USER'S MANUAL
µPD750008
4 BIT SINGLE-CHIP MICROCOMPUTER
µPD750004
µPD750006
µPD750008
µPD75P0016
Document No. U10740EJ2V0UM00 (2nd edition)
(Previous No. IEU-1421)
Date Published April 1996 P
Printed in Japan
©
1995
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The export of this product from Japan is regulated by the Japanese government. To export this product may be prohibited
without governmental license, the need for which must be judged by the customer. The export or re-export of this product
from a country other than Japan may also be prohibited without a license from that country. Please call an NEC sales
representative.
The information in this document is subject to change without notice.
No part of this document may be copied or reproduced in any form or by any means without the prior written
consent of NEC Corporation. NEC Corporation assumes no responsibility for any errors which may appear in
this document.
NEC Corporation does not assume any liability for infringement of patents, copyrights or other intellectual property
rights of third parties by or arising from use of a device described herein or any other liability arising from use
of such device. No license, either express, implied or otherwise, is granted under any patents, copyrights or other
intellectual property rights of NEC Corporation or others.
While NEC Corporation has been making continuous effort to enhance the reliability of its semiconductor devices,
the possibility of defects cannot be eliminated entirely. To minimize risks of damage or injury to persons or
property arising from a defect in an NEC semiconductor device, customer must incorporate sufficient safety
measures in its design, such as redundancy, fire-containment, and anti-failure features.
NEC devices are classified into the following three quality grades:
“Standard“, “Special“, and “Specific“. The Specific quality grade applies only to devices developed based on a
customer designated “quality assurance program“ for a specific application. The recommended applications of
a device depend on its quality grade, as indicated below. Customers must check the quality grade of each device
before using it in a particular application.
Standard:Computers, office equipment, communications equipment, test and measurement equipment, audio
and visual equipment, home electronic appliances, machine tools, personal electronic equipment
and industrial robots
Special: Transportation equipment (automobiles, trains, ships, etc.), traffic control systems, anti-disaster
systems, anti-crime systems, safety equipment and medical equipment (not specifically designed
for life support)
Specific: Aircrafts, aerospace equipment, submersible repeaters, nuclear reactor control systems, life
support systems or medical equipment for life support, etc.
The quality grade of NEC devices in “Standard“ unless otherwise specified in NEC's Data Sheets or Data Books.
If customers intend to use NEC devices for applications other than those specified for Standard quality grade,
they should contact NEC Sales Representative in advance.
Anti-radioactive design is not implemented in this product.
M7 94.11
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Major Changes
Page
Description
All
The 44-pin plastic QFP package has been changed from µPD750008GB-xxx-3B4
to µPD750008GB-xxx-3BS-MTX.
The µPD75P0016 under development has been changed to the already-developed
µPD75P0016.
The input withstand voltage at ports 4 and 5 during open drain has been changed from
12 V to 13 V.
Preface
p.4
English-version document numbers have been added to "Related documents."
The format of the table in Section 1.3 has been changed.
p.45
The caution in using Mk II mode has been added in Section 4.1.1.
p.85
The description for the mask option when using the feedback resistor has been added in
(6) in Section 5.2.2.
p.187
The description for the interrupt enable flag has been added in Section 6.3.
Table 6-4 has been added in Section 6.6.
p.198
p.233
Section 9.4 has been added.
p.235
Chapter 10 has been added.
p.237–298
p.241
The operand @rpa has been changed to @rpa1 in Section 11.
@rpa1 has been added in the table in (1) in Section 11.2.
The title of Section 11.4 has been modified to conform to that of Section 11.2.
p.264
p.301
Appendix B
Supported OS versions have been upgraded.
p.321
Appendix F has been added.
The mark shows major revised points.
*
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PREFACE
Readers
This manual is intended for engineers who want to learn the capabilities of the
µPD750004,µPD750006,µPD750008,andµPD75P0016todevelopapplicationsystems
based on them.
Purpose
The purpose of this manual is to help users understand the hardware capabilities (shown
below) of the µPD750004, µPD750006, µPD750008, and µPD75P0016.
Configuration
This manual is roughly divided as follows:
• General
• Pin functions
• Architecture feature and memory map
• Internal CPU functions
• Peripheral hardware functions
• Interrupt and test functions
• Standby function
• Reset function
• Writing to and verifying program memory (PROM)
• Mask option
• Instruction set
Guidance
Readers of this manual should have general knowledge of the electronics, logical circuit,
and microcomputer fields.
• For users who have used the µPD75008:
–> See Appendix A to check for any difference in the functions and read the
explanation of those differences.
• To check the functions of an instruction in detail when the reader knows its
mnemonics:
–> See the instruction index in Appendix D.
• To check the functions of specific internal circuits, etc.:
–> See Appendix E.
• To understand the overall functions of the µPD750004, µPD750006, µPD750008,
and µPD75P0016:
–> Read through all chapters sequentially.
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Notation
Data bit significance
: Higher-order bits on the left side
Lower-order bits on the right side
Active low
: xxx (Pin and signal names are overscored.)
: Low-order address on the upper side
High-order address on the lower side
: Explanation of an indicated part of text
: Information requesting the user's special attention
: Supplementary information
Memory map address
Note
Caution
Remark
Important and emphasized matter : Described in bold face
Numeric value : Binary .................. xxxx or xxxxB
Decimal ............... xxxx
Hexadecimal ....... xxxxH
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Related documents
Some documents are preliminary editions, but they are not so specified in the tables
below.
*
Documents related to devices
Document Number
Japanese
U10738J
U10328J
U10740J (This manual) IEU-1421
Document Name
English
IC-3647
To be prepared
µPD750004, 750006, 750008 Data Sheet
µPD75P0016 Data Sheet
µPD750008 User’s Manual
µPD750008 Instruction List
75XL Series Selection Guide
IEM-5593
U10453J
—
U10453E
Documents related to development tools
Document Number
Document Name
Japanese
EEU-846
English
Hardware IE-75000-R/IE-75001-R User’s Manual
IE-75300-R-EM User’s Manual
EP-75008CU-R User’s Manual
EP-75008GB-R User's Manual
PG-1500 User’s Manual
EEU-1416
EEU-1493
EEU-1317
EEU-1305
EEU-1335
EEU-1346
EEU-1363
EEU-1291
U10540E
EEU-951
EEU-699
EEU-698
EEU-651
EEU-731
EEU-730
EEU-704
EEU-5008
Software RA75X Assembler Package User’s
Manual
Operation
Language
TM
PG-1500 Controller PC-9800 Series (MS-DOS ) Base
User’s Manual
TM
IBM PC Series (PC DOS ) Base
Other documents
Document Number
Japanese English
Document Name
Package Manual
IEI-635
IEI-1213
IEI-1207
IEI-1209
Semiconductor Device Mounting Technology Manual
Quality Grade on NEC Semiconductor Devices
Reliability and Quality Control of NEC Semiconductor Devices
Electrostatic Discharge (ESD) Test
IEI-616
IEI-620
IEI-5068
MEM-539
MEI-603
MEI-604
—
—
MEI-1202
—
Semiconductor Device Quality Guarantee Guide
Microcontroller-Related Products Guide - by third parties
Caution The above related documents are subject to change without notice. Be sure to use the
latest edition when you design your system.
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[MEMO]
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CONTENTS
CHAPTER 1 GENERAL .........................................................................................................................
1
1.1 FUNCTION OVERVIEW .........................................................................................
1.2 ORDERING INFORMATION...................................................................................
1.3 DIFFERENCES AMONG SUBSERIES PRODUCTS.............................................
1.4 BLOCK DIAGRAM ..................................................................................................
1.5 PIN CONFIGURATION (TOP VIEW) .....................................................................
2
3
4
5
6
CHAPTER 2 PIN FUNCTIONS ..............................................................................................................
9
2.1 PIN FUNCTIONS OF THE µPD750008 .................................................................
9
2.2 PIN FUNCTIONS .................................................................................................... 12
2.2.1 P00-P03 (PORT0)...................................................................................... 12
P10-P13 (PORT1)...................................................................................... 12
2.2.2 P20-P23 (PORT2)...................................................................................... 13
P30-P33 (PORT3)...................................................................................... 13
P40-P43 (PORT4), P50-P53 (PORT5) ..................................................... 13
P60-P63 (PORT6), P70-P73 (PORT7) ..................................................... 13
2.2.3 P80, P81 (PORT8)..................................................................................... 13
2.2.4 TI0 .............................................................................................................. 13
2.2.5 PTO0, PTO1 .............................................................................................. 13
2.2.6 PCL............................................................................................................. 14
2.2.7 BUZ ............................................................................................................ 14
2.2.8 SCK, SO/SB0, SI/SB1 ............................................................................... 14
2.2.9 INT4............................................................................................................ 14
2.2.10 INT0, INT1 ................................................................................................ 14
2.2.11 INT2 .......................................................................................................... 15
2.2.12 KR0-KR3................................................................................................... 15
KR4-KR7................................................................................................... 15
2.2.13 X1, X2 ....................................................................................................... 15
2.2.14 XT1, XT2................................................................................................... 16
2.2.15 RESET ...................................................................................................... 16
2.2.16
2.2.17
V
V
......................................................................................................................................... 16
......................................................................................................................................... 16
DD
SS
2.2.18 IC (for the µPD750004, µPD750006, and µPD750008 only).................. 17
2.2.19 (for the µPD75P0016 only) ............................................................... 17
V
PP
2.2.20 MD0-MD3 (for the µPD75P0016 only)..................................................... 17
2.3 PIN INPUT/OUTPUT CIRCUITS ............................................................................ 18
2.4 CONNECTION OF UNUSED PINS ........................................................................ 20
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CHAPTER 3 FEATURES OF THE ARCHITECTURE AND MEMORY MAP ....................................... 21
3.1 DATA MEMORY BANK STRUCTURE AND ADDRESSING MODES .................. 21
3.1.1 Data Memory Bank Structure .................................................................... 21
3.1.2 Data Memory Addressing Modes .............................................................. 23
3.2 GENERAL REGISTER BANK CONFIGURATION ................................................. 34
3.3 MEMORY-MAPPED I/O .......................................................................................... 39
CHAPTER 4 INTERNAL CPU FUNCTIONS ......................................................................................... 45
4.1 Mk I MODE/Mk II MODE SWITCH FUNCTIONS................................................... 45
4.1.1 Differences between Mk I Mode and Mk II Mode..................................... 45
4.1.2 Setting of the Stack Bank Selection Register (SBS) ................................ 46
4.2 PROGRAM COUNTER (PC) ................................................................................. 47
4.3 PROGRAM MEMORY (ROM) ................................................................................ 48
4.4 DATA MEMORY (RAM) .......................................................................................... 53
4.4.1 Data Memory Configuration....................................................................... 53
4.4.2 Specification of a Data Memory Bank....................................................... 54
4.5 GENERAL REGISTER............................................................................................ 56
4.6 ACCUMULATOR..................................................................................................... 57
4.7 STACK POINTER (SP) AND STACK BANK SELECT REGISTER (SBS)............ 58
4.8 PROGRAM STATUS WORD (PSW) ...................................................................... 62
4.9 BANK SELECT REGISTER (BS) ........................................................................... 65
CHAPTER 5 PERIPHERAL HARDWARE FUNCTIONS ...................................................................... 67
5.1 DIGITAL I/O PORTS............................................................................................. 67
5.1.1 Types, Features, and Configurations of Digital I/O Ports ........................ 68
5.1.2 I/O Mode Setting........................................................................................ 74
5.1.3 Digital I/O Port Manipulation Instructions ................................................. 76
5.1.4 Digital I/O Port Operation .......................................................................... 79
5.1.5 Specification of Bilt-in Pull-Up Resistors .................................................. 81
5.1.6 I/O Timing of Digital I/O Ports ................................................................... 82
5.2 CLOCK GENERATOR ............................................................................................ 84
5.2.1 Clock Generator Configuration.................................................................. 84
5.2.2 Functions and Operations of the Clock Generator ................................... 85
5.2.3 System Clock and CPU Clock Setting ...................................................... 94
5.2.4 Clock Output Circuit................................................................................... 96
5.3 BASIC INTERVAL TIMER/WATCHDOG TIMER ................................................... 99
5.3.1 Configuration of the Basic Interval Timer/Watchdog Timer ..................... 99
5.3.2 Basic Interval Timer Mode Register (BTM) .............................................. 99
5.3.3 Watchdog Timer Enable Flag (WDTM) ..................................................... 101
5.3.4 Operation of the Basic Interval Timer ....................................................... 101
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5.3.5 Operation of the Watchdog Timer ............................................................. 102
5.3.6 Other Functions ......................................................................................... 103
5.4 CLOCK TIMER ........................................................................................................ 105
5.4.1 Configuration of the Clock Timer .............................................................. 106
5.4.2 Clock Mode Register ................................................................................. 106
5.5 TIMER/EVENT COUNTER ..................................................................................... 108
5.5.1 Configuration of Timer/Event Counter ...................................................... 108
5.5.2 8-Bit Timer/Event Counter Mode Operation ............................................. 114
5.5.3 Notes on Timer/Event Counter Applications............................................. 120
5.6 SERIAL INTERFACE .............................................................................................. 123
5.6.1 Serial Interface Functions.......................................................................... 123
5.6.2 Configuration of Serial Interface ............................................................... 124
5.6.3 Register Functions ..................................................................................... 127
5.6.4 Operation Halt Mode.................................................................................. 135
5.6.5 Three-Wire Serial I/O Mode Operations ................................................... 137
5.6.6 Two-Wire Serial I/O Mode ......................................................................... 144
5.6.7 SBI Mode Operation .................................................................................. 150
5.6.8 Manipulation of SCK Pin Output ............................................................... 179
5.7 BIT SEQUENTIAL BUFFER ................................................................................... 181
CHAPTER 6 INTERRUPT AND TEST FUNCTIONS .............................................................................. 183
6.1 CONFIGURATION OF THE INTERRUPT CONTROL CIRCUIT........................... 183
6.2 TYPES OF INTERRUPT SOURCES AND VECTOR TABLES ............................. 185
6.3 VARIOUS DEVICES TO CONTROL INTERRUPT FUNCTIONS.......................... 187
6.4 INTERRUPT SEQUENCE ...................................................................................... 195
6.5 MULTIPLE INTERRUPT PROCESSING CONTROL............................................. 196
6.6 PROCESSING OF INTERRUPTS SHARING A VECTOR ADDRESS ................. 198
6.7 MACHINE CYCLES FOR STARTING INTERRUPT PROCESSING .................... 200
6.8 EFFECTIVE USE OF INTERRUPTS ..................................................................... 202
6.9 INTERRUPT APPLICATIONS ................................................................................ 202
6.10 TEST FUNCTION ................................................................................................. 210
6.10.1 Test Sources .......................................................................................... 210
6.10.2 Hardware to Control Test Functions ..................................................... 210
CHAPTER 7 STANDBY FUNCTION ..................................................................................................... 215
7.1 SETTING OF STANDBY MODES AND OPERATION STATUS ........................... 216
7.2 RELEASE OF THE STANDBY MODES................................................................. 217
7.3 OPERATION AFTER A STANDBY MODE IS RELEASED ................................... 219
7.4 SELECTION OF A MASK OPTION........................................................................ 220
7.5 APPLICATIONS OF THE STANDBY MODES....................................................... 220
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CHAPTER 8 RESET FUNCTION ........................................................................................................... 225
CHAPTER 9 WRITING TO AND VERIFYING PROGRAM MEMORY (PROM) ................................... 229
9.1 OPERATING MODES WHEN WRITING TO AND VERIFYING
THE PROGRAM MEMORY .................................................................................... 230
9.2 WRITING TO THE PROGRAM MEMORY ............................................................. 230
9.3 READING THE PROGRAM MEMORY .................................................................. 232
9.4 SCREENING OF ONE-TIME PROM ...................................................................... 233
*
*
CHAPTER 10 MASK OPTION ............................................................................................................... 235
10.1 PIN......................................................................................................................... 235
10.2 MASK OPTION OF STANDBY FUNCTION......................................................... 235
10.3 MASK OPTION FOR FEEDBACK RESISTOR OF SUBSYSTEM CLOCK ........ 236
CHAPTER 11 INSTRUCTION SET .......................................................................................................... 237
11.1 UNIQUE INSTRUCTIONS .................................................................................... 237
11.1.1 GETI Instruction ..................................................................................... 237
11.1.2 Bit Manipulation Instructions .................................................................. 238
11.1.3 String-Effect Instructions ........................................................................ 238
11.1.4 Number System Conversion Instructions .............................................. 239
11.1.5 Skip Instructions and the Number of Machine Cycles Required
for a Skip ............................................................................................... 240
11.2 INSTRUCTION SET AND OPERATION .............................................................. 241
11.3 INSTRUCTION CODES OF EACH INSTRUCTION ............................................ 258
11.4 FUNCTIONS AND APPLICATIONS OF THE INSTRUCTIONS .......................... 264
11.4.1 Transfer Instructions .............................................................................. 264
11.4.2 Table Reference Instructions ................................................................. 270
11.4.3 Bit Transfer Instructions ......................................................................... 273
11.4.4 Arithmetic/Logical Instructions ............................................................... 273
11.4.5 Accumulator Manipulation Instructions.................................................. 279
11.4.6 Increment/Decrement Instructions ......................................................... 279
11.4.7 Compare Instructions ............................................................................. 280
11.4.8 Carry Flag Manipulation Instructions ..................................................... 281
11.4.9 Memory Bit Manipulation Instructions ................................................... 282
11.4.10 Branch Instructions .............................................................................. 284
11.4.11 Subroutine Stack Control Instructions ................................................. 289
11.4.12 Interrupt Control Instructions ............................................................... 293
11.4.13 I/O Instructions ..................................................................................... 294
11.4.14 CPU Control Instructions ..................................................................... 295
11.4.15 Special Instructions .............................................................................. 295
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APPENDIX A FUNCTIONS OF THE µPD75008, µPD750008, AND µPD75P0016 ............................ 299
APPENDIX B DEVELOPMENT TOOLS ................................................................................................ 301
APPENDIX C MASKED ROM ORDERING PROCEDURE................................................................... 309
APPENDIX D INSTRUCTION INDEX .................................................................................................... 311
D.1 INSTRUCTION INDEX (BY FUNCTION) .............................................................. 311
D.2 INSTRUCTION INDEX (ALPHABETICAL ORDER) ............................................. 314
APPENDIX E HARDWARE INDEX .......................................................................................................... 317
E.1 HARDWARE INDEX (ALPHABETICAL ORDER WITH RESPECT TO THE .......
HARDWARE NAME).............................................................................................. 317
E.2 HARDWARE INDEX (ALPHABETICAL ORDER WITH RESPECT TO THE
HARDWARE SYMBOL) ......................................................................................... 319
APPENDIX F REVISION HISTORY ......................................................................................................... 321
*
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LIST OF FIGURES (1/4)
Figure No.
2-1
Title
Page
Pin Input/Output Circuits .................................................................................................. 18
3-1
3-2
3-3
3-4
3-5
3-6
3-7
Use of MBE = 0 Mode and MBE = 1 Mode ..................................................................... 22
Data Memory Organization and Addressing Range of Each Addressing Mode ............ 24
Updating Static RAM Addresses...................................................................................... 28
Example of Register Bank Selection ............................................................................... 35
General Register Configuration (4-bit Processing) ......................................................... 37
General Register Configuration (8-bit Processing) ......................................................... 38
µPD750008 I/O Map ......................................................................................................... 40
4-1
Stack Bank Selection Register Format ............................................................................ 46
Program Counter Organization ........................................................................................ 47
Program Memory Map (in µPD750004) ........................................................................... 49
Program Memory Map (in µPD750006) ........................................................................... 50
Program Memory Map (in µPD750008) ........................................................................... 51
Program Memory Map (in µPD75P0016)......................................................................... 52
Data Memory Map ............................................................................................................ 54
General Register Format .................................................................................................. 56
Register Pair Format ........................................................................................................ 57
Accumulator ...................................................................................................................... 57
Format of Stack Pointer and Stack Bank Select Register .............................................. 59
Data Saved to the Stack Memory (Mk I Mode) ............................................................... 59
Data Restored from the Stack Memory (Mk I Mode) ...................................................... 60
Data Saved to the Stack Memory (Mk II Mode) .............................................................. 60
Data Restored from the Stack Memory (Mk II Mode) ..................................................... 61
Program Status Word Format .......................................................................................... 62
Bank Select Register Format ........................................................................................... 65
4-2
4-3
4-4
4-5
4-6
4-7
4-8
4-9
4-10
4-11
4-12
4-13
4-14
4-15
4-16
4-17
5-1
5-2
5-3
5-4
5-5
5-6
5-7
5-8
Data Memory Addresses of Digital Ports......................................................................... 67
Configurations of Ports 0 and 1 ....................................................................................... 69
Configurations of Ports 2 and 7 ....................................................................................... 70
Configurations of Ports 3n and 6n (n = 0 to 3)................................................................ 71
Configurations of Ports 4 and 5 ....................................................................................... 72
Configuration of Port 8 ..................................................................................................... 73
Formats of Port Mode Registers ...................................................................................... 75
Pull-Up Resistor Specification Register Format .............................................................. 82
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LIST OF FIGURES (2/4)
Figure No.
Title
Page
5-9
I/O Timing Chart of Digital I/O Ports ................................................................................ 82
ON Timing Chart of Built-in Pull-Up Resistor Connected by Software.......................... 83
Block Diagram of the Clock Generator ............................................................................ 84
Format of the Processor Clock Control Register............................................................. 87
Format of the System Clock Control Register ................................................................. 88
External Circuit for the Main System Clock Oscillator .................................................... 89
External Circuit for the Subsystem Clock Oscillator........................................................ 89
Examples of Oscillator Connections Which Should Be Avoided .................................... 90
Subsystem Clock Oscillator.............................................................................................. 92
Sub-Oscillator Control Register (SOS) Format ............................................................... 93
Changing the System Clock and CPU Clock................................................................... 95
Configuration of the Clock Output Circuit ........................................................................ 96
Format of the Clock Output Mode Register ..................................................................... 97
Application to Remote Control Output ............................................................................. 98
Block Diagram of the Basic Interval Timer/Watchdog Timer .......................................... 99
Format of the Basic Interval Timer Mode Register ......................................................... 100
Format of the Watchdog Timer Enable Flag (WDTM)..................................................... 101
Block Diagram of the Clock Timer ................................................................................... 106
Clock Mode Register Format ........................................................................................... 107
Block Diagram of the Timer/Event Counter (Channel 0) ................................................ 109
Block Diagram of the Timer Counter (Channel 1) ........................................................... 110
Timer/Event Counter Mode Register (Channel 0) Format .............................................. 112
Timer Counter Mode Register (Channel 1) Format......................................................... 113
Timer/Event Counter Output Enable Flag Format ........................................................... 114
Timer/Event Counter Mode Register Setup..................................................................... 115
Timer/Event Counter Output Enable Flag Setup............................................................. 116
Configuration of Timer/Event Counter ............................................................................. 118
Count Operation Timing ................................................................................................... 119
Error at the Start of the Timer .......................................................................................... 120
Example of the SBI System Configuration ...................................................................... 124
Block Diagram of the Serial Interface .............................................................................. 125
Format of Serial Operation Mode Register (CSIM) ......................................................... 127
Format of Serial Bus Interface Control Register (SBIC) ................................................. 131
Peripheral Hardware of Shift Register ............................................................................. 134
Example of Three-Wire Serial I/O System Configuration................................................ 137
Timing of Three-Wire Serial I/O Mode ............................................................................. 140
5-10
5-11
5-12
5-13
5-14
5-15
5-16
5-17
5-18
5-19
5-20
5-21
5-22
5-23
5-24
5-25
5-26
5-27
5-28
5-29
5-30
5-31
5-32
5-33
5-34
5-35
5-36
5-37
5-38
5-39
5-40
5-41
5-42
5-43
5-44
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LIST OF FIGURES (3/4)
Figure No.
Title
Page
5-45
5-46
5-47
5-48
5-49
5-50
5-51
5-52
5-53
5-54
5-55
5-56
5-57
5-58
5-59
5-60
5-61
5-62
5-63
5-64
5-65
5-66
5-67
5-68
5-69
5-70
5-71
5-72
5-73
5-74
5-75
5-76
5-77
5-78
5-79
5-80
Operations of RELT and CMDT ....................................................................................... 141
Transfer Bit Switching Circuit ........................................................................................... 141
Example of Two-Wire Serial I/O System Configuration .................................................. 144
Timing of Two-Wire Serial I/O Mode................................................................................ 147
Operations of RELT and CMDT ....................................................................................... 148
Example of SBI System Configuration............................................................................. 150
Timing of SBI Transfer ..................................................................................................... 152
Bus Release Signal .......................................................................................................... 153
Command Signal .............................................................................................................. 153
Address ............................................................................................................................. 153
Slave Selection Using an Address................................................................................... 154
Command.......................................................................................................................... 154
Data................................................................................................................................... 154
Acknowledge Signal ......................................................................................................... 155
Busy and Ready Signals .................................................................................................. 156
Operations of RELT, CMDT, RELD, and CMDD (Master) .............................................. 161
Operations of RELT, CMDT, RELD, and CMDD (Slave) ................................................ 161
Operation of ACKT ........................................................................................................... 162
Operation of ACKE ........................................................................................................... 162
Operation of ACKD ........................................................................................................... 163
Operation of BSYE ........................................................................................................... 164
Pin Configuration .............................................................................................................. 167
Address Transfer Operation from Master Device to Slave Device (WUP = 1) .............. 169
Command Transfer Operation from Master Device to Slave Device.............................. 170
Data Transfer Operation from Master Device to Slave Device....................................... 171
Data Transfer Operation from Slave Device to Master Device....................................... 172
Example of Serial Bus Configuration ............................................................................... 174
Transfer Format of the READ Command ........................................................................ 175
Transfer Format of the WRITE and END Commands ..................................................... 176
Transfer Format of the STOP Command......................................................................... 176
Transfer Format of the STATUS Command .................................................................... 177
Status Format of the STATUS Command ....................................................................... 177
Transfer Format of the RESET Command ...................................................................... 178
Transfer Format of the CHGMST Command................................................................... 178
Master and Slave Operation in Case of Error ................................................................. 179
SCK/P01 Pin Circuit Configuration .................................................................................. 180
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LIST OF FIGURES (4/4)
Figure No.
5-81
Title
Page
Format of the Bit Sequential Buffer ................................................................................. 181
6-1
6-2
6-3
6-4
6-5
6-6
6-7
6-8
6-9
6-10
6-11
Block Diagram of Interrupt Control Circuit ....................................................................... 184
Interrupt Vector Table....................................................................................................... 185
Interrupt Priority Specification Register ........................................................................... 189
Configurations of the INT0, INT1, and INT4 Circuits ...................................................... 191
I/O Timing of a Noise Eliminator ...................................................................................... 192
Format of Edge Detection Mode Registers ..................................................................... 193
Interrupt Sequence ........................................................................................................... 195
Multiple Interrupt Processing by a High-Order Interrupt ................................................. 196
Multiple Interrupt Processing by Changing the Interrupt Status Flags ........................... 197
Block Diagram of the INT2 and KR0 to KR7 Circuits...................................................... 212
Format of INT2 Edge Detection Mode Register (IM2) .................................................... 213
7-1
7-2
Standby Mode Release Operation ................................................................................... 218
Wait Time When the STOP Mode Is Released ............................................................... 219
8-1
8-2
Configuration of Reset Functions..................................................................................... 225
Reset Operation by Generation of RESET Signal .......................................................... 225
B-1
B-2
Drawings of the EV-9200G-44 (Reference)..................................................................... 306
Recommended Pattern on Boards for the EV-9200G-44 (Reference) ........................... 307
- ix -
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LIST OF TABLES (1/2)
Table No.
1-1
Title
Page
Features of the Products ..................................................................................................
1
2-1
2-2
2-3
Digital I/O Port Pins ..........................................................................................................
9
Non-Port Pin Functions .................................................................................................... 11
Connection of Unused Pins.............................................................................................. 20
3-1
3-2
3-3
Addressing Modes ............................................................................................................ 25
Register Bank to Be Selected with the RBE and RBS.................................................... 34
Recommended Use of Register Banks with Normal Routines and
Interrupt Routines ............................................................................................................. 34
Addressing Modes Applicable to Peripheral Hardware Operation.................................. 39
3-4
4-1
4-2
4-3
4-4
4-5
4-6
Differences between Mk I Mode and Mk II Mode............................................................ 45
Stack Area to Be Selected by the SBS ........................................................................... 58
PSW Flags Saved/Restored in Stack Operation ............................................................. 62
Carry Flag Manipulation Instructions ............................................................................... 63
Information Indicated by the Interrupt Status Flag .......................................................... 64
Register Bank to Be Selected with the RBE and RBS.................................................... 66
5-1
5-2
5-3
5-4
5-5
5-6
5-7
5-8
5-9
5-10
Types and Features of Digital Ports ................................................................................ 68
I/O Pin Manipulation Instructions ..................................................................................... 78
Operations by I/O Port Manipulation Instructions............................................................ 80
Specification of Built-in Pull-Up Resistors ....................................................................... 81
Maximum Time Required to Change the System Clock and CPU Clock ....................... 94
Resolution and Longest Setup Time................................................................................ 117
Serial Clock Selection and Application (In the Three-Wire Serial I/O Mode)................. 140
Serial Clock Selection and Application (In the Two-Wire Serial I/O Mode) ................... 148
Serial Clock Selection and Application (In the SBI Mode).............................................. 160
Various Signals Used in the SBI Mode............................................................................ 165
6-1
6-2
6-3
6-4
6-5
6-6
Interrupt Sources .............................................................................................................. 185
Set Signals for Interrupt Request Flags........................................................................... 188
Interrupt Processing Statuses of IST0 and IST1 ............................................................. 194
Identifying Interrupt Sharing Vector Table Address ........................................................ 198
Test Source....................................................................................................................... 210
Signals Setting Test Request Flags................................................................................. 210
- x -
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LIST OF TABLES (2/2)
Table No.
Title
Page
7-1
7-2
Operation Statuses in the Standby Mode ........................................................................ 216
Selection of a Wait Time with BTM.................................................................................. 219
8-1
Status of the Hardware after a Reset .............................................................................. 226
Selecting Mask Option of Pin ........................................................................................... 235
10-1
- xi -
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[MEMO]
- xii -
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CHAPTER 1 GENERAL
1
The µPD750004, µPD750006, µPD750008, and µPD75P0016 are 75XL series 4-bit single-chip microcom-
puters. The 75XL series is a successor of the 75X series consisting of many products. These µPD750004,
µPD750006, µPD750008, and µPD75P0016 are collectively called the µPD750008 subseries.
The 75XL series takes over the CPUs of the 75X series, realizing a wide range of operating voltages and
high-speed operation. In addition to having upward compatibility with existing products, the 75XL series is
best suited for battery-driven applications.
The µPD750004, µPD750006, µPD750008, and µPD75P0016 have the following features:
• Operable on low voltage: V
= 2.2 to 5.5 V
DD
• Switchable instruction execution times (useful for high-speed operation and power saving)
0.95 µs, 1.91 µs, 3.81 µs, 15.3 µs (at 4.19 MHz)
0.67 µs, 1.33 µs, 2.67 µs, 10.7 µs (at 6.0 MHz)
122 µs (at 32.768 kHz)
• Enhanced timers: 4 channels
• Easy replacement (The functions and instructions of the µPD75008 are taken over.)
The 75XL series comes in four models, according to the size and type of program memory (see
Table 1-1).
Table 1-1. Features of the Products
Model
Program memory (ROM)
Remarks
µPD750004
µPD750006
µPD750008
µPD75P0016
4096 x 8 bits
6144 x 8 bits
8192 x 8 bits
16384 x 8 bits
Masked ROM
One-time PROM
The µPD75P0016, having the electrically programmable one-time PROM, is pin-compatible with the
µPD750004, µPD750006, and µPD750008. It is suitable for small-scale production or prototype production
in system development.
Applications
• Consumer electronics
VCR, audio equipment (such as CD players), remote controller, etc.
• Others
Telephone, camera, etc.
Remark This manual will explain only the µPD750008 when the µPD750008, µPD750004,
µPD750006, and µPD75P0016 are functionally the same. Users of the µPD750004, µPD750006,
orµPD75P0016shouldreadµPD750008asreferringtoµPD750004,µPD750006,orµPD75P0016.
1
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µPD750008 USER'S MANUAL
1.1 FUNCTION OVERVIEW
Item
Function
Instruction execution
time
• 0.95, 1.91, 3.81, 15.3 µs (when the main system clock operates at 4.19 MHz)
• 0.67, 1.33, 2.67, 10.7 µs (when the main system clock operates at 6.0 MHz)
• 122 µs (when the subsystem clock operates at 32.768 kHz)
Internal memory ROM 4096 x 8 bits (µPD750004)
6144 x 8 bits (µPD750006)
8192 x 8 bits (µPD750008)
16384 x 8 bits (µPD75P0016)
RAM 512 x 4 bits
General register
I/O port
• When operating in 4 bits: 8 x 4 banks
• When operating in 8 bits: 4 x 4 banks
34
8
CMOS input pins
Can incorporate 25 pull-up resistors
that are specified with the software.
18
CMOS I/O pins
Four pins can directly drive
the LED.
8
N-ch open-drain I/O pins
Eight pins can directly drive
the LED.
Can withstand 13 V.
Can incorporate pull-up resistors that
are specified with the mask option.
*
Note
Timer
4
• Timer/event counter: 1 channel
• Timer counter: 1 channel
• Basic interval timer/watchdog timer: 1 channel
• Clock timer: 1 channel
Serial interface
• Three-wire serial I/O mode (switchable between the start LSB and the start MSB)
• Two-wire serial I/O mode
• SBI mode
Bit sequential buffer
Clock output
16 bits
• F, 524 kHz, 262 kHz, 65.5 kHz (when the main system clock operates at 4.19 MHz)
• F, 750 kHz, 375 kHz, 93.7 kHz (when the main system clock operates at 6.0 MHz)
Vectored interrupt
Test input
External: 3, Internal: 4
External: 1, Internal: 1
System clock oscillator • Ceramic or crystal oscillator for the main system clock
• Crystal oscillator for the subsystem clock
Standby function
STOP/HALT mode
T =–40°C to +85°C
Operating ambient
temperature
A
Supply voltage
Package
V
= 2.2 to 5.5 V
DD
42-pin plastic shrink DIP (600 mil)
44-pin plastic QFP (10 x 10 mm)
Note The N-ch open-drain I/O port pins of the µPD75P0016 are not connected to pull-up resistors by mask
*
option, and are always open.
2
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CHAPTER 1 GENERAL
1.2 ORDERING INFORMATION
Part number
Package
On-chip ROM
µPD750004CU-xxx
42-pin plastic shrink DIP (600 mil)
44-pin plastic QFP (10 x 10 mm)
42-pin plastic shrink DIP (600 mil)
44-pin plastic QFP (10 x 10 mm)
42-pin plastic shrink DIP (600 mil)
44-pin plastic QFP (10 x 10 mm)
42-pin plastic shrink DIP (600 mil)
44-pin plastic QFP (10 x 10 mm)
Masked ROM
Masked ROM
Masked ROM
Masked ROM
Masked ROM
Masked ROM
One-time PROM
One-time PROM
Note
µPD750004GB-xxx-3BS-MTX
*
*
*
*
µPD750006CU-xxx
Note
µPD750006GB-xxx-3BS-MTX
µPD750008CU-xxx
Note
µPD750008GB-xxx-3BS-MTX
µPD75P0016CU
Note
µPD75P0016GB-3BS-MTX
Note Code orders on and after April 1, 1996 can be accepted.
Remark xxx is a ROM code number.
3
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µPD750008 USER'S MANUAL
1.3 DIFFERENCES AMONG SUBSERIES PRODUCTS
Item
Program counter
µPD750004
12 bits
µPD750006
13 bits
µPD750008
µPD75P0016
14 bits
Program memory (byte)
Masked ROM
4096
Masked ROM
6144
Masked ROM
8192
One-time PROM
16384
Data memory (x 4 bits)
512
Mask
Pull-up resistors at
Incorporated
None
option
ports 4 and 5
(Whether to incorporate pull-up resistors can
be specified.)
(Cannot be
incorporated.)
Wait time during
RESET
Available
Not available
(Fixed to 2 /f .)
17
15
Note
15
(Can be selected from 2 /f or 2 /f .)
X
X
X
Selection to use
feedback resistors
for subsystem clock
Yes
No
*
(Whether to enable feedback resistors can
be specified.)
(Use of feedback
resistors is factory-set)
Pin
6-9 (CU)
23-26 (GB)
20 (CU)
P33-30
P33/MD3-P30/MD0
connection
IC
V
PP
38 (GB)
Others
Noise immunity and noise radiation vary with the circuit scale and mask
layout.
17
Note 2 /f (21.8 ms at 6.0 MHz, 31.3 ms at 4.19 MHz)
X
15
2 /f (5.46 ms at 6.0 MHz, 7.81 ms at 4.19 MHz)
X
Caution The noise immunity and noise radiation of the PROM model differ from those of the mask
ROM model. If you replace the PROM model with the ROM model of the course of
experimental production to mass production, perform thorough evaluation by using the
CS model (not ES model) of the mask ROM model.
*
4
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CHAPTER 1 GENERAL
1.4 BLOCK DIAGRAM
Port 0
Port 1
Port 2
Port 3
Port 4
Port 5
Port 6
Port 7
Port 8
4
4
4
4
4
4
4
4
2
P00 - P03
P10 - P13
Basic interval timer/
watchdog timer
RESET
INTBT
Program
CY
SP
ALU
counterNote 1
SBS
TI0
Timer/event
counter
P20 - P23
PTO0
BANK
TOUT0 INTT0
P30 - P33
P30/MD0 -
Note 3
General register
(
)
P33/MD3
Timer counter
INTT1
PTO1
BUZ
ROMNote 2
program
memory
Decode and
control
P40 - P43
RAM
data memory
512 x 4 bits
Wach timer
INTW
P50 - P53
SI/SB1
SO/SB0
SCK
P60 - P63
P70 - P73
Clocked serial
interface
fX
/2N
CPU clock
TOUT0
INTCSI
Clock generator
Clock output
control
Standby
control
INT0
INT1
INT2
INT4
Clock divider
Sub
Main
P80, P81
Interrupt
control
KR0 - KR7
PCL/P22
XT1 XT2
X1 X2
Bit sequential
buffer (16)
IC
VDD
VSS RESET
(VPP)Note 3
Notes 1. The program counter for the µPD750004 consists of 12 bits, 13 bits for the µPD750006 and
µPD750008, and 14 bits for the µPD75P0016.
2. The ROM capacity depends on the product.
3. ( ) : µPD75P0016
5
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µPD750008 USER'S MANUAL
1.5 PIN CONFIGURATION (TOP VIEW)
(1) 42-pin plastic shrink DIP (600 mil)
µPD750004CU-XXX
µPD750006CU-XXX
µPD750008CU-XXX
µPD75P0016CU
VSS
XT1
XT2
1
42
41
40
39
38
37
36
35
34
33
32
31
30
29
28
27
26
25
24
23
22
P40
2
P41
RESET
3
P42
X1
4
P43
X2
5
P50
P33 (/MD3)
P32 (/MD2)
P31 (/MD1)
P30 (/MD0)
P81
6
P51
7
P52
8
P53
9
P60/KR0
P61/KR1
P62/KR2
P63/KR3
P70/KR4
P71/KR5
P72/KR6
P73/KR7
P20/PTO0
P21/PTO1
P22/PCL
P23/BUZ
10
11
12
13
14
15
16
17
18
19
20
21
P80
SI/SB1/P03
SO/SB0/P02
SCK/P01
INT4/P00
TI0/P13
INT2/P12
INT1/P11
INT0/P10
IC (VPP)Note
VDD
Note Connect IC (V ) to V , keeping the wiring as short as possible.
PP
DD
Remark ( ) : µPD75P0016.
6
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CHAPTER 1 GENERAL
(2) 44-pin plastic QFP (10 x 10 mm)
µPD750004GB-XXX-3BS-MTX
µPD750006GB-XXX-3BS-MTX
µPD750008GB-XXX-3BS-MTX
µPD75P0016GB-3BS-MTX
44 43 42 41 40 39 38 37 36 35 34
33
1
P72/KR6
P71/KR5
P70/KR4
P63/KR3
P62/KR2
P61/KR1
P60/KR0
P53
P13/TI0
2
32
31
30
29
28
27
26
25
24
23
P00/INT4
P01/SCK
P02/SO/SB0
P03/SI/SB1
P80
3
4
5
6
7
P81
8
P30 (/MD0)
P31 (/MD1)
P32 (/MD2)
P33 (/MD3)
9
P52
10
11
P51
P50
12 13 14 15 16 17 18 19 20 21 22
Note Connect IC (V ) to V , keeping the wiring as short as possible.
PP
DD
Remark ( ) : µPD75P0016.
7
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µPD750008 USER'S MANUAL
Pin name
P00-P03 : Port 0
P10-P13 : Port 1
P20-P23 : Port 2
P30-P33 : Port 3
P40-P43 : Port 4
P50-P53 : Port 5
P60-P63 : Port 6
P70-P73 : Port 7
P80-P81 : Port 8
KR0-KR7 : Key return
RESET
TI0
: Reset input
: Timer input 0
PTO0, 1 : Programmable timer output 0, 1
BUZ
PCL
: Buzzer clock
: Programmable clock
INT0, 1, 4 : External vectored interrupt 0, 1, 4
INT2
X1, 2
XT1, 2
NC
: External test input 2
: Main system clock oscillation 1, 2
: Subsystem clock oscillation 1, 2
: No connection
SCK
SI
: Serial clock
: Serial input
: Serial output
IC
: Internally connected
: Positive power supply
: Ground
V
DD
V
SS
V
PP
SO
SB0, 1 : Serial bus 0, 1
: Programming power supply
MD0-MD3 : Mode selection 0 - 3
8
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CHAPTER 2 PIN FUNCTIONS
2.1 PIN FUNCTIONS OF THE µPD750008
2
Table 2-1. Digital I/O Port Pins (1/2)
Also
used
as
I/O
Input/
output
8 bit
I/O
Upon
reset
Pin
Function
circuit
Note 1
type
P00
Input
I/O
INT4
4-bit input port (PORT0).
x
Input
B
P01
P02
P03
P10
P11
P12
P13
SCK
For P01 to P03, built-in pull-up resistors
can be connected by software in units of
3 bits.
F -A
F -B
M -C
B -C
I/O
SO/SB0
SI/SB1
INT0
I/O
Input
4-bit input port (PORT1).
x
Input
INT1
Built-in pull-up resistors can be connected
by software in units of 4 bits. Only the
INT2
TI0
P10/INT0 pin is provided with noise
elimination function.
P20
P21
P22
P23
P30
P31
P32
P33
I/O
I/O
PTO0
PTO1
PCL
4-bit I/O port (PORT2).
x
x
Input
Input
E-B
E-B
Built-in pull-up resistors can be connected
by software in units of 4 bits.
BUZ
Note 2
Note 2
Note 2
Note 2
Note 3
(MD0)
(MD1)
(MD2)
(MD3)
Programmable 4-bit I/O port (PORT3).
I/O can be specified bit by bit.
Note 3
Note 3
Note 3
Built-in pull-up resistors can be connected
by software in units of 4 bits.
Notes 1. I/O circuits enclosed in circles have a Schmitt-triggered input.
2. An LED can be driven directly.
3. ( ): µPD75P0016
9
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µPD750008 USER'S MANUAL
Table 2-1. Digital I/O Port Pins (2/2)
Also
used
as
I/O
circuit
8 bit
I/O
Upon
reset
Input
output
Pin
Function
Note 1
type
P40-
I/O
—
N-ch open-drain 4-bit I/O port (PORT4).
Withstand voltage is 13 V in open-drain
mode.
O
High level (when M-D
Note 2, 4
Note 3
P43
a pull-up resistor (M-E)
is provided) or
*
*
*
*
A pull-up resistor can be provided bit
high impedance
Note 5
by bit (mask option)
.
Data input/output pins for writing/
verifying (lower 4 bits of program
memory (PROM).
P50-
I/O
—
N-ch open-drain 4-bit I/O port (PORT5).
Withstand voltage is 13 V in open-drain
mode.
O
High level (when M-D
a pull-up resistor (M-E)
is provided) or
Note 2, 4
Note 3
P53
A pull-up resistor can be provided bit
high impedance
Note 5
by bit (mask option)
.
Data input/output pins for writing/
verifying (higher 4 bits of program
memory (PROM).
P60
P61
P62
P63
P70
P71
P72
P73
P80
P81
I/O
I/O
I/O
KR0
KR1
KR2
KR3
KR4
KR5
KR6
KR7
—
Programmable 4-bit I/O port (PORT6).
I/O can be specified bit by bit.
Built-in pull-up resistors can be
connected by software in units of 4 bits.
4-bit I/O port (PORT7).
O
Input
Input
Input
F -A
F -A
Built-in pull-up resistors can be
connected by software in units of
4 bits.
2-bit input port (PORT8).
x
E-B
—
Built-in pull-up resistors can be
connected by software in units of 2 bits.
Notes 1. I/O circuits enclosed in circles have a Schmitt-triggered input.
2. An LED can be driven directly.
3. ( ): µPD75P0016
*
*
4. When pull-up resistors that can be specified with the mask option are not
incorporated (when pins are used as N-ch open-drain input ports), the input leak low
current increases when an input instruction or bit operation instruction is executed.
5. These pins of the µPD75P0016 are not provided with pull-up resistors by mask option, and are
always open.
10
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CHAPTER 2 PIN FUNCTIONS
Table 2-2. Non-Port Pin Functions
Also
used
as
I/O
Upon
Input/
output
Pin
Function
circuit
reset
Note 1
type
TI0
Input
I/O
P13
Inputs external event pulse to the timer/event counter
Timer/event counter output
—
B -C
PTO0
PTO1
PCL
P20
P21
P22
P23
Input
E-B
Timer counter output
I/O
I/O
Clock output
Input
Input
E-B
E-B
BUZ
Fixed frequency output
(for buzzer or system clock trimming)
Serial clock I/O
SCK
I/O
P01
P02
P03
P00
Input
Input
Input
—
F -A
F -B
M -C
B
SO/SB0
SI/SB1
INT4
I/O
Serial data output or serial data bus I/O
Serial data input or serial data bus I/O
Edge detection vectored interrupt input
(Either a rising or falling edge is detected.)
The INT0/P10 pin has a noise eliminating function.
I/O
Input
INT0
INT1
INT2
Input
Input
P10
P11
P12
Edge detection vectored interrupt input
(The edge to be detected is selectable.) Asynchronous
Rising edge detection testable input Asynchronous
Synchronous
—
B -C
*
—
Input
Input
—
B -C
F -A
F -A
—
KR0-KR3 I/O
KR4-KR7 I/O
P60-P63 Parallel falling edge detection testable input
P70-P73 Parallel falling edge detection testable input
X1, X2
Input
—
Connection pin to a crystal/ceramic resonator for main
system clock generation.
When external clock is used, it is input to X1,
and its inverted signal is input to X2.
Connection pin to a crystal for subsystem clock
generation.
XT1
Input
—
—
—
—
XT2
When external clock is used, it is input to XT1, and
XT2 is left open.
RESET
Input
—
—
—
System reset input
—
—
B
Note 2
IC
Internally connected.
—
Connect to V , keeping the wiring as short as possible.
DD
V
V
V
—
—
—
—
—
Positive power supply
GND potential
—
—
—
—
—
—
DD
SS
Note 2
P10/INT0 Program voltage application for program memory
(PROM) write/verify operation.
PP
+12.5 V is applied for PROM write/verify operation.
Connect to V , keeping the wiring as short as
DD
possible.
MD0-
MD3
I/O
—
P30-P33 Mode selection for program memory (PROM)
write/verify operation.
Input
—
E-B
—
Note 3
NC
—
No connection
Notes 1. The circuits enclosed in circles have a Schmitt-triggered input.
2. Used as the V pin for the µPD75P0016.
PP
3. Provided only in the µPD75P0016.
11
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µPD750008 USER'S MANUAL
2.2 PIN FUNCTIONS
2.2.1 P00-P03 (PORT0) : Input Pins Used Also for INT4, SCK, SO/SB0 and SI/SB1
P10-P13 (PORT1) : Input Pins Used Also for INT0-INT2, and TI0
These are the input pins of the 4-bit input ports: Ports 0 and 1.
Ports 0 and 1 function as input ports, and also have the functions described below.
(1) Port 0 : Vectored interrupt input (INT4)
Serial interface I/O (SCK, SO/SB0, SI/SB1)
(2) Port 1 : Vectored interrupt input (INT0, INT1)
Edge detection test input (INT2)
External event pulse input (TI0) for timer/event counter
Input is always enabled for each pin of ports 0 and 1 regardless of the operation status of the other function
of the pin.
Schmitt-triggered inputs are used for the input pin of port 0 and pins of port 1 to prevent malfunction due
to noise. In addition, a noise eliminator is provided for P10. (See (3) of Section 6.3.)
Port 0 can be connected with built-in pull-up resistors in units of 3 bits (P01 to P03) by software. Port 1
can be connected with built-in pull-up resistors in units of 4 bits (P10 to P13) by software. This is done by
manipulating pull-up resistor specification register group A (POGA).
A RESET signal input places these pins in the input port mode.
12
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CHAPTER 2 PIN FUNCTIONS
2.2.2 P20-P23 (PORT2) : I/O Pins Used Also for PTO0, PTO1, PCL, and BUZ
Note
P30-P33 (PORT3) : I/O Pins Used Also for MD0-MD3
P40-P43 (PORT4),
P50-P53 (PORT5) : N-ch Open-Drain Intermediate Withstand Voltage (13 V) Large-Current
*
Output
P60-P63 (PORT6),
P70-P73 (PORT7) : Tristate I/O
These pins are the I/O pins of the 4-bit I/O ports with output latches: Ports 2 to 7.
Port n (n = 2, 3, 6, and 7) functions as I/O ports, and also have the following functions:
(1) Port 2
: Timer/event counter (PTO0, PTO1)
Clock output (PCL)
Fixed frequency output (BUZ)
Note
(2) Port 3
: Mode selection for program memory (PROM) write/verify operation (MD0-MD3)
(3) Ports 6 and 7: Key interrupt input (KR0-KR3, KR4-KR7)
Note Provided only in the µPD75P0016.
Port 3 is a large-current output. Ports 4 and 5 are N-ch open-drain intermediate withstand voltage (13 V)
large-current output. These ports can directly drive the LED.
*
An I/O mode is selected by the port mode register. The I/O mode of port m (m = 2, 4, 5, and 7) can be
selected in units of 4 bits, and the I/O mode of ports 3 and 6 can be selected bit by bit.
Port n can be connected with built-in pull-up resistors in units of 4 bits by software. This can be done by
manipulating pull-up resistor specification register group A (POGA). For ports 4 and 5, the use of built-in pull-
up resistors can be specified bit by bit by mask option.
Ports 4 and 5, and ports 6 and 7 can be paired respectively for 8-bit I/O.
A RESET input clears the output latches in the ports, places port n in the input mode (output high-
impedance state), and drives ports 4 and 5 high if pull-up resistors are provided or causes ports 4 and 5
to go into a high-impedance state.
2.2.3 P80, P81 (PORT8)
These pins are the I/O pins of the 2-bit I/O ports with output latches: Port 8.
Port 8 can be connected with built-in pull-up resistors in units of 2 bits by software. This can be done by
manipulating pull-up resistor specification register group B (POGB).
2.2.4 TI0: Input Pin Used Also for Port 1
This is an external event pulse input pin for the programmable timer/event counter.
A Schmitt-triggered input is used for the TI0 pin.
2.2.5 PTO0, PTO1: Output Pin Used Also for Port 2
This is the output signal pin of the programmable timer/event counter and programmable timer counter.
Square-wave pulses appear on this pin. To output a signal from the programmable timer/event counter and
programmable timer counter, the output latch P20 or P21 must be cleared to 0, and the bit for port 2 in the
port mode register must be set to 1 (output mode).
The output is cleared to 0 by the timer start instruction.
13
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2.2.6 PCL: Output Pin Used Also for Port 2
This is the programmable clock output pin. It is used to supply the clock pulse to a peripheral LSI circuit
such as a slave microcomputer or A/D converter.
A RESET signal clears the clock mode register (CLOM) to 0, disabling clock output, then the pin is placed
in the normal mode to function as a normal port.
2.2.7 BUZ: Output Pin Used Also for Port 2
An arbitrary frequency (2.048, 4.096, or 32.768 kHz) output on this pin can be used for sounding the buzzer
or trimming the system clock frequency. This pin is used also as the P23 pin, and can be used only when
bit 7 (WM.7) of the clock mode register (WM) is set to 1.
A RESET signal places this pin in the normal operation mode as a general port (see Section 5.4.2 for
details).
2.2.8 SCK, SO/SB0, SI/SB1: Tristate I/O Pins Used Also as Port 0
These are I/O pins for serial interface. They operate according to the setting of the serial operation mode
registers (CSIM).
A RESET signal stops serial interface operation and places these pins in the input port mode.
A Schmitt-triggered input is used for each pin.
2.2.9 INT4: Input Pin Used Also as Port 0
INT4 is an external vectored interrupt input pin, which is rising edge active as well as falling edge active.
When a signal applied to this pin goes from low to high or from high to low, the interrupt request flag is set.
INT4 is an asynchronous input, and can accept a signal with some high level width or low level width
regardless of what the CPU clock is.
The INT4 pin can also be used to release the STOP and HALT modes. A Schmitt-triggered input is used
for this pin.
2.2.10 INT0, INT1: Input Pins Used Also for Port 1
These are edge detection vectored interrupt input pins. INT0 has a noise eliminator. The edge to be
detected can be selected using the edge detection mode registers (IM0, IM1).
(1) INT0 (bits 0 and 1 of IM0)
(a) Rising edge active
(b) Falling edge active
(c) Both rising and falling edges active
(d) External interrupt signal input disabled
(2) INT1 (bit 0 of IM1)
(a) Rising edge active
(b) Falling edge active
14
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CHAPTER 2 PIN FUNCTIONS
INT0 has a noise eliminator. Two different sampling clocks for noise elimination can be switched. The
acceptable width of a signal depends on the CPU clock.
INT1 is an asynchronous input, and can accept a signal with some high level width regardless of what the
CPU clock is.
A RESET input clears IM0 and IM1 to 0, selecting rising edge active.
The INT1 pin can also be used to release the STOP and HALT modes, but the INT0 pin cannot.
Schmitt-triggered inputs are used for the INT0 and INT1 pins.
2.2.11 INT2: Input Pin Used Also for Port 1
This is a rising edge active, external test input pin. When INT2 is selected with the edge detection mode
register (IM2), or when the signal applied to this pin goes high, the internal test flag (IRQ2) is set.
INT2 is an asynchronous input, and can accept a signal with some high level width regardless of the
operating clock of the CPU.
A RESET signal clears IM2 to 0. In this case, the test flag (IRQ2) is set by a rising edge on the INT2 pin.
The INT2 pin can also be used to release the STOP and HALT modes. A Schmitt-triggered input is used
for this pin.
2.2.12 KR0-KR3: Input Pins Used Also for Port 6
KR4-KR7: Input Pins Used Also for Port 7
KR0 to KR7 are key interrupt input pins. An interrupt is caused when parallel falling edges are detected
on them. The interrupt format can be specified with the edge detection mode register (IM2).
A RESET signal places these pins in the port 6 and 7 input modes.
2.2.13 X1, X2
These pins are used for connection to a crystal or ceramic resonator for main system clock generation.
An external clock can also be applied.
(a) Crystal/ceramic oscillation
(b) External clock
µPD750008
µPD750008
External
clock
VSS
X1
X1
µ
PD74HC04
X2
X2
Crystal or ceramic resonator
(Standard frequency:
4.194304 or 6.0 MHz)
15
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2.2.14 XT1, XT2
These pins are used for connection to a crystal for subsystem clock oscillation.
An external clock can also be applied.
(a) Crystal oscillation
(b) External clock
µPD750008
µPD750008
VSS
External
clock
XT1
XT1
XT2
XT2
Crystal
(Standard frequency:
32.768 kHz)
2.2.15 RESET
This is the pin for active-low reset input.
The RESET input is asynchronous. When a signal with certain low level width is applied to the pin, a RESET
signal is generated to cause a system reset, which has priority over any other operations.
The RESET signal is used for normal CPU initialize/start operation, and is also used to release the standby
(STOP or HALT) mode.
A Schmitt-triggered input is used for the RESET input pin.
2.2.16
V
DD
This is the positive power supply pin.
2.2.17
V
SS
This is the ground pin.
16
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CHAPTER 2 PIN FUNCTIONS
2.2.18 IC (for the µPD750004, µPD750006, and µPD750008 only)
The internally connected (IC) pin is used to set the µPD750008 to test mode for inspection prior to shipping.
In normal operation, connect the IC pin to the V pin, keeping the writing as short as possible.
DD
When the wiring between the IC pin and the V pin is too long, or noise is generated on the IC pin, a potential
DD
difference may occur between the IC pin and the V
pin. This may cause your program to malfunction.
DD
• Connect the IC pin to the V
pin, keeping the wiring as short as possible.
DD
Keep the wiring
as short as possible
VDD
IC (VPP)
VDD
2.2.19
V
(for the µPD75P0016 only)
PP
This is a program voltage input pin for program memory (PROM) write/verify operation.
For normal use, connect this pin to V , keeping the wiring as short as possible (shown above).
DD
+12.5 V is applied for PROM write/verify operation.
2.2.20 MD0-MD3 (for the µPD75P0016 only): I/O Pins Used Also for Port 3
MD0 to MD3 select a mode for program memory (PROM) write/verify operation.
17
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2.3 PIN INPUT/OUTPUT CIRCUITS
Figure 2-1 shows schematic diagrams of the I/O circuitry of the µPD750008.
Figure 2-1. Pin Input/Output Circuits (1/2)
Type B-C
Type A
VDD
VDD
P.U.R.
P-ch
P.U.R.
enable
P-ch
IN
N-ch
IN
CMOS input buffer
P.U.R.: Pull-Up Resistor
Type B
Type D
VDD
Data
P-ch
N-ch
OUT
IN
Output
disable
Schmitt trigger input with hysteresis
Push-pull output which can be set to high-impedance output
(off for both P-ch and N-ch)
18
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CHAPTER 2 PIN FUNCTIONS
Figure 2-1. Pin Input/Output Circuits (2/2)
VDD
Type M-C
Type E-B
VDD
P.U.R.
P.U.R.
P.U.R.
enable
P.U.R.
enable
P-ch
P-ch
IN/OUT
Data
IN/OUT
Type D
Type A
Data
Output
disable
N-ch
Output
disable
P.U.R.: Pull-Up Resistor
P.U.R.: Pull-Up Resistor
Type F-A
Type M-D*
VDD
VDD
Input instruction
P-ch
P.U.R.
P-ch
VDD
P.U.R.
(Mask option)
P.U.R Note
IN/OUT
P.U.R.
enable
Data
Data
IN/OUT
N-ch
(Withstand
voltage:13 V)
Type D
Output
disable
Output
disable
Type B
Input buffer with an intermediate
withstand voltage of +13 V
P.U.R.: Pull-Up Resistor
P.U.R.: Pull-Up Resistor
Note Pull-up resistor that operates only when an input
instruction is excuted (valid at low voltage)
VDD
Type M-E*
Type F-B
VDD
P.U.R.
Input instruction
P-ch
P.U.R.
enable
P-ch
Note
Output
disable
(P-ch)
VDD
IN/OUT
Data
N-ch
P-ch
(Withstand
voltage:13 V)
Output
disable
IN/OUT
Data
Output
disable
N-ch
Output
disable
(N-ch)
Input buffer with an intermediate
withstand voltage of +13 V
Note Pull-up resistor that operates only when an input
instruction is executed (valid at low voltage)
P.U.R.: Pull-Up Resistor
19
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2.4 CONNECTION OF UNUSED PINS
Table 2-3. Connection of Unused Pins
Pin name
Recommended connection
P00/INT4
P01/SCK
To be connected to V
SS
SS
To be connected to V
or V
DD
P02/SO/SB0
P03/SI/SB1
P10/INT0-P12/INT2
P13/TI0
To be connected to V
SS
P20/PTO0
P21/PTO1
P22/PCL
Input state:
To be connected to V
or
SS
V
through a resistor
DD
Output state: To be left open
P23/BUZ
Note
P30(/MD0)-P33(/MD3)
P40-P43
P50-P53
P60-P63
P70-P73
P80-P81
XT1
To be connected to V
To be left open
or V
SS DD
XT2
Note
IC (V
)
To be connected directly to V
DD
PP
Note ( ): µPD75P0016
20
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CHAPTER 3 FEATURES OF THE ARCHITECTURE AND MEMORY MAP
The 75XL series architecture of the µPD750008 has the following features:
• Internal RAM of up to 4K words x 4 bits (12-bit address)
• Peripheral hardware expansibility
3
To provide these features, the following are used:
(1) Data memory bank structure
(2) General register bank structure
(3) Memory-mapped I/O
This chapter explains these topics.
3.1 DATA MEMORY BANK STRUCTURE AND ADDRESSING MODES
3.1.1 Data Memory Bank Structure
In the µPD750008, addresses 000H to 1FFH in data memory space are assigned to static RAM (512 words
x 4 bits), and addresses F80H to FFFH are assigned to peripheral hardware (such as I/O ports and timers).
To address a 12-bit location in this data memory space (4K x 4 bits), the µPD750008 uses such a memory
bank structure that the low-order eight bits are specified with an instruction directly or indirectly, and the high-
order four bits are used to specify a memory bank.
To specify a memory bank (MB), two hardware items are incorporated:
• Memory bank enable flag (MBE)
• Memory bank select register (MBS)
The MBS is a register used to select a memory bank, and the register can be set to 0, 1, or 15. The MBE
is a flag used to determine whether the memory bank selected using the MBS is valid. As shown in Figure
3-1, when the MBE is set to 0, a certain memory bank is always selected regardless of the setting of the MBS.
When the MBE is set to 1, memory bank selection depends on the setting of the MBS, thus enabling data
memory space expansion.
In addressing data memory space, the MBE is usually set to 1 (MBE = 1), and data memory in the memory
bank specified in the MBS is operated. However, the MBE = 0 mode or MBE = 1 mode can be selected for
each step of processing for more efficient programming.
21
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Applicable program processing
Effect
MBE = 0 mode
MBE = 1 mode
•
•
Interrupt processing
MBS save/restoration becomes unnecessary.
MBS modification becomes unnecessary.
Processing that repeats internal
hardware and static RAM operations
•
•
Subroutine processing
MBS save/restoration becomes
Usual program processing
Figure 3-1. Use of MBE = 0 Mode and MBE = 1 Mode
<Main program>
SET1 MBE
<Subroutine>
MBE
= 1
CLR1 MBE
MBE = 0
CLR1 MBE
Internal hardware
and static RAM
operations are
repeated.
MBE
= 0
RET <Interrupt processing>
; MBE = 0 is to be set in the vector table.
SET1 MBE
MBE = 0
MEB
= 1
RETI
The contents of the MBE are automatically saved or restored at the time of subroutine processing, so that
the MBE can be freely modified during subroutine processing. In interrupt processing, the MBE is automatically
saved or restored, and when interrupt processing is started, the contents of the MBE can be specified for the
interrupt processing by setting the interrupt vector table. This speeds up interrupt processing.
The setting of the MBS can be modified for subroutine processing or interrupt processing by saving or
restoring the MBS with the PUSH or POP instruction.
The MBE is set using the SET1 or CLR1 instruction. The MBS is set using the SEL instruction.
Examples 1. The MBE is cleared, and a fixed memory bank is used.
CLR1
MBE
; MBE <– 0
2. Memory bank 1 is selected.
SET1
SEL
MBE
MB1
; MBE <– 1
; MBS <– 1
22
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CHAPTER 3 FEATURES OF THE ARCHITECTURE AND MEMORY MAP
3.1.2 Data Memory Addressing Modes
With the architecture of the µPD750008, seven addressing modes summarized in Figures 3-2 and 3-3, and
Table 3-1 are available to address data memory space efficiently for each bit length of data to be processed.
These addressing modes enable more efficient programming.
(1) 1-bit direct addressing (mem.bit)
In this addressing mode, the operand of an instruction can directly specify any bit in the entire data memory
space.
A particular memory bank (MB) is always used in this addressing mode. In the MBE = 0 mode, when an
address from 00H to 7FH is specified in the operand, memory bank 0 (MB = 0) is always used. When
an address from 80H to FFH is specified, memory bank 15 (MB = 15) is always used. Accordingly, both
the data area ranging from 000H to 07FH and the peripheral hardware area ranging from F80H to FFFH
can be addressed in the MBE = 0 mode.
In the MBE = 1 mode, MB = MBS, and specifiable data memory space can be expanded.
This addressing mode can be applied to four instructions: bit set and reset instructions (SET1 and CLR1),
and bit test instructions (SKT and SKF).
Example FLAG1 is set, FLAG2 is reset, and whether FLAG3 is zero is tested.
FLAG1
FLAG2
FLAG3
EQU
EQU
EQU
03FH.1 ; Bit 1 at address 3FH
087H.2 ; Bit 2 at address 87H
0A7H.0 ; Bit 0 at address A7H
SET1
SEL
MBE
MB0
; MBE <– 1
; MBS <– 0
SET1
CLR1
SKF
FLAG1 ; FLAG1 <– 1
FLAG2 ; FLAG2 <– 0
FLAG3 ; FLAG3 = 0?
23
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µPD750008 USER'S MANUAL
Figure 3-2. Data Memory Organization and Addressing Range of Each Addressing Mode
Stack
mem
mem.bit
@HL
@H+mem.bit
@DE
@DL
Addressing mode
address- fmem.bit pmem.@L
ing
MBE
=0
MBE
=1
MBE
=0
MBE
=1
—
—
—
—
Memory bank enable flag
000H
Area for
general register
01FH
020H
07FH
MBS
=0
MBS
=0
SBS
=0
Data area
Static RAM
(memory bank 0)
0FFH
100H
Data area
Static RAM
(memory bank 1)
MBS
=1
MBS
=1
SBS
=1
1FFH
F80H
Not provided
Peripheral hardware area
(memory bank 15)
MBS
=15
MBS
=15
FC0H
FFFH
Remark – : Don't care
24
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CHAPTER 3 FEATURES OF THE ARCHITECTURE AND MEMORY MAP
Table 3-1. Addressing Modes
Representation
format
Addressing mode
Specified address
1-bit direct
addressing
mem.bit
Bit specified by bit at the address specified by MB and mem.
• When MBE = 0 and
mem = 00H-7FH,
mem = 80H-FFH,
MB = 0
MB = 15
• When MBE = 1,
MB = MBS
4-bit direct
addressing
mem
Address specified by MB and mem.
• When MBE = 0 and
mem = 00H-7FH,
mem = 80H-FFH,
MB = 0
MB = 15
• When MBE = 1,
MB = MBS
8-bit direct
addressing
Address specified by MB and mem (mem: even address).
• When MBE = 0 and
mem = 00H-7FH,
mem = 80H-FFH,
MB = 0
MB = 15
• When MBE = 1,
MB = MBS
4-bit register
indirect
addressing
@HL
@HL+
@HL–
Address specified by MB and HL.
In this case, MB = MBE·MBS
HL+ automatically increments the L register after addressing.
HL– automatically decrements the L register after addressing.
@DE
@DL
@HL
Address specified by DE in memory bank 0
Address specified by DL in memory bank 0
8-bit register
indirect
Address specified by MB and HL. (Contents of the L register is
an even address.)
addressing
In this case, MB = MBE·MBS
Bit
fmem.bit
Bit specified by bit at the address specified by fmem.
In this case,
fmem = FB0H-FBFH (interrupt-related hardware)
FF0H-FFFH (I/O ports)
manipulation
addressing
pmem.@L
Bit specified by the low-order two bits of the L register
at the address specified by the high-order 10 bits of pmem and the
high-order two bits of the L register.
In this case, pmem = FC0H-FFFH
@H+mem.bit
—
Bit specified by bit at the address specified by MB, H, and the low-
order four bits of mem.
In this case, MB = MBE·MBS
Stack addressing
Address specified by the SP in memory bank selected by the SBS
25
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(2) 4-bit direct addressing (mem)
In this addressing mode, the operand of an instruction directly specifies any area in the data memory space
in units of four bits.
As with the 1-bit direct addressing mode, in the MBE = 0 mode, a fixed space consisting of the static RAM
area ranging from 000H to 07FH and the peripheral hardware area ranging from F80H to FFFH can be
addressed. In the MBE = 1 mode, MB = MBS, and specifiable data memory space can be expanded to
the entire space.
This addressing mode can be applied to the MOV, XCH, INCS, IN, and OUT instructions.
Caution Less efficient program processing results if data associated with an I/O port is stored in
the static RAM area of bank 1 as in Example 1. The modification of the MBS, as contained
in Example 2, becomes unnecessary in the programming if data associated with an I/O
port is stored at addresses 00H to 7FH of bank 0.
Examples 1. The data contained in BUFF is output on port 5.
BUFF
EQU
SET1
SEL
11AH
MBE
; BUFF located at address 11AH
; MBE <– 1
MB1
; MBS <– 1
MOV
SEL
A,BUFF
MB15
; A <– (BUFF)
; MBS <– 15
OUT
PORT5,A ; PORT5 <– A
2. Data on port 4 is entered, and is saved in DATA1.
DATA1 EQU
5FH
; DATA1 located at address 5FH
; MBE <– 0
CLR1
IN
MBE
A,PORT4 ; A <– PORT4
DATA1,A ; (DATA1) <– A
MOV
(3) 8-bit direct addressing (mem)
In this addressing mode, the operand of an instruction directly specifies any area in the data memory space
in units of eight bits.
The operand can specify an even address. The 4-bit data at the address specified in the operand and
the 4-bit data at the address incremented by 1 are processed as a pair on an 8-bit basis with the 8-bit
accumulator (XA register pair).
A memory bank is specified in the same way as the 4-bit direct addressing.
This addressing mode can be applied to the MOV, XCH, IN, and OUT instructions.
Example 1. Eight-bit data from port 4 and port 5 is transferred to addresses 20H and 21H.
DATA
EQU
CLR1
IN
020H
MBE
; MBE <– 0
XA,PORT4 ; X <– PORT5 , A <– PORT4
DATA,XA ; (21H) <– X, (20H) <– A
MOV
26
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CHAPTER 3 FEATURES OF THE ARCHITECTURE AND MEMORY MAP
Example 2. Eight-bit data is latched into the serial interface shift register (SIO), and the transfer data
is set at the same time.
SEL
MB15
; MBS <– 15
XCH
XA,SIO
; XA <—> (SIO)
(4) 4-bit register indirect addressing (@rpa)
In this addressing mode, the pointer (general register pair) specified in the operand of an instruction
indirectly specifies a data memory space in units of four bits.
There are three types of data pointers. One is the HL register pair, which can specify any area in the data
memory space when MB = MBE·MBS is specified. The other two are the DE register pair and DL register
pair, with which memory bank 0 is always used regardless of how the MBE and MBS are specified. More
efficient programming is possible by selecting a data pointer according to a data memory bank to be used.
When the HL register pair is specified, the L register can be incremented or decremented by one in the
automatic increment or automatic decrement mode each time an instruction is executed, thus simplifying
the program step.
Example The data at 50H to 57H is transferred to 110H to 117H.
DATA1
DATA2
EQU
EQU
SET1
SEL
57H
117H
MBE
; MBE <– 1
MB1
; MBS <– 1
MOV
MOV
MOV
XCH
BR
D,#DATA1 SHR4
HL,#DATA2 AND 0FFH
A,@DL
; D <– 5
; HL <– 17H
; A <– (DL)
LOOP:
A,@HL–
; A <—> (HL), L <– L – 1
LOOP
The addressing mode using the HL register pair as the data pointer finds a wide range of operations such
as data transfer, operations, comparison, and I/O. The addressing mode using the DE register pair or
DL register pair is applied to the MOV and XCH instructions.
This addressing mode, combined with an increment/decrement instruction for a general register or register
pair, enables data memory space addresses to be freely updated as shown in Figure 3-3.
Example 1. The data at 50H to 57H is compared with the data at 110H to 117H.
DATA1 EQU
DATA2 EQU
SET1
57H
117H
MBE
SEL
MB1
MOV
D,#DATA1 SHR4
HL,#DATA2 AND 0FFH
A,@DL
MOV
LOOP: MOV
SKE
A,@HL
NO
; A = (HL)?
; NO
BR
DECS
L
; YES, L <– L – 1
BR
LOOP
27
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µPD750008 USER'S MANUAL
Example 2. The data memory of 00H to FFH is cleared to 0.
CLR1
CLR1
RBE
MBE
MOV
XA,#00H
HL,#04H
@HL,A
HL
MOV
LOOP: MOV
INCS
; (HL) <– A
; HL <– HL + 1
BR
LOOP
Figure 3-3. Updating Static RAM Addresses
x 0H
x FH
0 x H
DECS D
DECS D
@DE
DECS E
INCS E
@DL
DECS L
INCS L
4-bit transfer
4-bit transfer
DECS DE
INCS DE
INCS D
INCS D
Direct
addressing
Bit manipulation
4-bit transfer
8-bit transfer
DECS H
@HL
DECS H
Automatic
decrement
Automatic
increment
4-bit
manipulation
@H + mem.bit
DECS L
INCS L
Bit manipulation
8-bit
manipulation
DECS HL
INCS HL
INCS H
INCS H
F x H
28
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CHAPTER 3 FEATURES OF THE ARCHITECTURE AND MEMORY MAP
(5) 8-bit register indirect addressing (@HL)
In this addressing mode, the data pointer (HL register pair) indirectly specifies any area in the data memory
space in units of eight bits.
The 4-bit data at the address determined with bit 0 of the data pointer (bit 0 of the L register) set to 0 and
the 4-bit data at the address incremented by 1 are processed as a pair on an 8-bit basis with the 8-bit
accumulator (XA register pair).
A memory bank is specified in the same way as the 4-bit register indirect addressing with the HL register
specified. In this case, MB = MBE·MBS.
This addressing mode can be applied to the MOV, XCH, and SKE instructions.
Examples 1. A comparison is made to determine whether the value of the count register (T0) of timer/
event counter 0 is equal to the data at addresses 30H and 31H.
DATA
EQU
CLR1
MOV
MOV
SKE
30H
MBE
HL,#DATA
XA,T0
; XA <– Count register 0
; XA = (HL)?
XA,@HL
2. The data memory of 00H to FFH is cleared to 0.
CLR1
CLR1
MOV
MOV
MOV
INCS
INCS
BR
RBE
MBE
XA,#00H
HL,#04H
@HL,XA
HL
LOOP:
; (HL) <– XA
HL
LOOP
(6) Bit manipulation addressing
This addressing mode is used to perform bit manipulations (such as Boolean operations and bit transfer)
for each bit in the data memory space.
The 1-bit direct addressing mode can be applied only to the set, reset, and test instructions. On the other
hand, the bit manipulation addressing enables a wide variety of bit manipulations such as Boolean
operations using the AND1, OR1, and XOR1 instructions, bit transfers using the MOV1 instruction, and
test and reset operations using the SKTCLR instruction.
There are three types of bit manipulation addressing. The user can choose from these options according
to the data memory address used.
29
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µPD750008 USER'S MANUAL
(a) Specific address bit direct addressing (fmem.bit)
In this addressing mode, peripheral equipment that frequently performs bit manipulations involving,
for example, I/O ports and interrupt flags, can be processed at all times regardless of memory bank
setting. Accordingly, the data memory addresses that allow this addressing mode to be used are FF0H
to FFFH where I/O ports are mapped, and FB0H to FBFH where interrupt-related hardware is mapped.
Hardware mapped to these data memory areas can freely perform bit manipulations in the direct
addressing mode at any time regardless of MBS and MBE setting.
Examples 1. Value input to P02 is inverted, and the result is output on P33.
MOV1
NOT1
MOV1
CY, PORT0.2
CY
PORT3.3, CY
2. The timer 0 interrupt request flag (IRQT0) is tested. The request flag, if set, is cleared,
and P63 is reset.
SKTCLR
BR
IRQT0
NO
; IRQT0 = 1?
; NO
CLR1
PORT6.3
; YES
3. If both P30 and P41 are set to 1, P53 is reset.
P30
P53
P41
MOV1
AND1
NOT1
MOV1
CY, PORT3.0
CY, PORT4.1
CY
; CY <– P30
; CY P41
; CY <– CY
; P53 <– CY
PORT5.3, CY
30
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CHAPTER 3 FEATURES OF THE ARCHITECTURE AND MEMORY MAP
(b) Specific address bit register indirect addressing (pmem.@L)
In this addressing mode, the bits of peripheral hardware I/O ports are indirectly specified using a
register to allow continuous manipulations. This addressing mode can be applied to data memory
addresses FC0H to FFFH.
In this addressing mode, the high-order 10 bits of a 12-bit data memory address is directly specified
in the operand, and the low-order two bits and bit address are indirectly specified using the L register.
Thus the use of the L register enables 16 bits (four ports) to be continuously manipulated.
This addressing mode again enables bit manipulation regardless of MBE and MBS setting.
Example Pulses are output on the bits in the order from port 4 to port 7.
P40
P41
·
·
·
·
·
·
P73
MOV
SET1
CLR1
INCS
NOP
BR
L,#0
LOOP:
PORT4.@L
PORT4.@L
L
; Bits (L ) of ports 4 to 7 <– 1
1-0
; Bits (L ) of ports 4 to 7 <– 0
1-0
LOOP
31
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µPD750008 USER'S MANUAL
(c) Specific 1-bit direct addressing (@H+mem.bit)
This addressing mode enables any bit in the data memory space to be manipulated.
In this addressing mode, the high-order four bits of the data memory address in the memory bank
specified by MB = MBE·MBS are indirectly specified using the H register, and the low-order four bits
and bit address are directly specified in the operand. This addressing mode enables a wide variety
of manipulations for each bit in the entire data memory space.
Example Bit 2 at address 32H (FLAG3) is reset if both bit 3 at address 30H (FLAG1) and bit 0 at
address 31H (FLAG2) are set to 0 or 1.
FLAG1
FLAG3
FLAG2
FLAG1
FLAG2
FLAG3
EQU
EQU
EQU
SEL
30H.3
31H.0
32H.2
MB0
MOV
H,#FLAG1 SHR 6
MOV1 CY, @H+FLAG1
XOR1 CY, @H+FLAG2
MOV1 @H+FLAG3, CY
; CY <– FLAG1
; CY <– CY FLAG2
; FLAG3 <– CY
32
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CHAPTER 3 FEATURES OF THE ARCHITECTURE AND MEMORY MAP
(7) Stack addressing
This addressing mode is used for save/restoration operation in interrupt processing or subroutine
processing.
In this addressing mode, the address indicated by the stack pointer (8 bits) of data memory bank 0 is
specified.
This addressing mode can be used for register save/restoration operation using the PUSH or POP
instruction as well as save/restoration operation in interrupt and subroutine processing.
Examples 1. A register is saved and restored in subroutine processing.
SUB:
PUSH
PUSH
PUSH
XA
HL
BS
; Save MBS and RBS
·
·
·
POP
POP
POP
RET
BS
HL
XA
2. The contents of the HL register pair are transferred to the DE register pair.
PUSH
POP
HL
DE
; DE <– HL
3. A branch is made to the address indicated by the [XABC] register.
PUSH
PUSH
RET
BC
XA
; Branch to address XABC
33
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µPD750008 USER'S MANUAL
3.2 GENERAL REGISTER BANK CONFIGURATION
The µPD750008 contains four register banks, each consisting of eight general registers: X, A, B, C, D,
E, H, and L. These registers are mapped to addresses 00H to 1FH in memory bank 0 of the data memory
(see Figure 3-5). To specify a general register bank, a register bank enable flag (RBE) and a register bank
select register (RBS) are contained. The RBS is a register used to select a register bank, and the RBE is
a flag used to determine whether a register bank selected using the RBS is to be enabled. The register bank
(RB) enabled at instruction execution is determined as
RB = RBE·RBS
Table 3-2. Register Bank to Be Selected with the RBE and RBS
RBS
RBE
Register bank
3
0
0
2
0
0
1
x
0
0
1
1
0
x
0
1
0
1
0
1
Bank 0 is always selected.
Bank 0 is selected.
Bank 1 is selected.
Bank 2 is selected.
Bank 3 is selected.
Always 0
Remark x: Don’t care
The contents of the RBE are automatically saved or restored at the beginning or end of subroutine
processing, so that the RBE can be freely modified during subroutine processing. In interrupt processing,
the RBE is automatically saved or restored, and when interrupt processing is started, the contents of the RBE
can be specified for the interrupt processing by setting the interrupt vector table. Therefore, as indicated in
Table 3-3, by selecting a register bank depending on whether the processing is normal or interrupt, the general
register need not be saved and restored for the level-one interrupt processing, and only the RBS needs to
be saved and restored for the level-two interrupt processing, thus speeding up interrupt processing.
Table 3-3. Recommended Use of Register Banks with Normal Routines and Interrupt Routines
Normal processing
Use register banks 2 and 3 with RBE = 1.
Use register bank 0 with RBE = 0.
Level-one interrupt processing
Level-two interrupt processing
Use register bank 1 with RBE = 1.
(In this case, the RBS needs to be saved and restored.)
Multiple (triple or more) interrupt processing
Save and restore the registers with PUSH or POP.
34
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CHAPTER 3 FEATURES OF THE ARCHITECTURE AND MEMORY MAP
Figure 3-4. Example of Register Bank Selection
<Main program>
SET1 RBE
SEL RB2
<Level-one interrupt> <Level-two interrupt> <Level-three interrupt>
; RBE = 0 in the
vector table
; RBE = 0 in the
vector table
; RBE = 1 in the
vector table
PUSH BS
SEL RB1
PUSH rp
RB = 2
RB = 0
RB = 1
RB = 0
RETI
POP rp
RETI
POP BS
RETI
The setting of the RBS can be modified for subroutine processing or interrupt processing by saving or
restoring the RBS with the PUSH or POP instruction.
The RBE is set using the SET1 or CLR1 instruction. The RBS is set using the SEL instruction.
Example
SET1
CLR1
SEL
RBE ; RBE <– 1
RBE ; RBE <– 0
RB0 ; RBS <– 0
RB3 ; RBS <– 3
SEL
The general register area of the µPD750008 can be used not only on a 4-bit basis, but also on an 8-bit
basis with register pairs. This enables users to perform transfers, arithmetic/logical operations, comparisons,
and increments and decrements at a speed comparable to that of an 8-bit microcomputer, and thereby enables
to program using mainly general registers.
(1) When used as a 4-bit register
When the general register area is used on a 4-bit basis, eight general registers, the X, A, B, C, D, E, H,
and L registers, are available in the register bank specified with RB = RBE·RBS as shown in Figure 3-
5. The A register functions as a 4-bit accumulator which performs transfers, arithmetic/logical operations,
andcomparisons. Theothergeneralregistersperformtransfers, comparisons, andincrements/decrements
with the accumulator.
35
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µPD750008 USER'S MANUAL
(2) When used as an 8-bit register
When the general register area is used on an 8-bit basis, the register pairs in the register bank specified
by RBE·RBS can be specified as XA, BC, DE, and HL as shown in Figure 3-6, and the register pairs in
the register bank that has the inverted value of bit 0 of the register bank (RB) can be specified as XA’,
BC’, DE’, and HL’, thus providing up to eight 8-bit registers. The XA register pair functions as an 8-bit
accumulator which performs transfers, arithmetic/logical operations, comparisons, and increments/
decrements of 8-bit data. The other register pairs perform transfers, arithmetic/logical operations,
comparisons, and increments/decrements with the accumulator. The HL register pair functions mainly
as a data pointer, and the DE and DL register pairs function as an auxiliary data pointer.
Examples 1.
INCS
ADDS
SUBC
MOV
HL
; HL <– HL + 1, skip at HL = 00H
; XA <– XA + BC, skip at carry
; DE’ <– DE’ – XA – CY
; XA <– XA’
XA,BC
DE’,XA
XA,XA’
XA,@PCDE
XA, BC
MOVT
SKE
; XA <– (PC
+ DE) ROM, reference table
12-8
; Skip if XA = BC
2. The value of the count register (T0) for timer/event counter 0 is tested until it becomes
greater than the value of the BC’ register pair.
CLR1
MOV
SUBS
BR
MBE
XA,T0
XA,BC’
YES
NO:
; Read count register
; XA • BC?
; YES
BR
NO
; NO
36
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CHAPTER 3 FEATURES OF THE ARCHITECTURE AND MEMORY MAP
Figure 3-5. General Register Configuration (4-bit Processing)
X
H
D
B
X
H
D
B
X
H
D
B
X
H
D
B
A
L
01H
03H
05H
07H
09H
0BH
0DH
0FH
11H
13H
15H
17H
19H
1BH
1DH
1FH
00H
02H
04H
06H
08H
0AH
0CH
0EH
10H
12H
14H
16H
18H
1AH
1CH
1EH
Register bank 0
(RBE·RBS = 0)
E
C
A
L
Register bank 1
(RBE·RBS = 1)
E
C
A
L
Register bank 2
(RBE·RBS = 2)
E
C
A
L
Register bank 3
(RBE·RBS = 3)
E
C
37
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µPD750008 USER'S MANUAL
Figure 3-6. General Register Configuration (8-bit Processing)
XA
HL
XA’
HL’
DE’
BC’
XA
HL
00H
02H
04H
06H
08H
0AH
0CH
0EH
00H
02H
04H
06H
08H
0AH
0CH
0EH
DE
BC
XA’
HL’
DE’
BC’
When RBE·RBS
= 0
When RBE·RBS
= 1
DE
BC
XA
HL
XA’
HL’
DE’
BC’
XA
HL
10H
12H
14H
16H
18H
1AH
1CH
1EH
10H
12H
14H
16H
18H
1AH
1CH
1EH
DE
BC
XA’
HL’
DE’
BC’
When RBE·RBS
= 2
When RBE·RBS
= 3
DE
BC
38
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CHAPTER 3 FEATURES OF THE ARCHITECTURE AND MEMORY MAP
3.3 MEMORY-MAPPED I/O
The µPD750008 employs memory-mapped I/O, which maps peripheral hardware such as timers and I/O
ports to addresses F80H to FFFH in data memory space as shown in Figure 3-2. This means that there is
no particular instruction to control peripheral hardware, but all peripheral hardware is controlled using memory
manipulation instructions. (Some mnemonics for hardware control are available to make programs readable.)
To manipulate peripheral hardware, the addressing modes listed in Table 3-4 can be used.
Table 3-4. Addressing Modes Applicable to Peripheral Hardware Operation
Applicable addressing mode
Applicable hardware
Bit
Direct addressing mode specifying mem.bit with
MBE = 0 (MBE = 1, MBS = 15)
All hardware
allowing bit manipulation
manipulation
Direct addressing mode specifying fmem.bit regardless of
MBE and MBS setting
IST1, IST0, MBE, RBE,
IExxx, IRQxxx, PORTn.x
Indirect addressing mode specifying pmem.@L regardless of
MBE and MBS setting
BSBn.x
PORTn.x
4-bit
manipulation
Direct addressing mode specifying mem with
MBE = 0 or (MBE = 1, MBS = 15)
All hardware allowing 4-bit
manipulation
Register indirect addressing mode specifying @HL with
(MBE = 1, MBS = 15)
8-bit
manipulation
Direct addressing mode specifying mem (even address) with
MBE = 0 or (MBE = 1, MBS = 15)
All hardware allowing 8-bit
manipulation
Register indirect addressing mode specifying @HL
(with the L register containing an even number) with
MBE = 1 and MBS = 15
Figure 3-7 summarizes the I/O map of the µPD750008.
The items in the figure have the following meanings:
• Symbol : Name representing incorporated hardware, which can be coded in the operand field of an
instruction
• R/W
: Indicates whether the hardware allows read/write operation.
R/W : Both read and write operations possible
R
: Read only
: Write only
W
• Number of manipulatable bits:
Indicates the number of bits that can be processed at a time in hardware manipulation
O
Ð
–
: Bit manipulation is possible in units of the indicated number of bits (1, 4, or 8 bits).
: Particular bits can be manipulated. For these bits, see Remarks.
: Bit manipulation is impossible in units of the indicated number of bits (1, 4, or 8 bits).
• Bit manipulation addressing:
Bit manipulation addressing applicable in hardware bit manipulation
39
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µPD750008 USER'S MANUAL
Figure 3-7. µPD750008 I/O Map (1/5)
Number of bits that can be
manipulated
Hardware name (symbol)
b2 b1
Bit
manipulation
addressing
Address
R/W
R/W
R
Remarks
b3
b0
1 bit
–
4 bits
8 bits
Bit 0 is fixed
to 0.
F80H
Stack pointer (SP)
–
–
–
Register bank selection register (RBS)
Bank selection register (BS)
F82H
F83H
F84H
F85H
F86H
–
–
–
Note 1
Memory bank selection register (MBS)
Stack bank selection register (SBS)
R/W
W
–
–
mem.bit
mem.bit
Only bit 3 can
be manipulated.
Basic interval timer mode register (BTM)
Basic interval timer (BT)
WDTMNote 2
R
–
–
–
–
F8BH
F98H
W
–
mem.bit
Only bit 3 can
be tested.
–
–
mem.bit
–
(R)
–
Clock mode register (WM)
R/W
Notes 1. Can be manipulated separately as the RBS and MBS in 4-bit units.
Can also be manipulated as the BS in 8-bit units.
Use SEL MBn and SEL RBn instructions to write data to MBS and RBS respectively.
2. WDTM: Watchdog timer enable flag (W); cannot be cleared by an instruction.
40
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CHAPTER 3 FEATURES OF THE ARCHITECTURE AND MEMORY MAP
Figure 3-7. µPD750008 I/O Map (2/5)
Number of bits that can be
manipulated
Hardware name (symbol)
b2 b1
Bit
manipulation
addressing
Address
FA0H
R/W
R/W
Remarks
b3
b0
1 bit
4 bits
8 bits
Bit write manipu-
lation is enabled
only for bit 3.
–
mem.bit
(W)
–
Timer/event counter mode register (TM0)
(R/W)
–
–
–
–
FA2H
FA4H
TOE0Note 1
W
R
mem.bit
Timer/event counter count register (T0)
–
–
–
–
FA6H
FA8H
Timer/event counter modulo register (TMOD0)
Timer counter mode register (TM1)
R/W
R/W
–
–
–
Bit write manipu-
lation is enabled
only for bit 3.
mem.bit
(W)
–
(R/W)
–
–
–
–
FAAH
FACH
TOE1Note 2
W
R
mem.bit
Timer counter count register (T1)
–
–
–
–
–
–
FAEH
Timer counter modulo register (TMOD1)
R/W
Notes 1. TOE0: Timer/event counter output enable flag (W)
2. TOE1: Timer counter output enable flag (W)
41
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µPD750008 USER'S MANUAL
Figure 3-7. µPD750008 I/O Map (3/5)
Number of bits that can be
manipulated
Hardware name (symbol)
Bit
manipulation
addressing
Address
R/W
R/W
Remarks
b3
b2
b1
b0
1 bit
4 bits
8 bits
(R)
IST1
IST0
MBE
RBE
Manipulation in
8-bit units is
enabled only
for reading.
FB0H
(R/W)
–
(R/W)
–
Program status word (PSW)
CY SK2 SK1
SK0
fmem.bit
Note 1
Note 2
FB2H
FB3H
FB4H
FB5H
FB6H
FB7H
FB8H
FBAH
Interrupt priority select register (IPS)
Processor clock control register (PCC)
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
–
–
–
–
–
–
–
INT0 edge detection mode register (IM0)
INT1 edge detection mode register (IM1)
INT2 edge detection mode register (IM2)
System clock control register (SCC)
Bits 3, 2, and 1
are fixed to 0.
–
–
–
Bits 3 and 2 are
fixed to 0.
Bits 2 and 1 are
fixed to 0.
–
–
(R/W)
(R)
IE4
IET1
IE1
IRQ4
IRQT1
IRQ1
IEBT
IEW
IRQBT
IRQW
FBCH
IET0
IRQT0
R/W
fmem.bit
–
–
FBDH
FBEH
FBFH
IECSI
IE0
IRQCSI
IRQ0
R/W
R/W
R/W
IE2
IRQ2
FC0H
FC1H
FC2H
FC3H
FCFH
Bit sequential buffer 0 (BSB0)
Bit sequential buffer 1 (BSB1)
Bit sequential buffer 2 (BSB2)
Bit sequential buffer 3 (BSB3)
Sub-oscillator control register (SOS)
R/W
R/W
R/W
R/W
R/W
mem.bit
pmem.@L
–
–
–
Remarks 1. IExxx : Interrupt enable flag
2. IRQxxx : Interrupt request flag
Notes 1. Only bit 3 can be manipulated by an EI/DI instruction.
2. Bits 3 and 2 can be manipulated bit by bit by a STOP/HALT instruction.
42
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CHAPTER 3 FEATURES OF THE ARCHITECTURE AND MEMORY MAP
Figure 3-7. µPD750008 I/O Map (4/5)
Number of bits that can be
manipulated
Hardware name (symbol)
b2 b1
Clock output mode register (CLOM)
Bit
manipulation
addressing
Address
R/W
R/W
R/W
Remarks
b3
b0
1 bit
–
4 bits
8 bits
–
FD0H
FDCH
–
–
Pull-up resistor specification register group A
(POGA)
–
–
–
–
FDEH
Pull-up resistor specification register group B
(POGB)
R/W
–
FE0H
FE2H
FE4H
FE6H
FE8H
FECH
FEEH
–
–
–
–
Serial operation mode register (CSIM)
Note
R/W
R/W
R/W
R/W
R/W
R/W
R/W
mem.bit
CSIE
COI
WUP
(R) (W)
Whether this
location is read-
or write-
accessible de-
pends on the bit.
CMDD
RELD
CMDT
RELT
ACKT
SBI control register (SBIC)
BSYE ACKD ACKE
–
–
–
–
–
–
–
mem.bit
Serial I/O shift register (SIO)
Slave address register (SVA)
–
–
–
–
–
–
–
–
–
–
PM33
PM32
PM31
PM30
Port mode register group A (PMGA)
PM63
–
PM62
PM2
PM61
–
PM60
–
Port mode register group B (PMGB)
PM7
–
–
–
PM5
–
PM4
PM8
Port mode register group C (PMGC)
–
–
–
–
Note Whether a bit can be read or written depends on the bit.
43
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µPD750008 USER'S MANUAL
Figure 3-7. µPD750008 I/O Map (5/5)
Number of bits that can be
manipulated
Hardware name (symbol)
Bit
manipulation
addressing
Address
R/W
Remarks
b3
b2
b1
b0
1 bit
4 bits
8 bits
–
SCKP
Note 1
FF0H
FF1H
Port 0 (PORT0)
Port 1 (PORT1)
Port 2 (PORT2)
Port 3 (PORT3)
Port 4 (PORT4)
Port 5 (PORT5)
R/W
R
(R) (R/W) (R)
FF2H
R/W
R/W
R/W
R/W
R/W
R/W
R/W
–
FF3H
fmem.bit
pmem.@L
FF4H
FF5H
KR3
KR2
KR1
KR5
KR0
KR4
FF6HNote 2
FF7HNote 2
FF8H
Port 6 (PORT6)
KR7
KR6
Port 7 (PORT7)
–
Port 8 (PORT8)
Notes 1. Bit 1 can be read or written only in serial operation enable mode. It can be read when four-bit
manipulation is performed.
2. KR0 to KR7 can be read (R) bit by bit. When inputting 4 bits at a time, specify PORT6 or PORT7.
44
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CHAPTER 4 INTERNAL CPU FUNCTIONS
4.1 Mk I MODE/Mk II MODE SWITCH FUNCTIONS
4.1.1 Differences between Mk I Mode and Mk II Mode
The CPU of the µPD750008 subseries has two modes (Mk I mode and Mk II mode) and which mode is
used is selectable. Bit 3 of the stack bank selection register (SBS) determines the mode.
4
• Mk I mode: This mode has the upward compatibility with the µPD75008 subseries.
It can be used in the 75XL CPUs having a ROM of up to 16KB.
• Mk II mode: This mode is not compatible with the µPD75008 subseries.
It can be used in all 75XL CPUs, including those having a ROM of 16KB or more.
Table 4-1 shows the differences between Mk I mode and Mk II mode.
Table 4-1. Differences between Mk I Mode and Mk II Mode
Mk I mode
2 bytes
Mk II mode
3 bytes
Number of stack bytes in a subroutine instruction
BRA !addr1 instruction
Undefined operation
Normal operation
CALLA !addr1 instruction
CALL !addr instruction
CALLF !faddr instruction
3 machine cycles
2 machine cycles
4 machine cycles
3 machine cycles
Caution Mk II mode is for maintaining a software compatibility with products in the 75X series or
75XL series whose program memory is more than 24K bytes.
Therefore, Mk I mode is recommended for applications with a focus on the ROM efficiency
or speed.
*
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4.1.2 Setting of the Stack Bank Selection Register (SBS)
The Mk I mode and Mk II mode are switched by stack bank selection register. Figure 4-1 shows the register
configuration.
The stack bank selection register is set with a 4-bit memory operation instruction. To use the CPU in Mk
Note
I mode, initialize the register to 10xxB
at the beginning of the program. To use the CPU in Mk II mode,
Note
initialize it to 00xxB
.
Figure 4-1. Stack Bank Selection Register Format
Address
F84H
3
2
1
0
Symbol
SBS
SBS3 SBS2 SBS1 SBS0
Stack area designation
0
0
0
1
Memory bank 0
Memory bank 1
Other settings are inhibited
Bit 2 must be set to 0
Mode switching designation
0
1
Mk II mode
Mk I mode
Note Specify the desired value in xx.
Caution The CPU operates in Mk I mode after the RESET signal is issued, because bit 3 of SBS
is set to 1. Set bit 3 of SBS to 0 (Mk II mode) to use the CPU in Mk II mode.
46
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CHAPTER 4 INTERNAL CPU FUNCTIONS
4.2 PROGRAM COUNTER (PC):
12 BITS (µPD750004)
13 BITS (µPD750006 AND µPD750008)
14 BITS (µPD75P0016)
The program counter is a binary counter which retains the address data of the program memory. The
program counter consists of 12 bits in the µPD750004 (see Figure 4-2(a)), 13 bits in the µPD750006 and
µPD750008 (see Figure 4-2(b)), and 14 bits in the µPD75P0016 (see Figure 4-2(c)).
Figure 4-2. Program Counter Organization
(a) µPD750004
PC11 PC10 PC9
PC8
PC7 PC6
PC5
PC4
PC3
PC2 PC1 PC0
(b) µPD750006 and µPD750008
PC12 PC11 PC10 PC9
PC8 PC7
PC6
PC5
PC4
PC3 PC2 PC1
PC0
(c) µPD75P0016
PC13 PC12 PC11 PC10 PC9 PC8
PC7
PC6
PC5
PC4 PC3 PC2
PC1 PC0
Usually, each time an instruction is executed, the program counter is automatically incremented according
to the number of bytes in the instruction.
When a branch instruction (BR, BRA, BRCB) is executed, immediate data indicating the branch destination
and the contents of a register pair are set in all or some bits of the program counter.
When a subroutine call instruction (CALL, CALLA, CALLF) is executed, or a vectored interrupt occurs, the
current contents of the program counter (already incremented return address for fetching the next instruction)
are saved in the stack memory (data memory indicated by the stack pointer), then the jump destination address
is loaded.
When a return instruction (RET, RETS, RETI) is executed, the contents of the stack memory are set in the
program counter.
When the RESET signal is issued, the program counter is initialized to the contents of the program memory
at addresses 000H and 001H. The program can be started from any address according to the contents.
µPD750004 :
PC -PC <– (000H)
, PC -PC <– (001H)
11
8
3-0
7
0
7-0
7-0
7-0
µPD750006 and µPD750008 :
PC -PC <– (000H)
, PC -PC <– (001H)
12
8
4-0
7
0
µPD75P0016 :
PC -PC <– (000H)
, PC -PC <– (001H)
13
8
5-0
7
0
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4.3 PROGRAM MEMORY (ROM):
4096 WORDS x 8 BITS (µPD750004: MASKED ROM)
6144 WORDS x 8 BITS (µPD750006: MASKED ROM)
8192 WORDS x 8 BITS (µPD750008: MASKED ROM)
16384 WORDS x 8 BITS (µPD75P0016: ONE-TIME PROM)
The program memory is used for storing programs, an interrupt vector table, GETI instruction reference
table, table data, and so forth. The µPD750004, µPD750006, and µPD750008 are provided with a mask-
programmable ROM as the program memory, and the µPD75P0016 is provided with a one-time PROM.
Figures 4-3 to 4-6 show the program memory maps.
Program memory is addressed by the program counter. Table data can be referenced using the table
reference instruction (MOVT).
Figures 4-3 to 4-6 also show the allowable branch address ranges for the branch instructions and subroutine
call instructions. The relative branch instruction (BR $addr) allows a branch to addresses (contents of the
PC less 15 to one, or plus two to 16) regardless of block.
The program memory is located at following addresses.
• 0000H to 0FFFH: µPD750004
• 0000H to 17FFH: µPD750006
• 0000H to 1FFFH: µPD750008
• 0000H to 3FFFH: µPD75P0016
The following addresses are assigned to special functions. All areas excluding 0000H and 0001H can be
used as normal program memory.
• 0000H to 0001H
Vector address table for holding the RBE and MBE values and program start address when a RESET
signal is issued (allowing a reset start at an arbitrary address)
• 0002H to 000DH
Vector address table for holding the RBE and MBE values and program start address for each vectored
interrupt (allowing interrupt processing to be started at an arbitrary address)
• 0020H to 007FH
Note
Table area referenced by the GETI instruction
Note The GETI instruction can represent an arbitrary two-byte or three-byte instruction or two one-byte
instructions in one byte and is used to reduce the number of program bytes. (SeeSection 11.1.1.)
48
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CHAPTER 4 INTERNAL CPU FUNCTIONS
Figure 4-3. Program Memory Map (in µPD750004)
7
6
0
0000H
0002H
0004H
0006H
0008H
000AH
000CH
MBE RBE
MBE RBE
MBE RBE
MBE RBE
MBE RBE
MBE RBE
MBE RBE
Internal reset start address (high-order 6 bits)
Internal reset start address (low-order 8 bits)
INTBT/INT4 start address (high-order 6 bits)
INTBT/INT4 start address (low-order 8 bits)
Entry
address
specified
in CALLF
!faddr
instruc-
tion
INT0 start address
INT0 start address
INT1 start address
INT1 start address
INTCSI start address
INTCSI start address
INTT0 start address
INTT0 start address
INTT1 start address
INTT1 start address
(high-order 6 bits)
(low-order 8 bits)
(high-order 6 bits)
(low-order 8 bits)
(high-order 6 bits)
(low-order 8 bits)
(high-order 6 bits)
(low-order 8 bits)
(high-order 6 bits)
(low-order 8 bits)
Branch
address
specified
in BRCB
!caddr
instruc-
tion
Branch address
specified in
BR !addr, BR BCDE,
BR BCXA, BRA
!addr1Note, CALL
!addr, or CALLA
!addr1Note
Branch/call
address by
GETI
0020H
GETI instruction reference table
Relative
branch
address
007FH
0080H
specified in
BR $addr
instruction
(–15 to –1,
+2 to +16)
07FFH
0800H
0FFFH
Note Can be used only in the MkII mode.
*
Remark In addition to the above, the BR PCDE and BR PCXA instructions can cause a branch to an
address with only the 8 low-order bits of the PC changed.
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Figure 4-4. Program Memory Map (in µPD750006)
7
6
0
0000H
0002H
0004H
0006H
0008H
000AH
000CH
MBE RBE
MBE RBE
MBE RBE
MBE RBE
MBE RBE
MBE RBE
MBE RBE
Internal reset start address (high-order 6 bits)
Internal reset start address (low-order 8 bits)
INTBT/INT4 start address (high-order 6 bits)
INTBT/INT4 start address (low-order 8 bits)
Entry
address
specified
in CALLF
!faddr
instruc-
tion
INT0 start address
INT0 start address
INT1 start address
INT1 start address
INTCSI start address
INTCSI start address
INTT0 start address
INTT0 start address
INTT1 start address
INTT1 start address
(high-order 6 bits)
(low-order 8 bits)
(high-order 6 bits)
(low-order 8 bits)
(high-order 6 bits)
(low-order 8 bits)
(high-order 6 bits)
(low-order 8 bits)
(high-order 6 bits)
(low-order 8 bits)
Branch
address
specified
in BRCB
!caddr
instruc-
tion
Branch address
specified in
BR !addr,
BR BCDE,
BR BCXA,
BRA !addr1Note
CALL !addr,
,
or CALLA !addr1Note
Branch/call
address by
GETI
0020H
GETI instruction reference table
007FH
0080H
Relative
branch
address
specified in
BR $addr
instruction
(–15 to –1,
+2 to +16)
07FFH
0800H
0FFFH
1000H
Branch address
specified in BRCB
!caddr instruction
17FFH
Note Can be used only in the MkII mode.
*
Remark In addition to the above, the BR PCDE and BR PCXA instructions can cause a branch to an
address with only the 8 low-order bits of the PC changed.
50
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CHAPTER 4 INTERNAL CPU FUNCTIONS
Figure 4-5. Program Memory Map (in µPD750008)
7
6
0
0000H
0002H
0004H
0006H
0008H
000AH
000CH
MBE RBE
MBE RBE
MBE RBE
MBE RBE
MBE RBE
MBE RBE
MBE RBE
Internal reset start address (high-order 6 bits)
Internal reset start address (low-order 8 bits)
INTBT/INT4 start address (high-order 6 bits)
INTBT/INT4 start address (low-order 8 bits)
Entry
address
specified
in CALLF
!faddr
instruc-
tion
INT0 start address
INT0 start address
INT1 start address
INT1 start address
INTCSI start address
INTCSI start address
INTT0 start address
INTT0 start address
INTT1 start address
INTT1 start address
(high-order 6 bits)
(low-order 8 bits)
(high-order 6 bits)
(low-order 8 bits)
(high-order 6 bits)
(low-order 8 bits)
(high-order 6 bits)
(low-order 8 bits)
(high-order 6 bits)
(low-order 8 bits)
Branch
address
specified
in BRCB
!caddr
instruc-
tion
Branch address
specified in
BR !addr,
BR BCDE,
BR BCXA,
BRA !addr1Note
,
,
CALL !addr
or CALLA !addr1Note
Branch/call
address by
GETI
0020H
GETI instruction reference table
007FH
0080H
Relative
branch
address
specified in
BR $addr
instruction
(–15 to –1,
+2 to +16)
07FFH
0800H
0FFFH
1000H
Branch address
specified in BRCB
!caddr instruction
1FFFH
Note Can be used only in the MkII mode.
*
Remark In addition to the above, the BR PCDE and BR PCXA instructions can cause a branch to an
address with only the 8 low-order bits of the PC changed.
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Figure 4-6. Program Memory Map (in µPD75P0016)
7
6
0
0000H
0002H
0004H
0006H
0008H
000AH
000CH
MBE RBE
MBE RBE
MBE RBE
MBE RBE
MBE RBE
MBE RBE
MBE RBE
Internal reset start address (high-order 6 bits)
Internal reset start address (low-order 8 bits)
INTBT/INT4 start address (high-order 6 bits)
INTBT/INT4 start address (low-order 8 bits)
Entry
address
specified
in CALLF
!faddr
instruc-
tion
INT0 start address
INT0 start address
INT1 start address
INT1 start address
INTCSI start address
INTCSI start address
INTT0 start address
INTT0 start address
INTT1 start address
INTT1 start address
(high-order 6 bits)
(low-order 8 bits)
(high-order 6 bits)
(low-order 8 bits)
(high-order 6 bits)
(low-order 8 bits)
(high-order 6 bits)
(low-order 8 bits)
(high-order 6 bits)
(low-order 8 bits)
Branch
address
specified
in BRCB
!caddr
instruc-
tion
Branch address
specified in
BR !addr,
BR BCDE
,
BR BCXA,
BRA !addr1Note
CALL !addr,
,
or CALLA !addr1Note
Branch/call
address by
GETI
0020H
GETI instruction reference table
007FH
0080H
Relative
branch
address
specified in
BR $addr
instruction
(–15 to –1,
+2 to +16)
07FFH
0800H
0FFFH
1000H
Branch address
specified in BRCB
!caddr instruction
1FFFH
Branch address
specified in BRCB
!caddr instruction
2FFFH
3000H
Branch address
specified in BRCB
!caddr instruction
3FFFH
Note Can be used only in the MkII mode.
*
Remark In addition to the above, the BR PCDE and BR PCXA instructions can cause a branch to an
address with only the 8 low-order bits of the PC changed.
52
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CHAPTER 4 INTERNAL CPU FUNCTIONS
4.4 DATA MEMORY (RAM): 512 WORDS x 4 BITS
The data memory consists of a data area and peripheral hardware area as shown in Figure 4-7.
The data memory consists of the following memory banks with each bank made of 256 words x 4 bits.
• Memory banks 0 and 1 (data area)
• Memory bank 15 (peripheral hardware area)
4.4.1 Data Memory Configuration
(1) Data area
The data area consists of a static RAM, and is used for storing program data and as stack memory for
subroutine and interrupt execution. Battery backup enables the memory to hold data for a long time even
if the CPU is stopped in the standby mode. The data area can be manipulated with memory manipulation
instructions.
The static RAM is mapped to memory banks 0 and 1, with each made up of 256 x 4 bits. Bank 0 is used
Note
as a data area, but can also be used as a general register area (000H to 01FH) and stack area
to 1FFH).
(000H
Whole locations in memory banks 0, 1, 2, and 3 (000H to 3FFH) can be used as a stack area.
The static RAM has a configuration of four bits per address. However, the memory can be manipulated
in 8 bit units using an 8-bit memory manipulation instruction, and in bit units using a bit manipulation
instruction. Note that an even address must be specified in an 8-bit manipulation instruction.
Note Memory bank 0 or 1 can be selected as the stack area.
*
• General register area
The general register area can be manipulated with either general register manipulation instructions or
memory manipulation instructions. Up to eight 4-bit registers are available. Of the 8 general registers,
registers not used by the program can be used as a data area or stack area. (See Section 4.5.)
• Stack memory area
The stack memory area is set by the instruction. This area can be used as a save area for subroutine
or interrupt execution. (See Section 4.7.)
(2) Peripheral hardware area
The peripheral hardware area is mapped at addresses F80H to FFFH of memory bank 15.
Memory manipulation instructions are used to manipulate the peripheral hardware area as well as the static
RAM area. Note that, however, the number of bits to be manipulated at a time varies according to the
individual addresses. Addresses to which no peripheral hardware is assigned cannot be accessed since
such address locations contain no data memory. (See Figure 3-7.)
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4.4.2 Specification of a Data Memory Bank
If the memory bank enable flag (MBE) enables bank specification (MBE = 1), a memory bank is specified
with the 4-bit memory bank select register (MBS = 0, 1, 15). If the MBE disables bank specification (MBE
= 0), memory bank 0 or 15 is automatically selected according to the addressing mode. Locations in a bank
is addressed by 8-bit immediate data or a register pair.
For details on the selection of a memory bank and addressing, see Section 3.1.
For how to use the particular data memory areas, see the following sections and chapter.
• General register area
• Stack memory area
: Section 4.5
: Section 4.7
• Peripheral hardware area: Chapter 5
Figure 4-7. Data Memory Map
Data memory
(32 x 4)
Memory bank
000H
Area for
general
register
01FH
020H
256 x 4
(224 x 4)
0
Stack
areaNote
Data area
static RAM
(512 x 4)
0FFH
100H
256 x 4
1
1FFH
F80H
Not contained
Peripheral
hardware area
128 x 4
15
FFFH
Note Memory bank 0 or 1 can be selected as the stack area.
*
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CHAPTER 4 INTERNAL CPU FUNCTIONS
Data memory is undefined when it is reset. For this reason, it is to be initialized to zero (RAM clear) usually
at the start of a program. Remember to perform this initialization. Otherwise, unexpected bugs may occur.
Example The following program clears data at addresses 000H to 1FFH in RAM.
SET1
MBE
SEL
MB0
MOV
XA,#00H
HL,#04H
@HL,A
L
MOV
Note
RAMC0: MOV
; Clear 04H to FFH
; L <– L + 1
INCS
BR
RAMC0
H
INCS
; H <– H + 1
BR
SEL
RAMC0
MB1
RAMC1: MOV
INCS
@HL,A
L
; Clear 100H to 1FFH
; L <– L + 1
BR
RAMC1
H
INCS
; H <– H + 1
Note Data memory locations at 000H to 003H are allocated to general registers XA and HL, so these are
not cleared.
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µPD750008 USER'S MANUAL
4.5 GENERAL REGISTER: 8 x 4 BITS x 4 BANKS
The general registers are mapped to particular addresses in data memory. Four banks of registers are
provided, with each bank consisting of eight 4-bit registers (B, C, D, E, H, L, X, and A).
The register bank (RB) to be enabled at the time of instruction execution is determined by:
RB = RBE·RBS: (RBS = 0 to 3)
Each general register allows 4-bit manipulation. In addition, BC, DE, HL, or XA serves as a register pair
for 8-bit manipulation. DL also makes a register pair as well as DE and HL. These three register pairs can
be used as data pointers.
In 8-bit manipulation, the register pairs in the register banks (0 <—> 1, 2 <—> 3) that have the inverted
value of bit 0 of the register bank (RB) address can be specified as BC’, DE’, HL’, and XA’ in addition to the
register pairs BC, DE, HL, and XA. (See Section 3.2.)
A general register area can be addressed and accessed as normal RAM, regardless of whether it is used
as a register.
Figure 4-8. General Register Format
Data memory
Address
3
0
000H
001H
002H
003H
004H
005H
006H
007H
008H
A register
X register
L register
H register
E register
D register
C register
B register
Register bank 0
Same as bank 0
Same as bank 0
Same as bank 0
Register bank 1
Register bank 2
Register bank 3
00FH
010H
017H
018H
01FH
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CHAPTER 4 INTERNAL CPU FUNCTIONS
Figure 4-9. Register Pair Format
3
0
3
0
B
C
3
3
0
0
3
3
0
0
D
H
E
L
One bank
3
0
3
0
X
A
4.6 ACCUMULATOR
In the µPD750008, the A register and XA register pair function as accumulators. The A register is mainly
used for 4-bit data processing instructions, and the XA register pair is mainly used for 8-bit data processing
instructions.
For a bit manipulation instruction, the carry flag (CY) functions as a bit accumulator.
Figure 4-10. Accumulator
CY
Bit accumulator
4-bit accumulator
8-bit accumulator
A
A
X
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4.7 STACK POINTER (SP) AND STACK BANK SELECT REGISTER (SBS)
The µPD750008 uses static RAM as stack memory (LIFO scheme), and the 8-bit register holding the start
address of the stack area is the stack pointer (SP).
The stack area is located at addresses 000H to 1FFH in memory banks 0 and 1. One memory bank is
selected according to the value of the 2-bit SBS. (See Table 4-2.)
Table 4-2. Stack Area to Be Selected by the SBS
SBS
Stack area
SBS1
SBS0
0
0
0
1
Memory bank 0
Memory bank 1
Not to be set
Other than above
The SP is decremented before a write (save) operation to stack memory, and is incremented after a read
(restoration) operation from stack memory.
Figures 4-12 to 4-15 show data saved to and restored from stack memory in these stack operations.
To place the stack area at a given location, the SP can be initialized with an 8-bit memory manipulation
instruction, and the SBS can be initialized with a 4-bit memory manipulation instruction. Both can be read
from as well.
When the SP is initialized to 00H, a stack operation starts at the high-order address (nFFH) of memory
bank (n) specified with the SBS.
A stack area must be within the memory bank specified with the SBS. If a stack operation exceeds address
n00H, the operation returns to address nFFH in the same bank. Linear stacking beyond memory bank
boundaries is enabled only by resetting the SBS.
A RESET signal causes the contents of the SP to be undefined, and causes the contents of the SBS to
be 1000B. Remember to initialize the SP and SBS to a desired value at the start of a program.
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CHAPTER 4 INTERNAL CPU FUNCTIONS
Figure 4-11. Format of Stack Pointer and Stack Bank Select Register
Address
F80H
Symbol
SP
SP7
SP6
SP5
SP4
SP3
SP2
0
SP1
0
Note
SBS3
F84H
SBS1
SBS
SP
SBS0
000H
Memory bank 0
Memory bank 1
SBS
0FFH
100H
SP
1FFH
Note The Mk I mode and Mk II mode can be switched by bit 3 of SBS. The stack bank selection function
can be used in both Mk I mode and Mk II mode. (See Section 4.1 for details.)
Example SP initialization
Specify memory bank 1 as a stack area to start stack operation at address 1FFH.
SEL
MB15
; or CLR1 MBE
MOV
MOV
MOV
MOV
A,#1
SBS,A
XA,#00H
SP,XA
; Specify memory bank 1 as a stack area
; SP <– 00H
Figure 4-12. Data Saved to the Stack Memory (Mk I Mode)
PUSH instruction
CALL or CALLF instruction
Interrupt
Stack
Stack
Stack
SP – 4
SP – 3
SP – 2
SP – 1
SP
PC11 - PC8
SP – 6
SP – 5
SP – 4
SP – 3
PC11 - PC8
Note
Note
Note
Note
MBE RBE PC13 PC12
MBE RBE PC13 PC12
SP – 2
SP – 1
SP
Lower bits of pair register
Upper bits of pair register
PC3 - PC0
PC3 - PC0
PC7 - PC4
PC7 - PC4
SP – 2 IST1 IST0 MBE RBE
PSW
SP – 1
CY SK2 SK1 SK0
SP
Note PC12 and PC13 are 0 in the µPD750004. PC13 is 0 in the µPD750006 and µPD750008.
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Figure 4-13. Data Restored from the Stack Memory (Mk I Mode)
POP instruction
Stack
RET or RETS instruction
RETI instruction
Stack
Stack
SP
Lower bits of pair register
Upper bits of pair register
SP
PC11 - PC8
SP
PC11 - PC8
Note
Note
Note
Note
SP + 1
SP + 2
SP + 1
SP + 2
SP + 3
SP + 4
SP + 1
SP + 2
SP + 3
MBE RBE PC13 PC12
MBE RBE PC13 PC12
PC3 - PC0
PC3 - PC0
PC7 - PC4
PC7 - PC4
SP + 4 IST1 IST0 MBE RBE
PSW
SP + 5
CY SK2 SK1 SK0
SP + 6
Note PC12 and PC13 are 0 in the µPD750004. PC13 is 0 in the µPD750006 and µPD750008.
Figure 4-14. Data Saved to the Stack Memory (Mk II Mode)
PUSH instruction
Stack
CALL, CALLA, or CALLF instruction
Stack
Interrupt
Stack
SP
SP
SP
SP
SP
SP
–
–
–
–
–
–
6
5
4
3
2
1
PC11 - PC8
SP
SP
SP
SP
SP
SP
–
–
–
–
–
–
6
5
4
3
2
1
PC11 - PC8
Note 1
Note 1
Note 1
Note 1
0
0
PC13 PC12
0
0
PC13 PC12
SP
SP
–
–
2
1
Lower bits of pair register
Upper bits of pair register
PC3 - PC0
PC7 - PC4
PC3 - PC0
PC7 - PC4
MBE RBE
IST1 IST0 MBE RBE
SP
*
*
*
*
Note 2
PSW
CY SK2 SK1 SK0
*
*
SP
SP
Notes 1. PC12 and PC13 are 0 in the µPD750004. PC13 is 0 in the µPD750006 and µPD750008.
2. PSW bits other than MBE and RBE are not saved or restored.
Remark * indicates an undefined bit.
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CHAPTER 4 INTERNAL CPU FUNCTIONS
Figure 4-15. Data Restored from the Stack Memory (Mk II Mode)
POP instruction
Stack
RET or RETS instruction
Stack
RETI instruction
Stack
SP
Lower bits of pair register
SP
PC11 - PC8
SP
PC11 - PC8
Note 1
Note 1
Note 1
Note 1
SP + 1 Upper bits of pair register
SP + 2
SP + 1
SP + 2
SP + 3
SP + 4
SP + 5
SP + 6
0
0
PC13 PC12
SP + 1
SP + 2
SP + 3
SP + 4
SP + 5
SP + 6
0
0
PC13 PC12
PC3 - PC0
PC7 - PC4
PC3 - PC0
PC7 - PC4
MBE RBE
IST1 IST0 MBE RBE
*
*
*
*
Note 2
PSW
CY SK2 SK1 SK0
*
*
Notes 1. PC12 and PC13 are 0 in the µPD750004. PC13 is 0 in the µPD750006 and µPD750008.
2. PSW bits other than MBE and RBE are not saved or restored.
Remark * indicates an undefined bit.
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µPD750008 USER'S MANUAL
4.8 PROGRAM STATUS WORD (PSW): 8 BITS
The program status word (PSW) consists of various flags closely associated with processor operations.
The PSW is mapped to addresses FB0H and FB1H in data memory space. Four bits at address FB0H
can be manipulated with a memory manipulation instruction.
Figure 4-16. Program Status Word Format
Address
FB0H
FB1H
FB0H
Symbol
PSW
CY
SK2
SK1
SK0
IST1
IST0
MBE
RBE
Cannot be manipulated
Can be manipulated
Can be manipulated
by an instruction
specifically provided
for controlling this flag
Table 4-3. PSW Flags Saved/Restored in Stack Operation
Saved/restored flag
Save
When a CALL, CALLA, or CALLF instruction is executed
When a hardware interrupt occurs
MBE and RBE are saved.
All PSW bits are saved.
MBE and RBE are restored.
All PSW bits are restored.
Restore
When a RET or RETS instruction is executed
When a RETI is executed
(1) Carry flag (CY)
The carry flag is a 1-bit flag used to store information about an overflow or underflow that occurs when
an arithmetic operation with a carry (ADDC, SUBC) is executed.
The carry flag functions as a bit accumulator, and therefore can be used to store the result of a Boolean
algebra operation performed on the CY and a bit at a specified data memory bit address.
The carry flag is manipulated using special instructions, independently of the other PSW bits.
A RESET signal causes the carry flag to be undefined.
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CHAPTER 4 INTERNAL CPU FUNCTIONS
Table 4-4. Carry Flag Manipulation Instructions
Instruction (mnemonic)
Carry flag operation/processing
Sets CY to 1.
Clears CY to 0.
Inverts the state of CY.
Skips if CY is 1.
Instruction dedicated to carry
flag manipulation
SET1
CY
CY
CY
CY
CLR1
NOT1
SKT
Bit transfer instruction
Bit Boolean instruction
MOV1
MOV1
mem*.bit, CY
CY, mem*.bit
Transfers the state of CY to a specified bit.
Transfers the state of a specified bit to CY.
AND1
OR1
XOR1
CY, mem*.bit
CY, mem*.bit
CY, mem*.bit
ANDs, ORs, or XORs CY with a specified bit,
then sets the result in CY.
Interrupt handling
Interrupt execution
RETI
Saves CY and all other PSW bits to
stack memory in parallel.
Restores CY together with the other PSW bits
from stack memory in parallel.
Remark mem*.bit represents the following bit addressing:
• fmem.bit
• pmem.@L
• @H+mem.bit
Example Bit 3 at address 3FH is ANDed with P33, then the result is set in P50.
MOV
H,#3H
; Set the high-order 4 bits of the address in H register
; CY <– bit 3 at 3FH
MOV1
AND1
MOV1
CY,@H+0FH.3
CY,PORT3.3
PORT5.0,CY
; CY <– CY P33
; P50 <– CY
(2) Skip flags (SK2, SK1, SK0)
The skip flags are used to store skip status, and are automatically set or reset when the CPU executes
an instruction.
The user cannot directly manipulate these flags by specifying an operand.
(3) Interrupt status flag (IST1, IST0)
The interrupt status flag is a 2-bit flag used to store the status of processing being performed.
See Table 6-3 for details.
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µPD750008 USER'S MANUAL
Table 4-5. Information Indicated by the Interrupt Status Flag
IST1
0
IST0
0
Status of processing
Status 0
Processing and interrupt control being performed
Normal program processing is being performed.
Any interrupts are acceptable.
0
1
1
1
0
1
Status 1
Status 2
A lower- or higher-priority interrupt is being serviced.
Higher-priority interrupts are acceptable.
A higher-priority interrupt is being serviced.
No interrupts are acceptable.
—
Not to be set
The interrupt priority control circuit (Figure 6-1) checks this flag to control multiple interrupts.
The contents of the IST1 and IST0 are saved as part of the PSW to stack memory if an interrupt is accepted,
then are automatically set to a one-step higher status. The RETI instruction restores the contents present
before an interrupt occurs.
The interrupt status flag can be manipulated using a memory manipulation instruction, and the status of
processing being performed can be changed by program control.
Caution The user must always disable interrupts with the DI instruction before manipulating this
flag, and must enable interrupts with the EI instruction after manipulating this flag.
(4) Memory bank enable flag (MBE)
The memory bank enable flag is a 1-bit flag used to specify the address information generation mode for
the high-order four bits of a 12-bit data memory address.
The MBE can be set or reset any time with a bit manipulation instruction, regardless of memory bank
setting.
When the MBE is set to 1, the data memory address space is expanded, allowing all data memory space
to be addressed.
When the MBE is reset to 0, the data memory address space is fixed, regardless of MBS setting. (See
Figure 3-2.)
A RESET signal automatically initializes the MBE by setting the MBE to the content of bit 7 at program
memory address 0.
In vectored interrupt processing, the MBE is automatically set to the content of bit 7 in the vector address
table for servicing the interrupt.
Usually, the MBE is set to 0 in interrupt processing, and static RAM in memory bank 0 is used.
(5) Register bank enable flag (RBE)
The register bank enable flag is a 1-bit flag used to determine whether to expand the general register bank
configuration.
The RBE can be set or reset any time with a bit manipulation instruction, regardless of memory bank
setting.
When the RBE is set to 1, a set of general registers can be selected from register banks 0 to 3, depending
on the setting of the register bank select register (RBS).
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CHAPTER 4 INTERNAL CPU FUNCTIONS
When the RBE is reset to 0, register bank 0 is always selected as general registers, regardless of the setting
of the RBS.
A RESET signal automatically initializes the RBE by setting the RBE to the state of bit 6 at program
memory address 0.
When a vectored interrupt occurs, the RBE is automatically set to the state of bit 6 in the vector address
table for servicing the interrupt. Usually, the RBE is set to 0 in interrupt processing. Register bank 0 is
used for 4-bit processing, and register banks 0 and 1 are used for 8-bit processing.
4.9 BANK SELECT REGISTER (BS)
The bank select register (BS) consists of a register bank select register (RBS) and memory bank select
register (MBS), which specify a register bank and memory bank to be used, respectively.
The RBS and MBS are set using the SEL RBn instruction and SEL MBn instruction, respectively.
The contents of the BS can be saved to or restored from a stack memory eight bits at a time by using the
PUSH BS/POP BS instruction.
Figure 4-17. Bank Select Register Format
Address
F82H
Symbol
BS
F83H
F82H
MBS3 MBS2 MBS1 MBS0
0
0
RBS1 RBS0
(1) Memory bank select register (MBS)
The memory bank select register is a 4-bit register used to store the high-order four bits of a 12-bit data
memory address. The contents of this register specify a memory bank to be accessed. The µPD750008
allows memory banks 0, 1, and 15 only to be specified.
The MBS is set with the SEL MBn instruction (n = 0, 1, 15).
Figure 3-2 shows the range of addressing using MBE and MBS settings.
A RESET signal initializes the MBS to 0.
(2) Register bank select register (RBS)
The register bank select register specifies a register bank to be used as general registers; a register bank
can be selected from register banks 0 to 3.
The RBS is set by the SEL RBn instruction (n = 0 to 3).
A RESET signal initializes the RBS to 0.
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µPD750008 USER'S MANUAL
Table 4-6. Register Bank to Be Selected with the RBE and RBS
RBS
RBE
Register bank
3
0
0
2
0
0
1
x
0
0
1
1
0
x
0
1
0
1
0
1
Bank 0 is always selected.
Bank 0 is selected.
Bank 1 is selected.
Bank 2 is selected.
Bank 3 is selected.
Always 0
x: Don’t care
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CHAPTER 5 PERIPHERAL HARDWARE FUNCTIONS
5.1 DIGITAL I/O PORTS
The µPD750008 employs the memory mapped I/O method. Thus, all input/output ports are mapped on
the data memory space.
Figure 5-1. Data Memory Addresses of Digital Ports
5
Address
FF0H
FF1H
FF2H
FF3H
FF4H
FF5H
FF6H
3
2
1
0
P03
P13
P23
P33
P43
P53
P02
P12
P22
P32
P42
P52
P01
P11
P21
P31
P41
P51
P00
P10
P20
P30
P40
P50
PORT 0
PORT 1
PORT 2
PORT 3
PORT 4
PORT 5
PORT 6
P63
P62
P61
P60
FF7H
FF8H
P73
–
P72
–
P71
P81
P70
P80
PORT 7
PORT 8
Remark Some I/O parts can be used as static RAM.
Input/output port manipulation instructions are as listed in Table 5-2. Ports 4 to 7 can be manipulated not
only in 4-bit units, but also in 8-bit or 1-bit units so that these ports can be controlled in various ways.
Example 1. To test the condition of P13 and output different values to ports 4 and 5 according to the test
result:
SKT
PORT1. 3 ; Skips if bit 3 of port 1 is 1
MOV XA, #18H ; XA <– 18H
MOV XA, #14H ; XA <– 14H
String-effect instructions
SEL
MB15
; Or CLR1 MBE
OUT PORT4, XA ; Port 5, 4 <– XA
2. SET1 PORT4. @L; Sets the bit(s) specified by the L register, in ports 4 to 7, to 1.
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5.1.1 Types, Features, and Configurations of Digital I/O Ports
Table 5-1 lists the types of digital I/O ports.
Figures 5-2 to 5-6 show the configurations of the ports.
Table 5-1. Types and Features of Digital Ports
Port name
(symbol)
Function
4-bit I/O
Operation and feature
Remarks
Allows read and test at any timeregard
less of the operation modes of another
functions assigned to these pins.
PORT0
Also used as INT4, SCK, SO/SB0,
and SI/SB1.
PORT1
Also used as INT0 to INT2 and
TI0.
Note 1
Note 2
Allows input or output mode setting bit
by bit.
PORT3
PORT6
PORT2
4-bit I/O
Also used as MD0 to MD3
Also used as KR0 to KR3.
.
Ports 6 and 7 can be paired, allowing
data I/O in units of 8 bits. Allows input
or output mode setting in units of 4 bits.
Also used as PTO0, PTO1, PCL,
and BUZ.
PORT7
Also used as KR4 to KR7.
Note 1
Note 1
PORT4
PORT5
4-bit I/O
Allows input or output mode setting in
Whether to use pull-up resistors
(N-ch open-drain; units of 4 bits. Ports 4 and 5 can be
can withstand
13V)
can be specified bit by bit with a
Note 3
paired, allowing data I/O in units of
8 bits.
mask option
.
*
*
PORT8
2-bit I/O
Allows input or output mode setting in
units of 2 bits.
Notes 1. Can directly drive the LED.
2. Only for the µPD75P0016.
3. The µPD75P0016 does not have a mask option and cannot be connected with a pull-up resistor.
P10 is also used as an external vectored interrupt input pin. This input is provided with a noise eliminator.
(See Section 6.3 for details.)
When the RESET signal is generated, output latches of ports 2 to 8 are cleared to 0 and the output buffer
is turned off so that these ports are in the input mode.
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CHAPTER 5 PERIPHERAL HARDWARE FUNCTIONS
Figure 5-2. Configurations of Ports 0 and 1
Internal
SCK
SI
SCK INT4
SO
P01
output
latch
VDD
Pull-up
resistor
Selector
Selector
8
CSIM
P-ch
Bit 0 of
POGA
P00/INT4
P01/SCK
P02/SO/SB0
P03/SI/SB1
Input buffer
Output buffer which can
be switched to either
push-pull output or N-ch
open-drain output
N-ch
open drain
VDD
Pull-up
resistor
P-ch
Bit 1 of
POGA
Φ or fX/64
Input buffer
Noise
eliminator
P10/INT0
P11/INT1
P12/INT2
P13/TI0
Input buffer with hysteresis
TI0 INT2 INT1 INT0
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µPD750008 USER'S MANUAL
Figure 5-3. Configurations of Ports 2 and 7
VDD
Pull-up
resistor
P-ch
Bit m of
POGA
Key interruptNote
PMm = 0
Input buffer
M
P
X
PMm = 1
Input buffer with
hysteresisNote
Pm0
Pm1
Pm2
Pm3
Output
latch
Output buffer
PMm
Bits 2 and 7 of port mode
register group B (m = 2, 7)
Note For port 7 only
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CHAPTER 5 PERIPHERAL HARDWARE FUNCTIONS
Figure 5-4. Configurations of Ports 3n and 6n (n = 0 to 3)
Key interruptNote
Input buffer with
hysteresisNote
VDD
Pull-up
PMmn = 0
Input buffer
M
P
X
resistor
PMmn = 1
Bit m of
POGA
P-ch
Output latch
Output buffer
Pmn
PMmn
Corresponding bits of
m = 3, 6
port mode register group A
n = 0 to 3
Note For port 6n only
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µPD750008 USER'S MANUAL
Figure 5-5. Configurations of Ports 4 and 5
VDD
Pull-up resistor
(Mask option)
Input buffer
PMm = 0
MPX
PMm = 1
Pm0
Pm1
Pm2
Pm3
Output
latch
N-ch open-drain
output buffer
PMm
Corresponding bits of port mode
register group B (m = 4, 5)
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CHAPTER 5 PERIPHERAL HARDWARE FUNCTIONS
Figure 5-6. Configuration of Port 8
VDD
Pull-up
resistor
P-ch
Bit 0 of
POGB
Input buffer
PM8 = 0
M
P
X
PM8 = 1
Output buffer
P80
P81
Ouput
latch
PM8
Corresponding bit of port
mode register group C
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µPD750008 USER'S MANUAL
5.1.2 I/O Mode Setting
The I/O mode of each I/O port is set by the port mode register as shown in Figure 5-7. The I/O modes
of ports 3 and 6 can be set bit by bit by port mode register group A (PMGA). The I/O modes of ports 2, 4,
5, and 7 can be set in units of four bits by port mode register group B (PMGB). The I/O mode of port 8 can
be set in units of two bits by port mode register group C (PMGC).
Each port functions as an input port when the corresponding bit of the port mode register is set to 0, and
functions as an output port when the same corresponding bit is set to 1.
When the output mode is selected by the port mode register, the contents of the output latch appear on
the output pins, and so the contents of the output latch must be changed to a desired value before the output
mode is set.
An 8-bit memory manipulation instruction is used to set port mode register group A, B, or C.
A RESET signal clears all bits of each port mode register to 0. This means that the output buffers are set
off, and all ports are placed in the input mode.
Example P30, P31, P62, and P63 are used as input pins, and P32, P33, P60, and P61 are used as output
pins.
CLR1
MOV
MOV
MBE
; or SEL MB15
XA,#3CH
PMGA,XA
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CHAPTER 5 PERIPHERAL HARDWARE FUNCTIONS
Figure 5-7. Formats of Port Mode Registers
Contents of specification
Input mode (Output buffer off)
Output mode (Output buffer on)
0
1
Port mode register group A
Address
Symbol
PMGA
7
6
5
4
3
2
1
0
FE8H
PM63 PM62 PM61 PM60 PM33 PM32 PM31 PM30
P30 I/O specification
P31 I/O specification
P32 I/O specification
P33 I/O specification
P60 I/O specification
P61 I/O specification
P62 I/O specification
P63 I/O specification
Port mode register group B
Address
Symbol
PMGB
7
6
5
4
3
2
1
0
FECH
PM7
—
PM5
PM4
—
PM2
—
—
Port 2 (P20 - P23) I/O specification
Port 4 (P40 - P43) I/O specification
Port 5 (P50 - P53) I/O specification
Port 7 (P70 - P73) I/O specification
Port mode register group C
Address
Symbol
PMGC
7
6
5
4
3
2
1
0
FEEH
—
—
—
—
—
—
—
PM8
Port 8 (P80, P81) I/O specification
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µPD750008 USER'S MANUAL
5.1.3 Digital I/O Port Manipulation Instructions
All I/O ports contained in the µPD750008 are mapped to data memory space, so that all data memory
manipulation instructions can be used. Table 5-3 lists the instructions that are particularly useful for I/O pin
manipulation and their application ranges.
(1) Bit manipulation instructions
For digital I/O ports PORT0 to PORT8, specific address bit direct addressing (fmem.bit) and specific
address bit register indirect addressing (pmem.@L) can be used. This means that bit manipulation can
be freely performed for these ports regardless of MBE and MBS settings.
Example P50 is ORed with P41, then the result is output to P61.
SET1
AND1
OR1
SKT
CY
; CY <– 1
CY,PORT5.0 ; CY <– CY P50
CY,PORT4.1 ; CY <– CY P41
CY
BR
CLRP
SET1
PORT6.1
; P61 <– 1
; P61 <– 0
.
.
.
CLRP :
CLR1
PORT6.1
(2) 4-bit manipulation instructions
All 4-bit memory manipulation instructions including the IN, OUT, MOV, XCH, ADDS, and INCS
instructions can be used. However, before these instructions can be executed, memory bank 15 must
be selected.
Examples 1. The contents of the accumulator are output to port 3.
SEL
MB15
; or CLR1 MBE
OUT
PORT3,A
2. The value of the accumulator is added to the data output on port 5, then the result is output.
SET1
SEL
MBE
MB15
MOV
HL,#PORT5
ADDS A,@HL
NOP
; A <– A+PORT5
; PORT5 <– A
MOV
@HL,A
3. Whether the data on port 4 is greater than the value of the accumulator is tested.
SET1
SEL
MBE
MB15
MOV
HL,#PORT4
SUBS A,@HL
BR NO
; A < PORT4
; NO
; YES
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CHAPTER 5 PERIPHERAL HARDWARE FUNCTIONS
(3) 8-bit manipulation instructions
The MOV, XCH, and SKE instructions as well as the IN and OUT instructions can be used for ports 4 and
5 that allow 8-bit manipulation. As with 4-bit manipulation, memory bank 15 must be selected in advance.
Example The data contained in the BC register pair is output on the output port specified by 8-bit data
applied to ports 4 and 5.
SET1
SEL
IN
MBE
MB15
XA,PORT4
HL,XA
; XA <– ports 5,4
; HL <– XA
MOV
MOV
MOV
XA,BC
@HL,XA
; XA <– BC
; Port (L) <– XA
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µPD750008 USER'S MANUAL
Table 5-2. I/O Pin Manipulation Instructions
PORT
PORT
PORT
1
PORT
2
PORT
3
PORT
4
PORT
5
PORT
6
PORT
7
PORT
8
Instruction
0
Note 1
IN
IN
A, PORTn
XA, PORTn
Note 1
Note 1
Note 1
—
—
—
—
—
—
—
—
—
—
—
OUT PORTn, A
OUT PORTn, XA
SET1 PORTn.bit
SET1 PORTn.@L
CLR1 PORTn.bit
CLR1 PORTn.@L
SKT PORTn.bit
SKT PORTn.@L
SKF PORTn.bit
SKF PORTn.@L
MOV1 CY, PORTn.bit
Note 2
Note 2
Note 2
Note 2
Note 2
*
*
*
*
MOV1 CY, PORTn.@L
MOV1 PORTn.bit,CY
—
—
—
—
Note 2
MOV1 PORTn.@L,CY
AND1 CY, PORTn.bit
AND1 CY, PORTn.@L
OR1 CY, PORTn.bit
OR1 CY, PORTn.@L
XOR1 CY, PORTn.bit
XOR1 CY, PORTn.@L
Note 2
Note 2
Note 2
Notes 1. MBE = 0 or (MBE = 1, MBS = 15) must be set before execution.
2. The low-order two bits of an address and bit address are indirectly specified using the L register.
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CHAPTER 5 PERIPHERAL HARDWARE FUNCTIONS
5.1.4 Digital I/O Port Operation
When a data memory manipulation instruction is executed for a digital I/O port, the operation of the port
and pins depends on the I/O mode setting (Table 5-3). This is because data taken in on the internal bus is
the data input from the pins in the input mode, or the output latch data in the output mode, as obvious from
the configurations of I/O ports.
(1) Operation when the input mode is set
Data from each pin is manipulated when a test instruction such as the SKT instruction ,a bit input instruction
such as MOV1,or an instruction for taking in port data on the internal bus in units of four or eight bits (such
as an IN, OUT, arithmetic/logical or comparison instruction) is executed.
*
When an instruction (the OUT or MOV instruction) is executed to transfer the contents of the accumulator
to a port in units of four or eight bits, the data of the accumulator is latched in the output latch, with the
output buffers kept off.
When the XCH instruction is executed, the data on each pin is loaded into the accumulator, and the data
in the accumulator is latched in the output latch, with the output buffers kept off.
When the INCS instruction is executed, the 4-bit data existing on the pins plus 1 is latched in the output
latch, with the output buffers kept off.
When an instruction such as the SET1, CLR1, or SKTCLR instruction is executed to rewrite a data memory
bit, the output latch data of the specified bit can be rewritten according to the instruction, but the states
of the other output latch bits are undefined.
(2) Operation when the output mode is set
When a test instruction or instruction for taking in port data on the internal bus in units of four or eight
bits is executed, output latch data is manipulated.
When an instruction is executed to transfer the contents of the accumulator in units of four or eight bits,
the output latch data is rewritten, and is output on the pins.
When the XCH instruction is executed, the output latch data is transferred to the accumulator. The
contents of the accumulator are latched in the output latches, and are output on the pins.
When the INCS instruction is executed, the contents of the output latch incremented by 1 are latched in
the output latch, and are output on the pins.
When a bit output instruction is executed, the specified bit of the output latch is rewritten, and is output
on the pin.
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µPD750008 USER'S MANUAL
Table 5-3. Operations by I/O Port Manipulation Instructions
Port and pin operation
Instruction
Input mode
Pin data is tested.
Output mode
SKT
SKF
<1>
<1>
Output latch data is tested.
MOV1 CY, <1>
Pin data is transferred to CY.
Output latch data is transferred to CY.
*
AND1 CY, <1>
An operation is performed on pin data and
CY.
An operation is performed
on output latch data and CY.
OR1
CY, <1>
XOR1 CY, <1>
IN
IN
A,PORTn
XA,PORTn
Pin data is transferred to the accumulator.
Output latch data is transferred to the
accumulator.
MOV A,@HL
MOV XA,@HL
ADDS A,@HL
ADDC A,@HL
SUBS A,@HL
SUBC A,@HL
An operation is performed on pin data and
the accumulator.
An operation is performed
on output latch data and the accumulator.
AND
OR
XOR
A,@HL
A,@HL
A,@HL
SKE
SKE
A,@HL
XA,@HL
Pin data is compared with the
accumulator.
Output latch data is com-
pared with the accumulator.
OUT
OUT
PORTn,A
Accumulator data is transferred to the
Accumulator data is transferred to the
output latch and is output on the pins.
PORTn,XA output latch (with the output buffers kept
MOV @HL,A
MOV @HL,XA
off).
XCH
XCH
XCH
XCH
A,PORTn
Pin data is transferred to the accumulator,
Data is exchanged between the output
latch and accumulator.
XA,PORTn and accumulator data is transferred to the
A,@HL
XA,@HL
output latch (with the output buffers kept
off).
INCS PORTn
INCS @HL
Pin data incremented by 1 is latched in
the output latch.
Output latch data is incremented by 1.
SET1 <1>
CLR1 <1>
MOV1 <1> ,CY
SKTCLR <1>
The output latch data of a specified bit is
rewritten, but the output latch data of the
other bits is undefined.
The output pin state is modified according
to the instruction.
*
<1> : Represents an addressing mode PORTn.bit or PORTn.@L.
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CHAPTER 5 PERIPHERAL HARDWARE FUNCTIONS
5.1.5 Specification of Bilt-in Pull-Up Resistors
A pull-up resistor can be contained at each port pin of the µPD750008 (except for P00). Whether to use
the pull-up resistor can be specified by software (for some pins) or a mask option (for the other pins).
Table 5-4 shows how a built-in pull-up resistor is specified for each port pin. The built-in pull-up resistor
is connected by software in the format shown in Figure 5-8.
Table 5-4. Specification of Built-in Pull-Up Resistors
Port (pin name)
Pull-up resistor incorporation specification method
Bit of POGA
Bit of POGB
Note
Port 0 (P01-P03)
Port 1 (P10-P13)
Port 2 (P20-P23)
Port 3 (P30-P33)
Port 6 (P60-P63)
Port 7 (P70-P73)
Port 4 (P40-P43)
Port 5 (P50-P53)
Port 8 (P80, P81)
Connection specification by software in 3-bit units
Connection specification by software in 4-bit units
Bit 0
Bit 1
Bit 2
Bit 3
Bit 6
Bit 7
—
—
—
—
—
—
—
—
Incorporation specification by mask option in 1-bit
units
Connection specification by software in-2-bit units
—
Bit 0
Note The P00 pin cannot specify connection of a built-in pull-up resistor.
Remark The port pins of the µPD75P0016 are not connected to a pull-up resistor by mask option, and
are always open.
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Figure 5-8. Pull-Up Resistor Specification Register Format
Specification contents
0
1
Built-in pull-up resistor not connected
Built-in pull-up resistor connected
Pull-up resistor specification register group A
Address
Symbol
POGA
7
6
5
4
3
2
1
0
FDCH
PO7
PO6
—
—
PO3
PO2
PO1
PO0
Port 0 (P01 - P03)
Port 1 (P10 - P13)
Port 2 (P20 - P23)
Port 3 (P30 - P33)
Port 6 (P60 - P63)
Port 7 (P70 - P73)
Pull-up resistor specification register group B
Address
Symbol
POGB
7
6
5
4
3
2
1
0
—
—
—
—
FDEH
—
—
—
PO8
Port 8 (P80, P81)
5.1.6 I/O Timing of Digital I/O Ports
Figure 5-9 shows the timing of data output to an output latch and the timing of taking in pin data or output
latch data on the internal bus.
Figure 5-10 shows an ON timing chart when a built-in pull-up resistor is connected to a port pin by software.
Figure 5-9. I/O Timing Chart of Digital I/O Ports (1/2)
(a) When data is input by a 1-machine cycle instruction
1 machine cycle
Instruction
Manipulation instruction
execution
Input timing
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CHAPTER 5 PERIPHERAL HARDWARE FUNCTIONS
Figure 5-9. I/O Timing Chart of Digital I/O Ports (2/2)
(b) When data is input by a 2-machine cycle instruction
2 machine cycles
Instruction
Manipulation instruction
execution
Input timing
(c) When data is latched by a 1-machine cycle instruction
Φ
3
Φ
0
Φ
1
Instruction
execution
Manipulation instruction
Output latch
(output pin)
(d) When data is latched by a 2-machine cycle instruction
Φ
0
Φ
1
Instruction
execution
Manipulation instruction
Output latch
(output pin)
Figure 5-10. ON Timing Chart of Built-in Pull-Up Resistor Connected by Software
2 machine cycles
Instruction
execution
Built-in pull-up resistor setting instruction
Pull-up resistor
specification
register
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5.2 CLOCK GENERATOR
The clock generator supplies various clock signals to the CPU and peripheral hardware to control the CPU
operation mode.
5.2.1 Clock Generator Configuration
Figure 5-11 shows the configuration of the clock generator.
Figure 5-11. Block Diagram of the Clock Generator
• Basic interval timer (BT)
• Timer/event counter
• Timer counter
• Serial interface
• Clock timer
XT1
fXT
Subsystem
clock generator
Clock timer
XT2
X1
• INT0 noise eliminator
• Clock output circuit
f
X
1/1 to 1/4096
Frequency divider
Main system
clock generator
X2
1/2 1/4 1/16
Selec-
tor
Oscillator
disable
signal
WM.3
SCC
Frequency
divider
SCC3
SCC0
Selec-
tor
1/4
Φ
•
•
•
CPU
INT0 noise eliminator
Clock output circuit
PCC
PCC0
PCC1
PCC2
PCC3
4
HALT flip-flop
S
HALTNote
STOPNote
Q
R
PCC2, PCC3
clear signal
STOP flip-flop
Wait release signal from BT
Q
S
RESET signal
R
Standby release signal from
interrupt control circuit
Note Instruction execution
Remarks 1. f : Main system clock frequency
X
2. f : Subsystem clock frequency
XT
3. F = CPU clock
4. PCC: Processor clock control register
5. SCC: System clock control register
6. One clock cycle (t ) of the CPU clock (F) is equal to one machine cycle of an instruction.
CY
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CHAPTER 5 PERIPHERAL HARDWARE FUNCTIONS
5.2.2 Functions and Operations of the Clock Generator
The clock generator generates the following clocks, and controls the CPU operation modes such as the
standby mode.
• Main system clock f
X
• Subsystem clock f
XT
• CPU clock F
• Clock to peripheral hardware
The operation of the clock generator is determined by the processor clock control register (PCC) and system
clock control register (SCC). The function and operation of the clock generator are described in (a) to (g) below.
Note 1
(a) A RESET signal selects the lowest-speed mode (10.7 µs at 6.00 MHz)
(PCC = 0, SCC = 0).
for the main system clock
(b) When the main system clock is selected, the PCC can be set to select one of four CPU clocks (0.67
Note 2
µs, 1.33 µs, 2.67 µs, and 10.7 µs at 6.00 MHz)
.
(c) When the main system clock is selected, the two standby modes, STOP mode and HALT mode, are
available.
(d) The SCC can be set to select the subsystem clock for very low-speed, low-current operation (122 µs
at 32.768 kHz). The value in the PCC does not affect the CPU clock.
(e) When the subsystem clock is selected, main system clock generation can be stopped with the SCC.
In addition, the HALT mode can be used, but the STOP mode cannot be used. (Subsystem clock
generation cannot be stopped.)
(f) The clock to be supplied to peripheral hardware is produced by frequency-dividing the main system
clock signal. The subsystem clock can directly be supplied only to the clock timer. This enables the
clock function and the buzzer output function to continue operating even in the standby state.
(g) When the subsystem clock is selected, the clock timer can continue to operate normally. The serial
interface, timer/event counter, and timer counter can continue to operate when the external clock is
selected. However, other hardware cannot be used when the main system clock is stopped because
they operate with the main system clock.
Notes 1. At f = 4.19 MHz: 15.3 µs
X
2. At f = 4.19 MHz: 0.95 µs, 1.91 µs, 3.81 µs, and 15.3 µs
X
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(1) Processor clock control register (PCC)
The PCC is a 4-bit register for selecting a CPU clock F with the low-order two bits and for controlling the
CPU operation mode with the high-order two bits (see Figure 5-12).
When bit 3 or bit 2 is set to 1, the standby mode is set. When the standby mode is released by the standby
release signal, these bits are automatically cleared to return to the normal operation mode. (SeeChapter
7 for details.)
A 4-bit memory manipulation instruction is used to set the low-order two bits of the PCC. (The high-order
two bits are set to 0.)
Bit 3 and bit 2 are set to 1 using the STOP instruction and HALT instruction, respectively.
The STOP instruction and HALT instruction can always be executed regardless of MBE setting.
The CPU clock can be selected only while the processor is operated by the main system clock. When
the processor is operated by the subsystem clock, the low-order 2 bits of the PCC are invalidated, and
f
/4 is automatically set. The STOP instruction can be executed only when the processor is operated
XT
by the main system clock.
Examples 1. The machine cycle is entered in highest-speed mode (0.67 µs at f = 6.00 MHz).
X
SEL MB15
MOV A,#0011B
MOV PCC,A
2. The machine cycle is set to 1.91 µs (at f = 4.19 MHz).
X
SEL MB15
MOV A,#0010B
MOV PCC,A
3. The STOP mode is set. (A STOP instruction or HALT instruction must always be followed
by an NOP instruction.)
STOP
NOP
A RESET signal clears the PCC to 0.
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CHAPTER 5 PERIPHERAL HARDWARE FUNCTIONS
Figure 5-12. Format of the Processor Clock Control Register
Address
FB3H
Symbol
PCC
3
2
1
0
PCC3 PCC2 PCC1 PCC0
CPU clock selection bit
(Operation with fX = 6.0 MHz)
SCC3, SCC0 = 00
SCC3, SCC0 = 01 or 11
( ) is actual frequency at fX = 6.0 MHz ( ) is actual frequency at fXT = 32.768 kHz
CPU clock frequency 1 machine cycle CPU clock frequency 1 machine cycle
0
0
1
1
0
1
0
1
Φ = fXT/4 (8.192 kHz)
122 µs
Φ = fX/64 (93.7 kHz)
Φ = fX/16 (375 kHz)
Φ = fX/8 (750 kHz)
Φ = fX/4 (1.5 MHz)
10.7 µs
2.67 µs
1.33 µs
0.67 µs
(Operation with fX = 4.19 MHz)
SCC3, SCC0 = 00
SCC3, SCC0 = 01 or 11
( ) is actual frequency at = 4.19 MHz ( ) is actual frequency at fXT = 32.768 kHz
f
X
CPU clock frequency 1 machine cycle CPU clock frequency 1 machine cycle
Φ = fXT/4 (8.192 kHz)
122 µs
0
0
1
1
0
1
0
1
15.3 µs
3.81 µs
1.91 µs
0.95 µs
Φ = fX/64 (65.5 kHz)
Φ = fX/16 (262 kHz)
Φ = fX/8 (524 kHz)
Φ = fX/4 (1.05 MHz)
Remarks 1. fX
:
Output frequency from the main system clock oscillator
2. fXT: Output frequency from the subsystem clock oscillator
CPU operation mode control bits
0
0
1
1
0
1
0
1
Normal operation mode
HALT mode
STOP mode
Not to be set
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(2) System clock control register (SCC)
The SCC is a 4-bit register for selecting CPU clock F with the least significant bit and for controlling the
termination of main system clock generation with the most significant bit (see Figure 5-13).
Bits 0 and 3 of the SCC are located at the same data memory address, but both bits cannot be changed
at the same time. Accordingly, bits 0 and 3 of the SCC are set using bit manipulation instructions. Bits
0 and 3 of the SCC can be manipulated regardless of MBE setting.
Main system clock generation can be terminated by setting bit 3 of the SCC only when the subsystem
clock is used for operation. The STOP instruction must be used to terminate main system clock generation.
A RESET signal clears the SCC to 0.
Figure 5-13. Format of the System Clock Control Register
Address
FB7H
3
2
1
0
Symbol
SCC
—
—
SCC3
SCC0
SCC3 SCC0
CPU clock frequency
Main system clock
Main system clock operation
Can oscillate
0
0
1
1
0
1
0
1
Subsystem clock
Not to be set
Subsystem clock
Oscillation stopped
Cautions 1. A time period of up to 1/f is needed to change the system clock. This means
XT
that to terminate main system clock generation, bit 3 of the SCC must be set to 1
when the machine cycles indicated in Table 5-4 or more have elapsed after the
clock is switched from the main system clock to the subsystem clock.
2. When the main system clock is used for operation, setting bit 3 of the SCC to
stop clock generation does not enter the normal STOP mode.
3. When the PCC is set to 0001B (F = f /16), do not set SCC.0 to 1. Before switch-
X
ing the main system clock to the subsystem clock, be sure to manipulate the
PCC so other than 0001B is set. When the system operates on the subsystem
clock, the PCC must also be other than 0001B.
4. When SCC.3 is set to 1, the X1 input pin is connected to V (ground electric
SS
potential) to prevent leakage in the crystal oscillator. When an external clock is
used as the main system clock, never set SCC.3 to 1.
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CHAPTER 5 PERIPHERAL HARDWARE FUNCTIONS
(3) System clock oscillator
The main system clock oscillator operates with a crystal resonator or ceramic resonator connected to the
X1 and X2 pins.
An external clock can also be input. Input the clock signal to the X1 pin and the reversed signal to the
X2 pin.
Figure 5-14. External Circuit for the Main System Clock Oscillator
(a) Crystal/ceramic oscillation
(b) External clock
µPD750008
X1
µPD750008
External
clock
VSS
X1
X2
X2
Crystal or ceramic resonator
(Standard frequency: 6.0 or 4.19 MHz)
The subsystem clock oscillator operates with a crystal resonator (32.768 kHz standard) connected to the
XT1 and XT2 pins.
An external clock can also be input. Input the clock signal to the XT1 pin and leave the XT2 pin open.
The state of the XT1 pin is tested by bit 3 of the clock mode register (WM).
Figure 5-15. External Circuit for the Subsystem Clock Oscillator
(a) Crystal oscillation
(b) External clock
µPD750008
XT1
µPD750008
External
clock
VSS
XT1
XT2
Open XT2
Crystal
(Standard frequency: 32.768 kHz)
Cautions 1. When the external clock is used as the main system clock or subsystem clock, the
STOP mode cannot be set. This is because the X1 pin is connected to V in the STOP
SS
mode.
2. When the main system clock or subsystem clock oscillator is used, conform to
the following guidelines when wiring enclosed in broken lines of Figures 5-14
and 5-15 to eliminate the influence of the stray capacitance around the wiring.
• The wiring must be as short as possible.
• Other signal lines must not run in these areas.
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Any line carrying a high pulsating current must be kept away as far as possible.
• The grounding point of the capacitor of the oscillator must have the same
potential as that of V . It must not be grounded to a grounding pattern carry
SS
ing a high current.
• No signal must be taken directly from the resonator.
The subsystem clock oscillator has low amplification to minimize current con-
sumption. For this reason, more malfunctions can occur due to noise than the
main system clock oscillator. So pay special attention to wiring when using the
subsystem clock.
Figure 5-16 gives examples of oscillator connections which should be avoided.
Figure 5-16. Examples of Oscillator Connections Which Should Be Avoided (1/2)
(a) The wiring is too long.
(b) The signal lines cross.
PORTn
(n = 0 to 8)
µPD750008
µPD750008
VSS
X1
X2
VSS
X1
X2
Remark When wiring the subsystem clock, read X1 and X2 as XT1 and XT2 respectively. In this case,
a resistor must be added to XT2 in series.
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CHAPTER 5 PERIPHERAL HARDWARE FUNCTIONS
Figure 5-16. Examples of Oscillator Connections Which Should Be Avoided (2/2)
(c) A high pulsating current is too
close to the signal line.
(d) The current flows through the ground
line of the oscillator. (The potential
at points A, B, and C fluctuates.)
VDD
µPD750008
µPD750008
Pnm
VSS
X1
X2
VSS
X1
X2
High current
A
B
C
High current
(e) A signal is taken directly from
the resonator.
(f) The signal lines of the main system
clock and subsystem clock are parallel
and adjacent to each other.
µPD750008
µPD750008
VSS
X1
X2
VSS
XT1
XT2
X1
X2
XT2 and XT1 are wired
in parallel.
Remark When wiring the subsystem clock, read X1 and X2 as XT1 and XT2 respectively. In this case,
a resistor must be added to XT2 in series.
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(4) Frequency divider
The frequency divider divides the output (f ) of the main system clock oscillator to generate various clocks.
X
(5) Control functions of subsystem clock oscillator
The subsystem clock oscillator of the µPD750008 subseries has two control functions to decrease the
supply current.
• The function to select with the software whether to use the built-in feedback resistor
• The function to suppress the supply current by reducing the drive current of the built-in inverter when
the operating supply voltage is high (V
• 2.7 V)
DD
Each function can be used by switching bits 0 and 1 in the sub-oscillator control register (SOS). (See
Figure 5-17.)
Figure 5-17. Subsystem Clock Oscillator
SOS.0
Feedback resistor
Inverter
µPD750008
SOS.1
XT1
XT2
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CHAPTER 5 PERIPHERAL HARDWARE FUNCTIONS
(6) Sub-oscillator control register (SOS)
The SOS register specifies whether to use the built-in feedback register and controls the drive current
of the built-in inverter. (See Figure 5-18.)
Inputting a RESET signal clears all bits of the SOS register. The functions of each flag in the SOS register
are described below.
(a) SOS.0 (feedback resistor cut flag)
*
To use the feedback resistor of the subsystem clock, the mask option setup and switching SOS.0 by
software are required. Set SOS.0 to 0 to turn on the feedback circuit.
When the resonator is not used, set SOS.0 to 1. The feedback circuit is turned off, reducing the current
drain.
To use the resonator, be sure to select "Enable the feedback resistor" upon setting the mask option.
Then, set SOS.0 to 0 (feedback circuit is turned on).
(b) SOS.1 (drive capability switch flag)
The built-in inverter in the subsystem clock oscillator of the µPD750008 subseries has a large drive
current because it can be used at low supply voltage (V = 1.8 V), so that the supply current becomes
DD
too high to use at high supply voltage (V
• 2.7 V). To reduce the supply current, set SOS.1 to 1
DD
so as to reduce the drive current of the inverter.
However, if SOS.1 is set to 1 when V is less than 2.7 V, the oscillation may stop for insufficient
DD
drive current. Set this flag to 0 when V
is less than 2.7 V.
DD
Figure 5-18. Sub-Oscillator Control Register (SOS) Format
Address
FCFH
Symbol
3
0
2
0
1
0
SOS1 SOS0
SOS
Cut flag for feedback resistor of the sub-oscillator
0
1
Built-in feedback resistor is used.
Built-in feedback resistor is not used.
Cut flag for the sub-oscillator current
0
1
Drive current is high (1.8 V ≤ VDD)
Drive current is low (2.7 V ≤ VDD)
Bits 2 and 3 of SOS must be set to 0.
Remark If the subsystem clock is not required , the XT1 and XT2 pins and SOS register must be
treated as follows:
XT1 : Connected to V or V
.
DD
SS
XT2 : Open
SOS: 0001B
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5.2.3 System Clock and CPU Clock Setting
(1) Time required to change the system clock and CPU clock
The system clock and CPU clock can be changed by using the least significant bit of the SCC and the
low-order two bits of the PCC. This switching is not performed immediately after the contents of the
registers are rewritten, but the system operates with the previous clock for some machine cycles.
Accordingly, after this time period, the STOP instruction must be executed to terminate main system clock
generation.
Table 5-5. Maximum Time Required to Change the System Clock and CPU Clock
Setting before
Setting after switching
switching
SCC0 PCC1 PCC0 SCC0 PCC1 PCC0 SCC0 PCC1 PCC0 SCC0 PCC1 PCC0 SCC0 PCC1 PCC0 SCC0 PCC1 PCC0
0
0
0
0
0
1
0
1
0
0
1
1
1
x
x
0
0
0
1
1
x
0
1
0
1
x
1 machine
cycle
1 machine
cycle
1 machine
cycle
fX/64fXT machine
cycles
(3 machine cycles)
4 machine
cycles
4 machine
cycles
4 machine
cycles
Not to be set
8 machine
cycles
8 machine
cycles
8 machine
cycles
fX/8fXT machine
cycles
(23 machine cycles)
16 machine
cycles
16 machine
cycles
16 machine
cycles
fX/4fXT machine
cycles
(46 machine cycles)
1
1 machine
cycle
Not to be
set
1 machine
cycle
1 machine
cycle
Remarks 1. Time indicated in parentheses is required when f = 6.00 MHz and f = 32.768 kHz.
X
XT
2. X: Dont care
3. CPU clock F is supplied to the CPU of the µPD750008. The reciprocal of this frequency
is a minimum instruction time (defined as one machine cycle in this manual).
Cautions 1. When the PCC is set to 0001B (F = f /16), do not set SCC.0 to 1. Before switching
X
the main system clock to the subsystem clock, be sure to manipulate the PCC so
other than 0001B is set. When the system operates on the subsystem clock, the
PCC must also be other than 0001B.
2. The fluctuation of the ambient temperature around an oscillator and the performance
of a load capacity change f and f . In particular, when f is higher than the nominal
X
XT
X
value or f is lower than the nominalvalue, the machine cycles calculated by f /64f ,
XT
XT
X
f / 8f , and f /4f in Table 5-5 are longer than the machine cycle calculated by the
X
XT
X
XT
nominal values of f and f . Therefore, the wait time required to change the system
X
XT
clock and CPU clock should be longer than the machine cycle calculated by the
nominal values of f and f
.
XT
X
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(2) Procedure for changing the system clock and CPU clock
The procedure for changing the system clock and CPU clock is explained using Figure 5-19.
Figure 5-19. Changing the System Clock and CPU Clock
ON
Commercial
power
line voltage
OFF
VDD pin voltage
RESET signal
Wait Note 1
f
X
f
X
fXT
f
X
System clock
CPU clock
10.7 µs
0.67 µs
122 µs
0.67 µs
f
X
= 6.00 MHz
Internal reset
operation
fXT = 32.768 kHz
<1> A RESET signal starts CPU operation at the lowest speed of the main system clock (10.7 µs at
Note 1
6.00 MHz,15.3 µs at 4.19 MHz) after a wait time
for stable oscillation.
<2> The PCC is rewritten for highest-speed operation after a time elapse which is sufficient for the
voltage on the V pin to be high enough for highest-speed operation.
DD
Note 2
<3> The removal of commercial current is detected using, for example, an interrupt input
, then bit
0 of the SCC is set to 1 to operate with the subsystem clock. (In this case, subsystem clock
generation must have been started.) After a time (46 machine cycles) required to switch to the
subsystem clock elapses, bit 3 of the SCC is set to 1 to terminate main system clock generation.
<4> After detecting the input of commercial current by using an interrupt, bit 3 of the SCC is cleared
to start main system clock generation. After a time required for stable generation, bit 0 of the SCC
is cleared to 0 to operate at the highest speed.
Notes 1. The following two wait times can be selected by a mask option:
17
2 /f (21.8ms at 6.00 MHz, 31.3ms at 4.19 MHz)
X
15
2 /f (5.46ms at 6.00 MHz, 7.81ms at 4.19 MHz)
X
15
However, the µPD75P0016 does not have a mask option and its wait time is fixed to 2 /f
X.
2. INT4 is useful.
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5.2.4 Clock Output Circuit
(1) Configuration of the clock output circuit
Figure 5-20 shows the configuration of the clock output circuit.
(2) Functions of the clock output circuit
The clock output circuit outputs a clock pulse signal on the P22/PCL pin to output remote control signals
or to supply clock pulses to a peripheral LSI device.
The procedure for outputting a clock pulse signal is as follows:
(a) Select a clock output frequency, and disable clock output.
(b) Write a 0 in the P22 output latch.
(c) Set the output mode for port 2.
(d) Enable clock output.
Figure 5-20. Configuration of the Clock Output Circuit
From the clock
generator
Φ
Output
f
f
f
X
X
X
/23
/24
/26
buffer
Selector
PCL/P22
PORT2.2
Bit 2 of PMGB
Port 2 input/
output mode
specification bit
P22 output
latch
CLOM3
0
CLOM1 CLOM0 CLOM
4
Internal bus
Remark The clock output circuit is designed so that pulses with short widths do not appear in enabling
or disabling clock output.
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(3) Clock output mode register (CLOM)
The CLOM is a 4-bit register to control clock output.
The CLOM is set by a 4-bit memory manipulation instruction. No read operation is allowed on this register.
Example CPU clock F is output on the PCL/P22 pin.
SEL
MB15
; or CLR1 MBE
MOV
MOV
A,#1000B
CLOM,A
A RESET signal clears the CLOM to 0, disabling clock output.
Figure 5-21. Format of the Clock Output Mode Register
Address
FD0H
Symbol
CLOM
3
2
0
1
0
CLOM3
CLOM1 CLOM0
Clock output frequency selection bit
(fX = 6.00 MHz)
0
1
0
1
Φ outputNote (1.5 MHz, 750 kHz, 375 kHz, 93.8 kHz)
X/23 output (750 kHz)
0
0
1
1
f
f
f
X/24 output (375 kHz)
X/26 output (93.8 kHz)
(fX = 4.19 MHz)
0
1
0
1
Φ outputNote (1.05 MHz, 524 kHz, 262 kHz, 65.5 kHz)
0
0
1
1
f
f
f
X/23 output (524 kHz)
X/24 output (262 kHz)
X/26 output (65.5 kHz)
Note
Φ
is the CPU clock selected by PCC.
Clock output enable/disable bit
0
1
Output disable
Output enable
Caution Be sure to write a 0 in bit 2 of the CLOM.
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(4) Application to remote control output
The clock output function of the µPD750008 is applicable to remote control output. The frequency of the
carrier for remote control output is selected by the clock frequency select bit of the clock output mode
register. Pulse output is enabled or disabled by controlling the clock output enable/disable bit by software.
The clock output circuit is designed so that pulses with short widths do not appear in enabling or disabling
clock output.
Figure 5-22. Application to Remote Control Output
Bit 3 of CLOM
PCL pin output
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5.3 BASIC INTERVAL TIMER/WATCHDOG TIMER
The µPD750008 contains an 8-bit basic interval timer/watchdog timer, which has the following functions:
(a) Interval timer operation which generates a reference timer interrupt
(b) Operation as a watchdog timer for detecting program crashes and resetting the CPU
(c) Selection of a wait time for releasing the standby mode, and counting
(d) Reading the count value
5.3.1 Configuration of the Basic Interval Timer/Watchdog Timer
Figure 5-23 shows the configuration of the basic interval timer/watchdog timer.
Figure 5-23. Block Diagram of the Basic Interval Timer/Watchdog Timer
From the clock
generator
Clear signal
Clear signal
fX
fX
fX
fX
/25
/27
/29
/212
Set
signal
Basic interval timer
(8-bit frequency divider)
BT interrupt
request flag
MPX
Vectored
interrupt
request
signal
BT
IRQBT
Internal
reset signal
3
Wait release
signal for standby
release
SET1Note
BTM3
BTM2 BTM1 BTM0
BTM
WDTM
SET1Note
8
4
1
Internal bus
Note Instruction execution
5.3.2 Basic Interval Timer Mode Register (BTM)
The BTM is a 4-bit register for controlling operation of the basic interval timer (BT).
A 4-bit memory manipulation instruction is used to set the BTM.
Bit 3 can be independently manipulated using a bit manipulation instruction.
Example The interrupt generation interval is set to 1.37 ms (at 6.00 MHz).
SEL
MB15
; or CLR1 MBE
MOV A,#1111B
MOV BTM,A
; BTM <– 1111B
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When bit 3 is set to 1, the BT is cleared, and the basic interval ltimer/watchdog timer interrupt request flag
(IRQBT) is also cleared (to start the basic interval timer/watchdog timer).
A RESET signal clears the interval timer to 0, and the longest interrupt request signal generation interval
time is set.
Figure 5-24. Format of the Basic Interval Timer Mode Register
Address
F85H
Symbol
BTM
3
2
1
0
BTM1
BTM3 BTM2
BTM0
(fX = 6.00 MHz)
Interrupt interval time
Input clock specification
X/212(1.46 kHz)
(wait time for releasing standby)
0
0
1
1
0
1
0
1
0
1
1
1
f
220/fX(175 ms)
f
f
f
X/29(11.7 kHz)
X/27(46.9 kHz)
X/25(188 kHz)
2
17/fX(21.8 ms)
215/fX(5.46 ms)
2
13/fX(1.37 ms)
Other than
above
—
Not to be set
(fX = 4.19 MHz)
Interrupt interval time
Input clock specification
X/212(1.02 kHz)
(wait time for releasing standby)
0
0
1
1
0
1
0
1
0
1
1
1
f
f
220/fX(250 ms)
X/29(8.18 kHz)
217/fX(31.3 ms)
f
X/27(32.768 kHz)
2
15/fX(7.82 ms)
X/25(131 kHz)
2
13/fX(1.95 ms)
f
Other than
above
—
Not to be set
Basic interval timer/watchdog timer start control bit
When 1 is written to this bit, the basic interval timer/watchdog timer operation starts
(the counter and the interrupt request flag are cleared).
When the operation starts, this bit is automatically reset to 0.
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5.3.3 Watchdog Timer Enable Flag (WDTM)
WDTM, when set, is a flag for enabling the generation of the reset signal when the basic interval timer
overflows. WDTM is set by a bit manipulation instruction. It cannot be cleared by an instruction.
Example Set the watchdog timer function.
SEL
MB15
; or CLR1 MBE
SET1 WDTM
·
·
·
SET1 BTM.3
; Set bit 3 of BTM to 1
The generation of a RESET signal clears WDTM to 0.
Figure 5-25. Format of the Watchdog Timer Enable Flag (WDTM)
Address
F8BH.3
WDTM
BT mode
Sets IRQBT when the basic interval timer (BT)
overflows.
0
1
WT mode
Generates an internal reset signal when the basic
interval timer (BT) overflows.
5.3.4 Operation of the Basic Interval Timer
When WDTM is set to 0, the basic interval timer (BT) functions as an interval timer. An interrupt request
flag (IRQBT) is set when the timer overflows. BT is constantly incremented by the clock supplied from the
clock generator. So it is impossible to stop the timer from incrementing.
One of four interrupt generation intervals can be selected by setting BTM. (See Figure 5-24.)
BT and IRQBT can be cleared by setting bit 3 of BTM to 1 (instruction for starting as an interval timer).
The count status of BT can be read by an 8-bit manipulation instruction. No data can be loaded to the timer.
Perform the timer operation as follows (<1> and <2> can be performed with the same instruction):
<1> Set the interval in BTM.
<2> Set 1 in bit 3 of BTM.
Example Generate an interrupt at intervals of 1.37 ms (at 6.00 MHz).
SET1 MBE
SEL
MB15
MOV A,#1111B
MOV BTM,A
EI
; Set the interval and start processing
; Enable interrupt
EI
IEBT
; Enable BT interrupt
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5.3.5 Operation of the Watchdog Timer
When WDTM is set to 1, the basic interval timer/watchdog timer functions as a watchdog timer. An internal
reset signal is generated when the basic interval timer (BT) overflows. No reset signal, however, is generated
during the oscillation wait time following the STOP instruction has been released (WDTM cannot be cleared
without using reset). BT is constantly incremented by the clock supplied from the clock generator. It cannot
be stopped from counting.
*
In the watchdog timer mode, program crashes are detected using the intervals at which BT overflows. The
interval can be selected from among four values depending on bits 2 to 0 of BTM (see Figure 5-24). Select
an interval for detecting crashes according to the user system. A large program should be divided into modules
each of which can be executed within the set interval. Include an instruction which clears BT at the end of
each module. If execution does not reach the instruction which clears BT within the set interval (in which case
a program error leading to a program crash may have occurred), BT overflows and an internal reset signal
is generated to forcibly terminate the program. The occurrence of internal reset possibly means that a program
crash has occurred. A crash can thus be detected.
Set the watchdog timer as follows (<1> and <2> can be performed with the same instruction):
<1> Set the interval in BTM.
<2> Set 1 in bit 3 of BTM.
Initial settings
<3> Set 1 in WDTM.
<4> After <1> to <3> are set, set 1 in bit 3 of BTM within each interval.
Example Use the basic interval/watchdog timer as a watchdog timer with 5.46-ms interval (at 6.00 MHz)
A program is divided into several modules each of which can be executed within the interval
set in BTM (5.46 ms). BT is cleared at the end of each module. If a program crash occurs, BT
overflows and an internal reset signal is generated because BT is not cleared within the set
interval.
Initial setting:
SET1 MBE
SEL
MB15
MOV
MOV
A, #1101B
BTM, A
; Specifies a time interval and
; starts processing.
SET1 WDTM
; Enables the watchdog timer.
(From now on, 1 is set in bit 3 of BTM at intervals of 5.46 ms.)
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Module 1:
Processing completes
within 5.46 ms.
SET1 MBE
SEL MB15
SET1 BTM.3
Module 2:
Processing completes
within 5.46 ms.
SET1 MBE
SEL MB15
SET1 BTM.3
5.3.6 Other Functions
The basic interval timer/watchdog has the following functions regardless of whether it operates as a basic
interval timer or watchdog timer:
<1> Selecting and counting the wait time after the standby mode is released
<2> Reading the count
(1) Selecting and counting the wait time after the STOP mode is released
To allow the system clock to stabilize after releasing the STOP mode, a wait function is available which
stops the operation of the CPU until the basic interval timer (BT) overflows.
The wait time after generation of a RESET signal is fixed as specified by a mask option. On the other
hand, a wait time can be selected by setting BTM when releasing the STOP mode with an interrupt
occurrence. In this case, the wait times are the same as the interval times shown in Figure 5-24. BTM
must be set before the STOP mode is set. (For details, see Chapter 7.)
Example Set the wait time 5.46 ms (at 6.00 MHz) in releasing the STOP mode with an interrupt.
SET1
SEL
MBE
MB15
MOV
MOV
STOP
NOP
A, #1101B
BTM, A
; Set wait time
; Set STOP mode
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(2) Reading the count
The count status of the basic interval timer (BT) can be read by using an 8-bit manipulation instruction.
No data can be loaded to the timer.
Caution When reading the count value of BT, execute a read instruction twice so that unstable
data which has been counted will not be read. If the two read values are reasonable, use
the second one as the result. If the two read values are far apart, retry from the beginning.
Examples 1. Read the count value of BT.
SET1
SEL
MBE
MB15
HL, #BT
MOV
; Set the BT address in HL
LOOP: MOV
MOV
XA, @HL ; First read
BC, XA
MOV
XA, @HL ; Second read
XA, BC
SKE
BR
LOOP
2. Set the high level width of pulses applied to the INT4 interrupt pin (both edges detected).
(The pulse width is assumed not to exceed the value (5.46 ms or longer at 6.00 MHz) set
in the BTM.)
<INT4 interrupt routine (MBE = 0)>
LOOP: MOV
MOV
MOV
SKE
XA, BT
BC, XA
XA, BT
A, C
; First read
; Store data
; Second read
BR
LOOP
A, X
MOV
SKE
A, B
BR
LOOP
SKT
PORT0.0 ; P00 = 1?
BR
AA
; NO
MOV
MOV
CLR1
RETI
XA, BC
BUFF, XA
FLAG
; Store data in data memory
; Clear data presence flag
AA:
MOV
MOV
SUBC
INCS
MOV
MOV
SUBC
MOV
HL, #BUFF
A, C
A, @HL
L
C, A
A, B
A, @HL
B, A
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MOV
MOV
SET1
RETI
XA, BC
BUFF, XA ; Store data
FLAG ; Set data presence flag
5.4 CLOCK TIMER
The µPD750008 contains one clock timer, which has the following functions.
(a) The clock timer sets the test flag (IRQW) every 0.5 seconds.
The IRQW can release the standby mode.
(b) Either the main system clock or the subsystem clock can be used to produce 0.5-second intervals.
Use a main system clock of 4.194304 MHz.
(c) The fast-forward mode produces an interval 128 times faster (3.91 ms), which is useful for program
debugging and testing.
(d) Any of the frequencies 2.048 kHz, 4.096 kHz, and 32.768 kHz can be output to the P23/BUZ pin, so
that it can be used for sounding the buzzer and for system clock frequency trimming.
(e) The frequency divider can be cleared to start the clock from zero second.
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5.4.1 Configuration of the Clock Timer
Figure 5-26 shows the configuration of the clock timer.
Figure 5-26. Block Diagram of the Clock Timer
f
27
w
(256 Hz: 3.91 ms)
f
w
INTW
IRQW
set signal
f
X
Selector
f
W
214
128
(32.768 kHz)
(32.768 kHz)
From the
clock
generator
Selector
Frequency divider
2 Hz
0.5 sec
fXT
(4 kHz) (2 kHz)
(32.768 kHz)
f
w
f
w
Clear signal
23
24
Selector
Output buffer
P23/BUZ
WM
PORT2.3
Bit 2 of PMGB
Port 2 input/
P23 output
latch
WM7
0
WM5 WM4 WM3 WM2 WM1 WM0
output mode
Bit test instruction
8
Internal bus
The values in parentheses are for f = 4.194304 MHz and f = 32.768 kHz.
X
XT
5.4.2 Clock Mode Register
The clock mode register (WM) is an 8-bit register which controls the clock timer. Figure 5-27 shows the
format of the clock mode register.
All bits except bit 3 of the clock mode register are controlled by an 8-bit manipulation instruction. Bit 3 is
for testing the XT1 pin input level. The input level of the XT1 pin can be tested by bit test operation. No data
can be written to this register.
When the RESET signal is generated, all bits except bit 3 of this register are cleared to 0.
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CHAPTER 5 PERIPHERAL HARDWARE FUNCTIONS
Example Time is set using the main system clock (4.19 MHz), and buzzer output is enabled:
CLR1 MBE
MOV XA, #84H
MOV WM, XA
; Sets WM
Figure 5-27. Clock Mode Register Format
Address
F98H
Symbol
7
6
0
5
4
3
2
1
0
WM7
WM5 WM4 WM3 WM2 WM1 WM0
WM
BUZ output enable/disable bit
0
1
WM7
Disables BUZ output
Enables BUZ output
BUZ output frequency selection bit
WM4 BUZ output frequency
WM5
f
W
0
0
0
1
(2.048 kHz)
(4.096 kHz)
24
f
23
W
1
1
0
1
Not to be set
f
W
(32.768 kHz)
XT1 pin input level (bit test only)
WM3
0
1
Input to the XT1 pin is low level
Input to the XT1 pin is high level
Clock operation enable/disable bit
0
1
Disables clock operation (clears the frequency dividing circuit)
Enables clock operation
WM2
Operation mode selection bit
f
W
0
1
WM1
Normal clock mode (
: sets IRQW at 0.5 seconds)
214
f
W
Advanced clock mode (
: sets IRQW at 3.91 ms)
27
Count clock (fW) selection bit
f
X
0
1
Selects divided system clock output:
Selects subsystem clock: fXT
WM0
128
Remark ( ) for f = 32.768 kHz
W
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5.5 TIMER/EVENT COUNTER
The µPD750008 has one timer/event counter channel (channel 0) and one timer counter channel (channel
1). Figures 5-28 and 5-29 show the configuration of these channels.
In this section, the timer/event counter and timer counters are referred to as "timer/event counters." When
you read this section for description of channel 1, take "timer/event counter" as "timer counter."
The timer/event counter has the following functions.
(a) Programmable interval timer operation
(b) Square wave output of any frequency to the PTOn pin.
(c) Event counter operation (Channel 0 only)
(d) Divides the frequency of signal input via the TI0 pin to 1-Nth of the original signal and outputs the
divided frequency to the PTO0 pin (frequency divider operation) (Channel 0 only).
(e) Supplies the serial shift clock to the serial interface circuit (Channel 0 only).
(f) Calls the counting status.
5.5.1 Configuration of timer/event counter
Figures 5-28 and 5-29 shows the configuration of the timer/event counter.
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(1) Timer/event counter mode register (TM0, TM1)
The mode register (TMn) is an 8-bit register which controls the timer/event counter.
Its format is shown in Figures 5-30 and 5-31.
The timer/event counter mode register is set by an 8-bit memory manipulation instruction.
Bit 3 is a timer start bit and can be operated bit-wise. It is automatically reset to 0 when the timer operation
starts.
All the bits of the timer/event counter mode register are cleared to 0 by a RESET signal generation.
Examples 1. Start the timer in the interval timer mode of CP = 5.86 kHz (during 6.00 MHz operation).
SEL
MB15
; or CLR1 MBE
; TMn <– 4CH
MOV
MOV
XA, #01001100B
TMn, XA
2. Restart the timer according to the setting of the timer/event counter mode register.
SEL
MB15
TMn.3
; or CLR1 MBE
; TMn.bit3 <– 1
SET1
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Figure 5-30. Timer/Event Counter Mode Register (Channel 0) Format
Address
FA0H
7
6
5
4
3
2
1
0
Symbol
TM0
TM06 TM05 TM04 TM03 TM02
Count pulse (CP) selection bit
When fX = 6.00 MHz
TM06 TM05 TM04
Count pulse (CP)
0
0
1
1
1
1
0
0
0
0
1
1
0
1
0
1
0
1
TI0 rising edge
TI0 falling edge
f
f
f
f
X/210 (5.86 kHz)
X/28 (23.4 kHz)
X/26 (93.8 kHz)
X/24 (375 kHz)
Other than above
Not to be set
When fX = 4.19 MHz
TM06 TM05 TM04
Count pulse (CP)
0
0
1
1
1
1
0
0
0
0
1
1
0
1
0
1
0
1
TI0 rising edge
TI0 falling edge
f
f
f
f
X/210 (4.09 kHz)
X/28 (16.4 kHz)
X/26 (65.5 kHz)
X/24 (262 kHz)
Other than above
Not to be set
Timer start indication bit
TM03 When 1 is written into the bit, the counter and IRQT0 flag are cleared.
If bit 2 is set to 1, count operation is started.
Operation mode
TM02
Count operation
Stop (retention of count contents)
Count operation
0
1
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Figure 5-31. Timer Counter Mode Register (Channel 1) Format
Address
FA8H
7
6
5
4
3
2
1
0
Symbol
TM1
TM16 TM15 TM14 TM13 TM12
Count pulse (CP) select bit
When fX = 6.00 MHz
TM16
TM14
Count pulse (CP)
TM15
X/212 (1.46 kHz)
X/210 (5.86 kHz)
X/28 (23.4 kHz)
X/26 (93.8 kHz)
1
1
1
1
f
f
f
f
0
1
0
1
0
0
1
1
Other than above
Not to be set
When fX = 4.19 MHz
TM16 TM15 TM14
Count pulse (CP)
f
f
f
f
X/212 (1.02 kHz)
X/210 (4.09 kHz)
X/28 (16.4 kHz)
X/26 (65.5 kHz)
1
1
1
1
0
0
1
1
0
1
0
1
Other than above
Not to be set
Timer start indication bit
TM13 When 1 is written into the bit, the counter and IRQT1 flag are cleared.
If bit 2 is set to 1, count operation is started.
Operation mode
TM12
Count operation
Stop (retention of count contents)
Count operation
0
1
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(2) Timer/event counter output enable flag (TOE0, TOE1)
The timer/event counter output enable flag (TOE0, TOE1) controls the output enable/disable to the PTO0
and PTO1 pins in the timer out flip-flop (TOUT flip-flop ) status.
The timer out flip-flop is inverted by the match signal sent from the comparator. When bit 3 of the timer/
event counter mode register (TM0, TM1) is set to 1, the timer out flip-flop is cleared to 0.
TOE0, TOE1, and timer out flip-flop are cleared to 0 by a RESET signal generation.
Figure 5-32. Timer/Event Counter Output Enable Flag Format
Address
FA2H
FAAH
TOE0
TOE1
Channel 0
Channel 1
Timer/event counter output enable flag (W)
0
1
Disabled.
Enabled.
5.5.2 8-bit timer/event counter mode operation
It is used as an 8-bit timer/event counter in this mode. It performs an 8-bit programmable interval timer
and event counter operation (channel 0 only).
(1) Register setting
The following three registers and one flag are used in the 8-bit timer/event counter mode.
• Timer/event counter mode register (TMn)
• Timer/event counter count register (Tn)
• Timer/event counter modulo register (TMODn)
• Timer/event counter output enable flag (TOEn)
(a) Timer/event counter mode register (TMn)
When the 8-bit timer/event counter mode is used, TMn must be set as shown in Figure 5-33 (For the
format of the TMn, see Figures 5-30 and 5-31).
The TMn is manipulated by an 8-bit manipulation instruction. Bit 3 is a timer start indication bit and
can be manipulated bit-wise and is automatically cleared to 0 when the timer starts.
The TMn is cleared to 00H when an internal reset signal is generated.
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Figure 5-33. Timer/Event Counter Mode Register Setup (1/2)
(a) In the case of timer/event counter (channel 0)
Address
FA0H
7
6
5
4
3
2
1
0
Symbol
TM0
TM06 TM05 TM04 TM03 TM02
Count pulse (CP) selection bit
TM06 TM05 TM04
Count pulse (CP)
0
0
1
1
1
1
0
0
0
0
1
1
0
1
0
1
0
1
TI0 rising edge
TI0 falling edge
f
f
f
f
X
X
X
X
/210
/28
/26
/24
Other than above
Not to be set
Timer start indication bit
TM03
When “1” is written into the bit, the counter and IRQT0 flag are cleared.
If bit 2 is set to “1”, count operation is started.
Operation mode
TM02
Count operation
Stop (retention of count contents)
Count operation
0
1
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Figure 5-33. Timer/Event Counter Mode Register Setup (2/2)
(b) In the case of timer counter (channel 1)
Address
FA8H
7
6
5
4
3
2
1
0
Symbol
TM1
TM16 TM15 TM14 TM13 TM12
Count pulse (CP) selection bit
TM16 TM15 TM14
Count pulse (CP)
1
1
1
1
0
0
1
1
0
1
0
1
f
f
f
f
X
X
X
X
/212
/210
/28
/26
Not to be set
Other than above
Timer start indication bit
TM13
When “1” is written to the bit, the counter and IRQT1 flag are cleared.
If bit 2 is set to “1”, count operation is started.
Operation mode
TM12
Count operation
Stop (retention of count contents)
Count operation
0
1
(b) Timer/event counter output enable flag (TOEn)
The TOEn is manipulated by a bit manipulation instruction.
The TOEn is cleared to 0 by an internal reset signal.
Figure 5-34. Timer/Event Counter Output Enable Flag Setup
Address
FA2H
FAAH
TOE0
TOE1
Channel 0
Channel 1
Timer/event counter output enable flag (W)
0
1
Disabled (outputs the low-level signal).
Enabled.
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(2) Timer/event counter time setting
[Timer setup time] (cycle) is found by dividing [modulo register contents + 1] by [count pulse (CP)
frequency] selected by setting the mode register.
n+1
T (sec) =
= (n + 1) · (resolution)
f
CP
T (sec) : Timer setup time (seconds)
f
(Hz) : Count pulse frequency (Hz)
: Modulo register content (n • 0)
CP
n
Once the timer is set, interrupt request signal (IRQTn) is generated at the intervals set in the timer.
Table 5-6 lists the resolution and longest setup time (time when FFH is set in the modulo register) for each
count pulse to the timer/event counter.
Table 5-6. Resolution and Longest Setup Time
(a) When timer/event counter (channel 0)
Mode register
At 6.00 MHz
At 4.19 MHz
TM06
1
TM05
0
TM04
0
Resolution
Longest setup time
43.7 ms
Resolution
Longest setup time
62.5 ms
171 µs
42.7 µs
10.7 µs
2.67 µs
244 µs
61.0 µs
15.3 µs
3.82 µs
1
1
1
0
1
1
1
0
1
10.9 ms
2.73 ms
683 µs
15.6 ms
3.91 ms
977 µs
(b) When timer counter (channel 1)
Mode register
At 6.00 MHz
At 4.19 MHz
TM16
1
TM15
0
TM14
0
Resolution
685 µs
Longest setup time
175 ms
Resolution
980 µs
Longest setup time
250 ms
1
1
1
0
1
1
1
0
1
171 µs
42.7 µs
10.7 µs
43.7 ms
10.9 ms
2.73 ms
244 µs
61.0 µs
15.3 µs
62.5 ms
15.6 ms
3.91 ms
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(3) Timer/event counter operation
The timer/event counter operates as follows.
Figure 5-35 shows the configuration of the timer/event counter.
<1> The count pulse (CP) is selected by setting the mode register (TMn) and is input to the count register
(Tn).
<2> The Tn is compared with the modulo register (TMODn), and if they are equal, a match signal is
generated and the interrupt request flag (IRQTn) is set. At the same time, the timer out flip-flop (TOUT
flip-flop) is inverted.
Figure 5-36 is a timing chart of the timer/event counter.
The timer/event counter normally begins operation in the following procedure.
<1> Set a count in the TMODn.
<2> Set the operating mode, count pulse, and start indication in the TMn.
Caution Set a value other than 00H in the modulo register (TMODn).
When using the timer/event counter output pin (PTOn), set the dual function pin P2n as follows.
<1> Clear the output latch of P2n.
<2> Set port 2 to the output mode.
<3> Make a status wherein the internal pull-up resistor is not connected in port 2.
<4> Set the timer/event counter output enable flag (TOEn) to 1.
Figure 5-35. Configuration of Timer/Event Counter
INTTn
(IRQTn set signal)
Modulo register (TMODn)
TI0Note
Match
TOUT flip-flop
PTOn
TOUT0
Comparator
MPX
Internal
clock
CP
To serial interfaceNote
Count register (Tn)
Clear
Note Channel 0 of the timer/event counter only.
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CHAPTER 5 PERIPHERAL HARDWARE FUNCTIONS
Figure 5-36. Count Operation Timing
Count pulse(CP)
n
Modulo register
(TMODn)
Count register
(Tn)
0
1
2
n–1
n
0
1
2
n–1
n
0
1
2
3
4
Match
Match
Reset
TOUT F/F
Timer start indication
(4) Applications of the timer/event counter
(a) Timer/event counter is used as an interval timer that generates interrupts at intervals of 30 ms.
• The high-order four bits of the mode register are set to 0100B to select maximum set time 43.7 ms
(at f = 6.00 MHz).
X
• The low-order four bits of the mode register are set to 1100B.
• The modulo register is set to the following value:
.
=
30 ms/171 µs = 175.4
AFH
.
<Sample program>
SEL
MOV
MOV
MOV
MOV
EI
MB15
XA,#0AEH
TMOD0,XA
; Set the modulo register
XA,#01001100B
TM0,XA
; Set the mode register and start the timer
; Enable an interrupt
EI
IET0
; Enable a timer interrupt
Remark In this application, the TI0 pin can be used as an input pin.
(b) An interrupt is caused when the number of pulses (active high) applied to the TI0 pin reaches
100.
• The high-order four bits of the mode register are set to 0000 to select the rising edge.
• The low-order four bits of the mode register are set to 1100B.
• The modulo register is set to 99 = 100 – 1.
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<Sample program>
SEL
MOV
MOV
MOV
MOV
EI
MB15
XA,#100 – 1
TMOD0,XA
XA,#00001100B
TM0,XA
; Set the modulo register
; Set the mode register
; Enable INTT0
EI
IET0
5.5.3 Notes on Timer/Event Counter Applications
(1) Time error at the start of the timer
A maximum error of one count pulse (CP) cycle from a value calculated according to Section 5.5.2 (2)
occurs in a time period from the start of the timer (bit 3 of the TM0 is set) to the generation of a match
signal. This is because the count register T0 is cleared not in phase with the CP as shown in Figure
5-37.
Figure 5-37. Error at the Start of the Timer
CP
Count register
0
1
2
3
0
1
2
Timer start
Timer start
(2) Notes on the start of the timer
Usually, when the timer is started (bit 3 of the TM0 is set), the count register T0 and the interrupt request
flag (IRQT0) are cleared. However, when the timer is placed in the operation mode, and the setting of
IRQT0 and the start of the timer occur at the same time, IRQT0 may not be cleared. This causes no problem
if IRQT0 is used for a vectored interrupt. However, if IRQT0 is being tested, a problem arises because
IRQT0 is set even if the timer is started. Accordingly, in a situation where the timer is started on such
timing that IRQT0 may be set, the timer must be restarted after it is once stopped (bit 2 of the TM0 is cleared
to 0), or timer start operation must be performed twice.
Example The timer is started on such timing that IRQT0 may be set.
SEL
MB15
MOV
MOV
MOV
MOV
or
XA,#0
TM0,XA
XA,#4CH
TM0,XA
; Stop the timer
; Restart
SEL
MB15
TM0.3
TM0.3
SET1
SET1
; Restart
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CHAPTER 5 PERIPHERAL HARDWARE FUNCTIONS
(3) Error in reading the count register
The contents of the count register can be read using an 8-bit data memory manipulation instruction at
any time. During operation by such an instruction, all count pulse changes are held not to change the
count register. This means that if the count pulse signal source is applied to the TI0 input, as many count
pulses as corresponding to the time required to execute the instruction are cut. (When an internal clock
is used for the count pulse signal, this problem does not occur because of synchronization with the
instruction.)
Accordingly, in an attempt to read the contents of the count register with a count pulse signal applied to
TI0, the signal must have a pulse wide enough to avoid incorrect counting even if count pulses are cut.
That is, the contents of the count register are held by a read instruction for one machine cycle, so that
a signal applied to the TI0 pin must have a pulse wider than that.
Read instruction
External clock (TI0)
Instruction
CP
Count register
K – 1
K
K + 1
K + 2
A change in a count
pulse is placed on hold
by the instruction.
A count pulse is canceled
by the instruction.
(4) Notes on changing the count pulse
When the count pulse is changed by rewriting the contents of the timer/event counter mode register, this
takes effect immediately after the rewrite instruction is executed.
Re-set instruction
Re-set instruction
Clock A specified
Clock B specified
Clock A specified
Clock A
Clock B
CP
A combination of clocks used for changing count pulse signals can generate a spike (<1> or <2>) count
pulse as shown in the figure below. In this case, an incorrect count operation may occur, or the contents
of the count register may be destroyed. So when the count pulse is changed, bit 3 of the timer/event counter
mode register must be set to 1, and the timer must be restarted at the same time.
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Re-set instruction Re-set instruction
Clock A specified
Clock B specified
Clock A specified
Clock A
Clock B
CP
<1>
<2>
(5) Operation after the modulo register is changed
The contents of the modulo register are changed when an 8-bit data memory manipulation instruction is
executed.
CP
Modulo register
n
m
Re-set instruction
Count register
n
0
1
m
0
Match signal
Match signal
If the new value of the modulo register is less than the value of the count register, the count register
continues count operation until it overflows, then it restarts count operation from 0. Accordingly, if the
new value (m) of the modulo register is less than the value (n) before it is changed, the timer must be
restarted after the contents of the modulo register are changed.
CP
Modulo register
Count register
n
m
x – 1
x
255
0
1
n > x > m
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CHAPTER 5 PERIPHERAL HARDWARE FUNCTIONS
5.6 SERIAL INTERFACE
5.6.1 Serial Interface Functions
The µPD750008 contains a clock synchronous 8-bit serial interface, which has four modes.
The functions of the four modes are outlined below.
(1) Operation halt mode
This mode is used when serial transfer is not performed. This mode reduces power consumption.
(2) Three-wire serial I/O mode
In this mode, 8-bit data is transferred through three lines: Serial clock (SCK), serial output (SO), and serial
input (SI).
The three-wire serial I/O mode allows full-duplex transmission, so data transfer can be performed at higher
speed.
The user can choose 8-bit data transfer starting with the MSB or LSB, so devices starting with either the
MSB or LSB can be connected.
The three-wire serial I/O mode enables connections to be made with the 75XL series, 78K series, and
many other types of peripheral I/O devices.
(3) Two-wire serial I/O mode
In this mode, 8-bit data is transferred through two lines: Serial clock (SCK) and serial data bus (SB0 or
SB1). By controlling output levels on the two lines by software, communication with multiple devices is
enabled.
The output levels of SCK and SB0 (or SB1) can be controlled by software, so the user can match an
arbitrary transfer format. This means that a line that has been required for handshaking to connect multiple
lines can be eliminated for more efficient input/output port utilization.
(4) Serial bus interface (SBI) mode
In this mode, communication with multiple devices can be performed using two lines: Serial clock (SCK)
and serial data bus (SB0 or SB1).
This mode conforms to the NEC serial bus format.
In this mode, the transmitter can output, on the serial data bus, an address for selecting a device subject
to serial communication, commands directed to the remote device, and data.
The receiver can identify an address, commands, and data from received data by hardware. This function
enables more efficient input/output port utilization as in the case of the two-wire serial I/O mode. In
addition, this function can simplify the serial interface control portion of an application program.
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Figure 5-38. Example of the SBI System Configuration
VDD
Master CPU
Slave CPU
Serial clock
SCK
SB0, SB1
SCK
SB0, SB1
#1
Address 1
Address
Command
Data
Slave IC
SCK
#N
Address N
SB0, SB1
5.6.2 Configuration of Serial Interface
Figure 5-39 shows the block diagram of the serial interface.
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CHAPTER 5 PERIPHERAL HARDWARE FUNCTIONS
B S Y E
A C K E
A C K T
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(1) Serial operation mode register 0 (CSIM)
CSIM is an 8-bit register which specifies a serial interface operation mode, serial clock, wake-up function,
and so forth. (See (1) in Section 5.6.3 for details.)
(2) Serial bus interface control register (SBIC)
SBIC is an 8-bit register consisting of bits for controlling the serial bus and flags for indicating the states
of input data from the serial bus. SBIC is used mainly in the SBI mode. (See (2) in Section 5.6.3 for
details.)
(3) Shift register (SIO)
SIO is an 8-bit register which converts 8-bit serial data to parallel data, and 8-bit parallel data to serial
data. SIO performs transfer (shift) in phase with the serial clock. Transfers operations are controlled by
writing data to SIO. (See (3) in Section 5.6.3 for details.)
(4) SO latch
SO is a latch to hold the levels of pins SO and SB0, or SI and SB1, which can be controlled directly by
software. In the SBI mode, SO is set when the eighth clock of SCK has been output. (See(2) in Section
5.6.3 for details.)
(5) Serial clock selector
The serial clock selector selects the serial clock to be used.
(6) Serial clock counter
The serial clock counter counts the serial clock to be output or input during transfer, and checks whether
8-bit data has been transferred.
(7) Slave address register (SVA) and address comparator
• In the SBI mode
SVA is used when the µPD750008 is used as a slave device. A slave sets the number assigned to
it (slave address) in SVA. The master outputs a slave address to select a particular slave.
Two data values (a slave address output from the master and the value of SVA) are compared with
each other by the address comparator. If a match is found, the slave is selected.
• In the two-wire serial I/O mode or SBI mode
SVA detects an error when data is transferred with the µPD750008 operating as the master or a slave.
(See (4) in Section 5.6.3 for details.)
(8) INTCSI control circuit
The INTCSI control circuit controls interrupt request processing. The circuit issues an interrupt request
(INTCSI), and set an interrupt request flag (IRQCSI) in the following cases. (See Figure 6-1.)
• In the three-wire or two-wire serial I/O mode
An interrupt request is issued whenever eight serial clocks are counted.
• In the SBI mode
Note
When WUP7
= 0, an interrupt request is issued whenever eight serial clocks are counted. When
WUP = 1, an interrupt request is issued when values of SVA and SIO match after an address is
received.
Note WUP: Wake-up function specification bit (bit 5 of CSIM)
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(9) Serial clock control circuit
The serial clock control circuit controls the serial clock to be supplied to the shift register, or controls the
clock to be output to the SCK pin when the internal system clock is used.
(10) Busy/acknowledge output circuit and bus release/command/acknowledge detection circuit
The busy/acknowledge output circuit and bus release/command/acknowledge detection circuit output and
detect control signals generated in the SBI mode.
These circuits do not operate in the three-wire or two-wire serial I/O mode.
(11) P01 output latch
The P01 output latch generates serial clock by software after the eighth serial clock has been output.
When the RESET signal is entered, this latch is set to 1.
To select the internal system clock as the serial clock, set the P01 output latch to 1.
5.6.3 Register Functions
(1) Serial operation mode register (CSIM)
Figure 5-40 shows the format of serial operation mode register (CSIM).
CSIM is an 8-bit register which specifies a serial interface operation mode, serial clock, wake-up function,
and so forth.
CSIM is manipulated using an 8-bit memory manipulation instruction. The higher three bits can be
manipulated bit by bit. Each bit can be manipulated using its name.
Each bit may or may not allow read and/or write operation (seeFigure 5-40). Bit 6 allows bit test operation
only; any data written to this bit is invalid.
When the RESET signal is generated, all bits are cleared to 0.
Figure 5-40. Format of Serial Operation Mode Register (CSIM) (1/4)
Address
FE0H
Symbol
CSIM
7
6
5
4
3
2
1
0
CSIE
COI
WUP
CSIM4 CSIM3 CSIM2 CSIM1 CSIM0
Serial clock selection bit (W)
Serial interface operation mode selection bit (W)
Wake-up function specification bit (W)
Signal from address comparator (R)
Serial interface operation enable/disable specification bit (W)
Remarks 1. (R) : Read only
2. (W): Write only
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Figure 5-40. Format of Serial Operation Mode Register (CSIM) (2/4)
Serial interface operation enable/disable specification bit (W)
Shift register
operation
Serial clock
counter
IRQCSI
flag
SO/SB0 and
SI/SB1 pins
CSIE
0
1
Shift operation
disabled
Cleared
Held
Used only for port 0
Shift operation
enabled
Count operation
Can be set.
Used in each mode as well
as for port 0
Signal from address comparator (R)
Note
COI
Condition for being cleared (COI = 0)
Condition for being set (COI = 1)
When the data in the slave address
register (SVA) does not match the data
in the shift register
When the data in the slave address register
(SVA) matches the data in the shift
register
Note COI can be read only before serial transfer is started or after serial transfer is completed. An
undefined value may result during transfer.
COI data written by an 8-bit manipulation instruction is ignored.
Wake-up function specification bit (W)
WUP
0
1
Sets IRQCSI each time serial transfer is completed in each mode.
Used in the SBI mode only to set IRQCSI only when an address received after bus release
matches the data in the slave address register (wake-up state). SB0 or SB1 goes to high-
impedance state.
Caution When WUP = 1 is set during BUSY signal output, BUSY is not released. In the SBI mode,
the BUSY signal is output until the next falling edge of the serial clock (SCK) appears after
release of BUSY is directed. Before setting WUP = 1, be sure to confirm that pin SB0 (or
SB1) is high after releasing BUSY.
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Figure 5-40. Format of Serial Operation Mode Register (CSIM) (3/4)
Serial interface operation mode selection bit (W)
Operation
mode
Bit order of
shift register
SO pin
function
SI pin
function
CSIM4 CSIM3 CSIM2
x
0
0
1
0
3-wire
serial
I/O mode
SIO <—> XA
(Transfer start
with MSB)
SO/P02
(CMOS output)
SI/P03
(Input)
7-0
SIO
<—> XA
0-7
(Transfer starting
with LSB)
0
1
0
1
1
SBI mode
SIO
<—> XA
SB0/P02
P03 input
7-0
(Transfer starting (N-ch open-drain I/O)
with MSB)
P02 input
SB1/P03
(N-ch open-drain I/O)
1
2-wire
SIO
<—> XA
SB0/P02
P03 input
7-0
serial
I/O mode
(Transfer starting (N-ch open-drain I/O)
with MSB)
1
P02 input
SB1/P03
(N-ch open-drain I/O)
Remark x: Don’t care
Serial clock selection bit (W)
CSIM1 CSIM0
Serial clock
SCK pin mode
3-wire serial I/O mode
SBI mode
2-wire serial I/O mode
0
0
1
0
1
0
Input clock externally applied to SCK pin
Input
Timer/event counter output (TOUT0)
Output
4
6
f /2 (375 kHz: at 6.00 MHz,
f /2 (93.8 kHz: at 6.00 MHz,
X
X
262 kHz: at 4.19 MHz)
65.47 kHz: at 4.19 MHz)
3
1
1
f /2 (750 kHz: at 6.00 MHz,
X
524 kHz: at 4.19 MHz)
Remarks 1. Each mode can be selected using CSIE, CSIM3, and CSIM2.
CSIE
CSIM3
CSIM2
Operation mode
0
1
1
1
x
0
1
1
x
x
0
1
Operation halt mode
Three-wire serial I/O mode
SBI mode
Two-wire serial I/O mode
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Figure 5-40. Format of Serial Operation Mode Register (CSIM) (4/4)
Remarks 2. The P01/SCK pin assumes any of the following states according to the state of
CSIE, CSIM1, and CSIM0:
CSIE
CSIM1
CSIM0
P01/SCK pin state
Input port
0
1
0
0
0
1
1
1
0
0
0
1
1
0
1
1
0
0
1
0
1
1
0
1
High impedance
High level output
Serial clock output (High level output)
3. When clearing CSIE during serial transfer, use the following procedure:
<1> Disable interrupts by clearing the interrupt enable flag (IECSI).
<2> Clear CSIE.
<3> Clear the interrupt request flag (IRQCSI).
4
Examples 1. f /2 is selected as the serial clock, serial interrupt IRQCSI, is generated each
X
time serial transfer is completed, and serial transfer is performed in the SBI
mode with the SB0 pin used as the serial data bus.
SEL
MB15
; or CLR1 MBE
MOV XA,#10001010B
MOV CSIM,XA
; CSIM <– 10001010B
2. Serial transfer dependent on the contents of CSIM is enabled.
SEL MB15 ; or CLR1 MBE
SET1 CSIE
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(2) Serial bus interface control register (SBIC)
Figure 5-41 shows the format of the serial bus interface control register (SBIC).
SBIC is an 8-bit register consisting of bits for controlling the serial bus and flags for indicating the states
of input data from the serial bus. SBIC is used mainly in the SBI mode.
SBIC is manipulated using a bit manipulation instruction. SBIC cannot be manipulated using a 4-bit or
8-bit memory manipulation instruction.
Each bit may or may not allow read and/or write operation (Figure 5-41).
When the RESET signal is generated, all bits are cleared to 0.
Caution Only the following bits can be used in the three-wire and two-wire serial I/O modes:
• Bus release trigger bit (RELT): Sets the SO latch.
• Command trigger bit (CMDT): Clears the SO latch
.
Figure 5-41. Format of Serial Bus Interface Control Register (SBIC) (1/3)
Address
FE2H
Symbol
7
6
5
4
3
2
1
0
BSYE
ACKD
ACKE
ACKT CMDD RELD
CMDT
RELT
SBIC
Bus release trigger bit (W)
Command trigger bit (W)
Bus release detection flag (R)
Command detection flag (R)
Acknowledge trigger bit (W)
Acknowledge enable bit (R/W)
Acknowledge detection flag (R)
Busy enable bit (R/W)
Remarks 1. (R:
Read only
Write only
2. (W):
3. (R/W): Read/write
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Figure 5-41. Format of Serial Bus Interface Control Register (SBIC) (2/3)
Busy enable bit (R/W)
BSYE
0
<1> The busy signal is automatically disabled.
<2> Busy signal output is stopped in phase with the falling edge of SCK immediately after
clear instruction execution.
1
The busy signal is output after the acknowledge signal in phase with the falling edge of SCK.
Acknowledge detection flag (R)
ACKD
Condition for being cleared (ACKD = 0)
Condition for being set (ACKD = 1)
<1> The transfer operation is started.
<2> The RESET signal is generated.
The acknowledge signal (ACK) is detected
(in phase with the rising edge of SCK).
Acknowledge enable bit (R/W)
ACKE
0
1
Disables automatic output of the acknowledge signal (ACK). (Output by ACKT is possible.)
When set before transfer
When set after transfer
ACK is output in phase with the 9th clock of SCK.
ACK is output in phase with SCK immediately following
the set instruction execution.
Acknowledge trigger bit (W)
ACKT
When set after transfer, ACK is output in phase with the next SCK. After ACK signal output,
this bit is automatically cleared to 0.
Cautions 1. Never set ACKT before or during serial transfer.
2. ACKT cannot be cleared by software.
3. Before setting ACKT, set ACKE = 0.
Command detection flag (R)
CMDD
Condition for being cleared (CMDD = 0)
Condition for being set (CMDD = 1)
<1> The transfer start instruction is executed.
<2> The bus release signal (REL)
<3> The RESET signal is generated.
<4> CSIE = 0 (Figure 5-40)
The command signal (CMD) is detected.
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Figure 5-41. Format of Serial Bus Interface Control Register (SBIC) (3/3)
Bus release detection flag (R)
RELD
Condition for being cleared (RELD = 0)
Condition for being set (RELD = 1)
<1> The transfer start instruction is executed.
<2> The RESET signal is generated.
<3> CSIE = 0 (Figure 5-40)
The bus release signal (REL) is detected.
<4> SVA does not match SIO when an address is
received.
Command trigger bit (W)
CMDT
Control bit for command signal (CMD) trigger output. By setting CMDT = 1, the SO latch is
cleared. Then the CMDT bit is automatically cleared to 0.
Caution Never clear SB0 (or SB1) during serial transfer. Be sure to clear SB0 (or SB1) before or
after serial transfer
Bus release trigger bit (W)
RELT
Control bit for bus release signal (REL) trigger output.
By setting RELT = 1, the SO latch is set to 1. Then the RELT bit is automatically cleared to 0.
Caution Never clear SB0 (or SB1) during serial transfer. Be sure to clear SB0 (or SB1) before or
after serial transfer.
Examples 1. A command signal is output.
SEL
MB15
; or CLR1 MBE
SET1 CMDT
2. RELD and CMDD are tested to identify the types of received data and the types of processing
accordingly. By setting WUP = 1, this interrupt routine is processed only when an address
match is found.
SEL
SKF
BR
MB15
RELD
!ADRS
CMDD
!DATA
!CMD
; RELD test
; CMDD test
SKT
BR
BR
CMD: ...................... ; Command analysis
DATA:..................... ; Data processing
ADRS: .................... ; Address decode
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(3) Shift register (SIO)
Figure 5-42 shows the configuration of peripheral hardware of shift register. SIO is an 8-bit register which
performs parallel-serial conversion and serial transfer (shift) operation in phase with the serial clock.
Serial transfer is started by writing data to SIO.
In transmission, data written to SIO is output on the serial output (SO) or serial data bus (SB0 or SB1).
In receive operation, data is read from the serial input (SI) or SB0 or SB1 into SIO.
Data can be read from or written to SIO by using an 8-bit manipulation instruction.
When the RESET signal is generated during operation, the value of SIO is undefined. When the RESET
signal is generated in the standby mode, the value of SIO is preserved.
Shift operation is stopped after 8-bit send or receive operation is completed.
Figure 5-42. Peripheral Hardware of Shift Register
Address
comparator
Internal bus
RELT
CMDT
Shift register
SO latch
SET
CLR
D
Q
CLK
CSIM
Shift clock
BUSY/ACK
N-ch open-drain output
The timing for reading SIO and start of serial transfer (writing to SIO) is as follows:
• When the serial interface operation enable/disable bit (CSIE) = 1. However, the case where CSIE
is set to 1 after data is written to the shift register is excluded.
• When the serial clock is masked after 8-bit serial transfer
• SCK is high.
When reading from or writing to SIO, make sure that SCK is high.
In the two-wire serial I/O mode and SBI mode, the pins specified for the data bus are used for both input
and output. Because the configuration of output pins is N-ch open-drain, write FFH in SIO for devices
that are to receive data.
(4) Slave address register (SVA)
The slave address register (SVA) is an 8-bit register for a slave to set its slave address (number assigned
to it).
SVA is manipulated using an 8-bit manipulation instruction.
When the RESET signal is generated, the value of SVA is undefined. However, the value of SVA is
preserved when the RESET signal is generated in the standby mode.
SVA has the following two functions:
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(a) Slave address detection
[In the SBI mode]
SVA is used when the µPD750008 is connected as a slave device to the serial bus. SVA is an 8-
bit register for a slave to set its slave address (number assigned to it). The master outputs a slave
address to the connected slaves to select a particular slave. Two data values (a slave address output
from the master and the value of SVA) are compared with each other by the address comparator. If
a match is found, the slave is selected.
At this time, bit 6 (COI) of serial operation mode register (CSIM) is set to 1.
If a match with received address data is not found, the bus release detection flag (RELD) is cleared
to 0. When WUP = 1 (wake-up state detection), IRQCSI is set only when a match is found. With this
interrupt request, the µPD750008 can be informed of a communication request transmitted from the
master.
(b) Error detection
[In the two-wire serial I/O mode or SBI mode]
SVA detects an error when addresses, commands, or data is transferred with the µPD750008
operating as the master or when data is transferred with the µPD750008 operating as a slave. (For
details, see (6) in Section 5.6.6 and (8) in Section 5.6.7.)
5.6.4 Operation Halt Mode
The operation halt mode is used when serial transfer is not performed. This mode reduces power
consumption.
The shift register does not perform shift operation in this mode, so the shift register can be used as a normal
8-bit register.
When the RESET signal is entered, the operation halt mode is set. The P02/SO/SB0 pin and P03/SI/SBI
pin function as input-only port pins. The P01/SCK pin can be used as an input port pin by setting the serial
operation mode register.
(1) Register setting
To set the operation halt mode, manipulate serial operation mode register (CSIM). (For details on CSIM
format, see (1) in Section 5.6.3.)
CSIM is manipulated with an 8-bit manipulation instruction. Only the CSIE bit of CSIM can be
independently manipulated. CSIM can also be manipulated using the name of each bit.
When the RESET signal is entered, CSIM is set to 00H.
In the figure below, hatched portions indicate bits used in the operation halt mode.
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7
6
5
4
3
2
1
0
Address
FE0H
CSIE COI WUP CSIM4 CSIM3 CSIM2 CSIM1 CSIM0 CSIM
Serial clock selection bit (W)Note
Serial interface operation mode selection bit (W)
Wake-up function specification bit (W)
Match signal from address comparator (R)
Serial interface operation enable/disable specification bit (W)
Note The status of the P01/SCK pin is selectable.
Remark (R): Read only
(W): Write only
Serial interface operation enable/disable specification bit (W)
Shift register operation
Shift operation disabled
Serial clock counter IRQCSI flag
Cleared Held
SO/SB0 and SI/SB1 pins
Used only for port 0
CSIE0
0
Serial clock selection bit (W)
The P01/SCK pin assumes the following state according to the setting of CSIM0 and CSIM1:
CSIM1 CSIM0
P01/SCK pin state
0
0
1
1
0
1
0
1
High impedance
High level output
When clearing CSIE during serial transfer, use the following procedure:
<1> Disable interrupts by clearing the interrupt enable flag (IECSI).
<2> Clear CSIE.
<3> Clear the interrupt request flag (IRQCSI).
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5.6.5 Three-Wire Serial I/O Mode Operations
The three-wire serial I/O mode is compatible with other modes used in the 75 XL series, 75X series,
µPD7500 series, and 87AD series.
Communication is performed using three lines:
Serial clock (SCK), serial output (SO), and serial input (SI).
Figure 5-43. Example of Three-Wire Serial I/O System Configuration
3-wire serial I/O
3-wire serial I/O
Master CPU
Slave CPU
µPD750008
SCK
SO
SI
SCK
SI
SO
Remark The µPD750008 can also be used as a slave CPU.
(1) Register setting
To set the three-wire serial I/O mode, manipulate the following two registers:
• Serial operation mode register (CSIM)
• Serial bus interface control register (SBIC)
(a) Serial operation mode register (CSIM)
To use the three-wire serial I/O mode, set CSIM as shown below. (For details on CSIM format, see
(1) in Section 5.6.3.)
CSIM0 is manipulated using an 8-bit manipulation instruction. Bits 7, 6, and 5 of CSIM can be
manipulated bit by bit.
When the RESET signal is input, CSIM is set to 00H.
In the figure below, hatched portions indicate the bits used in the three-wire serial I/O mode.
7
6
5
4
3
2
1
0
Address
FE0H
CSIE COI WUP CSIM4 CSIM3 CSIM2 CSIM1 CSIM0 CSIM
Serial clock selection bit (W)
Serial interface operation mode selection bit (W)
Wake-up function specification bit (W)
Match signal from address comparator (R)
Serial interface operation enable/disable specification bit (W)
Remark (R): Read only
(W): Write only
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Serial interface operation enable/disable specification bit (W)
Shift register operation
Shift operation enabled
Serial clock counter IRQCSI flag
SO/SB0 and SI/SB1 pins
CSIE
1
Count operation Can be set Used in each mode
as well as for port 0
Signal from address comparator (R)
Note
COI
Condition for being cleared (COI = 0)
Condition for being set (COI = 1)
When the slave address register (SVA)
does not match the data of the shift register
When the slave address register (SVA)
matches the data of the shift register
Note COI can be read only before serial transfer is started or after serial transfer is completed. An
undefined value may be read during transfer. COI data written by an 8-bit manipulation instruction
is ignored.
Wake-up function specification bit (W)
WUP
0
Sets IRQCSI each time serial transfer is completed.
Serial interface operation mode selection bit (W)
CSIM4 CSIM3
CSIM2
0
Shift register sequence
<—> XA
SO pin function
SI pin function
SI/P03
x
0
SIO
SO/P02
7-0
(Transfer starting with MSB)
(CMOS output)
(Input)
1
SIO <—> XA
0-7
(Transfer starting with LSB)
Remark x: Don’t care
Serial clock selection bit (W)
CSIM1 CSIM0
Serial clock
SCK pin mode
0
0
1
1
0
1
0
1
External clock applied to SCK pin
Timer/event counter output (TOUT0)
Input
Output
4
Note
Note
f /2 (262 kHz)
X
3
f /2 (524 kHz)
X
Note ( ): fx = 4.19 MHz
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(b) Serial bus interface control register (SBIC)
To use the three-wire serial I/O mode, set SBIC as shown below. (For details on SBIC format, see
(2) in Section 5.6.3.)
SBIC is manipulated using a bit memory manipulation instruction.
When the RESET signal is input, SBIC is set to 00H.
In the figure below, hatched portions indicate the bits used in the three-wire serial I/O mode.
7
6
5
4
3
2
1
0
Address
FE2H
BSYE ACKD ACKE ACKT CMDD RELD CMDT RELT SBIC
Do not use these bits in the
three-wire serial I/O mode.
Bus release trigger bit (W)
Command trigger bit (W)
Remark (W): Write only
Command trigger bit (W)
CMDT
Control bit for command signal (CMD) trigger output. By setting CMDT = 1, the SO latch is
cleared. Then the CMDT bit is automatically cleared.
Bus release trigger bit (W)
RELT
Control bit for bus release signal (REL) trigger output.
By setting RELT = 1, the SO latch is set to 1. Then the RELT bit automatically cleared to 0.
Caution Never use bits other than RELT and CMDT in the three-wire serial I/O mode.
(2) Communication operation
The three-wire serial I/O mode transfers data, with eight bits as one block. Data is transferred bit by bit
in phase with the serial clock.
The shift register performs shift operation on the falling edge of the serial clock (SCK). Send data is latched
on the SO latch, and is output on the SO pin. Receive data applied to the SI pin is latched in the shift
register on the rising edge of SCK.
When eight bits have been transferred, shift register operation automatically terminates setting the
interrupt request flag (IRQCSI).
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Figure 5-44. Timing of Three-Wire Serial I/O Mode
1
2
3
4
5
6
7
8
SCK
SI
DI7
DI6
DI5
DI4
DI3
DI2
DI1
DI0
SO
DO7
DO6
DO5
DO4
DO3
DO2
DO1
DO0
IRQCSI
Completion of transfer
Transfer operation is started in phase with falling edge of SCK.
Execution of instruction that writes data to SIO (Transfer start request)
The SO pin becomes a CMOS output and outputs the state of the SO latch. So the output state of the
SO pin can be manipulated by setting the RELT bit and CMDT bit.
However, this manipulation must not be performed during serial transfer.
The output level of the SCK pin can be controlled by manipulating the P01 output latch in the output mode
(internal system clock mode). (See Section 5.6.8.)
(3) Serial clock selection
To select the serial clock, manipulate bits 0 and 1 of serial operation mode register 0 (CSIM). The serial
clock can be selected out of the following four clocks:
Table 5-7. Serial Clock Selection and Application (In the Three-Wire Serial I/O Mode)
Mode register
Serial clock
Masking of
Timing for shift register R/W and
start of serial transfer
Application
CSIM
CSIM
0
Source
1
serial clock
0
0
1
External
SCK
Automatically
masked when
8-bit data
transfer is
completed
<1> In the operation halt mode
(CSIE = 0)
<2> When the serial clock is
masked after 8-bit transfer
<3> When SCK is high
Slave CPU
0
TOUT
flip-flop
Half-duplex asyn
chronous transfer
(software control)
4
1
1
0
1
f /2
Middle-speed
serial transfer
X
3
f /2
X
High-speed serial
transfer
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(4) Signals
Figure 5-45 shows operations of RELT and CMDT.
Figure 5-45. Operations of RELT and CMDT
SO latch
RELT
CMDT
(5) Switching between MSB and LSB as the first transfer bit
The three-wire serial I/O mode has a function that can switch between the MSB and LSB as the first bit
of transfer.
Figure 5-46 shows the configuration of shift register (SIO) and internal bus. As shown in Figure 5-46,
read or write operation can be performed by switching between the MSB and LSB.
This switching can be specified using bit 2 of serial operation mode register (CSIM).
Figure 5-46. Transfer Bit Switching Circuit
7
6
Internal bus
1
0
LSB first
Read/write gate
Read/write gate
MSB first
SO latch
Shift resister (SIO)
SI
D
Q
SO
SCK
The first bit is switched by changing the order of data bits written to shift register (SIO). The shift operation
order of SIO is always the same.
Accordingly, the first bit must be switched between the MSB and LSB before writing data to the shift
register.
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(6) Transfer start
Serial transfer is started by writing transfer data into shift register (SIO), provided that the following two
conditions are satisfied:
• The serial interface operation enable/disable specification bit (CSIE) is set to 1.
• The internal serial clock is not operating after 8-bit serial transfer, or SCK is high.
Caution Setting CSIE after writing data to the shift register does not start transfer.
When eight bits have been transferred, serial transfer automatically terminates setting the interrupt request
flag (IRQCSI).
Example To transfer the RAM data specified with the HL register to SIO, load the SIO data to the
accumulator and start serial transfer:
MOV XA,@HL
SEL MB15
; Fetch transmit data from RAM
; or CLR1 MBE
XCH XA,SIO
; Exchange transmit data and receive data, and start transfer
(7) Application of the three-wire serial I/O mode
(a) Data is transferred starting with the MSB on a transfer clock of 262 kHz (during 4.19-MHz
operation). (Master operation)
<Sample program>
CLR1 MBE
MOV XA,#10000010B
MOV CSIM,XA
MOV XA,TDATA
MOV SIO,XA
; Set transfer mode
; TDATA is transfer data storage address
; Set transfer data, and start transfer
Caution A second or subsequent transfer can be started by setting data in SIO (MOV SIO,XA
or XCH XA,SIO).
µPD750008
µPD7225G (LCD controller/driver), etc.
SCK
SCK
SI
SO/SB0
In this case, the SI/SBI pin on the µPD750008 can be used as an input.
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(b) Data is transmitted and received starting with the LSB on an external clock (slave operation).
(In this case, the function of inverting the MSB/LSB is used for shift register read/write operation.)
Other microcomputers
SCK
µPD750008
P01/SCK
SI/SB1
SO
SI
SO/SB0
<Sample program>
Main routine
CLR1
MOV
MOV
MOV
MOV
EI
MBE
XA,#84H
CSIM,XA
XA,TDATA
SIO,XA
; Serial operation halt, MSB/LSB invert mode, external clock
; Set transfer data, and start transfer
IECSI
EI
Interrupt routine (MBE = 0)
MOV
XCH
MOV
RETI
XA,TDATA
XA,SIO
; Start to transfer receive data and transmit data
; Save receive data
RDATA,XA
(c) Data is transmitted and received at high speed by using a transfer clock of 524 kHz (during
4.19 MHz operation).
µPD750008 (master)
SCK
µPD75206, etc.
SCK
SO/SB0
SI/SB1
SI
SO
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<Sample program> (master side):
CLR1
MOV
MOV
MOV
MOV
MBE
XA,#10000011B
CSIM,XA
XA,TDATA
SIO,XA
; Set transfer mode
; Set transfer data, and start transfer
.
.
.
.
.
.
.
.
.
.
LOOP : SKTCLR
BR
IRQCSI
LOOP
; Test IRQCSI
MOV
XA,SIO
; Read in receive data
5.6.6 Two-Wire Serial I/O Mode
The two-wire serial I/O mode can be made compatible with any communication format by programming.
In this mode, communication is basically performed using two lines: Serial clock (SCK) and serial data input/
output (SB0 or SB1).
Figure 5-47. Example of Two-Wire Serial I/O System Configuration
2-wire serial I/O
2-wire serial I/O
Master CPU
Slave CPU
(µPD750008)
SCK
SCK
VDD
SB0, SB1
SB0, SB1
Remark The µPD750008 can also be used as a slave CPU.
(1) Register setting
To set the two-wire serial I/O mode, manipulate the following two registers:
• Serial operation mode register (CSIM)
• Serial bus interface control register (SBIC)
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(a) Serial operation mode register (CSIM)
To use the two-wire serial I/O mode, set CSIM as shown below. (For details on CSIM format, see
(1) in Section 5.6.3.)
CSIM is manipulated using an 8-bit manipulation instruction. Bits 7, 6, and 5 of CSIM can be
manipulated bit by bit.
When the RESET signal is input, CSIM is set to 00H.
In the figure below, hatched portions indicate the bits used in the two-wire serial I/O mode.
7
6
5
4
3
2
1
0
Address
FE0H
CSIE COI WUP CSIM4 CSIM3 CSIM2 CSIM1 CSIM0 CSIM
Serial clock selection bit (W)
Serial interface operation mode selection bit (W)
Wake-up function specification bit (W)
Match signal from address comparator (R)
Serial interface operation enable/disable specification bit (W)
Remark (R: Read only
(W): Write only
Serial interface operation enable/disable specification bit (W)
Shift register operation
Shift operation enabled
Serial clock counter IRQCSI flag
SO/SB0 and SI/SB1 pins
CSIE
1
Count operation Can be set Used in each mode
as well as for port 0
Signal from address comparator (R)
Note
COI
Condition for being cleared (COI = 0)
Condition for being set (COI = 1)
When the slave address register (SVA)
does not match the data of the shift register
When the slave address register (SVA)
matches the data of the shift register
Note COI can be read only before serial transfer is started or after serial transfer is completed. An
undefined value may be read during transfer. COI data written by an 8-bit manipulation instruction
is ignored.
Wake-up function specification bit (W)
WUP
0
Sets IRQCSI each time serial transfer is completed.
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Serial interface operation mode selection bit (W)
CSIM4 CSIM3
CSIM2
1
Shift register sequence
<—> XA
SO pin function
SI pin function
P03 input
0
1
1
SIO
SB0/P02 (N-ch
open-drain I/O)
7-0
(Transfer starting with MSB)
P02 input
SB1/P03 (N-ch
open-drain I/O)
Serial clock selection bit (W)
CSIM1 CSIM0
Serial clock
External clock applied to SCK pin
SCK pin mode
0
0
1
1
0
1
0
1
Input
Output
Timer/event counter output (TOUT0)
6
f /2 (65.5 kHz)
X
Remark The value at 4.19 MHz is indicated in parentheses.
(b) Serial bus interface control register (SBIC)
To use the two-wire serial I/O mode, set SBIC as shown below. (For details on SBIC format, see (2)
in Section 5.6.3.)
SBIC is manipulated using a bit manipulation instruction.
When the RESET signal is input, SBIC is set to 00H.
In the figure below, the hatched portions indicate the bits used in the two-wire serial I/O mode.
7
6
5
4
3
2
1
0
Address
FE2H
BSYE ACKD ACKE ACKT CMDD RELD CMDT RELT SBIC
Do not use these bits in the
two-wire serial I/O mode.
Bus release trigger bit (W)
Command trigger bit (W)
Remark (W): Write only
Command trigger bit (W)
CMDT
Control bit for command signal (CMD) trigger output. By setting CMDT = 1, the SO latch is
cleared. Then the CMDT bit is automatically cleared.
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Bus release trigger bit (W)
RELT
Control bit for bus release signal (REL) trigger output.
By setting RELT = 1, the SO latch is set to 1. Then the RELT bit automatically cleared to 0.
Caution Never use bits other than RELT and CMDT in the two-wire serial I/O mode.
(2) Communication operation
The two-wire serial I/O mode transfers data, with eight bits as one block. Data is transferred bit by bit
in phase with the serial clock.
The shift register performs shift operation on the falling edge of the serial clock (SCK). Transmit data is
latched on the SO latch, and is output on the SB0/P02 pin or SB1/P03 pin starting with the MSB. Receive
data applied to the SB0 pin or SB1 pin is latched in the shift register on the rising edge of SCK.
When eight bits have been transferred, shift register operation automatically terminates setting the
interrupt request flag (IRQCSI).
Figure 5-48. Timing of Two-Wire Serial I/O Mode
1
2
3
4
5
6
7
8
SCK
SB0, SB1
D7
D6
D5
D4
D3
D2
D1
D0
IRQCSI
Completion of transfer
Transfer operation is started in phase with falling edge of SCK.
Execution of instruction that writes date to SIO (Transfer start request)
The SB0 (or SB1) pin becomes an N-ch open-drain I/O when specified as the serial data bus, so the voltage
level on that pin must be pulled up externally.
The state of the SO latch is output on the SB0 (or SB1) pin, so the SB0 (or SB1) pin output states can
be controlled by setting the RELT or CMDT bit.
However, this operation must not be performed during serial transfer.
The output state of the SCK pin can be controlled by manipulating the P01 output latch in the output mode
(internal system clock mode). (See Section 5.6.8.)
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(3) Serial clock selection
To select the serial clock, manipulate bits 0 and 1 of serial operation mode register (CSIM). The serial
clock can be selected out of the following four clocks:
Table 5-8. Serial Clock Selection and Application (In the Two-Wire Serial I/O Mode)
Mode register
Serial clock
Masking of
Timing for shift register R/W and
start of serial transfer
Application
CSIM
CSIM
0
Source
1
serial clock
0
0
1
External
SCK
Automatically
masked when
8-bit data
transfer is
completed
<1> In the operation halt mode
(CSIE = 0)
<2> When the serial clock is
masked after 8-bit transfer
<3> When SCK is high
Slave CPU
0
TOUT
flip-flop
Arbitrary-speed
serial transfer
6
1
1
0
1
f /2
X
Low-speed
serial transfer
(4) Signals
Figure 5-49 shows operations of RELT and CMDT.
Figure 5-49. Operations of RELT and CMDT
SO latch
RELT
CMDT
(5) Transfer start
Serial transfer starts by writing transfer data into shift register (SIO), provided that the following two
conditions are satisfied:
• The serial interface operation enable/disable specification bit (CSIE) is set to 1.
• The internal serial clock is not operating after 8-bit serial transfer, or SCK is high.
Cautions 1. Setting CSIE to 1 after writing data to the shift register does not start transfer.
2. When data is received, the N-ch transistor must be turned off, so FFH must be
written to SIO beforehand.
When eight bits have been transferred, serial transfer automatically terminates setting the interrupt
request flag (IRQCSI).
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(6) Error detection
In the two-wire serial I/O mode, the state of serial bus SB0 or SB1 being used for communication is loaded
into the shift register (SIO) of the transmitting device. So a transmission error can be detected by the
methods described below.
(a) Comparing SIO data before start of transmission with SIO data after start of transmission
With this method, the occurrence of a transmission error is assumed when two SIO values disagree
with each other.
(b) Using the slave address register (SVA)
Transmit data is set in SVA as well before the data is transmitted. On completion of transmission,
the COI bit (match signal from the address comparator) of serial operation mode register (CSIM) is
tested. If the result is 1, the transmission is regarded as successful. If the result is 0, the occurrence
of a transmission error is assumed.
(7) Application of two-wire serial I/O mode
A serial bus is configured, and multiple devices are connected to it.
Example A system is configured with a µPD750008 as the master to which a µPD75104, µPD75402A,
and µPD7225G are connected as slaves.
VDD
µPD750008 (master)
µPD7225G
Port
CS
SCK
SCK
SI
SO/SB0
µPD75402A
SCK
SI
SO
µPD75104
SCK
SI
SO
To configure the bus as shown above, connect the SI pin and SO pin. Then, writes FFH to the shift register
to make the SO pin high except when serial data is output, and free the bus by setting off the output buffer.
The SO pin of the µPD75402A cannot go into a high-impedance state, so that a transistor must be
connected as shown in the figure to make open collector output appear on the pin. When data is input,
00H must be set beforehand in the shift register to set the transistor off.
The timing of data output by each microcomputer must be predetermined.
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The µPD750008, which is the master microcomputer, outputs a serial clock, and all slave microcomputers
operate with an external clock.
5.6.7 SBI Mode Operation
The SBI (serial bus interface) is a high-speed serial interface that conforms to the NEC serial bus format.
To allow communication with multiple devices on a single-master and high-speed serial bus using two signal
lines, the SBI has a bus configuration function added to the clock synchronous serial I/O method. So the SBI
can reduce ports and wires on boards when multiple microcomputers and peripheral ICs are used to configure
a serial bus.
The master can output, on the serial data bus, an address for selecting a device subject to serial
communication, commands directed to the remote device, and data. A slave can identify an address,
commands, and data from received data by hardware. This function simplifies the serial interface control
portion of an application program.
The SBI function is available with devices such as the 75X series, 75XL series, and 78K series 8-/16-bit
single chip microcomputers.
Figure 5-50 is an example of the SBI system configuration when the CPU with a serial interface conforming
to SBI or peripheral ICs are used.
Figure 5-50. Example of SBI System Configuration
VDD
Master CPU
Slave CPU
µPD750008
µPD750008
SB0, SB1
SCK
SB0, SB1
SCK
Address 1
Slave CPU
SB0, SB1
SCK
Address 2
Slave IC
SB0, SB1
SCK
Address N
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Cautions 1. In the SBI mode, the serial data bus pin SB0 (or SB1) is an open-drain output. So
the serial data bus line is placed in the wired OR state. A pull-up resistor is
required for the serial data bus line.
2. To switch between the master and slave, a pull-up resistor is required also for the
serial clock line (SCK) because SCK input/output switching is performed between
the master and slave asynchronously.
(1) SBI functions
Conventional serial I/O methods provide only data transfer functions. Therefore, many ports and wires
are required to identify chip select signals, commands, and data, and to detect busy states, when the serial
bus is configured with multiple devices. Also, these processes are too burdensome to be controlled by
software.
The SBI method can configure a serial bus with two signal lines: Serial clock SCK and serial data bus
(SB0 or SB1). For this reason, the number of ports on a microcomputer can be reduced and the wiring
on a circuit board can be simplified.
SBI functions are described below.
(a) Address/command/data identification function
Serial data is classified into three types: Address, command, and data.
(b) Address-based chip select function
The master selects a chip for a slave by address transfer.
(c) Wake-up function
A slave can easily check address reception (for chip select identification) with the wake-up function.
This function can be set or released by software.
When the wake-up function is set, an interrupt (IRQCSI) is generated when a match address is
received. For this reason, in communication with multiple devices, a CPU other than a selected slave
can operate independently of serial communication.
(d) Acknowledge signal (ACK) control function
The acknowledge signal, which is used to confirm the reception of serial data, can be controlled.
(e) Busy signal (BUSY) control function
The busy signal, which is used to post the busy state of a slave, can be controlled.
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(2) SBI definition
The format of serial data and signal used in the SBI mode are described below.
Serial data to be transferred in the SBI mode is classified into three types: Address, command, and data.
Serial data forms one frame as shown below.
Figure 5-51 is a timing chart for transferring address, command, and data.
Figure 5-51. Timing of SBI Transfer
Address transfer
SCK
8
9
SB0, SB1
A7
A0
ACK
BUSY
Bus release signal
Command transfer
Command signal
SCK
9
SB0, SB1
C7
C0 ACK
BUSY
READY
Data transfer
8
9
SCK
D7
D0 ACK
BUSY
READY
SB0, SB1
The bus release signal and command signal are output by the master. BUSY is output by a slave. ACK
is output by either the master or a slave. (Normally, the device which received 8-bit data outputs ACK.)
The master continues to output the serial clock from when 8-bit data transfer starts to when BUSY is
released.
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(a) Bus release signal (REL)
When the SCK line is high (the serial clock is not output), the SB0 (or SB1) line changes from low
to high. This signal is called the bus release signal, and is output by the master.
Figure 5-52. Bus Release Signal
"H"
SCK
SB0, SB1
This signal indicates that the master is to send an address to a slave. Slaves contain hardware to
detect the bus release signal.
(b) Command signal (CMD)
When the SCK line is high (the serial clock is not output), the SB0 (or SB1) line changes from high
to low. This signal is called the command signal, which is output by the master.
Figure 5-53. Command Signal
SCK
"H"
SB0, SB1
Slaves contain hardware to detect the command signal.
(c) Address
An address is 8-bit data and is output by the master to connected slaves to select a particular slave.
Figure 5-54. Address
SCK
1
2
3
4
5
6
7
8
SB0, SB1
A7
A6 A5 A4 A3 A2 A1 A0
Address
Bus release signal
Command signal
The 8-bit data following the bus release signal or command signal is defined as an address. A slave
detects the condition for the addresses by hardware, and checks whether the 8-bit data matches the
number assigned to the slave (slave address). If the 8-bit data matches the slave address, that slave
is selected. The selected slave continues to communicate with the master until disconnection is
directed by the master.
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Figure 5-55. Slave Selection Using an Address
Master
Slave 1
Slave 2
Slave 3
Slave 4
Not selected
Selected
Transmits address for
slave 2
Not selected
Not selected
(d) Command and data
The master sends commands to the slave selected by sending an address. The master also transfers
data to or from the slave.
Figure 5-56. Command
1
2
3
4
5
6
7
8
SCK
SB0, SB1
C7 C6 C5 C4 C3 C2 C1 C0
Command
Command signal
Figure 5-57. Data
SCK
1
2
3
4
5
6
7
8
SB0, SB1
D7 D6 D5 D4 D3 D2 D1 D0
Data
The 8-bit data following the command signal is defined as a command. The 8-bit data without the
command signal is defined as data. The usage of commands or data can be selected optionally
according to the communication specifications.
(e) Acknowledge signal (ACK)
The acknowledge signal confirms the reception of serial data between the transmitter and the receiver.
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Figure 5-58. Acknowledge Signal
[When output in phase with the 11th clock of SCK]
SCK
8
9
10
11
SB0, SB1
ACK
[When output in phase with the 9th clock of SCK]
SCK
8
9
ACK
SB0, SB1
The acknowledge signal is a one-shot pulse output in phase with the falling edge of SCK after 8-bit
data transfer. This signal may be synchronized with any clock of SCK.
The transmitter checks if the receiver returns the acknowledge signal after 8-bit data transfer. If the
acknowledge signal is not returned after a specified period of time, the transmitter can assume that
the reception failed.
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(f) Busy signal (BUSY) and ready signal (READY)
The busy signal informs the master that a slave is getting ready for data transfer.
The ready signal informs the master that a slave is ready for data transfer.
Figure 5-59. Busy and Ready Signals
8
9
SCK
ACK
SB0, SB1
BUSY
READY
In the SBI mode, a slave notifies the master of the busy state by changing SB0 (or SB1) from high
to low.
The busy signal is output following the acknowledge signal output by the master or a slave. The busy
signal is set and released in phase with the falling edge of SCK. The master automatically terminates
output of serial clock SCK when the busy signal is released.
The master can transfer the next data when the busy signal is released and a slave enters the state
in which the ready signal is to be output.
(3) Register setting
To set the SBI mode, manipulate the following two registers:
• Serial operation mode register (CSIM)
• Serial bus interface control register (SBIC)
(a) Serial operation mode register (CSIM)
To use the SBI mode, set CSIM as shown below. (For details on CSIM format, see (1) in Section
5.6.3.)
CSIM is manipulated using an 8-bit manipulation instruction. Bits 7, 6, and 5 of CSIM can be
manipulated bit by bit.
When the RESET signal is input, CSIM is set to 00H.
In the figure below, hatched portions indicate the bits used in the SBI mode.
7
6
5
4
3
2
1
0
Address
FE0H
CSIE COI WUP CSIM4 CSIM3 CSIM2 CSIM1 CSIM0 CSIM
Serial clock selection bit (W)
Serial interface operation mode selection
bit (W)
Wake-up function specification bit (W)
Match signal from address comparator (R)
Serial interface operation enable/disable specification bit (W)
Remark (R): Read only
(W): Write only
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Serial interface operation enable/disable specification bit (W)
Shift register operation
Shift operation enabled
Serial clock counter IRQCSI flag
SO/SB0 and SI/SB1 pins
as well as for port 0
CSIE
1
Count operation Can be set Used in each mode
Signal from address comparator (R)
Note
COI
Condition for being cleared (COI = 0)
Condition for being set (COI = 1)
When the slave address register (SVA)
does not match the data of the shift register
When the slave address register (SVA)
matches the data of the shift register
Note COI can be read only before serial transfer is started or after serial transfer is completed. An
undefined value may be read during transfer.
COI data written by an 8-bit manipulation instruction is ignored.
Wake-up function specification bit (W)
WUP
0
1
Sets IRQCSI each time serial transfer is completed in each mode.
Used in the SBI mode only to set IRQCSI only when an address received after bus release
matches the data in the slave address register (wake-up state). SB0 or SB1 goes to high-
impedance state.
Caution When WUP = 1 is set during BUSY signal output, BUSY is not released. In the SBI mode,
the BUSY signal is output until the next falling edge of the serial clock (SCK) appears after
release of BUSY is directed. Before setting WUP = 1, be sure to confirm that the SB0 (or
SB1) pin is high after releasing BUSY.
Serial interface operation mode selection bit (W)
CSIM4 CSIM3
CSIM2
0
Shift register sequence
<—> XA
SO pin function
SI pin function
P03 input
0
1
1
SIO
SB0/P02 (N-ch
open-drain I/O)
7-0
(Transfer starting with MSB)
P02 input
SB1/P03 (N-ch
open-drain I/O)
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Serial clock selection bit (W)
CSIM1 CSIM0
Serial clock
External clock applied to SCK pin
SCK pin mode
0
0
1
1
0
1
0
1
Input
Output
Timer/event counter output (TOUT0)
4
f /2 (262 kHz)
X
3
f /2 (524 kHz)
X
Remark The value at 4.19 MHz is indicated in parentheses.
(b) Serial bus interface control register (SBIC)
To use the SBI mode, set SBIC as shown below. (For details on SBIC format, see(2) inSection 5.6.3.)
SBIC is manipulated using a bit manipulation instruction.
When the RESET signal is input, SBIC is set to 00H.
In the figure below, hatched portions indicate the bits used in the SBI mode.
7
6
5
4
3
2
1
0
Address
FE2H
BSYE
ACKD
ACKE
ACKT CMDD RELD
CMDT
RELT
SBIC
Bus release trigger bit (W)
Command trigger bit (W)
Bus release detection flag (R)
Command detection flag (R)
Acknowledge trigger bit (W)
Acknowledge enable bit (R/W)
Acknowledge detection flag (R)
Busy enable bit (R/W)
Remark (R):
Read only
Write only
(W):
(R/W): Read/write
Busy enable bit (R/W)
BSYE
0
1
<1> The busy signal is automatically disabled.
<2> Busy signal output is stopped in phase with the falling edge of SCK immediately after
clear instruction execution.
The busy signal is output after the acknowledge signal in phase with the falling edge of SCK.
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Acknowledge detection flag (R)
ACKD
Condition for being cleared (ACKD = 0)
Condition for being set (ACKD = 1)
<1> The transfer operation is started.
<2> The RESET signal is entered.
The acknowledge signal (ACK) is detected
(in phase with the rising edge of SCK).
Acknowledge enable bit (R/W)
ACKE
0
1
Disables automatic output of the acknowledge signal. (Output by ACKT is possible.)
When set before transfer
When set after transfer
ACK is output in phase with the 9th clock of SCK.
ACK is output in phase with SCK immediately following
the set instruction execution.
Acknowledge trigger bit (W)
ACKT
When set after transfer, ACK is output in phase with the next SCK. After ACK signal output,
this bit is automatically cleared to 0.
Cautions 1. Never set ACKT before or during serial transfer.
2. ACKT cannot be cleared by software.
3. Before setting ACKT, set ACKE = 0.
Command detection flag (R)
CMDD
Condition for being cleared (CMDD = 0)
Condition for being set (CMDD = 1)
<1> The transfer start instruction
is executed.
The command signal (CMD) is detected.
<2> The bus release signal (REL)
<3> The RESET signal is entered.
<4> CSIE = 0 (Figure 5-40)
Bus release detection flag (R)
RELD
Condition for being cleared (RELD = 0)
Condition for being set (RELD = 1)
<1> The transfer start instruction is executed.
<2> The RESET signal is entered.
<3> CSIE = 0 (Figure 5-40)
The bus release signal (REL) is detected.
<4> SVA does not match SIO when an address is
received.
Command trigger bit (W)
CMDT
Control bit for command signal (CMD) trigger output. By setting CMDT = 1, the SO latch is
cleared. Then the CMDT bit is automatically cleared.
Caution Never clear SB0 (or SB1) during serial transfer. Be sure to clear SB0 (or SB1) before or
after serial transfer.
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Bus release trigger bit (W)
RELT
Control bit for bus release signal (REL) trigger output.
By setting RELT = 1, the SO latch is set to 1. Then the RELT bit automatically cleared to 0.
Caution Never clear SB0 (or SB1) during serial transfer. Be sure to clear SB0 (or SB1) before or
after serial transfer.
(4) Serial clock selection
To select the serial clock, manipulate bits 0 and 1 of serial operation mode register (CSIM). The serial
clock can be selected out of the following four clocks:
Table 5-9. Serial Clock Selection and Application (In the SBI Mode)
Mode register
Serial clock
Masking of
Timing for shift register R/W and
start of serial transfer
Application
CSIM
1
CSIM
0
Source
serial clock
0
0
0
1
External
SCK
Automatically
masked when
8-bit data
transfer is
completed
<1> In the operation halt mode
(CSIE = 0)
<2> When the serial clock is
masked after 8-bit transfer
<3> When SCK is high
Slave CPU
TOUT
flip-flop
Arbitrary-speed
serial transfer
4
f /2
X
0
1
Middle-speed
serial transfer
1
1
3
f /2
X
High-speed
serial transfer
When the internal system clock is selected, SCK is internally terminated when the 8th clock has been
output, and is externally counted until the slave enters the ready state.
(5) Signals
Figures 5-60 to 5-65 show signals to be generated in the SBI mode and flag operations on the SBIC. Table
5-10 lists signals used in the SBI mode.
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Figure 5-60. Operations of RELT, CMDT, RELD, and CMDD (Master)
Transfer start request
SIO
SCK
SO latch
RELT
"H"
CMDT
RELD
CMDD
Figure 5-61. Operations of RELT, CMDT, RELD, and CMDD (Slave)
Transfer start request
Write to SIO.
SIO
SCK
1
2
7
8
SO latch
D7
D6
D1
D0
RELT
(Master)
CMDT
(Master)
When address match is found
RELD
When address mismatch is found
CMDD
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Figure 5-62. Operation of ACKT
When ACKT is set after transfer completion
SCK
SB0, SB1
ACKT
6
7
8
9
ACK signal is output during the first clock
cycle immediately after ACKT is set.
D2
D1
D0
ACK
When set during this period
Caution Do not set the ACKT until the transfer is completed.
Figure 5-63. Operation of ACKE (1/2)
(a) When ACKE = 1 at time of transfer completion
SCK
SB0, SB1
ACKE
1
2
7
8
9
The ACK signal is output
during the ninth clock
cycle.
D7
D6
D2
D1
D0
ACK
When ACKE = 1 at this point
(b) When ACKE is set after transfer completion
SCK
SB0, SB1
ACKE
6
7
8
9
The ACK signal is output
during the first clock cycle
immediately after ACKE is set.
D2
D1
D0
ACK
When ACKE is set during this period and ACKE = 1 at
the falling edge of the next SCK
(c) When ACKE = 0 at time of transfer completion
SCK
SB0, SB1
ACKE
1
2
7
8
9
The ACK signal is not
output.
D7
D6
D2
D1
D0
When ACKE = 0 at this point
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Figure 5-63. Operation of ACKE (2/2)
(d) When ACKE = 1 period is too short
SCK
SB0, SB1
ACKE
The ACK signal is not
output.
When ACKE is set or cleared during this period
and ACKE = 0 at the falling edge of SCK
Figure 5-64. Operation of ACKD (1/2)
(a) When ACK signal is output during the ninth SCK clock
Transfer start request
SIO
SCK
Transfer start
6
7
8
9
SB0, SB1
ACKD
D2
D1
D0
ACK
(b) When ACK signal is output after the ninth SCK clock
Transfer start request
SIO
Transfer start
SCK
SB0, SB1
ACKD
6
7
8
9
D2
D1
D0
ACK
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Figure 5-64. Operation of ACKD (2/2)
(c) Clear timing for case where start of transfer is directed during BUSY
Transfer start request
SIO
Transfer start
SCK
SB0, SB1
ACKD
6
7
8
9
D2
D1
D0
ACK
BUSY
D7
D6
Figure 5-65. Operation of BSYE
SCK
SB0, SB1
BSYE
6
7
8
9
BUSY
ACK
When BSYE = 1 at this point
When reset operation is executed during
this period and BSYE = 0 at the falling edge
of SCK
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(6) Pin configuration
The configurations of serial clock pin SCK and serial data bus pin (SB0 or SB1) are as follows:
(a) SCK: Pin for serial clock I/O
<1> Master : CMOS, push-pull output
<2> Slave : Schmitt input
(b) SB0, SB1: Pin for serial data I/O
Output to SB0 or SB1 is an N-ch open-drain output and input is Schmitt input for both
the master and a slave.
The serial data bus line must be externally pulled up because it has originally an N-ch open-drain
output.
Figure 5-66. Pin Configuration
Slave device
Master device
(Clock output)
Clock output
(Clock input)
Clock input
Serial clock
RL
N-ch open-drain
SB0, SB1
SB0, SB1 N-ch open-drain
Serial data bus
SO
SO
SI
SI
Caution When data is received, the N-ch transistor must be turned off, so FFH must be written to
SIO beforehand. The N-ch open-drain output can be turned off at any time during transfer.
However, when the wake-up function specification bit (WUP) is set to 1, the N-ch transistor
is always off, so there is no need to write FFH to SIO before reception.
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(7) Address match detection method
In the SBI mode, communication starts when the master selects a particular slave device by outputting
an address.
An address match is detected by hardware. The slave address register (SVA) is available. In the wake-
up state (WUP = 1), IRQCSI is set only when the address transmitted by the master and the value held
in SVA match.
Cautions 1. Whether a slave is selected is determined by detecting a match for a slave ad-
dress received after bus release (in the state of RELD = 1).
An address match is detected usually using an address match interrupt (IRQCSI)
generated when WUP is set to 1. So detect selection/nonselection state by slave
address when WUP is set to 1.
2. When determining whether a slave is selected without using an interrupt when
WUP is 0, do not use the address match detection method. Instead, use transfer
of commands set in advance in a program.
(8) Error detection
In the SBI mode, the state of serial bus SB0 (or SB1) being used for communication is loaded into the
shift register (SIO) of the transmitting device. So a transmission error can be detected by the methods
described below.
(a) Comparing SIO data before start of transmission with SIO data after start of transmission
With this method, the occurrence of a transmission error is assumed if two SIO values disagree with
each other.
(b) Using the slave address register (SVA)
Transmit data is set in SIO and SVA as well before the data is transmitted. On completion of
transmission, the COI bit (match signal from the address comparator) of serial operation mode register
(CSIM) is tested. If the result is 1, the transmission is regarded as successful. If the result is 0, the
occurrence of a transmission error is assumed.
(9) Communication operation
In the SBI mode, the master usually selects a slave device to communicate with from multiple devices
by outputting the address of the slave to the serial bus.
After selecting a device to communicate with, the master exchanges commands and data with the slave
device, thus establishing serial communication.
Figures 5-67 to 5-70 show the timing charts of data communication operations.
In the SBI mode, the shift register performs shift operation on the falling edge of the serial clock (SCK).
Transmit data is held on the SO latch, and is output on the SB0/P02 or SB1/P03pin starting with the MSB.
Receive data applied to the SB0 (or SB1) pin is latched in the shift register on the rising edge of SCK.
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(10) Transfer start
Serial transfer is started by writing transfer data in shift register (SIO), provided that the following two
conditions are satisfied:
• The serial interface operation enable/disable bit (CSIE) is set to 1.
• The internal serial clock is not operating after 8-bit serial transfer, or SCK is high.
Cautions 1. Transfer cannot be started by setting CSIE to 1 after writing data to the shift
register.
2. The N-ch transistor needs to be turned off when data is received. So FFH must
be written to SIO beforehand. However, when the wake-up function specification
bit (WUP) is set to 1, the N-ch transistor is always off. So FFH need not be
written to SIO beforehand for reception.
3. If data is written to SIO when the slave is busy, the data is not lost. Transfer is
started when the busy state is released and input to SB0 (or SB1) goes high.
When eight bits have been transferred, serial transfer automatically terminates setting the interrupt request
flag (IRQCSI).
Example When RAM data specified by the HL register is transferred to SIO, from which data is loaded
into the accumulator at the same time, and serial transfer is started.
MOV XA,@HL ; Extracts transmit data from RAM
SEL MB15
; or CLR1 MBE
XCH XA,SIO
; Exchanges transmit data with receive data and startstransfer
(11) Notes on the SBI mode
(a) Whether a slave is selected is determined by detecting a match for a slave address received after
bus release (in the state of RELD = 1).
An address match is detected usually using, an address match interrupt (IRQCSI) generated when
WUP is 1. So detect selection/nonselection state by slave address when WUP is set to 1.
(b) When determining whether a slave is selected without using an interrupt when WUP = 0, do not use
the address match detection method. Instead, use transfer of commands set in advance in a program.
(c) When WUP is set to 1 during BUSY signal output, BUSY is not released. In the SBI mode, after release
of BUSY is directed, the BUSY signal is output until the next falling edge of the serial clock (SCK)
appears. Before setting WUP to 1, be sure to confirm that the SB0 (or SB1) pin is high after releasing
BUSY.
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(12) SBI mode
This section describes an example of application which performs serial data communication in the SBI
mode. In the example, the µPD750008 can be used as either the master CPU or a slave CPU on the
serial bus.
The master can be switched to another CPU with a command.
(a) Serial bus configuration
In the serial bus configuration used for the example of this section, a µPD750008 is connected to the
bus line as a device on the serial bus.
Two pins on the µPD750008 are used: serial data bus SB0 (or SB1) and serial clock SCK (P01).
Figure 5-71 shows an example of the serial bus configuration.
Figure 5-71. Example of Serial Bus Configuration
VDD
Master CPU
Slave CPU
µPD750008
µPD750008
SB0, SB1
SCK
SB0, SB1
SCK
Address 1
Slave CPU
SB0, SB1
SCK
Address 2
Slave IC
SB0, SB1
SCK
Address N
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(b) Explanation of commands
(i) Types of commands
This example uses the following commands:
<1> READ command
: Transfers data from slave to master.
<2> WRITE command : Transfers data from master to slave.
<3> END command
: Informs slave of WRITE command completion.
: Informs slave of WRITE command interruption.
<4> STOP command
<5> STATUS command : Reads slave status.
<6> RESET command : Sets currently selected slave as non-selected slave.
<7> CHGMST command: Passes master authority to slave.
(ii) Protocol
The following protocol is used for communication between the master and slaves.
<1> The address of a slave with which the master intends to communicate is transmitted to select
the slave (chip select). This starts communication.
The slave that has received the address returns ACK to engage in communication with the
master (The state of the slave is changed from the non-selected state to selected state).
<2> Commands and data are transferred between the master and the slave selected in <1>.
Command and data are transferred between the master and the selected slave on a one-
to-one basis, so the other slaves must be placed in the non-selected state.
<3> Communication is completed when the selected slave is placed in the non-selected state.
This state is caused in the following cases:
• The selected slave is placed in the non-selected state when the slave receives a RESET
command from the master.
• The device that is switched from the master to a slave with a CHGMST command is placed
in the non-selected state.
(iii) Command format
The transfer format of each command is described below.
<1> READ command
The READ command reads data from a slave. One to 256 bytes of data can be read. The
data length is specified in a parameter by the master. When 00H is specified as the data
length, the 256-byte data transfer is assumed.
Figure 5-72. Transfer Format of the READ Command
M
S
M
S
S
S
S
S
READ
ACK
Data count
Data
ACK
Data 0
Data
ACK
Data N
Data
ACK
Command
Remark M: Output by the master
S: Output by the slave
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When the slave receives a transmission data count, if it has data enough for transmitting the
specified number of bytes of data, the slave returns ACK. If the slave does not have enough
data for transmission, an error occurs; ACK is not returned in this case.
The master sends ACK to the slave each time it receives one byte.
<2> WRITE command, END command, STOP command
These commands write data to a slave. One to 256 bytes of data can be written. The data
length is specified in a parameter by the master. When 00H is specified as the data length,
the 256-byte data transfer is assumed.
Figure 5-73. Transfer Format of the WRITE and END Commands
M
S
M
S
M
S
M
S
M
S
WRITE
Command
ACK
Data count
Data
ACK
Data 0
Data
ACK
Data N
Data
ACK
END
ACK
Command
Remark M: Output by the master
S: Output by the slave
If the slave has an enough area for storing receive data of the specified length, the slave
returns ACK. If the slave does not have an enough area, an error occurs; ACK is not returned
in this case.
The master transmits an END command when all data have been transferred. The END
command informs the slave that all data have been transferred correctly.
The slave accepts an END command even before data reception is uncompleted. In this case,
the data received just before the acceptance of the END command becomes valid.
The master compares the contents of SIO before transfer with the contents of SIO after
transfer to check whether the data has been output onto the bus correctly. If the contents
of SIO disagree with each other, the master interrupts data transfer by transmitting a STOP
command.
Figure 5-74. Transfer Format of the STOP Command
M
S
M
S
Data
Data
ACK
STOP
ACK
Command
Data transfer interruption
Data check error occurs.
Remark M: Output by the master
S: Output by the slave
When the slave receives a STOP command, the slave invalidates the most recently received one byte.
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CHAPTER 5 PERIPHERAL HARDWARE FUNCTIONS
<3> STATUS command
The STATUS command reads the status of the current slave.
Figure 5-75. Transfer Format of the STATUS Command
M
S
S
S
STATUS
Data
ACK
Status
ACK
Command
Remark M: Output by the master
S: Output by the slave
The slave returns the status in the format shown in Figure 5-78.
Figure 5-76. Status Format of the STATUS Command
MSB
Status
LSB
7
6
5
4
3
2
1
0
Bit indicating whether there is data ready for transmission
All 0s
0 : No transmit data
1 : Transmit data of one byte or more
Bit indicating whether the device is ready for data reception
0 : No receive data storage area
1 : Receive data storage area not smaller than one byte is present.
Bit indicating whether an error occurred
0 : No error
1 : Error occurred during previous transfer.
Bit indicating whether master can be changed or not
0 : Master cannot be changed.
1 : Master can be changed.
When the master receives a status, it returns ACK to the current slave.
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<4> RESET command
The RESET command changes the currently selected slave to a non-selected slave. When
a RESET command is transmitted, any slave can be placed in the non-selected state.
Figure 5-77. Transfer Format of the RESET Command
M
S
RESET
Command
ACK
Remark M: Output by the master
S: Output by the slave
<5> CHGMST command
The CHGMST command passes the master authority to the currently selected slave.
Figure 5-78. Transfer Format of the CHGMST Command
M
S
S
S
CHGMST
Command
ACK
Data
Data
ACK
Remark M: Output by the master
S: Output by the slave
When the slave receives a CHGMST command, the slave returns one of the following data
to the master after checking whether the slave can receive the master authority:
• 0FFH: Master changeable
• 00H: Master not changeable
The slave compares the contents of SIO before transfer with the contents of SIO after transfer.
If the contents of SIO disagree with each other, an error occurs; ACK is not returned in this
case.
If the master receives 0FFH, the master returns ACK to the slave, and starts to operate as
a slave. The slave which transmitted 0FFH starts to operate as the master when it receives
ACK.
(iv) Error occurrence
If a communication error occurs, the operation described below is performed.
The slave reports the occurrence of an error by not returning ACK to the master. If an error
occurs during reception of data, the slave sets the status bit for indicating error occurrence,
and cancels all command processing being performed.
When the transmission of one byte is completed, the master checks for ACK from the slave.
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If ACK is not returned from the slave within a predetermined period after transmission
completion, the occurrence of an error is assumed; the master outputs the ACK signal as a
dummy.
Figure 5-79. Master and Slave Operation in Case of Error
Reception is completed.
Processing by slave
Error is assumed, and processing is halted.
Erroneous data
ACK
SB0, SB1
ACK wait time
ACK from slave is checked.
Processing by master
Transfer is completed.
ACK check is started.
Error is assumed.
ACK is output.
The following errors may occur:
• Error that may occur on the slave side
<1> Invalid command transfer format
<2> Reception of an undefined command
<3> Insufficient number of transfer data bytes for a READ command
<4> Insufficient area to contain data for a WRITE command
<5> Change in data during transmission of a READ, STATUS, or CHGMST command
If any of the above types of errors occurs, ACK is not returned.
• Error that may occur on the master side
If data transmitted with a WRITE command changes during transmission, the master
transmits a STOP command to the slave.
5.6.8 Manipulation of SCK Pin Output
The SCK/P01 pin has a built-in output latch, so that this pin allows static output by software manipulation
in addition to normal serial clock output.
The number of SCK pulses can be software-set arbitrarily by manipulating the P01 output latch. (The SO/
SB0/P02 or SI/SB1/P03 pin is controlled by manipulating the RELT and CMDT bits of SBIC.)
The procedure for manipulating SCK/P01 pin output is explained below.
<1> Set serial operation mode register (CSIM) (SCK pin: output mode). When serial transfer is halted,
SCK from the serial clock control circuit is set to 1.
<2> Manipulate the P01 output latch by using a bit manipulation instruction.
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Example To output one SCK/P01 pin clock cycle by software
SEL
MB15
; or CLR1 MBE
3
MOV XA,#10000011B ; SCK (f /2 ), output mode
X
MOV CSIM,XA
CLR1 0FF0H.1
SET1 0FF0H.1
; SCK/P01 <- 0
; SCK/P01 <- 1
Figure 5-80. SCK/P01 Pin Circuit Configuration
Address
FF0H.1
P01
output
latch
P01/SCK
To internal circuit
From the serial clock
control circuit
SCK
SCK pin output mode
The P01 output latch is mapped to bit 1 of address FF0H. A RESET signal sets the P01 output latch to
1.
Cautions 1. During normal serial transfer, the P01 output latch must be set to 1.
2. The P01 output latch cannot be addressed by specifying PORT0.1 (as described
below). The address of the latch (0FF0H.1) must be coded in the operand of an
instruction directly. However, MBE = 0 (or MBE = 1, MBS = 15) must be specified
before the instruction is executed.
CLR1 PORT0.1
Not allowed
SET1 PORT0.1
CLR1 0FF0H.1
Allowed
SET1 0FF0H.1
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CHAPTER 5 PERIPHERAL HARDWARE FUNCTIONS
5.7 BIT SEQUENTIAL BUFFER: 16-BIT
The bit sequential buffer (BSB) is special data memory for bit manipulations. In particular, the buffer allows
bit manipulations to be performed very easily by sequentially changing address and bit specifications. So
the buffer is useful in processing long data bit by bit.
This data memory consists of 16 bits, and allows pmem.@L addressing with a bit manipulation instruction.
This addressing uses the L register for indirect bit specification. In this case, only by incrementing or
decrementing the L register in a program loop, the bit to be manipulated can be sequentially shifted for
continued processing.
Figure 5-81. Format of the Bit Sequential Buffer
Address
Bit
FC3H
FC2H
FC1H
FC0H
3
2
1
0
3
2
1
0
3
2
1
0
3
2
1
0
Symbol
BSB3
BSB2
BSB1
BSB0
L register L = FH
L = CH L = BH
L = 8H L = 7H
L = 4H L = 3H
DECS L
L = 0H
INCS L
Remarks 1. With pmem.@L addressing, bit specification is shifted according to the L register.
2. With pmem.@L addressing, BSB can be manipulated at any time regardless of
MBE/MBS specification.
Data can also be manipulated by direct addressing. The buffer can be used for applications such as
continuous 1-bit data input or output operations by combining direct 1-bit, 4-bit, and 8-bit addressing with
pmem.@L addressing. In 8-bit manipulation, the higher eight bits or lower eight bits are manipulated by
specifying BSB0 or BSB2.
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Example To output 16-bit data of BUFF1 and BUFF2 serially from bit 0 of port 3:
CLR1
MBE
MOV
XA,BUFF1
MOV
BSB0,XA ; Set BSB0 and BSB1
XA,BUFF2
MOV
MOV
BSB2,XA ; Set BSB2 and BSB3
L,#0
MOV
LOOP0: SKT
BSB0, @L ; Tests the specification bit of BSB
LOOP1
BR
NOP
; Dummy (For timing adjustment)
PORT3. 0 ; Sets bit 0 of port 3
LOOP2
SET1
BR
LOOP1: CLR1
NOP
PORT3. 0 ; Clears bit 0 of port 3
; Dummy (For timing adjustment)
NOP
LOOP2: INCS
BR
L
; L <- L + 1
LOOP0
RET
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CHAPTER 6 INTERRUPT AND TEST FUNCTIONS
The µPD750008 has seven vectored interrupt sources and two test inputs, allowing a wide range of
applications.
In addition, the interrupt control circuitry of the µPD750008 has the following features for very high-speed
interrupt processing.
(1) Interrupt functions
(a) Hardware controlled vectored interrupt function which can control whether or not to accept an interrupt
using the interrupt flag (IExxx) and interrupt master enable flag (IME).
(b) The interrupt start address can be set arbitrarily.
6
(c) Multiple interrupt function which can specify the priority by the interrupt priority specification register
(IPS)
(d) Test function of an interrupt request flag (IRQxxx)
(The software can confirm that an interrupt occurred.)
(e) Release of the standby mode (Interrupts released by an interrupt enable flag can be selected.)
(2) Test functions
(a) Whether test request flags (IRQxxx) are issued can be checked with software.
(b) Release of the standby mode (A test source to be released can be selected with test enable flags.)
6.1 CONFIGURATION OF THE INTERRUPT CONTROL CIRCUIT
Figure 6-1 shows the configuration of the interrupt control circuit. Each hardware item is mapped to a data
memory space.
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CHAPTER 6 INTERRUPT AND TEST FUNCTIONS
6.2 TYPES OF INTERRUPT SOURCES AND VECTOR TABLES
Table 6-1 lists the types of interrupt sources, and Figure 6-2 shows vector tables.
Table 6-1. Interrupt Sources
Interrupt
priority
Vectored interrupt request
(vector table address)
Interrupt source signal
In/out
Note
INTBT
INT4
Reference time interval signal from
basic interval timer/wactchdog timer
In
1
VRQ1 (0002H)
Detection of both rising and falling
edges
Out
INT0
INT1
Out
Out
2
3
VRQ2 (0004H)
VRQ3 (0006H)
Rising/falling edge
detection specification
INTCSI
INTT0
Serial data transfer completion signal
In
In
4
5
VRQ4 (0008H)
VRQ5 (000AH)
Match signal between the count
register of timer/event counter 0
and modulo register
INTT1
Match signal between the count
register of timer counter 1
and modulo register
In
6
VRQ6 (000CH)
Note The interrupt priority is used to determine the priority when two or more interrupts are
simultaneously generated.
Figure 6-2. Interrupt Vector Table
Address
0000H
0002H
0004H
0006H
0008H
000AH
000CH
(high-order 6 bits)
(low-order 8 bits)
MBE
MBE
MBE
MBE
MBE
MBE
MBE
RBE
RBE
RBE
RBE
RBE
RBE
RBE
Internal reset start address
Internal reset start address
INTBT/INT4 start address (high-order 6 bits)
INTBT/INT4 start address (low-order 8 bits)
INT0 start address
INT0 start address
INT1 start address
INT1 start address
INTCSI start address
INTCSI start address
INTT0 start address
INTT0 start address
INTT1 start address
INTT1 start address
(high-order 6 bits)
(low-order 8 bits)
(high-order 6 bits)
(low-order 8 bits)
(high-order 6 bits)
(low-order 8 bits)
(high-order 6 bits)
(low-order 8 bits)
(high-order 6 bits)
(low-order 8 bits)
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The column of interrupt priority in Table 6-1 indicates a priority assigned when multiple interrupt requests
occur concurrently or are held.
A vector table contains interrupt processing start addresses and MBE and RBE setting values during
interrupt processing. An assembler pseudo instruction (VENTn) is used to set a vector table.
Example A vector table is set for INTBT/INT4.
VENT1
MBE = 0, RBE = 0,
GOTOBT
Vector table at
address 0002
MBE·RBE setting value
Symbol for indicating
an interrupt service
routine start address
in interrupt service routine
Caution The vector table specified by VENTn (n = 1 to 6) is located at address 2n.
Example Vector tables are set for INTBT/INT4 and INTT0.
VENT1
VENT5
MBE = 0, RBE = 0, GOTOBT
MBE = 0, RBE = 1, GOTOT0
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CHAPTER 6 INTERRUPT AND TEST FUNCTIONS
6.3 VARIOUS DEVICES TO CONTROL INTERRUPT FUNCTIONS
(1) Interrupt request flags and interrupt enable flags
The following seven interrupt request flags (IRQxxx) corresponding to the interrupt sources are
provided.
INT0 interrupt request flag (IRQ0)
INT1 interrupt request flag (IRQ1)
INT4 interrupt request flag (IRQ4)
BT interrupt request flag (IRQBT)
Serial interface interrupt request flag (IRQCSI)
Timer/event counter interrupt request flag (IRQT0)
Timer counter interrupt request flag (IRQT1)
An interrupt request flag is set to 1 by an interrupt request, and is automatically cleared to 0 when interrupt
processing is performed. However, IRQBT and IRQ4 are cleared in a different way because these flags
share a vector address. (See Section 6.6.)
The following seven interrupt enable flags (IExxx) corresponding to the interrupt request flags are
provided.
INT0 interrupt enable flag (IE0)
INT1 interrupt enable flag (IE1)
INT4 interrupt enable flag (IE4)
BT interrupt enable flag (IEBT)
Serial interface interrupt enable flag (IECSI)
Timer/event counter interrupt enable flag (IET0)
Timer counter interrupt enable flag (IET1)
An interrupt enable flag set to 1 enables the corresponding interrupt, and an interrupt enable flag set to
0 disables the corresponding interrupt.
When an interrupt request flag and the interrupt enable flag are set to 1, a vectored interrupt request (VRQn)
occurs. This condition is also used to release a standby mode.
A bit manipulation instruction or 4-bit memory manipulation instruction is used to manipulate an interrupt
request flag and interrupt enable flag. A bit manipulation instruction allows direct manipulation regardless
of MBE setting. An interrupt enable flag can be manipulated using an EI IExxx instruction or DI IE instruction.
The SKTCLR instruction is usually used to test an interrupt request flag.
Example EI
IE0
IE1
; Enable INT0
DI
; Disable INT1
SKTCLR IRQCSI
; Skip and clear IRQCSI when it is set to 1.
When an interrupt request flag is set using an instruction, even if there is no interrupt request, a vectored
interrupt is executed in the same way as when an interrupt is requested.
Inputting a RESET signal clears the interrupt request and interrupt enable flags to 0, disabling all interrupts.
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Table 6-2. Set Signals for Interrupt Request Flags
Interrupt
request flag
Interrupt
enable flag
Set signals for interrupt request flags
IRQBT
Set by a reference time interval signal from the basic interval timer/watchdog
timer.
IEBT
IRQ4
IRQ0
Set by a detected rising or falling edge of an INT4/P00 pin input signal.
IE4
IE0
Set by a detected edge of an INT0/P10 pin input signal.
The detection edge is specified by the INT0 edge detection mode register
(IM0).
IRQ1
Set by a detected edge of an INT1/P11 pin input signal.
The detection edge is specified by the INT1 edge detection mode register
(IM1).
IE1
IRQCSI
IRQT0
IRQT1
Set by a serial data transfer completion signal for the serial interface.
Set by a match signal from timer/event counter 0.
IECSI
IET0
IET1
Set by a match signal from the timer counter.
(2) Interrupt priority specification register (IPS)
The interrupt priority specification register selects an interrupt with a higher priority from multiple interrupts
using the low-order three bits.
Bit 3, interrupt master enable flag (IME), specifies whether to disable all interrupts.
The IPS is set using a 4-bit memory manipulation instruction. Bit 3 is set by an EI instruction and reset
by a DI instruction.
When changing the low-order three bits of the IPS, interrupts must be disabled (IME = 0) beforehand.
Example DI
CLR1
; Disable interrupts
MBE
MOV
MOV
A,#1011B
IPS,A
; Assign a higher priority to INT1, then enable interrupts.
A RESET signal clears all bits to 0.
Caution Disable interrupts before setting the IPS.
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CHAPTER 6 INTERRUPT AND TEST FUNCTIONS
Figure 6-3. Interrupt Priority Specification Register
Address
FB2H
Symbol
IPS
3
2
1
0
IPS3
IPS2
IPS1
IPS0
High-order interrupt selection
0
0
0
0
0
1
All low-order interrupt
The listed vectored
interrupts are treated
as high-order interrupts.
VRQ1
(INTBT/INT4)
VRQ2
(INT0)
0
0
1
1
1
1
0
0
0
1
0
1
VRQ3
(INT1)
VRQ4
(INTCSI)
VRQ5
(INTT0)
VRQ6
(INTT1)
1
1
1
1
0
1
Not to be set
Interrupt master enable flag (IME)
All interrupts are disabled and no vectored interrupt is
activated.
0
1
The interrupt enable flag corresponding to an interrupt
request flag controls interrupt enabling/disabling.
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(3) Configurations of the INT0, INT1, and INT4 circuits
(a) As shown in Figure 6-4 (a), the INT0 circuit accepts an external interrupt at its rising or falling edge.
The edge to be detected can be selected.
The INT0 circuit has a noise elimination function (see Figure 6-5), called a noise eliminator, using
Note
a sampling clock, which removes pulses shorter than two sampling clock cycles
as noise. The
INT0 circuit may accept pulses which are longer than one sampling clock cycle and shorter than two
cycles as interrupts depending on the sampling timing (seeFigure 6-4 (a)). The circuit is sure to accept
pulses equal to or longer than two sampling clock cycles as interrupts.
The INT0 pin is supplied with sampling clock F or f /64, whichever is selected by bit 3 (IM03) of the
X
INT0 edge detection mode register (IM0).
Bit 0 (IM00) and bit 1 (IM01) of the INT0 edge detection mode register (IM0) are used to select a
detection edge.
Figure 6-6 (a) shows the format of IM0. A 4-bit memory manipulation instruction is used to set IM0.
A RESET signal clears all bits to 0, and a rising edge is specified to be detected.
Note When the frequency of a sampling clock is F, these cycles are equal to 2t . When the
CY
frequency of a sampling clock is f /64, these cycles are equal to 128/f .
X
X
Cautions 1. InputapulsewiderthantwosamplingclockcyclestotheINT0/P10pin. Otherwise,
the pulse is suppressed as noise by a noise eliminator when the pin is used as
a port.
2. When the noise eliminator is selected (IM02 is set to 0), INT0 does not operate
in standby mode because INT0 requires a clock for sampling. Do not select the
noise eliminator when using INT0 to release standby mode (set IM02 to 1).
(b) As shown in Figure 6-4 (b), the INT1 circuit accepts an external interrupt at its rising or falling edge.
The INT1 edge detection mode register (IM1) is used to select a detection edge.
Figure 6-6 (b) shows the format of IM1. A bit manipulation instruction is used to set IM1. A RESET
signal clears all bits to 0, and a rising edge is specified to be detected.
(c) As shown in Figure 6-4 (c), the INT4 circuit accepts an external interrupt at its rising and falling edges.
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Figure 6-4. Configurations of the INT0, INT1, and INT4 Circuits
(a) Configuration of the INT0 circuit
INT0
IRQ0
set signal
Edge detection
circuit
INT0/P10
Noise eliminator
IM02
IM03
IM00, IM01
Selector
Detection edge
specification
Sampling clock selection
IM0
4
f
X/64
Φ
Input buffer
Internal bus
(b) Configuration of the INT1 circuit
INT1
IRQ1
set signal
Edge detection circuit
INT1/P11
IM10
IM1
Detection edge specification
Input buffer
4
Internal bus
(c) Configuration of the INT4 circuit
INT4
Both-edge
detection circuit
IRQ4
set signal
INT4/P00
Input buffer
Internal bus
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Figure 6-5. I/O Timing of a Noise Eliminator
tSMP
tSMP
tSMP
tSMP
tSMP
<1> Shorter than sampling cycle (tSMP)
L
L
INT0
"L"
Removed as noise
Shaped output
H
H
<2> 1 to 2 times
L
L
L
L
(a)
INT0
Shaped output
H
L
(b)
INT0
"L"
Removed as noise
Shaped output
H
H
<3> Longer than 2 times
INT0
L
L
Shaped output
Remark t
= t or 64/f
CY X
SMP
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CHAPTER 6 INTERRUPT AND TEST FUNCTIONS
Figure 6-6. Format of Edge Detection Mode Registers
(a) INT0 edge detection mode register (IM0)
Address
FB4H
Symbol
IM0
3
2
1
0
IM03
IM02
IM01
IM00
IM01
IM00
Detection edge specification
Specifies rising edge.
0
0
1
1
0
1
0
1
Specifies falling edge.
Specifies both rising and falling edges.
Ignored (No interrupt request flag is set.)
IM02
Noise eliminator selection bit
Selects a noise eliminator.
Sampling
Enabled
Standby mode
Cannot be released
Can be released
0
1
Does not select a noise eliminator. Disabled
IM03
Sampling clock
0
1
Φ (0.67 µs, 1.33 µs, 2.67 µs, and 10.7 µs at 6.00 MHz)
f
X/64 (10.7 µs at 6.00 MHz)
(b) INT1 edge detection mode register (IM1)
Address
FB5H
Symbol
IM1
3
0
2
0
1
0
0
IM10
IM10
Detection edge specification
Specifies rising edge.
Specifies falling edge.
0
1
Caution Changing the edge detection mode register may set an interrupt request flag. So, disable
the interrupts before changing the edge detection mode register. Then clear the interrupt
request flag with a CLR1 instruction and enable the interrupts. When f /64 is selected
X
as a sampling clock pulse in changing IM0, wait for 16 machine cycles after changing the
mode register and clear the interrupt request flag.
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(4) Interrupt status flags
The interrupt status flags (IST0 and IST1), which are contained in the PSW, indicate the status of
processing currently executed by the CPU.
By using the content of these flags, the interrupt priority control circuit controls multiple interrupts as
indicated in Table 6-3.
A 4-bit manipulation instruction or bit manipulation instruction can be used to set and reset IST0 and IST1,
so that multiple interrupts are enabled by changing the current status of execution. IST0 and IST1 can
be manipulated on a single-bit basis at any time regardless of MBE setting.
Before IST0 or IST1 is manipulated, the DI instruction must be executed to disable interrupts, then the
EI instruction must be executed to enable interrupts.
IST1 and IST0 as well as the other PSW bits are saved in the stack memory when an interrupt is accepted
and the status of IST0 and IST1 changes to a status one level higher. When a RETI instruction is executed,
the former values of IST1 and IST0 are resumed.
Inputting a RESET signal clears the content of the flag to 0.
Table 6-3. Interrupt Processing Statuses of IST0 and IST1
After acceptance
Processing
status
Interrupts that
IST1 IST0
CPU operation
can be accepted
IST1
0
IST0
1
0
0
0
1
Status 0
Status 1
Is processing the normal program.
All
Is processing a low- or high-order
interrupt.
Only high-order
interrupts
1
0
1
1
0
1
Status 2
Is processing a high-order interrupt.
No
—
—
Not to be set
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CHAPTER 6 INTERRUPT AND TEST FUNCTIONS
6.4 INTERRUPT SEQUENCE
When an interrupt occurs, it is processed using the procedure shown in Figure 6-7.
Figure 6-7. Interrupt Sequence
Interrupt (INTxxx) occurrence
IRQxxx setting
No
IExxx set?
Hold until IExxx is set.
Yes
Corresponding VRQn occurrence
No
Hold until IME
is set.
IME = 1
Yes
Is
VRQn high-order
interrupt?
Hold until process-
ing being executed
is finished.
No
Yes
No
No
Note 1
Note 1
IST1, 0 = 00 or 01
IST1, 0 = 00
Yes
Yes
If two or more VRQns occur, select
one VRQn according to Table 6-1.
Selected
VRQn
Remaining
VRQns
Save contents of PC and PSW in stack memory and set dataNote 2 in vector table
corresponding to activated VRQn to PC, RBE, and MBE.
Change contents of IST0 and IST1 from 00 to 01
or from 01 to 10.
Reset accepted IRQxxx.
See Section 6.6 when those interrupt
sources share vector address.
Jump to the start address for processing the interrupt service program.
Notes 1. IST0 and IST1 are the interrupt status flags (bits 3 and 2 of the PSW). (See Table 6-3.)
2. An interrupt service program start address and MBE and RBE setting values at the
start of interrupt are stored in each vector table.
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6.5 MULTIPLE INTERRUPT PROCESSING CONTROL
The µPD750008 can handle multiple interrupts by either of the following methods.
(1) Multiple interrupt processing by a high-order interrupt
In this method, the µPD750008 selects an interrupt source among multiple interrupt sources, enabling
double interrupt processing.
That is, the high-order interrupt specified by the interrupt priority specification register (IPS) is enabled
when the processing status is 0 or 1. Other interrupts (interrupts lower than the specified high-order
interrupt) are enabled only when the status is 0. (See Figure 6-8 and Table 6-3.)
When only one interrupt is used as a level-two interrupt, using this method saves the user the trouble of
enabling or disabling interrupts during an interrupt processing, and holds down the number of nesting
levels to two.
Figure 6-8. Multiple Interrupt Processing by a High-Order Interrupt
Normal
processing
(Status 0)
Low- or high-order
interrupt processing
(Status 1)
High-order
interrupt
processing
(Status 2)
Interrupt is disabled.
IPS setting
Interrupt is enabled.
High-order
interrupt
occurrence
Low- or high-order
interrupt occurrence
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CHAPTER 6 INTERRUPT AND TEST FUNCTIONS
(2) Multiple interrupt processing by changing the interrupt status flags
Changing the interrupt status flags with the program causes multiple interrupts to be enabled. That is,
when the interrupt processing program changes both IST1 and IST0 to 0 (status 0), multiple interrupt
processing is enabled.
This method is used when two or more interrupts are to be enabled at a time or when the processing of
three or more interrupts is to be performed.
When changing IST1 and IST0, interrupts must be disabled beforehand with a DI instruction.
Figure 6-9. Multiple Interrupt Processing by Changing the Interrupt Status Flags
Normal processing
(status 0)
Single interrupt
Dual interrupts
Interrupt is disabled.
IPS setting
Status 1
Interrupt is
disabled.
Interrupt is enabled.
Modification
of IST
Low- or high-order
interrupt occurrence
Interrupt is
enabled.
Status 0
Status 1
Low- or high-order
interrupt occurrence
Status 0
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6.6 PROCESSING OF INTERRUPTS SHARING A VECTOR ADDRESS
Interrupt sources INTBT and INT4 share a vector table, so an interrupt source is selected as described
below.
(1) Using only one interrupt
The interrupt enable flag for desired one of the two interrupt sources sharing a vector table is set to 1,
and the interrupt enable flag for the other is cleared to 0. In this case, the enabled (IExxx = 1) interrupt
source causes an interrupt request. When the interrupt request is accepted, the interrupt request flag
is reset.
(2) Using both interrupts
The interrupt enable flags corresponding to the two interrupt sources are both set to 1. In this case, the
logical sum of the interrupt request flags for the two interrupt sources is used as an interrupt request.
In this case, even if an interrupt request or interrupt requests caused by the setting of one or both of the
interrupt request flags are accepted, the interrupt request flag or flags are not reset.
Accordingly, which of the two interrupt sources caused the interrupt needs to be determined using the
interrupt service routine. For this determination, the DI instruction is to be executed at the start of the
interrupt service routine, and the interrupt request flags are checked with the SKTCLR instruction.
If both the request flags are set when this request flag is tested or cleared, the interrupt request remains
even if one of the request flags is cleared. If this interrupt is selected as having the higher priority, nesting
processing is started by the remaining interrupt request.
*
*
Consequently, the interrupt request not tested is processed first. If the selected interrupt has the lower
priority, the remaining interrupt is kept pending and therefore, the interrupt request tested is processed
first. Therefore, an interrupt sharing a vector address with another interrupt is identified differently,
depending whether it has the higher priority, as shown in Table 6-4.
Table 6-4. Identifying Interrupt Sharing Vector Table Address
With higher priority
With lower priority
Interrupt is disabled and interrupt request flag of interrupt that takes precedence is
tested
Interrupt request flag of interrupt that takes precedence is tested
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CHAPTER 6 INTERRUPT AND TEST FUNCTIONS
Examples 1. To use both INTBT and INT4 as having the higher priority and give priority to INT4
*
DI
SKTCLR
IRQ4
;
IRQ4 = 1 ?
BR
VSUBBT
.
.
.
.
Processing routine
of INT4
EI
RETI
.
.
.
VSUBBT: CLR1
IRQBT
.
.
.
.
.
.
.
.
.
.
Processing routine
of INTBT
EI
RETI
2. To use both INTBT and INT4 as having the lower priority and give priority to INT4
*
SKTCLR
IRQ4
;
IRQ4 = 1 ?
BR
VSUBBT
.
.
.
.
.
.
.
.
.
.
Processing routine
of INT4
RETI
VSUBBT: CLR1
.
IRQBT
.
.
.
.
.
.
.
.
Processing routine
of INTBT
RETI
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6.7 MACHINE CYCLES FOR STARTING INTERRUPT PROCESSING
With the µPD750008 series, the following machine cycles are used to start the execution of the interrupt
service routine after an interrupt request flag (IRQn) is set.
(1) When IRQn is set during execution of an interrupt control instruction
When IRQn is set during execution of an interrupt control instruction, an instruction preceded by that
instruction is executed, and an interrupt processing of three machine cycles is executed, then the interrupt
service routine is started.
Interrupt control
instruction
A
B
C
D
A: IRQn is set.
B: The next instruction is executed (1 to 3 machine cycles according to the instruction).
C: Interrupt processing (3 machine cycles)
D: Interrupt service routine is executed.
Remarks 1. An interrupt control instruction manipulates hardware (address FBxH in data memory) which
handles interrupt processings. There are two types of interrupt control instruction, a DI
instruction and an EI instruction.
2. Three machine cycles required for the interrupt processing include the time to manipulate
the stack when an interrupt is accepted.
Cautions 1. Wheninterruptcontrolinstructionsarecontiguoustheseinterruptcontrolinstructions
are executed up to the last one. An instruction preceded by the interrupt control
instruction executed last is executed, and an interrupt processing of three machine
cycles is executed, then the interrupt service routine is started.
2. When a DI instruction is executed in the period during which IRQn is set (A in the
figure), or in the immediately following period, the interrupt request of the set IRQn
is held until an EI instruction is executed.
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CHAPTER 6 INTERRUPT AND TEST FUNCTIONS
(2) When IRQn is set during an instruction other than that described in (1)
(a) When IRQn is set at the last machine cycle of the instruction being executed
In this case, an instruction preceded by the instruction being executed is executed, and an interrupt
processing of three machine cycles is executed, then the interrupt service routine is started.
An instruction other than
interrupt control instruction
A
B
C
D
A: IRQn is set.
B: The next instruction is executed (1 to 3 machine cycles to the instruction).
C: Interrupt processing (3 machine cycles)
D: Interrupt service routine is executed.
Caution When one or more interrupt control instructions follow, an instruction preceded by the
interrupt control instructions is executed, and an interrupt processing of three machine
cycles is executed, then the interrupt service routine is started. When an instruction to
be executed after setting IRQn is a DI instruction, the interrupt request of the set IRQn
is held.
(b) When IRQn is set earlier than the last machine cycle of the instruction being executed
In this case, after executing the instruction being executed, an interrupt processing of three machine
cycles is executed, then the interrupt service routine is started.
An instruction other than
interrupt control instruction
A
C
D
A: IRQn is set.
C: Interrupt processing (3 machine cycles)
D: Interrupt service routine is executed.
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6.8 EFFECTIVE USE OF INTERRUPTS
The interrupt function can be used more effectively in the ways described below.
(1) MBE = 0 is set for the interrupt service routine
By allocating addresses 00H to 7FH as data memory used by the interrupt service routine and specifying
MBE = 0 in an interrupt vector table, the user can code a program without being concerned with a memory
bank.
If a program must use memory bank 1 for some reason, save the memory bank select register using the
PUSH BS instruction before selecting memory bank 1.
(2) Use different register banks for the normal routine and interrupt routine.
The normal routine uses register banks 2 and 3 with RBE = 1 and RBS = 2. If the interrupt routine is for
one nested interrupt, use register bank 0 with RBE = 0, so that you do not have to save or restore the
registers. When two or more interrupts are nested, set RBE to 1, save the register bank by using the PUSH
BS instruction, and set RBS to 1 to select register bank 1.
*
(3) Use of a software interrupt for debugging
Setting an interrupt request flag using an instruction has the same effect as the occurrence of an interrupt.
Debug operation for irregular interrupts or concurrently occurring interrupts can be performed more
efficiently by setting the interrupt request flags using an instruction.
6.9 INTERRUPT APPLICATIONS
To use the interrupt function, a main program must:
(a) Set a desired interrupt enable flag (using the EI IExxx instruction)
(b) Select an active edge when INT0 or INT1 is used (set IM0 or IM1)
(c) To use nesting (of an interrupt with the higher priority), set IPS (IME can be set at the same time).
(d) Set the interrupt master enable flag (IME) using the EI instruction
*
In the interrupt routine, MBE and RBE are set by the vector table. However, when the interrupt specified
as having the higher priority is processed, the register bank must be saved and set.
To return from the interrupt routine, use the RETI instruction.
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CHAPTER 6 INTERRUPT AND TEST FUNCTIONS
(1) Interrupt enable/disable
<Main program>
<1> Reset
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Interrupt disabled
<2> EI IE0
EI IET0
<3> EI
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INT0 and INTT0 enabled
INTT0 enabled
<4> DI IE0
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Interrupt disabled
<1> A RESET signal disables all interrupts.
<2> Interrupt enable flags are set by the EI IExxx instruction. At this stage, all interrupts are disabled.
<3> The interrupt master enable flag is set by the EI instruction. At this stage, INT0 and INTT0 are
enabled.
<4> An interrupt enable flag is cleared by the DI IExxx instruction to disable INT0.
<5> The DI instruction disables all interrupts.
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(2) Example of using INTBT, INT0 (falling edge active), and INTT0 without multiple interrupt processing
<Main program>
<1>
Reset
; RBE = 1, MBE = 0
<2> MOV A, #1
MOV IM0, A
CLR1 IRQ0
Status 0
<INT0 service program>
; RBE = 0
<3> EI IEBT
EI IE0
EI IET0
EI
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<4> INT0
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Status 1
Status 0
<5> RETI
<1> A RESET signal disables all interrupts, setting status 0.
<2> INT0 is set to be falling edge active.
<3> Interrupts are enabled by the EI and EI IExxx instructions.
<4> On the falling edge of INT0, the INT0 interrupt service program is started, status is set to 1, and all
interrupts are disabled.
<5> Control is returned from the interrupts by the RETI instruction, status 0 is set again, and interrupts
are enabled.
Remark If all the interrupts are used as having the lower priority as shown in this example, saving or
restoring the register bank is not necessary if RBE = 1 and RBS = 2 for the main program and
register banks 2 and 3 are used, and RBE = 0 for the interrupt service program and register banks
0 and 1 are used.
*
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CHAPTER 6 INTERRUPT AND TEST FUNCTIONS
(3) Nesting of interrupts with higher priority (INTBT has higher priority and INTT0 and INTCSI have
lower priority)
*
Reset
; RBE = 1, MBE = 0
SEL RB2
EI
EI
EI
IEBT
IET0
IECSI
<1> MOV A, #9
MOV IPS, A
Status 0
<INTT0 service program>
; RBE = 0
<INTBT service program>
; RBE = 1
Status 1
<4> SEL RB1
<2> INTT0
Status 2
<3> INTBT
<5> SEL RB2
RETI
Status 1
Status 0
RETI
<1> INTBT is specified as having the higher priority by setting of IPS, and the interrupt is enabled at the
same time.
<2> INTT0 service program is started when INTT0 with the lower priority occurs. Status 1 is set and the
other interrupts with the lower priority are disabled. RBE = 0 to select register bank 0.
<3> INTBT with the higher priority occurs. The level-two interrupts occurs. The status is changed to 0
and all the interrupts are disabled.
<4> RBE = 1 and RBS = 1 to select register bank 1 (only the registers used may be saved by the PUSH
instruction).
<5> RBS is returned to 2, and execution returns to the main program. The status is returned to 1.
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(4) Execution of held interrupts (interrupt requests when interrupts are disabled)
<Main program>
Reset
EI IE0
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<3> INTCSI
<2> EI
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RETI
<INTCSI service program>
<4> EI IECSI
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RETI
<1> If INT0 is set when interrupts are disabled, the interrupt request flag is held.
<2> When the interrupt is enabled by the EI instruction, the INT0 interrupt service program starts.
<3> Same as <1>
<4> When the held INTCSI flag is enabled, the INTCSI interrupt service program starts.
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CHAPTER 6 INTERRUPT AND TEST FUNCTIONS
(5) Execution of held interrupts – two interrupts with lower priority occur concurrently –
<Main program>
Reset
EI IET0
EI IE0
EI
<INT0 service program>
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<2> RETI
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RETI
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<1> When INT0 and INTT0 with the lower priority occur concurrently (during execution of the same
instruction), INT0, with a higher priority, is executed first. (INTT0 is held.)
<2> When the INT0 interrupt service program has been executed, the RETI instruction is executed to
start the interrupt service program for INTT0, which has been held.
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(6) Executing pending interrupt – interrupt occurs during interrupt processing (INTBT has higher
priority and INTT0 and INTCSI have lower priority) –
*
<Main program>
Reset
EI
EI
EI
IEBT
IET0
IECSI
MOV A, #9
MOV IPS, A
<INTBT service program>
PUSH rp
<2> INTCSI
POP rp
<3> RETI
INTT0
INTBT
<1>
<INTCSI service program>
<4> RETI
<INTT0 service program>
RETI
<1> When INTBT with the higher priority and INTT0 with the lower priority occur at the same time, the
processing of the interrupt with the higher priority is started (if there is no possibility that an interrupt
with the higher priority occurs while another interrupt with the higher priority is processed, DI IExx
is not necessary).
<2> When an interrupt with the lower priority occurs while the interrupt with the higher priority is executed,
the interrupt with the lower priority is kept pending.
<3> When the interrupt with the higher priority has been processed, INTCSI with the higher priority of
the pending interrupts is executed.
<4> When the processing of INTCSI has been completed, the pending INTT0 is processed.
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CHAPTER 6 INTERRUPT AND TEST FUNCTIONS
(7) Enabling of level-two interrupts (enabling level-two INTT0 and INT0 interrupts with INTCSI and INT4
handled as level-one interrupts)
<Main program>
Reset
EI IET0
EI IE0
Status 0
EI IECSI
<INTCSI service program>
EI IE4
EI
<2> DI
CLR1 IST0
Status 1
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DI
DI
EI
IECSI
IE4
<1> INTCSI
Status 0
<INTT0 service program>
Status 0
<3> INTT0
Status 1
<4> RETI
Status 0
<5> EI IECSI
EI IE4
RETI
<1> When an INTCSI interrupt not allowed to be a level-two interrupt occurs, the INTCSI service program
starts, and status 1 is set.
<2> Status 0 is set by clearing IST0. INTCSI and INT4 not allowed to be level-two interrupts are disabled.
<3> When INTT0 allowed to be a level-two interrupt occurs, the level-two interrupt is executed, and status
1 is set to disable all interrupts.
<4> When INTT0 processing is completed, status 0 is set again.
<5> INTCSI and INT4 which have been disabled are enabled, then control returns.
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6.10 TEST FUNCTION
6.10.1 Test Sources
The µPD750008 has two test sources. INT2 provides two types of edge-detection-test inputs.
Table 6-5. Test Source
Test source
Internal/external
INT2
(detection of the rising edge of the signal input to the INT2 pin or that of External
the first falling edge of the signals input to KR0 to KR7)
INTW (signal from clock timer)
Internal
6.10.2 Hardware to Control Test Functions
(1) Test request flags, test enable flags
Test request flags (IRQxxx) are set to 1 when the corresponding test requests (INTxxx) are issued. Clear
the test request flags to 0 with the software once the test processing has been executed.
Test enable flags (IExxx) correspond to test request flags. The test enable flags enable the standby
release signal when they are set to 1. They disables the standby release signal when they are set to 0.
When both a test request flag and the corresponding test enable flag are set to 1, the standby release
signal is generated.
Table 6-6 shows the signals which set test request flags.
Table 6-6. Signals Setting Test Request Flags
Test request flag
Signals setting test request flags
Signal from the clock timer.
Test enable flag
IRQW
IRQ2
IEW
IE2
Detection of the rising edge of INT2/P12 pin input signal or
the first falling edge of the signals input to the KR0/P60 to
KR7/P73 pins. The detection edge is selected with the INT2
edge detection mode register (IM2).
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CHAPTER 6 INTERRUPT AND TEST FUNCTIONS
(2) INT2 and key interrupt (KR0 to KR7) hardware
Figure 6-10 shows the configuration of INT2 and KR0 to KR7.
The IRQ2 set signal is output in either of the following edge detection modes, which is selected with the
INT2 edge detection mode register (IM2).
(a) Detection of a rising edge on the INT2 input pin
IRQ2 is set when a rising edge is detected on the INT2 input pin.
(b) Detection of a falling edge on any of the KR0 to KR7 input pins (key interrupt)
One of the pins KR0 to KR7 is selected to be used for interrupt input with the INT2 edge detection
mode register (IM2). When a falling edge of one of input signals applied to the selected pin is detected,
IRQ2 is set.
Figure 6-11 shows the format of IM2. IM2 is set using a 4-bit manipulation instruction. When the RESET
signal is generated, all bits are cleared to 0, and the rising edge on INT2 is specified.
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CHAPTER 6 INTERRUPT AND TEST FUNCTIONS
Figure 6-11. Format of INT2 Edge Detection Mode Register (IM2)
Address
FB6H
Symbol
IM2
3
0
2
0
1
0
IM21
IM20
IM21
IM20
INT2 interrupt source
Interrupt input pin
INT2 (1)
Specifies rising edge of INT2 pin input.
0
0
1
1
0
1
0
1
KR4 - KR7 (4)
KR2 - KR7 (6)
KR0 - KR7 (8)
Specifies falling edge of any of KRx pin
inputs.
Cautions 1. When the edge detection mode register is modified, test request flags may be set in
some cases. So, disable test inputs before modifying the edge detection mode
register. Then, clear the test request flags using a CLR1 instruction before enabling
test inputs.
2. When a low-level signal is applied to any of the pins subjected to falling edge detection,
IRQ2 is not set when a falling edge is detected on another pin.
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CHAPTER 7 STANDBY FUNCTION
The µPD750008 provides a standby function to reduce the power consumption by the system. The standby
function is available in the two modes: the STOP mode and HALT mode.
Differences between these two modes are as follows:
(1) STOP mode
In the STOP mode, the main system clock oscillator is stopped, and the entire system stops. The current
used by the CPU is reduced to quite a low level.
In addition, the contents of data memory can be preserved with a low supply voltage of down to V
1.8V, that is, this mode is effective to retain data memory with a very low current.
=
DD
7
The STOP mode of the µPD750008 can be released by an interrupt request to enable intermittent
operations. However, when the STOP mode is released, a wait time is needed for stable oscillation. Select
the HALT mode when processing must be started immediately after an interrupt request.
(2) HALT mode
In the HALT mode, the CPU clock is stopped, but the oscillation of the system clock oscillator continues.
In this mode, the system uses more current than in the STOP mode. However, the HALT mode is suitable
for starting processing immediately after an interrupt request or for intermittent operations such as watch
operation.
In either mode, all contents of the registers, flags, and data memory that are present immediately before
the standby mode is set are preserved. In addition, the states of the output latches of the I/O ports and the
states of the output buffers are also preserved, so that the states of the I/O ports are to be processed to minimize
the power consumption of the entire system.
Cautions 1. The STOP mode can be used only for the main system clock. (Subsystem clock
generation cannot be terminated.) The HALT mode can be used for either the main
system clock or the subsystem clock.
2. If the STOP mode is set when main system clock f is used for clock timer operation,
X
the clock stops operating. For continued operation, the clock must be changed to
subsystem clock f before the STOP mode is set.
XT
3. A lower power consumption and lower-voltage operation are enabled by switching
standby modes or switching CPU and system clocks. However, a switching time as
described in Section 5.2.3 is required before operation is started with a new clock after
the clock is selected with the control register. For this reason, when the clock
switching function is used together with a standby mode, the standby mode must be
set after a time needed for switching elapses.
4. Configure I/O ports for minimum power consumption in the stand by mode. Be sure
to connect signals which are high or low to input ports.
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7.1 SETTING OF STANDBY MODES AND OPERATION STATUS
Table 7-1. Operation Statuses in the Standby Mode
Mode
STOP mode
STOP instruction
HALT mode
HALT instruction
Item
Instruction for setting
Can be set only when operating on
the main system clock
Can be set either with the main
system clock or the subsystem clock
System clock for setting
Only the main system clock stops its
operation
Only the CPU clock F stops its
operation (oscillation continues)
Clock oscillator
Operation
status
Does not operate
Can operate only at main system
clock oscillation. (IRQBT is set at
reference time intervals.)
Basic interval
timer/watchdog
timer
Can operate only when the external
SCK input is selected for the serial
clock
Can operate only when external SCK
input is selected as the serial clock or
at main system clock oscillation.
Serial interface
Can operate only when TI0 pin input
is specified as the count clock or at
main system clock oscillation.
Timer/event
counter
Can operate only when the TI0 pin
input is selected for the count clock
Note 1
Does not operate
Can operate
Timer counter
Clock timer
Can operate
Can operate when f
the count clock
is selected as
XT
INT1, INT2, and INT4 can operate.
Only INT0 cannot operate.
External interrupt
CPU
Note 2
Does not operate
Release signal
An interrupt request signal from hardware whose operation is enabled by the
interrupt enable flag or the generation of a RESET signal
Notes 1. Operation is possible only when the main system clock operates.
2. Operation is possible only when the noise eliminator is not selected by bit 2 of the edge detection
mode register (IM0) (when IM02 = 1).
A STOP instruction is used to set the STOP mode, and a HALT instruction is used to set the HALT mode.
(A STOP instruction sets bit 3 of PCC, and a HALT instruction sets bit 2 of PCC.)
STOP instruction or HALT instruction must always be followed by an NOP instruction.
When changing a CPU operation clock pulse with the low-order two bits of PCC, a time lag may occur from
the time when PCC is rewritten as shown in Table 5-5 to the time when the CPU clock signal is changed.
When changing an operation clock pulse before the standby mode or a CPU clock signal after the standby
mode is released, it is necessary to rewrite PCC and set the standby mode after as many machine cycles
as required to change the CPU clock pulse have elapsed.
In a standby mode, the contents of all registers and data memory that are stopped during the standby mode,
including general registers, flags, mode registers, and output latches, are retained.
Caution 1. When the STOP mode is set, the X1 input is internally connected to V
(ground
SS
potential) to suppress leakage at the crystal oscillator circuitry. This means that the
STOP mode cannot be used with a system that uses an external clock.
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CHAPTER 7 STANDBY FUNCTION
Caution 2. Reset all the interrupt request flags before setting the standby mode. If an interrupt
source whose interrupt request flag and interrupt enable flag are both set exists, the
initiated standby mode is released immediately after it is set (see Figure 6-1). When
the STOP mode is set, however, the µPD750008 enters the HALT mode immediately
after the STOP instruction is executed, then returns to the operation mode after the
wait time specified by the BTM register has elapsed.
7.2 RELEASE OF THE STANDBY MODES
The STOP mode and HALT mode are released by a RESET signal or the generation of an interrupt request
signal that is enabled with the interrupt enable flag. Figure 7-1 shows how the STOP and HALT modes are
released.
Figure 7-1. Standby Mode Release Operation (1/2)
(a) Release of the STOP mode by RESET signal
STOP instruction
WaitNote
RESET
signal
Operating
mode
Operating
mode
STOP mode
No oscillation
HALT mode
Oscillation
Oscillation
Clock
(b) Release of the STOP mode by the occurrence of an interrupt
Wait
(Time set by BTM)
STOP instruction
Standby
release
signal
Operating
mode
Operating
mode
STOP mode
No oscillation
HALT mode
Oscillation
Oscillation
Clock
Note The following two wait times can be selected by a mask option:
17
2 /f (21.8 ms at 6.00 MHz, 31.3 ms at 4.19 MHz)
X
15
2 /f (5.46 ms at 6.00 MHz, 7.81 ms at 4.19 MHz)
X
15
However, the µPD75P0016 does not have a mask option and its wait time is fixed to 2 /f .
X
*
Remark The dashed line indicates the case where the interrupt request that releases the standby mode
is accepted.
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Figure 7-1. Standby Mode Release Operation (2/2)
(c) Release of the HALT mode by RESET signal
WaitNote
HALT instruction
RESET
signal
Operating
mode
Operating
mode
HALT mode
Oscillation
Clock
(d) Release of the HALT mode by the occurrence of an interrupt
HALT instruction
Standby
release
signal
Operating mode
HALT mode
Operating mode
Oscillation
Clock
Note The following two wait times can be selected by a mask option:
17
2 /f (21.8 ms at 6.00 MHz, 31.3 ms at 4.19 MHz)
X
15
2 /f (5.46 ms at 6.00 MHz, 7.81 ms at 4.19 MHz)
X
15
However, the µPD75P0016 dose not have a mask option and its wait time is fixed to 2 /f .
X
*
Remark The dashed line indicates the case where the interrupt request that releases the standby mode
is accepted.
When the STOP mode is released by the occurrence of an interrupt, a wait time is determined by the basic
interval timer mode register (BTM). (See Table 7-2.)
A time required for stable oscillation varies with the type of resonator used and the supply voltage at the
time of STOP mode release. Accordingly, a wait time is to be selected according to each application, and
BTM is to be set before the STOP mode is set.
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CHAPTER 7 STANDBY FUNCTION
Table 7-2. Selection of a Wait Time with BTM
Note
Wait time
BTM3 BTM2 BTM1 BTM0
( ) indicates the value for f
6.00 MHz
=
( ) indicates the value for f
4.19 MHz
=
X
X
20
20
–
–
–
–
0
0
1
1
0
1
0
1
0
1
1
1
Approx. 2 /f (Approx. 175 ms)
Approx. 2 /f (Approx. 250 ms)
X
X
17
17
Approx. 2 /f (Approx. 31.3 ms)
Approx. 2 /f (Approx. 21.8 ms)
X
X
15
15
Approx. 2 /f (Approx. 7.81 ms)
Approx. 2 /f (Approx. 5.46 ms)
X
X
13
13
Approx. 2 /f (Approx. 1.95 ms)
Approx. 2 /f (Approx. 1.37 ms)
X
X
Other than above
Not to be set
Note This time does not include the time from the release of the STOP mode to the start of oscillation.
Caution The wait times used when the STOP mode is released do not include the time (a in Figure7-
2) required before clock oscillation is started following the release of the STOP mode,
regardless of whether the STOP mode is released by a RESET signal or the generation of
an interrupt.
Figure 7-2. Wait Time When the STOP Mode Is Released
STOP mode release
Waveform
at the X1 pin
a
VSS
7.3 OPERATION AFTER A STANDBY MODE IS RELEASED
(1) If a standby mode is released by a RESET signal, normal reset operation is performed.
(2) If a standby mode is released by the occurrence of an interrupt request, the contents of the interrupt master
enable flag (IME) determines whether to perform a vectored interrupt when the CPU resumes instruction
execution.
(a) When IME = 0
If a standby mode is released, execution restarts with the instruction immediately following the
instruction used to set the standby mode.
The interrupt request flag is held.
(b) When IME = 1
If a standby mode is released, a vectored interrupt is executed after the two instructions are executed.
However, if the standby mode is released by INT2 or INTW (testable input), no vectored interrupt
occurs, and the same processing as (a) above is performed.
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7.4 SELECTION OF A MASK OPTION
For the standby function of the µPD750008, either of the following two values can be selected by a mask
option as the wait time during which the start of oscillation deferred from the generation of a RESET signal:
17
<1> 2 /f (21.8 ms at 6.00 MHz, 31.3 ms at 4.19 MHz)
X
15
<2> 2 /f (5.46 ms at 6.00 MHz, 7.81 ms at 4.19 MHz)
X
15
However, the µPD75P0016 dose not have a mask option and its wait time is fixed to 2 /f .
X
7.5 APPLICATIONS OF THE STANDBY MODES
When the standby modes are used, the following steps are used.
<1> Detect a standby mode setting factor such as power removal on an interrupt input or port input. (INT4
is useful for power removal detection.)
<2> Configure I/O ports for minimum current drain.
<3> Specify interrupts for releasing a standby mode. (INT4 is useful. All interrupt enable flags not used
for release are to be cleared.)
<4> Specify an operation to be performed after release. (IME is to be manipulated according to whether
interrupt processing is performed or not.)
<5> Specify a CPU clock to be used after release. (If the CPU clock is changed, required machine cycles
must elapse before the standby mode is set.)
<6> Select a wait time to be used when a standby mode is released.
<7> Set a standby mode using a STOP or HALT instruction.
A standby mode when combined with the system clock switch function enables a lower power consumption
and lower-voltage operation.
(1) Application of the STOP mode (at f = 4.19 MHz)
X
<Use of the STOP mode under the following conditions>
• The STOP mode is set on the falling edge of INT4, and is released on the rising edge of INT4. (INTBT
is not used.)
• All I/O ports have a high impedance.
• The INT0 and INTT0 interrupts are used for the program, but are not used to release the STOP mode.
• After the STOP mode is released, interrupts are enabled.
• After the STOP mode is released, the lowest-speed CPU clock is used for operation. Then, the CPU
clock is changed to the high-speed one after 250 ms.
• A wait time used when the STOP mode is released is about 31.3 ms.
• After the STOP mode is released, another wait time of 31.3 ms is used for stable power supply operation.
The P00/INT4 pin is checked twice to remove chattering.
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CHAPTER 7 STANDBY FUNCTION
<Timing chart>
VDD
Voltage on VDD
0 V
P00/INT4
Low-speed High-speed
operation operation
Wait
Operating mode
STOP mode
CPU operation
31.3 ms 31.3 ms
INT4
INT4
STOP instruction
<Sample program>
(INT4 service program, MBE = 0)
VSUB4:
SKT
BR
PORT0.0
; P00 = 1?
PDOWN
BTM.3
; Power-down
; Power-on
SET1
SKT
BR
WAIT:
IRQBT
WAIT
; Wait for 31.3 ms.
SKT
BR
PORT0.0
PDOWN
A,#0011B
PCC,A
XA.#xxH
PMGm,XA
IE0
; Chattering check
MOV
MOV
MOV
MOV
EI
; Set high-speed mode.
; Set port mode register.
EI
IET0
RETI
MOV
MOV
MOV
MOV
MOV
DI
PDOWN:
A,#0
; Lowest-speed mode
PCC,A
XA,#00H
PMGA,XA
PMGB,XA
IE0
; I/O port high impedance
; Disable INT0 and INTT0
DI
IET0
MOV
MOV
STOP
NOP
RETI
A,#1011B
BTM,A
.
; Wait time
31.3 ms
=
.
; Set STOP mode.
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(2) Application of the HALT mode (at f = 4.19 MHz)
X
<Intermittent operation under the following conditions>
• The main system clock is switched to the subsystem clock on the falling edge of INT4.
• The oscillation of the main system clock is stopped, and HALT mode is set.
• In the standby mode, intermittent operation is performed at intervals of 0.5 s.
• The subsystem clock is switched back to the main system clock on the rising edge of INT4.
• INTBT is not used.
<Timing chart>
VDD
Voltage on VDD
0 V
P00/INT4
Intermittent operation
(HALT mode + low-speed operation)
Operating mode Operating mode
(low-speed)
(high-speed)
Operating mode
CPU operation
250 ms
INT4
INT4
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CHAPTER 7 STANDBY FUNCTION
<Sample program>
(Initialization)
MOV
A,#0011B
PCC,A
XA,#05
WM,XA
IE4
MOV
; High-speed mode
; Subsystem clock
MOV
MOV
EI
EI
IEW
EI
(Main routine)
SKT
; Enable interrupt
PORT0.0
; Power normal?
; Power-down mode
; Power normal?
HALT
NOP
SKTCLR
IRQW
MAIN
; Flag set for 0.5 second?
; NO
BR
CALL
WATCH
; Clock subroutine
MAIN:
.
.
.
.
.
.
.
.
.
.
(INT4 service routine)
VINT4:
SKT
BR
PORT0.0
PDOWN
SCC.3
; Power normal? MBE = 0
CLR1
MOV
MOV
SKT
BR
; Start main system clock oscillation
A,#8
BTM,A
IRQBT
WAIT1
PORT0.0
PDOWN
SCC.0
WAIT1:
; Wait for 250 ms
SKT
BR
; Chattering check
CLR1
RETI
; Switch to main system clock
PDOWN:
WAIT2:
SET1
MOV
INCS
BR
SCC.0
A,#6
; Switch to subsystem clock
A
; Wait for 32 machine cycles
; Stop main system clock oscillation
WAIT2
SCC.3
SET1
RETI
Caution Before the system clock is changed from the main system clock to the subsystem clock,
a wait time sufficient for stable subsystem clock generation is required.
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CHAPTER 8 RESET FUNCTION
The µPD750008 is reset with the external reset signal (RESET) or the reset signal received from the basic
interval timer/watchdog timer. When either reset signal is input, the internal reset signal is generated. Figure
8-1 shows the configuration of the reset circuit.
Figure 8-1. Configuration of Reset Functions
RESET
Internal reset signal
Reset signal from basic
interval timer/watchdog timer
8
WDTM
Internal bus
When the RESET signal is generated, all hardware is initialized as indicated in Table 8-1. Figure 8-2 shows
the reset operation timing.
Figure 8-2. Reset Operation by Generation of RESET Signal
WaitNote
RESET signal is generated
Operating mode or
standby mode
HALT mode
Operating mode
Internal reset operation
Note The following two wait times can be selected by a mask option:
17
2 /f (21.8 ms at 6.00 MHz, 31.3 ms at 4.19 MHz)
X
15
2 /f (5.46 ms at 6.00 MHz, 7.81 ms at 4.19 MHz)
X
15
However, the µPD75P0016 dose not have a mask option and its wait time is fixed to 2 /f .
X
*
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Table 8-1. Status of the Hardware after a Reset (1/2)
Generation of a RESET signal
in a standby mode
Generation of a RESET signal
during operation
Hardware
µPD750004
4 low-order bits at address
4 low-order bits at address
Program counter (PC)
0000H in program memory are 0000H in program memory are
set in PC bits 11 to 8, and the set in PC bits 11 to 8, and the
data at address 0001H are set data at address 0001H are set
in PC bits 7 to 0.
in PC bits 7 to 0.
µPD750006,
µPD750008
5 low-order bits at address
5 low-order bits at address
0000H in program memory are 0000H in program memory are
set in PC bits 12 to 8, and the set in PC bits 12 to 8, and the
data at address 0001H are set data at address 0001H are set
in PC bits 7 to 0.
in PC bits 7 to 0.
µPD75P0016
5 low-order bits at address
5 low-order bits at address
0000H in program memory are 0000H in program memory are
set in PC bits 13 to 8, and the set in PC bits 13 to 8, and the
data at address 0001H are set data at address 0001H are set
in PC bits 7 to 0.
in PC bits 7 to 0.
Carry flag (CY)
Held
Undefined
PSW
Skip flags (SK0 to SK2)
0
0
0
0
Interrupt status flags (IST0, IST1)
Bank enable flags (MBE, RBE)
Bit 6 at address 0000H in
Bit 6 at address 0000H in
program memory is set in RBE, program memory is set in RBE,
and bit 7 is set in MBE.
and bit 7 is set in MBE.
Stack pointer (SP)
Undefined
Undefined
1000B
Undefined
Undefined
0, 0
1000B
Stack bank selection register (SBS)
Data memory (RAM)
Note
Held
General registers (X, A, H, L, D, E, B, C)
Bank selection register (MBS, RBS)
Held
0, 0
Counter (BT)
Basic
Undefined
Undefined
0
interval
timer/watch-
dog timer
Mode register (BTM)
0
0
Watchdog timer enable flag
(WDTM)
0
Counter (T0)
0
0
Timer
event
counter
Modulo register (TMOD0)
Mode register (TM0)
TOE0, TOUT flip-flop
Counter (T1)
FFH
0
FFH
0
0, 0
0
0, 0
0
Timer
counter
Modulo registers (TMOD1)
Mode register (TM1)
TOE1, TOUT flip-flop
Mode register (WM)
Shift register (SIO)
FFH
0
FFH
0
0, 0
0
0, 0
0
Clock timer
Held
0
Undefined
0
Serial
interface
Operation mode register
(CSIM)
SBI control register (SBIC)
Slave address register (SVA)
0
0
Held
Undefined
Note Data of address 0F8H to 0FDH of the data memory becomes undefined when the RESET signal is
generated.
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CHAPTER 8 RESET FUNCTION
Table 8-1. Statuses of the Hardware after a Reset (2/2)
Generation of a RESET
signal in a standby mode
Generation of a RESET
signal during operation
Hardware
Processor clock control register
(PCC)
Clock
generator,
clock
output
circuit
0
0
0
0
0
0
System clock control register
(SCC)
Clock output mode register
(CLOM)
0
0
Sub-oscillator control register (SOS)
Interrupt request flag (IRQxxx)
Reset (0)
Interrupt
Reset (0)
Interrupt enable flag (IExxx)
0
0
Priority selection register (IPS)
0
0
INT0, INT1 and INT2 mode
registers (IM0, IM1, IM2)
0, 0, 0
0, 0, 0
Output buffer
Output latch
Digital
ports
Off
Off
Clear (0)
0
Clear (0)
0
I/O mode registers (PMGA,
PMGB, PMGC)
Pull-up resistor specification
register (POGA, POGB)
0
0
Bit sequential buffers (BSB0 to BSB3)
Held
Undefined
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CHAPTER 9 WRITING TO AND VERIFYING PROGRAM MEMORY (PROM)
The program memory in the µPD75P0016 consists of a one-time PROM (16384 x 8 bits).
Writing to and verifying the contents of the one-time PROM is accomplished by using the pins shown in
the table below. Note that address inputs are not used; instead, the address is updated using the clock input
from the X1 pin.
Pin name
Function
V
Voltage is applied to this pin when writing to the program memory or verifying its
PP
contents (normally V
electric potential).
DD
X1, X2
Address update clock inputs used when writing to the program memory or verifying
its contents. The X2 pin is used to input the inverted signal of the X1 pin input.
MD0-MD3
Operation mode selection pins used when writing to the program memory or
verifying its contents.
9
P40 to P43
(low-order four bits)
P50 to P53
I/O pins for 8-bit data used when writing to the program memory or verifying
its contents.
(high-order four bits)
V
Power voltage is applied to this pin. During normal operation, 2.2 to 5.5 V should
be applied; +6 V should be applied when writing to the program memory or verifying
its contents.
DD
*
Cautions 1. The µPD75P0016CU/GB does not have an erasure window, so the erasing with
ultraviolet radiation cannot be performed.
2. Handle the pins not used for writing to or verifying the program memory, as follows:
*
• Pins other than XT2: Connect these pins to V through pull-down resistors.
SS
• XT2 pin: Open
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9.1 OPERATING MODES WHEN WRITING TO AND VERIFYING THE PROGRAM MEMORY
If +6 V is applied to the VDD pin and +12.5 V is applied to the V pin, the µPD75P0016 enters program
PP
memory write/verify mode. The specific operating mode is then selected by the setting of the MD0 through
MD3 pins as listed in the table below.
Operating mode specification
Operating mode
V
V
MD0
MD1
MD2
MD3
PP
DD
+12.5 V
+6 V
H
L
L
H
L
H
L
Program memory address clear mode
Write mode
H
H
L
H
H
Verify mode
H
X
H
H
Program inhibit mode
Remark X indicates L or H.
9.2 WRITING TO THE PROGRAM MEMORY
The procedure for writing to program memory is described below; high-speed write is possible.
(1) Pull low all unused pins to V by means of resistors.
SS
Bring X1 to low level.
(2) Apply 5 V to V
(3) Wait 10 µs.
and to V
.
PP
DD
(4) Select program memory address clear mode.
(5) Apply 6 V to V and 12.5 V to V
.
PP
DD
(6) Select program inhibit mode.
(7) Select write mode for 1 ms duration and write data.
(8) Select program inhibit mode.
(9) Select verify mode. If write is successful, proceed to step (10). If write fails, repeat steps (7) to (9).
(10) Perform additional write for (Number of repetitions of steps (7) to (9)) x 1 ms duration.
(11) Select program inhibit mode.
(12) Increment the program memory address by inputting four pulses on the X1 pin.
(13) Repeat steps (7) to (12) until the last address is reached.
(14) Select program memory address clear mode.
(15) Apply 5 V to V
and to V
.
PP
DD
(16) Turn the power off.
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CHAPTER 9 WRITING TO AND VERIFYING PROGRAM MEMORY (PROM)
The timing for steps (2) to (12) is shown below.
Repeat x times
Address
increment
Additional write
Write
Verify
VPP
VDD
VPP
VDD
VDD +1
VDD
X1
P40-P43
P50-P53
Data input
Data output
Data input
MD0
(P30)
MD1
(P31)
MD2
(P32)
MD3
(P33)
231
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µPD75008 USER'S MANUAL
9.3 READING THE PROGRAM MEMORY
The procedure for reading the contents of program memory is described below. The read is performed
in the verify mode.
(1) Pull low all unused pins to V by means of resistors. Bring X1 to low level.
SS
(2) Apply 5 V to V
(3) Wait 10 µs.
and V
.
PP
DD
(4) Select program memory address clear mode.
(5) Apply 6 V to V and 12.5 V to V
.
PP
DD
(6) Select program inhibit mode.
(7) Select verify mode. Data is output sequentially one address at a time for each cycle of four clock pulses
appearing on the X1 pin.
(8) Select program inhibit mode.
(9) Select program memory address clear mode.
(10) Apply 5 V to V
and to V
.
DD
PP
(11) Turn the power off.
The timing for steps (2) to (9) is shown below.
VPP
VPP
VDD
VDD+1
VDD
VDD
X1
P40-P43
Data output
P50-P53
Data output
MD0
(P30)
MD1
(P31)
“L”
MD2
(P32)
MD3
(P33)
232
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CHAPTER 9 WRITING TO AND VERIFYING PROGRAM MEMORY (PROM)
9.4 SCREENING OF ONE-TIME PROM
*
Because of its structure, it is difficult for NEC to completely test the one-time PROM product before
shipment. It is therefore recommended that screening be performed to verify the PROM contents after the
necessary data has been written to the PROM and the product has been stored under the following conditions.
Storage Temperature
125°C
Storage Time
24 hours
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µPD75008 USER'S MANUAL
[MEMO]
234
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CHAPTER 10 MASK OPTION
*
10.1 PIN
The pins of the µPD750008 have the following mask options:
Table 10-1. Selecting Mask Option of Pin
Pin
Mask Option
Pull-up resistor can be connected in 1-bit units.
P40-P43
P50-P53
P40 through P43 (port 4) or P50 through P53 (port 5) can be connected with pull-up resistors by mask option.
The mask option can be specified in 1-bit units.
If the pull-up resistor is connected by mask option, port 4 or 5 goes high on reset. If the pull-up resistor
is not connected, the port goes into a high-impedance state on reset.
10
The ports of the µPD75P0016 do not have a mask option and is always open.
10.2 MASK OPTION OF STANDBY FUNCTION
The standby function of the µPD750008 allows you to select wait time by using a mask option. The wait
time is required for the CPU to return to the normal operation mode after the standby function has been
released by the RESET signal (for details, see Section 7.2).
The following two wait times can be selected:
17
<1> 2 /f (21.8 ms at f = 6.00 MHz, 31.3 ms at f = 4.19 MHz)
X
X
X
15
<2> 2 /f (5.46 ms at f = 6.00 MHz, 7.81 ms at f = 4.19 MHz)
X
X
X
15
The µPD75P0016 does not have a mask option and its wait time is fixed to 2 /f .
X
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µPD750008 USER'S MANUAL
10.3 MASK OPTION FOR FEEDBACK RESISTOR OF SUBSYSTEM CLOCK
For the subsystem clock of the µPD750008, whether to enable the feedback resistor is selected by the mask
option.
<1> Enable the feedback resistor (switches on or off by software).
<2> Disable the feedback resistor (cuts by hardware).
To use the feedback resistor after selecting <1>, turn the feedback resistor on by setting SOS.0 to 0 (for
details, see (6) in Section 5.2.2).
Select <1> to use the subsystem clock.
For the µPD75P0016, the mask option need not be set; use of the feedback resistor is factory-set.
236
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CHAPTER 11 INSTRUCTION SET
The instruction set of the µPD750008 is an improved and extended version of the 75X series instruction
set. This instruction set takes over the instruction set of the 75X series, having the following features:
(1) Bit manipulation instructions allowing a wide variety of applications
(2) Efficient 4-bit manipulation instructions
(3) Eight-bit instructions comparable to 8-bit microcomputers
(4) GETI instruction for reducing program sizes
(5) String-effect instructions and number system conversion instructions for increased program efficiency
(6) Table reference instructions suitable for successive references
(7) 1-byte relative branch instructions
(8) NEC standard mnemonics designed for clarity and readability
SeeSection 3.2 for the addressing modes applicable to data memory manipulation and register banks used
for instruction execution.
11
11.1 UNIQUE INSTRUCTIONS
This section outlines the unique instructions among the µPD750008 instruction set.
11.1.1 GETI Instruction
The GETI instruction converts any of the following instructions to a 1-byte instruction:
(a) Subroutine call instruction for the entire space
(b) Branch instruction for the entire space
(c) Arbitrary 2-byte instruction operating with two machine cycles (Except the BRCB and CALLF
instructions)
(d) A combination of two 1-byte instructions
The GETI instruction references the table located at addresses 0020H to 007FH in program memory, and
executes referenced 2-byte data as an instruction of (a), (b), (c), or (d) above. This means that 48 instructions
consisting of (a) to (d) can be converted to 1-byte instructions.
Thus the GETI instruction can be used to convert frequently used instructions of (a) to (d) to 1-byte
instructions to reduce the number of program bytes significantly.
237
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µPD750008 USER'S MANUAL
11.1.2 Bit Manipulation Instructions
With the µPD750008, a variety of instructions are available for bit manipulation.
(a) Bit setting:
(b) Bit clearing:
(c) Bit testing:
(d) Bit testing:
SET1
SET1
CLR1
CLR1
SKT
mem.bit
mem.bit*
mem.bit
mem.bit*
mem.bit
mem.bit*
mem.bit
mem.bit*
SKT
SKF
SKF
(e) Bit testing and clearing: SKTCLR mem.bit*
(f) Boolean operation:
AND1
OR1
CY,mem.bit*
CY,mem.bit*
CY,mem.bit*
XOR1
mem.bit* represents a bit address addressed by using a bit manipulation addressing mode (fmem.bit,
pmem.@L, or @H+mem.bit).
Particularly, all of these bit manipulation instructions can be used for the I/O ports, so that I/O port
manipulation can be performed in a very efficient manner.
11.1.3 String-Effect Instructions
With the µPD750008, two types of string-effect instructions are available.
(a) MOV A,#n4 or MOV XA,#n8
(b) MOV HL,#n8
"String effect" means the locating of these two types of instructions at contiguous addresses.
Example A0: MOV A,#0
A1: MOV A,#1
XA7: MOV XA,#07
When string-effect instructions are arranged as in this example, if execution starts at address A0, the
following two instructions are replaced with an NOP instruction. If execution starts at address A1, the following
one instruction is replaced with an NOP instruction. That is, only the instruction first executed is valid, and
any following instructions are processed as an NOP instruction.
By using string-effect instructions, a constant can be set in an accumulator (the A register or the XA register
pair) or data pointer (the HL register pair) more efficiently.
238
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CHAPTER 11 INSTRUCTION SET
11.1.4 Number System Conversion Instructions
An application may need to convert the result of a 4-bit data addition or subtraction (performed in binary)
to a decimal number. A time-related application may require sexagesimal conversion.
For this reason, the instruction set of the µPD750008 contains number system conversion instructions for
converting the result of a 4-bit data addition or subtraction to a number in an arbitrary number system.
(a) Number system conversion for addition
Let m be a desired number system after conversion. The following combination of instructions adds
the contents of an accumulator to data in memory (HL), then converts the result of the addition to
number system m.
ADDS A,#16 – m
ADDC A,@HL ; A, CY <– A + (HL) + CY
ADDS A,#m
An overflow is set in the carry flag.
If the execution of the instruction ADDC A,@HL generates a carry, the next instruction ADDS A,#n4
is skipped. If no carry is generated, ADDS A,#n4 is executed. In this case, the skip function of this
instruction (ADDS A,#n4) is disabled, so that even if this addition generates a carry, the instruction
following this instruction is not skipped. Accordingly, programs can be written after ADDS A,#n4.
Example An accumulator is added to memory data in decimal.
ADDS A,#6
ADDC A,@HL
ADDS A,#10
; A,CY <– A + (HL) + CY
·
·
·
(b) Number system conversion for subtraction
Let m be a desired number system after conversion. The following combination of instructions
subtracts data in memory (HL) from the contents of an accumulator, then converts the result of the
subtraction to number system m.
SUBC A,@HL
ADDS A,#m
An underflow is set in the carry flag.
If the execution of the instruction SUBC A,@HL generates no borrow, the next instruction ADDS A,#n4
is skipped. If a borrow is generated, the instruction ADDS A, #n4 is executed. In this case, the skip
function of this instruction (ADDS A,#n4) is disabled, so that even if this addition generates a carry,
the instruction following this instruction is not skipped. Accordingly, programs can be written after
ADDS A,#n4.
239
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µPD750008 USER'S MANUAL
11.1.5 Skip Instructions and the Number of Machine Cycles Required for a Skip
The instruction set of the µPD750008 is designed to organize a program by testing a condition with the
skip function.
When a skip instruction satisfies the skip condition, the immediately following instruction is skipped to
execute the instruction immediately after the skipped instruction.
A skip requires the following number of machine cycles:
(a) When the instruction (to be skipped) immediately following the skip instruction is a 3-byte instruction
(that is, the BR !addr, BRA !addr1, CALL !addr, or CALLA !addr1 instruction): 2 machine cycles
(b) When the instruction (to be skipped) immediately following the skip instruction is an instruction other
than the instructions described in (a) above: 1 machine cycle
240
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CHAPTER 11 INSTRUCTION SET
11.2 INSTRUCTION SET AND OPERATION
(1) Operand identifier and description
The operand field of an instruction must contain an operand coded according to the description rule for
the operand identifier of the instruction. (Refer to RA75X Assembler Package User’s Manual:
Language (EEU-1343) for detailed information.) When there are multiple descriptions for an identifier,
one item is to be selected. The uppercase letters and + and – signs are keywords, which must be coded
as they appear.
For immediate data, a proper numeric value or label must be coded.
The abbreviations for register flags shown in Figure 3-7 can be coded as labels in place of mem, fmem,
pmem, and bit. (However, not all labels can be coded for the fmem and pmem. For details, see Table
3-1 and Figure 3-7)
Representation format
Description method
reg
reg1
X, A, B, C, D, E, H, L
X, B, C, D, E, H, L
rp
XA, BC, DE, HL
BC, DE, HL
BC, DE
XA, BC, DE, HL, XA’, BC’, DE’, HL’
BC, DE, HL, XA’, BC’, DE’, HL’
rp1
rp2
rp’
rp’1
rpa
rpa1
HL, HL+, HL–, DE, DL
DE,DL
*
n4
n8
4-bit immediate data or label
8-bit immediate data or label
Note
mem
bit
8-bit immediate data or label
2-bit immediate data or label
fmem
pmem
FB0H-FBFH and FF0H-FFFH immediate data or label
FC0H-FFFH immediate data or label
addr,
0000H-0FFFH immediate data or label (µPD750004)
0000H-17FFH immediate data or label (µPD750006)
0000H-1FFFH immediate data or label (µPD750008)
0000H-3FFFH immediate data or label (µPD75P0016)
addr1(for MkII mode only)
caddr
faddr
taddr
12-bit immediate data or label
11-bit immediate data or label
20H-7FH immediate data (bit 0 = 0) or label
PORTn
IExxx
RBn
PORT0-PORT8
IEBT, IET0, IET1, IE0-IE2, IE4, IECSI, IEW
RB0-RB3
MBn
MB0, MB1, MB15
Note For mem, only even addresses can be coded for 8-bit data processing.
241
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µPD750008 USER'S MANUAL
(2) Legend
A:
A register; 4-bit accumulator
B:
B register
C:
C register
D:
D register
E:
E register
H:
H register
L:
L register
X:
X register
XA:
BC:
DE:
HL:
XA’:
BC’:
DE’:
HL’:
PC:
SP:
CY:
PSW:
MBE:
RBE:
Register pair (XA), 8-bit accumulator
Register pair (BC)
Register pair (DE)
Register pair (HL)
Extended register pair (XA’)
Extended register pair (BC’)
Extended register pair (DE’)
Extended register pair (HL’)
Program counter
Stack pointer
Carry flag, bit accumulator
Program status word
Memory bank enable flag
Register bank enable flag
PORTn: Port n (n = 0 to 8)
IME:
IPS:
IExxx:
RBS:
MBS:
PCC:
.:
Interrupt master enable flag
Interrupt priority specification register
Interrupt enable flag
Register bank select register
Memory bank select register
Processor clock control register
Address/bit delimiter
(xx):
xxH:
Contents addressed by xx
Hexadecimal data
242
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CHAPTER 11 INSTRUCTION SET
(3) Explanation of symbols used for the addressing area column
MB = MBE · MBS
1
*
(MBS = 0, 1, 15)
2
MB = 0
*
*
3
MBE = 0 : MB = 0
(00H – 7FH)
Data memory
addressing
MB = 15 (F80H – FFFH)
MBE = 1 : MB = MBS (MBS =0, 1, 15)
4
MB = 15, fmem = FB0H – FBFH,
FF0H – FFFH
*
5
6
MB = 15, pmem = FC0H – FFFH
*
*
µPD750004
µPD750006
µPD750008
µPD75P0016
addr, addr1 = 0000H – 0FFFH
addr, addr1 = 0000H – 17FFH
addr, addr1 = 0000H – 1FFFH
addr, addr1 = 0000H – 3FFFH
addr , addr1 = (Current PC) – 15 to (Current PC) – 1
(Current PC) + 2 to (Current PC) + 16
7
8
*
µPD750004
µPD750006
caddr = 0000H – 0FFFH
*
caddr = 0000H – 0FFFH (PC12 = 0) or
1000H – 17FFH (PC12 = 1)
µPD750008
caddr = 0000H – 0FFFH (PC12 = 0) or
1000H – 1FFFH (PC12 = 1)
Program memory
addressing
µPD75P0016
caddr = 0000H – 0FFFH (PC13, PC12 = 00B) or
1000H – 1FFFH (PC13, PC12 = 01B) or
2000H – 2FFFH (PC13, PC12 = 10B) or
3000H – 3FFFH (PC13, PC12 = 11B)
9
faddr = 0000H – 07FFH
*
*
10 taddr = 0020H – 007FH
11 For MkII mode only
*
addr1 = 0000H – 0FFFH (µPD750004)
0000H – 17FFH (µPD750006)
0000H – 1FFFH (µPD750008)
0000H – 3FFFH (µPD75P0016)
Remarks 1. MB represents an accessible memory bank.
2. For 2, MB = 0 regardless of the setting of MBE and MBS.
*
3. For 4 and 5, MB = 15 regardless of the setting of MBE and MBS.
*
*
4. Each of 6 to 10 indicates an addressable area.
*
*
243
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µPD750008 USER'S MANUAL
(4) Explanation of the machine cycle column
S represents the number of machine cycles required when a skip instruction with the skip function performs
a skip operation. S assumes one of the following values:
• When no skip operation is performed: S = 0
• When a 1-byte instruction or 2-byte instruction is skipped: S = 1
Note
• When a 3-byte instruction
is skipped: S = 2
Note 3-byte instruction: BR !addr, BRA !addr1, CALL !addr, and CALLA !addr1 instructions
Caution The GETI instruction is skipped in one machine cycle.
One machine cycle is equal to one cycle (t ) of the CPU clock (F), and four different machine cycles are
CY
available for selection according to the PCC setting. (See Figure 5-12.)
244
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CHAPTER 11 INSTRUCTION SET
In
struc-
tion
Number
of
bytes
Address-
ing
area
Mne-
monic
Machine
cycle
Operation
Operation
Skip condition
String-effect A
MOV
A,#n4
1
2
2
2
2
1
1
1
1
2
1
2
2
2
2
2
2
2
2
2
1
1
1
1
2
2
2
1
2
1
2
A <– n4
reg1,#n4
XA,#n8
HL,#n8
rp2,#n8
A,@HL
A,@HL+
A,@HL–
A,@rpa1
XA,@HL
@HL,A
@HL,XA
A,mem
XA,mem
mem,A
mem,XA
A,reg
reg1 <– n4
2
XA <– n8
String-effect A
String-effect B
2
HL <– n8
2
rp2 <– n8
1
A <– (HL)
1
1
1
2
1
1
1
3
3
3
3
*
*
*
*
*
*
*
*
*
*
*
2+S
2+S
1
A <– (HL), then L <– L+1
A <– (HL), then L <– L–1
A <– (rpa1)
L=0
L=FH
2
XA <– (HL)
1
(HL) <– A
2
(HL) <– XA
2
A <– (mem)
2
XA <– (mem)
(mem) <– A
2
2
(mem) <– XA
A <– reg
2
XA,rp’
2
XA <– rp’
reg1,A
2
reg1 <– A
rp’1,XA
A,@HL
A,@HL+
A,@HL–
A,@rpa1
XA,@HL
A,mem
XA,mem
A,reg1
2
rp’1 <– XA
XCH
1
A <–> (HL)
1
1
1
2
1
3
3
*
*
*
*
*
*
*
2+S
2+S
1
A <–> (HL), then L <- L+1
A <–> (HL), then L <- L–1
A <–> (rpa1)
XA <–> (HL)
A <–> (mem)
XA <–> (mem)
A <–> reg1
L=0
L=FH
2
2
2
1
XA,rp’
2
XA <–> rp’
245
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µPD750008 USER'S MANUAL
In-
struc-
tion
Number
of
bytes
Address-
ing
area
Mne-
monic
Machine
cycle
Operand
Operation
Skip condition
MOVT
XA,@PCDE
1
3
• µPD750004
XA <– (PC
+DE)
11-8
ROM
• µPD750006, µPD750008
XA <– (PC
+DE)
12-8
ROM
ROM
ROM
• µPD75P0016
XA <– (PC
+DE)
+XA)
13-8
XA,@PCXA
1
3
• µPD750004
XA <– (PC
11-8
• µPD750006, µPD750008
XA <– (PC
+XA)
12-8
ROM
• µPD75P0016
XA <– (PC +XA)
13-8
ROM
Note
XA,@BCDE
XA,@BCXA
CY,fmem.bit
CY,pmem.@L
CY,@H+mem.bit
fmem.bit,CY
pmem.@L,CY
@H+mem.bit,CY
A,#n4
1
1
2
2
2
2
2
2
1
2
1
2
2
1
2
2
1
2
2
1
2
2
3
3
XA <– (BCDE)
XA <– (BCXA)
6
*
ROM
ROM
Note
6
*
MOV1
2
CY <– (fmem.bit)
CY <– (pmem +L .bit(L ))
4
5
1
4
5
1
*
*
*
*
*
*
2
7-2 3-2
1-0
2
CY <– (H+mem .bit)
3-0
2
(fmem.bit) <– CY
2
(pmem +L .bit(L )) <– CY
7-2 3-2 1-0
2
(H+mem .bit) <– CY
3-0
ADDS
1+S
2+S
1+S
2+S
2+S
1
A <– A+n4
carry
XA,#n8
XA <– XA+n8
carry
carry
carry
carry
A,@HL
A <– A+(HL)
1
1
1
1
*
*
*
*
XA,rp’
XA <– XA+rp’
rp’1,XA
rp’1 <– rp’1+XA
A,CY <– A+(HL)+CY
XA,CY <– XA+rp’+CY
rp’1,CY <– rp’1+XA+CY
A <– A–(HL)
ADDC
SUBS
SUBC
A,@HL
XA,rp’
2
rp’1,XA
2
A,@HL
1+S
2+S
2+S
1
borrow
borrow
borrow
XA,rp’
XA <– XA–rp’
rp’1,XA
rp’1 <– rp’1–XA
A,CY <– A–(HL)–CY
XA,CY <– XA–rp’–CY
rp’1,CY <– rp’1–XA–CY
A,@HL
XA,rp’
2
rp’1,XA
2
Note Set register B to 0 in the µPD750004. Only the LSB is valid in register B in the µPD750006 and
µPD750008. Only the low-order two bits are valid in the µPD75P0016.
246
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CHAPTER 11 INSTRUCTION SET
In-
struc-
tion
Number
of
bytes
Address-
ing
area
Mne-
monic
Machine
cycle
Operand
Operation
Skip condition
AND
A,#n4
2
1
2
2
2
1
2
2
2
1
2
2
1
2
1
1
2
2
1
2
2
2
1
2
2
2
1
1
1
1
2
1
A <– A n4
A,@HL
XA,rp’
rp’1,XA
A,#n4
A,@HL
XA,rp’
rp’1,XA
A,#n4
A,@HL
XA,rp’
rp’1,XA
A
A <– A (HL)
XA <– XA rp’
rp’1 <– rp’1 XA
A <– A n4
1
1
1
*
*
*
2
2
OR
2
1
A <– A (HL)
XA <– X A rp’
rp’1 <- rp’1 XA
A <– A n4
2
2
XOR
2
1
A <– A (HL)
XA <– XA rp’
rp’1 <– rp’1 XA
2
2
RORC
NOT
1
CY <– A , A <– CY, A
<– A
n-1 n
0
3
A
2
A <– A
INCS
reg
1+S
1+S
2+S
2+S
1+S
2+S
2+S
2+S
1+S
2+S
2+S
2+S
1
reg <– reg+1
rp1 <– rp1+1
(HL) <– (HL)+1
(mem) <– (mem)+1
reg <– reg–1
rp’ <– rp’–1
reg=0
rp1
rp1=00H
(HL)=0
@HL
mem
reg
1
3
*
*
(mem)=0
reg=FH
rp’=FFH
reg=n4
(HL)=n4
A=(HL)
XA=(HL)
A=reg
DECS
SKE
rp’
reg,#n4
@HL,#n4
A,@HL
XA,@HL
A,reg
XA,rp’
CY
Skip if reg=n4
Skip if (HL)=n4
Skip if A=(HL)
Skip if XA=(HL)
Skip if A=reg
Skip if XA=rp’
CY <– 1
1
1
1
*
*
*
XA=rp’
SET1
CLR1
SKT
CY
1
CY <– 0
CY
1+S
1
Skip if CY=1
CY <– CY
CY=1
NOT1
CY
247
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µPD750008 USER'S MANUAL
In
struc-
tion
Number
of
bytes
Address-
ing
area
Mne-
monic
Machine
cycle
Operand
Operation
Skip condition
SET1
mem.bit
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
(mem.bit) <– 1
(fmem.bit) <– 1
(pmem +L .bit(L )) <– 1
3
4
5
1
3
4
5
1
3
4
5
1
3
4
5
1
4
5
*
*
*
*
*
*
*
*
*
*
*
*
*
*
*
*
*
*
fmem.bit
pmem.@L
@H+mem.bit
mem.bit
2
7-2
3-2
1-0
2
(H+mem .bit) <– 1
3-0
CLR1
SKT
2
(mem.bit) <– 0
(fmem.bit) <– 0
fmem.bit
2
pmem.@L
@H+mem.bit
mem.bit
2
(pmem +L .bit(L )) <– 0
7-2 3-2 1-0
2
(H+mem .bit) <– 0
3-0
2+S
2+S
2+S
2+S
2+S
2+S
2+S
2+S
2+S
2+S
Skip if (mem.bit)=1
Skip if (fmem.bit)=1
(mem.bit)=1
fmem.bit
(fmem.bit)=1
(pmem.@L)=1
(@H+mem.bit)=1
(mem.bit)=0
pmem.@L
@H+mem.bit
mem.bit
Skip if (pmem +L .bit(L ))=1
7-2 3-2 1-0
Skip if (H+mem .bit)=1
3-0
SKF
Skip if (mem.bit)=0
Skip if (fmem.bit)=0
fmem.bit
(fmem.bit)=0
(pmem.@L)=0
(@H+mem.bit)=0
(fmem.bit)=1
(pmem.@L)=1
pmem.@L
@H+mem.bit
Skip if (pmem +L .bit(L ))=0
7-2 3-2 1-0
Skip if (H+mem .bit)=0
3-0
SKTCLR fmem.bit
Skip if (fmem.bit)=1 and clear
pmem.@L
Skip if (pmem +L .bit(L ))
7-2 3-2 1-0
=1 and clear
@H+mem.bit
2
2+S
Skip if (H+mem .bit)=1
1
(@H+mem.bit)=1
3-0
*
and clear
AND1
OR1
CY,fmem.bit
2
2
2
2
CY <– CY (fmem.bit)
CY <– CY
4
5
*
*
CY,pmem.@L
(pmem +L .bit(L ))
7-2
3-2
1-0
CY,@H+mem.bit
CY,fmem.bit
2
2
2
2
2
2
CY <– CY Y (H+mem .bit)
1
4
5
3-0
*
*
*
CY <– CY (fmem.bit)
CY <– CY
CY,pmem.@L
(pmem +L .bit(L ))
7-2
3-2
1-0
CY,@H+mem.bit
CY,fmem.bit
2
2
2
2
2
2
CY <– CY (H+mem .bit)
1
4
5
3-0
*
*
*
XOR1
CY <– CY (fmem.bit)
CY <– CY
CY,pmem.@L
(pmem +L .bit(L ))
7-2
3-2
1-0
CY,@H+mem.bit
2
2
CY <– CY (H+mem .bit)
1
3-0
*
248
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CHAPTER 11 INSTRUCTION SET
In
struc-
tion
Number
of
bytes
Address-
ing
area
Mne-
monic
Machine
cycle
Operand
Operation
Skip condition
BR
addr
—
—
• µPD750004
PC <– addr
6
*
11-0
The assembler selects the most
adequate instruction from
instructions below.
• BR !addr
• BR $addr
• BRCB !caddr
• µPD750006, µPD750008
PC
<– addr
12-0
The assembler selects the most
adequate instruction from
instructions below.
• BR !addr
• BRCB !caddr
• BR $addr
• µPD75P0016
PC
<– addr
13-0
The assembler selects the most
adequate instruction from
instructions below.
• BR !addr
• BRCB !caddr
• BR $addr
Note
addr1
—
—
• µPD750004
11
*
PC
<– addr1
11-0
The assembler selects the most
adequate instruction from
instructions below.
• BRA !addr1
• BR !addr
• BRCB !caddr
• BR $addr1
• µPD750006, µPD750008
PC
<– addr1
12-0
The assembler selects the most
adequate instruction from
instructions below.
• BRA !addr1
• BR !addr
• BRCB !caddr
• BR $addr1
• µPD75P0016
PC
<– addr1
13-0
The assembler selects the most
adequate instruction from
instructions below.
• BRA !addr1
• BR !addr
• BRCB !caddr
• BR $addr1
Note The shaded portion is supported in Mk II mode only.
249
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µPD750008 USER'S MANUAL
In
struc-
tion
Number
of
bytes
Address-
ing
area
Mne-
monic
Machine
cycle
Operand
!addr
Operation
Skip condition
BR
3
1
1
2
2
2
3
2
2
3
3
3
• µPD750004
PC <– addr
6
7
7
*
*
*
11-0
• µPD750006, µPD750008
PC <– addr
12-0
• µPD75P0016
PC <– addr
13-0
$addr
$addr1
PCDE
PCXA
BCDE
• µPD750004
PC <– addr
11-0
• µPD750006, µPD750008
PC <– addr
12-0
• µPD75P0016
PC <– addr
13-0
• µPD750004
PC <– addr1
11-0
• µPD750006, µPD750008
PC <– addr1
12-0
• µPD75P0016
PC <– addr1
13-0
• µPD750004
PC <– PC
+DE
11-8
11-0
• µPD750006, µPD750008
PC
<– PC
+DE
+DE
+XA
12-0
12-8
• µPD75P0016
PC
<– PC
13-0
13-8
11-8
• µPD750004
PC <– PC
11-0
• µPD750006, µPD750008
PC
<– PC
+XA
+XA
12-0
12-8
• µPD75P0016
PC <– PC
13-0
13-8
• µPD750004
PC <– BCDE
11
*
Note 1
11-0
• µPD750006, µPD750008
Note 2
PC
<– BCDE
12-0
• µPD75P0016
PC <– BCDE
Note 3
13-0
Note 1. Set register B to 0.
2. Only the LSB is valid in register B.
3. Only the low-order two bits are valid in register B.
250
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CHAPTER 11 INSTRUCTION SET
In
struc-
tion
Number
of
bytes
Address-
ing
area
Mne-
monic
Machine
cycle
Operand
BCXA
Operation
Skip condition
BR
2
3
2
3
3
3
2
3
• µPD750004
PC <– BCXA
11
*
Note 1
11-0
• µPD750006, µPD750008
Note 2
PC
<– BCXA
12-0
• µPD75P0016
Note 3
PC
<– BCXA
13-0
Note 1
BRA
!addr1
!caddr
!addr1
• µPD750004
PC <– addr
11
*
11-0
• µPD750006, µPD750008
PC <– addr
12-0
• µPD75P0016
PC <– addr1
13-0
BRCB
• µPD750004
PC <– caddr
8
*
11-0
11-0
• µPD750006, µPD750008
PC <– PC +caddr
12-0
12
11-0
• µPD75P0016
PC <– PC
+caddr
11-0
13-0
13, 12
Note 2
CALLA
• µPD750004
11
*
(SP–2) <– x, x, MBE,RBE
(SP–6)(SP–3)(SP–4) <– PC
(SP–5) <– 0, 0, 0, 0
11-0
PC
<– addr, SP <– SP–6
11-0
• µPD750006, µPD750008
(SP–2) <– x, x, MBE,RBE
(SP–6)(SP–3)(SP–4) <– PC
11-0
(SP–5) <– 0, 0, 0, PC
12
PC
<– addr, SP <– SP–6
12-0
• µPD75P0016
(SP–2) <– x, x, MBE,RBE
(SP–6)(SP–3)(SP–4) <– PC
11-0
(SP–5) <– 0, 0, PC , PC
13
12
PC
<– addr1, SP <– SP–6
13-0
Note 1. The shaded portion is supported in Mk II mode only.
2. The shaded portion is supported in Mk II mode only. The other portions are supported in Mk
I mode only.
251
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µPD750008 USER'S MANUAL
In
struc-
tion
Number
of
bytes
Address-
ing
area
Mne-
monic
Machine
cycle
Operand
!addr
Operation
Skip condition
CALLNote
3
3
• µPD750004
(SP–3) <– MBE,RBE, 0, 0
(SP–4)(SP–1)(SP–2) <– PC
6
*
11-0
PC
<– addr, SP <– SP–4
11-0
• µPD750006, µPD750008
(SP–3) <– MBE,RBE, 0, PC
(SP–4)(SP–1)(SP–2) <– PC
12
11-0
PC
<– addr, SP <– SP–4
12-0
• µPD75P0016
(SP–3) <– MBE,RBE, PC , PC
13
12
11-0
(SP–4)(SP–1)(SP–2) <– PC
PC <– addr1, SP <– SP–4
13-0
4
• µPD750004
(SP–2) <– x, x, MBE,RBE
(SP–6)(SP–3)(SP–4) <– PC
(SP–5) <– 0, 0, 0, 0
11-0
11-0
PC
<– addr, SP <– SP–6
11-0
• µPD750006, µPD750008
(SP–2) <– x, x, MBE,RBE
(SP–6)(SP–3)(SP–4) <– PC
(SP–5) <– 0, 0, 0, PC
12
PC
<– addr, SP <– SP–6
12-0
• µPD75P0016
(SP–2) <– x, x, MBE,RBE
(SP–6)(SP–3)(SP–4) <– PC
11-0
11-0
(SP–5) <– 0, 0, PC , PC
13
12
PC
<– addr, SP <– SP–6
13-0
Note
CALLF
!faddr
2
2
• µPD750004
(SP–3) <– MBE,RBE, 0, 0
(SP–4)(SP–1)(SP–2) <– PC
9
*
PC
<– 0+faddr, SP <– SP–4
11-0
• µPD750006, µPD750008
(SP–3) <– MBE,RBE, 0, PC
(SP–4)(SP–1)(SP–2) <– PC
12
11-0
PC
<– 00+faddr, SP <– SP–4
12-0
• µPD75P0016
(SP–3) <– MBE,RBE, PC , PC
13
12
11-0
(SP–4)(SP–1)(SP–2) <– PC
PC <– 000+faddr, SP <– SP–4
13-0
Note The shaded portion is supported in Mk II mode only. The other portions are supported in Mk I mode
only.
252
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CHAPTER 11 INSTRUCTION SET
In
struc-
tion
Number
of
bytes
Address-
ing
area
Mne-
monic
Machine
cycle
Operand
!faddr
Operation
Skip condition
Note
CALLF
2
3
• µPD750004
9
*
(SP–2) –> x, x, MBE,RBE
(SP–6)(SP–3)(SP–4) <– PC
(SP–5) <– 0, 0, 0, 0
11-0
PC
<– 0+faddr, SP <– SP–6
11-0
• µPD750006, µPD750008
(SP–2) –> x, x, MBE,RBE
(SP–6)(SP–3)(SP–4) <– PC
11-0
(SP–5) <– 0, 0, 0, PC
12
PC
<– 00+faddr, SP <– SP–6
12-0
• µPD75P0016
(SP–2) <– x, x, MBE,RBE
(SP–6)(SP–3)(SP–4) <– PC
11-0
(SP–5) <– 0, 0, PC , PC
13
12
PC
<– 000+faddr, SP <– SP–6
13-0
Note
RET
1
3
• µPD750004
PC <– (SP)(SP+3)(SP+2)
11-0
MBE,RBE, 0, 0 <– (SP+1), SP <– SP+4
• µPD750006, µPD750008
PC
<– (SP)(SP+3)(SP+2)
11-0
MBE,RBE, 0, PC <– (SP+1)
12
SP <– SP+4
• µPD75P0016
PC
<– (SP)(SP+3)(SP+2)
11-0
MBE,RBE, PC , PC <– (SP+1)
13
12
SP <– SP+4
3
• µPD750004
x, x, MBE, RBE <– (SP+4)
0, 0, 0, 0 <– (SP+1)
PC
<– (SP)(SP+3)(SP+2)
11-0
SP <– SP+6
• µPD750006, µPD750008
x, x, MBE, RBE <– (SP+4)
MBE,0, 0, PC <– (SP+1)
12
PC
<– (SP)(SP+3)(SP+2)
11-0
SP <– SP+6
• µPD75P0016
x, x, MBE, RBE <– (SP+4)
0,0, PC , PC <– (SP+1)
13
12
PC
<– (SP)(SP+3)(SP+2)
11-0
SP <– SP+6
Note The shaded portion is supported in Mk II mode only. The other portions are supported in Mk I mode
only.
253
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µPD750008 USER'S MANUAL
In
struc-
tion
Number
of
bytes
Address-
ing
area
Mne-
monic
Machine
cycle
Operand
Operation
Skip condition
Unconditionally
Note
RETS
1
3+S
• µPD750004
MBE, RBE, 0, 0 <– (SP+1)
PC <– (SP)(SP+3)(SP+2)
11-0
SP <– SP+4
Then skip unconditionally
• µPD750006, µPD750008
MBE, 0, 0, PC <– (SP+1)
12
PC
<– (SP)(SP+3)(SP+2)
11-0
SP <– SP+4
Then skip unconditionally
• µPD75P0016
MBE, RBE, PC , PC <– (SP+1)
13
12
PC
<– (SP)(SP+3)(SP+2)
11-0
SP <– SP+4
Then skip unconditionally
3+S
• µPD750004
0, 0, 0, 0 <– (SP+1)
PC
<– (SP)(SP+3)(SP+2)
11-0
x, x, MBE, RBE <– (SP+4)
SP <– SP+6
Then skip unconditionally
• µPD750006, µPD750008
0, 0, 0, PC <– (SP+1)
12
PC
<– (SP)(SP+3)(SP+2)
11-0
x, x, MBE, RBE <– (SP+4)
SP <– SP+6
Then skip unconditionally
• µPD75P0016
0, 0, PC , PC <– (SP+1)
13
12
PC
<– (SP)(SP+3)(SP+2)
11-0
x, x, MBE, RBE <– (SP+4)
SP <– SP+6
Then skip unconditionally
Note
RETI
1
3
• µPD750004
Unconditionally
MBE, RBE, 0, 0 <– (SP+1)
PC
<– (SP)(SP+3)(SP+2)
11-0
PSW <– (SP+4)(SP+5), SP <– SP+6
• µPD750006, µPD750008
MBE, RBE, 0, PC <– (SP+1)
12
PC
<– (SP)(SP+3)(SP+2)
11-0
PSW <– (SP+4)(SP+5), SP <– SP+6
• µPD75P0016
MBE, RBE, PC , PC <– (SP+1)
13
12
PC
<– (SP)(SP+3)(SP+2)
11-0
PSW <– (SP+4)(SP+5), SP <– SP+6
Note The shaded portion is supported in Mk II mode only. The other portions are supported in Mk I mode
only.
254
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CHAPTER 11 INSTRUCTION SET
In
struc-
tion
Number
of
bytes
Address-
ing
area
Mne-
monic
Machine
cycle
Operand
Operation
Skip condition
Note 1
RETI
1
3
• µPD750004
0, 0, 0, 0 <– (SP+1)
PC <– (SP)(SP+3)(SP+2)
11-0
PSW <– (SP+4)(SP+5), SP <– SP+6
• µPD750006, µPD750008
0, 0, 0, PC <– (SP+1)
12
PC
<– (SP)(SP+3)(SP+2)
11-0
PSW <– (SP+4)(SP+5), SP <– SP+6
• µPD75P0016
0, 0, PC , PC <– (SP+1)
13
12
PC
<– (SP)(SP+3)(SP+2)
11-0
PSW <– (SP+4)(SP+5), SP <– SP+6
PUSH
POP
rp
1
2
1
2
(SP–1)(SP–2) <– rp, SP <– SP–2
BS
(SP–1) <– MBS, (SP–2) <– RBS,
SP <– SP–2
rp
1
2
1
2
rp <– (SP+1)(SP), SP <– SP+2
BS
MBS <– (SP+1), RBS <– (SP),
SP <– SP+2
EI
DI
2
2
2
2
2
2
2
2
2
2
1
2
2
2
2
2
2
2
2
2
2
1
IME(IPS.3) <– 1
IExxx <– 1
IExxx
IExxx
IME(IPS.3) <– 0
IExxx <– 0
Note 2
IN
A,PORT
A <– PORT (n=0 – 8)
n
n
XA,PORT
XA <– PORT , PORT (n=4, 6)
n+1
n
n
OUTNote 2
PORT ,A
PORT <- A (n=2 - 8)
n
n
PORT ,XA
PORT ,PORT <– XA (n=4, 6)
n+1
n
n
HALT
STOP
NOP
Set HALT Mode (PCC.2 <– 1)
Set STOP Mode (PCC.3 <– 1)
No Operation
Note 1. The shaded portion is supported in Mk II mode only. The other portions are
supported in Mk I mode only.
2. MBE = 0, or MBE = 1 and MBS = 15 must be set when an IN/OUT instruction is
executed.
255
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µPD750008 USER'S MANUAL
In
struc-
tion
Number
of
bytes
Address-
ing
area
Mne-
monic
Machine
cycle
Operand
Operation
Skip condition
SEL
RBn
2
2
1
2
2
3
RBS <– n (n=0 - 3)
MBn
MBS <– n (n=0, 1, 15)
Note
GETI
taddr
• µPD750004
10
*
When the TBR instruction is used
PC
<– (taddr) +(taddr+1)
11-0
3-0
When the TCALL instruction is used
(SP–4)(SP–1)(SP–2) <– PC
(SP–3) <– MBE, RBE, 0, 0
11-0
PC
<– (taddr) +(taddr+1)
11-0
3-0
SP <– SP–4
When an instruction other than
the TBR or TCALL instruction is
used
Depends on the
referenced
instruction
Execution of (taddr)(taddr+1)
instruction
• µPD750006, µPD750008
When the TBR instruction is used
PC
<– (taddr) +(taddr+1)
12-0
4-0
When the TCALL instruction is used
(SP–4)(SP–1)(SP–2) <- PC
11-0
(SP–3) <– MBE, RBE, 0, PC
12
PC
<– (taddr) +(taddr+1)
12-0
4-0
SP <– SP–4
When an instruction other than
the TBR or TCALL instruction is
used
Depends on the
referenced
instruction
Execution of (taddr)(taddr+1)
instruction
• µPD75P0016
When the TBR instruction is used
PC
<– (taddr) +(taddr+1)
13-0
5-0
When the TCALL instruction is used
(SP–4)(SP–1)(SP–2) <- PC
11-0
(SP–3) <– MBE, RBE, PC , PC
13
12
PC
<– (taddr) +(taddr+1)
13-0
5-0
SP <– SP–4
When an instruction other than
the TBR or TCALL instruction is
used
Depends on the
referenced
instruction
Execution of (taddr)(taddr+1)
instruction
Note The TBR and TCALL instructions are assembler pseudo instructions to define tables used for GETI
instructions.
256
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CHAPTER 11 INSTRUCTION SET
In
struc-
tion
Number
of
bytes
Address-
ing
area
Mne-
monic
Machine
cycle
Operand
Operation
Skip condition
Notes1, 2
GETI
taddr
1
3
• µPD750004
When the TBR instruction is used
PC <– (taddr) +(taddr+1)
10
*
11-0
3-0
4
When the TCALL instruction is used
(SP–6)(SP–3)(SP–4) <– PC
(SP–5) <– 0, 0, 0, 0
11-0
(SP–2) <– x, x, MBE, RBE
PC
<– (taddr) +(taddr+1)
11-0
3-0
SP <– SP–6
3
When an instruction other than
the TBR or TCALL instruction is
used
Depends on the
referenced
instruction
Execution of (taddr)(taddr+1)
instruction
3
4
• µPD750006, µPD750008
When the TBR instruction is used
PC
<– (taddr) +(taddr+1)
12-0
4-0
When the TCALL instruction is used
(SP–6)(SP–3)(SP–4) <– PC
11-0
(SP–5) <– 0, 0, 0, PC
12
(SP–2) <– x, x, MBE, RBE
PC <– (taddr) +(taddr+1)
12-0
4-0
SP <– SP–6
3
When an instruction other than
the TBR or TCALL instruction is
used
Depends on the
referenced
instruction
Execution of (taddr)(taddr+1)
instruction
3
4
• µPD75P0016
When the TBR instruction is used
PC
<– (taddr) +(taddr+1)
13-0
5-0
When the TCALL instruction is used
(SP–6)(SP–3)(SP–4) <– PC
11-0
(SP–5) <– 0, 0, PC , PC
13
12
(SP–2) <– x, x, MBE, RBE
PC <– (taddr) +(taddr+1)
13-0
5-0
SP <– SP–6
3
When an instruction other than
the TBR or TCALL instruction is
used
Depends on the
referenced
instruction
Execution of (taddr)(taddr+1)
instruction
Notes 1. The shaded portion is supported in Mk II mode only. The other portions are
supported in Mk I mode only.
2. The TBR and TCALL instructions are assembler pseudo instructions to define tables used for
GETI instructions.
257
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µPD750008 USER'S MANUAL
11.3 INSTRUCTION CODES OF EACH INSTRUCTION
(1) Explanations of the symbols for the instruction codes
R2 R1 R0 reg
P2 P1 P0
reg-pair
XA
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0
1
0
1
0
1
0
1
A
X
L
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0
1
0
1
0
1
0
1
XA'
HL
H
E
D
C
B
HL'
reg
rp'
DE
reg1
rp'1
DE'
BC
BC'
Q2 Q1 Q0 addressing
P2 P1
reg-pair
0
0
0
1
1
0
1
1
0
0
1
0
1
0
1
@HL
@HL+
@HL–
@DE
@DL
0
0
1
1
0
1
0
1
XA
HL
DE
BC
rp
rp1
@rpa
@rpa1
rp2
N5 N2 N1 N0
IExxx
0
0
0
0
0
0
1
1
1
0
0
1
1
1
1
0
1
1
0
1
0
0
1
1
0
0
1
0
0
0
1
0
1
0
0
0
IEBT
IEW
IET0
IECSI
IE0
IE2
IE4
IET1
IE1
I
: Immediate data for n4 or n8
n
D : Immediate data for mem
n
B : Immediate data for bit
n
N : Immediate data for n or IExxx
n
T : Immediate data for taddr x 1/2
n
A : Immediate data for the address (2 to 16) relative to branch destination address minus one
n
S : Immediate data for the one’s complement of the address (15 to 1) relative to the branch destination
n
address
258
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CHAPTER 11 INSTRUCTION SET
(2) Bit manipulation addressing instruction codes
in the operand field indicates that there are three types of bit manipulation addressing, fmem.bit,
1
*
pmem.@L, and @H+mem.bit.
The table below lists the second byte
2
of an instruction code corresponding to the above addressing.
*
1
Second byte of instruction code
Accessible bits
FB0H-FBFH manipulatable bits
*
fmem.bit
1
1
0
0
0
1
1
0
B
B
0
B
B
0
F
F
F
F
F
F
F
F
1
1
0
0
3
3
2
2
1
1
0
0
FF0H-FFFH manipulatable bits
pmem.@L
G
G
G
D
G
FC0H-FFFH manipulatable bits
3
3
2
2
1
1
0
0
@H+mem.bit
B
B
D
D
D
Manipulatable bits of accessible memory bank
1
0
B : Immediate data for bit
n
F : Immediate data for fmem (Low-order four bits of address)
n
G : Immediate data for pmem (Bits 2 to 5 of address)
n
D : Immediate data for mem (Low-order four bits of address)
n
259
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µPD750008 USER'S MANUAL
Instruction code
Mne-
monic
Instruction
Transfer
Operand
B
B
B
3
1
2
MOV
A,#n4
0
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
0
0
1
0
1
0
0
0
0
0
0
0
0
0
1
0
0
0
1
0
1
1
1
1
0
0
1
0
0
1
1
1
1
1
1
0
0
0
1
0
1
1
1
1
1
0
1
0
0
0
0
1
0
1
1
0
0
0
0
0
0
0
1
1
1
0
1
0
0
0
1
1
1
0
1
1
1
1
1
1
I
I
I
I
0
3
2
1
reg1,#n4
rp,#n8
1
0
1
0
1
I
I
I
I
I
I
I
I
1
R R R
3
7
2
6
1
5
0
2
1
0
1
0
1
1
1
0
0
0
0
1
1
1
1
1
1
0
0
1
1
0
0
0
0
1
1
P
P
I
I
I
I
0
2
1
4
3
2
1
A,@rpa1
XA,@HL
@HL,A
Q Q Q
2
1
0
0
0
0
0
0
0
0
0
0
0
0
1
0
1
1
1
1
1
0
1
0
1
0
0
0
1
0
1
0
1
0
1
0
0
0
0
0
0
0
1
1
1
0
0
0
0
0
0
0
@HL,XA
A,mem
D D D D D D D D
7
6
5
4
3
2
1
0
0
XA,mem
mem,A
D D D D D D D 0
7
6
5
4
3
2
1
D D D D D D D D
7
6
5
4
3
2
1
mem,XA
A,reg
D D D D D D D 0
7
6
5
4
3
2
1
0
0
0
0
1
1
1
1
1
0
1
0
1
1
1
1
1
1
0
0
R R R
2
2
1
1
0
0
0
0
XA,rp’
P
P
P
reg1,A
R R R
2
2
1
1
rp’1,XA
P
0
P
0
P
1
XCH
A,@rpa1
XA,@HL
A,mem
Q Q Q
0
2
1
0
0
0
1
1
1
0
1
0
0
0
0
1
0
D D D D D D D D
7
6
5
4
3
2
1
0
0
XA,mem
A,reg1
D D D D D D D 0
7
6
5
4
3
2
1
R R R
0
2
1
XA,rp’
0
1
0
0
1
1
0
1
0
0
0
0
0
1
0
0
0
1
1
1
1
0
1
0
0
0
P
P
P
2
1
MOVT
MOV1
XA,@PCDE
XA,@PCXA
XA,@BCXA
XA,@BCDE
Table
reference
CY,
1
2
*
*
Bit
transfer
1
,CY
2
*
*
260
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CHAPTER 11 INSTRUCTION SET
Instruction code
Mne-
monic
Instruction
Operand
B
B
B
3
1
2
Arithmetic/ ADDS
logical
A,#n4
0
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
0
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
1
0
1
1
1
1
1
1
1
1
1
1
1
0
0
1
1
0
1
1
1
0
1
1
1
0
0
0
1
1
0
0
0
0
0
0
0
0
1
0
0
1
1
0
0
1
0
0
0
1
1
0
0
1
1
I
I
I
I
0
3
2
1
XA,#n8
A,@HL
XA,rp’
rp’1,XA
A,@HL
XA,rp’
rp’1,XA
A,@HL
XA,rp’
rp’1,XA
A,@HL
XA,rp’
rp’1,XA
A,#n4
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
1
1
0
1
1
0
1
1
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
0
0
0
1
0
0
0
0
0
0
0
0
1
0
0
0
1
0
0
0
1
0
0
0
0
1
I
I
I
I
I
I
I
I
0
7
6
5
4
3
2
1
0
1
1
1
1
1
1
1
1
1
1
1
1
0
1
1
1
0
1
1
1
0
1
1
1
1
1
1
1
1
0
0
0
0
1
P
P
P
P
P
P
2
2
1
1
0
0
0
ADDC
SUBS
SUBC
AND
1
1
1
1
0
0
1
1
1
0
P
P
P
P
P
P
2
2
1
1
0
0
1
1
1
1
1
1
0
0
1
0
P
P
P
P
P
P
2
2
1
1
0
0
1
1
0
1
1
0
1
1
1
1
1
1
1
0
P
P
P
P
P
P
2
2
1
1
0
0
I
I
I
I
0
3
2
1
A,@HL
XA,rp’
rp’1,XA
A,#n4
1
1
0
0
0
1
0
0
0
1
1
0
1
0
P
P
P
P
P
P
2
2
1
1
0
0
OR
I
I
I
I
0
3
2
1
A,@HL
XA,rp’
rp’1,XA
A,#n4
1
1
0
0
0
1
1
1
0
0
0
1
1
0
P
P
P
P
P
P
2
2
1
1
0
0
XOR
I
I
I
I
0
3
2
1
A,@HL
XA,rp’
rp’1,XA
A
1
1
0
0
1
1
1
1
1
0
P
P
P
P
P
P
2
2
1
1
0
0
Accumulator RORC
manipulation
NOT
A
0
1
0
1
1
1
1
1
261
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µPD750008 USER'S MANUAL
Instruction code
Mne-
monic
Instruction
Operand
B
B
B
3
1
2
Increment/ INCS
reg
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
0
0
0
1
0
0
0
0
0
0
0
1
1
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
0
0
0
1
0
1
1
1
0
0
B
0
B
0
B
1
B
1
0
1
1
1
0
0
1
0
0
0
1
1
0
0
1
0
0
0
1
1
B
1
B
1
B
1
B
1
1
0
0
1
0
R R R
2
1
0
decrement
rp1
1
1
0
1
1
1
1
0
1
1
1
0
0
0
0
0
1
0
1
0
1
0
1
1
1
1
1
P
0
0
P
0
1
0
1
0
2
1
@HL
mem
reg
0
0
0
0
0
0
1
0
D D D D D D D D
7
6
5
4
3
2
1
0
DECS
R R R
0
2
1
rp’
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
0
0
1
0
1
1
1
1
1
0
0
0
0
1
1
1
1
1
0
1
0
0
0
1
0
0
1
0
1
0
1
0
1
1
0
0
1
1
0
0
1
0
0
0
0
1
1
0
1
0
P
P
P
2
1
0
0
Comparison SKE
reg,#n4
@HL,#n4
A,@HL
XA,@HL
A,reg
XA,rp’
CY
I
I
I
I
R R R
3
2
1
0
2
1
0
1
1
0
I
I
I
I
0
3
2
1
0
0
0
0
0
1
0
0
0
1
0
0
1
1
1
0
0
1
R R R
2
1
0
P
P
P
2
1
0
Carry flag SET1
manipu-
CLR1
CY
lation
SKT
CY
NOT1
CY
Memory
bit
SET1
CLR1
SKT
mem.bit
D D D D D D D D
1
1
1
1
0
0
0
0
7
6
5
4
3
2
1
0
0
0
0
1
2
*
*
manipu-
lation
mem.bit
D D D D D D D D
7
6
5
4
3
2
1
1
2
*
*
mem.bit
D D D D D D D D
7
6
5
4
3
2
1
1
2
*
*
SKF
mem.bit
D D D D D D D D
7
6
5
4
3
2
1
1
2
2
2
2
2
*
*
SKTCLR
AND1
OR1
1
*
*
*
*
*
CY,
CY,
CY,
1
1
1
*
*
*
XOR1
262
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CHAPTER 11 INSTRUCTION SET
Instruction code
Mne-
monic
Instruction
Branch
Operand
B
B
B
3
1
2
BR
!addr
1
0
0
0
1
0
0
0
1
0
1
1
0
0
addr
$addr1
(+16) to (+2)
A
A
A
A
3
3
2
2
1
1
0
0
(–1) to (–15)
PCDE
1
1
1
0
1
1
0
1
1
0
1
1
1
0
1
0
1
1
1
1
1
1
1
1
1
1
1
0
1
1
0
1
0
0
0
0
0
1
0
0
1
1
1
1
1
0
1
0
0
0
0
0
0
0
0
0
0
0
1
0
0
0
1
0
0
0
0
1
0
1
1
0
1
1
1
0
0
0
0
1
1
0
0
0
0
0
0
0
0
1
0
0
T
1
1
1
0
1
1
1
0
1
0
0
0
0
0
1
0
1
0
0
1
1
1
1
1
1
1
1
0
1
1
T
S
1
1
0
1
1
S
0
0
1
0
0
S
0
0
0
0
1
S
1
1
1
1
0
0
0
0
0
0
0
0
0
0
1
0
0
0
0
0
PCXA
0
BCDE
BCXA
0
0
0
0
0
0
0
0
1
BRA
!addr1
!caddr
!addr
addr1
BRCB
CALL
caddr
1
Sub-
1
1
0
1
0
1
1
1
1
1
0
0
0
0
1
1
1
1
1
1
0
1
1
T
0
0
1
1
1
1
0
0
addr
routine
stack
CALLA !addr1
CALLF !faddr
RET
addr1
faddr
control
1
0
1
P
0
P
0
0
0
0
0
1
1
1
1
1
1
0
0
0
1
0
1
P
0
P
0
1
1
1
1
0
0
0
0
0
0
0
0
0
T
0
0
1
1
1
0
1
1
0
1
0
1
1
0
0
1
1
0
1
1
RETS
RETI
PUSH
POP
IN
rp
2
2
1
1
BS
0
0
0
0
0
1
1
1
1
1
0
rp
BS
0
1
1
1
1
1
1
1
1
1
1
0
1
1
1
1
0
0
0
0
0
0
0
1
1
1
1
1
0
1
1
1
1
1
0
I/O
A,PORTn
XA,PORTn
PORTn,A
PORTn,XA
N
N
N
N
0
N N N
3
3
3
3
2
1
0
0
0
0
N N N
2
1
OUT
EI
N N N
2
1
N N N
2
1
Interrupt
control
0
1
0
IExxx
IExxx
N 1
1
N N N
5
2
1
0
0
DI
1
1
0
0
1
0
N 1
1
N N N
5
2
1
CPU
HALT
STOP
NOP
1
1
0
1
0
0
0
1
1
1
1
control
0
Special
SEL
RBn
MBn
taddr
0
0
0
0
1
0
0
1
0
0
N N
1
0
0
N
N N N
3
2
1
GETI
T
T
5
4
3
2
1
0
263
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µPD750008 USER'S MANUAL
11.4 FUNCTIONS AND APPLICATIONS OF THE INSTRUCTIONS
This section explains functions and applications of the instructions. For the µPD750004, µPD750006,
µPD750008, and µPD75P0016, usable instructions and their functions in Mk I mode are different from those
in Mk II mode. Read the following explanation.
How to read
Can be used in both Mk I mode and Mk II mode for the µPD750004, µPD750006, µPD750008, and
µPD75P0016
I
Can be used in only Mk I mode for the µPD750004, µPD750006, µPD750008, and µPD75P0016
Can be used in only Mk II mode for the µPD750004, µPD750006, µPD750008, and µPD75P0016
II
I/II
Can be used in both Mk I mode and Mk II mode for the µPD750004, µPD750006, µPD750008, and
µPD75P0016. However, Mk I mode is different from Mk II mode in the functions. Read the
explanation of [Mk I mode] for Mk I mode and the explanation of [Mk II mode] for Mk II mode, as
required.
Remark "Function" in this section is applicable to the µPD750006 and µPD750008 whose program
counters consist of 13 bits each. This is also applicable to the µPD750004 whose program
counter consists of 12 bits and the µPD75P0016 whose program counter consists of 14 bits,
however.
11.4.1 Transfer Instructions
MOV A,#n4
Function: A <– n4 n4 = I : 0-FH
3-0
Transfers the 4-bit immediate data n4 to the A register (4-bit accumulator).
The string effect (group A) can be utilized. When MOV A, #n4 and/or MOV XA, #n8 instructions are located
contiguously, the string instructions following an executed instruction are processed as NOP instructions.
Examples 1. The data 0BH is set in the accumulator.
MOV A,#0BH
2. Data to be output to port 3 is selected from 0 to 2.
A0: MOV A,#0
A1: MOV A,#1
A2: MOV A,#2
OUT PORT3,A
264
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CHAPTER 11 INSTRUCTION SET
MOV reg1,#n4
Function: reg1 <– n4
n4 = I : 0-FH
3-0
Transfers the 4-bit immediate data n4 to A register reg1 (X, H, L, D, E, B, C).
MOV XA,#n8
*
*
*
Function: XA <– n8
n8 = I : 00H-FFH
7-0
Transfers the 8-bit immediate data n8 to register pair XA. The string effect can be utilized. When two
or more of this instruction are executed in succession or when MOV A,#n4 instruction is located
continguously, the string instructions following an executed instruction are processed as NOP instructions.
MOV HL,#n8
Function: HL <– n8
n8 = I : 00H-FFH
7-0
Transfers the 8-bit immediate data n8 to register pair HL. The string effect can be utilized. When two or
more of this instruction are executed in succession, the string instructions following an executed instruction
are processed as NOP instructions.
MOV rp2,#n8
Function: rp2 <– n8
n8 = I : 00H-FFH
7-0
Transfers the 8-bit immediate data n8 to register pair rp2 (BC, DE).
MOV A,@HL
MOV A,@HL+
MOV A,@HL–
MOV A,@rpa1
*
*
*
*
Function: A <– (Register pair specified by the operand)
When HL+ is specified for the register pair: Skip if L = 0
When HL– is specified for the register pair: Skip if L = FH
Transfers the data at the data memory location addressed by the specified register pair (HL, HL+, HL–,
DE, DL) to the A register.
When HL+ (automatic increment) is specified for the register pair, automatically increments the contents
of the L register by one after the data transfer, and continues the operation until the contents are set to 0.
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Then skips the immediately following instruction.
When HL– (automatic decrement) is specified for the register pair, automatically decrements the contents
of the L register by one after the data transfer, and continues the operation until the contents are set to FH.
Then skips the immediately following instruction.
MOV XA,@HL
Function: A <– (HL), X <– (HL+1)
Transfers the data at the data memory location addressed by the HL register pair to the A register, and
transfers the data at the next data memory address to the X register.
However, if the contents of the L register are odd- numbered, an address with the low-order bit ignored
is specified.
Example The data at addresses 3EH and 3FH are transferred to the XA register pair.
MOV HL, #3EH
MOV XA, @HL
MOV @HL,A
Function: (HL) <– A
Transfers the contents of the A register to the data memory location addressed by the HL register pair.
MOV @HL,XA
Function: (HL) <– A, (HL+1) <– X
Transfers the contents of the A register to the data memory location addressed by the HL register pair, and
transfers the contents of the X register to the next memory address.
However, if the contents of the L register are odd- numbered, an address with the low-order bit ignored
is specified
MOV A,mem
Function: A <– (mem)
mem = D : 00H-FFH
7-0
Transfers the data at the data memory location addressed by the 8-bit immediate data mem to the A register.
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CHAPTER 11 INSTRUCTION SET
MOV XA,mem
Function: A <– (mem), X <– (mem+1)
mem = D : 00H-FEH
7-0
Transfers the data at the data memory location addressed by the 8-bit immediate data mem to the A register,
and transfers the data at the next address to the X register.
An even address can be specified with mem.
Example The data at addresses 40H and 41H are transferred to the XA register pair.
MOV XA,40H
MOV mem,A
Function: (mem) <– A
mem = D : 00H-FFH
7-0
Transfers the contents of the A register to the data memory location addressed by the 8-bit immediate data
mem.
MOV mem,XA
Function: (mem) <– A, (mem+1) <– X
mem = D : 00H-FEH
7-0
Transfers the contents of the A register to the data memory location addressed by the 8-bit immediate data
mem, and transfers the contents of the X register to the next memory address.
An even address can be specified with mem.
MOV A,reg
Function: A <– reg
Transfers the contents of register reg (X, A, H, L, D, E, B, C) to the A register.
MOV XA,rp’
Function: XA <– rp’
Transfers the contents of register pair rp’ (XA, HL, DE, BC, XA’, HL’, DE’, BC’) to the XA register pair.
Example The contents of the XA’ register pair are transferred to the XA register pair.
MOV XA, XA’
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MOV reg1,A
Function: reg1 <– A
Transfers the contents of the A register to register reg1 (X, H, L, D, E, B, C).
MOV rp’1,XA
Function: rp’1 <– XA
Transfers the contents of the XA register pair to register pair rp’1 (HL, DE, BC, XA’, HL’, DE’, BC’).
XCH A,@HL
XCH A,@HL+
XCH A,@HL–
XCH A,@rpa1
*
*
*
*
Function: A <–> (Register pair specified by the operand)
When HL+ is specified for the register pair: Skip if L = 0
When HL– is specified for the register pair: Skip if L = FH
Exchanges the contents of the A register with the data at the data memory location addressed by the
specified register pair (HL, HL+, HL– , DE, DL).
When HL+ (automatic increment) is specified for the register pair, automatically increments the contents
of the L register by one after the data exchange, and continues the operation until the contents are set to 0.
Then skips the immediately following instruction.
When HL– (automatic decrement) is specified for the register pair, automatically decrements the contents
of the L register by one after the data exchange, and continues the operation until the contents are set to FH.
Then skips the immediately following instruction.
Example The data at addresses 20H-2FH are exchanged with the data at addresses 30H-3FH.
SEL
MOV
MOV
XCH
XCH
XCH
BR
MB0
D,#2
HL,#30H
A,@HL
A,@DL
A,@HL+
LOOP
LOOP:
; A <–> (3x)
; A <–> (2x)
; A <–> (3x)
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CHAPTER 11 INSTRUCTION SET
XCH XA,@HL
Function: A <–> (HL), X <–> (HL+1)
Exchanges the contents of the A register with the data at the data memory location addressed by the HL
register pair, and exchanges the contents of the X register with the data at the next memory address.
However, if the contents of the L register are odd- numbered, an address with the low-order bit ignored
is specified.
XCH A,mem
Function: A <–> (mem)
mem = D : 00H-FEH
7-0
Exchanges the contents of the A register with the data at the data memory location addressed by the 8-
bit immediate data mem.
XCH XA,mem
Function: A <–> (mem), X <–> (mem+1)
mem = D : 00H-FEH
7-0
Exchanges the contents of the A register with the data at the data memory location addressed by the 8-
bit immediate data mem, and exchanges the contents of the X register 1 with the data at the next memory
address.
An even address can be specified with mem.
XCH A,reg1
Function: A <–> reg1
Exchanges the contents of the A register with register reg1 (X, H, L, D, E, B, C).
XCH XA,rp’
Function: XA <–> rp’
Exchanges the contents of the XA register pair with the contents of register pair rp’ (XA, HL, DE, BC, XA’,
HL’, DE’, BC’).
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11.4.2 Table Reference Instructions
MOVT XA,@PCDE
Function: For the µPD750006 and µPD750008
XA <– ROM (PC
+DE)
12-8
Transfers the low-order four bits of the table data in program memory to the A register, and the high-order
four bits to the X register. The table data is addressed by the program counter (PC) with its low-order eight
bits (PC ) exchanged with the contents of the DE register pair.
7-0
The table address is determined by the contents of the program counter (PC) present when this instruction
is executed.
The table area must have necessary data loaded by an assembler pseudo instruction (DB instruction).
The program counter is not affected by the execution of the pseudo instruction.
This instruction is useful for consecutive table data references.
Example For the µPD750006 and µPD750008
Program memory
12
8 7
4 3
0
7
4 3
0
Table
address
Table
data H
Table
data L
PC12-8
D3-0
E3-0
3
0 3
0
X
A
Remark "Function" in this section is applicable to the µPD750006 and µPD750008 whose program
counters consist of 13 bits each. This is also applicable to the µPD750004 whose program
counter consists of 12 bits and the µPD75P0016 whose program counter consists of 14 bits,
however.
Caution The MOVT XA,@PCDE instruction usually references table data in the page containing that
instruction. However, when the instruction is located at address xxFFH, table data in the
next page is referenced instead of table data in the page containing that instruction.
Program memory
7
0
Page 2
02FFH
0300H
a
Page 3
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CHAPTER 11 INSTRUCTION SET
For example, if MOVT XA,@PCDE is located at a as shown above, the table data in page 3 specified by
the contents of the DE register pair is transferred to the XA register pair instead of that in page 2.
Example The 16-byte data at addresses xxF0H-xxFFH in program memory is transferred to addresses
30H-4FH in data memory.
SUB:
SEL
MB0
MOV
MOV
HL,#30H
DE,#0F0H
; HL <– 30H
; DE <– F0H
LOOP:
MOVT XA,@PCDE
; XA <– table data
; (HL) <– XA
MOV
INCS
INCS
INCS
BR
@HL, XA
HL
; HL <– HL + 2
HL
E
; E <– E + 1
LOOP
RET
ORG
DB
xxF0H
xxH, xxH, ....... ; Table data
MOVT XA, @PCXA
Function: For the µPD750006 and µPD750008
XA <– ROM (PC +XA)
12-8
Transfers the low-order four bits of the table data in program memory to the A register, and the high-order
four bits to the X register. The table data is addressed by the program counter (PC) with its low-order eight
bits (PC ) exchanged with the contents of the XA register pair.
7-0
The table address is determined by the contents of the program counter present when this instruction is
executed.
The table area must have necessary data loaded by an assembler pseudo instruction (DB instruction).
The program counter is not affected by the execution of this instruction.
Caution As with MOVT XA,@PCDE, when the instruction is located at address xxFFH, table data
in the next page is transferred.
Remark "Function" in this section is applicable to the µPD750006 and µPD750008 whose program
counters consist of 13 bits each. This is also applicable to the µPD750004 whose program
counter consists of 12 bits and the µPD75P0016 whose program counter consists of 14 bits,
however.
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MOVT XA,@BCXA
Function: For the µPD750006 and µPD750008
XA <– (BCXA)
ROM
Transfers the low-order four bits of the table data (eight bits) in program memory to the A register, and the
high-order four bits to the X register. The table data is addressed by the low-order one bit of the B register
and the contents of the C, X, and A registers.
The table area must have necessary data loaded by an assembler pseudo instruction (DB instruction). The
program counter is not affected by the execution of this instruction.
12
11
8 7
4 3
0
B0
C
X
A
Table data H
Table data L
3
0
3
0
X
A
MOVT XA,@BCDE
Function: For the µPD750006 and µPD750008
XA <– (BCDE)
ROM
Transfers the low-order four bits of the table data (eight bits) in program memory to the A register, and the
high-order four bits to the X register. The table data is addressed by the low-order three bits of the B register
and the contents of the C, D, and E registers.
The table area must have necessary data loaded by an assembler pseudo instruction (DB instruction). The
program counter is not affected by the execution of this instruction.
12
11
8 7
4 3
0
B
0
C
D
E
Table data H
Table data L
3
0
3
0
X
A
Remark "Function" in this section is applicable to the µPD750006 and µPD750008 whose program
counters consist of 13 bits each. This is also applicable to the µPD750004 whose program
counter consists of 12 bits and the µPD75P0016 whose program counter consists of 14 bits,
however.
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CHAPTER 11 INSTRUCTION SET
11.4.3 Bit Transfer Instructions
MOV1 CY,fmem.bit
MOV1 CY,pmem.@l
MOV1 CY,@H+mem.bit
Function: CY <– (bit specified in operand)
Transfersthedatamemorybitspecifiedbybitmanipulationaddressing(fmem.bit, pmem.@L, @H+mem.bit)
to the carry flag (CY).
MOV1 fmem.bit,CY
MOV1 pmem.@L,CY
MOV1 @H+mem.bit,CY
Function: (bit specified in operand) <– CY
Transfers the carry flag (CY) bit to the data memory bit specified by bit manipulation addressing (fmem.bit,
pmem.@L,@H+mem.bit)
Example The flag (bit 3 at address 3FH) in data memory is set in bit 2 of port 3.
FLAG EQU 3FH.3
SEL
MB0
MOV H,#FLAG SHR6 ; H <– high-order 4 bits of FLAG
MOV1 CY,@H+FLAG
MOV1 PORT3.2,CY
; CY <– FLAG
; P32 <– CY
11.4.4 Arithmetic/Logical Instructions
ADDS A,#n4
Function: A <– A+n4 ; Skip if carry.
n4 = I : 0-FH
3-0
Adds the 4-bit immediate data n4 to the contents of the A register in binary, then skips the next instruction
if the addition generates a carry. The carry flag is not affected.
This instruction, when combined with the ADDC A,@HL or SUBC A,@HL instruction, functions as a number
system conversion instruction. (See Section 11.1.)
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ADDS XA,#n8
Function: XA <– XA+n8 ; Skip if carry.
n8 = I : 00H-FFH
7-0
Adds the 8-bit immediate data n8 to the contents of the XA register pair in binary, then skips the next
instruction if the addition generates a carry. The carry flag is not affected.
ADDS A,@HL
Function: A <– A+(HL) ; Skip if carry.
Adds the data at the data memory location addressed by the HL register pair to the contents of the A register
in binary, then skips the next instruction if the addition generates a carry. The carry flag is not affected.
ADDS XA,rp’
Function: XA <– XA+rp’ ; Skip if carry.
Adds the contents of register pair rp’ (XA, HL, DE, BC, XA’, HL’, DE’, BC’) to the contents of the XA register
pair in binary, then skips the next instruction if the addition generates a carry. The carry flag is not affected.
ADDS rp’1,XA
Function: rp’ <– rp’1+XA ; Skip if carry.
Adds the contents of the XA register pair to the contents of register pair rp’1 (HL, DE, BC, XA’, HL’, DE’,
BC’) in binary, then skips the next instruction if the addition generates a carry. The carry flag is not affected.
Example The register pair is left-shifted.
MOV XA, rp’1
ADDS rp’1, XA
NOP
ADDC A,@HL
Function: A,CY <– A+(HL)+CY
Adds the data at the data memory location addressed by the HL register pair together with the carry flag
to the contents of the A register in binary. If the addition generates a carry, the carry flag is set. If no carry
is generated, the carry flag is reset.
If the execution of this instruction generates a carry when this instruction is immediately followed by the
ADDS A,#n4 instruction, the ADDS A,#n4 instruction is skipped. If no carry is generated, the ADDS A,#n4
instruction is executed, and the skip function of the ADDS A,#n4 instruction is disabled. Accordingly, a
combination of these instructions can be used for number system conversion. (See Section 11.1.)
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ADDC XA,rp’
Function: XA, CY <– XA+rp’+CY
Adds the contents of register pair rp’ (XA, HL, DE, BC, XA’, HL’, DE’, BC’) together with the carry flag to
the contents of the XA register pair in binary. If the addition generates a carry, the carry flag is set. If no carry
is generated, the carry flag is reset.
ADDC rp’1,XA
Function: rp’1, CY <– rp’1+XA+CY
Adds the contents of the XA register pair together with the carry flag to the contents of register pair rp’1
(HL, DE, BC, XA’, HL’, DE’, BC’) in binary. If the addition generates a carry, the carry flag is set. If no carry
is generated, the carry flag is reset.
SUBS A,@HL
Function: A <– A–(HL) ; Skip if borrow
Subtracts the data at the data memory location addressed by the HL register pair from the contents of the
A register, then sets the result in the A register. If the subtraction generates a borrow, the immediately following
instruction is skipped.
The carry flag is not affected.
SUBS XA,rp’
Function: XA <– XA–rp’ ; Skip if borrow
Subtracts the contents of register pair rp’ (XA, HL, DE, BC, XA’, HL’, DE’, BC’) from the contents of the
XA register pair, then sets the result in the XA register pair. If the subtraction generates a borrow, the
immediately following instruction is skipped.
The carry flag is not affected.
Example Data memory is compared with register pair rp’.
MOV XA, mem
SUBS XA, rp’
; (mem) • rp’
; (mem) < rp’
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SUBS rp’1,XA
Function: rp’1 <– rp’1+XA ; Skip if borrow
Subtracts the contents of the XA register pair from the contents of register pair rp’1 (HL, DE, BC, XA’, HL’,
DE’, BC’), then sets the result in register pair rp’1. If the subtraction generates a borrow, the immediately
following instruction is skipped.
The carry flag is not affected.
SUBC A,@HL
Function: A, CY <– A–(HL)–CY
Subtracts the data at the data memory location addressed by the HL register pair together with the carry
flag from the contents of the A register, then sets the result in the A register. If the subtraction generates a
borrow, the carry flag is set. If no borrow is generated, the carry flag is reset.
If the execution of this instruction generates no borrow when this instruction is followed by the ADDS A,
#n4 instruction, the ADDS A, #n4 instruction is skipped. If a borrow is generated, the ADDS A, #n4 instruction
is executed, and the skip function of the ADDS A, #n4 instruction is disabled. Accordingly, a combination of
these instructions can be used for number system conversion. (See Section 11.1.)
SUBC XA,rp’
Function: XA, CY <– XA–rp’–CY
Subtracts the contents of register pair rp’ (XA, HL, DE, BC, XA’, HL’, DE’, BC’) together with the carry flag
from the contents of the XA register pair, then sets the result in the XA register pair. If the subtraction generates
a borrow, the carry flag is set. If no borrow is generated, the carry flag is reset.
SUBC rp’1,XA
Function: rp’1, CY <– rp’1–XA–CY
Subtracts the contents of the XA register pair together with the carry flag from the contents of register pair
rp’1 (HL, DE, BC, XA’, HL’, DE’, BC’), then sets the result in register pair rp’1. If the subtraction generates
a borrow, the carry flag is set. If no borrow is generated, the carry flag is reset.
AND A,#n4
Function: A <– A n4
n4 = I : 0-FH
3-0
ANDs the contents of the A register with the 4-bit immediate data n4, then sets the result in the A register.
Example The high-order two bits of an accumulator are set to 0.
AND A,#0011B
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AND A,@HL
Function: A <– A (HL)
ANDs the contents of the A register with the data at the data memory location addressed by the HL register
pair, then sets the result in the A register.
AND XA,rp’
Function: XA <– XA rp’
ANDs the contents of the XA register pair with the contents of register pair rp’ (XA, HL, DE, BC, XA’, HL’,
DE’, BC’), then sets the result in the XA register pair.
AND rp’1,XA
Function: rp’1 <– rp’1 XA
ANDs the contents of register pair rp’1 (HL, DE, BC, XA’, HL’, DE’, BC’) with the contents of the XA register
pair, then sets the result in the specified register pair.
OR A,#n4
Function: A <– A 4
n4 = I : 0-FH
3-0
ORs the contents of the A register with the 4-bit immediate data n4, then sets the result in the A register.
Example The low-order three bits of an accumulator are set to 1.
OR A,#0111B
OR A,@HL
Function: A <– A (HL)
ORs the contents of the A register with the data at the data memory location addressed by the HL register
pair, then sets the result in the A register.
OR XA,rp’
Function: XA <– XA rp’
ORs the contents of the XA register pair with the contents of register pair rp’ (XA, HL, DE, BC, XA’, HL’,
DE’, BC’), then sets the result in the XA register pair.
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OR rp’1,XA
Function: rp’1 <– rp’ XA
ORs the contents of register pair rp’1 (HL, DE, BC, XA’, HL’, DE’, BC’) with the contents of the XA register
pair, then sets the result in register pair rp’1.
XOR A,#n4
Function: A <– A n4
n4 = I : 0-FH
3-0
Exclusive-ORs the contents of the A register with the 4-bit immediate data n4, then sets the result in the
A register.
Example The high-order four bits of an accumulator is inverted.
XOR A,#1000B
XOR A,@HL
Function: A <– A (HL)
Exclusive-ORs the contents of the A register with the data at the data memory location addressed by the
HL register pair, then sets the result in the A register.
XOR XA,rp’
Function: XA <– XA rp’
Exclusive-ORs the contents of the XA register pair with the contents of register pair rp’ (XA, HL, DE, BC,
XA’, HL’, DE’, BC’), then sets the result in the XA register pair.
XOR rp’1,XA
Function: rp’1 <– rp’1 XA
Exclusive-ORs the contents of register pair rp’1 (HL, DE, BC, XA’, HL’, DE’, BC’) with the contents of the
XA register pair, then sets the result in register pair rp’1.
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CHAPTER 11 INSTRUCTION SET
11.4.5 Accumulator Manipulation Instructions
RORC A
Function: CY <- A , A
<- A , A <- CY (n = 1–3)
0
n-1
n
3
Rotates the contents of the A register (4-bit accumulator) through the carry flag one bit position to the right.
A
CY
0
3
0
2
1
1
0
0
1
•
•
•
•
•
•
•
•
Before
execution
RORC A
After
execution
1
0
0
1
0
NOT A
Function: A <– A
Obtains the one’s complement of the A register (4-bit accumulator), that is, inverts each bit of the A register.
11.4.6 Increment/Decrement Instructions
INCS reg
Function: reg <– reg+1 ; Skip if reg = 0
Increments the contents of register reg (X, A, H, L, D, E, B, C). If the result of increment produces reg =
0, the immediately following instruction is skipped.
INCS rp1
Function: rp1 <– rp1+1 ; Skip if rp1 = 00H
Increments the contents of register pair rp1 (HL, DE, BC). If the result of increment produces rp1 = 00H,
the immediately following instruction is skipped.
INCS @HL
Function: (HL) <– (HL)+1 ; Skip if (HL) = 0
Increments the data at the data memory location addressed by the HL register pair. If the result of increment
produces data that is 0, the immediately following instruction is skipped.
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INCS mem
Function: (mem) <– (mem)+1 ; Skip if (mem) = 0, mem = D : 00H-FFH
7-0
Increments the data at the data memory location addressed by the 8-bit immediate data mem. If the result
of increment produces data that is 0, the immediately following instruction is skipped.
DECS reg
Function: reg <– reg–1 ; Skip if reg = FH
Decrements the contents of register reg (X, A, H, L, D, E, B, C). If the result of decrement produces reg
= FH, the immediately following instruction is skipped.
DECS rp’
Function: rp’ <– rp’–1 ; Skip if rp’ = FFH
Decrements the contents of register pair rp’ (XA, HL, DE, BC, XA’, HL’, DE’, BC’). If the result of decrement
produces rp’ = FFH, the immediately following instruction is skipped.
11.4.7 Compare Instructions
SKE reg,#n4
Function: Skip if reg = n4
n4 = I : 0-FH
3-0
Skips the immediately following instruction if the contents of register reg (X, A, H, L, D, E, B, C) match the
4-bit immediate data n4.
SKE @HL,#n4
Function: Skip if (HL) = n4
n4 = I : 0-FH
3-0
Skips the immediately following instruction if the data at the data memory location addressed by the HL
register pair match the 4-bit immediate data n4.
SKE A,@HL
Function: Skip if A = (HL)
Skips the immediately following instruction if the contents of the A register match the data at the data memory
location addressed by the HL register pair.
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CHAPTER 11 INSTRUCTION SET
SKE XA,@HL
Function: Skip if A = (HL) and X = (HL+1)
Skips the immediately following instruction if the contents of the A register match the data at the data memory
location addressed by the HL register pair, and the contents of the X register match the data at the next address
in data memory.
However, if the contents of the L register are odd- numbered, an address with the lowest-order bit ignored
is specified.
SKE A,reg
Function: Skip if A = reg
Skips the immediately following instruction if the contents of the A register match the contents of register
reg (X, A, H, L, D, E, B, C).
SKE XA,rp’
Function: Skip if XA = rp’
Skips the immediately following instruction if the contents of the XA register pair match the contents of
register pair rp’ (XA, HL, DE, BC, XA’, HL’, DE’, BC’).
11.4.8 Carry Flag Manipulation Instructions
SET1 CY
Function: CY <– 1
Sets the carry flag.
CLR1 CY
Function: CY <– 0
Clears the carry flag.
SKT CY
Function: Skip if CY = 1
Skips the immediately following instruction if the carry flag is set to 1.
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NOT1 CY
Function: CY <– CY
Inverts the carry flag. If it is 0, it is set to 1, or vice versa.
11.4.9 Memory Bit Manipulation Instructions
SET1 mem.bit
Function: (mem.bit) <– 1
mem = D : 00H-FFH, bit = B : 0–3
7-0 1-0
Sets the bit specified by the 2-bit immediate data bit at the address specified by the 8-bit immediate data
mem.
SET1 fmem.bit
SET1 pmem.@L
SET1 @H+mem.bit
Function: (Bit specified in operand) <– 1
Sets the bit in data memory specified by bit manipulation addressing (fmem.bit, pmem.@L, @H+mem.bit).
CLR1 mem.bit
Function: (mem.bit) <– 0
mem = D : 00H-FFH, bit = B : 0–3
7-0 1-0
Clears the bit specified by the 2-bit immediate data bit at the address specified by the 8-bit immediate data
mem.
CLR1 fmem.bit
CLR1 pmem.@L
CLR1 @H+mem.bit
Function: (Bit specified in operand) <– 0
Clears the bit in data memory specified by bit manipulation addressing (fmem.bit, pmem.@L, @H+mem.bit).
SKT mem.bit
Function: Skip if (mem.bit) = 1
mem = D : 00H-FFH, bit = B : 0–3
7-0
1-0
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CHAPTER 11 INSTRUCTION SET
Skips the immediately following instruction if the bit specified by the 2-bit immediate data bit at the address
specified by the 8-bit immediate data mem is 1.
SKT fmem.bit
SKT pmem.@L
SKT @H+mem.bit
Function: Skip if (bit specified in operand) = 1
Skips the immediately following instruction if the bit in data memory specified by bit manipulation addressing
(fmem.bit, pmem.@L, @H+mem.bit) is set to 1.
SKF mem.bit
Function: Skip if (mem.bit) = 0
mem = D : 00H-FFH, bit = B : 0–3
7-0
1-0
Skips the immediately following instruction if the bit specified by the 2-bit immediate data bit at the address
specified by the 8-bit immediate data mem is 0.
SKF fmem.bit
SKF pmem.@L
SKF @H+mem.bit
Function: Skip if (bit specified in operand) = 0
Skips the immediately following instruction if the bit in data memory specified by bit manipulation addressing
(fmem.bit, pmem.@L, @H+mem.bit) is 0.
SKTCLR fmem.bit
SKTCLR pmem.@L
SKTCLR @H+mem.bit
Function: Skip if (bit specified in operand) = 1 then clear
Skips the immediately following instruction if the bit in data memory specified by bit manipulation addressing
(fmem.bit, pmem.@L, @H+mem.bit) is 1, then clears the bit to 0.
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AND1 CY, fmem.bit
AND1 CY, pmem.@L
AND1 CY, @H+mem.bit
Function: CY <– CY (bit specified in operand)
^
ANDs the content of the carry flag with the bit in data memory specified by bit manipulation addressing
(fmem.bit, pmem.@L, @H+mem.bit), then sets the result in the carry flag.
OR1 CY, fmem.bit
OR1 CY, pmem.@L
OR1 CY, @H+mem.bit
Function: CY <– CY¦ (bit specified in operand)
ORs the content of the carry flag with the bit in data memory specified by bit manipulation addressing
(fmem.bit, pmem.@L, @H+mem.bit), then sets the result in the carry flag.
XOR1 CY, fmem.bit
XOR1 CY, pmem.@L
XOR1 CY, @H+mem.bit
Function: CY <– CY¦ (bit specified in operand)
Exclusive-ORs the content of the carry flag with the bit in data memory specified by bit manipulation
addressing (fmem.bit, pmem.@L, @H+mem.bit), then sets the result in the carry flag.
11.4.10 Branch Instructions
BR addr
Function: For the µPD750008 PC
I
<– addr
12-0
addr = 0000H-1FFFH
Branches to the address specified by the immediate data addr.
This instruction is an assembler pseudo instruction, and the assembler automatically replaces this
instruction with the BR !addr instruction, BRCB !caddr instruction, or BR $addr instruction as required at
assembly time.
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CHAPTER 11 INSTRUCTION SET
BR addr1
Function: For the µPD750008 PC
II
<– addr1
12-0
addr1 = 0000H-1FFFH
Branches to the address specified by the immediate data addr1.
This instruction is an assembler pseudo instruction, and the assembler automatically replaces this
instruction with the BRA !addr1 instruction, BR !addr instruction, BRCB !caddr instruction, or BR $addr1
instruction as required at assembly time.
Remark "Function" in this section is applicable to the µPD750008 whose program counter consists of
13 bits (addr = 0000H to 1FFFH).
However, this is also applicable to the µPD750004 whose program counter consists of
12 bits (addr = 0000H to 0FFFH), the µPD750006 whose program counter consists of 13
bits (addr = 0000H to 17FFH), and the µPD75P0016 whose program counter consists of
14 bits (addr = 0000H to 3FFFH).
BRA !addr1
Function: For the µPD750008 PC
II
<– addr1
<– addr
12-0
12-0
BR !addr
Function: For the µPD750008 PC
I
addr = 0000H-1FFFH
Transfers the immediate data addr to the program counter (PC), then branches to the location addressed
by the program counter.
BR $addr
Function: For the µPD750008 PC
I
<– addr
12-0
addr = (PC–15) to (PC–1), (PC+2) to (PC+16)
Relative branch instruction with branch ranges of (–15 to –1) and (+2 to +16) from the current address.
The instruction is not affected by page or block boundaries.
II
BR $addr1
Function: For the µPD750008 PC
<– addr1
12-0
addr = (PC–15) to (PC–1), (PC+2) to (PC+16)
Relative branch instruction with branch ranges of (–15 to –1) and (+2 to +16) from the current address.
The instruction is not affected by page or block boundaries.
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Remark "Function" in this section is applicable to the µPD750008 whose program counter consists of
13 bits (addr = 0000H to 1FFFH).
However, this is also applicable to the µPD750004 whose program counter consists of 12 bits
(addr = 0000H to 0FFFH), the µPD750006 whose program counter consists of 13 bits (addr =
0000H to 17FFH), and the µPD75P0016 whose program counter consists of 14 bits (addr = 0000H
to 3FFFH).
BRCB !caddr
Function: For the µPD750008 PC
<– PC + caddr
12 11-0
12-0
caddr = n000H-nFFFH
n = PC = 0, 1
12
Branches to the address specified by the program counter whose low-order 12 bits
(PC ) have been replaced with the 12-bit immediate data caddr (A ).
11-0
11-0
Since the program counter of the µPD750004 consists of 11 bits, this instruction enables a branch to any
location in the program memory space.
In the µPD750006 and µPD750008, PC cannot be changed, so no branch occurs beyond the block.
12
Similarly, in the µPD75P0016, PC and PC cannot be changed, so no branch occurs beyond the block.
12
13
Caution The BRCB !caddr instruction usually causes a branch within the block containing the
instruction. However, if the first byte is located at address 0FFEH or 0FFFH, a branch to
block 1 instead of block 0 occurs.
Program memory
7
0
Block 0
Block 1
0FFEH
0FFFH
1000H
a
b
If the BRCB !caddr instruction is located at a or b in the figure above, a branch to block 1 instead of block
0 occurs.
Remark "Function" in this section is applicable to the µPD750008 whose program counter consists of
13 bits (addr = 0000H to 1FFFH).
However, this is also applicable to the µPD750004 whose program counter consists of 12
bits (addr = 0000H to 0FFFH), the µPD750006 whose program counter consists of 13 bits
(addr = 0000H to 17FFH), and the µPD75P0016 whose program counter consists of 14 bits
(addr = 0000H to 3FFFH).
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CHAPTER 11 INSTRUCTION SET
BR PCDE
Function: For the µPD750008 PC
<– PC
+ DE
12-8
12-0
7- 4
PC
<– D, PC <– E
3-0
Branches to the address specified by the program counter whose low-order 8 bits (PC ) have been
7-0
replaced with the contents of the DE register pair. The high-order bits of the program counter are not affected.
Caution TheBRPCDEinstructionusuallycausesabranchwithinthepagecontainingtheinstruction.
However, if the first byte of the instruction code is located at address xxFEH or xxFFH,
a branch to the next page instead of that page occurs.
Program memory
7
0
Page 2
Page 3
02FEH
02FFH
0300H
a
b
If the BR PCDE instruction is located at a or b in the figure above, a branch to page 3 instead of page 2
occurs, jumping to the low-order 8 bits of the address specified by the contents of the DE register pair.
BR PCXA
Function: For the µPD750008 PC
<– PC
+ XA
12-8
12-0
7- 4
PC
<– X, PC <– A
3-0
Branches to the address specified by the program counter whose low-order 8 bits (PC ) have been
7-0
replaced with the contents of the XA register pair. The high-order bits of the program counter are not affected.
Caution As with the BR PCDE instruction, if the first byte is located at address xxFEH or xxFFH,
a branch to the next page instead of the page containing the instruction occurs.
Remark "Function" in this section is applicable to the µPD750008 whose program counter consists of
13 bits (addr = 0000H to 1FFFH).
However, this is also applicable to the µPD750004 whose program counter consists of 12
bits (addr = 0000H to 0FFFH), the µPD750006 whose program counter consists of 13 bits
(addr = 0000H to 17FFH), and the µPD75P0016 whose program counter consists of 14 bits
(addr = 0000H to 3FFFH).
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BR BCDE
Function: For the µPD750008 PC
<– BCDE
12-0
Branches to the address specified by the program counter whose bits have been replaced with the contents
of the B , C, D, and E registers.
0
12
11
8 7
4 3
0
PC
0
3
0
3
0
3
0
B
C
D
E
BR BCXA
Function: For the µPD750008 PC
<– BCXA
12-0
Branches to the address specified by the program counter whose bits have been replaced with the contents
of the B , C, X, and A registers.
0
12
11
8 7
4 3
0
PC
0
3
0
3
0
3
0
B
C
X
A
TBR addr
Function: Assembler pseudo instruction of the GETI instruction for table definition. This instruction is
used to replace a 3-byte BR instruction with a 1-byte GETI instruction. The 12-bit address data
must be coded in addr. For detailed information, refer to RA75X Assembler Package User’s
Manual: Language (EEU-1363).
Remark "Function" in this section is applicable to the µPD750008 whose program counter consists of
13 bits (addr = 0000H to 1FFFH).
However, this is also applicable to the µPD750004 whose program counter consists of 12
bits (addr = 0000H to 0FFFH), the µPD750006 whose program counter consists of 13 bits
(addr = 0000H to 17FFH), and the µPD75P0016 whose program counter consists of 14 bits
(addr = 0000H to 3FFFH).
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CHAPTER 11 INSTRUCTION SET
11.4.11 Subroutine Stack Control Instructions
CALLA !addr1
II
Function: For the µPD750008
(SP–2) <– x, x, MBE, RBE, (SP–3) <– PC
7-4
(SP–4) <– PC
(SP–6) <– PC
(SP–5) <– 0, 0, 0, PC
12
3-0,
11-8
PC
<– addr1, SP <– SP–6
12-0
CALL !addr
I/II
Function: For the µPD750008
[Mk I mode]
(SP–1) <– PC , (SP–2) <– PC
7-4
3-0
(SP–3) <– MBE, RBE, 0, PC
12
(SP–4) <– PC
, PC
11-8
<– addr, SP <– SP–4
12-0
addr = 0000H – 1FFFH
[Mk II mode]
(SP–2) <– x, x, MBE, RBE
(SP–3) <– PC , (SP–4) <– PC
7-4
3-0
(SP–5) <– 0, 0, 0, PC , (SP–6) <– PC
12
11-8
PC
<– addr, SP <– SP–6
12-0
addr = 0000H – 1FFFH
Saves the contents of the program counter (return address), memory bank enable flag (MBE), and register
bank enable flag (RBE) to the data memory location (stack) addressed by the stack pointer (SP), then branches
to the location addressed by the 14-bit immediate data addr after decrementing SP.
Remark "Function" in this section is applicable to the µPD750008 whose program counter consists of
13 bits (addr = 0000H to 1FFFH).
However, this is also applicable to the µPD750004 whose program counter consists of 12
bits (addr = 0000H to 0FFFH), the µPD750006 whose program counter consists of 13 bits
(addr = 0000H to 17FFH), and the µPD75P0016 whose program counter consists of 14 bits
(addr = 0000H to 3FFFH).
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CALLF !faddr
I/II
Function: For the µPD750008
[Mk I mode]
(SP–1) <– PC , (SP–2) <– PC
7-4
3-0
(SP–3) <– MBE, RBE, 0, PC
12
(SP–4) <– PC
, SP <– SP – 4
11-8
PC
<– 00 + faddr
12-0
faddr = 0000H – 07FFH
[Mk II mode]
(SP–2) <– x, x, MBE, RBE
(SP–3) <– PC , (SP–4) <– PC
7-4
3-0
(SP–5) <– 0, 0, 0, PC , (SP–6) <– PC
12
11-8
SP <– SP–6
PC
<– 00 + faddr
12-0
faddr = 0000H – 07FFH
Saves the contents of the program counter (PC; Return address), memory bank enable flag (MBE), and
register bank enable flag (RBE) to the data memory location (stack) addressed by the stack pointer (SP), then
branches to the location addressed by the 11-bit immediate data faddr after decrementing SP. Only the
address range 0000H-07FFH (0-2047) can be called.
TCALL !addr
Function: Assembler pseudo instruction of the GETI instruction for table definition. This instruction is
used to replace a 3-byte CALL !addr instruction with a 1-byte GETI instruction. The 12-bit
address data must be coded in addr. For detailed information, refer to RA75X Assembler
Package User’s Manual: Language (EEU-1363).
Remark "Function" in this section is applicable to the µPD750008 whose program counter consists of
13 bits (addr = 0000H to 1FFFH).
However, this is also applicable to the µPD750004 whose program counter consists of 12
bits (addr = 0000H to 0FFFH), the µPD750006 whose program counter consists of 13 bits
(addr = 0000H to 17FFH), and the µPD75P0016 whose program counter consists of 14 bits
(addr = 0000H to 3FFFH).
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CHAPTER 11 INSTRUCTION SET
RET
Function: For the µPD750008
I/II
[Mk I mode]
PC
<– (SP)
11-8
MBE, RBE, 0, PC <– (SP+1)
12
PC
PC
PC
PC
<– (SP+2)
3-0
<– (SP+3), SP <– SP+4
7-4
[Mk II mode]
<– (SP), x, x, x, PC <– (SP+1)
11-8
12
<– (SP+2), PC
<– (SP+3)
7-4
3-0
x, x, MBE, RBE <– (SP+4)
SP <– SP+6
Restores the program counter (PC), memory bank enable flag (MBE), and register bank enable flag (RBE)
with the data at the data memory location (stack) addressed by the stack pointer (SP), then increments the
contents of SP.
Caution The program status word (PSW) is not restored except MBE and RBE.
Remark "Function" in this section is applicable to the µPD750008 whose program counter consists of
13 bits (addr = 0000H to 1FFFH).
However, this is also applicable to the µPD750004 whose program counter consists of 12
bits (addr = 0000H to 0FFFH), the µPD750006 whose program counter consists of 13 bits
(addr = 0000H to 17FFH), and the µPD75P0016 whose program counter consists of 14 bits
(addr = 0000H to 3FFFH).
RETS
Function: For the µPD750008
I/II
[Mk I mode]
PC
<– (SP)
11-8
MBE, 0, 0, PC <– (SP+1)
12
PC
<– (SP+2), PC
<– (SP+3), SP <– SP+4
7-4
3-0
Then skip unconditionally
[Mk II mode]
PC
PC
<– (SP), 0, 0, 0, PC <– (SP+1)
12
11-8
<– (SP+2), PC
<– (SP+3)
7-4
3-0
x, x, MBE, RBE <– (SP+4)
SP <– SP+6
Then skip unconditionally
Restores the program counter (PC), memory bank enable flag (MBE), and register bank enable flag (RBE)
withthedataatthedatamemorylocation(stack)addressedbythestackpointer(SP), thenskipsunconditionally
after incrementing the contents of SP.
Caution The program status word (PSW) is not restored except MBE and RBE.
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Remark "Function" in this section is applicable to the µPD750008 whose program counter consists of
13 bits (addr = 0000H to 1FFFH).
However, this is also applicable to the µPD750004 whose program counter consists of 12
bits (addr = 0000H to 0FFFH),the µPD750006 whose program counter consists of 13 bits
(addr = 0000H to 17FFH),and the µPD75P0016 whose program counter consists of 14 bits
(addr = 0000H to 3FFFH).
RETI
Function: For the µPD750008
I/II
[Mk I mode]
PC
PC
PC
<– (SP), MBE, RBE, 0, PC <– (SP+1)
11-8 12
<– (SP+2)
<– (SP+3)
3-0
7-4
PSW <– (SP+4), PSW <– (SP+5)
L
H
SP <– SP+6
[Mk II mode]
PC
PC
PC
<– (SP), 0, 0, 0, PC <– (SP+1)
12
11-8
<– (SP+2)
<– (SP+3),
3-0
7-4
PSW <– (SP+4), PSW <– (SP+5)
L
H
SP <– SP+6
Restores the program counter (PC) and program status word with the data at the data memory location
(stack) addressed by the stack pointer (SP), then increments the contents of SP.
This instruction is used when control is returned from an interrupt service routine.
Remark "Function" in this section is applicable to the µPD750008 whose program counter consists of
13 bits (addr = 0000H to 1FFFH).
However, this is also applicable to the µPD750004 whose program counter consists of 12
bits (addr = 0000H to 0FFFH), the µPD750006 whose program counter consists of 13 bits
(addr = 0000H to 17FFH), and the µPD75P0016 whose program counter consists of 14 bits
(addr = 0000H to 3FFFH).
PUSH rp
Function: (SP–1) <– rp , (SP–2) <– rp , SP <– SP–2
H
L
Saves the contents of register pair rp (XA, HL, DE, BC) to the data memory location (stack) addressed by
the stack pointer (SP), then decrements SP.
The high-order part of a register pair (rp : X, H, D, B) is saved to the stack location addressed by (SP–
H
1), and the low-order part (rp : A, L, E, C) is saved to the stack location addressed by (SP–2).
L
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CHAPTER 11 INSTRUCTION SET
PUSH BS
Function: (SP–1) <– MBS, (SP–2) <– RBS, SP <– SP–2
Saves the contents of the memory bank select register (MBS) and the register bank select register (RBS)
to the data memory location (stack) addressed by the stack pointer (SP), then decrements SP.
POP rp
Function: rp <– (SP), rp <– (SP+1), SP <– SP+2
L
H
Restores register pair rp (XA, HL, DE, BC) with the data at the data memory location (stack) addressed
by the stack pointer (SP), then increments SP.
The low-order part of a register pair (rp : A, L, E, C) is restored from the contents of (SP), and the high-
L
order part (rp : X, H, D, B) is restored with the contents of (SP+ ).
H
POP BS
Function: RBS <– (SP), MBS <– (SP+1), SP <– SP+2
Restores the register bank select register (RBS) and the memory bank select register (MBS) with the data
at the data memory location (stack) addressed by the stack pointer (SP), then increments SP.
11.4.12 Interrupt Control Instructions
EI
Function: IME (IPS.3) <– 1
Sets the interrupt master enable flag (bit 3 of the interrupt priority specification register) to 1 to enable
interrupts. Whether to accept an interrupt is controlled with the corresponding interrupt enable flag.
EI IExxx
Function: IExxx <– 1
xxx = N , N
2-0
5
Sets an interrupt enable flag (IExxx) to 1 to enable an interrupt. (xxx = BT, CSI, T0, T1, W, 0, 1, 2, 4)
DI
Function: IME (IPS.3) <– 0
Resets the interrupt master enable flag (bit 3 of the interrupt priority specification register) to 0 to disable
all interrupts regardless of the states of the interrupt enable flags.
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DI IExxx
Function: IExxx <– 0 xxx = N , N
5
2-0
Resets an interrupt enable flag (IExxx) to 0 to disable an interrupt. (xxx = BT, CSI, T0, T1, W, 0, 1, 2, 4)
11.4.13 I/O Instructions
IN A,PORTn
Function: A <– PORTn
n = N : 0–8
3-0
Transfers the contents of the port specified by PORTn (n = 0-8) to the A register.
Caution Before this instruction can be executed, MBE = 0 or (MBE = 1, MBS = 15) must be set. A
number from 0 to 8 can be specified as n. Depending on I/O mode specification, output
latch data (in the output mode) or pin data (in the input mode) are transferred.
IN XA,PORTn
Function: A <– PORTn, X <– PORT
n = N : 4, 6
3-0
n+1
Transfers the contents of the port specified by PORTn (n = 4 or 6) to the A register, then transfers the
contents of the next port to the X register.
Caution Only the number 4 or 6 can be specified as n. Before this instruction can be executed,
MBE = 0 or (MBE = 1, MBS = 15) must be set. Depending on I/O mode specification, output
latch data (in the output mode) or pin data (in the input mode) are transferred.
OUT PORTn, A
Function: PORTn <– A
n = N : 2–8
3-0
Transfers the contents of the A register to the output latch of the port specified by PORTn (n = 2–8).
Caution Before this instruction can be executed, MBE = 0 or (MBE = 1, MBS = 15) must be set.
A number from 2 to 8 can be specified as n.
OUT PORTn, XA
Function: PORTn <– A, PORT
<– X
n = N : 4, 6
3-0
n+1
Transfers the contents of the A register to the output latch of the port specified by PORTn (n = 4, 6), then
transfers the contents of the X register to the output latch of the next port.
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Caution Before this instruction can be executed, MBE = 0 or (MBE = 1, MBS = 15) must be set.
Only 4 or 6 can be specified as n.
11.4.14 CPU Control Instructions
HALT
Function: PCC.2 <– 1
Sets the HALT mode. (This instruction is used to set bit 2 of the processor clock control register.)
Caution The instruction immediately following a HALT instruction must be a NOP instruction.
STOP
Function: PCC.3 <– 1
Sets the STOP mode. (This instruction is used to set bit 3 of the processor clock control register.)
Caution The instruction immediately following a STOP instruction must be a NOP instruction.
NOP
Function: Uses one machine cycle without performing an action.
11.4.15 Special Instructions
SEL RBn
Function: RBS <– n
n = N : 0 to 3
1-0
Sets the 2-bit immediate data n in the register bank select register (RBS).
SEL MBn
Function: MBS <– n
n = N : 0, 1, 15
3-0
Transfers the 4-bit immediate data n to the memory bank select register (MBS).
Only 0, 1, or 15 can be specified as n.
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GETI taddr
I/II
Function: taddr = T , 0 : 20H-7FH
5-0
For the µPD750008
[Mk I mode]
• When a table defined by the TBR instruction is referenced
PC <– (taddr) + (taddr+1)
12-0
4-0
• When a table defined by the TCALL instruction is referenced
(SP–1) <– PC , (SP–2) <– PC
7-4
3-0
(SP–3) <– MBE, RBE, 0, PC
12
(SP–4) <– PC
11-8
PC
<– (taddr)
+ (taddr+1)
4-0
12-0
SP <– SP–4
• When a table defined by an instruction other than the TBR or TCALL instruction is
referenced
An instruction using (taddr) (taddr+1) as its operation code is executed.
[Mk II mode]
• When a table defined by the TBR instruction is referenced
PC
<– (taddr)
+ (taddr+1)
4-0
12-0
• When a table defined by the TCALL instruction is referenced
(SP–2) <– x, x, MBE, RBE
(SP–3) <– PC , (SP–4) <– PC
7-4
3-0
(SP–5) <– 0, 0, 0, PC , (SP–6) <– PC
12
11-8
PC
<– (taddr)
+ (taddr+1)
4-0
12-0
SP <– SP–6
• When a table defined by an instruction other than the TBR or TCALL instruction is
referenced
An instruction using (taddr) (taddr+1) as its operation code is executed.
Remark "Function" in this section is applicable to the µPD750008 whose program counter consists of
13 bits (addr = 0000H to 1FFFH).
However, this is also applicable to the µPD750004 whose program counter consists of 12
bits (addr = 0000H to 0FFFH), the µPD750006 whose program counter consists of 13 bits
(addr = 0000H to 17FFH), and the µPD75P0016 whose program counter consists of 14 bits
(addr = 0000H to 3FFFH).
The 2-byte data at the program memory addresses specified by (taddr) and (taddr+1) is referenced and
executed as an instruction.
Addresses 0020H to 007FH are used as a reference table area. Data must be written to this area
beforehand. When a 1-byte instruction or 2-byte instruction is written, its mnemonic can be used directly.
For a 3-byte call instruction or 3-byte branch instruction, an assembler pseudo instruction (TCALL, TBR)
is used.
Only an even address can be specified as taddr.
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CHAPTER 11 INSTRUCTION SET
Caution All 2-byte instructions (except the BRCB instruction and CALLF instruction) set in the
reference table must be 2-machine-cycle instructions. Pairs of 1-byte instructions can be
set as indicated in the table below.
First byte instruction
Second byte instruction
INCS
DECS
INCS
DECS
INCS
L
L
H
H
HL
MOV A,@HL
MOV @HL,A
XCH A,@HL
INCS
DECS
INCS
DECS
INCS
E
E
D
D
MOV A,@DE
XCH A,@DE
DE
MOV A,@DL
XCH A,@DL
INCS
DECS
INCS
DECS
L
L
D
D
The PC is not incremented during execution of a GETI instruction, so that after a reference instruction is
executed, execution is resumed starting at the address immediately after the GETI instruction.
If the instruction immediately preceding a GETI instruction has the skip function, the GETI instruction is
skipped as with other 1-byte instructions. If an instruction referenced with a GETI instruction has the skip
function, the instruction immediately following the GETI instruction is skipped.
If a GETI instruction references an instruction having a string effect, the following processing is performed:
• If the instruction immediately preceding the GETI instruction also has the string effect in the same group,
the execution of the GETI instruction cancels the string effect, and the referenced instruction is not
skipped.
• If the instruction immediately following the GETI instruction also has the string effect of the same group,
the string effect of the referenced instruction remains valid, and the next instruction is skipped.
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µPD750008 USER'S MANUAL
Example
MOV HL, #00H
MOV XA, #FFH
CALL SUB1
are replaced with GETI instructions.
BR SUB2
ORG
20H
HL00:
MOV
MOV
TCALL
TBR
HL, #00H
XA, #FFH
SUB1
XAFF:
CSUB1:
BSUB2:
SUB2
·
·
·
·
·
·
·
·
·
·
GET HL00
; MOV HL,#00H
·
·
·
·
·
·
·
·
·
·
GETI BSUB2
; BR SUB2
·
·
·
·
·
·
·
·
·
·
GETI CSUB1
; CALL SUB1
·
·
·
·
·
·
·
·
·
·
GETI XAFF
; MOV XA,#FFH
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APPENDIX A FUNCTIONS OF THE µPD75008, µPD750008, AND µPD75P0016
(1/2)
Item
Program memory
µPD75008
µPD750008
µPD75P0016
Masked ROM
0000H - 1F7FH
(8064 x 8 bits)
Masked ROM
0000H - 1FFFH
(8192 x 8 bits)
One-time PROM
0000H - 3FFFH
(16384 x 8 bits)
000H - 1FFH
(512 x 4 bits)
Data memory
CPU
75X standard CPU
31.3 ms
75XL CPU
(equivalent to the 75X high-end CPU)
15
17
15
Oscillation settling time
2
/f , 2 /f (select-
Fixed to
2
/f
X
X
X
able by a mask option)
0.95, 1.91, 15.3 µs
(when operating at
4.19 MHz)
When selecting the main
system clock
• 0.95, 1.91, 3.81, 15.3 µs (when operating at 4.19
MHz)
• 0.67, 1.33, 2.67, 10.7 µs (when operating at 6.0 MHz)
122 µs (when operating at 32.768 kHz)
When selecting the subsys-
tem clock
NC
V
PP
20 (CU)
IC
38 (GB)
24 (CU)
P21
P21/PTO1
A
42 (GB)
P33 - P30
Not provided
P33/MD3 - P30/MD0
6 - 9 (CU)
23-26 (GB)
SBS register
Provided SBS.3 = 1 : Mk I mode selection
SBS.3 = 0 : Mk II mode selection
000H - 0FFH
2-byte stack
Stack area
n00H - nFFH (n = 0, 1)
Stack operation for a
subroutine call instruction
Mk
Mk II mode: 3-byte stack
Mk mode: Not available
I
mode: 2-byte stack
Not available
BRA !addr1
I
CALLA !addr1
Mk II mode: Available
MOVT XA, @BCDE
MOVT XA, @BCXA
BR BCDE
Available
BR BCXA
CALL !addr
3 machine cycles
2 machine cycles
Mk
machine cycles
Mk mode: 2 machine cycles, Mk II mode: 3
machine cycles
I
mode: 3 machine cycles, Mk II mode: 4
CALLF !faddr
I
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µPD750008 USER'S MANUAL
(2/2)
Item
µPD75008
3 channels
µPD750008
4 channels
µPD75P0016
Timer
• Basic interval timer: 1
• Timer/event counter: 1
• Clock timer: 1
• Basic interval timer/watchdog timer: 1
• Timer/event counter: 1
• Timer/counter: 1
• Clock timer: 1
F, 524, 262, 65.5 kHz
(when the main system
clock operates at 4.19
MHz)
Clock output (PCL)
BUZ output (BUZ)
•
F
, 524, 262, 65.5 kHz
(when the main system clock operates at 4.19 MHz)
, 750, 375, 93.7 kHz
(when the main system clock operates at 6.0 MHz)
•
F
2 kHz
• 2, 4, 32 kHz
(when the main system clock operates at 4.19 MHz)
• 2.86, 5.72, 45.8 kHz
(when the main system clock operates at 6.0 MHz)
3 modes supported
Serial interface
• Three-wire serial I/O mode: First transferred bit switchable between the
LSB and MSB
• Two-wire serial I/O mode
• SBI mode
Can incorporate feedback
resistors that are specified
with the mask option.
Feedback resistor cut
flag (SOS.0)
Incorporated
Not provided
Sub-oscillator current cut
flag (SOS.1)
Incorporated
Provided
Not provided
Register bank selection register
(RBS)
Disable
Standby release with INT0
Enable
External: 3, internal: 3
Number of vectored interrupts
Processor clock control register
External: 3, internal: 4
Available when PCC is 0 to 3
Available when PCC is 0,
2, or 3
VDD = 2.7 to 6.0 V
Power supply voltage
Operating ambient temperature
Package
VDD = 2.2 to 5.5 V
T
A
= –40 to +85 °C
• 42-pin plastic shrink DIP (600 mil)
• 44-pin plastic QFP (10 x 10 mm)
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APPENDIX B DEVELOPMENT TOOLS
The following development tools are provided for the development of a system which employs the
µPD750008. In the 75XL series, use the common relocatable assembler together with a device file of each
model.
RA75X relocatable assembler
Host machine
Part number
OS
Distribution media
3.5-inch 2HD
PC-9800 series
MS-DOS
Ver. 3.30
to
µS5A13RA75X
5.25-inch 2HD
µS5A10RA75X
Note
Ver. 6.2
*
IBM PC/AT and See "OS for IBM
3.5-inch 2HC
5.25-inch 2HC
µS7B13RA75X
µS7B10RA75X
compatibles
PC."
Device file
Host machine
Part number
OS
Distribution media
3.5-inch 2HD
PC-9800 series
MS-DOS
Ver. 3.30
to
µS5A13DF750008
5.25-inch 2HD
µS5A10DF750008
Note
Ver. 6.2
IBM PC/AT and See "OS for IBM
compatibles PC."
B
*
3.5-inch 2HC
5.25-inch 2HC
µS7B13DF750008
µS7B10DF750008
Note These software products cannot use the task swap function, which is available in MS-DOS Ver. 5.00
or later.
Remark The operations of the assembler and device file are guaranteed only on the above host machines
*
and OSs.
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PROM programming tools
Hardware PG-1500
The PG-1500 PROM programmer is used together with an accessory board and optional
program adapter. It allows the user to program a single chip microcomputer containing
PROM from a standalone terminal or a host machine. The PG-1500 can be used to
program typical 256K-bit to 4M-bit PROMs.
PA-75P008CU
The PA-75P008CU is a PROM programmer adapter provided for the µPD75P008CU/
GB and µPD75P0016CU/GB. It is used in conjunction with the PG-1500.
Software PG-1500
controller
This program enables the host machine to control the PG-1500 through the serial and
parallel interfaces.
Host machine
PC-9800 series
Part number
OS
Distribution media
3.5-inch 2HD
MS-DOS
Ver. 3.30
to
µS5A13PG1500
5.25-inch 2HD
µS5A10PG1500
Note
Ver. 6.2
*
IBM PC/AT and
compatibles
See "OS for IBM
PC."
3.5-inch 2HD
5.25-inch 2HC
µS7B13PG1500
µS7B10PG1500
Note These software products cannot use the task swap function, which is available in MS-DOS Ver. 5.00
or later.
Remark Operation of the PG-1500 controller is guaranteed only on the above host machines and OSs.
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APPENDIX B DEVELOPMENT TOOLS
Debugging Tools
The in-circuit emulators (IE-75000-R and IE-75001-R) are provided to debug programs used for the
µPD750008.
The following system is shown below.
Note 1
IE-75000-R
The IE-75000-R is an in-circuit emulator used to debug hardware and software
when developing an application system using the 75X series and 75XL series.
Use this emulator together with optional emulation board IE-75300-R-EM and
emulation probe to develop application systems of the µPD750008 subseries.
For efficient debugging, connect the emulator to the host machine and a
PROM programmer.
The IE-75000-R contains emulation board IE-75000-R-EM. The board is
connected to the IE-75000-R.
IE-75001-R
The IE-75001-R is an in-circuit emulator used to debug hardware and software
when developing an application system using the 75X series and 75XL series.
Use this emulator together with optional emulation board IE-75300-R-EM and
emulation probe.
For efficient debugging, connect the emulator to the host machine and a
PROM programmer.
Note 2
IE-75300-R-EM
The IE-75300-R-EM is an emulation board used to evaluate an application
system using the µPD750008 subseries.
Use this board together with the IE-75000-R or IE-75001-R.
EP-75008GB-R
The EP-75008GB-R is an emulation probe for the µPD75008GB and
µPD750008GB.
Connect this emulation probe to the IE-75000-R or IE-75001-R, and the IE-
75300-R-EM.
A 44-pin conversion socket, the EV-9200G-44, supplied with this probe facili-
tates the connection of the probe to the target system.
EV-9200G-44
EP-75008CU-R
The EP-75008CU-R is an emulation probe for the µPD75008CU and
µPD750008CU.
Connect this emulation probe to the IE-75000-R or IE-75001-R, and the IE-
75300-R-EM.
This program enables the host machine to control the IE-75000-R or IE-75001-
R through the RS-232-C and Centronics interface.
IE control program
Part number
Host machine
OS
Distribution media
3.5-inch 2HD
MS-DOS
µS5A13IE75X
µS5A10IE75X
Ver. 3.30 to
5.25-inch 2HD
PC-9800 series
Note 3
Ver. 6.2
*
µS7B13IE75X
µS7B10IE75X
See “OS for
IBM PC.”
3.5-inch 2HC
5.25-inch 2HC
IBM PC/AT and
compatibles
Notes 1. Maintenance service only
2. To be ordered.
3. These software products cannot use the task swap function, which is available in
MS DOS Ver. 5.00 or later.
Remark Operation of the IE control program is guaranteed only on the above host machines and OSs.
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µPD750008 USER'S MANUAL
OS for IBM PC
*
The following IBM PC OSs are supported.
OS
Version
PC DOS
Ver. 3.1 to Ver. 6.3
Note
Note
J6.1/V
to J6.3/V
MS-DOS
IBM DOS
Ver. 5.0 to Ver. 6.22
Note
Note
5.0/V
to J6.2/V
TM
Note
J5.02/V
Note
Only English version is supported.
Caution These software products cannot use the task swap function, which is available in MS-DOS
Ver. 5.00 or later.
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APPENDIX B DEVELOPMENT TOOLS
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µPD750008 USER'S MANUAL
Drawings of the Conversion Socket (EV-9200G-44) and Recommended Pattern on Boards
Figure B-1. Drawings of the EV-9200G-44 (Reference)
EV-9200G-44-G0
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APPENDIX B DEVELOPMENT TOOLS
Figure B-2. Recommended Pattern on Boards for the EV-9200G-44 (Reference)
EV-9200G-44-P0
Caution Dimensions of mount pad for EV-9200 and that for target device (QFP) may be different
in some parts. For the recommended mount pad dimensions for QFP, refer to
"SEMICONDUCTOR DEVICE MOUNTING TECHNOLOGY MANUAL" (IEI-1207).
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µPD750008 USER'S MANUAL
[MEMO]
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APPENDIX C MASKED ROM ORDERING PROCEDURE
After program development is completed, the masked ROM is ordered by the following procedure:
<1> Advance notice of an order for masked ROM
Give advance notice of masked ROM ordering to a special agent or NEC’s Sales Department,
otherwise the ordered products may be delivered with delay.
<2> Preparation of media for ordering
Use three UV-EPROMs having the same contents, or 3.5- or 5.25-inch IBM format floppy disk in
ordering a masked ROM. (Prepare a mask option information sheet describing the mask option data.)
<3> Preparation of the required documents
Prepare the following documents when ordering a masked ROM:
• Masked ROM order sheet
• Masked ROM order check sheet
• Mask option information sheet
<4> Ordering
Send a set of the media created in<2> and the documents created in<3> to a special agent or NEC’s
Sales Department by the date indicated in the advance notice.
C
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[MEMO]
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APPENDIX D INSTRUCTION INDEX
D.1 INSTRUCTION INDEX (BY FUNCTION)
[Transfer instructions]
A,#n4 ... 245, 264
MOVT
MOVT
MOVT
XA,@PCXA ... 246, 271
XA,@BCDE ... 246, 272
XA,@BCXA ... 246, 272
MOV
MOV
MOV
MOV
MOV
MOV
MOV
MOV
MOV
MOV
MOV
MOV
MOV
MOV
MOV
MOV
MOV
MOV
MOV
MOV
XCH
XCH
XCH
XCH
XCH
XCH
XCH
XCH
XCH
reg1,#n4 ... 245, 265
XA,#n8 ... 245, 265
HL,#n8 ... 245, 265
rp2,#n8 ... 245, 265
A,@HL ... 245, 265
A,@HL+ ... 245, 265
A,@HL– ... 245, 265
A,@rpa1 ... 245, 265
XA,@HL ... 245, 266
@HL,A ... 245, 266
@HL,XA ... 245, 266
A,mem ... 245, 266
XA,mem ... 245, 267
mem,A ... 245, 267
mem,XA ... 245, 267
A,reg ... 245, 267
[Bit transfer instructions]
MOV1
MOV1
MOV1
MOV1
MOV1
MOV1
CY,fmem.bit ... 246, 273
CY,pmem.@L ... 246, 273
CY,@H+mem.bit ... 246, 273
fmem.bit,CY ... 246, 273
pmem.@L,CY ... 246, 273
@H+mem.bit,CY ... 246, 273
[Arithmetic/logical instructions]
ADDS
ADDS
ADDS
ADDS
ADDS
ADDC
ADDC
ADDC
SUBS
SUBS
SUBS
SUBC
SUBC
SUBC
AND
A,#n4 ... 246, 273
XA,#n8 ... 246, 274
A,@HL ... 246, 274
XA,rp’ ... 246, 274
rp’1,XA ... 246, 274
A,@HL ... 246, 274
XA,rp’ ... 246, 275
rp’1,XA ... 246, 275
A,@HL ... 246, 275
XA,rp’ ... 246, 275
rp’1,XA ... 246, 276
A,@HL ... 246, 276
XA,rp’ ... 246, 276
rp’1,XA ... 246, 276
A,#n4 ... 247, 276
A,@HL ... 247, 277
XA,rp’ ... 247, 277
rp’1,XA ... 247, 277
D
XA,rp’ ... 245, 267
reg1,A ... 245, 268
rp’1,XA ... 245, 268
A,@HL ... 245, 268
A,@HL+ ... 245, 268
A,@HL– ... 245, 268
A,@rpa1 ... 245, 268
XA,@HL ... 245, 269
A,mem ... 245, 269
XA,mem ... 245, 269
A,reg1 ... 245, 269
XA,rp’ ... 245, 269
AND
AND
AND
[Table reference instructions]
MOVT XA,@PCDE ... 246, 270
OR
A,#n4 ... 247, 277
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OR
A,@HL ... 247, 277
XA,rp’ ... 247, 277
rp’1,XA ... 247, 278
A,#n4 ... 247, 278
A,@HL ... 247, 278
XA,rp’ ... 247, 278
rp’1,XA ... 247, 278
SET1
SET1
CLR1
CLR1
CLR1
CLR1
SKT
pmem.@L ... 248, 282
@H+mem.bit ... 248, 282
mem.bit ... 248, 282
OR
OR
XOR
XOR
XOR
XOR
fmem.bit ... 248, 282
pmem.@L ... 248 282
@H+mem.bit ... 248, 282
mem.bit ... 248, 283
SKT
fmem.bit ... 248, 283
[Accumulator manipulation instructions]
SKT
pmem.@L ... 248, 283
@H+mem.bit ... 248, 283
mem.bit ... 248, 283
RORC
NOT
A ... 247, 279
A ... 247, 279
SKT
SKF
SKF
fmem.bit ... 248, 283
[Increment/decrement instructions]
SKF
pmem.@L ... 248, 283
@H+mem.bit ... 248, 283
fmem.bit ... 248, 283
INCS
INCS
INCS
INCS
DECS
DECS
reg ... 247, 279
rp1 ... 247, 279
@HL ... 247, 279
mem ... 247, 280
reg ... 247, 280
rp’ ... 247, 280
SKF
SKTCLR
SKTCLR
SKTCLR
AND1
AND1
AND1
OR1
pmem.@L ... 248, 283
@H+mem.bit ... 248, 283
CY,fmem.bit ... 248, 284
CY,pmem.@L ... 248, 284
CY,@H+mem.bit ... 248, 284
CY,fmem.bit ... 248, 284
CY,pmem.@L ... 248, 284
CY,@H+mem.bit ... 248, 284
CY,fmem.bit ... 248, 284
CY,pmem,@L ... 248, 284
CY,@H+mem.bit ... 248, 284
[Compare instructions]
SKE
SKE
SKE
SKE
SKE
SKE
reg,#n4 ... 247, 280
OR1
@HL,#n4 ... 247, 280
A,@HL ... 247, 280
XA,@HL ... 247, 281
A,reg ... 247, 281
OR1
XOR1
XOR1
XOR1
XA,rp’ ... 247, 281
[Branch instructions]
[Carry flag manipulation instructions]
BR
BR
BR
BR
BR
BR
BR
BR
BR
addr ... 249, 284
SET1
CLR1
SKT
CY ... 247, 281
CY ... 247, 281
CY ... 247, 281
CY ... 247, 282
addr1 ... 249, 285
!addr ... 250, 285
$addr ... 250, 285
$addr1 ... 250, 285
PCDE ... 250, 287
PCXA ... 250, 287
BCDE ... 250, 288
BCXA ... 251, 288
NOT1
[Memory bit manipulation instructions]
SET1
SET1
mem.bit ... 248, 282
fmem.bit ... 248, 282
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APPENDIX D INSTRUCTION INDEX
BRA
!addr1 ... 251, 285
!caddr ... 251, 286
addr ... 256, 288
BRCB
TBR
[Subroutine stack control instructions]
CALLA
CALL
!addr1 ... 251, 289
!addr ... 252, 289
!faddr ... 252, 290
!addr ... 256, 290
CALLF
TCALL
RET ... 253, 291
RETS ... 254, 291
RETI ... 254, 292
PUSH
PUSH
POP
rp ... 255, 292
BS ... 255, 293
rp ... 255, 293
BS ... 255, 293
POP
[Interrupt control instructions]
EI ... 255, 293
EI
IExxx ... 255, 293
DI ... 255, 293
DI
IExxx ... 255, 294
[I/O instructions]
IN
A,PORTn ... 255, 294
IN
XA,PORTn ... 255, 294
PORTn,A ... 255, 294
PORTn,XA ... 255, 294
OUT
OUT
[CPU control instructions]
HALT ... 255, 295
STOP ... 255, 295
NOP ... 255, 295
[Special instructions]
SEL
SEL
GETI
RBn ... 256, 295
MBn ... 256, 295
taddr ... 256, 296
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D.2 INSTRUCTION INDEX (ALPHABETICAL ORDER)
[A]
CLR1
mem.bit ... 248, 282
ADDC
A,@HL ... 246, 274
rp’1,XA .. 246, 275
XA,rp’ ... 246, 275
CLR1
CLR1
pmem.@L ... 248 282
@H+mem.bit ... 248, 282
ADDC
ADDC
ADDS
ADDS
ADDS
ADDS
ADDS
AND
A,#n4 ... 246, 273
[D]
A,@HL ... 246, 274
rp’1,XA ... 246, 274
XA,rp’ ... 246, 274
DECS
reg ... 247, 280
rp’ ... 247, 280
DECS
DI ... 255, 293
XA,#n8 ... 246, 274
A,#n4 ... 247, 276
DI
IExxx ... 255, 294
AND
A,@HL ... 247, 277
rp’1,XA ... 247, 277
XA,rp’ ... 247, 277
[E]
EI ... 255, 293
AND
EI
IExxx ... 255, 293
AND
AND1
AND1
AND1
CY,fmem.bit ... 248, 284
CY,pmem.@L ... 248, 284
CY,@H+mem.bit ... 248, 284
[G]
GETI
taddr ... 256, 296
[H]
[B]
HALT ... 255, 295
BR
addr ... 249, 284
addr1 ... 249, 285
BCDE ... 250, 288
BCXA ... 251, 288
PCDE ... 250, 287
PCXA ... 250, 287
!addr ... 250, 285
$addr ... 250, 285
$addr1 ... 250, 285
!addr1 ... 251, 285
!caddr ... 251, 286
BR
[I]
BR
IN
A,PORTn ... 255, 294
BR
IN
XA,PORTn ... 255, 294
mem ... 247, 280
reg ... 247, 279
BR
INCS
INCS
INCS
INCS
BR
BR
rp1 ... 247, 279
BR
@HL ... 247, 279
BR
BRA
BRCB
[M]
MOV
A,mem ... 245, 266
A,reg ... 245, 267
A,#n4 ... 245, 264
A,@HL ... 245, 265
A,@HL+ ... 245, 265
A,@HL– ... 245, 265
MOV
MOV
MOV
MOV
MOV
[C]
CALL
!addr ... 252, 289
!addr1 ... 251, 289
!faddr ... 252, 290
CY ... 247, 281
CALLA
CALLF
CLR1
CLR1
fmem.bit ... 248, 282
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APPENDIX D INSTRUCTION INDEX
MOV
A,@rpa1 ... 245, 265
HL,#n8 ... 245, 265
OR1
OUT
OUT
CY,@H+mem.bit ... 248, 284
PORTn,A ... 255, 294
MOV
MOV
mem,A ... 245, 267
PORTn,XA ... 255, 294
MOV
mem,XA ... 245, 267
reg1,A ... 245, 268
MOV
[P]
POP
BS ... 255, 293
rp ... 255, 293
BS ... 255, 293
MOV
reg1,#n4 ... 245, 265
rp’1,XA ... 245, 268
POP
MOV
PUSH
MOV
rp2,#n8 ... 245, 265
MOV
XA,mem ... 245, 267
XA,rp’ ... 245, 267
PUSH
rp ... 255, 292
MOV
MOV
XA,#n8 ... 245, 265
[R]
MOV
XA,@HL ... 245, 266
@HL,A ... 245, 266
RET ... 253, 291
RETI ... 254, 292
RETS ... 254, 291
MOV
MOV
@HL,XA ... 245, 266
XA,@BCDE ... 246, 272
XA,@BCXA ... 246, 272
XA,@PCDE ... 246, 270
XA,@PCXA ... 246, 271
CY,fmem.bit ... 246, 273
CY,pmem.@L ... 246, 273
CY,@H+mem.bit ... 246, 273
fmem.bit,CY ... 246, 273
pmem.@L,CY ... 246, 273
@H+mem.bit,CY ... 246, 273
MOVT
MOVT
MOVT
MOVT
MOV1
MOV1
MOV1
MOV1
MOV1
MOV1
RORC
A ... 247, 279
[S]
SEL
MBn ... 256, 295
SEL
RBn ... 256, 295
SET1
SET1
SET1
SET1
SET1
SKE
SKE
SKE
SKE
SKE
SKE
SKF
SKF
SKF
SKF
SKT
SKT
SKT
CY ... 247, 281
fmem.bit ... 248, 282
mem.bit ... 248, 282
pmem.@L ... 248, 282
@H+mem.bit ... 248, 282
A,reg ... 247, 281
A,@HL ... 247, 280
reg,#n4 ... 247, 280
XA,rp’ ... 247, 281
XA,@HL ... 247, 281
@HL,#n4 ... 247, 280
fmem.bit ... 248, 283
mem.bit ... 248, 283
pmem.@L ... 248, 283
@H+mem.bit ... 248, 283
CY ... 247, 281
[N]
NOP ... 255, 295
NOT
A ... 247, 279
NOT1
CY ... 247, 282
[O]
OR
A,#n4 ... 247, 277
OR
A,@HL ... 247, 277
rp’1,XA ... 247, 278
XA,rp’ ... 247, 277
OR
OR
OR1
OR1
CY,fmem.bit ... 248, 284
CY,pmem.@L ... 248, 284
fmem.bit ... 248, 283
mem.bit ... 248, 283
315
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SKT
pmem.@L ... 248, 283
@H+mem.bit ... 248, 283
fmem.bit ... 248, 283
SKT
SKTCLR
SKTCLR
SKTCLR
pmem.@L ... 248, 283
@H+mem.bit ... 248, 283
STOP ... 255, 295
SUBC
SUBC
SUBC
SUBS
SUBS
SUBS
A,@HL ... 246, 276
rp’1,XA ... 246, 276
XA,rp’ ... 246, 276
A,@HL ... 246, 275
rp’1,XA ... 246, 276
XA,rp’ ... 246, 275
[T]
TBR
addr ... 256, 288
!addr ... 256, 290
TCALL
[X]
XCH
A,mem ... 245, 269
A,reg1 ... 245, 269
XCH
XCH
XCH
XCH
XCH
XCH
XCH
XCH
XOR
XOR
XOR
XOR
XOR1
XOR1
XOR1
A,@HL ... 245, 268
A,@HL+ ... 245, 268
A,@HL– ... 245, 268
A,@rpa1 ... 245, 268
XA,mem ... 245, 269
XA,rp’ ... 245, 269
XA,@HL ... 245, 269
A,#n4 ... 247, 278
A,@HL ... 247, 278
rp’1,XA ... 247, 278
XA,rp’ ... 247, 278
CY,fmem.bit ... 248, 284
CY,pmem,@L ... 248, 284
CY,@H+mem.bit ... 248, 284
316
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APPENDIX E HARDWARE INDEX
E.1 HARDWARE INDEX (ALPHABETICAL ORDER WITH RESPECT TO THE HARDWARE NAME)
[A]
INT0 interrupt enable flag ... 187
INT0 interrupt request flag ... 187
INT1 edge detection mode register ... 193
INT1 interrupt enable flag ... 187
INT1 interrupt request flag ... 187
INT2 edge detection mode register ... 213
INT2 interrupt enable flag ... 210
INT2 interrupt request flag ... 210
INT4 interrupt enable flag ... 187
INT4 interrupt request flag ... 187
Acknowledge detection flag ... 132
Acknowledge enable bit ... 132
Acknowledge trigger bit ... 132
[B]
Bank select register ... 65
Basic interval timer ... 99
Basic interval timer mode register ... 99
Bit sequential buffer ... 181
BT interrupt enable flag ... 187
BT interrupt request flag ... 187
Bus release detection flag ... 133
Bus release trigger bit ... 133
Busy enable bit ... 132
[K]
Key interrupt input ... 211
[M]
[C]
Memory bank enable flag ... 21, 64
Memory bank select register ... 21, 65
E
Carry flag ... 62
Clock mode register ... 106
Clock output mode register ... 97
Command detection flag ... 132
Command trigger bit ... 133
[P]
Port 0 to port 8 ... 68
Port mode register group A ... 75
Port mode register group B ... 75
Port mode register group C ... 75
Processor clock control register ... 86
Program counter ... 47
[E]
Edge detection mode register ... 193, 213
[I]
Interrupt enable flag for clock timer ... 210
Interrupt master enable flag ... 189
Interrupt request flag for clock timer ... 210
Interrupt status flag ... 63, 194
INT0 edge detection mode register ... 193
Program status word ... 62
Pull-up resistor specification register
group A ... 82
Pull-up resistor specification register
group B ... 82
317
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µPD750008 USER'S MANUAL
[R]
[W]
Wake-up function specification bit ... 128
Watchdog timer enable flag ... 101
Register bank enable flag ... 34, 64
Register bank select register ... 34, 65
[S]
Serial bus interface control register ... 131
Serial interface interrupt enable flag ... 187
Serial interface interrupt request flag ... 187
Serial interface operation enable/disable
specification bit ... 128
Serial operation mode register ... 127
Shift register ... 134
Signal from address comparator ... 128
Skip flag ... 63
Slave address register ... 134
Stack bank select register ... 46, 58
Stack pointer ... 58
Sub-oscillator control register ... 93
System clock control register ... 88
[T]
Timer/counter 1 interrupt enable
flag ... 187
Timer/counter 1 interrupt request
flag ... 187
Timer/counter 1 mode register ... 111
Timer/counter 1 modulo register ... 110
Timer/counter 1 output enable flag ... 114
Timer/counter count 1 register ... 110
Timer/event counter 0 count register ... 109
Timer/event counter 0 interrupt enable
flag ... 187
Timer/event counter 0 interrupt request
flag ... 187
Timer/event counter 0 mode register ... 111
Timer/event counter 0 modulo register ... 109
Timer/event counter 0 output enable
flag ... 114
318
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APPENDIX E HARDWARE INDEX
E.2 HARDWARE INDEX (ALPHABETICAL ORDER WITH RESPECT TO THE HARDWARE SYMBOL)
[A]
IRQ1 ... 187
ACKD ... 132
ACKE ... 132
ACKT ... 132
IRQ2 ... 210
IRQ4 ... 187
IRQBT ... 187
IRQCSI ... 187
IRQT0 ... 187
IRQT1 ... 187
IRQW ... 210
IST0 ... 63, 194
IST1 ... 63, 194
[B]
BS ... 65
BSB0-BSB3 ... 181
BSYE ... 132
BT ... 99
BTM ... 99
[K]
[C]
KR0-KR7 ... 211
CLOM ... 97
CMDD ... 132
CMDT ... 133
COI ... 128
CSIE ... 128
CSIM .. 127
CY ... 62
[M]
MBE ... 21, 64
MBS ... 21, 65
[P]
PC ... 47
PCC ... 86
[I]
PMGA ... 75
PMGB ... 75
PMGC ... 75
POGA ... 82
POGB ... 82
PORT0-PORT8 ... 68
PSW ... 62
IE0 ... 187
IE1 ... 187
IE2 ... 210
IE4 ... 187
IEBT ... 187
IECSI ... 187
IET0 ... 187
IET1 ... 187
IEW ... 210
IM0, IM1 ... 193
IM2 ... 213
IME ... 189
IRQ0 ... 187
[R]
RBE ... 34, 64
RBS ... 34, 65
RELD ... 133
RELT ... 133
319
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µPD750008 USER'S MANUAL
[S]
SBIC ... 131
SBS ... 46, 58
SCC ... 88
SIO ... 134
SK0, SK1, SK2 ... 63
SOS ... 93
SP ... 58
SVA ... 134
[T]
T0 ... 109
T1 ... 110
TOE0 ... 114
TOE1 ... 114
TM0 ... 112
TM1 ... 113
TMOD0 ... 109
TMOD1 ... 110
[W]
WDTM ... 101
WM ... 106
WUP ... 128
320
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APPENDIX F REVISION HISTORY
Major revisions in this edition are shown below. The revised chapters refer to this edition.
Edition
Second
Major revisions from previous edition
Revised chapters
The 44-pin plastic QFP package was changed from
All
µPD750008GB-xxx-3B4 to µPD750008GB-xxx-3BS-MTX.
The µPD75P0016 under development has been changed to the
already-developed µPD75P0016.
The input withstand voltage at ports 4 and 5 during open drain was
changed from 12 V to 13 V.
English-version document numbers was added to "Related
documents."
Preface
The format of the table in Section 1.3 was changed.
Chapter 1
Chapter 4
The caution in using Mk II mode was added in Table 4-1
"Differences between Mk I Mode and Mk II Mode."
The description for the mask option when using the feedback resistor Chapter 5
was added in the section "Sub-oscillator control register."
The description for the interrupt enable flag was added in Section 6.3 Chapter 6
"VARIOUS DEVICES TO CONTROL INTERRUPT FUNCTIONS."
Table 6-4 "Identifying Interrupt Sharing Vector Table Address" was
added in Section 6.6 "PROCESSING OF INTERRUPTS SHARING
A VECTOR ADDRESS."
The description for the screening of one-time PROM was added.
The description for the mask option was added.
Chapter 9
Chapter 10
Chapter 11
The operand @rpa was changed to @rpa1 in Chapter 11
"INSTRUCTION SET."
F
@rpa1 was added in the table in item (1) "Operand identifier and
description" in Section 11.2 "INSTRUCTION SET AND OPERATION."
The title of Section 11.4 "FUNCTIONS AND APPLICATIONS OF
THE INSTRUCTIONS" was changed to conform to that of Section
11.2 "INSTRUCTION SET AND OPERATION."
Supported OS versions were upgraded
Appendix B
321
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µPD750008 USER'S MANUAL
[MEMO]
322
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