0.6 < PD_OUT < V

– 0.6

PLL_CTL0[7:6] = 10

–0.42 –1.0 –1.42 mA

oLCP_OUT

Low level output current for

CP_OUT pin (programmed

value ±42%)

3.0 < V

<3.6

0.6 < PD_OUT <V

– 0.6

PLL_CTL0[7:6] = 10

0.42 1.0 1.42 mA

oHCP_OUT

High level output current for

CP_OUT pin (programmed

value ±42%)

3.0 < V

<3.6

0.6 < PD_OUT <V

– 0.6

PLL_CTL0[7:6] = 01

–210 –500 –710 µA

oLCP_OUT

Low level output current for

CP_OUT pin (programmed

value ±42%)

3.0 < V

<3.6

0.6 < PD_OUT <V

– 0.6

PLL_CTL0[7:6] = 01

210 500 710 µA

oHCP_OUT

High level output current for

CP_OUT pin (programmed

value ±42%)

3.0 < V

<3.6

0.6 < PD_OUT <V

– 0.6

PLL_CTL0[7:6] = 00

–42 –100 –142 µA

oLCP_OUT

Low level output current for

CP_OUT pin (programmed

value ±42%)

3.0 < V

<3.6

0.6 < PD_OUT <V

– 0.6

PLL_CTL0[7:6] = 00

42 100 142 µA

Match I

OHCP_OUT

–I

OLCP_OUT

current match 3.0 < V

<3.6

0.6 < CP_OUT <V

– 0.6

PLL_CTL0[7:6] = XX

–15 +15 %

LCP_OUT

Tristate leakage on CP_OUT

output pin CP_OUT tristated –1 1 µA

osc

Crystal oscillator frequency PLL_CTL0[5:4] = 01 1 M 10 M Hz

Note:

PS027001-0707 Phase-Locked Loop

eZ80F91 ASSP

Product Specification

277

vco

VCO frequency Recommended operating

conditions 50 MHz

vco

VCO Gain Recommended operating

conditions 36 120 MHz/

D1 SCLK Duty Cycle from PLL or

XTALOSC source. Recommended operating

conditions 45 50 55 %

T1A PLL Clock Jitter F

VCO

= 50 MHz. XTALOSC

= 10 MHz 350 500 ps

Lock2 PLL Lock-Time F

VCO

= 50 MHz. XTALOSC

= 3.579 MHz

pll1

= 220 pF, R

pll

= 499¾,

pll2

= 0.056 µF

oH1

(XTL) High-level Output Current for

XTAL2 pin V

= V

–0.4 V

PLL_CTL0[5:4] = 01 –0.3 mA

oL1

(XTL) Low-level Output Cu rrent for

XTAL2 pin V

= 0.4 V

PLL_CTL0[5:4] = 01 0.6 mA

oH2

(XTL) High-level Output Current for

XTAL2 pin V

= V

–0.4 V

PLL_CTL0[5:4] = 11 mA

oL2

(XTL) Low-level Output Cu rrent for

XTAL2 pin V

= 0.4 V

PLL_CTL0[5:4] = 11 mA

PP3M

(XTL) Peak-to-peak voltage under

oscillator conditions for

XTAL2 pin

FOSC = 3.579 MHz

Cx1 = 10 pF

Cx2 = 10 pF

PP10M

(XTL) Peak-to-peak voltage under

oscillator conditions for

XTAL2 pin

FOSC = 10 MHz

Cx1 = 10 pF

Cx2 = 10 pF

xtal1

(package

type)

Capacitance measured from

XTAL1 pin to GND T = 25 ºC pF

xtal2

(package

type)

Capacitance measured from

XTAL2 pin to GND T = 25 ºC pF

loop

(package

type)

Capacitance measured from

loop filter pin to GND T = 25 ºC pF

Table 156. PLL Characteristics (Continued)

Symbol Parameter Test Condition Min Typ Max Units

PS027001-0707 Phase-Locked Loop

eZ80F91 ASSP

Product Specification

278

PS027001-0707 eZ80® CPU Instruction Set

eZ80F91 ASSP

Product Specification

279

eZ80® CPU Instruction Set

Table 157 through Table 166 indicate the CPU instructions available for use with the

eZ80F91 device. The instructions are grouped by class. For more information, refer to

eZ80 CPU User Manual (UM0077).

Table 157. Arithmetic Instructions

Mnemonic Instruction

ADC Add with Carry

ADD Add without Carry

CP Compare with Accumulator

DAA Decimal Adjust Accumulator

DEC Decrement

INC Increment

MLT Multiply

NEG Negate Accumulator

SBC Subtract with Carry

SUB Subtract without Carry

Table 158. Bit Manipulation Instructions

Mnemonic Instruction

BIT Bit Test

RES Reset Bit

SET Set Bit

Table 159. Block Transfer and Compare Instructions

Mnemonic Instruction

CPD (CPDR) Compare and Decremen t (wit h Rep e at )

CPI (CPIR) Compare and In cre m en t (wit h Rep e at )

LDD (LDDR) Load and Decrement (with Repeat)

LDI (LDIR) Load and Increment (with Repeat)

PS027001-0707 eZ80® CPU Instruction Set

eZ80F91 ASSP

Product Specification

280

Table 160. Exchange Instructions

Mnemonic Instruction

EX Exchange registers

EXX Exchange CPU Multibyte register banks

Table 161. Input/Output Instructions

Mnemonic Instruction

IN Input from I/O

IN0 Input from I/O on Page 0

IND (INDR) Input from I/O and Decrement (with Repeat)

INDRX Input from I/O and Decrement Memory Address with Stationary

I/O Address

IND2 (IND2R) Input from I/O and Decrement (with Repeat)

INDM (INDMR) Input from I/O and Decrement (with Repeat)

INI (INIR) Input from I/O and Increment (with Repeat)

INIRX Input from I/O and Increment Memory Address with Stationary

I/O Address

INI2 (INI2R) Input from I/O and Increment (with Repeat)

INIM (INIMR) Input from I/O and Increment (with Repeat)

OTDM (OTDMR) Output to I/O and Decrement (with Repeat)

OTDRX Output to I/O and Decrement Memory Address with Stationary

I/O Address

OTIM (OTIMR) Output to I/O and Increment (with Repeat)

OTIRX Output to I/O and Increment Memory Address with Stationary

I/O Address

OUT Output to I/O

OUT0 Output to I/0 on Page 0

OUTD (OTDR) Output to I/O and Decrement (with Repeat)

OUTD2 (OTD2R) Output to I/O and Decrement (with Repeat)

OUTI (OTIR) Output to I/O and Increment (with Repeat)

PS027001-0707 eZ80® CPU Instruction Set

eZ80F91 ASSP

Product Specification

281

OUTI2 (OTI2R) Output to I/O and Increment (with Repeat)

TSTIO Test I/O

Table 162. Load Instructions

Mnemonic Instruction

LD Load

LEA Load Effective Address

PEA Push Effective Address

POP Pop

PUSH Push

Table 163. Logical Instructions

Mnemonic Instruction

AND Logical AND

CPL Com p lem e nt Accum ula to r

OR Logical OR

TST Test Accumulator

XOR Logical Exclusive OR

Table 164. Processor Control Instructions

Mnemonic Instruction

CCF Complement Carry Flag

DI Disable Interrupts

EI Enable Interrupts

HALT Halt

IM Interrupt Mode

NOP No Operation

Table 161. Input/Output Instructions (Continued)

Mnemonic Instruction

PS027001-0707 eZ80® CPU Instruction Set

eZ80F91 ASSP

Product Specification

282

RSMIX Reset Mixed-Memory Mode Flag

SCF Set Carry Flag

SLP Sleep

STMIX Set Mixed-Memory Mode Flag

Table 165. Program Control Instructions

Mnemonic Instruction

CALL Call Subroutine

CALL cc Conditional Call Subroutine

DJNZ Decrement and Jump if Nonzero

JP Jump

JP cc Conditional Jump

JR Jump Relative

JR cc Conditional Jump Relative

RET Return

RET cc Conditional Return

RETI Return from Interrupt

RETN Return from Nonmaskable interrupt

RST Restart

Table 166. Rotate and Shift Instructions

Mnemonic Instruction

RL Rotate Left

RLA Rotate Left–Accumulator

RLC Rotate Left Circular

RLCA Rotate Left Circular–Accumulator

RLD Rotate Left Decimal

RR Rotate Right

Table 164. Processor Control Instructions (Continued)

Mnemonic Instruction

PS027001-0707 eZ80® CPU Instruction Set

eZ80F91 ASSP

Product Specification

283

RRA Rotate Right–Accumulator

RRC Rotate Right Circular

RRCA Rotate Right Circular–Accumulator

RRD Rot ate Right Decimal

SLA Shift Left Arithmetic

SRA Shift Right Arithmetic

SRL Shift Right Logical

Table 166. Rotate and Shift Instructions (Continued)

Mnemonic Instruction

PS027001-0707 eZ80® CPU Instruction Set

eZ80F91 ASSP

Product Specification

284

Opcode Map

Table 167 through Table 173 indicate the hex values for each of the eZ80 instructions.

Table 167. Opcode Map—First Opcode

Lower Nibb le (Hex)

0123456789ABCDEF

Upper Nibble (Hex)

0NOP LD

BC,

Mmn

(BC),A INC

BC INC

BDEC

BLD

B,n RLCA EX

AF,AF’ ADD

HL,BC LD

A,(BC) DEC

BC INC

CDEC

CLD

C,n RRCA

1DJNZ

dLD

DE,

Mmn

(DE),A INC

DE INC

DDEC

DLD

D,n RLA JR

dADD

HL,DE LD

A,(DE) DEC

DE INC

EDEC

ELD

E,n RRA

2JR

NZ,d LD

HL,

Mmn

(Mmn),

INC

HL INC

HDEC

HLD

H,n DAA JR

Z,d ADD

HL,HL LD

HL,

(Mmn)

DEC

HL INC

LDEC

LLD

L,n CPL

3JR

NC,d LD

SP,

Mmn

(Mmn),

INC

SP INC

(HL) DEC

(HL) LD

(HL),n SCF JR

CF,d ADD

HL,SP LD

(Mmn)

DEC

SP INC

ADEC

ALD

A,n CCF

4.SIS

suffix LD

B,C LD

B,D LD

B,E LD

B,H LD

B,L LD

B,(HL) LD

B,A LD

C,B .LIS

suffix LD

C,D LD

C,E LD

C,H LD

C,L LD

C,(HL) LD

C,A

5LD

D,B LD

D,C .SIL

suffix LD

D,E LD

D,H LD

D,L LD

D,(HL) LD

D,A LD

E,B LD

E,C LD

E,D .LIL

suffix LD

E,H LD

E,L LD

E,(HL) LD

E,A

6LD

H,B LD

H,C LD

H,D LD

H,E LD

H,H LD

H,L LD

H,(HL) LD

H,A LD

L,B LD

L,C LD

L,D LD

L,E LD

L,H LD

L,L LD

L,(HL) LD

L,A

7LD

(HL),B LD

(HL),C LD

(HL),D LD

(HL),E LD

(HL),H LD

(HL),L HALT LD

(HL),A LD

A,B LD

A,C LD

A,D LD

A,E LD

A,H LD

A,L LD

A,(HL) LD

A,A

8ADD

A,B ADD

A,C ADD

A,D ADD

A,E ADD

A,H ADD

A,L ADD

A,(HL) ADD

A,A ADC

A,B ADC

A,C ADC

A,D ADC

A,E ADC

A,H ADC

A,L ADC

A,(HL) ADC

A,A

9SUB

A,B SUB

A,C SUB

A,D SUB

A,E SUB

A,H SUB

A,L SUB

A,(HL) SUB

A,A SBC

A,B SBC

A,C SBC

A,D SBC

A,E SBC

A,H SBC

A,L SBC

A,(HL) SBC

A,A

AAND

A,B AND

A,C AND

A,D AND

A,E AND

A,H AND

A,L AND

A,(HL) AND

A,A XOR

A,B XOR

A,C XOR

A,D XOR

A,E XOR

A,H XOR

A,L XOR

A,(HL) XOR

A,A

BOR

A,B OR

A,C OR

A,D OR

A,E OR

A,H OR

A,L OR

A,(HL) OR

A,A CP

A,B CP

A,C CP

A,D CP

A,E CP

A,H CP

A,L CP

A,(HL) CP

A,A

CRET

NZ POP

BC JP

NZ,

Mmn

Mmn CALL

NZ,

Mmn

PUSH

BC ADD

A,n RST

00h RET

ZRET JP

Mmn

See

Table

168

CALL

Mmn

CALL

Mmn ADC

A,n RST

08h

DRET

NC POP

DE JP

NC,

Mmn

OUT

(n),A CALL

NC,

Mmn

PUSH

DE SUB

A,n RST

10h RET

CF EXX JP

CF,

Mmn

A,(n) CALL

CF,

Mmn

See

Table

169

SBC

A,n RST

18h

ERET

PO POP

HL JP

PO,

Mmn

(SP),HL CALL

PO,

Mmn

PUSH

HL AND

A,n RST

20h RET

PE JP

(HL) JP

PE,

Mmn

DE,HL CALL

PE,

Mmn

See

Table

170

XOR

A,n RST

28h

FRET

PPOP

AF JP

Mmn

DI CALL

Mmn

PUSH

AF OR

A,n RST

30h RET

MLD

SP,HL JP

Mmn

EI CALL

Mmn

See

Table

171

A,n RST

38h

Note: n = 8-bit data; Mmn = 16- or 24-bit addr or data; d = 8-bit two’s-complement displacement.

AND

Lower Opcode Nibble

Mnemonic

Second Operand

Upper

Opcode

Nibble

First Operand A,H

Legend

PS027001-0707 eZ80® CPU Instruction Set

eZ80F91 ASSP

Product Specification

285

Table 168. Opcode Map—Second Opcode after 0CBh

Lower Nibb le (Hex)

0123456789ABCDEF

Upper Nibble (Hex)

0RLC

BRLC

CRLC

DRLC

ERLC

HRLC

LRLC

(HL) RLC

ARRC

BRRC

CRRC

DRRC

ERRC

HRRC

LRRC

(HL) RRC

1RL

BRL

CRL

DRL

ERL

HRL

LRL

(HL) RL

ARR

BRR

CRR

DRR

ERR

HRR

LRR

(HL) RR

2SLA

BSLA

CSLA

DSLA

ESLA

HSLA

LSLA

(HL) SLA

ASRA

BSRA

CSRA

DSRA

ESRA

HSRA

LSRA

(HL) SRA

3SRL

BSRL

CSRL

DSRL

ESRL

HSRL

LSRL

(HL) SRL

4BIT

0,B BIT

0,C BIT

0,D BIT

0,E BIT

0,H BIT

0,L BIT

0,(HL) BIT

0,A BIT

1,B BIT

1,C BIT

1,D BIT

1,E BIT

1,H BIT

1,L BIT

1,(HL) BIT

1,A

5BIT

2,B BIT

2,C BIT

2,D BIT

2,E BIT

2,H BIT

2,L BIT

2,(HL) BIT

2,A BIT

3,B BIT

3,C BIT

3,D BIT

3,E BIT

3,H BIT

3,L BIT

3,(HL) BIT

3,A

6BIT

4,B BIT

4,C BIT

4,D BIT

4,E BIT

4,H BIT

4,L BIT

4,(HL) BIT

4,A BIT

5,B BIT

5,C BIT

5,D BIT

5,E BIT

5,H BIT

5,L BIT

5,(HL) BIT

5,A

7BIT

6,B BIT

6,C BIT

6,D BIT

6,E BIT

6,H BIT

6,L BIT

6,(HL) BIT

6,A BIT

7,B BIT

7,C BIT

7,D BIT

7,E BIT

7,H BIT

7,L BIT

7,(HL) BIT

7,A

8RES

0,B RES

0,C RES

0,D RES

0,E RES

0,H RES

0,L RES

0,(HL) RES

0,A RES

1,B RES

1,C RES

1,D RES

1,E RES

1,H RES

1,L RES

1,(HL) RES

1,A

9RES

2,B RES

2,C RES

2,D RES

2,E RES

2,H RES

2,L RES

2,(HL) RES

2,A RES

3,B RES

3,C RES

3,D RES

3,E RES

3,H RES

3,L RES

3,(HL) RES

3,A

ARES

4,B RES

4,C RES

4,D RES

4,E RES

4,H RES

4,L RES

4,(HL) RES

4,A RES

5,B RES

5,C RES

5,D RES

5,E RES

5,H RES

5,L RES

5,(HL) RES

5,A

BRES

6,B RES

6,C RES

6,D RES

6,E RES

6,H RES

6,L RES

6,(HL) RES

6,A RES

7,B RES

7,C RES

7,D RES

7,E RES

7,H RES

7,L RES

7,(HL) RES

7,A

CSET

0,B SET

0,C SET

0,D SET

0,E SET

0,H SET

0,L SET

0,(HL) SET

0,A SET

1,B SET

1,C SET

1,D SET

1,E SET

1,H SET

1,L SET

1,(HL) SET

1,A

DSET

2,B SET

2,C SET

2,D SET

2,E SET

2,H SET

2,L SET

2,(HL) SET

2,A SET

3,B SET

3,C SET

3,D SET

3,E SET

3,H SET

3,L SET

3,(HL) SET

3,A

ESET

4,B SET

4,C SET

4,D SET

4,E SET

4,H SET

4,L SET

4,(HL) SET

4,A SET

5,B SET

5,C SET

5,D SET

5,E SET

5,H SET

5,L SET

5,(HL) SET

5,A

FSET

6,B SET

6,C SET

6,D SET

6,E SET

6,H SET

6,L SET

6,(HL) SET

6,A SET

7,B SET

7,C SET

7,D SET

7,E SET

7,H SET

7,L SET

7,(HL) SET

7,A

Note: n = 8-bit data; Mmn = 16- or 24-bit addr or data; d = 8-bit two’s-complement displacement.

RES

Lower Nibble of 2nd Opcode

Mnemonic

Second Operand

Upper

Opcode

First Operand 4,H

of Second

Nibble

Legend

PS027001-0707 eZ80® CPU Instruction Set

eZ80F91 ASSP

Product Specification

286

Table 169. Opcode Map—Second Opcode After 0DDh

Lower Nibb le (Hex)

0123456789ABCDEF

Upper Nibble (Hex)

0LD BC,

(IX+d) ADD

IX,BC LD

(IX+d),

1 LD DE,

(IX+d) ADD

IX,DE LD

(IX+d),

2LD

IX,

Mmn

(Mmn),

INC

IX INC

IXH DEC

IXH LD

IXH,n LD HL,

(IX+d) ADD

IX,IX LD

IX,

(Mmn)

DEC

IX INC

IXL DEC

IXL LD

IXL,n LD

(IX+d),

3LD IY,

(IX+d) INC

(IX+d) DEC

(IX+d) LD (IX

+d),n LD IX,

(IX+d) ADD

IX,SP LD

(IX+d),

4LD

B,IXH LD

B,IXL LD B,

(IX+d) LD

C,IXH LD

C,IXL LD C,

(IX+d)

5LD

D,IXH LD

D,IXL LD D,

(IX+d) LD

E,IXH LD

E,IXL LD E,

(IX+d)

6LD

IXH,B LD

IXH,C LD

IXH,D LD

IXH,E LD

IXH,IXH LD

IXH,IXL LD H,

(IX+d) LD

IXH,A LD

IXL,B LD

IXL,C LD

IXL,D LD

IXL,E LD

IXL,IXH LD

IXL,IXL LD L,

(IX+d) LD

IXL,A

7LD

(IX+d),B LD

(IX+d),C LD

(IX+d),D LD

(IX+d),E LD

(IX+d),H LD

(IX+d),L LD

(IX+d),A LD

A,IXH LD

A,IXL LD A,

(IX+d)

8 ADD

A,IXH ADD

A,IXL ADD A,

(IX+d) ADC

A,IXH ADC

A,IXL ADC A,

(IX+d)

9SUB

A,IXH SUB

A,IXL SUB A,

(IX+d) SBC

A,IXH SBC

A,IXL SBC A,

(IX+d)

A AND

A,IXH AND

A,IXL AND A,

(IX+d) XOR

A,IXH XOR

A,IXL XOR A,

(IX+d)

BOR

A,IXH OR

A,IXL OR A,

(IX+d) CP

A,IXH CP

A,IXL CP A,

(IX+d)

CTable

172

EPOP

IX EX

(SP),IX PUSH

IX JP

(IX)

FLD

SP,IX

Note: n = 8-bit data; Mmn = 16- or 24-bit addr or data; d = 8-bit two’s-complement displacement.

FMnemonic

Second Operand

First Operand SP,IX

Lower Nibble of 2nd Opcode

Upper

Opcode

of Second

Nibble

Legend

PS027001-0707 eZ80® CPU Instruction Set

eZ80F91 ASSP

Product Specification

287

Table 170. Opcode Map—Second Opcode After 0EDh

Lower Nibb le (Hex)

0123456789ABCDEF

Upper Nibble (Hex)

0IN0

B,(n) OUT0

(n),B LEA

BC,

IX+d

LEA

BC,

IY+d

TST

A,B LD BC,

(HL) IN0

C,(n) OUT0

(n),C TST

A,C LD

(HL),

1IN0

D,(n) OUT0

(n),D LEA

DE,

IX+d

LEA

DE,

IY+d

TST

A,D LD DE,

(HL) IN0

E,(n) OUT0

(n),E TST

A,E LD(HL),

2IN0

H,(n) OUT0

(n),H LEA HL

,IX+d LEA HL

,IY+d TST

A,H LD HL,

(HL) IN0

L,(n) OUT0

(n),L TST

A,L LD

(HL),

3LD IY,

(HL) LEA IX

,IX+d LEA IY

,IY+d TST

A,(HL) LD IX,

(HL) IN0

A,(n) OUT0

(n),A TST

A,A LD

(HL),IY LD

(HL),

4IN

B,(BC) OUT

(BC),B SBC

HL,BC LD

(Mmn),

NEG RETN IM 0 LD

I,A IN

C,(C) OUT

(C),C ADC

HL,BC LD

BC,

(Mmn)

MLT

BC RETI LD

R,A

5IN

D,(BC) OUT

(BC),D SBC

HL,DE LD

(Mmn),

LEA IX,

IY+d LEA IY,

IX+d IM 1 LD

A,I IN

E,(C) OUT

(C),E ADC

HL,DE LD

DE,

(Mmn)

MLT

DE IM 2 LD

A,R

6IBN

H,(C) OUT

(BC),H SBC

HL,HL LD

(Mmn),

TST

A,n PEA

IX+d PEA

IY+d RRD IN

L,(C) OUT

(C),L ADC

HL,HL LD

HL,

(Mmn)

MLT

HL LD

MB,A LD

A,MB RLD

7 SBC

HL,SP LD

(Mmn),

TSTIO

nSLP IN

A,(C) OUT

(C),A ADC

HL,SP LD

SP,

(Mmn)

MLT

SP STMIX RSMIX

8 INIM OTIM INI2 INDM OTDM IND2

9 INIMR OTIMR INI2R INDMR OTDMR IND2R

A LDI CPI INI OUTI OUTI2 LDD CPD IND OUTD OUTD2

B LDIR CPIR INIR OTIR OTI2R LDDR CPDR INDR OTDR OTD2R

C INIRX OTIRX LD

I,HL INDRX OTDRX

DLD

HL,I

Note: n = 8-bit data; Mmn = 16- or 24-bit addr or data; d = 8-bit two’s-complement displacement.

SBC

4Mnemonic

Second Operand

First Operand HL,BC

Lower Nibble of 2nd Opcode

Upper

Opcode

of Second

Nibble

Legend

PS027001-0707 eZ80® CPU Instruction Set

eZ80F91 ASSP

Product Specification

288

Table 171. Opcode Map—Second Opcode After 0FDh

Lower Nibb le (Hex)

0123456789ABCDEF

Upper Nibble (Hex)

0LD BC,

(IY+d) ADD

IY,BC LD (IY

+d),BC

1 LD DE,

(IY+d) ADD

IY,DE LD (IY

+d),DE

2LD

IY,Mmn LD

(Mmn),I

INC

IY INC

IYH DEC

IYH LD

IYH,n LD HL,

(IY+d) ADD

IY,IY LD

IY,

(Mmn)

DEC

IY INC

IYL DEC

IYL LD

IYL,n LD (IY

+d),HL

3LD IX,

(IY+d) INC

(IY+d) DEC

(IY+d) LD (IY

+d),n LD IY,

(IY+d) ADD

IY,SP LD (IY

+d),IX LD (IY

+d),IY

4LD

B,IYH LD

B,IYL LD B,

(IY+d) LD

C,IYH LD

C,IYL LD C,

(IY+d)

5LD

D,IYH LD

D,IYL LD D,

(IY+d) LD

E,IYH LD

E,IYL LD E,

(IY+d)

6LD

IYH,B LD

IYH,C LD

IYH,D LD

IYH,E LD

IYH,IYH LD

IYH,IYL LD H,

(IY+d) LD

IYH,A LD

IYL,B LD

IYL,C LD

IYL,D LD

IYL,E LD

IYL,IYH LD

IYL,IYL LD L,

(IY+d) LD

IYL,A

7LD (IY

+d),B LD (IY

+d),C LD (IY

+d),D LD (IY

+d),E LD (IY

+d),H LD (IY

+d),L LD (IY

+d),A LD

A,IYH LD

A,IYL LD A,

(IY+d)

8 ADD

A,IYH ADD

A,IYL ADD A,

(IY+d) ADC

A,IYH ADC

A,IYL ADC A,

(IY+d)

9SUB

A,IYH SUB

A,IYL SUB A,

(IY+d) SBC

A,IYH SBC

A,IYL SBC A,

(IY+d)

A A ND

A,IYH AND

A,IYL AND A,

(IY+d) XOR

A,IYH XOR

A,IYL XOR A,

(IY+d)

BOR

A,IYH OR

A,IYL OR A,

(IY+d) CP

A,IYH CP

A,IYL CP A,

(IY+d)

CTable

173

EPOP

IY EX

(SP),IY PUSH

IY JP

(IY)

FLD

SP,IY

Note: n = 8-bit data; Mmn = 16- or 24-bit addr or data; d = 8-bit two’s-complement displacement.

FMnemonic

Second Operand

First Operand SP,IY

Lower Nibble of 2nd Opcode

Upper

Opcode

of Second

Nibble

Legend

PS027001-0707 eZ80® CPU Instruction Set

eZ80F91 ASSP

Product Specification

289

Table 172. Opcode Map—Fourth By te Af ter 0DDh, 0CBh, and dd

Lower Nibb le (Hex)

0123456789ABCDEF

Upper Nibble (Hex)

0RLC

(IX+d) RRC

(IX+d)

1RL

(IX+d) RR

(IX+d)

2SLA

(IX+d) SRA

(IX+d)

3SRL

(IX+d)

4 BIT 0,

(IX+d) BIT 1,

(IX+d)

5 BIT 2,

(IX+d) BIT 3,

(IX+d)

6 BIT 4,

(IX+d) BIT 5,

(IX+d)

7 BIT 6,

(IX+d) BIT 7,

(IX+d)

8 RES 0,

(IX+d) RES 1,

(IX+d)

9 RES 2,

(IX+d) RES 3,

(IX+d)

A RES 4,

(IX+d) RES 5,

(IX+d)

B RES 6,

(IX+d) RES 7,

(IX+d)

C SET 0,

(IX+d) SET 1,

(IX+d)

D SET 2,

(IX+d) SET 3,

(IX+d)

E SET 4,

(IX+d) SET 5,

(IX+d)

F SET 6,

(IX+d) SET 7,

(IX+d)

Note: d = 8-bit two’s-complement displacement

BIT

Lower Nibble of 4th Byte

Mnemonic

Second Operand

Upper

Byte

First Operand 0,(IX+d)

of Fourth

Nibble

Legend

PS027001-0707 eZ80® CPU Instruction Set

eZ80F91 ASSP

Product Specification

290

Table 173. Opcode Map—Fourth Byte After 0FDh, 0CBh, and dd

Lower Nibb le (Hex)

0123456789ABCDEF

Upper Nibble (Hex)

0RLC

(IY+d) RRC

(IY+d)

1RL

(IY+d) RR

(IY+d)

2SLA

(IY+d) SRA

(IY+d)

3SRL

(IY+d)

4 BIT 0,

(IY+d) BIT 1,

(IY+d)

5 BIT 2,

(IY+d) BIT 3,

(IY+d)

6 BIT 4,

(IY+d) BIT 5,

(IY+d)

7 BIT 6,

(IY+d) BIT 7,

(IY+d)

8RES 0,

(IY+d) RES 1,

(IY+d)

9RES 2,

(IY+d) RES 3,

(IY+d)

ARES 4,

(IY+d) RES 5,

(IY+d)

BRES 6,

(IY+d) RES 7,

(IY+d)

CSET 0,

(IY+d) SET 1,

(IY+d)

DSET 2,

(IY+d) SET 3,

(IY+d)

ESET 4,

(IY+d) SET 5,

(IY+d)

FSET 6,

(IY+d) SET 7,

(IY+d)

Note: d = 8-bit two’s-complement displacement

BIT

Lower Nibble of 4th Byte

Mnemonic

Second Operand

Upper

Byte

First Operand 0,(IY+d)

of Fourth

Nibble

Legend

PS027001-0707 Ethernet Media Access Controller

eZ80F91 ASSP

Product Specification

291

Ethernet Media Access Controller

The Ethernet Media Access Controller (EMAC) is a full-function 10/100 Mbps media

access control module with a Media-Independent Interface (MII). When communicating

with an external PHY device, the eZ80F91 ASSP uses the MII to gain access to the

Ethernet network.

Figure 59 illustrates the EMAC block diagram.

For additional information about the Ethernet protocol and using it with the eZ80F91

ASSP, refer to the IEEE 802.3 specification, 1998 edition, Section 22. The eZ 80F91 ASSP

supports the IEEE 802.3 pro t ocol with the following exception:

The eZ80F91 ASSP does not support the Giga Media Independent Interface (GMII)

referred to in the following sections of the IEEE 802.3 1998 version: section 22.1.5, sec-

tion 22.2.4, section 22.2.4.1.2, section 22.2.4.1.5, and section 22.2.4.1.6.

The EMAC is used for many different applications, including network interface, ethernet

switching, and test equipment designs. The EMAC includes the following blocks:

•

Central clock and reset module (not shown in the block diagram).

•

Host memory interface and transmit/receiver arbiter.

Figure 59. EMAC Block Diagram

Media Access Controller

Arbiter

Memory

MDIO

MDC

TxD

TxCLK

TxER

TxEN

COL

CRS

RxD

TxFIFO

TxDMA

RxDMA

RxFIFO

CTRL

RxD/CTRL

Reject

RxCLK

RxDV

RxER

MII Interface

Note:

PS027001-0707 Ethernet Media Access Controller

eZ80F91 ASSP

Product Specification

292

•

FIFO buffer and DMA control blocks for transmit and receive.

•

802.3x media access control block.

•

MII interface management.

The media access control block implements 802.3x flow control functions for both trans-

mit and receive.

The MII management module provides a two-wire control/status path to the MII PHY.

Read and Write communication to and from registers within the PHY is accomplished via

the host interface.

MII PHY is a Physical Layer transceiver device; PHY does not refer to the eZ80F91 sys-

tem clock output pin, PHI.

The MII management module provides a two-wire control/status path to the MII. Read

and Write communication to and from registers within the PHY is accomplished via the

host interface.

EMAC Functional Description

The EMAC block implements memory, arbiter, and transmit and receive direct memory

access functions, and offers four communication modes: HALF-DUPLEX, FULL-

DUPLEX, NIBBLE, and ENDEC. In HALF-DUPLEX and FULL-DUPLEX modes,

throughput occurs at both 10 Mbps and 100 Mbps speeds. Throughput in ENDEC and

NIBBLE modes occurs at 10 Mbps. A brief description of these four modes are as follows:

10/100 Mbps HALF-DUPLEX Mode— In this mode, data are transferred only in one

direction at a time; that is, one can either transmit or receive, but both cannot occur

simultaneously.

10/100 Mbps FULL-DUPLEX Mode— In this mode, data are transmitted and received at

the same time.

10 Mbps ENDEC Mode— This mode affects the MII interface between the PHY and the

MAC. In ENDEC mode, the RxCLK and TxCLK clocks are bit clocks instead of the nor-

mal nibble clock. In NIBBLE mode, 4 bits are transferred on each clock. In ENDEC

mode, 1 bit is transferred per clock.

For more information on throughput, see EMAC and the System Clock on page 300.

Memory

EMAC memory is the shared Ethernet memory location of the Transmit and Receive buf f-

ers. This memory is broken into two parts: the Tx buffer and the Rx buffer. The Transmit

Lower Boundary Pointer Register, EmacTLBP, is the register that holds the starting

address of the Tx buf fer . The Boundary Poin ter Register , EmacBP, points to the start of the

Rx buffer (end of Tx buffer + 1). The Receive High Boundary Pointer Register,

Note:

PS027001-0707 Ethernet Media Access Controller

eZ80F91 ASSP

Product Specification

293

EmacRHBP, points to the end of the Rx buffer + 1. The Tx and Receive buffers are

divided into packet buffers of either 256, 128, 64, or 32 bytes. These buffer sizes are

selected by EmacBufSize register bits 7 and 6.

The EmacBlksLeft register contains the number of Receive packet buffers remaining in

the Rx buffer. This buffer is used for software flow control. If the Block_Lev el is nonzero

(bits 5:0 of the EmacBufSize register), hardware flow control is enabled. If in FULL-

DUPLEX mode, the EMAC transmits a pause control frame when the EmacBlksLeft reg-

ister is less than the Block_Level. In HALF-DUPLEX mode, the EMAC continually trans-

mits a nibble pattern of hexadecimal 5’s to jam the channel.

Four pointers are defined for reading and writing the Tx and Rx buffers. The Transmit

Write Pointer, TWP, is a software pointer that points to the next available packet buffer.

The TWP is reset to the value stored in EmacTLBP. The Transmit Read Pointer, TRP, is a

hardware pointer in the Transmit Direct Memory Access Register, TxDMA, that contains

the address of the next packet to be transmitted. It is automatically reset to the EmacTLBP.

The Receive Write Pointer, RWP, is a hardware pointer in the Receive Direct Memory

Access Register , RxDMA, which contains the storage address of the incoming packet. The

RWP pointer is automatically initialized to the Boundary Pointer registers. The Receive

Read Pointer, RRP, is a software pointer to where the next packet must be read from. The

RRP pointer must be initialized to the Boundary Pointer registers. For the hardware flow

control to function properly, the software must update the hardware RRP (EmacRrp)

pointer whenever the software version is updated. The RxDMA uses RWP and the RRP to

determine how many packet buffers remain in the Rx buffer.

Arbiter

The arbiter controls access to EMAC memory. It prioritizes the requests for memory

access between the CPU, the TxDMA, and the RxDMA. The TxDMA of fers two levels of

priority: a high priority when the TxFIFO is less than half full and a Low priority when the

TxFIFO is more than half full. Similarly, the RxDMA offers two levels of priority: a high

priority when the RxFIFO is more than half full and a Low priority when the RxFIFO is

less than half full.

The arbiter determines resolution between the CPU, the RxDMA, and the TxDMA

requests to access EMAC memory. Post writing for CPU W rites results in Zero-Wait-state

write access timing when the CPU assumes the highest priority. CPU Reads require a min-

imum of 1 Wait state and takes more when the CPU does not hold the highest priority. The

CPU Read Wait state is not a user-controllable operation, because it is controlled by the

arbiter. The RxDMA and TxDMA requests are not allowed to oc cur back-to-back. There-

fore, the maximum throughput rate for the two Direct Memory Access (DMA) ports is 25

MBps each (one byte every 2 clocks) when the system clock is running at 50 MHz. The

rate is reduced to 20 MBps for a 40 MHz system clock. The arbiter uses the internal WAIT

signal to add Wait states to CPU access when required. See Table 174 on page 294.

PS027001-0707 Ethernet Media Access Controller

eZ80F91 ASSP

Product Specification

294

TxDMA

The TxDMA module moves the next packet to be transmitted from EMAC memory into

the TxFIFO. Whenever the polling timer expires, the TxDMA reads the High status byte

from the Tx descriptor table pointed to by the T ransmit Read Pointer, TRP. Polling contin-

ues until the High status Read reaches bit 7, when the Emac_Owns ownership semaphore,

bit 15 of the descriptor table (see Table 178 on page 299) is set to 1. The TxDMA then ini-

tializes the packet length counter with the size of the packet from descriptor table bytes 3

and 4. The TxDMA moves the data into the TxFIFO until the packet length counter down-

counts to zero. The TxDMA then waits for T ransmission Complete signal to be asserted to

indicate that the packet is sent and that the Transmit status from the EMAC is valid. The

TxDMA updates the descriptor table status and resets the ownership semaphore, bit 15.

Finally, the Tx_DONE_STAT bit of the EMAC Interrupt Status Register is set to 1, the

address field, DMA_Address, is updated from the descriptor table next pointer, NP (see

Figure 62 on page 298). The High b yte of th e status is read to determine if the next packet

is ready to be transmitted.

While the TxDMA is filling the TxFIFO, it monitors two signals from the Transmit FIFO

State Machine (TxFifoSM) to detect error conditions and to determine if the packet is to

be retransmitted (TxDMA_Retry asserted) or the packet is aborted (TxDMA_Abort

asserted). If the packet is aborted, the TxDMA updates the descriptor status and moves to

the next packet. If the packet is to be retried, the DMA_Address is reset to the start of the

packet, the packet length counter is reloaded from the descriptor table, bytes 3 and 4, and

the packet is moved into the TxFIFO again. When an abort or retry event occurs, the

TxDMA asserts the appropriate signal to reset the TxFIFO Read and W rite pointers which

clears out any data that is in the FIFO. The TxFifoSM negates the TxDMA_Abort or

TxDMA_Retry signal(s) or both when the TxFCWP signal is High. This handshaking

maintains synchronization between the TxDMA and the TxFifoSM.

RxDMA

The RxDMA reads the data from the RxFIFO and stores it in the EMAC memory Receive

buffer. When the end of the packet is detected, the RxDMA reads the next two bytes from

Table 174. Arbiter Priority

Priority

Level Device

Serviced Flags

0 RxDMA High RxFIFO > half full (FAF)

1 TxDMA High TxFIFO < half full (FAE)

2eZ80

® CPU

3 RxDMA Low RxFIFO < half full (FAE)

4 TxDMA Low T xFIFO > half full (FAF)

PS027001-0707 Ethernet Media Access Controller

eZ80F91 ASSP

Product Specification

295

the RxFIFO and writes them into the Rx descriptor status LSB and MSB. The packet-

length counter is stored into the descriptor table’s Packet Length field, and the descriptor

table’s next pointer is written into the Rx descriptor table. Additionally, the

Rx_DONE_STAT bit in the EMAC Interrupt Status Register is set to 1.

Signal Termination

When the EMAC interface is not used, the MII signals must be terminated as indicated in

Table 175. Terminated pins are either left unconnected (float) or tied to ground.

MDIO is controlled by the MDC output signal. When the EMAC is not being used, these

two pins are not driven. The RX_DV, RX_ER, and RXD[3:0] inputs are controlled by the

rising edge of the RX_CLK input signal. When RX_CLK is tied to Ground, these pins do

not affect the EMAC. The TX_EN, TX_ER, and TXD[3:0] outputs are controlled by the

rising edge of the TX_CLK input signal. When TX_CLK is tied to Ground, these pins do

not affect the EMAC. The CRS and COL input pi ns have no relationship to the clock, and

therefore must be placed into nonactive states and tied to Ground.

Table 175. MII Signal Termination When EMAC is Not Used

Signal Pin Type Termination

Direction

MDIO Bidirectional Float

MDC Output pin Float

RX_DV Input pin Float

CRS Input pin Ground

RX_CLK Input pin Ground

RX_ER Input pin Float

RXD[3:0] Input pins Float

COL Input pin Ground

TX_CLK Input pin Ground

TX_EN O ut pu t pin F lo at

TXD[3:0] Output pins Flo at

TX_ER O ut pu t pin F lo at

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EMAC Interrupts

Eight different sources of interrupts from the EMAC are described in Table 176.

EMAC Shared Memory Organization

Internal Ethernet SRAM shares memory with the CPU. This memory is divided into the

Transmit buffer and the Receive buffer by defining three registers, as listed below.

•

Transmit Lower Boundary Pointer (TLBP)—this register points to the start of the

Transmit buffer in the internal Ethernet shared memory space.

•

Boundary Pointer (BP)—this register points to the start of the Receive buffer.

Table 176. EMAC Interrupts

Interrupt Description

EMAC System Interrupts

Transmit State M achin e Err or Bit 7 (TxFSMERR_STAT) of the EMAC Interrupt Status Register

(EMAC_ISTAT). A Transmit State Machine Error must not occu r.

However, if this bit is set, the entire transmitter module must be

reset.

MIIMGT Done Bit 6 (MGTDONE_STAT) of the Interrupt Stat us Re gister

(EMAC_ISTAT). This bit is set when communicating to the PHY

over the MII during a Read or Write operation.

Receive Overrun Bit 2 (Rx_OVR_STAT) of the Interrupt Status Register

(EMAC_ISTAT). If this bit is set, all incoming packets are ignored

until this bit is cleared by software.

EMAC Transmitter Interrupts

Transmit Control Frame Transmit Control Frame = Bit 1 (Tx_CF_STAT) of the Interrupt

Status Register (EMAC_ISTAT). Denotes when co ntrol frame

transmission is complete.

Transmit Done Bit 0 (Tx_DONE_STAT) of the Interrupt Status Register

(EMAC_ISTAT). Denotes when packet transmission is complete.

EMAC Receiver Interrupts

Receive Packet Bit 5 (Rx_CF_STAT) of the Interrupt Status Register

(EMAC_ISTAT). Denotes when packet reception is complete.

Receive Pause Packet Bit 4 (Rx_PCF_STAT) of the Interrupt Status Register

(EMAC_ISTAT). Denotes when pause packet reception is

complete.

Receive Done Bit 3 (Rx_DONE_STAT) of the Interrupt Stat us Re gis te r

(EMAC_ISTAT). Denotes when packet reception is complete.

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•

Receive High Boundary Pointer (RHBP)—this register points to the end of the Receive

buffer + 1.

Figure 60 displays the internal Ethernet shared memory.

The T ransmit and Receive buffers are subdivided into packet buf fers of 32, 6 4, 128, or 256

bytes in size. The packet buffer size is set in bits 7 and 6 of the EmacBufSize register. An

Ethernet packet accommodate multiple packet buf fers. First, however , a brief listing of the

contents of a typical Ethernet packet is in order. See Table 177.

At the start of each packet is a descriptor table that describes the pac ke t. Each actual

Ethernet packet follows the descriptor table as illustrated in Figure 61 on page 298.

Figure 60. Internal Ethernet Shared Memory

Table 177. Ethernet Packet Contents

Byte Range Contents

Bytes 0–5 M AC de st ina tio n ad dre ss.

Bytes 6–11 MAC source address.

Bytes 12–13 Length/Type field.

Bytes 14–n MAC Client Data.

Bytes (n+1)–(n+4) Frame Check Sequence.

RHBP Rx Buffer

Tx Buffer

TLBP

Upper Memory Address

Lower Memory Address

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For an official description of an Ethernet packet, refer to IEEE 802.3 specification, Figure

3-1.

The descriptor table contains three entries: the next pointer (NP), the packet size

(Pkt_Size) and the packet status (Stat), as illustrated in Figure 62.

NP is a 24-bit pointer to the start of the next packet. Pkt_Size contains the number of bytes

of data in the Ethernet packet, including the four CRC bytes, but does not contain the

seven descriptor table bytes. Stat contains the status of the packet. Stat dif fers for T ransmit

and Receive packets. See Table 178 and Table 179 on page 299.

Figure 61. Descriptor Table

Figure 62. Descriptor Table Entries

TWP 0000h

Offset

0007h

Descriptor

Table

Ethernet

Packet

Note:

TWP 0000h

Offset

0005h

0003h

Pkt_Size

Stat

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Table 178. Tr ansmit Descriptor Status

Bit Name Description

15 TxOwner 0 = Host (eZ80) owns, 1 = EMAC owns.

14 TxAbort 1 = Packet aborted (not transmitted).

13 TxBPA 1 = Back pressure applied.

12 TxHuge 1 = Packet size is very large (Pkt_Size > EmacMaxf).

11 TxLOOR 1 = Type/Length field is out of range (lar ger than 1518 bytes).

10 TxLCError 1 = Type/Length field is not a Type field and it does not match the

actual data byte length of the Ethernet packet. The data byte length is

the number of bytes of data in the Ethernet packet between the Type/

Length field and the FCS.

9 TxCrcError 1 = The packet contains an invalid FCS (CRC). This flag is set when

CRCEN = 0 and the last 4 bytes of the packet are not the valid FCS.

8 TxPktDeferred 1 = Packet is deferred.

7 TxXsDfr 1 = Packet is excessively deferred. (> 60 7 1 nib ble time s in 10 0 BaseT

or 24,287 bit times in 10 BaseT).

6 TxFifoUnderRun 1 = TxFIFO experiences underrun. Check the TxAbor t bit to see if the

packet is aborted or retried.

5 TxLateCol 1 = A late collision occurs. Collision is detected at a byte count >

EmacCfg2[5:0]. Collisions detected before the byte count reaches

EmacCfg2[5:0] are early collisions and retried.

4 TxMaxCol 1 = The maximum number of collisions occurs. # Collisions >

EmacCfg3[3:0]. These packets are aborted.

[3:0] TxNumberOfCollisions This field contains the number of collisions that occur while transmitting

the packet.

Table 179. Receive Descriptor Status

Bit Name Description

15 RxOK 1 = Packet received intact.

14 RxAlignError 1 = An odd number of nibbles is received.

13 RxCrcError 1 = The CRC (FCS) is in error.

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EMAC and the System Clock

Ef fectiv e Ethernet through pu t in any given system is dependent upon factors such as sys-

tem clock speed, network protocol overhead, application complexity, and network traffic

conditions at any given moment. The following information provides a general guideline

about the effects of system clock speed on Ethernet operation.

The eZ80F91 ASSP's EMAC block performs a synchronous function that is designed to

operate over a wide range of system clock frequencies. To understand its maximum data

12 RxLongEvent 1 = A Long or Dropped Event occurs. A Long Event is when a packet

over 50,000 bit times occurs. A Drop ped Packet occurs if the minimum

interpacket gap is not met, the preamble is not pure, and the

EmacCfg3[PUREP] bit is set, or if a preamble over 11 bytes in length is

detected and the EmacCfg3[LONGP] bit is set to 1.

11 RxPCF 1 = The packet is a pause control frame.

10 RxCF 1 = The packet is a control frame.

9 RxMcPkt 1 = The packet contains a multicast address.

8 RxBcPkt 1 = The packet contains a broadcast address.

7 RxVLAN 1 = The packet is a VLAN packet.

6 RxUOpCode 1 = An unsupported opcode is indicated in the opcode field of the

Ethernet packet.

5 RxLOOR 1 = The Type/Length field is out of range (larger than 1518 bytes).

4 RxLCError 1 = Type/Length field is not a Type field and it does not match the

actual data byte length of the Ethernet packet. The data byte length is

the number of bytes of data in the Ethernet packet between the Type/

Length field and the FCS.

3 RxCodeV 1 = A code violation is detected. The PHY asserts Rx error (RxER).

2 RxCEvent 1 = A carrier event is previously seen. This event is defined as Rx error

RxER = 1, receive data valid (RxDV) = 0 and receive data (RxD) = Eh.

1 RxDvEvent 1 = A receive data (RxDV) event is previously seen. Indicates that the

last Receive event is not long enough to be a valid packet.

0 RxOVR 1 = A Receive overrun occurs in this packet. An overrun occurs when

all of the EMAC Receive buffers are in use and the Receive FIFO is full.

The hardware igno r es all inc omi ng packe ts un til th e Ema cI S ta t

as to how many packets are ignored.

Table 179. Receive Descriptor Status (Continued)

Bit Name Description

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transfer capabilities at certain system operating frequencies, you must first understand the

internal data bus bandwidth that is required under ideal conditions.

For 10 BaseT Ethernet connectivity, the data rate is 10 Mbps, which equates to 1. 25 Mbps.

If the eZ80F91 ASSP is operating in FULL-DUPLEX mode over 10BaseT, the data rate for

RX data and TX data is 1.25 Mbps. Because raw data transfers at this rate consume a cer-

tain amount of CPU bandwidth, the CPU must support traf fic from both directions as well

as operate at a minimum clock frequency of (1.25 + 1.25) * 2 = 5 MHz while transferring

Ethernet packets to and from the physical layer.

Similarly, for 100 BaseT Ethernet, the data rate is 100 Mbps, which equates to 12.5 Mbps.

If the eZ80F91 ASSP is operating in FULL-DUPLEX mode over 100 BaseT, the data rate

for RX data and TX data is 12.5 Mbps. Because raw data transfers at this rate consume a

certain amount of CPU bandwidth, the CPU must support traffic from both directions as

well as operate at a minimum clock frequency of (12.5 + 12.5) x 2 = 50 MHz while trans-

ferring Ethernet packets to and from the physical layer. Consequently, 50 MHz is the min-

imum system clock speed that the eZ80 CPU requires to sustain EMAC data transfers

while not including any software overhead or additional eZ80 tasks.

The FIFO functionality of the EMAC operates at any frequency as long as the user appli-

cation avoids overrun and underrun errors via higher-level flow control. Actual applica-

tion requirements will dictate Ethernet modes of operation (FULL-DUPLEX, HALF-

DUPLEX, etc.). Because each user and application is different, it becomes your responsi-

bility to control the data flow with these parameters. Under ideal conditions, the system

clock will operate somewhere between 5 MHz and 50 MHz to handle the EMAC data

rates.

EMAC Operation in HALT Modes

When the CPU is in HALT mode, the eZ80F91 device’s EMAC block cannot be disabled

as other peripherals. Upon receipt of an Ethernet packet, a maskable Receive interrupt is

generated by the EMAC block, just as it would be in a non-halt mode. Accordingly, the

processor wakes up and continues with the user-defined application.

EMAC Registers

After a system reset, all EMAC registers are set to their default values. Any Writes to

unused registers or register bits are ignored and reads return a value of 0. For compatibil-

ity with future revisions, unused bits within a register must always be written with a value

of 0. Read/Write attributes, reset conditions, and bit descriptions of all of the EMAC reg-

isters are provided in this section.

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EMAC Test Register

The EMAC Test Register allows test functionality of the EMAC block. Available test

modes are defined for bits [6:0]. See Table 180.

Table 180. EMAC Test Register (EMAC_ TEST = 0020h)

Bit 76543210

Reset 00000000

CPU Access R R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write, R = Read Only.

Bit

Position Value Description

7 0 Reserved.

TEST_FIFO 0 FIFO test mode di sabled—Normal operation.

1 FIFO test mode enabled.

TxRx_SEL 0 Select the Receive FIFO when FIFO test mode is enabled.

1 Select the Transmit FIFO when FIFO test mode is enabled.

SSTC 0 Normal operation.

1 Short Cut Slot Timer Counte r. Slot time is shortened to

speed up simulation.

SIMR 0 Normal operation.

1 Simulation Reset.

FRC_OVR_ERR 0 Normal operation.

1 Force Overrun error in Receive FIFO.

FRC_UND_ERR 0 Normal operation.

1 Force Underrun error in Tran smit FIFO.

LPBK 0 Normal operation.

1 EMAC Transmit interface is looped back into EMAC Receive

interface.

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EMAC Configuration Register 1

The EMAC Configuration Register 1 allows control of the padding, autodetection, cyclic

redundancy checking (CRC) control, full-duplex , field length checking, max imu m packet

ignores, and proprietary header options. See Table 181.

Table 181. EMAC Configuration Re gister 1 (EMAC_CFG1 = 0021h)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit

Position Value Description

PADEN 0 No padding. Assume all frames presented to EMAC have

proper length.

1 EMAC pads all short fra mes by adding zeroes to the end of the

data field. This bit is used in conjunction with ADPADN and

VLPAD.

ADPADN 0 Disable autodetection.

1 Enable frame detection by comparing the two bytes following

the source address with 0x8100 (VLAN Protocol ID) and pad

accordingly. This bit is ignored if PADEN is cleared to 0.

VLPAD 0 Do not pad all sh ort frames.

1 EMAC pads all short frames to 64 bytes and append a valid

CRC. This bit is ignored if PADEN is cleared to 0.

CRCEN 0 Do not append CRC.

1 Append CRC to every frame regardless of padding options.

FULLD 0 HALF-DUPLEX mode. CSMA/CD is enabled.

1 Enable FULL-DUPLEX mode. CSMA/CD is disabled.

FLCHK 0 Ignore the length fie ld with i n Tr a nsm it/ Re ce i ve fr am e s.

1 Both Transmit and Receive frame lengths ar e compared to the

length/type field. If the length/type field represents a length

then the fram e len gt h check is performed .

HUGEN 0 Limit the Receive frame-size to the number of bytes specified

in the MAXF[15:0] field.

1 Allow unlimited sized frames to be received. Ignore the

MAXF[15:0] field.

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Table 182 shows the results of different settings for bits [7:4] of EMAC Configuration

DCRCC 0 No proprietary header. Normal operation.

1 Four bytes of proprietary header, ignored by CRC, exists on

the front of IEEE 802.3 frames.

Table 182. CRC/PAD Features of EMAC Configuration Register

ADPADN VLPADN PADEN CRCEN Result

0 0 0 0 No pad or CRC appended.

0 0 0 1 CRC appended.

0 0 1 0 Pad to 60 bytes if necessary; append CRC (min. size = 64).

0 0 1 1 Pad to 60 bytes if necessary; append CRC (min. size = 64).

0 1 0 0 No pad or CRC appended.

0 1 0 1 CRC appended.

0 1 1 0 Pad to 64 bytes if necessary, append CRC (min. size = 68).

0 1 1 1 Pad to 64 bytes if necessary, append CRC (min. size = 68).

1 0 0 0 No pad or CRC appended.

1 0 0 1 CRC appended.

1 0 1 0 If VLAN not detected, pad to 60, add CRC.

If VLAN detected, pad to 64 , ad d CRC .

1 0 1 1 If VLAN not detected, pad to 60, add CRC.

If VLAN detected, pad to 64 , ad d CRC .

1 1 0 0 No pad or CRC appended.

1 1 0 1 CRC appended.

1 1 1 0 If VLAN not detected, pad to 60, add CRC.

If VLAN detected, pad to 64 , ad d CRC .

1 1 1 1 If VLAN not detected, pad to 60, add CRC.

If VLAN detected, pad to 64 , ad d CRC .

Bit

Position Value Description

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EMAC Configuration Register 2

The EMAC Configuration Register 2 controls the behavior of the back pressure and late

collision data from the Descriptor table. See Table 183.

Table 183. EMAC Configuration Register 2 (EMAC_CFG2 = 0022h)

Bit 76543210

Reset 00110111

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit

Position Value Description

BPNB 0 Use normal back-off algorithm prior to transmitting packet. No

back pressure applied.

1 After incidentally causing a collision during back pressure, the

EMAC immediately (that is, no back-off) retransm its the packet

without back-off, which reduces the chance of further collisions

and ensures that the Transmit packets are sent.

NOBO 0 Enable exponential back-off.

1 The EMAC immediately retransmits following a collision rather

than use the binary exponential backfill algorithm, as specified

in the IEEE 802.3 specification.

[5:0]

LCOL 00h–3Fh Sets the number of bytes after Start Fram e Delimiter (SF D) for

which a late collision occurs. By default, all late collisions are

aborted.

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EMAC Configuration Register 3

The EMAC Configuration Register 3 controls preamble length and value, excessive defer-

ment, and the number of retransmission tries. See Table 184.

Table 184. EMAC Configuration Register 3 (EMAC_CFG3 = 0023h)

Bit 76543210

Reset 00001111

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit

Position Value Description

LONGP 0 The EMAC allows any preamble length as per the IEEE 802.3

specification.*

1 The EMAC only allows Receive packets that contain preamble

fields less than 12 bytes in length.*

PUREP 0 No preamble error checking is performed.

1 The EMAC verifies the content of the preamble to ensure that it

contains a value of 55h and that it is error-free. Packets

containing an error ed preamble are discarded.

XSDFR 0 The EMAC aborts when the excessive deferral limit is reached.

1 The EMAC defers to the carrier indefinitely as per the IEEE

802.3 specification.

BITMD 0 Disable 10 Mbps ENDEC mode.

1 Enable 10 Mbps ENDEC mode.

[3:0]

RETRY 0h–Fh A programmable field specifying the number of retransmission

attempts following a collision before aborting the packet due to

excessive collisions.

Note: IEEE 802.3 specifies a minimum of 56 bits of preamble. A maximum number of bits is not de-

fined. For details, see the IEEE 802.3 Specification, Section 7.2.3.2.

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EMAC Configuration Register 4

The EMAC Configuration Regis ter 4 co ntrols pause control frame behavior, back

pressure, and receive frame acceptance. Se e Table 185.

EMAC Station Address Register

The EMAC Station Address register is used for two functions. In the address recogni-

tion logic for Receive frames, EMAC_STAD_0–EMAC_STAD_5 are matched against

Table 185. EMAC Configuration Register 4 (EMAC_CFG4 = 0024h)

Bit 76543210

Reset 00000000

CPU Access R R/W R/W R/W R/W R/W R/W R/W

Note: R = Read Only; R/W = Read/Write.

Bit

Position Value Description

7 0 Reserved.

TPCF 0 Do not transmit a pause control frame.

1 Transmit pause control frame (FULL-DUPLEX mode). TPCF

continually sends pause control frames until negated.

THDF 0 Disable back pressure.

1 EMAC asserts back pressure on the link. Back pressure

causes preamble to be transmitted, raising carrier sense

(HALF-DUPLEX mode).

PARF 0 Only accept frames th at meet preset criteria (that is, address,

CRC, length, etc.).

1 All frames are received regardless of address, CRC, length,

etc.

RxFC 0 EMAC ignores received pause control frames.

1 EMAC acts upon pause control frames received.

TxFC 0 PAUSE control fr ames are not allowed to be transmitted.

1 PAUSE control frames are allowed to be transmitted.

TPAUSE 0 Do not force a pause condition.

1 Force a pause condition while this bit is asserted.

RxEN 0 EMAC receiver disabled.

1 EMAC receiver enabled.

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the sixth byte Destination Address (DA) field of the Receive frame. EMAC_STAD_0 is

matched against the first byte of the Receive frame, and EMAC_STAD_5 is matched

against the sixth byte of the Receive frame. Bit 0 of EMAC_STAD_0 (STAD[40]) is

matched against the first bit (Unicast/Multicast bit) of the first byte of the Receive

frame. This bit ordering is used to logically map the PE-MACMII station address as

illustrated below.

EMAC_STAD0[7:0] contains STAD[47:40]

....

EMAC_STAD5[7:0] contains STAD[7:0]

The second function of the EMAC Station Address registers is to provide the Source

Address (SA) field of Transmit Pause frames when these frames are transmitted by the

EMAC. EMAC_STAD_0 provides the first byte of the 6 byte SA field and

EMAC_STAD_5 provides the final byte of the SA field in order of transmission. The LSB

is the first byte sent out. The EMAC Station Address register is detailed in Table 186.

Table 186. EMAC Station Address Register (EMAC_STAD_0 = 0025h, EMAC_STAD_1 =

0026h, EMAC_STAD_2 = 0027h, EMAC_STAD_3 = 0028h, EMAC_STAD_4 = 0029h,

EMAC_STAD_5 = 002Ah)

Bit 76543210

EMAC_STAD_0 Reset 00000000

EMAC_STAD_1 Reset 00000000

EMAC_STAD_2 Reset 00000000

EMAC_STAD_3 Reset 00000000

EMAC_STAD_4 Reset 00000000

EMAC_STAD_5 Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit

Position Value Description

[7:0]

EMAC_STAD_x 00h–FFh This 48-bit station address comprises {EMAC_STAD_5,

EMAC_STAD_4, EMAC_STAD_3, EMAC_STAD_2,

EMAC_STAD_1, EMAC_STAD_0}.

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EMAC Transmit Pause Timer Value Register—Low and High Bytes

The Low and High bytes of the EMAC Transmit Pause Timer Value Register are inse rted

into outgoing pause control frames. See Table 187 and Table 188 on page 309.

EMAC Interpacket Gap

EMAC Interpacket Gap Overview

Interpacket Gap (IPG) is measured between the last nibble of the frame check sequence

(FCS) and the first nibble of the preamble of the next packet. Three registers are available

to fine tune the IPG, the EMAC_IPGT, EMAC_IPGR1, and the EMAC_IPGR2. The first

determine the non-back-to-ba ck IPG in two parts. Table 189 on page 310 shows the values

for the EMAC_IPGT and the corresponding IPGs for both FULL-DUPLEX and HALF-

DUPLEX modes.

Table 187. EMAC Transmit Pause Timer Value Register—Low Byte (EMAC_TPTV_L = 002Bh)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit

Position Value Description

[7:0]

EMAC_TPTV_L 00h–FFh The 16-bit value, {EMAC_TPTV_H, EMAC_TPTV_L}, is

inserted into outgoing pause cont rol frames as the pause

timer value upon asserting TPCF .

Table 188. EMAC Transmit Pause Timer Value Register—High Byte (EMAC_TPTV_H = 002Ch)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit

Position Value Description

[7:0]

EMAC_TPTV_H 00h–FFh The 16-bit value, {EMAC_TPTV_H, EMAC_TPTV_L}, is

inserted into outgoing pause co ntrol frames as the pause

timer value upon asserting TPCF.

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The equations for bac k-to -ba ck Transmit IPG are determined by the following:

FULL-DUPLEX Mode (3 clocks + IPGT clocks) * clock period = IPG

HALF-DUPLEX Mode (6 clocks + IPGT clocks) * clock period = IPG

Table 190 on page 311 lists the IPGR2 settings for the non-back-to-back packets.

Table 189. EMAC_IPGT Back-to-Back Settings for Full- and Half-Duplex Modes

MII, RMII/SMII, PMD

(100 Mbps) MII, RMII/SMII

(10 Mbps) ENDEC Mode

(10 Mbps)

Clock Period = 40 ns

IPGT[6:0] Clock Period = 400 ns

IPGT[6:0] Clock Period = 100 ns

IPGT[6:0]

Half

Duplex Full

Duplex Interpacket

Gap Half

Duplex Full

Duplex Interpacket

Gap Half

Duplex Full

Duplex Interpacket

Gap

0Dh 0.12 µs 00h 1.2 µs 10h 1.9 µs

0Bh 0.44 µs 08h 4.4 µs 18h 2.7 µs

0Ch 0.60 µs 0Ch 6.0 µs 20h 3.5 µs

10h 0.76 µs 10h 7.5 µs 40h 6.7 µs

*12h 15h 0.96 µs 12h 15h 9.6 µs 5Ah 5Dh 9.6 µs

20h 1.40 µs 20h 14.0 µs 20h 13.0 µs

Note: *The IEEE 802.3, 802.3(u) minimum values are shaded.

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A non-back-to-back Transmit IPG is determined by the following formula:

(6 clocks + IPGR2 clocks) * clock period = IPG

The difference in values between Table 189 on page 310 an d Table 190 is due to the

asynchronous nature of the Carrier Sense (CRS). The CRS must undergo a 2-clock

synchronization before the internal Tx state machine detects it. This synchronization

equates to a 6-clock intrinsic delay between packets instead of the 3-clock intrinsic delay

in the back-to-back packet mode. More information covering this topic is found in the

IEEE 802.3/4.2.3.2.1 Carrier Deference section.

EMAC Interpacket Gap Register

The EMAC Interpacket Gap (IPG) is a programmable field representing the IPG between

back-to-back packets. It is the IPG parameter used in FULL-DUPLEX and HALF-

DUPLEX modes between back-to-back packets. Set this field to the appropriate number

of IPG bytes. The default setting of 15h represents the minimum IPG of 0.96 µs (at 100

Mbps) or 9.6 μs (at 10 Mbps). See Table 191.

Table 190. EMAC_IPGT Non-Back-to-Back Settings for Full- /Half-Duplex Modes

MII, RMII/SMII, PMD

(100 Mbps) MII, RMII/SMII

(10 Mbps) ENDEC Mode

(10 Mbps)

Clock Period = 40 ns Clock Period = 400 ns Clock Period = 100 ns

IPGR2[6:0] Interpacket

Gap IPGR2[6:0] Interpacket

Gap

00h 0.24 µs 00h 2.4 µs 00h 0.6 µs

10h 0.88 µs 10h 8.8 µs 10h 2.2 µs

*12h 0.96 µs 12h 9.6 µs 20h 3.8 µs

20h 1.52 µs 20h 15.2 µs 40h 7.0 µs

40h 2.80 µs 40h 28.0 µs 5Ah 9.6 µs

7Fh 5.32 µs 7Fh 53.2 µs 7Fh 13.3 µs

Note: *The IEEE 802.3, 802.3(u) minimum values are shaded.

Table 191. EMAC Interpacket Gap Register (EMAC_IPGT = 002Dh)

Bit 76543210

Reset 00010101

CPU Access R R/W R/W R/W R/W R/W R/W R/W

Note: R = Read Only; R/W = Read/Write

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EMAC Non-Back-To-Back IPG Register—Part 1

Part 1 of the EMAC non-back-to-back IPG Register is a programmable field representing

the optional carrier sense window referenced in IEEE 802.3/4.2.3.2.1 Carr ier Deference. If

a carrier is detected during the timing of IPGR1, the EMAC defers to the carrier. If, how-

ever, the carrier becomes active after IPGR1, the EMAC continues timing for IPGR2 and

transmits, knowingly causing a collision. This collision acts to ensure fair access to the

medium. Its range of values is 00h to IPGR2. See Table 192. The default setting of 0Ch

represents the Carrier Sense Window Referencing depicted tin IEEE 802.3, Section

4.2.3.2.1.

EMAC Non-Back-To-Back IPG Register—Part 2

Part 2 of the EMAC non-back-to-back IPG Register is a programmable field representing

the non-back-to-back IPG. Its default is 12h, which represents the minimum IPG of 0.96

µs at 100 Mbps or 9.6 µs at 10 Mbps. See Table 193 on page 313.

Bit

Position Value Description

7 0 Reserved.

[6:0]

IPGT 00h–7Fh The number of bytes of IPG.

Table 192. EMAC Non-Back-To-Back IPG Register—Part 1 (EMAC_IPGR1 = 002Eh)

Bit 76543210

Reset 00001100

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write

Bit

Position Value Description

7 0 Reserved.

[6:0]

IPGR 1 00h–

7Fh This is a programm ab l e fie ld re pr es en tin g th e op tio na l car rie r

sense window referenced in IEEE 802.3/4.2.3.2.1 Carrier

Deference.

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EMAC Maximum Frame Length Register—Low and High Bytes

The 16-bit field resets to 0600h, which represents a maximum Receive frame of 1536

bytes. An untagged maximum size Ethernet frame (packet) is 1518 bytes. A tagged frame

adds four bytes for a total of 1522 bytes. If a shorter maximum length restriction is more

appropriate, program this field. See Table 194 and Table 195 on page 314.

The default value of 1536 bytes is lar ge enough to cover the largest Ethernet packet, which

contains 14 bytes of Ethernet header , 1500 bytes of MAC client data, plus 4 bytes of CRC

for a total of 1518 maximum bytes. This value is also large enough to cover VLAN frames

with prepended headers up to 18 bytes.

VLAN frames have a proprietary header prepended to the Ethernet packet. Setting the

DCRCC bit in EMAC_CFG1 will exclude the first 4 bytes—the proprietary header—from

the CRC calculation. For VLAN packets, the maximum frame length is 1522, 4 more than

for normal Ethernet packets due to the 4 byte prepended header. Normal packets feature a

12 byte header before the MAC client data. For more information about this topic, refer to

Figure 3-1 of the IEEE 802.3 specification.

If a proprietary header is allowed, this field must be adjusted accordingly. For example, if

12 byte headers are prepended to frames, MAXF must be set to 1524 bytes to allow the

maximum VLAN tagged frame plus the 12 byte header. The default value of 1536 is large

enough to cover the largest Ethernet packet: 14 bytes of Ethernet header, 1500 bytes of

MAC client data, plus 4 bytes of CRC for a total of 1518 bytes maximum. It is also large

enough to cover VLAN packets with prepended headers up to 18 bytes. The following

formulas illustrate:

Ethernet Packet— Maximum frame size = normal Ethernet packet – 14 (Ethernet header)

+ 1500 (MAC client data) + 4 (CRC) = 1518 bytes

Table 193. EMAC Non-Back-To-Back IPG Register—Part 2 (EMAC_IPGR2 = 002Fh)

Bit 76543210

Reset 00010010

CPU Access R R/W R/W R/W R/W R/W R/W R/W

Note: R = Read Only; R/W = Read/Write.

Bit

Position Value Description

7 0 Reserved.

[6:0]

IPGR2 00h–7Fh This bit range is a programmable field representing the non-

back-to-back interpacket gap.

Note:

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VLAN Packet— Maximum frame size = VLAN with 4 byte header – 4 (VLAN header) +

14 (Ethernet header) + 1500 MAC client data) + 4 (CRC) = 1522 bytes.

Table 194. EMAC Maximum Frame Length Register—Low Byte (EMAC_MAXF_L = 0030h

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit

Position Value Description

[7:0]

EMAC_MAXF_L 00h–FFh These bits represent the Low byte of the 2 byte MAXF

value, {EMAC_MAXF_H, EMAC_MAXF_L}. Bit 7 is bit 7 of

the 16-bit value. Bit 0 is bit 0 (lsb) of the 16-bit value.

Table 195. EMAC Maximum Frame Length Register—High Byte (EMAC_MAXF_H = 0031h)

Bit 76543210

Reset 00000110

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit

Position Value Description

[7:0]

EMAC_MAXF_H 00h–

FFh These bits represent the High byte of the 2 byte MAXF

value, {EMAC_MAXF_H, EMAC_MAXF_L}. Bit 7 is bit 15

(msb) of the 16-bit value. Bit 0 is bit 8 of the 16-bit value.

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EMAC Address Filter Register

The EMAC Address Filter Reg ister functions as a filter to control Promiscuous mode, and

multicast and broadcast messaging. See Table 196.

Table 196. EMAC Address Filter Register (EMAC_AFR = 0032h)

Bit 76543210

Reset 00000000

CPU Access RRRRR/WR/WR/WR/W

Note: R = Read Only; R/W = Read/Write.

Bit

Position Value Description

[7:4] 0h Reserved.

PROM 1 Enable Promiscuous Mode. Receive all incoming packets

regardless of station address. Disables station address

filtering.

0 Disable Promiscuous Mode.

MC 1 Accept any multicast message. A multicast packet is

determined by the first bit in the destination address. If the first

LSB is a 1, it is a group address and is globally or locally

administered depending on the 2nd bit. For more information,

see IEEE 802.3/3.2.3.

0 Do not accept multicast messages of any type.

QMC 1 Accept only qualified multicast (Q M C) me ss ag es as

determined by the hash table.

0 Do not accept QMC messages.

BC 1 Accept broadcast messages. Broadcast messages have the

destination address set to FFFFFFFFFFFFh.

0 Do not accept broadcast messages.

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EMAC Hash Table Register

The EMAC Hash Table Register represents the 8x8 hash table matrix. This table is used as

an option to select between different multicast addresses. If a multicast address is

received, the first 6 bits of the CRC are decoded and added to a table that points to a single

bit within the hash table matrix. If the selected bit = 1, the multicast packet is accepted. If

the bit = 0, the multicast packet is rejected. See Table 197.

Table 197. EMAC Hash Table Register (EMAC_HTBL_0 = 0033h, EMAC_HTBL_1 = 0034h,

EMAC_HTBL_2 = 0035h, EMAC_HTBL_3 = 0036h, EMAC_HTBL_4 = 0 037h, EMAC_HTBL_5

= 0038h, EMAC_HTBL_6 = 0039h, EMAC_HTBL_7 = 003Ah)

Bit 76543210

EMAC_HTBL_0 Reset 00000000

EMAC_HTBL_1 Reset 00000000

EMAC_HTBL_2 Reset 00000000

EMAC_HTBL_3 Reset 00000000

EMAC_HTBL_4 Reset 00000000

EMAC_HTBL_5 Reset 00000000

EMAC_HTBL_6 Reset 00000000

EMAC_HTBL_7 Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write

Bit

Position Value Description

[7:0]

EMAC_HTBL_x 00h–

FFh This field is the hash table. The 64 bit hash table is

{EMAC_HTBL_7, EMAC_HTBL_6, EMAC_HTBL_5,

EMAC_HTBL_4, EMAC_HTBL_3, EMAC_HTBL_2,

EMAC_HTBL_1, EMAC_HTBL_0}.

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EMAC MII Management Register

The EMAC MII Management Reg ist er is used to control the external PHY attached to the

MII. See Table 198.

Table 198. EMAC MII Management Register (EMAC_MIIMGT = 003Bh)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit

Position Value Description

LCTLD 1 Rising edge causes the CTLD control data to be transmitted to

external PHY if MII is not busy. This bit is self clearing.

0 No operation.

RSTAT 1 Rising edge causes status to be read from external PHY via

PRSD[15:0] bus if MII is not busy. This bit is self clearing.

0 No operation.

SCINC 1 Scan PHY address increments upon SCAN cycle. The SCAN

bit must also be set for the PHY addr ess to increment after

each scan. The scanning starts at the EMAC_FIAD and

increments up to 1Fh. It then returns to the EMAC_FIAD

address.

0 Normal operation.

SCAN 1 Perform continuous Read cycles via MII management. Wh ile in

SCAN mode, the EMAC_ISTAT[MGTDONE] bit is set when the

current PHY Read has completed. At this time, the

EMAC_PRSD register holds the Read data and th e

EMAC_MIISTAT[4:0] holds the address of the PHY for which

the EMAC_PRSD data pertains.

0 Normal operation.

SPRE 1 Suppress the MDO preamble. MDO is management data

output, an internal signal driven from the MDIO pin.

0 Normal pr eamble.

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EMAC PHY Configuration Data Register—Low and High Byte

The Low and High bytes of the EMAC PHY Configuration Data Register represents the

configuration data written to the external PHY. The EMAC_CTLD_H and

EMAC_CTLD_L registers form a 16-bit register. These registers are loaded with data to

be sent via the MDIO pin to the PHY. The PHY is selected by setting the EMAC_FIAD.

The register inside the PHY is selected by setting EMAC_RGAD. See Table 199 and

Table 200 on page 319.

[2:0]

CLKS Programmable divisor that produces MDC from SCLK. MDC is the

management data clock pin, which clocks MDIO data to and from the

PHY. its frequency is SCLK divided by the MDC clock divider.

000 MDC = SCLK ÷ 4.

001 MDC = SCLK ÷ 4.

010 MDC = SCLK ÷ 6.

011 MDC = SCLK ÷ 8.

100 MDC = SCLK ÷ 10.

101 MDC = SCLK ÷ 14.

110 MDC = SCLK ÷ 20.

111 MDC = SCLK ÷ 28.

Table 199. EMAC PHY Configuration Data Register—Low Byte (EMAC_CTLD_L = 003Ch)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit

Position Value Description

[7:0]

EMAC_CTLD_L 00h–

FFh These bits represent the Low byte of the 2 byte PHY

configuration data value, {EMAC_CTLD_H,

EMAC_CTLD_L}. Bit 7 is bit 7 of the 16 bit value. Bit 0 is bit

0 (lsb) of the 16 bit value.

Bit

Position Value Description

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EMAC PHY Address Register

The EMAC PHY Address Register allows access to the external PHY registers. See

Table 201.

Table 200. EMAC PHY Configuration Data Register—High Byte (EMAC_CTLD_H = 003Dh)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit

Position Value Description

[7:0]

EMAC_CTLD_H 00h–

FFh These bits represent the High byte of the 2 byte PHY

configuration data value, {EMAC_CTLD_H,

EMAC_CTLD_L}. Bit 7 is bit 15 (msb) of the 16 bit value. Bit

0 is bit 8 of the 16 bit value.

Table 201. EMAC PHY Address Register (EMAC_RGAD = 003Eh)

Bit 76543210

Reset 00000000

CPU Access R R R R/W R/W R/W R/W R/W

Note: R = Read Only; R/W = Read/Write.

Bit

Position Value Description

[7:5] 000 Reserved.

[4:0]

RGAD 00h–

1Fh Programmable 5 bit value which selects address within the

selected external PHY.

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EMAC PHY Unit Select Address Register

The EMAC PHY Unit Select Address Register allows the selection of multiple connected

external PHY devices. See Table 202.

EMAC Transmit Polling Timer Register

This register sets the T ransmit Polling Peri od in increments of TPTMR = SYSCLK ÷ 256.

Whenever this register is written, the status of the Transmit Buffer Descriptor is checked

to determine if the EMAC owns the Transmit buffer. It then rechecks this status every

TPTMR (calculated by TPTMR x EMAC_PTMR[7:0]). The Transmit Polling Timer is

disabled if this register is set to 00h (which also disables the transmitting of packets). If a

transmission is in progress when EMAC_PTMR is set to 00h, the transmission will com-

plete. See Table 203.

Table 202. EMAC PHY Unit Select Address Register (EMAC_FIAD = 003Fh)

Bit 76543210

Reset 00000000

CPU Access R R R R/W R/W R/W R/W R/W

Note: R = Read Only; R/W = Read/Write.

Bit

Position Value Description

[7:5] 000 Reserved.

[4:0]

FIAD 00h–1Fh Programmable 5-bit value that selects an external PHY.

Table 203. EMAC Transmit Polling Timer Register (EMAC_PTMR = 0040h)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit

Position Value Description

[7:0]

EMAC_PTMR 00h–FFh The Transmit polling period.

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EMAC Reset Control Register

The bit values in the EMAC Reset Control Register are not self-clearing bits. You are

responsible for controlling their state. See Table 204.

Table 204. EMAC Reset Control Register (EMAC_RST = 0041h)

Bit 76543210

Reset 00100000

CPU Access R R R/W R/W R/W R/W R/W R/W

Note: R = Read Only; R/W = Read/Write.

Bit

Position Value Description

[7:6] 00 Reserved

SRST 1 Software Reset Active—resets Receive, Transmit, EMAC

Control and EMAC MII_MGT functio ns

0 Normal op eration

HRTFN 1 Reset Transmit function

0 Normal op eration

HRRFN 1 Reset Receive funct i on

0 Normal op eration

HRTMC 1 Reset EMAC Transmit Control function

0 Normal op eration

HRRMC 1 Reset EMAC Receive Control function

0 Normal op eration

HRMGT 1 Reset EMAC Manage m ent fu nc tion

0 Normal op eration

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EMAC Transmit Lower Boundary Pointer Register—Low and High Bytes

The EMAC Transmit Lower Boundary Pointer is set to the start of the Transmit buffer in

EMAC shared memory. See Table 205 and Table 206.

Table 205. EMAC Transmit Lower Boundary Pointer Registe r —Low Byte (EMAC_TLBP_L = 0042h)

Bit 76543210

Reset 00000000

CPU Access R/WR/WR/WRRRRR

Note: R/W = Read/Write.

Bit

Position Value Description

[7:0]

EMAC_TLBP_L 00h–

FFh These bits represent the Low byte of the 2 byte Transmit

Lower Boundary Pointer value, {EMAC_TLBP_H,

EMAC_TLBP_L}. Bit 7 is bit 7 of the 16 bit value. Bit 0 is bit 0

(lsb) of the 16 bit value.

Table 206. EMAC Transmit Lower Boundary Pointer Register—High Byte (EMAC_TLBP_H

= 0043h)*

Bit 76543210

Reset 11000000

CPU Access R R R R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit

Position Value Description

[7:0]

EMAC_TLBP_H 00h–

FFh These bits represent the High byte of the 2 byte Transmit

Lower Boundary Pointer value, {EMAC_TLBP_H,

EMAC_TLBP_L}. Bit 7 is bit 15 (msb) of the 16 bit value. Bits

7:5 default to 000 on reset; bit 0 is bit 8 of the 16- bit value.

Note: *Bits 7:5 are not used by the EMAC; these bits re turn 000.

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EMAC Boundary Pointer Register—Low and High Bytes

The Boundary Pointer is set to the start of the Receive buffer (end of Transmit buffer +1)

in EMAC shared memory. This pointer is 24 bits and determined by {RAM_ADDR_U,

EMAC_BP_H, EMAC_BP_L}. The upper 3 bits of the EMAC_BP_H register are hard-

wired inside the eZ80F91 device to locate the base of EMAC shared memory. The last 5

bits of the EMAC_BP_L register value are hard-wired to keep the addressing aligned to

a 32 byte boundary. See Table 207 and Table 208.

EMAC Boundary Pointer Register—Upper Byte

The EMAC Boundary Pointer Register maps directly to the RAM_ADDR_U register

within the eZ80F91 device. This register value is Read Only. See Table 209 on page 324.

Table 207. EMAC Boundary Pointer Register—Low Byte (EMAC_BP_L = 0044h)

Bit 76543210

Reset 00000000

CPU Access R/WR/WR/WRRRRR

Note: R = Read Only, R/W = Read/Write.

Bit

Position Value Description

[7:0]

EMAC_BP_L 00h–FFh These bits represent the Low byte of the 3 byte EMAC

Boundary Pointer value, {EMAC_BP_U, EMAC_BP_H,

EMAC_BP_L}. Bit 7 is bit 7 of the 24 bit value. Bit 0 is bit 0 of

the 24 bit value.

Table 208. EMAC Boundary Pointer Register—High Byte (EMAC_BP_H = 0045h)

Bit 15:13 12:8

Reset 11000000

CPU Access R R R R/W R/W R/W R/W R/W

Note: R = Read Only, R/W = Read/Write.

Bit

Position Value Description

[7:0]

EMAC_BP_H 00h–FFh These bits represent the High byte of the 3 byte EMAC

Boundary Pointer value, {EMAC_BP_U, EMAC_BP_H,

EMAC_BP_L}. Bit 7 is bit 15 of the 24 bit value. Bit 0 is bit 8 of

the 24 bit value.

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EMAC Receive High Boundary Pointer Register—Low and High Bytes

The Receive High Boun dary Pointer Register must be set to the end of the Receive buffer

+1 in EMAC shared memory. This RHBP uses the same RAM_ADDR_U as the

EMAC_BP_U pointer above. See Table 210 and Table 211 on page 325.

Table 209. EMAC Boundary Pointer Register—Upper Byte (EMAC_BP_U = 0046h)

Bit 76543210

Reset 11111111

CPU Access RRRRRRRR

Note: R = Read Only.

Bit

Position Value Description

[7:0]

EMAC_BP_U 00h–FFh These bits represent the upper byte of the 3 byte EMAC

Boundary Pointer value, {EMAC_BP_U, EMAC_BP_H,

EMAC_BP_L}. Bit 7 is bit 23 of the 24 bit value. Bit 0 is b it 16 of

the 24 bit value.

Table 210. EMAC Receive High Boundary Pointer Register—Low Byte (EMAC_RHBP_L = 0047h)

Bit 76543210

Reset 00000000

CPU Access R/WR/WR/WRRRRR

Note: R = Read Only, R/W = Read/Write

Bit

Position Value Description

[7:0]

EMAC_RHBP_L 00h–E0h These bits represent the Low byte of the 2 byte EMAC

Receive High Boundary Pointer value, {EMA C_RHBP_H,

EMAC_RHBP_L}. Bit 7 is bit 7 of the 16 bit value. Bit 0 is bit

0 (lsb) of the 16 bit value.

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EMAC Receive Read Pointer Register—Low and High Bytes

The Receive Read Pointer Register must be initialized to the EMAC_BP value (start of the

Receive buffer). This register points to where the next Receive packet is read from. The

EMAC_BP[12:5] is loaded into this register whenever the EMAC_RST [(HRRFN) is set

to 1. The RxDMA block uses the Emac_Rrp[12:5] to compare to EmacRwp[12:5] for

determining how many buffers remain. The result equates to the EmacBlksLeft register.

See Table 212 and Table 213 on page 326.

Table 211. EMAC Receive High Boundary Pointer Register—High Byte (EMAC_RHBP_H = 0048h)

Bit 76543210

Reset 11000000

CPU Access R R R R/W R/W R/W R/W R/W

Note: R = Read Only, R/W = Read/Write

Bit

Position Value Description

[7:0]

EMAC_RHBP_H 00h–FFh These bits represent the High byte of the 2 byte EMAC

Receive High Boundary Pointer value, {EMA C_RHBP_H,

EMAC_RHBP_L}. Bit 7 is bit 15 (msb) of the 16 bit value. Bit

0 is bit 8 of the 16 bit value.

Note: *Bits 7:5 are not used by the EMAC; these bits return 000 upon reset.

Table 212. EMAC Receive Read Pointer Register—Low Byte (EMAC_RRP_L = 0049h)

Bit 76543210

Reset 00000000

CPU Access R/WR/WR/WRRRRR

Note: R = Read Only, R/W = Read/Write

Bit

Position Value Description

[7:0]

EMAC_RRP_L 00h–FFh These bits represent the Low byte of the 2 byte EMAC

Receive Read Pointer value, {EMAC_RRP_H,

EMAC_RRP_L}. Bit 7 is bit 7 of the 16 bit value. Bit 0 is bit 0

(lsb) of the 16 bit value.

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EMAC Buffer Size Register

The lower six bits of this register set the level at which the EMAC either transmits a pause

control frame or jams the Ethernet bus, depending on the mode selec te d. When each of

these bits contain a zero, this feature is disabled.

In FULL-DUPLEX mode, a Pause Control Frame is transmitted as a One-shot operation.

The software must free up a number of Rx buffe rs so that the number of buffers remaining,

EmacBlksLeft, is greater than TCPF_LEV.

In HALF-DUPLEX mode, the EMAC jams the Ethernet by sending a continuous stream

of hexadecimal 5s (5fh). When the software frees up the Rx buffers and the number of

buffers remaining, EmacBlksLeft, is greater than TCPF_LEV, the EMAC stops jamming.

Table 213. EMAC Receive Read Pointer Register—High Byte (EMAC_RRP_H = 004Ah)

Bit 76543210

Reset 00000000

CPU Access R R R R/W R/W R/W R/W R/W

Note: R = Read Only, R/W = Read/Write

Bit

Position Value Description

[7:0]

EMAC_RRP_H 00h–FFh These bits represent the High byte of the 2-byte EMAC

Receive Read Pointer value, {EMAC_RRP_H,

EMAC_RRP_L}. Bit 7 is bit 15 (msb) of the 16-bit value. Bits

7:5 default to 000 on reset; bit 0 is bit 8 of the 16-bit value.

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EMAC Interrupt Enable Register

Enabling the Receive Overrun interrupt allows software to detect an overrun condition

as soon as it occurs. If this interrupt is not set, then an overrun cannot be detected until

the software processes the Receive packet with the overrun and chec ks the Receive sta-

tus in the Rx descriptor table. Because the receiver is disabled by an overrun error until

the Rx_OVR bit is cleared in the EMAC_ISTAT register, this packet is the final packet

in the Receive buffer. To re-enable the receiver before all of the Receive packets are

processed and the Receive buffer is empty, software enables this interrupt to detect the

overrun condition early. As it processes the Receive packets, it re-enables the receiver

when the number of free buffers is greater than the number of minimum buffers. See

Table 215 on page 328.

Table 214. EMAC Buffer Size Register (EMAC_BUFSZ = 004Bh)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit

Position Value Description

[7:6]

BUFSZ 00 Set EMAC Rx/Tx buffer size to 256 bytes.

01 Set EMAC Rx/Tx buffer size to 128 bytes.

10 Set EMAC Rx/Tx buffer size to 64 bytes.

11 Set EMAC Rx/Tx buffer size to 32 bytes.

[5:0]

TPCF_LEV 00h–3Fh Transmit Pause Control Frame level. 00h disabl es the

hardware generated transmit pause control frame.

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Table 215. EMAC Interrupt Enable Register (EMAC_IEN = 004Ch)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit

Position Value Description

TxFSMERR 1 Enable Transmit Sta te Machine Error Interrupt (system

interrupt).

0 Disable Transmit State Machine Error Interrupt (system

interrupt).

MGTDONE 1 Enable MII Management. Done Interrupt (system Interrupt).

0 Disable MII Management. Done Interrupt (system Interrupt).

Rx_CF 1 Enable Receive Control Frame Interrupt (Receive interrupt).

0 Disable Receive Control Frame Interrupt (Receive interrupt).

Rx_PCF 1 Enable Receive Pause Control Frame interrupt (Receive

interrupt).

0 Disable Receive Pause Control Frame interrupt (Receive

interrupt).

Rx_DONE 1 Enable Receive Done interrupt (Receive interrupt).

0 Disable Receive Done interrupt (Recei ve interrupt).

Rx_OVR 1 Enable Receive Overrun interrupt (System interrupt) .

0 Disable Receive Overrun interrupt (System interrupt).

Tx_CF 1 Enable Transmit Control Frame Interrupt (Tran s m it interrupt).

0 Disable Transmit Control Frame Interrupt (Transmit interrupt).

Tx_DONE 1 Enable Tr ansmit Done interrupt (Transmit interrupt).

0 Disable Transmit Done Interrupt (Transmit interrupt).

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EMAC Interrupt Status Register

When a Receive overrun occurs, all incoming packets are ignored until the

Rx_OVR_STAT status bit is cleared by software. Consequently, software controls when

the receiver is re-en abled after an overrun. Enable the Rx_OVR interrupt to det ect overrun

conditions when they occur. Clear this condition when the Rx buffers are freed to avoid

additional overrun errors. See Table 216.

Status bits are not self-clearing. Each status bit is cleared by writing a 1 into the selected

bit.

Table 216. EMAC Interrupt Status Register (EMAC_ISTAT = 004Dh)

Bit 76543210

Reset 00000000

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit

Position Value Description

TxFSMERR_STAT 1 An internal error occurs in the EMAC Transmit path. The

Transmit path must be reset to reset this error condition.

0 Normal operation—no Transmit state machine errors.

MGTDONE_STAT 1 The MII Management interrupt has completed a Read

(RSTAT or SCAN) or a Write (LDCTLD) access to the

PHY.

0 T he MII Management interrupt does not occur.

Rx_CF_STAT 1 Receive Control Frame interrupt (Receive Interrupt)

occurs.

0 Receive Control Frame interrupt does not occur.

Rx_PCF_STAT 1 Receive Pause Control Frame interrupt (Receive

Interrupt) occurs.

0 Disable Receive Pause Control Frame interrupt (Receive

Interrupt) doe s not occur.

Rx_DONE_STAT 1 Receive Done interrupt (Receive Interrupt) occurs.

0 Disable Receive Done interrupt (Receive Interrupt) does

not occur.

Rx_OVR_STAT 1 Receive Overrun interrupt (System Interrupt) occurs.

0 Receive Overrun interrupt (System Interrupt) does not

occur.

Note:

PS027001-0707 Ethernet Media Access Controller

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Product Specification

330

EMAC PHY Read Status Data Register—Low and High Bytes

The PHY MII Management Data Register is where the data Read from the PHY is stored.

See Table 217 and Table 218 on page 331.

Tx_CF_STAT 1 Transmit Control Frame Interrupt (Transmit Interrupt)

occurs.

0 Transmit Control Frame Interrupt (Transmit Interr upt)

does not occur.

Tx_DONE_STAT 1 Transmit Done interrupt (Transmit Interrupt) occurs.

0 Transmit Done interrupt (Transmit Interrupt) does not

occur.

Table 217. EMAC PHY Read Status Data Register—Low Byte (EMAC_PRSD_L = 004Eh)

Bit 76543210

Reset 00000000

CPU Access RRRRRRRR

Note: R = Read Only.

Bit

Position Value Description

[7:0]

EMAC_PRSD_L 00h–FFh These bits represent the Low byte of the 2 byte EMAC PHY

Read Status Data value, {EMAC_PRSD_H,

EMAC_PRSD_L}. Bit 7 is bit 7 of the 16 bit value. Bit 0 is bit

0 (lsb) of the 16 bit value.

Bit

Position Value Description

PS027001-0707 Ethernet Media Access Controller

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Product Specification

331

EMAC MII Status Register

The EMAC MII Status Register is used to determine the current state of the external PHY

device. See Table 219.

Table 218. EMAC PHY Read Status Data Register—High Byte (EMAC_PRSD_H = 004Fh)

Bit 76543210

Reset 00000000

CPU Access RRRRRRRR

Note: R = Read Only.

Bit

Position Value Description

[7:0]

EMAC_PRSD_H 00h–FFh These bits represent the High byte of the 2-byte EMAC

PHY Read Status Data value, {EMAC_PRSD_H,

EMAC_PRSD_L}. Bit 7 is bit 15 (msb) of the 16 -bit value.

Bit 0 is bit 8 of the 16-bit value.

Table 219. EMAC MII Status Register (EMAC_MIISTAT = 0050h)

Bit 76543210

Reset 00000000

CPU Access RRRRRRRR

Note: R = Read Only.

Bit

Position Value Description

BUSY 1 MII management operation in progress—Busy. This status bit

goes busy whenever the LCTLD (PHY Write) or the RSTAT

(PHY Read) is set in the EMAC_MIIMGT register. It is

negated when the Write or Read operation to the PHY has

completed. In SCAN mode, the BUSY will be asserted until

the SCAN is disabled. Use the EmacIStat[MGTDONE]

interrupt status bit to determine when the data is valid.

0 Not Busy.

MIILF 1 Local copy of PHY Link fail bit.

0PHY Link OK.

PS027001-0707 Ethernet Media Access Controller

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Product Specification

332

EMAC Receive Write Pointer Register—Low Byte

The Read Only Receive-W rite-Pointer register reports the current RxDMA Receive Write

pointer. This pointer gets initialized to EmacTLBP whenever Emac_RST bits SRST or

HRRTN are set. Because the size of the packet is limited to a minimum of 32 bytes, the

last five bits are always zero. See Table 220 and Table 221 on page 333.

NVALID 1 MII Scan result is not valid Emac_PRSD is invalid

0 Emac_PRSD is valid.

[4:0]

RDADR 00h–1Fh Denotes PHY addressed in current scan cycle.

Table 220. EMAC Receive Write Pointer Register—Low Byte (EMAC_RWP_L = 0051h)

Bit 76543210

Reset 00000000

CPU Access RRRRRRRR

Note: R = Read Only.

Bit

Position Value Description

[7:0]

EMAC_RWP_L 00h–

E0h These bits represent the Low byte of the 2 byte EMAC

RxDMA Receive Write Pointer value, {EMAC_RWP_H,

EMAC_RWP_L}. Bit 7 is bit 7 of the 16 bit value. Bit 0 is bit 0

(lsb) of the 16 bit value.

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Product Specification

333

EMAC Receive Write Pointer Register—High Byte

Because of the size of the EMAC’s 8 KB SRAM, the upper three bits of the EMAC

Receive Write Pointer Register are always zero.

EMAC Transmit Read Pointer Register—Low Byte

The Low byte of the Transmit Read Pointer register reports the current TxDMA Transmit

Read pointer.This pointer is initialized to EmacTLBP whenever Emac_RST bits SRST or

HRRTN are set. Because the size of the packet is limited to a minimum of 32 bytes, the

last five bits are always zero. See Table 222.

Table 221. EMAC Receive Write Pointer Register—High Byte (EMAC_RWP_H = 0052h)

Bit 76543210

Reset 00000000

CPU Access RRRRRRRR

Note: R = Read Only.

Bit

Position Value Description

[7:0]

EMAC_RWP_H 00h–1Fh These bits represent the High byte of the 2 byte EMAC

RxDMA Receive Write Pointer value, {EMAC_RWP_H,

EMAC_RWP_L}. Bit 7 is bit 15 ( m sb) o f the 16 bit va lue. Bit

0 is bit 8 of the 16 bit value.

Table 222. EMAC Transmit Read Pointer Register—Low Byte (EMAC_TRP_L = 0053h)

Bit 76543210

Reset 00000000

CPU Access RRRRRRRR

Note: R = Read Only.

Bit

Position Value Description

[7:0]

EMAC_TRP_L 00h–E0h These bits represent the Low byte of the 2 byte EMAC

TxDMA Transmit Read Pointer value, {EMAC_TRP_H,

EMAC_TRP_L}. Bit 7 is bit 7 of the 16 bit value. Bit 0 is bit 0

(lsb) of the 16 bit value.

PS027001-0707 Ethernet Media Access Controller

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Product Specification

334

EMAC Transmit Read Pointer Register—High Byte

Because of the size of the EMAC’s 8 KB SRAM, the upper three bits of the EMAC T rans-

mit Read Pointer Register are always zero. See Table 223.

EMAC Receive Blocks Left Register—Low and High Bytes

This register reports the number of buffers left in the Receive EMAC shared memory. The

hardware uses this information along with the block-level set in the EMAC_BUFSZ regis-

ter to determine when to transmit a pause control frame. Software uses this information to

determine when it must request that a pause control frame be transmitted (by setting bit 6

of the EMAC_CFG4 register). For the BlksLeft logic to operate properly, the Receive

buffer must contain at least one more packet buffer than the number of packet buffers

required for the largest packet. That is, one packet cannot fill the entire Receive buffer.

Otherwise, the BlksLeft will be in error. See Table 224 and Table 225 on page 335.

Table 223. EMAC Transmit Read Pointer Register—High Byte (EMAC_TRP_H = 0054h)

Bit 76543210

Reset 00000000

CPU Access RO RO RO RO RO RO RO RO

Note: R/W = Read/Write.

Bit

Position Value Description

[7:0]

EMAC_TRP_H 00h–1Fh These bits represent the High byte of the 2 byte EMAC

TxDMA Transmit Read Pointer value, {EMAC_TRP_H,

EMAC_TRP_L}. Bit 7 is bit 15 (msb) of the 16 bit value. Bit

0 is bit 8 of the 16 bit value.

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Table 224. EMAC Receive Blocks Left Register—Low Byte (EMAC_BLKSLFT_L = 0055h)

Bit 76543210

Reset 00000000

CPU Access RRRRRRRR

Note: R = Read Only.

Bit

Position Value Description

[7:0]

EMAC_BLKSLFT_L 00h–FFh These bits represent the Low byte of the 2 byte EMAC

Receive Blocks Left value, {EMAC_BLKSLFT_H,

EMAC_BLKSLFT_L}. Bit 7 is bit 7 of the 16 bit value. Bit

0 is bit 0 (lsb) of the 16 bit value.

Table 225. EMAC Receive Blocks Left Register—High Byte (EMAC_ BLKSLFT_H = 0056h)

Bit 76543210

Reset 00000000

CPU Access RRRRRRRR

Note: R = Read Only.

Bit

Position Value Description

[7:0]

EMAC_BLKSLFT_H 00h–FFh These bits represent the High byte of the 2 byte EMAC

Receive Blocks Left value, {EMAC_BLKSLFT_H,

EMAC_BLKSLFT_L}. Bit 7 is bit 15 (msb) of the 16 bit

value. Bit 0 is bit 8 of the 16 bit value.

PS027001-0707 Ethernet Media Access Controller

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Product Specification

336

EMAC FIFO Data Register—Low and High Bytes

The FIFO Read/Write Test Access Data Register allows writing and reading the FIFO

selected by the EMAC_TEST TxRx_SEL bit when the EMAC_TEST register

TEST_FIFO bit is set. See Table 226 and Table 227.

Table 226. EMAC FIFO Data Register—Low Byte (EMAC_FDATA_L = 0057h)

Bit 76543210

Reset XXXXXXXX

CPU Access R/W R/W R/W R/W R/W R/W R/W R/W

Note: R/W = Read/Write.

Bit

Position Value Description

[7:0]

EMAC_FDATA_L 00h–FFh These bits represent the Low byte of the 10 bit EMAC

FIFO data value, {EMAC_FDATA_H[1:0],

EMAC_FDATA_L}. Bit 7 is bit 7 of the 16 bit value. Bit 0 is

bit 0 (lsb) of the 10 bit value.

Table 227. EMAC FIFO Data Register—High Byte (EMAC_FDATA_H = 0058h)

Bit 76543210

Reset 000000XX

CPU Access RRRRRRR/WR/W

Note: R = Read Only; R/W = Read/Write.

Bit

Position Value Description

[7:2] 00h Reserved.

[1:0]

EMAC_FDATA_H 0h–3h These bits represent the upper two bits of the 10 bit EMAC

FIFO data value, {EMAC_FDATA_H[1:0],

EMAC_FDATA_L}. Bit 1 is bit 9 (msb) of the 16 bit value.

Bit 0 is bit 8 of the 10 bit value.

PS027001-0707 Ethernet Media Access Controller

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Product Specification

337

EMAC FIFO Flags Register

The FIFO Flags value is set in the EMAC hardware to half full, or 16 bytes. See Table 228.

Table 228. EMAC FIFO Flags Register (EMAC_FFLAGS = 0059h)

Bit 76543210

Reset 00110011

CPU Access RRRRRRRR

Note: R = Read Only.

Bit

Position Value Description

TFF 1 Transmit FIFO full

0 Transmit FIFO not full

60Reserved

TFAE 1 Transmit FIFO almost empty

0 Transmit FIFO not almost empty

TFE 1 Transmit FIFO empty

0 Transmit FIFO not em pty

RFF 1 Receive FIFO full

0 Receive FIFO not full

RFAF 1 Receive FIFO almost full

0 Receive FIFO not almost full

RFAE 1 Receive FIFO almost empty

0 Receive FIFO not almost empty

RFE 1 Receive FIFO empty

0 Receive FIFO not empty

PS027001-0707 Ethernet Media Access Controller

eZ80F91 ASSP

Product Specification

338

PS027001-0707 On-Chip Oscillators

eZ80F91 ASSP

Product Specification

339

On-Chip Oscillators

The eZ80F91 features two on-chi p oscillators for use with an external crys tal. The primary

oscillator generates the system clock for the internal CPU and the majority of the on-chip

peripherals. Alternatively , the XIN input pin also accepts a CMOS-level clock input signal.

If an external clock generator is used, the XOUT pin must be left unconnected. The second -

ary oscillator drives a 32 kHz crystal to generate the time-base for the Real-Time Clock.

Primary Crystal Oscillator Operation

Figure 63 on page 340 illustrates a recommended configuration for connection with an

external 50 MHz, 3rd-overtone, parallel-resonant crystal. Recommended crystal specifica-

tions are provided in Table 229 on page 340 and Table 230 on page 341. Printed circuit

board layout must add not more than 4 pF of stray capacitance to either the XIN or XOUT

pins. If oscillation does not occur, try removing C1 for testing and decreasing the value of

C2 by the estimated stray capacitanc e to decrease loading.

PS027001-0707 On-Chip Oscillators

eZ80F91 ASSP

Product Specification

340

Figure 63. Recommended Crystal Oscillator Configuration—50 MHz Operation

Table 229. Recommended Crystal Oscillator Specifications—1 MHz Operation

Parameter Frequency

Dependent Value Units Comments

Frequency 1 MHz

Resonance Parallel

Mode Fundamental

Series Resistance (RS) 750 Ohms Maximum

Load Capacitance (CL)13 pF Maximum

C=10-15pF L=3.3H (± 10%)

IN XOUT

C = .01-0.1 F

R = 100 Kȍ

C=5pF

50 MHz Crystal

(Third Overtone)

On-Chip Oscillator

(this value is not critical)

PS027001-0707 On-Chip Oscillators

eZ80F91 ASSP

Product Specification

341

32 kHz Real-Time Clock Crystal Oscillator Operation

Figure 64 on page 342 illustrates a recommended configuration for connecting the Real-

Time Clock oscillator with an external 32 kHz, fundamental mode, parallel-resonant crys-

tal. The recommended crystal specifications are provided in Table 231on page 342. A

printed circuit board layout must not add more than 4 pF of stray capacitance to either the

RTC_XIN or RTC_XOUT pins. If oscillation does not occur, reduce the values of capaci-

tors C1 and C2 to decrease loading.

An on-chip MOS resistor sets the crystal drive current limit. This configuration does not

require an external bias resistor across the crystal. An on-chip MOS resistor provides the

biasing.

Shunt Capacitance (C0) 7 pF Maximum

Drive Level 1 mW Maximum

Table 230. Recommended Crystal Oscillator Specifications—10 MHz Operation

Parameter Frequency

Dependent Value Units Comments

Frequency 10 MHz

Resonance Parallel

Mode Fundamental

Series Resistance (RS) 35 Ohms Maximum

Load Capacitance (CL)30 pF Maximum

Shunt Capacitance (C0) 7 pF Maximum

Drive Level 1 mW Maximum

Table 229. Recommended Crystal Oscillator Specifications—1 MHz Operation

(Continued)

Parameter Frequency

Dependent Value Units Comments

PS027001-0707 On-Chip Oscillators

eZ80F91 ASSP

Product Specification

342

Figure 64. Recommended Crystal Oscillator Configuration—32 kHz Operation

Table 231. Recommended Crystal Oscillator Specifications—32 kHz Operation

Parameter Value Units Comments

Frequency 32 kHz 32768 Hz

Resonance Parallel

Mode Fundamental

Series Resistance (RS)50 kΩMaximum

Load Capacitance (CL) 12.5 pF Maximum

Shunt Capacitance (C0) 3 pF Maximum

Drive Level 1 µW Maximum

RTC_X

C = 10 pF

IN RTC_XOUT

C = 10 pF

132 kHz Crystal

(Fundamental Mode)

On-Chip Oscillator

PS027001-0707 Electrical Characteristics

eZ80F91 ASSP

Product Specification

343

Electrical Characteristics

Absolute Maximum Ratings

Stresses greater than those listed in Table 232 causes permanent damage to the device.

These ratings are stress ratings only . Operation of the device at any condition outside those

indicated in the operational sections of these specifications is not implied. Exposure to

absolute maximum rating conditions for extended periods affects device reliability. For

improved reliability, unused inputs must be tied to one of the supply voltages (VDD or

VSS).

Table 232. Absolute Maximum Ratings

Parameter Minimum Maximum Units Notes

Ambient temperature under bias (ºC) –40 +105 ºC 1

Storage temperature (ºC) –65 +1 50 C

Voltage on any pin with respect to VSS –0.3 +5.5 V 2

Voltage on VDD pin with respect to VSS –0.3 +3.6 V

Total power dissipation 830 mW

Maximum current out of VSS 230 mA

Maximum current into VDD 230 mA

Maximum current on input and/or inactive output pin –15 +15 µA

Maximum output current from active output pin

(except PORT A pins) –8 +8 mA

Maximum PORT A output SOURCE current from active

output pin +8 mA

Maximum PORT A output SINK current from active output

pin +10 mA

Flash memory Writes to Same Single Address — 2 — 3

Flash Memory Data Retention 100 — Years

Flash Memory Write/Erase Endurance 10,000 — Cycles 4

Notes

1. Operating temperature is specified in DC Characteristics.

2. This voltage applies to all pins except XIN and XOUT.

3. Before next erase operation.

4. Write cycles.

PS027001-0707 Electrical Characteristics

eZ80F91 ASSP

Product Specification

344

DC Characteristics

Table 233 on page 344 lists the DC characteristics of the eZ80F91 device.

Table 233. DC Characteristics

Symbol Parameter

TA =

0 ºC to 70 ºC TA =

–40 ºC to 105 ºC

Units ConditionsMinimum Typ2Maximum Minimum Typ2Maximum

VDD Supply Voltage 3.0 3.3 3.6 3.0 3.3 3.6 V

VIL Low Level

Input Voltage –0.3 0.3 x VDD –0.3 0.3 x VDD V

VIH High Level

Input Voltage 0.7 x VDD 5.5 0.7 x VDD 5.5 V

VOL Low Level

Output Volta g e 0.4 0.4 V VDD = 3.0 V;

IOL = 1 mA

VOH High Level

Output Volta g e 2.4 2.4 V VDD = 3.0 V;

IOH = –1 mA

VRTC RTC Supply

Voltage 2.0 3.6 2.0 3.6 V

IIL Input Leakage

Current –10 +10 –10 +10 μAVDD = 3.6 V;

VIN = VDD or

VSS1

ITL Open-drain

Leakage Current –10 +10 –10 +10 μAV

DD = 3.6 V

ICC a Active Current 26 40 mA @ 10 MHz

52 80 mA @ 20 MHz

137 190 mA @ 50 MHz

ICC h HALT Mode

Current 15 20 mA @ 10 MHz

27 40 mA @ 20 MHz

75 100 mA @ 50 MHz

ICC s SLEEP Mode

Current 2.5 20 2.5 95 μA VBO_OFF=1

(VBO

disabled)

IRTC RTC Supply

Current 2.5 10 2.5 10 μA Supply current

into VRTC

1This condition excludes all pins with on-chip pull-ups when driven Low.

2Values in Typical column are for Vdd = 3.3 V and TA = 25 ºC.

PS027001-0707 Electrical Characteristics

eZ80F91 ASSP

Product Specification

345

POR and VBO Electrical Characteristics

Table 234 on page 345 lists the Power-On Reset and Voltage Brownout characteristics of

the eZ80F91 device.

Flash Memory Characteristics

Table 235 lists the Flash memory characteristics of the eZ80F91 device. For Flash

programming and erase timing information, see Flash Memory on page 97.

Current Consumption Under Various Operating Conditions

Figure 65 on page 346 illustrates the typical current consumption of the eZ80F91 device

versus Vdd while operating at 25 ºC, with zero Wait states, and with either a 10 MHz,

20 MHz, or 50 MHz system clock.

Table 234. POR and VBO Electrical Characteristics

Symbol Parameter

TA = –40 ºC to 105 ºC

Unit ConditionsMinimum Typ Maximum

VVBO VBO Voltage Threshold 2.45 2.65 2.90 V VCC = VVBO

VPOR POR Voltage Threshold 2.55 2.75 2.95 V VCC = VPOR

VHYST POR/VBO Hysteresis 30 100 120 mV

TANA POR/VBO analog RESET duration 40 100 μs

TVBO_MIN VBO pulse reject period 10 μs

IPOR_VBO POR/VBO DC current consumption 40 50 μA

ISPOR_VBO POR/VBO DC sleepmode current

consumption 120 150 μA VBO_OFF=0

(VBO enabled)

VCCRAMP VCC ramp rate requirements to

guarantee proper RESET occurs 0.1 100 V/ms

Table 235. Flash Memory Electrical Characteristics and Timing

Symbol

VDD = 3.0 V to 3.6 V;

TA = –40 ºC to 105 ºC

Units NotesMinimum Typical Maximum

Flash Byte Read Cycle Time 78 — — ns

PS027001-0707 Electrical Characteristics

eZ80F91 ASSP

Product Specification

346

Figure 65. ICC vs. System Clock Frequency During ACTIVE Mode

e Z80F91 Active Id d vs CL K Fre q @ V d d (25C)

0.00

20.00

40.00

60.00

80.00

100.00

120.00

140.00

160.00

180.00

10Mhz 20Mhz 50Mhz

Frequency (MHz)

Actve Idd (Icca) (mA)

Vdd=2.9V Vdd=3.3V Vdd=3.7V

PS027001-0707 Electrical Characteristics

eZ80F91 ASSP

Product Specification

347

Figure 66 illustrates the typical current consumption of the eZ80F91 device versus system

clock frequency while operating in HALT mode.

Figure 66. ICC vs. System Clock Frequency During HALT Mode

e Z80F91 HALT Mode Idd vs CLK Freq @ Vdd (25C)

0.00

10.00

20.00

30.00

40.00

50.00

60.00

70.00

80.00

90.00

100.00

10Mhz 20Mhz 50Mhz

Fre q ue ncy (MHz)

HA LT Mode Idd (I cch) (mA)

Vdd=2.9V Vdd=3.3V Vdd=3.7V

PS027001-0707 Electrical Characteristics

eZ80F91 ASSP

Product Specification

348

Figure 67 illustrates the typical current consumption of the eZ80F91 device versus Vdd

while operating in SLEEP mode (units in mi croamps, 10-6A); all peripherals of f, and VBO

disabled.

AC Characteristics

This section provides information about the AC characteristics and timing of the

eZ80F91 device. All AC timing information assumes a standard load of 50 pF on all

outputs. See Table 236.

Figure 67. ICC vs. Vdd During SLEEP Mode

Table 236. AC Characteristics

Symbol Parameter

TA =

0 ºC to 70 ºC TA =

–40 ºC to 105 ºC

Units ConditionsMinimum Maximum Minimum Maximum

TXIN System Clock

Cycle Time 20 1000 20 1000 ns VDD = 3.0–3.6 V

TXINH System Clock

High Time 88nsV

DD = 3.0–3.6 V;

TCLK = 20 ns

TXINL System Clock

Low Time 88nsV

DD = 3.0–3.6 V;

TCLK = 20 ns

e Z80F91 S LEEP M ode Idd vs V dd (25C)

2.15

2.20

2.25

2.30

2.35

2.40

2.45

2.50

2.55

2.60

2.65

2.9 3.3 3.7

Vdd (V)

SLEEP Mode I dd (Iccs) (u A)

Iccs (V BO disabled)

PS027001-0707 Electrical Characteristics

eZ80F91 ASSP

Product Specification

349

Table 237 lists simulated inductance, capacitance, and resistance results for the 144-pin

LQFP package at 100 MHz operating frequency.

Package vendor-supplied; 100 MHz operating frequency

TXINR System Clock

Rise Time 33nsV

DD = 3.0–3.6 V;

TCLK = 20 ns

TXINF System Clock

Fall Time 33nsV

DD = 3.0–3.6 V;

TCLK = 20 ns

CIN Input capacitance 10 typical 10 typical pF

Table 237. Typical 144-LQFP Package Electrical Characteristics

Lead Inductance (nH) Capacitance (pF) Resistance (mohm)

Longest 6.430 1.100 62.9

Shortest 4.230 1.070 52.6

Table 236. AC Characteristics (Continued)

Symbol Parameter

TA =

0 ºC to 70 ºC TA =

–40 ºC to 105 ºC

Units ConditionsMinimum Maximum Minimum Maximum

Note:

PS027001-0707 Electrical Characteristics

eZ80F91 ASSP

Product Specification

350

External Memory Read Timing

Figure 68 and Table 238 display the timing for external memory reads.

Figure 68. External Memory Read Timing

Table 238. External Memory Read Timing

Parameter Abbreviation

Delay (ns)

Minimum Maximum

T1PHI Clock Rise to ADDR Valid Delay — 8.5

T2PHI Clock Rise to ADDR Hold Time 1.0 —

T3DATA Valid to PHI Clock Rise Setup Time 0.5 —

T4PHI Clock Rise to DATA Hold Time 0.5 —

T5PHI Clock Rise to CSx Assertion Delay 2.6 8.0

T6PHI Clock Rise to CSx Deassertion Delay 0.0 6.0

T7PHI Clock Rise to MREQ Assertion Delay 2.6 7.0

T8PHI Clock Rise to MREQ Deas sertion Delay 1.0 6.3

PHI

ADDR[23:0]

DATA[7:0]

(input)

CSx

MREQ

CLK

PS027001-0707 Electrical Characteristics

eZ80F91 ASSP

Product Specification

351

External Memory Write Timing

Figure 69 and Table 239 on page 352 display the timing for external memory Writes.

T9PHI Clock Rise to RD Assertion Delay 2 .7 7.0

T10 PHI Clock Rise to RD Deassertion Delay 1.0 6.3

Figure 69. External Memory Write Timing

Table 238. External Memory Read Timing (Continued)

Parameter Abbreviation

Delay (ns)

Minimum Maximum

PHI

ADDR[23:0]

DATA[7:0]

(output)

CSx

MREQ

CLK

PS027001-0707 Electrical Characteristics

eZ80F91 ASSP

Product Specification

352

Table 239. External Memory Write Timing

Parameter Abbreviation

Delay (ns)

Minimum Maximum

T1PHI Clock Rise to ADDR Valid Delay — 8.5

T2PHI Clock Rise to ADDR Hold Time 1 —

T3PHI Clock Fall to DATA Valid — 2.5

T4PHI Clock Rise to DATA Hold Time 1.0 —

T5PHI Clock Rise to CSx Assertion Delay 2.3 10.8

T6PHI Clock Rise to CSx Deassertion Delay 0.0 6.0

T7PHI Clock Rise to MREQ Assertion Delay 2.3 7.0

T8PHI Clock Rise to MREQ Deas sertion Delay 2.3 6.5

T9PHI Clock Fall to WR Assertion Delay — 1.0

T10 PHI Clock Rise to WR Deassertion Delay* 0.0 5.0

WR Deassertion to ADDR Hold Time 0.4 —

WR Deassertion to DATA Hold Time 0.5 —

WR Deassertion to CSx Hold Time 1.2 —

WR Deassertion to MREQ Hold Time 0.5 —

*At the conclusion of a Write cycle, deassertion of WR always occurs before any change to

ADDR, DATA, CSx, or MREQ.

PS027001-0707 Electrical Characteristics

eZ80F91 ASSP

Product Specification

353

External I/O Read Timing

Figure 70 and Table 240 display the timing for external I/O reads. PHI clock rise/fall to

signal transition timing is independent of the particular bus mode employed (eZ80®, Z80,

Intel, or Motorola).

Figure 70. External I/O Read Timing

Table 240. External I/O Read Timing

Parameter Abbreviation

Delay (ns)

Minimum Maximum

T1PHI Clock Rise to ADDR Valid Delay — 7.3

T2PHI Clock Rise to ADDR Hold Time 1.0 —

T3DATA Valid to PHI Clock Rise Setup Time 0.5 —

T4PHI Clock Rise to DATA Hold Time 0.0 —

T5PHI Clock Rise to CSx Assertion Delay 2.0 8.5

T6PHI Clock Rise to CSx Deassertion Delay 0.0 6.0

T7PHI Clock Rise to IORQ Assertion Delay 2.6 7.0

PHI

ADDR[23:0]

DATA[7:0]

(input)

CSx

IORQ

T1T2

T3T4

T10

TCLK

PS027001-0707 Electrical Characteristics

eZ80F91 ASSP

Product Specification

354

External I/O Write Timing

Figure 71 and Table 241 on page 355 display the timing for external I/O W rites. PHI clock

rise/fall to signal transition timing is independent of the particular bus mode employed

(eZ80, Z80, Intel, or Motorola).

T8PHI Clock Rise to IORQ Deassertion Delay 1.0 6.3

T9PHI Clock Rise to RD Assertion Delay 2.7 7.0

T10 PHI Clock Rise to RD Deassertion Delay 0.5 6.3

Figure 71. External I/O Write Timing

Table 240. External I/O Read Timing (Continued)

Parameter Abbreviation

Delay (ns)

Minimum Maximum

PHI

ADDR[23:0]

DATA[7:0]

(output)

CSx

IORQ

T1T2

T3T4

T10

TCLK

PS027001-0707 Electrical Characteristics

eZ80F91 ASSP

Product Specification

355

Table 241. External I/O Write Timing

Parameter Abbreviation

Delay (ns)

Min Max

T1PHI Clock Rise to ADDR Valid Delay — 7.3

T2PHI Clock Rise to ADDR Hold Time 1.0 —

T3PHI Clock Fall to DATA Valid — 2.5

T4PHI Clock Rise to DATA Hold Time 1.0 —

T5PHI Clock Rise to CSx Assertion Delay 2.3 10.8

T6PHI Clock Rise to CSx Deassertion Delay 1.0 6.0

T7PHI Clock Rise to IORQ Assertion Delay 2.4 7.0

T8PHI Clock Rise to IORQ Deassertion Delay 1 .0 6.3

T9PHI Clock Fall to WR Assertion Delay — 1.0

T10 PHI Clock Rise to WR Deassertion Delay* 0.0 5.0

WR Deassertion to ADDR Hold Time 0.4 —

WR Deassertion to DATA Hold Time 0.5 —

WR Deassertion to CSx Hold Time 1.2 —

WR Deassertion to IORQ Hold Time 0.5 —

*At the conclusion of a Write cycle, deassertion of WR always occurs before any change to ADDR,

DATA, CSx, or IORQ.

PS027001-0707 Electrical Characteristics

eZ80F91 ASSP

Product Specification

356

Wait State Timing for Read Operations

Figure 72 illustrates the extension of the memory access signal s using a single Wait state

for a Read operation. This Wait state is generated by setting CS_WAIT to 001 in the Chip

Select Control Register.

Figure 72. Wait State Timing for Read Operations

TCLK TWAIT

SCLK

ADDR[23:0]

DATA[7:0]

(output)

CSx

MREQ

INSTRD

PS027001-0707 Electrical Characteristics

eZ80F91 ASSP

Product Specification

357

Wait State Timing for Write Operations

Figure 73 illustrates the extension of the memory access signal s using a single Wait state

for a W rite operation. This Wait state is generated by setting CS_WAIT to 001 in the Chip

Select Control Register.

Figure 73. Wait State Timing for Write Operations

CLK

WAIT

PHI

ADDR[23:0]

DATA[7:0]

(output)

CSx

MREQ

PS027001-0707 Electrical Characteristics

eZ80F91 ASSP

Product Specification

358

General Purpose Input/Output Port Input Sample Timing

Figure 74 illustrates timing of the GPIO input sampling. The input value on a GPIO port

pin is sampled on the rising edge of the system clock. The port value is then available to

the CPU on the second rising clock edge following the change of the port value.

General Purpose I/O Port Output Timing

Figure 75 and Table 242 on page 359 display timing information for GPIO port pins.

Figure 74. Port Input Sample Timing

Figure 75. GPIO Port Output Timing

TCLK

PHI

GPIO Pin

Input Value

GPIO Input

Data Latch

GPIO Data

READ on Data Bus

Port Value

Changes to 0

0 Latched

Into GPIO

Data Register GPIO Data Register

Value 0 Read

by eZ80

CLK

PHI

Port Output

PS027001-0707 Electrical Characteristics

eZ80F91 ASSP

Product Specification

359

External Bus Acknowledge Timing

Table 243 lists information on the bus acknowledge timing.

Table 242. GPIO Port Output Timing

Parameter Abbreviation

Delay (ns)

Minimum Maximum

T1PHI Clock Rise to Port Output Valid Delay — 5

T2PHI Clock Rise to Port Output Hold Time 1.0 —

Table 243. Bus Acknowledge Timing

Parameter Abbreviation

Delay (ns)

Minimum Maximum

T1PHI Clock Rise to BUSACK Assertion Delay 2.8 7.1

T2PHI Clock Rise to BUSACK Deassertion Delay 1.5 6.5

PS027001-0707 Electrical Characteristics

eZ80F91 ASSP

Product Specification

360

PS027001-0707 Packaging

eZ80F91 ASSP

Product Specification

361

Packaging

Figure 76 illustrates the 144-pin low-profile quad flat package (LQFP) for the eZ80F91

device.

Figure 76. 144-Lead Plastic Low-Profile Quad Flat Package (LQFP)

EF HE

DETAIL A

PS027001-0707 Packaging

eZ80F91 ASSP

Product Specification

362

Figure 77 illustrates the 144-pin chip array ball grid array (BGA) package for the eZ80F91

device.

Figure 77. 144-Lead Chip Array Ball Grid Array (BGA)

PS027001-0707 Ordering Information

eZ80F91 ASSP

Product Specification

363

Ordering Information

Table 244 provides a part name, a product specification index code, and a brief description

of each part.

Navigate your browser to Zilog ’s website to order the eZ80F91 ASSP. Or, contact your

local Zilog Sales Office. Zilog provides additional assistance on its Customer Service

page, and is also here to help with Technical Support issues.

For Zilog’s valuable development tools and downloadable software, refer to

www.zilog.com.

Part Number Description

Zilog part numbers consists of number of components as described below:

Table 244. Ordering Information

Part PSI Description

eZ80F91 e Z 80F 91 AZA5 0SG 144-LQFP, 256 KB Flash memo ry, 8 KB

SRAM, 50 MHz, Standard Temperature

eZ80F91AZ A5 0EG 14 4- L QF P, 25 6 KB Flash memory, 8 KB

SRAM, 50 MHz, Extended Temperature

eZ80F91NAA50SG 144-BGA, 256 KB Flash memory, 8 KB

SRAM, 50 MHz, Standard Temperature

eZ80F91NAA50EG 144-BGA, 256 KB Flash memory, 8 KB

SRAM, 50 MHz, Extended Temperature

eZ80F910300ZCOG eZ80F91 Development Kit

ez80F910200KITG eZ80F91 Modular Development Kit

eZ80F917050SBC Zdots® Single Board Computer for

eZ80AcclaimPlus!™ Connectivity ASSP

ZUSBSC00100ZACG USB Smart Cable

ZENETSC0100ZACG Ethernet Smart Cable

Zilog Base Products

eZ80®Zilog eZ80 CPU

F91 Product Number

AZ Package

PS027001-0707 Ordering Information

eZ80F91 ASSP

Product Specification

364

Example: Part number eZ80F91AZ050SC is an eZ80F91 product in a LQFP package,

operating with a 50 MHz external clock frequency over a 0 ºC to +70 ºC temperature range

and built using the Plastic Standard environmental flow.

050 Speed

S or E Temperature

C or G Environmental Flow

Package AZ = LQFP (also called VQFP)

Speed 050 = 50 MHz

Standard Temperatur e S = 0 ºC to +70 ºC

Extended Temperature E = –40 ºC to +105 ºC

Environmental Flow C = Plastic Standard; G = Lead-Free

Zilog Base Products

eZ80F91 ASSP

Product Specification

PS027001-0707

365

Index

Numerics

100-pin LQFP package 4, 5

16-bit clock divisor value 182, 208

16-bit divisor count 182, 208

32 KHz Real-Time Clock Crystal Oscillator Opera-

tion 341

AAK 219, 220, 222, 223, 224, 228, 229

Absolute Maximum Ratings 343

Absolute maximum ratings 343

AC Characteristics 348

ACK 215, 219, 220, 221, 222, 223, 226, 230,

231

Acknowledge 215

Acknowledge, I2C 215

ADDR0 6

ADDR1 6

ADDR10 6

ADDR11 6

ADDR12 7

ADDR13 7

ADDR14 7

ADDR15 7

ADDR16 7

ADDR17 7

ADDR18 7

ADDR19 7

ADDR2 6

ADDR20 7

ADDR21 7

ADDR22 7

ADDR23 7

ADDR3 6

ADDR4 6

ADDR5 6

ADDR6 6

ADDR7 6

ADDR8 6

ADDR9 6

Address Bus 6, 7

address bus 58, 68, 70, 71, 74, 75, 78, 81, 82,

85, 86, 161, 242, 243, 253, 259

address bus, 24-bit 27

Addressing, I2C 225

ALARM 160, 174

ALARM bit flag 173

alarm condition 160, 161, 173, 174

AND/OR Gating of the PWM Outputs 148, 149

Arbiter, EMAC 293

Arbitration, I2C 217

asynchronous communications protocol 175, 176

asynchronous communications protocol bits 176

asynchronous serial data 11, 14

Basic Timer Operation 122

Basic Timer Register Set 130

Baud Rate Generator 181

Baud Rate Generator Functional Description 207

BCD 159, 173, 174

Binary Operation 161, 162, 163, 166, 167, 168,

169, 170, 171, 172

binary operation 159

binary-coded-decimal 159

Binary-Coded-Decimal Operation 161, 164, 165,

166, 167, 168, 169, 170, 171, 172

bit generation 175, 176

Block Diagram 2

Boot Block 25, 97, 107, 109

Boundary Scan Cell Functionality 264

Boundary Scan Instructions 268

Boundary-Scan Architecture 261

break detection 175, 185

Break Point Halting 126

break point trigger functions 261

BRG Control Registers 182

Bus Acknowledge Cycle 70

bus acknowledge cycle 6, 8, 9, 89, 90, 91, 94

bus acknow ledge pin 70, 253

Bus Arbiter 89

Bus Arbitration Overview 213

eZ80F91 ASSP

Product Specification

PS027001-0707

366

Bus Clock Speed, I2C 233

Bus Mode Controller 70

bus mode state 71, 72, 75

Bus modes 70

bus modes 71, 84, 88

Bus Modes, Switching Between 84

Bus Requests During ZDI Debug Mode 242

bus timing 70

BUSACK 9, 70, 243, 253, 259, 359

BUSACK pin 89, 253, 259

BUSREQ 9, 70, 259

BUSREQ pin 89, 243, 253, 259

Byte Format, I2C 215

C source-level debugging 235

capture flag 128

Carrier Sense 311

carrier sense 307

carrier sense window 312

Carrier Sense Window Referencing 312

Carrier Sense, MII 22

Chain Sequence and Length, JTAG Boundary Scan

264

Characteristics, electrical

Absolute maximum ratings 343

Charge Pump 269

charge pump 273

Charge Pump, PLL 270

Chip Select Registers 85

Chip Select x Bus Mode Control Register 88

Chip Select x Control Register 87

Chip Select x Lower Bound Register 85

Chip Select x Upper Bound Register 86

Chip Select/Wait State Generator block 6

Chip Selects During Bus Request/Bus Acknowl-

edge Cycles 70

Clear to Send 12, 15, 194

CLK_MUX 273

clock divisor valu e, 16-bit 182, 208

clock initialization circuitry 262

Clock Peripheral Power-Down Registers 46

clock phase 204

clock phase bit 206

clock polarity bit 206

Clock Synchronization for Handshake 218

Clock Synchronization, I2C 216

Clocking Overview 213

COL 22

Complex triggers 261

CONTINUOUS mode 125

Continuous Mode 123, 126

continuous mode 121, 132, 138, 139

Control Transfers, UART 179

CPHA—see clock phase 204, 205, 210

CPOL—see clock polarity 205, 210

CRC 298, 299, 303, 304, 316

CRS 22, 311

CS0 7, 65, 66, 67, 68

CS1 7, 65, 66, 67, 68

CS2 7, 65, 67, 68

CS3 7, 65, 67, 68

CTS 192, 194

CTS0 12, 200

CTS1 15

Customer Feedback Form 379

DATA bus 78

Data Bus 8

data bus 70, 71, 73, 74, 75, 82, 88, 161, 242,

243, 253, 259

Data Carrier Detect 13, 16, 194

Data Set Ready 13, 16, 194

Data Terminal Ready 12, 15, 192

Data Transfer Proce dur e with SPI config ure d as a

Slave 208

Data Transfer Procedure with SPI Configured as the

Master 207

data transfer, SPI 211

Data Transfers, UA RT 179

Data Validity, I2C 214

DATA0 8

DATA1 8

DATA2 8

DATA3 8

eZ80F91 ASSP

Product Specification

PS027001-0707

367

DATA4 8

DATA5 8

DATA6 8

DATA7 8

DC Characteristics 344

DCD 191, 194

DCD0 13, 200

DCD1 16

DCTS 194

DDCD 194

DDSR 194

Divider, PLL 270

divisor count 208

divisor count, 16-bit 182

DSR 192, 194

DSR0 13, 200

DSR1 16

DTACK 81, 82

DTR 192, 194

DTR0 12, 200

DTR1 15

EC0 17, 127, 129, 132

EC1 22, 127, 129, 132

edge-selectable interrupts 55

Edge-Triggered Interrupts 54

EI, Op Code Map 284

EMAC 291

EMAC Address Filter Register 315

EMAC Boundary Pointer Register—Low and High

Bytes 323

EMAC Boundary Pointer Register—Upper Byte

323

EMAC Buffer Size Register 326

EMAC Configuration Register 1 303

EMAC Configuration Register 2 305

EMAC Configuration Register 3 306

EMAC Configuration Register 4 307

EMAC FIFO Data Register—Low and High Bytes

336

EMAC FIFO Flags Register 337

EMAC Functional Description 292

EMAC Hash Table Register 316

EMAC Interpacket Gap 309

EMAC Interpacket Gap Overview 309

EMAC Interpacket Gap Register 311

EMAC Interrupt Enable Register 327

EMAC Interrupt Status Register 329

EMAC Interrupts 296

EMAC Maximum Frame Length Register—Low

and High Bytes 313

EMAC memory 292, 293

EMAC MII Management Register 317

EMAC MII Status Register 331

EMAC Non-Back-To-Back IPG Register—Part 1

312

EMAC Non-Back-To-Back IPG Register—Part 2

312

EMAC PHY Address Register 319

EMAC PHY Configuration Data Register—Low

Byte 318

EMAC PHY Read Status Data Register—Low and

High Bytes 330

EMAC PHY Unit Select Address Register 320

EMAC RAM 93, 94, 95, 96

EMAC Receive Blocks Left Register—Low and

High Bytes 334

EMAC Receive High Boundary Pointer Register—

Low and High Bytes 324

EMAC Receive Read Pointer Register—Low and

High Bytes 325

EMAC Receive Write Pointer Register—High Byte

333

EMAC Receive Write Pointer Register—Low Byte

332

EMAC Receiver Interrupts 296

EMAC Registers 301

EMAC Reset Control Register 321

EMAC Shared Memory Organization 296

EMAC Station Address Register 307

EMAC System Interrupts 296

EMAC Test Register 302

EMAC Transmit Lower Boundary Pointer Regis-

ter—Low and High Bytes 322

EMAC Transmit Pause Timer Value Register—

Low and High Bytes 309

eZ80F91 ASSP

Product Specification

PS027001-0707

368

EMAC Transmit Polling Timer Register 320

EMAC Transmit Read Pointer Register—High

Byte 334

EMAC Transmit Read Pointer Register—Low Byte

333

EMAC Transmitter Interrupts 296

EMACMII module 291

Enabling and Disabling the WDT 116

Endec 201

endec 197, 198, 200

ENDEC Mode 310

ENDEC mode 306

endec signal pins 200

endec, IrDA 47

Erasing Flash Memory 101

Ethernet Media Access Controller 291

event count input 132

Event count mode 127

event count mode 128

Event Counter 125, 127

event counter 127

External Bus Acknowledge Timing 359

external bus master 89, 90

external bus request 70, 239, 243

External I/O Read Timing 353

External I/O Write Timing 354

External Memory Read Timing 350

External Memory Write Timing 351

external pull-down resistor 51

External Reset Input and Indicator 41

eZ80 Bus Mode 71

eZ80 bus mode 88

eZ80 CPU 8, 69, 70, 74, 81, 197, 245, 261

eZ80 Product ID Low and High Byte Registers 255

eZ80 Product ID Revision Register 256

eZ80 Webserver-i 2, 6, 8, 9, 19, 57, 58, 68, 115

eZ80 Webserver-i Block Diagram 3

eZ80AcclaimPlus! Flash Microcontrollers 1, 98

eZ80F91 device 4, 5, 27, 345

eZ80F92 256

f 71, 74, 350

falling edge 147, 148, 150, 155

FAST mode 213, 233

FCS 299, 300, 309

Features 1

Features, eZ80 CPU Core 39

FIFO mode 176, 179

Flash Address registers 100, 103, 110

Flash address registers 99

Flash Address Upper Byte Register 104

Flash Column Select Register 112

Flash Control Register 105

Flash Control Registers 102

Flash controller 98, 99, 100, 106, 108

Flash controller clock 106

Flash Data Register 103

Flash Frequency Divider Register 106

Flash Interrupt Control Register 108

Flash Key Register 102

Flash Memory 97

Flash memory array 98, 109

Flash Memory Overview 98

Flash Page Select Register 109

Flash Program Control Register 112

Flash Row Select Register 111

Flash Write/Erase Protection Register 107

frame check sequence 309

framing error 175, 177, 185, 193

frequency divider 98, 106

full-duplex transmission 206

Functional Description, Infrared Encoder/Decoder

197

Functional Description, Serial Peripheral Interface

206

General Purpose I/O Port Input Sample Timing 358

General Purpose I/O Port Output Timing 358

General-Purpose Input/Output 49

GND 2

GPIO Control Registers 55

GPIO Interrupts 54

GPIO modes 50, 52

GPIO Operation 49

eZ80F91 ASSP

Product Specification

PS027001-0707

369

GPIO Overview 49

GPIO port pins 41, 49, 55, 358

HALT 10, 257, 281

HALT instruction 45

HALT Mode 45

HALT mode 1, 46, 249, 257

HALT, Op-Code Map 284

HALT_SLP 10, 257, 264

Handshake 218

handshake 175, 177

hash table 315

I/O Chip Select Operation 68

I/O Chip Selects, External 27

I/O Read 99

I/O space 6, 8, 65, 68

I2C Acknowledge bit 228

I2C bus 213, 216, 217

I2C bus clock 213

I2C bus protocol 214

I2C Clock Control Register 232

I2C control bit 219, 220, 222

I2C Control Register 227

I2C Data Register 227

I2C Extended Slave Address Register 226

I2C Registers 225

I2C Software Reset Register 233

I2C Status Register 230

IC0 17, 127, 129, 134, 135, 139, 140, 141, 142,

152, 156

IC1 17, 127, 129, 134, 135 , 139, 141, 152, 156

IC2 18, 127, 129, 134, 135, 139, 140, 141, 152,

156

IC3 18, 127, 129, 134, 135, 139, 141, 142, 152,

156

IEEE 1149.1 specification 263, 268

IEEE 802.3 315

IEEE 802.3 frames 304

IEEE 802.3 specification 305, 306

IEEE 802.3, 802.3(u) minimum values 310

IEEE 802.3/4.2.3.2.1 Carrier Deference 311, 312

IEEE Standard 1149.1 261, 262

IEF1 59, 125, 257

IEF2 59

IFLG bit 213, 218, 221, 223, 224, 225, 228, 231

IM 0, Op Code Map 287

IM 1, Op Code Map 287

IM 2, Op Code Map 287

Information Page Characteristics 102

Infrared Encoder/Decoder 197

Infrared Encoder/Decoder Register 201

Infrared Encoder/Decoder Signal Pins 200

Input Capture 128

INPUT capture mode 130

Input capture mode 128

input capture mode 127, 134

INSTRD 9

Instruction Store 4

0 Registers 253

Intel- 70

Intel Bus Mode 73

Intel Bus Mode (Separate Address and Data Buses)

internal pull-up 51

Internal RC oscillator 115

internal RC oscillator 118

internal system clock 69

Interpacket Gap 310, 311

Interpacket gap 309

interpacket gap 300, 312

Interrupt Controller 57

interrupt enable 9

Interrupt Enable bit 227

interrupt enable bit 160, 178

Interrupt Enable Flag 257

interrupt enable flag 125

Interrupt Input 200

interrupt input 11, 12, 13, 14, 15, 16

Interrupt Priority 61, 63

interrupt priority 63

interrupt priority levels 60

Interrupt Priority Registers 60

Interrupt request 133, 134

eZ80F91 ASSP

Product Specification

PS027001-0707

370

interrupt request 54, 58, 108, 127

interrupt request signals 57

interrupt service routine 58, 59, 60

interrupt service routine, SPI 58

interrupt sources 152

interrupt vector 57, 58

interrupt vector address 59, 60

interrupt vector bus 58

interrupt vector locations 58

interrupt vector table 58

interrupt, higher-priority 62, 186

interrupt, highest-priority 57, 58

interrupts, edge-selectable 55

interrupts, level-sensitive 55

Introduction to On-Chip Instrumentation 261

Introduction, ZiLOG Debug Interface 235

IORQ 8, 9, 68, 71, 74, 75, 78

IORQ Assertion Delay 353, 355

IORQ Deassertion Delay 354, 355

IORQ Hold Time 355

IR_RXD 198, 200, 201

IR_TxD modulation signal 11, 198, 200

IrDA Encoder/Decoder 200

IrDA encoder/decoder 11

IrDA endec 47

IrDA Receive Data 11

IrDA specifications 198

IrDA standard 197

IrDA standard baud rates 197

IrDA transceiver 200

IrDA Transmit Data 11

IrDA—see Infrared Data Association 197

IRQ 58

irq_en 207, 210

ISR 58

IVECT 57, 58, 59, 60

Jitter, Infrared Encoder/Decoder 200

JTAG Boundary Scan 263

JTAG interface 261, 268

JTAG mode selection 262

JTAG Test Mode 10

least-significant byte 58

level-sensitive interrupt modes 52

level-sensitive interrupts 55, 200

Level-Triggered Interrupts 54

Line break detection 175

line status error 178

Line status interrupt 185

line status interrupt 177, 179, 180

Lock Detect 269

lock detect 271

lock detect sensitivity 273

Lock Detect, PLL 270

Loop Filter 269

loop filter 271, 277

Loop Filter, PLL 13, 270

loop mode 177

LOOP_FILT 263

Loopback Testing, Infrared Encoder/Decoder 200

low-byte vector 57

LSB 59, 60, 138, 232, 308, 315

Lsb 295

lsb 136, 138, 140, 141, 144, 157, 158, 218,

219, 220, 221, 222, 224, 314, 318, 322, 324,

325, 330, 332, 333

maskable interrupt 46, 57, 60, 62

Maskable Interrupts 57

Mass Erase 101

mass erase 107, 108, 112

MASS ERASE operation 102

Mass Erase operation 113

mass erase operation 101, 110

MASTER mode 205, 213, 228, 230, 231, 232,

233

Master mode 224, 229

master mode 224

Master Mode Start bit 227

Master Mode Stop bit 228

MASTER mode, SPI 206

Master Receive 213, 221

Master Transmit 218

eZ80F91 ASSP

Product Specification

PS027001-0707

371

MASTER TRANSMIT mode 213

master_en bit 206

Master-In, Slave-Out 204

Master-Out, Slave-In 204

MAXF 303

MAXF—see Maximum Frame Length 313

Maximum Frame Length 313

MBIST 96

MBIST Control 96

MDC 24, 318

MDIO 25

Memory and I/O Chip Selects 65

Memory Built-In Self-Test controllers 96

Memory Chip Select Example 66

Memory Chip Select Operation 65

Memory Chip Select Priority 66

Memory Read 99

Memory Request 8

memory space 65, 68

Memory Write 101

Memory, EMAC 292

MII 291, 296, 310, 317, 328, 329, 330, 331

MISO—see SPI Master In Slave Out 19, 204, 206

mode fault 211

Mode Fault error flag 204

Mode Fault flag 206

Mode Fault, SPI Flag 206

Modem Status 186, 194

Modem status 178

modem status 179, 180, 191

modem status interrupt 200

Modem status signal 12, 13, 15, 16

MODF 204, 206, 211

Module Reset, UART 179

MOSI—see SPI Master Out Slave In 19, 204, 205,

206

Motorola Bus Mode 80

Motorola-compatible 70

mpwm_en 146, 153

MREQ 8, 9, 65, 71, 74, 75, 78, 350, 352

MREQ Hold Time 352

MSB 58, 139

Msb 295

msb 109, 137, 139, 141, 142, 145, 157, 158,

215, 241, 314, 322, 331, 333, 334, 335

Multibyte I/O Write (Row Programming) 100

multicast address 300, 316

multicast packet 315, 316

multimaster conflict 206, 211

Multi-PWM Control Registers 153

Multi-PWM Mode 145

Multi-PWM Power-Trip Mode 152

Mux/CLK Sync 269

MUX/CLK Sync, PLL 270

NACK 215, 219, 220, 222, 223, 228, 231

New Instructions, eZ80 CPU Core 39

NMI 9, 39, 46, 57, 115, 117, 118

NMI_flag bit 117

nmi_out bit 117

Nonmaskable Interrupt 9, 39

Nonmaskable interrupt 282

nonmaskable interrupt 46, 57, 115, 117

nonoverlapping delay, PWM 148, 151

Not Acknowledge 215

OC0 20, 127, 129, 133, 135, 143, 144, 145

OC1 20, 127, 129, 133, 135

OC2 20, 127, 129, 133, 135

OC3 21, 127, 129, 133, 135, 144, 145

OCI Activation 262

OCI clock pin 262

OCI Interface 262

On-Chip Instrumentation, Introduction to 261

on-chip pull-up 344

On-chip RAM 65, 93, 94

Op Code maps 284

Op-Code Map 284

Open source I/O 50

Open-drain I/O 50

open-drain I/O 51

open-drain mode 51

Open-drain output 50

open-drain output 213

eZ80F91 ASSP

Product Specification

PS027001-0707

372

open-source mode 51

Open-source output 50

open-source output 11, 12, 13, 14, 15, 16, 17, 18,

Operating Modes, I2C 218

Operation of the eZ80F91 Device during ZDI Break

Points 242

Ordering Information 362

Output Compare 128

Output compare mode 143

output compare mode 127, 128, 130, 133

overrun condition, receiver 178

Overrun error 193

overrun error 175, 177, 185

Overview, Phase-Locked Loop 269

PA7 150

Packaging 361

Page Erase 101

page erase 112

Page Erase operation 11 3

page erase operation 101, 109

PAIR_EN 153, 154

parity error 177, 188, 193

Part Number Description 363

PB0 17

PB1 17

PB2 17

PB3 18

PB4 18

PB5 18

PB6 19

PB7 19

PC0 14, 20

PC1 14, 20

PC2 15, 20

PC3 15, 21

PC4 15, 21

PC5 16, 21

PC6 16, 22

PC7 16, 22

PD0 11, 200

PD1 11, 200

PD2 12, 200

PD3 12

PD4 12

PD5 13

PD6 13

PD7 13, 200

Phase Frequency Detector 269

Phase Frequency Detector, PLL 270

PHI 19, 265

PHI Clock output 48

PHY 22, 24, 28, 29, 296, 300, 318, 319, 329,

330, 331

PHY, MII 292, 317

Pin Characteristics 6

Pin Coverage, JTAG Boundary Scan 263

Pin Description 4

PLL Characteristics 276

PLL Control Register 0 273

PLL Control Register 1 274

PLL Divider Control Register—Low and High

Bytes 272

PLL Loop Filter 13

PLL Normal Operation 271

PLL Registers 272

PLL_VDD 272

PLL_VSS 272

Poll Mode Transfers 181

POP, Op Code Map 284, 286, 288

POR Voltage Threshold 345

POR voltage threshold 42

POR/VBO analog RESET duration 345

POR/VBO DC current cons um ptio n 345

POR/VBO Hysteresis 345

Port A 20, 21, 47, 49, 58, 62, 63, 145

Port x Alternate Register 1 56

Port x Alternate Register 2 56

Port x Data Direction Registers 55

Port x Data Registers 55

Potential Hazards of Enabling Bus Requests During

Debug Mode 243

Power connections 2

Power Requirement to the Phase-Locked Loop

Function 272

eZ80F91 ASSP

Product Specification

PS027001-0707

373

Power-On Reset 41, 42, 345

power-trip 153

Power-Trip Mode, Multi-PWM 152

power-trip, multi-PWM 152

Primary Crystal Oscillator Operation 339

Program Counter 41, 45, 46, 59, 97, 254, 255,

259

Program Counter, Starting 60

Programmable Reload Timers 121

Programming Flash Memory 99

Promiscuous Mode 315

PT_EN 153

pull-up resistor, external 51, 213

Pulse-Width Modulation Control Register 1 153

Pulse-Width Modulation Control Register 2 154

Pulse-Width Modulation Control Register 3 156

Pulse-Width Modulation Falling Edge—High Byte

158

Pulse-Width Modulation Falling Edge—Low Byte

158

Pulse-Width Modulation Rising Edge—High Byte

157

Pulse-Width Modulation Rising Edge—Low Byte

157

PUSH, Op Code Map 284, 286, 288

PWM delay feature 151

PWM edge transition values 148, 149

PWM generator 145, 146, 147, 148, 153

PWM generators 146

PWM Master Mode 148

PWM mode 121, 127, 130, 131, 134

PWM mode, Multi- 145, 146, 148, 149, 153

PWM nonoverlapping delay 148

PWM nonoverlapping delay time 151

PWM Nonoverlapping Outpu t Pair Delays 150

PWM output pairs 148

PWM outputs 149, 150, 152

PWM Outputs, AND/OR Gating 148, 149

PWM outputs, inverted 147

PWM pairs 149

PWM power-trip state 152

PWM signals 145

PWM trip levels 156

PWM waveform 149

PWM0 150

PWM1 20, 21, 127, 129, 147, 149

PWM1 falling edge end-of-count 148, 151

PWM1 rising edge end-of-count 148, 151

pwm1_en 153

PWM1FH 148

PWM1RH 157, 158

PWM1RL 157, 158

PWM2 20, 22, 127, 129, 147

PWM2 falling edge end-of-count 148

PWM2 rising edge end-of-count 148

pwm2_en 153

PWM2RH 148

PWM3 21, 22, 127, 147

pwm3_en 153

PWMCNTRL1 146

PWMCNTRL2 148

PWMCNTRL3 152

QMC 315

qualified multicast messages 315

RAM 93

RAM Address Upper Byte Register 95

RAM Control Register 94

Random Access Memory 93

RD 8, 65, 68, 71, 74, 75, 78

RD Assertion Delay 351, 354

RD Deassertion Delay 351, 354

Reading Flash Memory 98

Reading the Current Count Value 122

Real-Time Clock 41, 45, 159, 160, 161, 173

Real-Time Clock Alarm 160

Real-Time Clock alarm 45

Real-Time Clock Alarm Control Register 173

Real-Time Clock Alarm Day-of-the-Week Register

172

Real-Time Clock Alarm Hours Register 171

Real-Time Clock Alarm Minutes Register 170

Real-Time Clock Alarm Seconds Register 169

eZ80F91 ASSP

Product Specification

PS027001-0707

374

Real-Time Clock Battery Backup 160

Real-Time Clock Century Register 168

Real-Time Clock Control Register 173

Real-Time Clock Day-of-the-Month Register 165

Real-Time Clock Day-of-the-Week Register 164

Real-Time Clock Hours Registe r 163

Real-Time Clock Minutes Register 162

Real-Time Clock Month Register 166

Real-Time Clock Oscillat or and Source Selection

160

Real-Time Clock Overview 159

Real-Time Clock Recommended Operation 160

Real-Time Clock Registers 161

Real-Time Clock Seconds Register 161

Real-Time Clock signal 128

Real-Time Clock source 115, 118, 125

Real-Time Clock Year Register 167

Receive, Infrared Encoder/Decoder 198

Recommended Usage of the Baud Rate Generator

181

130

Request to Send 12, 15, 192

RESET 9, 41, 42, 45, 46, 50, 65, 93, 94, 105,

107, 115, 116, 117, 161, 164, 165, 166, 167,

168, 169, 170, 171, 172, 173, 174, 181, 182,

201, 207, 208, 247, 249, 262, 264, 345

Reset controller 41, 42

RESET event 41, 49

RESET mode timer 41, 42

RESET Or NMI Generation 117

Reset States 66

RESET_OUT 264

Resetting the I2C Registers 225

RI 177, 191, 194

RI0 13, 200

RI1 16, 51

Ring Indicator 13, 16, 194

rising edge 147, 148, 150, 155

rst_flag bit 117

RTC Oscillator Input 128

RTC Supply Voltage 344

RTC_VDD 10

RTC_XIN 10

RTC_XOUT 10

RTS 192, 194, 200

RTS0 12

RTS1 15

RX_CLK 24

Rx_CLK 23

Rx_DV 24

Rx_ER 23

RxD0 11, 24

RxD1 14, 24

RxD2 24

RxD3 24

RxDMA 294

Schmitt Trigger 9

Schmitt trigger 9

Schmitt Trigger Input 9, 11, 14, 15, 17, 18, 25

Schmitt-trigger input buffers 49

SCK 18, 204

SCK Idle State 205

SCK pin 206, 210

SCK Receive Edge 205

SCK signal 206

SCK Transmit Edge 205

SCL 19, 213, 214, 215, 232

SCL line 216, 218

SCLK 41, 150, 269, 318

SClk 270

Sclk 271

SCLK periods 155

SDA 19, 213, 214, 215, 224

SDA line 217

see system reset 8

serial bus, SPI 211, 212

Serial Clock 213

Serial Clock, I2C 19

Serial Clock, SPI 18, 204

Serial Data 213

serial data 204

Serial Data, I2C 19

Serial Peripheral Interface 1, 47, 58, 62, 203,

eZ80F91 ASSP

Product Specification

PS027001-0707

375

204, 206

Serial Peripheral Interface flag 211, 212

Serial Peripheral Interface Functional Description

206

Setting Timer Duration 122

Single Pass Mode 123

single pass mode 121, 124, 132

Single-Byte I/O Write 99

SLA 220, 222, 226, 283

SLA, Op Code Map 289, 290

SLA, Op Code map 285

SLAVE mode 213, 227, 231

slave mode 224, 225, 226

SLAVE mode, SPI 206

Slave Receive 213, 224

Slave Select 204

Slave Transmit 213, 223

Slave Transmit mode 228

slave transmit mode 223, 224

SLEEP Mode 45

SLEEP mode 173, 249, 257

sleep-mode recovery 173

sleep-mode recovery reset 174

Software break point instruction 261

Specialty Timer Modes 126

SPI Baud Rate Generator 207

SPI Baud Rate Generator Registers—Low Byte and

High Byte 208

SPI Control Register 210

SPI Data Rate 207

SPI Flag 206

SPI interrupt service routine 58

SPI Master device 208

SPI master device 19

SPI MASTER mode 206

SPI mode 17

SPI Receive Buffer Register 212

SPI Registers 208

SPI serial bus 211

SPI Serial Clock 18

SPI Signals 204

SPI slave device 19

SPI SLAVE mode 206

SPI Status Register 207, 211

SPI Transmit Shift Register 207, 208, 211

SPIF status bit—see Serial Peripheral Interface flag

211

SPIF—see Serial Peripheral Interface flag 206,

211

SRA 283

SRA, Op Code Map 285, 289

SRAM 1, 104, 235, 333, 363

SRAM, internal Ethernet 296

SS—see Slave Select 17, 204, 205, 206, 208,

210

STA 227

standard mode 213

Standard VHDL Package STD_1149_1_2001 264

START and STOP Conditions 214

START condition 214, 217, 218, 22 1, 223, 224,

225, 227, 229, 230, 231, 232

start condition 215

Start Condition, ZDI 237

Starting Program Counter 59, 60

STOP condition 214, 215, 217, 221, 223, 224,

228, 229, 231, 232

Supply Voltage 344

supply voltage 2, 42, 51, 213, 271, 343

Switching Between Bus Modes 84

System clock 47, 48, 115

system clock 41, 45, 51, 54, 118, 125, 127, 132,

150, 181, 207, 232, 233, 242, 262, 270, 293,

358

system clock cycle 75, 78, 122

System Clock Cycle Time 348

system clock cycles 9, 68, 71, 72, 75, 78, 82,

116, 262

System clock divider 132

System Clock Fall Time 349

System Clock Frequency 122, 181, 207

system clock frequency 99, 101, 105, 106, 236

System Clock High Time 348

system clock jitter 127

System Clock Low Time 348

System Clock Oscillator Input 14

System Clock Oscillator Output 13

system clock period 262

system clock periods 151

eZ80F91 ASSP

Product Specification

PS027001-0707

376

System Clock Rise Time 349

system clock rising edge 181, 207

System Clock Source 273

System clock source 274

system clock source 273

system clock, high-frequency 207

system clock, internal 69

system RESET 41, 162, 163

system reset 160, 183, 271, 301

T2 clock 151

T2 end-of-count 151

T23CLKCN 151

TAP 268

TAP Reset 262

TCK 237, 262, 263, 268

TDI 262, 263, 264

TDO 262, 263, 264

TERI 194

Test Access Port 261

Test Access Port instruction 268

Test Access Port state register 262

Test Mode 262

Time-Out Period Selection 116

Timer Control Register 132

Timer Data Register—High Byte 137

Timer Data Register—Low Byte 136

Timer Input Capture Control Register 139

Timer Input Capture Value A Register—High Byte

141

Timer Input Capture Value A Register—Low Byte

140

Timer Input Capture Value B Register—High Byte

142

Timer Input Capture Value B Register—Low Byte

141

Timer Input Source Selection 125

Timer Interrupt Enable Register 133

Timer Interrupt Identification Register 135

Timer Interrupts 124

Timer Output 125

Timer Output Compare Control Register 1 142

Timer Output Compare Control Register 2 143

Timer Output Compare Value Register—High Byte

145

Timer Output Compare Value Register—Low Byte

144

Timer Port Pin Allocation 129

Timer Registers 130

Timer Reload Register—High Byte 139

Timer Reload Register—Low Byte 138

TMS 262, 263

TOUT0 21, 129

TOUT1 21, 129

Trace buffer memory 261

Trace history buffer 261

Transferring Data 215

transmit shift register 176, 185, 188, 192

Transmit Shift Register, SPI 206, 207, 208, 211,

212

Transmit, Infrared Encoder/Decoder 198

trigger-level detection logic 176

TRIGOUT 262, 264

tristate 152

TRSTN 262, 263

Tx_CLK 23

Tx_EN 23

Tx_ER 23

TxD0 11, 23

TxD1 14, 23

TxD2 23

TxD3 22

TxDMA 294

UART Baud Rate Generator Register—Low and

High Bytes 182

UART FIFO Control Register 187

UART Functional Description 176

UART Functions 176

UART Interrupt Enable Register 184

UART Interrupt Identification Register 186

UART Interrupts 178

UART Line Control Register 188

UART Line Status Register 192

eZ80F91 ASSP

Product Specification

PS027001-0707

377

UART Modem Control 177

UART Modem Control Register 191

UART Modem Status Interrupt 179

UART Modem Status Register 194

UART Receive Buffer Register 184

UART Receiver 177

UART Receiver Interrupts 178

UART Recommended Usage 179

UART Registers 183

UART Scratch Pad Register 195

UART Transmit Holding Register 183

UART Transmitter 176

UART Transmitter Interrupt 178

Universal Asynchronous Receiver/Transmitter 175

Usage, JTAG Boundary Scan 268

VBO 41, 42, 345

VBO pulse reject period 345

VBO Voltage Threshold 345

VCC 2, 42, 345

VCC ramp rate 345

VCO 270, 277

vco 277

VLAN tagged frame 313

Voltage Brown-O u t 345

Voltage Brown-Ou t Rese t 42

Voltage Controlled Oscillator 269

Voltage Controlled Oscillator, PLL 270

voltage signal, high 100

voltage, input 270

voltage, peak-to-peak 277

voltage, supply 2, 51, 213, 271, 343, 344

WAIT 1, 9, 75, 78, 81, 82

WAIT condition 112

WAIT Input Signal 69

WAIT pin, external 71

WAIT state 72, 78, 356, 357

Wait State Timing for Read Operations 356

Wait State Timing for Write Operations 357

WAIT states 58, 75, 78, 87, 243

Wait States 68

Watch-Dog Timer 1, 45, 115, 116, 242

Watch-Dog Timer Control Register 117

Watch-Dog Timer Operation 116

Watch-Dog Timer Registers 117

Watch-Dog Timer Reset Register 120

Watch-Dog Timer time-out 41, 45, 46

wcOl 211

WCOL—see Write Collision 206, 207

WDT 41, 45, 115, 116, 117

WDT clock source 115, 116, 118

WDT oscillator 117

WDT time-out 115, 117, 118, 120

WDT time-out period 116, 119

WP 25

WP pin 97, 107, 108, 109

WR 8, 65, 68, 71, 75, 78, 352, 355

Write Collision 207

write collision 206

write collision, SPI 211

XIN input pin 339

XOUT output pin 339

Z80- 70

Z80 Bus Mode 71

ZCL 237, 240, 247

ZDA 237, 247, 262

ZDI 235, 236, 261

ZDI Address Match Registers 245

ZDI Block Read 242

ZDI Block Write 240

ZDI Break Control Register 246

ZDI Bus Control Register 253

ZDI Bus Status Register 259

ZDI Clock and Data Conventions 237

ZDI clock pin 237

ZDI data pin 237

ZDI debug control 261

eZ80F91 ASSP

Product Specification

PS027001-0707

378

ZDI Master Control Register 249

ZDI Read Memory Register 259

ZDI Read Operations 241

ZDI Read Register Low, High, and Upper 258

ZDI Read/Write Control Register 251

ZDI Read-Only Registers 244

ZDI Register Addressing 239

ZDI Register Definitions 245

ZDI Single-Bit Byte Separator 238

ZDI Single-Byte Read 241

ZDI Single-Byte Write 240

ZDI Start Condition 237

ZDI Status Register 257

ZDI Write Data Registers 250

ZDI Write Memory Register 254

ZDI Write Only Registers 243

ZDI Write Operations 240

ZDI_BUS_STAT 243, 245, 259

ZDI_BUSACK_EN 242

ZDI_BUSAcK_En 259

ZDI-Supported Protocol 236

ZDS II 235

ZiLOG Debug Interface 235, 261

ZiLOG Developer Studio II 235

PS027001-0707 Customer Support

eZ80F91 ASSP

Product Specification

379

Customer Support

For answers to technical questions about the product, documentation, or any other issues

with Zilog’s offerings, please visit Zilog’s Knowledge Base at

http://www.zilog.com/kb.

For any comments, detail technical questions, or reporting problems, please visit Zilog’s

Technical Support at http://support.zilog.com.