User’s Manual
TM
V850E/MS1
32-/16-Bit Single-Chip Microcontrollers
Hardware
µPD703100
µPD703100A
µPD703101
µPD703101A
µPD703102
µPD703102A
µPD70F3102
µPD70F3102A
Document No. U12688EJ4V0UM00 (4th edition)
Date Published January 2000 N CP(K)
©
1997
Printed in Japan
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User’s Manual U12688EJ4V0UM00
NOTES FOR CMOS DEVICES
1
PRECAUTION AGAINST ESD FOR SEMICONDUCTORS
Note:
Strong electric field, when exposed to a MOS device, can cause destruction of the gate oxide and
ultimately degrade the device operation. Steps must be taken to stop generation of static electricity
as much as possible, and quickly dissipate it once, when it has occurred. Environmental control
must be adequate. When it is dry, humidifier should be used. It is recommended to avoid using
insulators that easily build static electricity. Semiconductor devices must be stored and transported
in an anti-static container, static shielding bag or conductive material. All test and measurement
tools including work bench and floor should be grounded. The operator should be grounded using
wrist strap. Semiconductor devices must not be touched with bare hands. Similar precautions need
to be taken for PW boards with semiconductor devices on it.
2
HANDLING OF UNUSED INPUT PINS FOR CMOS
Note:
No connection for CMOS device inputs can be cause of malfunction. If no connection is provided
to the input pins, it is possible that an internal input level may be generated due to noise, etc., hence
causing malfunction. CMOS devices behave differently than Bipolar or NMOS devices. Input levels
of CMOS devices must be fixed high or low by using a pull-up or pull-down circuitry. Each unused
pin should be connected to V DD or GND with a resistor, if it is considered to have a possibility of
being an output pin. All handling related to the unused pins must be judged device by device and
related specifications governing the devices.
3
STATUS BEFORE INITIALIZATION OF MOS DEVICES
Note:
Power-on does not necessarily define initial status of MOS device. Production process of MOS
does not define the initial operation status of the device. Immediately after the power source is
turned ON, the devices with reset function have not yet been initialized. Hence, power-on does
not guarantee out-pin levels, I/O settings or contents of registers. Device is not initialized until the
reset signal is received. Reset operation must be executed immediately after power-on for devices
having reset function.
V850E/MS1 and V850 Family are trademarks of NEC Corporation.
Windows is either a registered trademark or a trademark of Microsoft Corporation in the United States and/or
other countries.
User’s Manual U12688EJ4V0UM00
3
The export of these products from Japan is regulated by the Japanese government. The export of some or all of these
products may be prohibited without governmental license. To export or re-export some or all of these products from a
country other than Japan may also be prohibited without a license from that country. Please call an NEC sales
representative.
License not needed:
µPD703100, 703100A, 70F3102, 70F3102A
The customer must judge the need for license:
µPD703101, 703101A, 703102, 703102A
• The information in this document is subject to change without notice. Before using this document, please
confirm that this is the latest version.
• 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.
• Descriptions of circuits, software, and other related information in this document are provided for illustrative
purposes in semiconductor product operation and application examples. The incorporation of these circuits,
software, and information in the design of the customer's equipment shall be done under the full responsibility
of the customer. NEC Corporation assumes no responsibility for any losses incurred by the customer or third
parties arising from the use of these circuits, software, and information.
• 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, customers 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: Aircraft, aerospace equipment, submersible repeaters, nuclear reactor control systems, life
support systems or medical equipment for life support, etc.
The quality grade of NEC devices is "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 an NEC sales representative in advance.
M7 98. 8
4
User’s Manual U12688EJ4V0UM00
Regional Information
Some information contained in this document may vary from country to country. Before using any NEC
product in your application, pIease contact the NEC office in your country to obtain a list of authorized
representatives and distributors. They will verify:
•
Device availability
•
Ordering information
•
Product release schedule
•
Availability of related technical literature
•
Development environment specifications (for example, specifications for third-party tools and
components, host computers, power plugs, AC supply voltages, and so forth)
•
Network requirements
In addition, trademarks, registered trademarks, export restrictions, and other legal issues may also vary
from country to country.
NEC Electronics Inc. (U.S.)
NEC Electronics (Germany) GmbH
NEC Electronics Hong Kong Ltd.
Santa Clara, California
Tel: 408-588-6000
800-366-9782
Fax: 408-588-6130
800-729-9288
Benelux Office
Eindhoven, The Netherlands
Tel: 040-2445845
Fax: 040-2444580
Hong Kong
Tel: 2886-9318
Fax: 2886-9022/9044
NEC Electronics (France) S.A.
Velizy-Villacoublay, France
Tel: 01-30-67 58 00
Fax: 01-30-67 58 99
Seoul Branch
Seoul, Korea
Tel: 02-528-0303
Fax: 02-528-4411
NEC Electronics (France) S.A.
NEC Electronics Singapore Pte. Ltd.
Milton Keynes, UK
Tel: 01908-691-133
Fax: 01908-670-290
Spain Office
Madrid, Spain
Tel: 91-504-2787
Fax: 91-504-2860
United Square, Singapore 1130
Tel: 65-253-8311
Fax: 65-250-3583
NEC Electronics Italiana s.r.l.
NEC Electronics (Germany) GmbH
Milano, Italy
Tel: 02-66 75 41
Fax: 02-66 75 42 99
Scandinavia Office
Taeby, Sweden
Tel: 08-63 80 820
Fax: 08-63 80 388
NEC Electronics (Germany) GmbH
Duesseldorf, Germany
Tel: 0211-65 03 02
Fax: 0211-65 03 490
NEC Electronics (UK) Ltd.
NEC Electronics Hong Kong Ltd.
NEC Electronics Taiwan Ltd.
Taipei, Taiwan
Tel: 02-2719-2377
Fax: 02-2719-5951
NEC do Brasil S.A.
Electron Devices Division
Rodovia Presidente Dutra, Km 214
07210-902-Guarulhos-SP Brasil
Tel: 55-11-6465-6810
Fax: 55-11-6465-6829
J99.1
User’s Manual U12688EJ4V0UM00
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User’s Manual U12688EJ4V0UM00
Major Revisions in This Edition
Page
Description
p. 98
Change of R/W and bit units for manipulation for PMX and PMCX in 3.4.8 Peripheral I/O registers
p. 108
Addition of Caution to 4.5.2 (1) Bus size configuration register (BSC)
p. 151
Modification of WAIT signal in Figure 5-10 DRAM Access Timing During DMA Flyby Transfer
p. 172
Addition of interrupt factor (INTAD) to 6.3.6 DMA trigger factor registers 0 to 3 (DTFR0 to DTFR3)
p. 235
Deletion of part of explanation from 8.5.1 (3) (a) When in the PLL mode
p. 235
Deletion of 8.5.1 (3) (b) When in the Direct mode
p. 326
Modification of Figure 11-3 Select Mode Operation Timing: 1-Buffer Mode (ANI1)
p. 349
Change of block type of Port 2 in 12.2 (1) Function of each port
p. 355
Modification of Figure 12-3 Type C Block Diagram
p. 367
Addition of Figure 12-17 Type Q Block Diagram
p. 374
Change of block types of P22 and P25 in 12.3.3 (1) Operation in control mode
p. 375
Modification of Caution in 12.3.3 (2) (a) Port 2 mode register (PM2)
p. 378
Deletion of Caution from 12.3.4 (2) (a) Port 3 mode register (PM3)
p. 398
Deletion of Caution from 12.3.12 (2) (a) Port 11 mode register (PM11)
p. 407
Addition of Caution and modification of explanation in 12.3.16 (2) (a) Port X mode register (PMX)
p. 408
Addition of Caution and modification of explanation in 12.3.16 (2) (b) Port X mode control register (PMCX)
The mark
shows major revised points.
User’s Manual U12688EJ4V0UM00
7
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User’s Manual U12688EJ4V0UM00
INTRODUCTION
Readers
This manual is intended for users who wish to understand the functions of the
V850E/MS1 (µPD703100, 703100A, 703101, 703101A, 703102, 703102A, 70F3102,
70F3102A) to design application systems using the V850E/MS1.
Purpose
This manual is designed to help users understand the hardware functions of the
V850E/MS1.
Organization
The V850E/MS1 User’s Manual consists of two manuals: Hardware (this manual) and
Architecture (V850E/MS1 User’s Manual Architecture).
The organization of each
manual is as follows:
Hardware
Architecture
• Pin functions
• Data type
• CPU function
• Register set
• Internal peripheral functions
• Instruction format and instruction set
• Flash memory programming
• Interrupts and exceptions
• Pipeline operation
How to Read This Manual
It is assumed that the readers of this manual have general knowledge of electrical
engineering, logic circuits, and microcontrollers.
• To find the details of a register where the name is known
→ Refer to APPENDIX A REGISTER INDEX.
• To find the details of a function, etc. where the name is known
→ Refer to APPENDIX C INDEX.
• To understand the details of an instruction function
→ Refer to the V850E/MS1 User’s Manual Architecture.
• To understand the overall functions of the V850E/MS1
→ Read this manual in the order of the CONTENTS.
User’s Manual U12688EJ4V0UM00
9
Conventions
Data significance:
Higher digits on the left and lower digits on the right
Active low representation:
xxx (overscore over pin or signal name)
Memory map address:
Higher address on the top and lower address on the bottom
Note:
Footnote for item marked with Note in the text
Caution:
Information requiring particular attention
Remark:
Supplementary information
Numerical representation:
Binary ... xxxx or xxxxB
Decimal ... xxxx
Hexadecimal ... xxxxH
Prefix indicating power of 2
10
(address space, memory
K (kilo) ... 2 = 1,024
capacity):
M (mega) ... 2 = 1,024
20
30
G (giga) ... 2 = 1,024
Data type:
Word ... 32 bits
Halfword ... 16 bits
Byte ... 8 bits
10
User’s Manual U12688EJ4V0UM00
3
2
Related Documents
The related documents indicated in this publication may include preliminary versions.
However, preliminary versions are not marked as such.
Document related to device
Document Name
Document No.
µPD703100-33, 703100-40, 703101-33, 703102-33 Data Sheet
U13995E
µPD703100A-33, 703100A-40, 703101A-33, 703102A-33 Data Sheet
U14168E
µPD70F3102-33 Data Sheet
U13844E
µPD70F3102A-33 Data Sheet
U13845E
V850E/MS1 User’s Manual Hardware
This manual
V850E/MS1 User’s Manual Architecture
U12197E
V850E/MS1 Application Note Hardware
U14214E
Documents related to development tools (User’s Manuals)
Document Name
Document No.
IE-703102-MC (In-circuit Emulator)
U13875E
IE-703102-MC-EM1, IE-703102-MC-EM1-A (In-circuit Emulator Option
Board)
U13876E
CA850 (C Compiler Package)
Operation
U13998E
C Language
U13997E
Assembly Language
U13828E
Project Manager
U13996E
Basics
U13430E
Installation
U13410E
Fundamental
U13773E
Installation
U13774E
ID850 (Integrated Debugger)
(Ver.1.31)
Operation Windows™ Based
U13716E
ID850 (Integrated Debugger)
(Ver.2.00 or later)
Operation Windows Based
U14217E
SM850 (System Simulator)
(Ver.2.00 or later)
Operation Windows Based
U13759E
RX850 (Real-Time OS)
RX850 Pro (Real-Time OS)
Note
RD850
(Task Debugger)
U11158E
RD850 (Ver.3.0) (Task Debugger)
U13737E
RD850 Pro (Ver.3.0) (Task Debugger)
U13916E
AZ850 (System Performance Analyzer)
U14410E
PG-FP3 (Flash Memory Programmer)
U13502E
Note Supporting ID850 (Ver.1.32)
User’s Manual U12688EJ4V0UM00
11
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User’s Manual U12688EJ4V0UM00
CONTENTS
CHAPTER 1 INTRODUCTION................................................................................................................. 27
1.1 Outline ......................................................................................................................................... 27
1.2 Features....................................................................................................................................... 28
1.3 Applications ................................................................................................................................ 30
1.4 Ordering Information ................................................................................................................. 30
1.5 Pin Configuration (Top View) .................................................................................................... 31
1.6 Function Block ........................................................................................................................... 35
1.6.1
Internal block diagram ................................................................................................................... 35
1.6.2
Internal units .................................................................................................................................. 36
CHAPTER 2 PIN FUNCTIONS................................................................................................................. 39
2.1 List of Pin Functions.................................................................................................................. 39
2.2 Pin Status .................................................................................................................................... 47
2.3 Description of Pin Functions .................................................................................................... 49
2.4 Pin Input/Output Circuits and Recommended Connection of Unused Pins ........................ 65
2.5 Pin Input/Output Circuits........................................................................................................... 67
CHAPTER 3 CPU FUNCTION ................................................................................................................ 69
3.1 Features....................................................................................................................................... 69
3.2 CPU Register Set ........................................................................................................................ 70
3.3
3.4
3.2.1
Program register set ...................................................................................................................... 71
3.2.2
System register set........................................................................................................................ 72
Operation Modes ........................................................................................................................ 74
3.3.1
Operation modes ........................................................................................................................... 74
3.3.2
Operation mode specification ........................................................................................................ 75
Address Space............................................................................................................................ 76
3.4.1
CPU address space....................................................................................................................... 76
3.4.2
Image............................................................................................................................................. 77
3.4.3
Wrap-around of CPU address space............................................................................................. 78
3.4.4
Memory map.................................................................................................................................. 79
3.4.5
Area ............................................................................................................................................... 80
3.4.6
External expansion mode .............................................................................................................. 87
3.4.7
Recommended use of address space ........................................................................................... 89
3.4.8
Peripheral I/O registers.................................................................................................................. 92
3.4.9
Specific registers ......................................................................................................................... 100
CHAPTER 4 BUS CONTROL FUNCTION .......................................................................................... 103
4.1 Features..................................................................................................................................... 103
4.2 Bus Control Pins ...................................................................................................................... 103
4.3 Memory Block Function........................................................................................................... 104
4.4 Bus Cycle Type Control Function........................................................................................... 105
4.4.1
4.5
Bus cycle type configuration register (BCT) ................................................................................ 105
Bus Access ............................................................................................................................... 107
4.5.1
Number of access clocks............................................................................................................. 107
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13
4.6
4.5.2
Bus sizing function.......................................................................................................................108
4.5.3
Bus width .....................................................................................................................................109
Wait Function ............................................................................................................................ 113
4.6.1
4.7
4.8
Programmable wait function ........................................................................................................113
4.6.2
External wait function...................................................................................................................114
4.6.3
Relationship between programmable wait and external wait.......................................................114
4.6.4
Bus cycles in which the wait function is valid............................................................................ ...115
Idle State Insertion Function ................................................................................................... 117
Bus Hold Function.................................................................................................................... 119
4.8.1
Outline of function........................................................................................................................119
4.8.2
Bus hold procedure......................................................................................................................120
4.8.3
Operation in power save mode ....................................................................................................120
4.8.4
Bus hold timing ............................................................................................................................121
4.9 Bus Priority Order..................................................................................................................... 122
4.10 Boundary Operation Conditions ............................................................................................. 122
4.10.1
Program space ............................................................................................................................122
4.10.2
Data space...................................................................................................................................123
CHAPTER 5 MEMORY ACCESS CONTROL FUNCTION ................................................................. 125
5.1 SRAM, External ROM, External I/O Interface.......................................................................... 125
5.2
5.3
5.1.1
SRAM connections ......................................................................................................................125
5.1.2
SRAM, external ROM, external I/O access..................................................................................126
Page ROM Controller (ROMC) ................................................................................................. 130
5.2.1
Features.......................................................................................................................................130
5.2.2
Page ROM connections ...............................................................................................................130
5.2.3
On-page/off-page judgment .........................................................................................................132
5.2.4
Page ROM configuration register (PRC)......................................................................................134
5.2.5
Page ROM access .......................................................................................................................135
DRAM Controller....................................................................................................................... 136
5.3.1
Features.......................................................................................................................................136
5.3.2
DRAM connections ......................................................................................................................137
5.3.3
Address multiplex function...........................................................................................................138
5.3.4
DRAM configuration registers 0 to 3 (DRC0 to DRC3) ...............................................................139
5.3.5
DRAM type configuration register (DTC) .....................................................................................142
5.3.6
DRAM access ..............................................................................................................................143
5.3.7
DRAM access during DMA flyby transfer..................................................................................... 151
5.3.8
Refresh control function...............................................................................................................153
5.3.9
Self-refresh functions...................................................................................................................158
CHAPTER 6 DMA FUNCTIONS (DMA CONTROLLER).................................................................... 161
6.1 Features..................................................................................................................................... 161
6.2 Configuration ............................................................................................................................ 162
6.3 Control Registers...................................................................................................................... 163
14
6.3.1
DMA source address registers 0 to 3 (DSA0 to DSA3) ...............................................................163
6.3.2
DMA destination address registers 0 to 3 (DDA0 to DDA3) ........................................................165
6.3.3
DMA byte count registers 0 to 3 (DBC0 to DBC3) .......................................................................167
6.3.4
DMA addressing control registers 0 to 3 (DADC0 to DADC3) .....................................................168
6.3.5
DMA channel control registers 0 to 3 (DCHC0 to DCHC3)..........................................................170
User’s Manual U12688EJ4V0UM00
6.4
6.5
6.6
6.7
6.8
6.9
6.10
6.11
6.3.6
DMA trigger factor registers 0 to 3 (DTFR0 to DTFR3) ............................................................... 171
6.3.7
DMA disable status register (DDIS)............................................................................................. 173
6.3.8
DMA restart register (DRST) ....................................................................................................... 173
6.3.9
Flyby transfer data wait control register (FDW) ........................................................................... 174
DMA Bus States........................................................................................................................ 175
6.4.1
Types of bus states ..................................................................................................................... 175
6.4.2
DMAC state transition.................................................................................................................. 178
Transfer Mode........................................................................................................................... 179
6.5.1
Single transfer mode ................................................................................................................... 179
6.5.2
Single-step transfer mode ........................................................................................................... 180
6.5.3
Block transfer mode..................................................................................................................... 180
Transfer Types.......................................................................................................................... 181
6.6.1
Two-cycle transfer ....................................................................................................................... 181
6.6.2
Flyby transfer............................................................................................................................... 185
Transfer Objects ....................................................................................................................... 189
6.7.1
Transfer type and transfer objects............................................................................................... 189
6.7.2
External bus cycle during DMA transfer ...................................................................................... 189
DMA Channel Priorities............................................................................................................ 190
Next Address Setting Function............................................................................................... 190
DMA Transfer Start Factors..................................................................................................... 191
Interrupting DMA Transfer....................................................................................................... 192
6.11.1
Interruption factors....................................................................................................................... 192
6.11.2
Forcible interruption..................................................................................................................... 192
6.12 Terminating DMA Transfer ...................................................................................................... 192
6.13
6.14
6.15
6.16
6.17
6.18
6.19
6.12.1
DMA transfer end interrupt .......................................................................................................... 192
6.12.2
Terminal count output.................................................................................................................. 192
6.12.3
Forcible termination ..................................................................................................................... 193
Boundary of Memory Area ...................................................................................................... 194
Transfer of Misalign Data ........................................................................................................ 194
Clocks of DMA Transfer........................................................................................................... 194
Maximum Response Time to DMA Request .......................................................................... 194
One Time Single Transfer with DMARQ0 to DMARQ3.......................................................... 196
Bus Arbitration for CPU........................................................................................................... 197
Precaution ................................................................................................................................. 197
CHAPTER 7 INTERRUPT/EXCEPTION PROCESSING FUNCTION ................................................. 199
7.1 Features..................................................................................................................................... 199
7.2 Non-Maskable Interrupt ........................................................................................................... 204
7.3
7.2.1
Operation..................................................................................................................................... 205
7.2.2
Restore ........................................................................................................................................ 207
7.2.3
Non-maskable interrupt status flag (NP) ..................................................................................... 208
7.2.4
Noise elimination ......................................................................................................................... 208
7.2.5
Edge detection function ............................................................................................................... 208
Maskable Interrupts.................................................................................................................. 209
7.3.1
Operation..................................................................................................................................... 209
7.3.2
Restore ........................................................................................................................................ 211
7.3.3
Priorities of maskable interrupts .................................................................................................. 212
7.3.4
Interrupt control register (xxICn).................................................................................................. 216
User’s Manual U12688EJ4V0UM00
15
7.4
7.5
7.6
7.7
7.8
7.3.5
In-service priority register (ISPR).................................................................................................218
7.3.6
Maskable interrupt status flag (ID)...............................................................................................218
7.3.7
Noise elimination .........................................................................................................................219
7.3.8
Edge detection function ...............................................................................................................220
Software Exception .................................................................................................................. 222
7.4.1
Operation .....................................................................................................................................222
7.4.2
Restore ........................................................................................................................................223
7.4.3
Exception status flag (EP) ...........................................................................................................224
Exception Trap.......................................................................................................................... 225
7.5.1
Illegal op code definition ..............................................................................................................225
7.5.2
Operation .....................................................................................................................................226
7.5.3
Restore ........................................................................................................................................226
Multiple Interrupt Processing Control .................................................................................... 227
Interrupt Latency Time ............................................................................................................. 229
Periods in Which Interrupt Is Not Acknowledged ................................................................. 229
CHAPTER 8 CLOCK GENERATOR FUNCTIONS.............................................................................. 231
8.1 Features..................................................................................................................................... 231
8.2 Configuration ............................................................................................................................ 231
8.3 Input Clock Selection ............................................................................................................... 232
8.4
8.5
8.6
8.3.1
Direct mode .................................................................................................................................232
8.3.2
PLL mode ....................................................................................................................................232
8.3.3
Clock control register (CKC) ........................................................................................................233
PLL Lockup ............................................................................................................................... 234
Power Saving Control .............................................................................................................. 235
8.5.1
Outline .........................................................................................................................................235
8.5.2
Control registers ..........................................................................................................................237
8.5.3
HALT mode..................................................................................................................................238
8.5.4
IDLE mode ...................................................................................................................................240
8.5.5
Software STOP mode ..................................................................................................................242
8.5.6
Clock output inhibit mode ............................................................................................................243
Securing Oscillation Stabilization Time ................................................................................. 244
8.6.1
Specifying securing of oscillation stabilization time .....................................................................244
8.6.2
Time base counter (TBC).............................................................................................................246
CHAPTER 9 TIMER/COUNTER FUNCTION (REAL-TIME PULSE UNIT)........................................ 247
9.1 Features..................................................................................................................................... 247
9.2 Basic Configuration.................................................................................................................. 248
9.3
9.4
16
9.2.1
Timer 1.........................................................................................................................................251
9.2.2
Timer 4.........................................................................................................................................253
Control Registers...................................................................................................................... 254
Timer 1 Operation ..................................................................................................................... 262
9.4.1
Count operation ...........................................................................................................................262
9.4.2
Count clock selection...................................................................................................................263
9.4.3
Overflow.......................................................................................................................................264
9.4.4
Clearing/starting timer by TCLR1n signal input ...........................................................................265
9.4.5
Capture operation ........................................................................................................................266
9.4.6
Compare operation ......................................................................................................................269
User’s Manual U12688EJ4V0UM00
9.5
9.6
9.7
Timer 4 Operation..................................................................................................................... 271
9.5.1
Count operation ........................................................................................................................... 271
9.5.2
Count clock selection................................................................................................................... 271
9.5.3
Overflow ...................................................................................................................................... 271
9.5.4
Compare operation...................................................................................................................... 272
Application Example ................................................................................................................ 274
Precaution ................................................................................................................................. 281
CHAPTER 10 SERIAL INTERFACE FUNCTION ................................................................................ 283
10.1 Features..................................................................................................................................... 283
10.2 Asynchronous Serial Interfaces 0, 1 (UART0, UART1) ......................................................... 284
10.2.1
Features ...................................................................................................................................... 284
10.2.2
Configuration ............................................................................................................................... 285
10.2.3
Control registers .......................................................................................................................... 287
10.2.4
Interrupt request .......................................................................................................................... 294
10.2.5
Operation..................................................................................................................................... 295
10.3 Clocked Serial Interfaces 0 to 3 (CSI0 to CSI3) ..................................................................... 299
10.3.1
Features ...................................................................................................................................... 299
10.3.2
Configuration ............................................................................................................................... 299
10.3.3
Control registers .......................................................................................................................... 301
10.3.4
Basic operation............................................................................................................................ 304
10.3.5
Transmission by CSI0 to CSI3 .................................................................................................... 306
10.3.6
Reception by CSI0 to CSI3.......................................................................................................... 307
10.3.7
Transmission and reception by CSI0 to CSI3.............................................................................. 308
10.3.8
Example of system configuration................................................................................................. 309
10.4 Dedicated Baud Rate Generators 0 to 2 (BRG0 to BRG2)................................................... 310
10.4.1
Configuration and function........................................................................................................... 310
10.4.2
Baud rate generator compare registers 0 to 2 (BRGC0 to BRGC2) ............................................ 313
10.4.3
Baud rate generator prescaler mode registers 0 to 2 (BPRM0 to BPRM2) ................................. 314
CHAPTER 11 A/D CONVERTER.......................................................................................................... 315
11.1 Features..................................................................................................................................... 315
11.2 Configuration............................................................................................................................ 315
11.3 Control Registers ..................................................................................................................... 318
11.4 A/D Converter Operation ......................................................................................................... 323
11.4.1
Basic operation of A/D converter................................................................................................. 323
11.4.2
Operation mode and trigger mode............................................................................................... 324
11.5 Operation in A/D Trigger Mode ............................................................................................... 329
11.5.1
Select mode operations............................................................................................................... 329
11.5.2
Scan mode operations................................................................................................................. 331
11.6 Operation in Timer Trigger Mode............................................................................................ 332
11.6.1
Select mode operations............................................................................................................... 333
11.6.2
Scan mode operations................................................................................................................. 337
11.7 Operation in External Trigger Mode ....................................................................................... 341
11.7.1
Select mode operations (external trigger select) ......................................................................... 341
11.7.2
Scan mode operations (external trigger scan)............................................................................. 343
11.8 Operating Precautions............................................................................................................. 345
11.8.1
Stopping conversion operation .................................................................................................... 345
User’s Manual U12688EJ4V0UM00
17
11.8.2
External/timer trigger interval.......................................................................................................345
11.8.3
Operation of standby mode .........................................................................................................345
11.8.4
Compare match interrupt when in timer trigger mode..................................................................345
11.8.5
Timer 1 functions when in external trigger mode .........................................................................346
CHAPTER 12 PORT FUNCTIONS........................................................................................................ 347
12.1 Features..................................................................................................................................... 347
12.2 Port Configuration .................................................................................................................... 348
12.3 Port Pin Functions.................................................................................................................... 368
12.3.1
Port 0 ...........................................................................................................................................368
12.3.2
Port 1 ...........................................................................................................................................371
12.3.3
Port 2 ...........................................................................................................................................374
12.3.4
Port 3 ...........................................................................................................................................377
12.3.5
Port 4 ...........................................................................................................................................380
12.3.6
Port 5 ...........................................................................................................................................382
12.3.7
Port 6 ...........................................................................................................................................384
12.3.8
Port 7 ...........................................................................................................................................386
12.3.9
Port 8 ...........................................................................................................................................387
12.3.10 Port 9 ...........................................................................................................................................391
12.3.11 Port 10 .........................................................................................................................................394
12.3.12 Port 11 .........................................................................................................................................397
12.3.13 Port 12 .........................................................................................................................................401
12.3.14 Port A...........................................................................................................................................403
12.3.15 Port B...........................................................................................................................................405
12.3.16 Port X...........................................................................................................................................407
CHAPTER 13 RESET FUNCTIONS...................................................................................................... 409
13.1 Features..................................................................................................................................... 409
13.2 Pin Functions ............................................................................................................................ 409
13.3 Initialization ............................................................................................................................... 410
CHAPTER 14 FLASH MEMORY (µPD70F3102, 70F3102A) .............................................................. 413
14.1 Features..................................................................................................................................... 413
14.2 Writing by Flash Programmer ................................................................................................. 413
14.3 Programming Environment ..................................................................................................... 414
14.4 Communication System........................................................................................................... 414
14.5 Pin Handling.............................................................................................................................. 415
14.5.1
MODE3/VPP pin............................................................................................................................415
14.5.2
Serial interface pin .......................................................................................................................415
14.5.3
RESET pin ...................................................................................................................................417
14.5.4
NMI pin ........................................................................................................................................417
14.5.5
MODE0 to MODE2 pins ...............................................................................................................417
14.5.6
Port pin ........................................................................................................................................417
14.5.7
WAIT pin ......................................................................................................................................417
14.5.8
Other signal pins..........................................................................................................................417
14.5.9
Power supply ...............................................................................................................................418
14.6 Programming Method............................................................................................................... 418
14.6.1
18
Flash memory control ..................................................................................................................418
User’s Manual U12688EJ4V0UM00
14.6.2
Flash memory programming mode.............................................................................................. 419
14.6.3
Selection of communication mode............................................................................................... 419
14.6.4
Communication command ........................................................................................................... 420
APPENDIX A REGISTER INDEX.......................................................................................................... 423
APPENDIX B INSTRUCTION SET LIST.............................................................................................. 431
B.1 General Examples .................................................................................................................... 431
B.2 Instruction Set (in Alphabetical Order) .................................................................................. 434
APPENDIX C INDEX .............................................................................................................................. 441
User’s Manual U12688EJ4V0UM00
19
LIST OF FIGURES (1/4)
Figure No.
Title
Page
3-1
Program Counter (PC) ................................................................................................................................... 71
3-2
Interrupt Source Register (ECR).................................................................................................................... 72
3-3
Program Status Word (PSW)......................................................................................................................... 73
3-4
CPU Address Space...................................................................................................................................... 76
3-5
Image on Address Space .............................................................................................................................. 77
3-6
Internal ROM Area in Single-Chip Mode 1..................................................................................................... 84
3-7
Recommended Memory Map......................................................................................................................... 91
4-1
Example of Inserting Wait States................................................................................................................. 114
5-1
Example of Connection to SRAM ................................................................................................................ 125
5-2
SRAM, External ROM, External I/O Access Timing..................................................................................... 126
5-3
Example of Page ROM Connections ........................................................................................................... 130
5-4
On-Page/Off-Page Judgment for Page ROM Connection ........................................................................... 132
5-5
Page ROM Access Timing........................................................................................................................... 135
5-6
Examples of Connections to DRAM ............................................................................................................ 137
5-7
Row Address/Column Address Output ........................................................................................................ 138
5-8
High-Speed Page DRAM Access Timing..................................................................................................... 143
5-9
EDO DRAM Access Timing ......................................................................................................................... 147
5-10
DRAM Access Timing During DMA Flyby Transfer ..................................................................................... 151
5-11
CBR Refresh Timing.................................................................................................................................... 157
5-12
CBR Self-Refresh Timing ............................................................................................................................ 159
6-1
DMAC Bus Cycle State Transition Diagram ................................................................................................ 178
6-2
Single Transfer Example 1 .......................................................................................................................... 179
6-3
Single Transfer Example 2 .......................................................................................................................... 179
6-4
Single-Step Transfer Example 1.................................................................................................................. 180
6-5
Single-Step Transfer Example 2.................................................................................................................. 180
6-6
Block Transfer Example............................................................................................................................... 180
6-7
Timing of Two-Cycle Transfer...................................................................................................................... 181
6-8
Timing of Flyby Transfer (DRAM → External I/O)........................................................................................ 185
6-9
Timing of Flyby Transfer (Internal Peripheral I/O → Internal RAM) ............................................................. 188
6-10
Buffer Register Configuration ...................................................................................................................... 190
20
User’s Manual U12688EJ4V0UM00
LIST OF FIGURES (2/4)
Figure No.
Title
Page
6-11
Example of Forcible Termination of DMA Transfer ..................................................................................... 193
7-1
Block Diagram of Interrupt Control Function ............................................................................................... 203
7-2
Processing Configuration of Non-Maskable Interrupt.................................................................................. 205
7-3
Acknowledging Non-Maskable Interrupt Request ....................................................................................... 206
7-4
RETI Instruction Processing ........................................................................................................................ 207
7-5
Maskable Interrupt Processing .................................................................................................................... 210
7-6
RETI Instruction Processing ........................................................................................................................ 211
7-7
Example of Processing in Which Another Interrupt Request Is Issued While
Interrupt Is Being Processed ....................................................................................................................... 213
7-8
Example of Processing Interrupt Requests Simultaneously Generated...................................................... 215
7-9
Example of Noise Elimination Timing .......................................................................................................... 219
7-10
Software Exception Processing................................................................................................................... 222
7-11
RETI Instruction Processing ........................................................................................................................ 223
7-12
Exception Trap Processing ......................................................................................................................... 226
7-13
Pipeline Operation at Interrupt Request Acknowledgement (Outline) ......................................................... 229
8-1
Power Save Mode State Transition Diagram .............................................................................................. 236
9-1
Basic Operation of Timer 1.......................................................................................................................... 262
9-2
Operation after Overflow (If ECLR1n = 0 and OSTn = 1) ............................................................................ 264
9-3
Timer Clear/Start Operation by TCLR1n Signal Input (If ECLR1n = 1 and OSTn = 0)............................... 265
9-4
Relationship Between Clear/Start by TCLR1n Signal Input and Overflow Operation
(If ECLR1n = 1 and OSTn = 1) .................................................................................................................... 266
9-5
Example of Capture Operation .................................................................................................................... 267
9-6
Example of TM11 Capture Operation (When Both Edges Are Specified) ................................................... 268
9-7
Example of Compare Operation .................................................................................................................. 269
9-8
Example of TM11 Compare Operation (Set/Reset Output Mode) ............................................................... 270
9-9
Basic Operation of Timer 4.......................................................................................................................... 271
9-10
Example of TM40 Compare Operation ........................................................................................................ 272
9-11
Example of Timing in Interval Timer Operation ........................................................................................... 274
9-12
Example of Interval Timer Operation Setting Procedure ............................................................................. 274
9-13
Example of Pulse Measurement Timing...................................................................................................... 275
User’s Manual U12688EJ4V0UM00
21
LIST OF FIGURES (3/4)
Figure No.
Title
Page
9-14
Example of Pulse Width Measurement Setting Procedure .......................................................................... 276
9-15
Example of Interrupt Request Processing Routine Which Calculates the Pulse Width............................... 276
9-16
Example of PWM Output Timing.................................................................................................................. 277
9-17
Example of PWM Output Setting Procedure................................................................................................ 278
9-18
Example of Interrupt Request Processing Routine for Rewriting Compare Value....................................... 278
9-19
Example of Frequency Measurement Timing .............................................................................................. 279
9-20
Example of Frequency Measurement Setting Procedure ............................................................................ 280
9-21
Example of Interrupt Request Processing Routine Which Calculates the Frequency ................................. 280
10-1
Block Diagram of Asynchronous Serial Interface ........................................................................................ 286
10-2
Transmission/Reception Data Format of Asynchronous Serial Interface .................................................... 295
10-3
Asynchronous Serial Interface Transmission Completion Interrupt Timing ................................................. 296
10-4
Asynchronous Serial Interface Reception Complete Interrupt Timing ......................................................... 298
10-5
Receive Error Timing ................................................................................................................................... 298
10-6
Block Diagram of Clocked Serial Interface .................................................................................................. 300
10-7
Timing of 3-Wire Serial I/O Mode (Transmission)........................................................................................ 306
10-8
Timing of 3-Wire Serial I/O Mode (Reception) ............................................................................................. 307
10-9
Timing of 3-Wire Serial I/O Mode (Transmission/Reception)....................................................................... 309
10-10
Example of CSI System Configuration ........................................................................................................ 309
10-11
Block Diagram of Dedicated Baud Rate Generator ..................................................................................... 310
11-1
A/D Converter Block Diagram...................................................................................................................... 317
11-2
Relationship Between Analog Input Voltage and A/D Conversion Results ................................................. 322
11-3
Select Mode Operation Timing: 1-Buffer Mode (ANI1) ................................................................................ 326
11-4
Select Mode Operation Timing: 4-Buffer Mode (ANI6) ................................................................................ 327
11-5
Scan Mode Operation Timing: 4-Channel Scan (ANI0 to ANI3) .................................................................. 328
11-6
Example of 1-Buffer Mode (A/D Trigger Select 1-Buffer) Operation............................................................ 329
11-7
Example of 4-Buffer Mode (A/D Trigger Select 4-Buffer) Operation............................................................ 330
11-8
Example of Scan Mode (A/D Trigger Scan) Operation ................................................................................ 331
11-9
Example of 1-Trigger Mode (Timer Trigger Select 1-Buffer 1-Trigger) Operation ....................................... 333
11-10
Example of 4-Trigger Mode (Timer Trigger Select 1-Buffer 4-Trigger) Operation ....................................... 334
11-11
Example of 1-Trigger Mode (Timer Trigger Select 4-Buffer 1-Trigger) Operation ....................................... 335
11-12
Example of 4-Trigger Mode (Timer Trigger Select 4-Buffer 4-Trigger) Operation ....................................... 336
22
User’s Manual U12688EJ4V0UM00
LIST OF FIGURES (4/4)
Figure No.
Title
Page
11-13
Example of 1-Trigger Mode (Timer Trigger Scan 1-Trigger) Operation....................................................... 338
11-14
Example of 4-Trigger Mode (Timer Trigger Scan 4-Trigger) Operation....................................................... 340
11-15
Example of 1-Buffer Mode (External Trigger Select 1-Buffer) Operation .................................................... 341
11-16
Example of 4-Buffer Mode (External Trigger Select 4-Buffer) Operation .................................................... 342
11-17
Example of Scan Mode (External Trigger Scan) Operation ........................................................................ 344
11-18
Relationship of A/D Converter and Port, INTC and RPU............................................................................. 346
12-1
Type A Block Diagram................................................................................................................................. 353
12-2
Type B Block Diagram................................................................................................................................. 354
12-3
Type C Block Diagram................................................................................................................................. 355
12-4
Type D Block Diagram................................................................................................................................. 356
12-5
Type E Block Diagram................................................................................................................................. 357
12-6
Type F Block Diagram ................................................................................................................................. 358
12-7
Type G Block Diagram ................................................................................................................................ 358
12-8
Type H Block Diagram................................................................................................................................. 359
12-9
Type I Block Diagram .................................................................................................................................. 359
12-10
Type J Block Diagram ................................................................................................................................. 360
12-11
Type K Block Diagram................................................................................................................................. 361
12-12
Type L Block Diagram ................................................................................................................................. 362
12-13
Type M Block Diagram ................................................................................................................................ 363
12-14
Type N Block Diagram................................................................................................................................. 364
12-15
Type O Block Diagram ................................................................................................................................ 365
12-16
Type P Block Diagram................................................................................................................................. 366
12-17
Type Q Block Diagram ................................................................................................................................ 367
User’s Manual U12688EJ4V0UM00
23
LIST OF TABLES (1/2)
Table No.
Title
Page
3-1
Program Registers......................................................................................................................................... 71
3-2
System Register Numbers ............................................................................................................................. 72
3-3
Interrupt/Exception Table............................................................................................................................... 83
4-1
Bus Cycles in Which the Wait Function Is Valid .......................................................................................... 115
4-2
Bus Priority Order ........................................................................................................................................ 122
5-1
Example of DRAM and Address Multiplex Width......................................................................................... 138
5-2
Example of DRAM Refresh Interval ............................................................................................................. 155
5-3
Example of Interval Factor Settings............................................................................................................. 155
6-1
Relationship Between Transfer Type and Transfer Object.......................................................................... 189
6-2
External Bus Cycle During DMA Transfer ................................................................................................... 189
6-3
Minimum Execution Clock in DMA Cycle..................................................................................................... 194
6-4
DMAAKn Active → DMARQn Inactive Time for Single Transfer to External Memory ................................. 196
7-1
Interrupt List................................................................................................................................................. 200
7-2
Interrupt Control Register Addresses and Bits ............................................................................................ 216
8-1
Clock Generator Operation by Power Save Control .................................................................................... 236
8-2
Operating States When in HALT Mode ....................................................................................................... 238
8-3
Operations after HALT Mode Is Released by Interrupt Request ................................................................. 239
8-4
Operating States When in IDLE Mode......................................................................................................... 240
8-5
Operating States When in Software STOP Mode........................................................................................ 242
8-6
Example of Count Time ( φ = 5 × fXX)............................................................................................................ 246
9-1
RPU Configuration List ................................................................................................................................ 248
9-2
Capture Trigger Signals (TM1n) to 16-Bit Capture Registers ...................................................................... 266
9-3
Interrupt Request Signals (TM1n) from 16-Bit Compare Registers ............................................................. 269
10-1
Default Priority of Interrupt........................................................................................................................... 294
10-2
Baud Rate Generator Setup Values ............................................................................................................ 312
24
User’s Manual U12688EJ4V0UM00
LIST OF TABLES (2/2)
Table No.
Title
Page
13-1
Operating State of Each Pin During Reset .................................................................................................. 409
13-2
Initial Values of CPU, Internal RAM, and Internal Peripheral I/O after Reset .............................................. 411
14-1
List of Communication Modes ..................................................................................................................... 419
User’s Manual U12688EJ4V0UM00
25
[MEMO]
26
User’s Manual U12688EJ4V0UM00
CHAPTER 1 INTRODUCTION
The V850E/MS1 is one of NEC’s “V850 FamilyTM” of single-chip microcontrollers. This chapter gives a simple
outline of the V850E/MS1.
1.1
Outline
The V850E/MS1 is a 32-/16-bit single-chip microcontroller which uses the V850 Family’s “V850E” CPU, and
incorporates peripheral functions such as ROM, RAM, various types of memory controllers, a DMA controller, realtime pulse unit, serial interface and A/D converter, realizing large volume data processing and sophisticated real-time
control.
(1) “V850E” CPU included
The “V850E” CPU supports the RISC instruction set, and through the use of basic instructions, each of which
can be executed in 1 clock period, and an optimized pipeline, achieves a marked improvement in instruction
execution speed. In addition, in order to make it ideal for use in digital servo control, a 32-bit hardware
multiplier enables this CPU to support multiply instructions, saturated multiply instructions, bit operation
instructions, etc.
Also, through 2-byte basic instructions and instructions compatible with high level languages, etc., the object
code efficiency in a C compiler is increased, and the program size can be made more compact.
Further, since the on-chip interrupt controller provides a high speed interrupt response, including processing,
this device is suited to high level real-time control fields.
(2) External memory interface function
The V850E/MS1 features various on-chip external memory interfaces including separately address configured
(24 bits) and data (16 bits) buses, and SRAM and ROM interfaces, as well as on-chip memory controllers that
can be directly linked to EDO DRAM, high-speed page DRAM, page ROM, etc., thereby raising the system
performance and reducing the number of parts needed for application systems.
Also, through the DMA controller, CPU internal calculations and data transfers can be performed
simultaneously with transfers with external memory, so it is possible to process large volumes of image data or
voice data, etc., and through the high-speed execution of instructions using internal ROM and RAM, motor
control, communications control and other real-time control tasks can be realized simultaneously.
(3) On-chip flash memory (µPD70F3102, 70F3102A)
The on-chip flash memory model (µPD70F3102, 70F3102A) has on-chip flash memory which is capable of
high speed access, and since it is possible to rewrite a program with the V850E/MS1 mounted as is in the
application system, system development time can be reduced and system maintainability after shipping can be
markedly improved.
(4) A full range of middleware and development environment products
The V850E/MS1 can execute middleware such as JPEG, JBIG and MH/MR/MMR at high speed.
Also,
middleware that enables voice recognition, voice synthesis and other such processing is available; by
including these middleware programs, a multimedia system can be easily realized.
A development environment system that includes an optimized C compiler, debugger, in-circuit emulator,
simulator, system performance analyzer and other elements is also available.
User’s Manual U12688EJ4V0UM00
27
CHAPTER 1 INTRODUCTION
1.2
Features
{ Number of instructions:
81
{ Minimum instruction execution time:
25 ns (at internal 40 MHz) … µPD703100-40, 703100A-40
30 ns (at internal 33 MHz) … other than above
{ General registers:
32 bits × 32
{ Instruction set:
Upwardly compatible with V850 CPU
Signed multiplication (16 bits × 16 bits → 32 bits or 32 bits × 32 bits →
64 bits): 1 to 2 clocks
Saturated operation instructions (with overflow/underflow detection
function)
32-bit shift instructions: 1 clock
Bit manipulation instructions
Load/store instructions with long/short format
Signed load instructions
{ Memory space:
32 MB linear address space (common program/data use)
Chip select output function: 8 spaces
Memory block division function: 2, 4, 8 MB/block
Programmable wait function
Idle state insertion function
{ External bus interface:
16-bit data bus (address/data multiplexed)
16-/8-bit bus sizing function
Bus hold function
External wait function
{ Internal memory:
{ Interrupt/exception:
Part Number
Internal ROM
Internal RAM
µPD703100, 703100A
None
4 Kbytes
µPD703101, 703101A
96 Kbytes (Mask ROM)
4 Kbytes
µPD703102, 703102A
128 Kbytes (Mask ROM)
4 Kbytes
µPD70F3102, 70F3102A
128 Kbytes (Flash memory)
4 Kbytes
External interrupts: 25 (including NMI)
Internal interrupts: 47 sources
Exceptions:
1 source
Eight levels of priorities can be set.
{ Memory access controller:
DRAM controller (Compatible with EDO DRAM and high-speed page
DRAM)
Page-ROM controller
28
User’s Manual U12688EJ4V0UM00
CHAPTER 1 INTRODUCTION
{ DMA controller:
4 channels
Transfer units: 8 bits/16 bits
Maximum transfer count: 65,536 (216)
Transfer type: Flyby (1-cycle)/2-cycle
Transfer mode: Single/Single step/Block
DMA transfer terminate (terminal count) output signal
{ I/O lines:
{ Real-time pulse unit:
Input ports:
9
I/O ports:
114
16-bit timer/event counter: 6 channels
16-bit timers: 6
16-bit capture/compare registers: 24
16-bit interval timer: 2 channels
{ Serial interface:
Asynchronous serial interface (UART)
Clocked serial interface (CSI)
UART/CSI: 2 channels
CSI: 2 channels
Dedicated baud rate generator: 3 channels
{ A/D converter:
10-bit resolution A/D converter: 8 channels
{ Clock generator:
A multiply-by-five function via a PLL clock synthesizer.
A divide-by-two function via external clock input.
{ Power save function:
HALT/IDLE/software STOP mode
Clock output stop function
{ Package:
144-pin plastic LQFP: pin pitch 0.5 mm
{ CMOS technology:
All static circuits
User’s Manual U12688EJ4V0UM00
29
CHAPTER 1 INTRODUCTION
1.3
Applications
• OA devices (printers, facsimiles, PPCs, etc.)
• Multimedia devices (digital still cameras, video printers, etc.)
• Consumer appliances (single lens reflex cameras, etc.)
• Industrial devices (motor control, NC machine tools, etc.)
1.4
Ordering Information
Part Number
Package
µPD703100AF1-40-FA1
Note
Maximum Operating
On-chip
Frequency
ROM
157-pin plastic FBGA
HVDD
40 MHz
None
3.0 to 3.6 V
40 MHz
None
3.0 to 3.6 V
40 MHz
None
4.5 to 5.5 V
33 MHz
None
3.0 to 3.6 V
33 MHz
None
3.0 to 3.6 V
33 MHz
None
4.5 to 5.5 V
Mask ROM
3.0 to 3.6 V
(14 × 14 mm)
µPD703100AGJ-40-8EU
Note
144-pin plastic LQFP (Fine pitch)
(20 × 20 mm)
µPD703100GJ-40-8EU
Note
144-pin plastic LQFP (Fine pitch)
(20 × 20 mm)
µPD703100AF1-33-FA1
Note
157-pin plastic FBGA
(14 × 14 mm)
µPD703100AGJ-33-8EU
144-pin plastic LQFP (Fine pitch)
(20 × 20 mm)
µPD703100GJ-33-8EU
Note
144-pin plastic LQFP (Fine pitch)
(20 × 20 mm)
µPD703101AF1-33-×××-FA1
Note
157-pin plastic FBGA
33 MHz
(14 × 14 mm)
µPD703101AGJ-33-×××-8EU
144-pin plastic LQFP (Fine pitch)
(96 KB)
33 MHz
(20 × 20 mm)
µPD703101GJ-33-×××-8EU
Note
144-pin plastic LQFP (Fine pitch)
33 MHz
(20 × 20 mm)
µPD703102AF1-33-×××-FA1
Note
157-pin plastic FBGA
144-pin plastic LQFP (Fine pitch)
33 MHz
Note
144-pin plastic LQFP (Fine pitch)
33 MHz
Note
157-pin plastic FBGA
33 MHz
Note
144-pin plastic LQFP (Fine pitch)
33 MHz
Note
144-pin plastic LQFP (Fine pitch)
33 MHz
33 MHz
Note Under development
30
Mask ROM
3.0 to 3.6 V
Mask ROM
4.5 to 5.5 V
Flash memory 3.0 to 3.6 V
Flash memory 3.0 to 3.6 V
(128 KB)
(20 × 20 mm)
Remark
3.0 to 3.6 V
(128 KB)
(20 × 20 mm)
µPD70F3102GJ-33-8EU
Mask ROM
(128 KB)
(14 × 14 mm)
µPD70F3102AGJ-33-8EU
4.5 to 5.5 V
(128 KB)
(20 × 20 mm)
µPD70F3102AF1-33-FA1
Mask ROM
(128 KB)
(20 × 20 mm)
µPD703102GJ-33-×××-8EU
3.0 to 3.6 V
(96 KB)
(14 × 14 mm)
µPD703102AGJ-33-×××-8EU
Mask ROM
(96 KB)
××× indicates ROM code suffix.
User’s Manual U12688EJ4V0UM00
Flash memory 4.5 to 5.5 V
(128 KB)
CHAPTER 1 INTRODUCTION
1.5
Pin Configuration (Top View)
157-pin plastic FBGA (14 × 14 mm)
• µPD703100AF1-40-FA1
• µPD703100AF1-33-FA1
• µPD703101AF1-33-×××-FA1
• µPD703102AF1-33-×××-FA1
• µPD70F3102AF1-33-FA1
Top View
Bottom View
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
A B C D E F G H J K L M N P R T
T R P N M L K J H G F E D C B A
Index mark
Index mark
(1/2)
Pin
Number
Pin Name
Pin
Number
Pin Name
Pin
Number
Pin Name
A1
—
B1
INTP103/DMARQ3/P07
C1
INTP101/DMARQ1/P05
A2
D0/P40
B2
D1/P41
C2
INTP102/DMARQ2/P06
A3
D2/P42
B3
D3/P43
C3
VSS
A4
D4/P44
B4
D5/P45
C4
VSS
A5
D6/P46
B5
D7/P47
C5
HVDD
A6
D8/P50
B6
D9/P51
C6
VSS
A7
D10/P52
B7
D11/P53
C7
D12/P54
A8
D13/P55
B8
D14/P56
C8
D15/P57
A9
A0/PA0
B9
A1/PA1
C9
HVDD
A10
A2/PA2
B10
A3/PA3
C10
A4/PA4
A11
A5/PA5
B11
A6/PA6
C11
A7/PA7
A12
A8/PB0
B12
A9/PB1
C12
VSS
A13
A10/PB2
B13
A11/PB3
C13
A12/PB4
A14
A13/PB5
B14
A14/PB6
C14
A18/P62
A15
A15/PB7
B15
A17/P61
C15
A19/P63
A16
—
B16
A16/P60
C16
—
User’s Manual U12688EJ4V0UM00
31
CHAPTER 1 INTRODUCTION
(2/2)
Pin
Number
Pin Name
Pin
Number
Pin Name
Pin
Number
Pin Name
D1
TI10/P03
K1
TI12/P103
P14
RESET
D2
INTP100/DMARQ0/P04
K2
INTP120/TC0/P104
P15
INTP151/P125
D3
HVDD
K3
INTP121/TC1/P105
P16
INTP150/P124
D4
—
K14
HLDAK/P96
R1
AVSS
D14
VSS
K15
OE/P95
R2
ANI0/P70
D15
A21/P65
K16
BCYST/P94
R3
P21
D16
A20/P64
L1
TO120/P100
R4
SCK0/P24
E1
TO101/P01
L2
TO121/P101
R5
SCK1/P27
E2
TCLR10/P02
L3
TCLR12/P102
R6
INTP132/SI2/P36
E3
VSS
L14
VSS
R7
TI13/P33
E14
HVDD
L15
REFRQ/PX5
R8
TO130/P30
E15
A23/P67
L16
HLDRQ/P97
R9
INTP141/SO3/P115
E16
A22/P66
M1
ANI5/P75
R10
TCLR14/P112
F1
INTP113/DMAAK3/P17
M2
ANI6/P76
R11
TO140/P110
F2
TO100/P00
M3
ANI7/P77
R12
MODE0
F3
VDD
M14
TO150/P120
R13
MODE1
F14
CS2/RAS2/P82
M15
WAIT/PX6
R14
MODE2
F15
CS1/RAS1/P81
M16
CLKOUT/PX7
R15
INTP153/ADTRG/P127
F16
CS0/RAS0/P80
N1
ANI2/P72
R16
INTP152/P126
G1
INTP110/DMAAK0/P14
N2
ANI3/P73
T1
—
G2
INTP111/DMAAK1/P15
N3
ANI4/P74
T2
AVREF
G3
INTP112/DMAAK2/P16
N14
TI15/P123
T3
NMI/P20
G14
CS5/RAS5/IORD/P85
N15
TCLR15/P122
T4
RXD0/SI0/P23
G15
CS4/RAS4/IOWR/P84
N16
TO151/P121
T5
RXD1/SI1/P26
G16
CS3/RAS3/P83
P1
AVDD
T6
INTP131/SO2/P35
H1
TO111/P11
P2
ANI1/P71
T7
TCLR13/P32
H2
TCLR11/P12
P3
TXD0/SO0/P22
T8
INTP143/SCK3/P117
H3
TI11/P13
P4
TXD1/SO1/P25
T9
INTP140/P114
H14
LCAS/LWR/P90
P5
VDD
T10
CVDD
H15
CS7/RAS7/P87
P6
INTP133/SCK2/P37
T11
X2
H16
CS6/RAS6/P86
P7
INTP130/P34
T12
X1
J1
INTP122/TC2/P106
P8
TO131/P31
T13
CVSS
J2
INTP123/TC3/P107
P9
INTP142/SI3/P116
T14
MODE3 (MODE3/VPP)
J3
TO110/P10
P10
TI14/P113
T15
—
J14
WE/P93
P11
TO141/P111
T16
—
J15
RD/P92
P12
CKSEL
—
—
J16
UCAS/UWR/P91
P13
HVDD
—
—
Remarks 1. Leave the A1, A16, C16, D4, T1, T15, and T16 pins open.
2. Items in parentheses are pin names in the µPD70F3102, 70F3102A.
32
User’s Manual U12688EJ4V0UM00
CHAPTER 1 INTRODUCTION
144-pin plastic LQFP (fine pitch) (20 × 20 mm)
• µPD703100GJ-40-8EU, 703100AGJ-40-8EU
• µPD703100GJ-33-8EU, 703100AGJ-33-8EU
• µPD703101GJ-33-×××-8EU, 703101AGJ-33-×××-8EU
• µPD703102GJ-33-×××-8EU, 703102AGJ-33-×××-8EU
144
143
142
141
140
139
138
137
136
135
134
133
132
131
130
129
128
127
126
125
124
123
122
121
120
119
118
117
116
115
114
113
112
111
110
109
VDD
D0/P40
D1/P41
D2/P42
D3/P43
D4/P44
D5/P45
D6/P46
D7/P47
VSS
D8/P50
D9/P51
D10/P52
D11/P53
D12/P54
D13/P55
D14/P56
D15/P57
HVDD
A0/PA0
A1/PA1
A2/PA2
A3/PA3
A4/PA4
A5/PA5
A6/PA6
A7/PA7
VSS
A8/PB0
A9/PB1
A10/PB2
A11/PB3
A12/PB4
A13/PB5
A14/PB6
A15/PB7
• µPD70F3102GJ-33-8EU, 70F3102AGJ-33-8EU
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
108
107
106
105
104
103
102
101
100
99
98
97
96
95
94
93
92
91
90
89
88
87
86
85
84
83
82
81
80
79
78
77
76
75
74
73
A16/P60
A17/P61
A18/P62
A19/P63
A20/P64
A21/P65
A22/P66
A23/P67
HVDD
CS0/RAS0/P80
CS1/RAS1/P81
CS2/RAS2/P82
CS3/RAS3/P83
CS4/RAS4/IOWR/P84
CS5/RAS5/IORD/P85
CS6/RAS6/P86
CS7/RAS7/P87
LCAS/LWR/P90
UCAS/UWR/P91
RD/P92
WE/P93
BCYST/P94
OE/P95
HLDAK/P96
HLDRQ/P97
VSS
REFRQ/PX5
WAIT/PX6
CLKOUT/PX7
TO150/P120
TO151/P121
TCLR15/P122
TI15/P123
INTP150/P124
INTP151/P125
INTP152/P126
NMI/P20
P21
TXD0/SO0/P22
RXD0/SI0/P23
SCK0/P24
TXD1/SO1/P25
RXD1/SI1/P26
SCK1/P27
VDD
INTP133/SCK2/P37
INTP132/SI2/P36
INTP131/SO2/P35
INTP130/P34
TI13/P33
TCLR13/P32
TO131/P31
TO130/P30
INTP143/SCK3/P117
INTP142/SI3/P116
INTP141/SO3/P115
INTP140/P114
TI14/P113
TCLR14/P112
TO141/P111
TO140/P110
CVDD
X2
X1
CVSS
CKSEL
MODE0
MODE1
MODE2
MODE3 (MODE3/VPP)
RESET
INTP153/ADTRG/P127
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
INTP103/DMARQ3/P07
INTP102/DMARQ2/P06
INTP101/DMARQ1/P05
INTP100/DMARQ0/P04
TI10/P03
TCLR10/P02
TO101/P01
TO100/P00
VSS
INTP113/DMAAK3/P17
INTP112/DMAAK2/P16
INTP111/DMAAK1/P15
INTP110/DMAAK0/P14
TI11/P13
TCLR11/P12
TO111/P11
TO110/P10
INTP123/TC3/P107
INTP122/TC2/P106
INTP121/TC1/P105
INTP120/TC0/P104
TI12/P103
TCLR12/P102
TO121/P101
TO120/P100
ANI7/P77
ANI6/P76
ANI5/P75
ANI4/P74
ANI3/P73
ANI2/P72
ANI1/P71
ANI0/P70
AVDD
AVSS
AVREF
Remark
Items in parentheses are pin names in the µPD70F3102, 70F3102A.
User’s Manual U12688EJ4V0UM00
33
CHAPTER 1 INTRODUCTION
Pin Name
A0 to A23:
Address Bus
P60 to P67:
Port 6
ADTRG:
AD Trigger Input
P70 to P77:
Port 7
ANI0 to ANI7:
Analog Input
P80 to P87:
Port 8
AVDD:
Analog Power Supply
P90 to P97:
Port 9
AVREF:
Analog Reference Voltage
P100 to P107:
Port 10
AVSS:
Analog Ground
P110 to P117:
Port 11
BCYST:
Bus Cycle Start Timing
P120 to P127:
Port 12
CKSEL:
Clock Generator Operating Mode Select PA0 to PA7:
Port A
CLKOUT:
Clock Output
PB0 to PB7:
Port B
CS0 to CS7:
Chip Select
PX5 to PX7:
Port X
CVDD:
Clock Generator Power Supply
RAS0 to RAS7:
Row Address Strobe
CVSS:
Clock Generator Ground
RD:
Read
D0 to D15:
Data Bus
REFRQ:
Refresh Request
DMAAK0 to DMAAK3:
DMA Acknowledge
RESET:
Reset
DMARQ0 to DMARQ3: DMA Request
RXD0, RXD1:
Receive Data
HLDAK:
Hold Acknowledge
SCK0 to SCK3:
Serial Clock
HLDRQ:
Hold Request
SI0 to SI3:
Serial Input
HVDD:
Power Supply for External Pins
SO0 to SO3:
Serial Output
INTP100 to INTP103,
TC0 to TC3:
Terminal Count Signal
INTP110 to INTP113,
TCLR10 to TCLR15: Timer Clear
INTP120 to INTP123,
TI10 to TI15:
INTP130 to INTP133,
TO100, TO101,
INTP140 to INTP143,
Timer Input
TO110, TO111,
INTP150 to INTP153:
Interrupt Request from Peripherals
TO120, TO121,
IORD:
I/O Read Strobe
TO130, TO131,
IOWR:
I/O Write Strobe
TO140, TO141,
LCAS:
Lower Column Address Strobe
TO150, TO151:
Timer Output
LWR:
Lower Write Strobe
TXD0, TXD1:
Transmit Data
MODE0 to MODE3:
Mode
UCAS:
Upper Column Address Strobe
NMI:
Non-Maskable Interrupt Request
UWR:
Upper Write Strobe
OE:
Output Enable
VDD:
Power Supply for Internal Unit
P00 to P07:
Port 0
VPP:
Programming Power Supply
P10 to P17:
Port 1
VSS:
Ground
P20 to P27:
Port 2
WAIT:
Wait
P30 to P37:
Port 3
WE:
Write Enable
P40 to P47:
Port 4
X1, X2:
Crystal
P50 to P57:
Port 5
34
User’s Manual U12688EJ4V0UM00
CHAPTER 1 INTRODUCTION
1.6
Function Block
1.6.1 Internal block diagram
ROM
NMI
INTP100 to INTP103
INTP110 to INTP113
INTP120 to INTP123
INTP130 to INTP133
INTP140 to INTP143
INTP150 to INTP153
TO100, TO101
TO110, TO111
TO120, TO121
TO130, TO131
TO140, TO141
TO150, TO151
TCLR10 to TCLR15
TI10 to TI15
INTC
Note
CPU
Instruction
queue
BCU
DRAMC
Multiplier
(32 × 32 → 64)
PC
Barrel
shifter
System
register
RPU
Page ROM
controller
RAM
4
Kbytes
General
registers
(32 bits × 32)
ALU
DMAC
SIO
SO0/TXD0
SI0/RXD0
SCK0
HLDRQ
HLDAK
CS0 to CS7/RAS0 to RAS7
IOWR
IORD
REFRQ
BCYST
WE
RD
OE
UWR/UCAS
LWR/LCAS
WAIT
A0 to A23
D0 to D15
DMARQ0 to DMARQ3
DMAAK0 to DMAAK3
TC0 to TC3
UART0/CSI0
BRG0
SO1/TXD1
SI1/RXD1
SCK1
UART1/CSI1
Ports
CG
SO2
SI2
SCK2
PX5 to PX7
PB0 to PB7
PA0 to PA7
P120 to P127
P110 to P117
P100 to P107
P90 to P97
P80 to P87
P70 to P77
P60 to P67
P50 to P57
P40 to P47
P30 to P37
P21 to P27
P20
P10 to P17
P00 to P07
HVDD
BRG1
CSI2
BRG2
SO3
SI3
SCK3
ANI0 to ANI7
AVREF
AVSS
AVDD
ADTRG
System
controller
CKSEL
CLKOUT
X1
X2
CVDD
CVSS
MODE0 to MODE3
RESET
VPP
CSI3
VDD
VSS
ADC
Note µPD703100, 703100A:
None
µPD703101, 703101A:
96 Kbytes (Mask ROM)
µPD703102, 703102A:
128 Kbytes (Mask ROM)
µPD70F3102, 70F3102A: 128 Kbytes (Flash memory)
User’s Manual U12688EJ4V0UM00
35
CHAPTER 1 INTRODUCTION
1.6.2 Internal units
(1) CPU
The CPU uses five-stage pipeline control to enable single-clock execution of address calculations, arithmetic
logic operations, data transfers, and almost all other instruction processing.
Other dedicated on-chip hardware, such as a multiplier (16 bits × 16 bits → 32 bits or 32 bits × 32 bits → 64
bits) and a barrel shifter (32 bits), help accelerate processing of complex instructions.
(2) Bus control unit (BCU)
The BCU starts a required external bus cycle based on the physical address obtained by the CPU. When an
instruction is fetched from external memory space and the CPU does not send a bus cycle start request, the
BCU generates a prefetch address and prefetches the instruction code. The prefetched instruction code is
stored in an instruction queue in the CPU.
The BCU incorporates a DRAM controller (DRAMC), page ROM controller, and DMA controller (DMAC).
(a) DRAM controller (DRAMC)
This controller generates the RAS, UCAS and LCAS signals (2CAS control) and controls DRAM access.
It is compatible with high-speed DRAM and EDO DRAM. When accessing DRAM, there are 2 types of
cycle; normal access (off page) and page access (on page).
Also, it includes a refresh function that is compatible with the CBR refresh cycle.
(b) Page ROM controller
This controller is compatible with ROM that includes a page access function.
It performs address comparisons with the immediately preceding bus cycle and executes wait control for
normal access (off page)/page access (on page). It can handle page widths of 8 to 64 bytes.
(c) DMA controller (DMAC)
This controller transfers data between memory and I/O in place of the CPU.
There are two address modes, flyby (1 cycle) transfer, and 2-cycle transfer. There are three bus modes,
single transfer, single step transfer, and block transfer.
(3) ROM
The µPD703101 and 703101A have on-chip mask ROM (96 KB), the µPD703102 and 703102A have on-chip
mask ROM (128 KB), and the µPD70F3102 and 70F3102A have on-chip flash memory (128 KB).
The
µPD703100 and 703100A do not include on-chip memory.
During instruction fetch, these memories can be accessed from the CPU in 1 clock cycles.
If the single-chip mode 0 or flash memory programming mode is set, memory mapping is done from address
00000000H, and if single-chip mode 1 is set, from address 00100000H. If ROM-less mode 0 or 1 is set,
access is impossible.
(4) RAM
4 KB of RAM is mapped from address FFFFE000H. During instruction fetch, data can be accessed from the
CPU in 1-clock cycles.
36
User’s Manual U12688EJ4V0UM00
CHAPTER 1 INTRODUCTION
(5) Interrupt controller (INTC)
This controller handles hardware interrupt requests (NMI, INTP100 to INTP103, INTP110 to INTP113,
INTP120 to INTP123, INTP130 to INTP133, INTP140 to INTP143, INTP150 to INTP153) from internal
peripheral I/O and external hardware. Eight levels of interrupt priorities can be specified for these interrupt
requests, and multiplexed servicing control can be performed for interrupt sources.
(6) Clock generator (CG)
This clock generator supplies frequencies that are 5 times the input clock (fxx) (used by the internal PLL) and
1/2 the input clock (when the internal PLL is not used) as an internal system clock (φ). As the input clock, an
external oscillator is connected to pins X1 and X2 (only when an internal PLL synthesizer is used) or an
external clock is input from pin X1.
(7) Real-time pulse unit (RPU)
This unit has a 6-channel 16-bit timer/event counter and 2-channel 16-bit interval timer on-chip, and it is
possible to measure pulse widths or frequency and to output a programmable pulse.
(8) Serial interface (SIO)
The serial interface has a total of 4 channels of asynchronous serial interfaces (UART) and synchronous or
clocked serial interfaces (CSI). Two of these channels can be switched between UART and CSI, and the
other two channels are fixed to CSI.
UART transfers data by using the TXD and RXD pins and the CSI transfers data by using the SO, SI, and SCK
pins.
The serial clock source can be selected from dedicated baud rate generator output or internal system clock.
(9) A/D converter (ADC)
This high-speed, high-resolution 10-bit A/D converter includes 8 analog input pins. Conversion uses the
successive approximation method.
User’s Manual U12688EJ4V0UM00
37
CHAPTER 1 INTRODUCTION
(10) Ports
As shown below, the following ports have general port functions and control pin functions.
Port
38
Port Function
Control Function
Port 0
8-bit I/O
Real-time pulse unit input/output, external interrupt input, DMA controller input
Port 1
8-bit I/O
Real-time pulse unit input/output, external interrupt input, DMA controller output
Port 2
1-bit input,
7-bit I/O
NMI input, serial interface input/output
Port 3
8-bit I/O
Real-time pulse unit input/output, external interrupt input, serial interface input/output
Port 4
8-bit I/O
External data bus
Port 5
8-bit I/O
External data bus
Port 6
8-bit I/O
External address bus
Port 7
8-bit input
A/D converter input
Port 8
8-bit I/O
External bus interface control signal output
Port 9
8-bit I/O
External bus interface control signal input/output
Port 10
8-bit I/O
Real-time pulse unit input/output, external interrupt input, DMA controller output
Port 11
8-bit I/O
Real-time pulse unit input/output, external interrupt input, serial interface input/output
Port 12
8-bit I/O
Real-time pulse unit input/output, external interrupt input, A/D converter external trigger
input
Port A
8-bit I/O
External address bus
Port B
8-bit I/O
External address bus
Port X
3-bit I/O
Refresh request signal output, wait insertion signal input, internal system clock output
User’s Manual U12688EJ4V0UM00
CHAPTER 2 PIN FUNCTIONS
The names and functions of this product’s pins are listed below. These pins can be divided into port pins and nonport pins according to their functions.
2.1
List of Pin Functions
(1) Port pins (1/4)
Pin Name
P00
I/O
I/O
P01
Function
Port 0
8-bit input/output port
Input/output mode can be specified in 1-bit units.
Alternate Function
TO100
TO101
P02
TCLR10
P03
TI10
P04
INTP100/DMARQ0
P05
INTP101/DMARQ1
P06
INTP102/DMARQ2
P07
INTP103/DMARQ3
P10
I/O
P11
Port 1
8-bit input/output port
Input/output mode can be specified in 1-bit units.
TO110
TO111
P12
TCLR11
P13
TI11
P14
INTP110/DMAAK0
P15
INTP111/DMAAK1
P16
INTP112/DMAAK2
P17
INTP113/DMAAK3
P20
Input
P21
I/O
P22
P23
P24
Port 2
P20 is an input-only port.
If a valid edge is input, it operates as an NMI input. Also, the
status of the NMI input is shown by bit 0 of the P2 register.
P21 to P27 are 7-bit input/output ports.
Input/output mode can be specified in 1-bit units.
NMI
TXD0/SO0
RXD0/SI0
SCK0
P25
TXD1/SO1
P26
RXD1/SI1
P27
SCK1
User’s Manual U12688EJ4V0UM00
39
CHAPTER 2 PIN FUNCTIONS
(1) Port pins (2/4)
Pin Name
P30
I/O
I/O
P31
Function
Port 3
8-bit input/output port
Input/output mode can be specified in 1-bit units.
Alternate Function
TO130
TO131
P32
TCLR13
P33
TI13
P34
INTP130
P35
INTP131/SO2
P36
INTP132/SI2
P37
INTP133/SCK2
P40 to P47
I/O
Port 4
8-bit input/output port
Input/output mode can be specified in 1-bit units.
D0 to D7
P50 to P57
I/O
Port 5
8-bit input/output port
Input/output mode can be specified in 1-bit units.
D8 to D15
P60 to P67
I/O
Port 6
8-bit input/output port
Input/output mode can be specified in 1-bit units.
A16 to A23
P70 to P77
Input
Port 7
8-bit input only port
ANI0 to ANI7
Port 8
8-bit input/output port
Input/output mode can be specified in 1-bit units.
CS0/RAS0
P80
I/O
P81
CS1/RAS1
P82
CS2/RAS2
P83
CS3/RAS3
P84
CS4/RAS4/IOWR
P85
CS5/RAS5/IORD
P86
CS6/RAS6
P87
CS7/RAS7
P90
P91
I/O
Port 9
8-bit input/output port
Input/output mode can be specified in 1-bit units.
LCAS/LWR
UCAS/UWR
P92
RD
P93
WE
P94
BCYST
P95
OE
P96
HLDAK
P97
HLDRQ
40
User’s Manual U12688EJ4V0UM00
CHAPTER 2 PIN FUNCTIONS
(1) Port pins (3/4)
Pin Name
P100
I/O
I/O
P101
Function
Port 10
8-bit input/output port
Input/output mode can be specified in 1-bit units.
Alternate Function
TO120
TO121
P102
TCLR12
P103
TI12
P104
INTP120/TC0
P105
INTP121/TC1
P106
INTP122/TC2
P107
INTP123/TC3
P110
I/O
P111
Port 11
8-bit input/output port
Input/output mode can be specified in 1-bit units.
TO140
TO141
P112
TCLR14
P113
TI14
P114
INTP140
P115
INTP141/SO3
P116
INTP142/SI3
P117
INTP143/SCK3
P120
I/O
P121
Port 12
8-bit input/output port
Input/output mode can be specified in 1-bit units.
TO150
TO151
P122
TCLR15
P123
TI15
P124
INTP150
P125
INTP151
P126
INTP152
P127
INTP153/ADTRG
PA0
PA1
I/O
Port A
8-bit input/output port
Input/output mode can be specified in 1-bit units.
A0
A1
PA2
A2
PA3
A3
PA4
A4
PA5
A5
PA6
A6
PA7
A7
User’s Manual U12688EJ4V0UM00
41
CHAPTER 2 PIN FUNCTIONS
(1) Port pins (4/4)
Pin Name
PB0
I/O
I/O
PB1
Function
Port B
8-bit input/out port
Input/output mode can be specified in 1-bit units.
Alternate Function
A8
A9
PB2
A10
PB3
A11
PB4
A12
PB5
A13
PB6
A14
PB7
A15
PX5
PX6
I/O
Port X
3-bit input/output port
Input/output mode can be specified in 1-bit units.
WAIT
CLKOUT
PX7
42
REFRQ
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CHAPTER 2 PIN FUNCTIONS
(2) Non-port pins (1/4)
Pin Name
TO100
I/O
Output
Function
Pulse signal output of timers 10 to 15
Alternate Function
P00
TO101
P01
TO110
P10
TO111
P11
TO120
P100
TO121
P101
TO130
P30
TO131
P31
TO140
P110
TO141
P111
TO150
P120
TO151
P121
TCLR10
Input
External clear signal input of timers 10 to 15
P02
TCLR11
P12
TCLR12
P102
TCLR13
P32
TCLR14
P112
TCLR15
P122
TI10
Input
External count clock input of timers 10 to 15
P03
TI11
P13
TI12
P103
TI13
P33
TI14
P113
TI15
P123
INTP100
Input
INTP101
External maskable interrupt request input, or timer 10 external
capture trigger input
P04/DMARQ0
P05/DMARQ1
INTP102
P06/DMARQ2
INTP103
P07/DMARQ3
INTP110
Input
INTP111
External maskable interrupt request input, or timer 11 external
capture trigger input
P14/DMAAK0
P15/DMAAK1
INTP112
P16/DMAAK2
INTP113
P17/DMAAK3
INTP120
INTP121
Input
External maskable interrupt request input, or timer 12 external
capture trigger input
P104/TC0
P105/TC1
INTP122
P106/TC2
INTP123
P107/TC3
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CHAPTER 2 PIN FUNCTIONS
(2) Non-port pins (2/4)
Pin Name
INTP130
I/O
Input
INTP131
Function
External maskable interrupt request input, or timer 13 external
capture trigger input
Alternate Function
P34
P35/SO2
INTP132
P36/SI2
INTP133
P37/SCK2
INTP140
Input
INTP141
External maskable interrupt request input, or timer 14 external
capture trigger input
P114
P115/SO3
INTP142
P116/SI3
INTP143
P117/SCK3
INTP150
Input
INTP151
External maskable interrupt request input, or timer 15 external
capture trigger input
P124
P125
INTP152
P126
INTP153
P127/ADTRG
SO0
Input
CSI0 to CSI3 serial transmission data output (3-wire)
P22/TXD0
SO1
P25/TXD1
SO2
P35/INTP131
SO3
P115/INTP141
SI0
Input
CSI0 to CSI3 serial reception data input (3-wire)
P23/RXD0
SI1
P26/RXD1
SI2
P36/INTP132
SI3
P116/INTP142
SCK0
I/O
CSI0 to CSI3 serial clock input/output (3-wire)
P24
SCK1
P27
SCK2
P37/INTP133
SCK3
P117/INTP143
TXD0
Output
UART0 and UART1 serial transmission data output
TXD1
RXD0
P25/SO1
Input
UART0 and UART1 serial reception data input
RXD1
D0 to D7
P23/SI0
P26/SI1
I/O
16-bit data bus for external memory
D8 to D15
A0 to A7
P22/SO0
P40 to P47
P50 to P57
Output
24-bit address bus for external memory
PA0 to PA7
A8 to A15
PB0 to PB7
A16 to A23
P60 to P67
LWR
Output
External data bus lower byte write enable signal output
P90/LCAS
UWR
Output
External data bus higher byte write enable signal output
P91/UCAS
RD
Output
External data bus read strobe signal output
P92
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CHAPTER 2 PIN FUNCTIONS
(2) Non-port pins (3/4)
Pin Name
I/O
Function
Alternate Function
WE
Output
Write enable signal output for DRAM
P93
OE
Output
Output enable signal output for DRAM
P95
LCAS
Output
Column address strobe signal output for DRAM lower data
P90/LWR
UCAS
Output
Column address strobe signal output for DRAM higher data
P91/UWR
RAS0 to RAS3
Output
Row address strobe signal output for DRAM
P80/CS0 to P83/CS3
RAS4
P84/CS4/IOWR
RAS5
P85/CS5/IORD
RAS6
P86/CS6
RAS7
P87/CS7
BCYST
Output
Strobe signal output that shows the start of the bus cycle
P94
CS0 to CS3
Output
Chip select signal output
P80/RAS0 to
P83/RAS3
CS4
P84/RAS4/IOWR
CS5
P85/RAS5/IORD
CS6
P86/RAS6
CS7
P87/RAS7
WAIT
Input
Control signal input that inserts a wait in the bus cycle
PX6
REFRQ
Output
Refresh request signal output for DRAM
PX5
IOWR
Output
DMA write strobe signal output
P84/RAS4/CS4
IORD
Output
DMA read strobe signal output
P85/RAS5/CS5
DMA request signal input
P04/INTP100 to
P07/INTP103
DMARQ0 to
DMARQ3
Input
DMAAK0 to
DMAAK3
Output
DMA acknowledge signal output
P14/INTP110 to
P17/INTP113
TC0 to TC3
Output
DMA termination (terminal count) signal output
P104/INTP120 to
P107/INTP123
HLDAK
Output
Bus hold acknowledge output
P96
HLDRQ
Input
Bus hold request input
P97
ANI0 to ANI7
Input
Analog inputs to the A/D converter
P70 to P77
NMI
Input
Non-maskable interrupt request input
P20
System clock output
PX7
CLKOUT
Output
CKSEL
Input
Input which specifies the clock generator’s operating mode
MODE0 to
MODE2
Input
Operation mode specification
Note
VPP
MODE3
Note µPD70F3102 and 70F3102A only
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CHAPTER 2 PIN FUNCTIONS
(2) Non-port pins (4/4)
Pin Name
I/O
Function
Alternate Function
RESET
Input
System reset input
X1
Input
X2
Connects the system clock oscillator. In the case of an external
source supplying the clock, it is input to X1.
ADTRG
Input
A/D converter external trigger input
AVREF
Input
Reference voltage applied to A/D converter
AVDD
Positive power supply to A/D converter
AVSS
Ground for A/D converter
CVDD
Supplies a positive power supply for the dedicated clock
generator.
CVSS
Ground potential for the dedicated clock generator
VDD
Supplies the positive power supply (internal unit power supply).
HVDD
Supplies the positive power supply (external pin power supply).
VSS
Ground potential
High-voltage application pin during program write/verify
Note
VPP
Note µPD70F3102 and 70F3102A only
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P127/INTP153
MODE3
CHAPTER 2 PIN FUNCTIONS
2.2
Pin Status
The state of each pin after reset, in a power save mode (software STOP, IDLE, HALT), during bus hold (TH), and
in the idle state (TI), is shown below.
Operating State
Reset
Pin
Software
STOP Mode
IDLE Mode
HALT Mode
Bus Hold
(TH)
Idle State
(TI)
D0 to D15
Hi-Z
HI-Z (output)
(input)
HI-Z (output)
(input)
Operating
Hi-Z
Hi-Z
A0 to A23
Hi-Z
Hi-Z
Hi-Z
Operating
Hi-Z
Hold
WE, OE, RD, BCYST
Hi-Z
Hi-Z
Hi-Z
Operating
Hi-Z
H
UWR, LWR, IORD,
IOWR, CS0 to CS7
Hi-Z
H
H
Operating
Hi-Z
H
RAS0 to RAS7
Hi-Z
Operating
Operating
Operating
Hi-Z
Hold
UCAS, LCAS
Hi-Z
Operating
Operating
Operating
Hi-Z
H
REFRQ
Hi-Z
Operating
Operating
Operating
Operating
H
HLDRQ
Operating
Operating
Operating
HLDAK
Hi-Z
Hi-Z
Hi-Z
Operating
L
Operating
WAIT
Operating
CLKOUT
Note 1
L
L
Operating
Operating
Operating
DMARQ0 to DMARQ3
Operating
Operating
Operating
DMAAK0 to DMAAK3
Hi-Z
H
H
Operating
H
H
TC0 to TC3
Hi-Z
H
H
Operating
Operating
Operating
INTP100 to INTP103,
INTP110 to INTP113,
INTP120 to INTP123,
INTP130 to INTP133,
INTP140 to INTP143,
INTP150 to INTP153
Operating
Operating
Operating
NMI
Operating
Operating
Operating
Operating
Operating
P00 to P07, P10 to P17,
P20 to P27, P30 to P37,
P40 to P47, P50 to P57,
P60 to P67, P70 to P77,
P80 to P87, P90 to P97,
P100 to P107, P110 to
P117, P120 to P127, PA0
to PA7, PB0 to PB7, PX5
to PX7
Hi-Z
Hold (output)
(input)
Hold (output)
(input)
Operating
Operating
Operating
TCLR10 to TCLR15
Operating
Operating
Operating
TI10 to TI15
Operating
Operating
Operating
TO100, TO101,
TO110, TO111,
TO120, TO121,
TO130, TO131,
TO140, TO141,
TO150, TO151
Hi-Z
Hold
Hold
Operating
Operating
Operating
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CHAPTER 2 PIN FUNCTIONS
Operating State
Reset
Pin
Software
STOP Mode
IDLE Mode
HALT Mode
Bus Hold
(TH)
Idle State
(TI)
SI0 to SI3
Operating
Operating
Operating
SO0 to SO3
Hi-Z
Hold
Hold
Operating
Operating
Operating
SCK0 to SCK3
Hi-Z
Hold (output)
Hold (output)
Operating
Operating
Operating
(input)
(input)
RXD0, RXD1
Operating
Operating
Operating
TXD0, TXD1
Hi-Z
Hold
Hold
Operating
Operating
Operating
ANI0 to ANI7, ADTRG
Operating
Operating
Operating
Notes 1. When in single-chip mode 0: Hi-Z
At other times: Operating
2. In the idle state (TI) just before and just after bus hold, H
Remark
Hi-Z: High-impedance
Hold: State during immediately preceding external bus cycle is held
H:
High-level output
L:
Low-level output
:
No sampling of input
Cautions when turning on/off power supply
The V850E/MS1 is configured with two power supply pins: the internal unit power supply pin (V DD) and the external
pin power supply pin (HVDD). If the voltage exceeds its operation guaranteed range, the input/output state of the I/O
pins may become undefined. If this input/output undefined state causes problems in the system, the pin status can be
made high impedance by taking the following countermeasures.
• When turning on the power
Apply 0 V to the HVDD pin until the voltage of the VDD pin is within the operation guaranteed range (3.0 to 3.6 V).
• When turning off the power
Apply a voltage within the operation guaranteed range (3.0 to 3.6 V) to the VDD pin until the voltage of the HVDD
pin becomes 0 V.
VDD
3.0 V
3.0 V
HVDD
0V
Oscillation
stabilization time
RESET (input)
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0V
CHAPTER 2 PIN FUNCTIONS
2.3
Description of Pin Functions
(1) P00 to P07 (Port 0) ··· 3-state I/O
Port 0 is an 8-bit input/output port that can be set to input or output in 1-bit units.
Besides functioning as a port, in the control mode it operates as the input/output for the real-time pulse unit
(RPU), the external interrupt request input and the DMA request input.
The operation mode can be set as port or control in 1-bit units, specified by the port 0 mode control register
(PMC0).
(a) Port mode
P00 to P07 can be set to input or output in bit units by the port 0 mode register (PM0).
(b) Control mode
P00 to P07 can be set in the port/control mode in bit units by the PMC0 register.
(i)
TO100, TO101 (Timer Output) ··· output
Output the pulse signals for timer 1.
(ii) TCLR10 (Timer Clear) ··· input
This is an input pin for external clear signals for timer 1.
(iii) TI10 (Timer Input) ··· input
This is an input pin for an external counter clock for timer 1.
(iv) INTP100 to INTP103 (Interrupt Request from Peripherals) ··· input
These are input pins for external interrupt requests for timer 1.
(v) DMARQ0 to DMARQ3 (DMA Request) ··· input
These are DMA service request signals. They correspond to DMA channels 0 to 3, respectively, and
operate independently of each other. The priority order is fixed at DMARQ0 > DMARQ1 > DMARQ2
> DMARQ3.
This signal is sampled when the CLKOUT signal falls. Maintain the active level until a DMA request
is received.
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CHAPTER 2 PIN FUNCTIONS
(2) P10 to P17 (Port 1) ··· 3-state I/O
Port 1 is an 8-bit input/output port that can be set to input or output in 1-bit units.
Besides functioning as a port, in the control mode it operates as the input/output for the real-time pulse unit
(RPU), the external interrupt request input and the DMA request input.
The operation mode can be set as port or control in 1-bit units, specified by the port 1 mode control register
(PMC1).
(a) Port mode
P10 to P17 can be set to input or output in bit units by the port 1 mode register (PM1).
(b) Control Mode
P10 to P17 can be set in the port/control mode in bit units by the PMC1 register.
(i)
TO110, TO111 (Timer Output) ··· output
Output the pulse signals for timer 1.
(ii) TCLR11 (Timer Clear) ··· input
This is an input pin for external clear signals for timer 1.
(iii) TI11 (Timer Input) ··· input
This is an input pin for an external counter clock for timer 1.
(iv) INTP110 to INTP113 (Interrupt Request from Peripherals) ··· input
These are input pins for external interrupt requests for timer 1.
(v) DMAAK0 to DMAAK3 (DMA Acknowledge) ··· output
This signal shows that a DMA service request was acknowledged.
They correspond to DMA channels 0 to 3, respectively, and operate independently of each other.
These signals become active only when external memory is being accessed. When DMA transfers
are being executed between internal RAM and internal peripheral I/O, they do not become active.
These signals are activated on the falling of the CLKOUT signal in the T0, T1R, or T1FH state of the
DMA cycle, and are retained at the active level during DMA transfers.
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CHAPTER 2 PIN FUNCTIONS
(3) P20 to P27 (Port 2) ··· 3-state I/O
Port 2, except for P20, which is an input-only pin, is an input/output port which can be set to input or output in
1-bit units.
Besides functioning as a port, in the control mode it operates as the input/output for the serial interface
(UART0/CSI0, UART1/CST1).
The operation mode can be set as port or control in 1-bit units, specified by the port 2 mode control register
(PMC2).
(a) Port mode
P21 to P27 can be set to input or output in bit units by the port 2 mode register (PM2). P20 is an
exclusive input port, and if a valid edge is input, it operates as an NMI input.
(b) Control mode
P22 to P27 can be set in the port/control mode in bit units by the PMC2 register.
(i)
NMI (Non-Maskable Interrupt Request) ··· input
This is the input pin for non-maskable interrupt requests.
(ii) TXD0, TXD1 (Transmit Data) ··· output
Output UART0, UART1 serial transmit data.
(iii) RXD0, RXD1 (Receive Data) ··· input
Input UART0, UART1 serial receive data.
(iv) SO0, SO1 (Serial Output) ··· output
Output CSI0, CSI1 serial transmit data.
(v) SI0, SI1 (Serial Input) ··· input
Input CSI0, CSI1 serial receive data.
(vi) SCK0, SCK1 (Serial Clock) ··· 3-state I/O
These are the input/output pins for the CSI0, CSI1 serial clock.
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CHAPTER 2 PIN FUNCTIONS
(4) P30 to P37 (Port 3) ··· 3-state I/O
Port 3 is an 8-bit input/output port that can be set to input or output in 1-bit units.
Besides functioning as a port, in the control mode it operates as the input/output for the real-time pulse unit
(RPU), the external request input and the serial interface (CSI2) input/output. The operation mode can be set
as port or control in 1-bit units, specified by the port 3 mode control register (PMC3).
(a) Port mode
P33 to P37 can be set to input or output in bit units by the port 3 mode register (PM3).
(b) Control mode
P30 to P37 can be set in the port/control mode in bit units by the PMC3 register.
(i)
TO130, TO131 (Timer Output) ··· output
Output pulse signals for timer 1.
(ii) TCLR13 (Timer Clear) ··· input
This is an input pin for external clear signals for timer 1.
(iii) TI13 (Timer Input) ··· input
This is an input pin for an external counter clock for timer 1.
(iv) INTP130 to INTP133 (Interrupt Request from Peripherals) ··· input
These are input pins for external interrupt requests for timer 1.
(v) SO2 (Serial Output)··· output
Outputs CSI2 serial transmit data.
(vi) SI2 (Serial Input)··· input
Inputs CSI2 serial receive data.
(vii) SCK2 (Serial Clock)··· 3-state I/O
This is the input/output pin for the CSI2 serial clock.
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CHAPTER 2 PIN FUNCTIONS
(5) P40 to P47 (Port 4) ··· 3-state I/O
Port 4 is an 8-bit input/output port that can be set to input or output in 1-bit units.
Besides functioning as a port, in the control mode (external expansion mode) it operates as a data bus (D0 to
D7) when memory is externally expanded.
The operation mode is specified by the mode specification pins (MODE0 to MODE3) and the memory
expansion mode register (MM).
(a) Port mode
P40 to P47 can be set to input or output in bit units by the port 4 mode register (PM4).
(b) Control mode (External expansion mode)
P40 to P47 can be set as D0 to D7 by using the MODE0 to MODE3 pins and MM register.
(i)
D0 to D7 (Data) ··· 3-state I/O
These pins constitute the data bus that is used for external access. They operate as the lower 8-bit
input/output bus pins for 16-bit data. The output changes in synchronization with the falling of the
clock in the T1 state CLKOUT signal of the bus cycle. In the idle state (TI), the impedance becomes
high.
(6) P50 to P57 (Port 5) ··· 3-state I/O
Port 5 is an 8-bit input/output port that can be set to input or output in 1-bit units.
Besides functioning as an I/O port, in the control mode (external expansion mode) it operates as a data bus
(D8 to D15) when memory is externally expanded.
The operation mode is specified by the mode specification pins (MODE0 to MODE3) and the memory
expansion mode register (MM).
(a) Port mode
P50 to P57 can be set to input or output in bit units by the port 5 mode register (PM5).
(b) Control mode (External expansion mode)
P50 to P57 can be set as D8 to D15 by using the MODE0 to MODE3 pins and MM register.
(i)
D8 to D15 (Data) ··· 3-state I/O
These pins constitute the data bus that is used for external access. They operate as the higher 8-bit
input/output bus pins for 16-bit data. The output changes in synchronization with the falling of the
clock in the T1 state CLKOUT signal of the bus cycle. In the idle state (TI), the impedance becomes
high.
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CHAPTER 2 PIN FUNCTIONS
(7) P60 to P67 (Port 6) ··· 3-state I/O
Port 6 is an 8-bit input/output port that can be set to input or output in 1-bit units.
Besides functioning as a port, in the control mode (external expansion mode) it operates as an address bus
(A16 to A23) when memory is externally expanded.
The operation mode can be set as port or control in 2-bit units, specified by the mode specification pins
(MODE0 to MODE3) and the memory expansion mode register (MM).
(a) Port mode
P60 to P67 can be set to input or output in bit units by the port 6 mode register (PM6).
(b) Control mode (External expansion mode)
P60 to P67 can be set as A16 to A23 by using the MODE0 to MODE3 pins and MM register.
(i)
A16 to A23 (Address) ··· output
These pins constitute the higher 8-bits of a 24-bits address bus when the external memory is
accessed. The output changes in synchronization with the falling edge of the CLKOUT signal in the
T1 state of the bus cycle. In the idle state (TI), the previous bus cycle’s address is held.
(8) P70 to P77 (Port 7) ··· input
Port 7 is an 8-bit input-only port in which all pins are fixed as input pins.
Besides functioning as a port, in the control mode it operates as analog input for the A/D converter. However,
the input port and analog input pin cannot be switched.
(a) Port mode
P70 to P77 are input-only pins.
(b) Control mode
P70 to P77 function alternately pins ANI0 to ANI7, but these alternate functions are not switchable.
(i)
ANI0 to ANI7 (Analog Input) ··· input
These are analog input pins for the A/D converter.
Connect a capacitor between these pins and AVSS to prevent noise-related operation faults. Also, do
not apply voltage that is outside the range for AVSS and AVREF to pins that are being used as inputs
for the A/D converter. If it is possible for noise above the AVREF range or below the AVSS to enter,
clamp these pins using a diode that has a small VF value.
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(9) P80 to P87 (Port 8) ··· 3-state I/O
Port 8 is an 8-bit input/output port that can be set to input or output in 1-bit units.
Besides functioning as a port, in the control mode it operates as a control signal output when memory and
peripheral I/O are externally expanded.
The operation mode can be set as port or control in 1-bit units, specified by the port 8 mode control register
(PMC8).
(a) Port mode
P80 to P87 can be set to input or output in bit units by the port 8 mode register (PM8).
(b) Control mode
P80 to P87 can be set in the port/control mode in bit units by the PMC8 register.
(i)
CS0 to CS7 (Chip Select) ··· 3-state output
This is the chip select signal for SRAM, external ROM, external peripheral I/O, page ROM and the
synchronous flash memory area.
The CSn signal is assigned to memory block n (n = 0 to 7).
It becomes active at the time the bus cycle when the corresponding memory block is accessed starts.
In the idle state (TI), it becomes inactive.
(ii) RAS0 to RAS7 (Row Address Strobe) ··· 3-state output
This is the strobe signal for the row address for the DRAM area and the strobe signal for the CBR
refresh cycle.
The RASn signal is assigned to memory block n (n = 0 to 7).
During on-page disable, after the DRAM access bus cycle ends, it becomes inactive.
During on-page enable, even after the DRAM access bus cycle ends, it is kept in the active state.
During the reset period and during a hold period, it is in the high impedance state, so connect it to
HVDD via a resistor.
(iii) IORD (I/O Read) ··· 3-state output
This is the read strobe signal for external I/O during DMA flyby transfer. It indicates whether the bus
cycle currently being executed is a read cycle for external I/O during flyby transfer, or a read cycle for
the SRAM area.
In order to make it possible to connect directly to memory or external I/O during DMA flyby transfer,
UWR or LWR rises before IORD rises.
Furthermore, this external I/O can be accessed even when it is assigned to the SRAM area.
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CHAPTER 2 PIN FUNCTIONS
(iv) IOWR (I/O Write) ··· 3-state output
This is the write strobe signal for external I/O during DMA flyby transfer. It indicates whether the bus
cycle currently being executed is a write cycle for external I/O during flyby transfer, or a write cycle for
the SRAM area.
In order to make it possible to connect directly to memory or external I/O during DMA flyby transfer,
IOWR rises before RD rises.
Furthermore, this external I/O can be accessed even when it is assigned to the SRAM area.
(10) P90 to P97 (Port 9) ··· 3-state I/O
Port 9 is an 8-bit input/output port that can be set to input or output in 1-bit units.
Besides functioning as a port, in the control mode it operates as a control signal output and bus hold control
signal input/output when memory is externally expanded.
The operation mode can be set as port or control in 1-bit units, specified by the port 9 mode control register
(PMC9).
(a) Port mode
P90 to P97 can be set to input or output in bit units by the port 9 mode register (PM9).
(b) Control mode
P90 to P97 can be set in the port/control mode in bit units by the PMC9 register.
(i)
LCAS (Lower Column Address Strobe) ··· 3-state output
This is the strobe signal for column address for DRAM and the strobe signal for the CBR refresh
cycle.
In the data bus, the lower byte is valid.
(ii) UCAS (Upper Column Address Strobe) ··· 3-state output
This is the strobe signal for column address for DRAM and the strobe signal for the CBR refresh
cycle.
In the data bus, the higher byte is valid.
(iii) LWR (Lower Byte Write Strobe) ··· 3-state output
This strobe signal shows whether the bus cycle currently being executed is a write cycle for the
SRAM, external ROM, external peripheral I/O, or page ROM.
In the data bus, the lower byte becomes valid. If the bus cycle is a lower memory write, it becomes
active at the rise of the T1 state’s CLKOUT signal and becomes inactive at the rise of the T2 state’s
CLKOUT signal.
(iv) UWR (Upper Byte Write Strobe) ··· 3-state output
This strobe signal shows whether the bus cycle currently being executed is a write cycle for the
SRAM, external ROM, external peripheral I/O, or page ROM.
In the data bus, the higher byte becomes valid. If the bus cycle is a higher memory write, it becomes
active at the rise of the T1 state’s CLKOUT signal and becomes inactive at the rise of the T2 state’s
CLKOUT signal.
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(v) RD (Read Strobe) ··· 3-state output
This strobe signal shows that the bus cycle currently being executed is a read cycle for the SRAM,
external ROM, external peripheral I/O, page ROM or synchronous flash memory area.
In the idle state (TI), it becomes inactive.
(vi) WE (Write Enable) ··· 3-state output
This signal shows that the bus cycle currently being executed is a write cycle for the SRAM area. In
the idle state (TI), it becomes inactive.
(vii) BCYST (Bus Cycle Start Timing) ··· 3-state output
This outputs a status signal showing the start of the bus cycle. It becomes active for 1 clock cycle
from the start of each cycle.
In the idle state (TI), it becomes inactive.
(viii) OE (Output Enable) ··· 3-state output
This signal shows that the bus cycle currently being executed is a read cycle for the DRAM area.
In the idle state (TI), it becomes inactive.
(ix) HLDAK (Hold Acknowledge) ··· output
In this mode, this pin is the output pin for the acknowledge signal that indicates high impedance
status for the address bus, data bus, and control bus when the V850E/MS1 receives a bus hold
request.
While this signal is active, the impedance of the address bus, data bus and control bus becomes high
and the bus mastership is transferred to the external bus master.
(x) HLDRQ (Hold Request) ··· input
In this mode, this pin is the input pin by which an external device requests the V850E/MS1 to release
the address bus, data bus, and control bus. This pin accepts asynchronous input for the CLKOUT
signal.
When this pin is active, the address bus, data bus, and control bus are set to high
impedance. This occurs either when the V850E/MS1 completes execution of the current bus cycle or
immediately if no bus cycle is being executed, then the HLDAK signal is set as active and the bus is
released.
In order to make the bus hold state secure, keep the HLDRQ signal active until the HLDAK signal is
output.
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CHAPTER 2 PIN FUNCTIONS
(11) P100 to P107 (Port 10) ··· 3-state I/O
Port 10 is an 8-bit input/output port that can be set to input or output in 1-bit units.
Besides functioning as a port, in the control mode it operates as an input/output for real time pulse unit (RPU),
external interrupt request input and DMA termination signal (terminal count) from DMA controller.
The operation mode can be set as port or control in 1-bit units, specified by the port 10 mode control register
(PMC10).
(a) Port mode
P100 to P107 can be set to input or output in bit units by the port 10 mode register (PM10).
(b) Control mode
P100 to P107 can be set in the port/control mode in bit units by the PMC10 register.
(i)
TO120, TO121 (Timer Output) ··· output
Output the pulse signal of timer 1.
(ii) TCLR12 (Timer Clear) ··· input
This is an input pin for external clear signals for timer 1.
(iii) TI12 (Timer Input) ··· input
This is an input pin for an external counter clock for timer 1.
(iv) INTP120 to INTP123 (Interrupt Request from Peripherals) ··· input
These are input pins for external interrupt requests for timer 1.
(v) TC0 to TC3 (Terminal Count) ··· output
This signal shows that DMA transfer by the DMA controller is terminated.
This signal becomes active for 1 clock cycle at the fall of the CLKOUT signal.
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(12) P110 to P117 (Port 11) ··· 3-state I/O
Port 11 is an 8-bit input/output port that can be set to input or output in 1-bit units.
Besides functioning as a port, in the control mode it operates as an input/output for real-time pulse unit (RPU),
external interrupt request, input and serial interface (CSI3) input/output.
The operation mode can be set as port or control in 1-bit units, specified by the port 11 mode control register
(PMC11).
(a) Port mode
P110 to P117 can be set to input or output in bit units by the port 11 mode register (PM11).
(b) Control mode
P110 to P117 can be set in the port/control mode in bit units by the PMC11 register.
(i)
TO140, TO141 (Timer Output) ··· output
Output the pulse signal of timer 1.
(ii) TCLR14 (Timer Clear) ··· input
This is an input pin for external clear signals for timer 1.
(iii) TI14 (Timer Input) ··· input
This is an input pin for an external counter clock for timer 1.
(iv) INTP140 to INTP143 (Interrupt Request from Peripherals) ··· input
These are input pins for external interrupt requests for timer 1.
(v) SO3 (Serial Output 3)··· output
Outputs the CSI3 serial transfer data.
(vi) SI3 (Serial Input 3)··· input
Inputs the CSI3 serial receive data.
(vii) SCK3 (Serial Clock 3)··· 3-state I/O
This is the input/output pin for the CSI3 serial clock.
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CHAPTER 2 PIN FUNCTIONS
(13) P120 to P127 (Port 12) ··· 3-state I/O
Port 12 is an 8-bit input/output port that can be set to input or output in 1-bit units.
Besides functioning as a port, in the control mode it operates as an input/output for real-time pulse unit (RPU),
external interrupt request input and external trigger input to A/D converter.
The operation mode can be set as port or control in 1-bit units, specified by the port 12 mode control register
(PMC12).
(a) Port mode
P120 to P127 can be set to input or output in bit units by the port 12 mode register (PM12).
(b) Control mode
P120 to P127 can be set in the port/control mode in bit units by the PMC12 register.
(i)
TO150, TO151 (Timer Output) ··· output
Output the pulse signal of timer 1.
(ii) TCLR15 (Timer Clear) ··· input
This is an input pin for external clear signals for timer 1.
(iii) TI15 (Timer Input) ··· input
This is an input pin for an external counter clock for timer 1.
(iv) INTP150 to INTP153 (Interrupt Request from Peripherals) ··· input
These are input pins for external interrupt requests for timer 1.
(v) ADTRG (AD Trigger Input)··· input
This is the A/D converter external trigger input pin.
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(14) PA0 to PA7 (Port A) ··· 3-state I/O
Port A is an 8-bit input/output port that can be set to input or output in 1-bit units.
Besides functioning as a port, in the control mode (external expansion mode) it operates as an address bus
(A0 to A7) when memory is externally expanded.
The operation mode is specified by the mode specification pins (MODE0 to MODE3) and the memory
expansion mode register (MM).
(a) Port mode
PA0 to PA7 can be set to input or output in bit units by the port A mode register (PMA).
(b) Control mode (External expansion mode)
PA0 to PA7 can be set as A0 to A7 by using the MODE0 to MODE3 pins and MM register.
(i)
A0 to A7 (Address) ··· output
These pins constitute the address bus that is used for external access. The output changes in
synchronization with the falling of the CLKOUT signal in the T1 state of the bus cycle. In the idle
state (TI), the previous bus cycle’s address is held.
(15) PB0 to PB7 (Port B) ··· 3-state I/O
Port B is an 8-bit input/output port that can be set to input or output in 1-bit units.
Besides functioning as a port, in the control mode (external expansion mode) it operates as an address bus
(A8 to A15) when memory is externally expanded.
The operation mode can be set as port or control in 2-bit or 4-bit units, specified by the mode specification pins
(MODE0 to MODE3) and memory expansion mode register (MM).
(a) Port mode
PB0 to PB7 can be set to input or output in bit units by the port B mode register (PMB).
(b) Control mode (External expansion mode)
PB0 to PB7 can be set as A8 to A15 by using the MODE0 to MODE3 pins and MM register.
(i)
A8 to A15 (Address) ··· output
These pins constitute the address bus when the external memory is accessed.
The output changes in synchronization with the rising edge of the CLKOUT signal in the T1 state of
the bus cycle. In the idle state (TI), the impedance becomes high.
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(16) PX5 to PX7 (Port X) ··· 3-state I/O
Port X is an 8-bit input/output port that can be set to input or output in 1-bit units.
Besides functioning as a port, in the control mode it operates as a refresh request signal output for DRAM,
wait insertion signal input and system clock output.
The operation mode can be set as port or control in 1-bit units, specified by the port X mode control register
(PMCX).
(a) Port mode
PX5 to PX7 can be set to input or output in bit units by the port X mode register (PMX).
(b) Control mode
PX5 to PX7 can be set in the port/control mode in bit units by the PMCX register.
(i)
REFRQ (Refresh Request) ··· 3-state output
This is the refresh request signal for DRAM.
In cases where the address is decoded by an external circuit and the connected DRAM is increased,
or in cases where external SIMMs are connected, this signal is used for RAS control during the
refresh cycle.
This signal becomes active during the refresh cycle. Also, during bus hold, it becomes active when a
refresh request is generated and informs the external bus master that a refresh request was
generated.
(ii) WAIT (Wait) ··· input
This is the control signal input pin that inserts a data wait in the bus cycle, and it can be input
asynchronously with respect to the CLKOUT signal. When the CLKOUT signal falls, sampling is
executed. When the set/hold time is not terminated within the sampling timing, the wait insertion may
not be executed.
(iii) CLKOUT (Clock Output) ··· output
This is the internal system clock output pin. When in single-chip mode 1 and ROM-less modes 0 and
1, output from the CLKOUT pin can be executed even during reset.
When in single-chip mode 0, it changes to the port mode during reset, so output from the CLKOUT
pin cannot be executed. Set the port X mode control register (PMCX) to control mode to execute
CLKOUT output.
(17) CKSEL (Clock Generator Operating Mode Select) ··· input
This is the input pin that specifies the clock generator’s operation mode.
Make sure the input level does not change during operation.
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(18) MODE0 to MODE3 (Mode) ··· input
These are the input pins that specify the operation mode. Operation modes can be roughly divided into
normal operation mode and flash memory programming mode. In the normal operation mode, there are
single-chip modes 0 and 1, and ROM-less modes 0 and 1 (for details, refer to 3.3 Operation Modes). The
operation mode is determined by sampling the status of each of the MODE0 to MODE3 pins during reset.
Note that this status must be fixed so that the input level does not change during operation.
(a) µPD703100, 703100A
MODE3
MODE2
MODE1
MODE0
L
L
L
L
L
L
L
H
Operation Mode
Normal operation
mode
Other than above
ROM-less mode 0
ROM-less mode 1
Setting prohibited
(b) µPD703101, 703101A, 703102, 703102A
MODE3
MODE2
MODE1
MODE0
Operation Mode
L
L
L
L
L
L
L
H
L
L
H
L
Single-chip mode 0
L
L
H
H
Single-chip mode 1
Normal operation
mode
Other than above
ROM-less mode 0
ROM-less mode 1
Setting prohibited
(c) µPD70F3102, 70F3102A
MODE3/VPP
MODE2
MODE1
MODE0
Operation Mode
Normal operation
mode
0V
L
L
L
0V
L
L
H
0V
L
H
L
Single-chip mode 0
0V
L
H
H
Single-chip mode 1
7.8 V
L
H
L
Other than above
Remark
ROM-less mode 0
ROM-less mode 1
Flash memory programming mode
Setting prohibited
L: Low-level input
H: High-level input
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CHAPTER 2 PIN FUNCTIONS
(19) RESET (Reset) ··· input
RESET input is asynchronous input for a signal that has a constant low-level width regardless of the operating
clock’s status. When this signal is input, a system reset is executed as the first priority ahead of all other
operations.
In addition to being used for ordinary initialization/start operations, this pin can also be used to release a power
save mode (HALT, IDLE, or software STOP).
(20) X1, X2 (Crystal) ··· input
These pins are used to connect the resonator that generates the system clock.
An external clock source can be referenced by connecting the external clock input to the X1 pin and leaving
the X2 pin open.
(21) CVDD (Power Supply for Clock Generator)
This pin supplies positive power to the clock generator.
(22) CVSS (Ground for Clock Generator)
This is the ground pin of the clock generator.
(23) VDD (Power Supply for Internal Unit)
These are the positive power supply pins for each internal unit. All the VDD pins should be connected to a
positive power source (3.3 V).
(24) HVDD (Power Supply for External Pins)
These are the positive power supply pins for external pins. All the HVDD pins should be connected to a
positive power source (5 V to 3.3 V).
(25) VSS (Ground)
These are ground pins. All the VSS pins should be connected to ground.
(26) AVDD (Analog VDD)
This is the analog power supply pin for the A/D converter.
(27) AVSS (Analog VSS)
This is the ground pin for the A/D converter.
(28) AVREF (Analog Reference Voltage) ··· input
This is the reference voltage supply pin for the A/D converter.
(29) VPP (Programming Power Supply)
This is the positive power supply pin used for flash memory programming mode.
This pin is used for µPD70F3102 and 70F3102A.
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2.4
Pin Input/Output Circuits and Recommended Connection of Unused Pins
If connecting to VDD or VSS via resistors, it is recommended that 1 to 10 kΩ resistors be connected.
Pin Name
Input/Output Circuit Type
P00/TO100, P01/TO101
5
P02,TCLR10, P03/TI10
5-K
Recommended Connection of Unused Pins
Input:
Independently connect to HVDD or
VSS via a resistor.
Output: Leave open.
P04/INTP100/DMARQ0 to
P07/INTP103/DMARQ3
P10/TO110, P11/TO111
5
P12/TCLR11, P13/TI11
5-K
P14/INTP110/DMAAK0 to
P17/INTP113/DMAAK3
P20/NMI
2
Connect directly to VSS.
P21
5
Input:
P22/TXD0/SO0
P23/RXD0/SI0
5-K
Independently connect to HVDD or
VSS via a resistor.
Output: Leave open.
P24/SCK0
P25/TXD1/SO1
5
P26/RXD1/SI1
5-K
P27/SCK1
P30/TO130, P31/TO131
5
P32/TCLR13, P33/TI13
5-K
P34/INTP130
P35/INTP131/SO2
P36/INTP132/SI2
P37/INTP133/SCK2
P40/D0 to P47/D7
5
P50/D8 to P57/D15
P60/A16 to P67/A23
P70/ANI0 to P77/ANI7
9
Connect directly to VSS.
P80/CS0/RAS0 to P83/CS3/RAS3
5
Input:
P84/CS4/RAS4/IOWR,
Independently connect to HVDD or
VSS via a resistor.
Output: Leave open.
P85/CS5/RAS5/IORD
P86/CS6/RAS6, P87/CS7/RAS7
P90/LCAS/LWR
P91/UCAS/UWR
P92/RD
P93/WE
P94/BCYST
P95/OE
P96/HLDAK
P97/HLDRQ
P100/TO120, P101/TO121
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CHAPTER 2 PIN FUNCTIONS
Pin Name
P102/TCLR12, P103/TI12
Input/Output Circuit Type
5-K
Recommended Connection of Unused Pins
Input:
P104/INTP120/TC0 to
Independently connect to HVDD or
VSS via a resistor.
Output: Leave open.
P107/INTP123/TC3
P110/TO140, P111/TO141
5
P112/TCLR14, P113/TI14
5-K
P114/INTP140
P115/INTP141/SO3
P116/INTP142/SI3
P117/INTP143/SCK3
P120/TO150, P121/TO151
5
P122/TCLR15, P123/TI15
5-K
P124/INTP150 to P126/INTP152
P127/INTP153/ADTRG
PA0/A0 to PA7/A7
5
PB0/A8 to PB7/A15
PX5/REFRQ
PX6/WAIT
PX7/CLKOUT
CKSEL
1
RESET
2
Connect directly to HVDD.
MODE0 to MODE2
Note 1
MODE3
Connect to VSS via a resistor (RVPP).
Note 2
MODE3/VPP
AVREF, AVSS
Connect directly to VSS.
AVDD
Connect directly to HVDD.
Notes 1. µPD703100, 703100A, 703101, 703101A, 703102, 703102A only
2. µPD70F3102, 70F3102A only
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2.5
Pin Input/Output Circuits
Type 1
Type 5-K
VDD
VDD
Data
P-ch
IN/OUT
P-ch
IN
Output
disable
N-ch
N-ch
Input
enable
Type 9
Type 2
P-ch
IN
+
N-ch
IN
Comparator
–
VREF (threshold voltage)
Schmitt-triggered input with hysteresis characteristics
Input enable
Type 5
VDD
Data
P-ch
IN/OUT
Output
disable
N-ch
Input
enable
Caution Note that VDD in the circuit diagram is replaced by HVDD.
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[MEMO]
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The CPU of the V850E/MS1 is based on RISC architecture and executes almost all the instructions in one clock
cycle, using 5-stage pipeline control.
3.1
Features
• Minimum instruction execution time: 25 ns (at internal 40 MHz operation) … µPD703100-40, 703100A-40
30 ns (at internal 33 MHz operation) … other than above
• Memory space
Program space: 64 MB Linear
Data space:
4 GB Linear
• Thirty-two 32-bit general-purpose registers
• Internal 32-bit architecture
• Five-stage pipeline control
• Multiplication/division instructions
• Saturated operation instructions
• One-clock 32-bit shift instruction
• Long/short instruction format
• Four types of bit manipulation instructions
• Set
• Clear
• Not
• Test
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3.2
CPU Register Set
The registers of the V850E/MS1 can be classified into two categories: a general-purpose program register set and
a dedicated system register set. The size of the registers is 32 bits.
For details, refer to V850E/MS1 User’s Manual Architecture.
(1) Program register set
31
r0
(2) System register set
0
31
0
Zero Register
EIPC
Exception/Interrupt PC
r1
Reserved for Address Generation
EIPSW
Exception/Interrupt PSW
r2
Interrupt Stack Pointer
r3
Stack Pointer (SP)
r4
Global Pointer (GP)
FEPC
Fatal Error PC
r5
Text Pointer (TP)
FEPSW
Fatal Error PSW
31
0
r6
r7
31
r8
ECR
0
Exception Cause Register
r9
r10
31
r11
PSW
0
Program Status Word
r12
r13
31
0
r14
CTPC
CALLT Caller PC
r15
CTPSW
CALLT Caller PSW
r16
r17
31
0
r18
DBPC
ILGOP Caller PC
r19
DBPSW
ILGOP Caller PSW
r20
r21
31
r22
CTBP
r23
r24
r25
r26
r27
r28
r29
r30
Element Pointer (EP)
r31
Link Pointer (LP)
31
PC
70
0
Program Counter
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CALLT Base Pointer
CHAPTER 3 CPU FUNCTION
3.2.1 Program register set
The program register set includes general-purpose registers and a program counter.
(1) General-purpose registers
Thirty-two general-purpose registers, r0 to r31, are available. Any of these registers can be used as a data
variable or address variable.
However, r0 and r30 are implicitly used by instructions, and care must be exercised when using these
registers. Also, r1 to r5 and r31 are implicitly used by the assembler and C compiler. Therefore, before using
these registers, their contents must be saved so that they are not lost. The contents must be restored to the
registers after the registers have been used.
Table 3-1. Program Registers
Name
Usage
Operation
r0
Zero register
Always holds 0
r1
Assembler-reserved register
Working register for generating 32-bit immediate data
r2
Interrupt stack pointer
Stack pointer for interrupt handler
r3
Stack pointer
Used to generate stack frame when function is called
r4
Global pointer
Used to access global variable in data area
r5
Text pointer
Register to indicate the start of the text area (where program
code is located)
r6 to r29
Address/data variable registers
r30
Element pointer
Base pointer when memory is accessed
r31
Link pointer
Used by compiler when calling function
PC
Program counter
Holds instruction address during program execution
(2) Program counter
This register holds the instruction address during program execution. The lower 26 bits of this register are
valid, and bits 31 to 26 are fixed to 0. If a carry occurs from bit 25 to 26, it is ignored.
Bit 0 is fixed to 0, and branching to an odd address cannot be performed.
Figure 3-1. Program Counter (PC)
31
PC
26 25
Fixed to 0
1 0
Instruction address during execution
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After reset
00000000H
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CHAPTER 3 CPU FUNCTION
3.2.2 System register set
System registers control the status of the CPU and hold interrupt information.
Table 3-2. System Register Numbers
No.
System Register Name
0
EIPC
1
EIPSW
2
FEPC
3
4
5
Usage
Status saving register during
interrupt
Operation
These registers save the PC and PSW when a
software exception or interrupt occurs. Because only
one set of these registers is available, their contents
must be saved when multiple interrupts are enabled.
FEPSW
Status saving register during
NMI
These registers save the PC and PSW when an NMI
occurs.
ECR
Interrupt source register
If an exception, maskable interrupt, or NMI occurs,
this register will contain information referencing the
interrupt source. The higher 16 bits of this register
are called FECC, to which the exception code of the
NMI is set. The lower 16 bits are called EICC, to
which the exception code of the exception/interrupt is
set.
Refer to Figure 3-2.
PSW
Program status word
The program status word is a collection of flags that
indicate the program status (instruction execution
result) and CPU status.
Refer to Figure 3-3.
16
CTPC
17
CTPSW
Status saving register during
CALLT execution
If the CALLT instruction is executed, this register
saves the PC and PSW.
18
DBPC
Status saving register during
If an exception trap is generated due to detection of
an illegal instruction code, this register saves the PC
exception trap
19
DBPSW
20
CTBP
and PSW.
CALLT base pointer
This is used to specify the table address and
generate the target address.
Reserved
6 to 15
21 to 31
To read/write these system registers, specify the system register number indicated by a system register load/store
instruction (LDSR or STSR instruction).
Figure 3-2. Interrupt Source Register (ECR)
31
16 15
ECR
Bit Position
72
0
FECC
Bit Name
EICC
After reset
00000000H
Function
31 to 16
FECC
Fatal Error Cause Code
Exception code of NMI (refer to Table 7-1 Interrupt List)
15 to 0
EICC
Exception/Interrupt Cause Code
Exception code of exception/interrupt (refer to Table 7-1 Interrupt List)
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Figure 3-3. Program Status Word (PSW)
31
8 7 6 5 4 3 2 1 0
PSW
RFU
NP EP ID SAT CY OV S Z
After reset
00000020H
Bit Position
Flag
Function
31 to 8
RFU
7
NP
NMI Pending
Indicates that NMI processing is in progress. This flag is set when an NMI is
accepted, and disables multiple interrupts.
6
EP
Exception Pending
Indicates that exception processing is in progress. This flag is set when an
exception is generated. Moreover, interrupt requests can be accepted when this
bit is set.
5
ID
Interrupt Disable
Indicates that accepting maskable interrupt request is disabled.
4
SAT
Saturated Math
This flag is set if the result of executing saturated operation instruction overflows
(if overflow does not occur, value of previous operation is held).
3
CY
Carry
This flag is set if carry or borrow occurs as result of operation (if carry or borrow
does not occur, it is reset).
2
OV
Overflow
This flag is set if overflow occurs during operation (if overflow does not occur, it
is reset).
1
S
Sign
This flag is set if the result of operation is negative (it is reset if the result is
positive).
0
Z
Zero
This flag is set if the result of operation is zero (if the result is not zero, it is
reset).
Reserved field (fixed to 0).
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3.3
Operation Modes
3.3.1 Operation modes
The V850E/MS1 has the following operation modes. Mode specification is carried out by MODE0 to MODE3.
(1) Normal operation mode
(a) Single-chip modes 0, 1
Access to the internal ROM is enabled.
In single-chip mode 0, after system reset is cancelled, each pin related to the bus interface enters the port
mode, branches to the reset entry address of the internal ROM and starts instruction processing. The
external expansion mode, which connects an external device to external memory area, is enabled by
setting the memory expansion mode register (MM: refer to 3.4.6 (1)) with an instruction.
In single-chip mode 1, after system reset is cancelled, each pin related to the bus interface enters the
control mode, branches to the external device (memory) reset entry address and starts instruction
processing.
The internal ROM area is mapped from address 100000H.
(b) ROM-less modes 0, 1
After system reset is cancelled, each pin related to the bus interface enters the control mode, branches to
the external device (memory) reset entry address and starts instruction processing.
Fetching of
instructions and data access from internal ROM becomes impossible.
In ROM-less mode 0, the data bus is a 16-bit data bus and in ROM-less mode 1, the data bus is an 8-bit
data bus.
(2) Flash memory programming mode (µPD70F3102 and 70F3102A only)
If this mode is specified, it becomes possible for the flash programmer to run a program to the internal flash
memory.
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3.3.2 Operation mode specification
The operation mode is specified according to the status of pins MODE0 to MODE3. In an application system fix
the specification of these pins and do not change them during operation.
Operation is not guaranteed if these pins are changed during operation.
(a) µPD703100, 703100A
MODE3
MODE2
MODE1
MODE0
L
L
L
L
L
L
L
H
Other than above
Operation Mode
Normal operation
mode
External Data
Bus Width
ROM-less mode 0
16 bits
ROM-less mode 1
8 bits
Remarks
Setting prohibited
(b) µPD703101, 703101A, 703102, 703102A
MODE3
MODE2
MODE1
MODE0
L
L
L
L
L
L
L
H
L
L
H
L
L
H
Operation Mode
External Data
Bus Width
Remarks
ROM-less mode 0
16 bits
ROM-less mode 1
8 bits
L
Single-chip mode 0
Internal ROM
area is allocated
from address
000000H.
H
Single-chip mode 1
16 bits
Internal ROM
area is allocated
from address
100000H.
Other than above
Normal operation
mode
Setting prohibited
(c) µPD70F3102, 70F3102A
MODE3/
VPP
MODE2
MODE1
MODE0
0V
L
L
L
0V
L
L
H
0V
L
H
0V
L
7.8 V
L
L:
External Data
Bus Width
Remarks
ROM-less mode 0
16 bits
ROM-less mode 1
8 bits
L
Single-chip mode 0
Internal ROM
area is allocated
from address
000000H.
H
H
Single-chip mode 1
16 bits
Internal ROM
area is allocated
from address
100000H.
H
L
Flash memory programming mode
Setting prohibited
Other than above
Remark
Operation Mode
Normal operation
mode
Low-level input
H: High-level input
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3.4
Address Space
3.4.1 CPU address space
The CPU of the V850E/MS1 is of 32-bit architecture and supports up to 4 GB of linear address space (data space)
during operand addressing (data access). Also, in instruction address addressing, a maximum of 64 MB of linear
address space (program space) is supported.
Figure 3-4 shows the CPU address space.
Figure 3-4. CPU Address Space
CPU address space
FFFFFFFFH
Data area
(4 GB linear)
04000000H
03FFFFFFH
Program area
(64 MB linear)
00000000H
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3.4.2 Image
The core CPU supports 4 GB of “virtual” addressing space, or 64 memory blocks, each containing 64 MB physical
address space. In actuality, the same 64 MB physical address space is accessed regardless of the values of bits 31
to 26 of the CPU address. Figure 3-5 shows the image of the virtual addressing space.
Because the higher 6 bits of a 32-bit CPU address are disregarded and access is made to a 26-bit physical
address, physical address x0000000H can be seen as CPU address 00000000H, and in addition, can be seen as
address 04000000H, address 08000000H, address F8000000H or address FC000000H.
Figure 3-5. Image on Address Space
CPU address space
FFFFFFFFH
Image
FC000000H
FBFFFFFFH
Image
Physical address space
F8000000H
F7FFFFFFH
Peripheral I/O
x3FFFFFFH
Internal RAM
Image
(External memory)
08000000H
07FFFFFFH
Internal ROM
x0000000H
Image
04000000H
03FFFFFFH
Image
00000000H
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3.4.3 Wrap-around of CPU address space
(1) Program space
Of the 32 bits of the PC (program counter), the higher 6 bits are set to 0, and only the lower 26 bits are valid.
Even if a carry or borrow occurs from bit 25 to 26 as a result of branch address calculation, the higher 6 bits
ignore the carry or borrow.
Therefore, the lower-limit address of the program space, address 00000000H, and the upper-limit address
03FFFFFFH become contiguous addresses. Wrap-around refers to the situation that the lower-limit address
and upper-limit address become contiguous like this.
Caution
No instruction can be fetched from the 4 KB area of 03FFF000H to 03FFFFFFH because this
area is defined as the peripheral I/O area. Therefore, do not execute any branch address
calculation in which the result will reside in any part of this area.
Program space
03FFFFFEH
03FFFFFFH
(+) direction
( ) direction
00000000H
00000001H
Program space
(2) Data space
The result of an operand address calculation that exceeds 32 bits is ignored.
Therefore, the lower-limit address of the program space, address 00000000H, and the upper-limit address
FFFFFFFFH are contiguous addresses, and the data space is wrapped around at the boundary of these
addresses.
Data space
FFFFFFFEH
FFFFFFFFH
(+) direction
00000000H
00000001H
Data space
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CHAPTER 3 CPU FUNCTION
3.4.4 Memory map
The V850E/MS1 reserves areas as shown below.
Each mode is specified by the MM register and the MODE0 to MODE3 pins.
Single-chip mode 0Note 1
Single-chip mode 1Note 1
ROM-less mode 0, 1
Internal peripheral
I/O area
Internal peripheral
I/O area
Internal peripheral
I/O area
4 Kbytes
Internal RAM area
Internal RAM area
Internal RAM area
4 Kbytes
(Access prohibited)Note 2
External memory
area
External memory
area
16 Mbytes
Reserved
area
Reserved
area
Reserved
area
32 Mbytes
x3FFFFFFH
x3FFF000H
x3FFEFFFH
x3FFE000H
x3FFDFFFH
x3000000H
x2FFFFFFH
x1000000H
x0FFFFFFH
External memory
area
16 Mbytes
(Access prohibited)Note 2
External memory
area
x0200000H
x01FFFFFH
Internal ROM area
1 Mbyte
External memory
area
1 Mbyte
x0100000H
x00FFFFFH
Internal ROM area
x0000000H
Notes 1. µPD703101, 703101A, 703102, 703102A, 70F3102, and 70F3102A only
2. If the external expansion mode is set, this area can be accessed as external memory area.
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3.4.5 Area
(1) Internal ROM area (µPD703101, 703101A, 703102, 703102A, 70F3102, and 70F3102A only)
(a) Memory map
1 MB of internal ROM area, addresses 00000H to FFFFFH, is reserved.
<1> µPD703101, 703101A
96 KB of memory, addresses 00000H to 17FFFH, is provided as physical internal ROM (mask
ROM).
Also, in the remaining area (20000H to FFFFFH), the image of 00000H to 1FFFFH can be seen
(however, addresses 18000H to 1FFFFH are fixed at 1).
x00FFFFFH
Image
x00E0000H
Physical internal ROM
(Mask ROM)
x00DFFFFH
1FFFFH
1
x0040000H
18000H
17FFFH
x003FFFFH
Interrupt/exception table
00000H
Image
x0020000H
x001FFFFH
Image
x0000000H
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<2> µPD703102, 703102A
128 KB of memory, addresses 00000H to 1FFFFH, is provided as physical internal ROM (mask
ROM).
Also, in the remaining area (20000H to FFFFFH), the image of 00000H to 1FFFFH can be seen.
x00FFFFFH
Image
x00E0000H
Physical internal ROM
(Mask ROM)
x00DFFFFH
1FFFFH
x0040000H
x003FFFFH
Interrupt/exception table
00000H
Image
x0020000H
x001FFFFH
Image
x0000000H
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<3> µPD70F3102, 70F3102A
128 KB of memory, addresses 00000H to 1FFFFH, is provided as physical internal ROM (flash
memory).
Also, in the remaining area (20000H to FFFFFH), the image of 00000H to 1FFFFH can be seen.
x00FFFFFH
Image
x00E0000H
Physical internal ROM
(Flash memory)
x00DFFFFH
1FFFFH
x0040000H
x003FFFFH
Interrupt/exception table
00000H
Image
x0020000H
x001FFFFH
Image
x0000000H
(b) Interrupt/exception table
The V850E/MS1 increases the interrupt response speed by assigning handler addresses corresponding
to interrupts/exceptions.
The collection of these handler addresses is called an interrupt/exception table, which is located in the
internal ROM area. When an interrupt/exception request is granted, execution jumps to the handler
address, and the program written at that memory is executed.
Table 3-3 shows the sources of
interrupts/exceptions, and the corresponding addresses.
Remark
When in ROM-less modes 0 and 1, or in the case of the µPD703100 or 703100A, the internal
ROM area becomes an external memory area. In order to restore correct operation after reset,
provide a handler address to the reset routine in address 0 of the external memory.
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Table 3-3. Interrupt/Exception Table (1/2)
Start Address of Interrupt/Exception Table
Interrupt/Exception Source
00000000H
RESET
00000010H
NMI
00000040H
TRAP0n (n = 0 to FH)
00000050H
TRAP1n (n = 0 to FH)
00000060H
ILGOP
00000080H
INTOV10
00000090H
INTOV11
000000A0H
INTOV12
000000B0H
INTOV13
000000C0H
INTOV14
000000D0H
INTOV15
00000100H
INTP100/INTCC100
00000110H
INTP101/INTCC101
00000120H
INTP102/INTCC102
00000130H
INTP103/INTCC103
00000140H
INTP110/INTCC110
00000150H
INTP111/INTCC111
00000160H
INTP112/INTCC112
00000170H
INTP113/INTCC113
00000180H
INTP120/INTCC120
00000190H
INTP121/INTCC121
000001A0H
INTP122/INTCC122
000001B0H
INTP123/INTCC123
000001C0H
INTP130/INTCC130
000001D0H
INTP131/INTCC131
000001E0H
INTP132/INTCC132
000001F0H
INTP133/INTCC133
00000200H
INTP140/INTCC140
00000210H
INTP141/INTCC141
00000220H
INTP142/INTCC142
00000230H
INTP143/INTCC143
00000240H
INTP150/INTCC150
00000250H
INTP151/INTCC151
00000260H
INTP152/INTCC152
00000270H
INTP153/INTCC153
00000280H
INTCM40
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Table 3-3. Interrupt/Exception Table (2/2)
Start Address of Interrupt/Exception Table
Interrupt/Exception Source
00000290H
INTCM41
000002A0H
INTDMA0
000002B0H
INTDMA1
000002C0H
INTDMA2
000002D0H
INTDMA3
00000300H
INTCSI0
00000310H
INTSER0
00000320H
INTSR0
00000330H
INTST0
00000340H
INTCSI1
00000350H
INTSER1
00000360H
INTSR1
00000370H
INTST1
00000380H
INTCSI2
000003C0H
INTCSI3
00000400H
INTAD
(c) Internal ROM area relocation function
If set in single-chip mode 1, the internal ROM area is located beginning from address 100000H, so
booting from external memory becomes possible.
Therefore, in order to restore correct operation after reset, provide a handler address to the reset routine
in address 0 of the external memory.
Figure 3-6. Internal ROM Area in Single-Chip Mode 1
200000H
1FFFFFH
Internal ROM area
100000H
0FFFFFH
Block 0Note
External memory area
000000H
Note Refer to 4.3 Memory Block Function
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(2) Internal RAM area
4 KB of memory, addresses 3FFE000H to 3FFEFFFH, is provided as a physical internal RAM area.
x3FFEFFFH
Internal RAM
x3FFE000H
(3) Internal peripheral I/O area
4 KB of memory, addresses 3FFF000H to 3FFFFFFH, is provided as an internal peripheral I/O area.
x3FFFFFFH
Internal peripheral I/O
x3FFF000H
Peripheral I/O registers associated with the operation mode specification and the state monitoring for the
internal peripheral I/O are all memory-mapped to the internal peripheral I/O area. Program fetches are not
allowed in this area.
Cautions 1. The least significant bit of an address is not decoded. If byte access is executed in the
register at an odd address (2n + 1), the register at the even address (2n) will be accessed
because of the hardware specification.
2. In the V850E/MS1, no registers exist which are capable of word access, but if word
access is executed in the register, for the word area, disregarding the bottom 2 bits of
the address, halfword access is performed twice in the order of lower, then higher.
3. For registers in which byte access is possible, if halfword access is executed, the higher
8 bits become non-specific during the read operation, and the lower 8 bits of data are
written to the register during the write operation.
4. Addresses that are not defined as registers are reserved for future expansion. If these
addresses are accessed, the operation is undefined and not guaranteed.
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(4) External memory area
The following areas can be used as external memory area. However, the reserved area from x1000000H to
x2FFFFFFH is excluded.
(a) µPD703101, 703101A, 703102, 703102A, 70F3102, 70F3102A
When in single-chip mode 0:
x0100000H to x3FFDFFFH
When in single-chip mode 1:
x0000000H to x00FFFFFH, x0200000H to x3FFDFFFH
When in ROM-less modes 0 and 1:
x0000000H to x3FFDFFFH
(b) µPD703100, 703100A
x0000000H to x3FFDFFFH
Access to the external memory area uses the chip select signal assigned to each memory block (refer to 4.4
Bus Cycle Type Control Function).
Note that the internal ROM, internal RAM and internal peripheral I/O areas cannot be accessed as external
memory areas.
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3.4.6 External expansion mode
The V850E/MS1 allows external devices to be connected to the external memory space by using the pins of ports
4, 5, 6, A, and B. Setting the external expansion mode is carried out by selecting each pin of ports 4, 5, 6, A, and B in
the control mode by means of the MM register.
Note that the status at reset time differs as shown below in accordance with the operating mode specification set
by pins MODE0 to MODE3 (refer to 3.3 Operation Modes for details of the operation modes).
(1) Status at reset time in each operation mode
(a) In the case of ROM-less mode 0
At reset time, each pin of ports 4, 5, 6, A, and B enters the control mode, so the external expansion mode
is set without changing the MM register (the external data bus width is 16 bits).
(b) In the case of ROM-less mode 1
At reset time, each pin of ports 4, 5, 6, A, and B enters the control mode, so the external expansion mode
is set without changing the setting of the MM register (the external data bus width is 8 bits).
(c) In the case of single-chip mode 0
At reset time, since the internal ROM area is accessed, each pin of ports 4, 5, 6, A, and B enters the port
mode and external devices cannot be used.
Set the MM register to change to the external expansion mode.
(d)
In the case of single-chip mode 1
Internal ROM area is allocated from address 100000H (Refer to 3.4.5 (1) (c) Internal ROM area
relocation function). For that reason, at reset time, each pin of ports 4, 5, 6, A, and B enters the control
mode, and is set in the external expansion mode without changing the settings of the MM register (the
external data bus width becomes 16 bits).
(2) Memory expansion mode register (MM)
This register sets the mode of each pin of ports 4, 5, 6, A, and B. In the external expansion mode, an external
device can be connected to an external memory area of up to 32 MB. However, an external device cannot be
connected to the internal RAM area, internal peripheral I/O area, and internal ROM area in the single-chip
modes 0, 1 (even if connected physically, it does not become an access target.).
The MM register can be read/written in 8- or 1-bit units. However, bits 4 to 7 are fixed to 0.
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MM
7
6
5
4
3
2
1
0
0
0
0
0
MM3
MM2
MM1
MM0
Address
FFFFF04CH
Note When in ROM-less mode 0: 07H
When in single-chip mode 0: 00H
When in ROM-less mode 1: 0FH
When in single-chip mode 1: 07H
Bit Position
3 to 0
Bit Name
MM3 to
MM0
After reset
Note
Function
Memory Expansion Mode
Set the function of ports 4, 5, 6, A, and B.
MM3 MM2 MM1 MM0
Port 4
Port 5
Port A
Port B
Port 6
0
0
0
0
P40 to P47
P50 to P57
PA0 to PA7 PB0 to PB3 PB4, PB6, P60, P62, P64, P66,
0
0
0
1
D0 to D7
D8 to D15
A0 to A7
0
0
1
0
A12,
0
0
1
1
A13 A14,
0
1
0
0
0
1
0
1
0
1
1
0
0
1
1
1
1
0
0
0
P40 to P47
D0 to D7
A8 to A11
PB5 PB7 P61 P63 P65 P67
A15 A16,
A17 A18,
A19 A20,
A21 A22,
A23
P50 to P57
PA0 to PA7 PB0 to PB3 PB4, PB6, P60, P62, P64, P66,
1
0
0
1
1
0
1
0
A0 to A7
A8 to A11
A12,
PB5 PB7 P61 P63 P65 P67
1
0
1
1
A13 A14,
1
1
0
0
1
1
0
1
1
1
1
0
1
1
1
1
A15 A16,
A17 A18,
A19 A20,
A21 A22,
A23
Caution Write to the MM register after reset, and then do not change the set value. Also, do not access
an external memory area other than the one for this initialization routine until the initial setting
of the MM register is complete. However, it is possible to access an external memory area
whose initialization is complete.
Remarks 1. For details of the operation of each port’s pins, refer to 2.3 Description of Pin Functions.
2. The function of each port at system reset time is as shown below.
Operation Mode
88
MM Register
Port 4
Port 5
D0 to D7
D8 to D15
ROM-less mode 0
07H
ROM-less mode 1
0FH
Single-chip mode 0
00H
P40 to P47
Single-chip mode 1
07H
D0 to D7
Port A
Port B
Port 6
A0 to A7
A8 to A15
A16 to A23
P50 to P57
PA0 to PA7
PB0 to PB7
P60 to P67
D8 to D15
A0 to A7
A8 to A15
A16 to A23
P50 to P57
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3.4.7 Recommended use of address space
The architecture of the V850E/MS1 requires that a register that serves as a pointer be secured for address
generation when accessing the operand data in the data space. An instruction can be used to directly access
operand data at the address in this pointer register ±32 KB. However, the general-purpose registers that can be used
as a pointer register are limited. Therefore, by minimizing the deterioration of address calculation performance when
changing the pointer value, the number of usable general-purpose registers for handling variables is maximized, and
the program size can be saved.
To enhance the efficiency of using the pointer in connection with the memory map of the V850E/MS1, the following
points are recommended:
(1) Program space
Of the 32 bits of the PC (program counter), the higher 6 bits are fixed to 0, and only the lower 26 bits are valid.
Therefore, a contiguous 64 MB space, starting from address 00000000H, unconditionally corresponds to the
memory map of the program space.
(2) Data space
For the efficient use of resources using the wrap-around feature of the data space, the continuous 16 MB
address spaces 00000000H to 00FFFFFFH and FF000000H to FFFFFFFFH of the 4 GB CPU are used as the
data space. With the V850E/MS1, the 64 MB physical address space is seen as 64 images in the 4 GB CPU
address space. The highest bit (bit 25) of this 26-bit address is assigned as address sign-extended to 32 bits.
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Example Application of wrap-around
0001FFFFH
00007FFFH
Internal ROM area
32 Kbytes
Internal peripheral
I/O area
4 Kbytes
Internal RAM area
4 Kbytes
External memory
area
24 Kbytes
(R=) 00000000H
FFFFF000H
FFFFE000H
FFFF8000H
When R = r0 (zero register) is specified for the LD/ST disp16 [R] instruction, an addressing range of 00000000H ±32
KB can be referenced with the sign-extended, 16-bit displacement value. By mapping the external memory in the 24
KB area in the figure, all resources including internal hardware can be accessed with one pointer.
The zero register (r0) is a register set to 0 by hardware, and eliminates the need for additional registers for the pointer.
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Figure 3-7. Recommended Memory Map
Program space
Data space
FFFFFFFFH
FFFFF5F7H
FFFFF5F6H
Internal
peripheral I/O
FFFFF000H
FFFFEFFFH
Internal RAM
FFFFE000H
FFFFDFFFH
External
memory
x3FFFFFFH
Internal
peripheral I/O
FF000000H
FEFFFFFFH
04000000H
03FFFFFFH
x3FFF000H
x3FFDFFFH
03FFF000H
03FFEFFFH
External
memory
Internal RAM
03FFE000H
03FFDFFFH
Reserved
area
External
memory
64 Mbytes
01000000H
00FFFFFFH
x3000000H
x2FFFFFFH
x1000000H
x0FFFFFFH
External
memory
Reserved
area
x0100000H
x00FFFFFH
External
memory
16 Mbytes
x3FFF000H
x3FFEFFFH
Internal RAM
Internal
peripheral I/ONote
03000000H
02FFFFFFH
x3FFF5F7H
x3FFF5F6H
External
memory
00100000H
000FFFFFH
x0020000H
x001FFFFH
Internal ROM
x0000000H
00020000H
0001FFFFH
Internal ROM
Internal ROM
00000000H
Note This area cannot be used as a program area.
Remarks 1. The arrows indicate the recommended area.
2. This is a recommended memory map when the µPD703102 is set to single-chip mode 0, and
used as external expansion mode.
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3.4.8 Peripheral I/O registers
(1/8)
Address
Function Register Name
Symbol
R/W
Bit Units for Manipulation
1 bit
8 bits
{
{
16 bits
After
Reset
FFFFF000H
Port 0
P0
FFFFF002H
Port 1
P1
{
{
FFFFF004H
Port 2
P2
{
{
FFFFF006H
Port 3
P3
{
{
FFFFF008H
Port 4
P4
{
{
FFFFF00AH
Port 5
P5
{
{
FFFFF00CH
Port 6
P6
{
{
FFFFF00EH
Port 7
P7
R
{
{
FFFFF010H
Port 8
P8
R/W
{
{
FFFFF012H
Port 9
P9
{
{
FFFFF014H
Port 10
P10
{
{
FFFFF016H
Port 11
P11
{
{
FFFFF018H
Port 12
P12
{
{
FFFFF01CH
Port A
PA
{
{
FFFFF01EH
Port B
PB
{
{
FFFFF020H
Port 0 mode register
PM0
{
{
FFFFF022H
Port 1 mode register
PM1
{
{
FFFFF024H
Port 2 mode register
PM2
{
{
FFFFF026H
Port 3 mode register
PM3
{
{
FFFFF028H
Port 4 mode register
PM4
{
{
FFFFF02AH
Port 5 mode register
PM5
{
{
FFFFF02CH
Port 6 mode register
PM6
{
{
FFFFF030H
Port 8 mode register
PM8
{
{
FFFFF032H
Port 9 mode register
PM9
{
{
FFFFF034H
Port 10 mode register
PM10
{
{
FFFFF036H
Port 11 mode register
PM11
{
{
FFFFF038H
Port 12 mode register
PM12
{
{
FFFFF03CH
Port A mode register
PMA
{
{
FFFFF03EH
Port B mode register
PMB
{
{
FFFFF040H
Port 0 mode control register
PMC0
{
{
FFFFF042H
Port 1 mode control register
PMC1
{
{
FFFFF044H
Port 2 mode control register
PMC2
{
{
01H
FFFFF046H
Port 3 mode control register
PMC3
{
{
00H
FFFFF04CH
Memory expansion mode register
MM
{
{
00H/07H/
0FH
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R/W
Undefined
FFH
00H
CHAPTER 3 CPU FUNCTION
(2/8)
Address
Function Register Name
Symbol
R/W
Bit Units for Manipulation
1 bit
8 bits
{
{
16 bits
After
Reset
FFFFF050H
Port 8 mode control register
PMC8
FFFFF052H
Port 9 mode control register
PMC9
{
{
FFFFF054H
Port 10 mode control register
PMC10
{
{
FFFFF056H
Port 11 mode control register
PMC11
{
{
FFFFF058H
Port 12 mode control register
PMC12
{
{
FFFFF060H
Data wait control register 1
DWC1
{
FFFFH
FFFFF062H
Bus cycle control register
BCC
{
5555H
FFFFF064H
Bus cycle type control register
BCT
{
0000H
FFFFF066H
Bus size configuration register
BSC
{
5555H/
0000H
FFFFF06AH
Data wait control register 2
DWC2
{
{
FFH
FFFFF06CH
Fly-by transfer data wait control register
FDW
{
{
00H
FFFFF070H
Power save control register
PSC
{
{
FFFFF072H
Clock control register
CKC
{
{
FFFFF078H
System status register
SYS
{
{
0000000×B
FFFFF084H
Baud rate generator compare register 0
BRGC0
{
{
Undefined
FFFFF086H
Baud rate generator prescaler mode register 0
BPRM0
{
{
00H
FFFFF088H
Clocked serial interface mode register 0
CSIM0
{
{
FFFFF08AH
Serial I/O shift register 0
SIO0
{
{
FFFFF094H
Baud rate generator compare register 1
BRGC1
{
{
FFFFF096H
Baud rate generator prescaler mode register 1
BPRM1
{
{
FFFFF098H
Clocked serial interface mode register 1
CSIM1
{
{
FFFFF09AH
Serial I/O shift register 1
SIO1
{
{
FFFFF0A4H
Baud rate generator compare register 2
BRGC2
{
{
FFFFF0A6H
Baud rate generator prescaler mode register 2
BPRM2
{
{
FFFFF0A8H
Clocked serial interface mode register 2
CSIM2
{
{
FFFFF0AAH
Serial I/O shift register 2
SIO2
{
{
Undefined
FFFFF0B8H
Clocked serial interface mode register 3
CSIM3
{
{
00H
FFFFF0BAH
Serial I/O shift register 3
SIO3
{
{
Undefined
FFFFF0C0H
Asynchronous serial interface mode register 00
ASIM00
{
{
80H
FFFFF0C2H
Asynchronous serial interface mode register 01
ASIM01
{
{
00H
FFFFF0C4H
Asynchronous serial interface status register 0
ASIS0
{
{
FFFFF0C8H
Receive buffer 0 (9 bits)
RXB0
FFFFF0CAH
Receive buffer 0L (lower 8 bits)
RXB0L
FFFFF0CCH
Transmit shift register 0 (9 bits)
TXS0
FFFFF0CEH
Transmit shift register 0L (lower 8 bits)
TXS0L
User’s Manual U12688EJ4V0UM00
R/W
R
00H/FFH
00H
Undefined
00H
Undefined
00H
{
{
Undefined
{
{
W
{
93
CHAPTER 3 CPU FUNCTION
(3/8)
Address
Function Register Name
Symbol
FFFFF0D0H
Asynchronous serial interface mode register 10
ASIM10
FFFFF0D2H
Asynchronous serial interface mode register 11
ASIM11
FFFFF0D4H
Asynchronous serial interface status register 1
ASIS1
FFFFF0D8H
Receive buffer 1 (9 bits)
RXB1
FFFFF0DAH
Receive buffer 1L (lower 8 bits)
RXB1L
FFFFF0DCH
Transmit shift register 1 (9 bits)
TXS1
FFFFF0DEH
Transmit shift register 1L (lower 8 bits)
TXS1L
FFFFF100H
Interrupt control register
OVIC10
FFFFF102H
Interrupt control register
FFFFF104H
R/W
R/W
R
Bit Units for Manipulation
1 bit
8 bits
{
{
80H
{
{
00H
{
{
{
{
{
W
{
{
OVIC11
{
{
Interrupt control register
OVIC12
{
{
FFFFF106H
Interrupt control register
OVIC13
{
{
FFFFF108H
Interrupt control register
OVIC14
{
{
FFFFF10AH
Interrupt control register
OVIC15
{
{
FFFFF10CH
Interrupt control register
CMIC40
{
{
FFFFF10EH
Interrupt control register
CMIC41
{
{
FFFFF110H
Interrupt control register
P10IC0
{
{
FFFFF112H
Interrupt control register
P10IC1
{
{
FFFFF114H
Interrupt control register
P10IC2
{
{
FFFFF116H
Interrupt control register
P10IC3
{
{
FFFFF118H
Interrupt control register
P11IC0
{
{
FFFFF11AH
Interrupt control register
P11IC1
{
{
FFFFF11CH
Interrupt control register
P11IC2
{
{
FFFFF11EH
Interrupt control register
P11IC3
{
{
FFFFF120H
Interrupt control register
P12IC0
{
{
FFFFF122H
Interrupt control register
P12IC1
{
{
FFFFF124H
Interrupt control register
P12IC2
{
{
FFFFF126H
Interrupt control register
P12IC3
{
{
FFFFF128H
Interrupt control register
P13IC0
{
{
FFFFF12AH
Interrupt control register
P13IC1
{
{
FFFFF12CH
Interrupt control register
P13IC2
{
{
FFFFF12EH
Interrupt control register
P13IC3
{
{
FFFFF130H
Interrupt control register
P14IC0
{
{
FFFFF132H
Interrupt control register
P14IC1
{
{
FFFFF134H
Interrupt control register
P14IC2
{
{
FFFFF136H
Interrupt control register
P14IC3
{
{
User’s Manual U12688EJ4V0UM00
Undefined
{
{
94
16 bits
After
Reset
R/W
47H
CHAPTER 3 CPU FUNCTION
(4/8)
Address
Function Register Name
Symbol
R/W
Bit Units for Manipulation
1 bit
8 bits
{
{
16 bits
After
Reset
FFFFF138H
Interrupt control register
P15IC0
FFFFF13AH
Interrupt control register
P15IC1
{
{
FFFFF13CH
Interrupt control register
P15IC2
{
{
FFFFF13EH
Interrupt control register
P15IC3
{
{
FFFFF140H
Interrupt control register
DMAIC0
{
{
FFFFF142H
Interrupt control register
DMAIC1
{
{
FFFFF144H
Interrupt control register
DMAIC2
{
{
FFFFF146H
Interrupt control register
DMAIC3
{
{
FFFFF148H
Interrupt control register
CSIC0
{
{
FFFFF14AH
Interrupt control register
CSIC1
{
{
FFFFF14CH
Interrupt control register
CSIC2
{
{
FFFFF14EH
Interrupt control register
CSIC3
{
{
FFFFF150H
Interrupt control register
SEIC0
{
{
FFFFF152H
Interrupt control register
SRIC0
{
{
FFFFF154H
Interrupt control register
STIC0
{
{
FFFFF156H
Interrupt control register
SEIC1
{
{
FFFFF158H
Interrupt control register
SRIC1
{
{
FFFFF15AH
Interrupt control register
STIC1
{
{
FFFFF15CH
Interrupt control register
ADIC
{
{
FFFFF166H
In-service priority register
ISPR
R
{
{
00H
FFFFF170H
Command register
PRCMD
W
{
Undefined
FFFFF180H
External interrupt mode register 0
INTM0
{
{
00H
FFFFF182H
External interrupt mode register 1
INTM1
{
{
FFFFF184H
External interrupt mode register 2
INTM2
{
{
FFFFF186H
External interrupt mode register 3
INTM3
{
{
FFFFF188H
External interrupt mode register 4
INTM4
{
{
FFFFF18AH
External interrupt mode register 5
INTM5
{
{
FFFFF18CH
External interrupt mode register 6
INTM6
{
{
FFFFF1A0H
DMA source address register 0H
DSA0H
{
FFFFF1A2H
DMA source address register 0L
DSA0L
{
FFFFF1A4H
DMA destination address register 0H
DDA0H
{
FFFFF1A6H
DMA destination address register 0L
DDA0L
{
FFFFF1A8H
DMA source address register 1H
DSA1H
{
FFFFF1AAH
DMA source address register 1L
DSA1L
{
FFFFF1ACH
DMA destination address register 1H
DDA1H
{
FFFFF1AEH
DMA destination address register 1L
DDA1L
{
User’s Manual U12688EJ4V0UM00
R/W
R/W
47H
Undefined
95
CHAPTER 3 CPU FUNCTION
(5/8)
Address
Function Register Name
Symbol
R/W
Bit Units for Manipulation
1 bit
8 bits
16 bits
{
After
Reset
FFFFF1B0H
DMA source address register 2H
DSA2H
FFFFF1B2H
DMA source address register 2L
DSA2L
{
FFFFF1B4H
DMA destination address register 2H
DDA2H
{
FFFFF1B6H
DMA destination address register 2L
DDA2L
{
FFFFF1B8H
DMA source address register 3H
DSA3H
{
FFFFF1BAH
DMA source address register 3L
DSA3L
{
FFFFF1BCH
DMA destination address register 3H
DDA3H
{
FFFFF1BEH
DMA destination address register 3L
DDA3L
{
FFFFF1E0H
DMA byte count register 0
DBC0
{
FFFFF1E2H
DMA byte count register 1
DBC1
{
FFFFF1E4H
DMA byte count register 2
DBC2
{
FFFFF1E6H
DMA byte count register 3
DBC3
{
FFFFF1F0H
DMA addressing control register 0
DADC0
{
FFFFF1F2H
DMA addressing control register 1
DADC1
{
FFFFF1F4H
DMA addressing control register 2
DADC2
{
FFFFF1F6H
DMA addressing control register 3
DADC3
{
FFFFF200H
DRAM configuration register 0
DRC0
{
FFFFF202H
DRAM configuration register 1
DRC1
{
FFFFF204H
DRAM configuration register 2
DRC2
{
FFFFF206H
DRAM configuration register 3
DRC3
{
FFFFF210H
Refresh control register 0
RFC0
{
FFFFF212H
Refresh control register 1
RFC1
{
FFFFF214H
Refresh control register 2
RFC2
{
FFFFF216H
Refresh control register 3
RFC3
{
FFFFF218H
Refresh wait control register
RWC
FFFFF220H
DRAM type configuration register
DTC
FFFFF224H
Page-ROM configuration register
PRC
{
{
E0H
FFFFF230H
Timer overflow status register
TOVS
{
{
00H
FFFFF240H
Timer unit mode register 10
TUM10
FFFFF242H
Timer control register 10
TMC10
{
{
FFFFF244H
Timer output control register 10
TOC10
{
{
FFFFF250H
Timer 10
TM10
R
{
0000H
FFFFF252H
Capture/compare register 100
CC100
R/W
{
Undefined
FFFFF254H
Capture/compare register 101
CC101
{
FFFFF256H
Capture/compare register 102
CC102
{
FFFFF258H
Capture/compare register 103
CC103
{
96
User’s Manual U12688EJ4V0UM00
R/W
{
{
Undefined
0000H
3FC1H
0000H
00H
{
{
0000H
0000H
00H
CHAPTER 3 CPU FUNCTION
(6/8)
Address
Function Register Name
Symbol
R/W
Bit Units for Manipulation
1 bit
8 bits
16 bits
{
R/W
After
Reset
FFFFF260H
Timer unit mode register 11
TUM11
FFFFF262H
Timer control register 11
TMC11
{
{
FFFFF264H
Timer output control register 11
TOC11
{
{
FFFFF270H
Timer 11
TM11
R
{
0000H
FFFFF272H
Capture/compare register 110
CC110
R/W
{
Undefined
FFFFF274H
Capture/compare register 111
CC111
{
FFFFF276H
Capture/compare register 112
CC112
{
FFFFF278H
Capture/compare register 113
CC113
{
FFFFF280H
Timer unit mode register 12
TUM12
{
FFFFF282H
Timer control register 12
TMC12
{
{
FFFFF284H
Timer output control register 12
TOC12
{
{
FFFFF290H
Timer 12
TM12
R
{
0000H
FFFFF292H
Capture/compare register 120
CC120
R/W
{
Undefined
FFFFF294H
Capture/compare register 121
CC121
{
FFFFF296H
Capture/compare register 122
CC122
{
FFFFF298H
Capture/compare register 123
CC123
{
FFFFF2A0H
Timer unit mode register 13
TUM13
{
FFFFF2A2H
Timer control register 13
TMC13
{
{
FFFFF2A4H
Timer output control register 13
TOC13
{
{
FFFFF2B0H
Timer 13
TM13
R
{
0000H
FFFFF2B2H
Capture/compare register 130
CC130
R/W
{
Undefined
FFFFF2B4H
Capture/compare register 131
CC131
{
FFFFF2B6H
Capture/compare register 132
CC132
{
FFFFF2B8H
Capture/compare register 133
CC133
{
FFFFF2C0H
Timer unit mode register 14
TUM14
{
FFFFF2C2H
Timer control register 14
TMC14
{
{
FFFFF2C4H
Timer output control register 14
TOC14
{
{
FFFFF2D0H
Timer 14
TM14
R
{
0000H
FFFFF2D2H
Capture/compare register 140
CC140
R/W
{
Undefined
FFFFF2D4H
Capture/compare register 141
CC141
{
FFFFF2D6H
Capture/compare register 142
CC142
{
FFFFF2D8H
Capture/compare register 143
CC143
{
FFFFF2E0H
Timer unit mode register 15
TUM15
{
FFFFF2E2H
Timer control register 15
TMC15
{
{
FFFFF2E4H
Timer output control register 15
TOC15
{
{
FFFFF2F0H
Timer 15
TM15
User’s Manual U12688EJ4V0UM00
R
0000H
00H
0000H
00H
0000H
00H
0000H
00H
0000H
00H
{
0000H
97
CHAPTER 3 CPU FUNCTION
(7/8)
Address
Function Register Name
Symbol
R/W
Bit Units for Manipulation
1 bit
8 bits
16 bits
{
R/W
After
Reset
FFFFF2F2H
Capture/compare register 150
CC150
FFFFF2F4H
Capture/compare register 151
CC151
{
FFFFF2F6H
Capture/compare register 152
CC152
{
FFFFF2F8H
Capture/compare register 153
CC153
{
FFFFF342H
Timer control register 40
TMC40
{
{
FFFFF346H
Timer control register 41
TMC41
{
{
FFFFF350H
Timer 40
TM40
R
{
0000H
FFFFF352H
Compare register 40
CM40
R/W
{
Undefined
FFFFF354H
Timer 41
TM41
R
{
0000H
FFFFF356H
Compare register 41
CM41
R/W
{
Undefined
FFFFF380H
A/D converter mode register 0
ADM0
{
{
00H
FFFFF382H
A/D converter mode register 1
ADM1
{
{
07H
FFFFF390H
A/D conversion result register 0
ADCR0
FFFFF392H
A/D conversion result register 0H
ADCR0H
FFFFF394H
A/D conversion result register 1
ADCR1
FFFFF396H
A/D conversion result register 1H
ADCR1H
FFFFF398H
A/D conversion result register 2
ADCR2
FFFFF39AH
A/D conversion result register 2H
ADCR2H
FFFFF39CH
A/D conversion result register 3
ADCR3
FFFFF39EH
A/D conversion result register 3H
ADCR3H
FFFFF3A0H
A/D conversion result register 4
ADCR4
FFFFF3A2H
A/D conversion result register 4H
ADCR4H
FFFFF3A4H
A/D conversion result register 5
ADCR5
FFFFF3A6H
A/D conversion result register 5H
ADCR5H
FFFFF3A8H
A/D conversion result register 6
ADCR6
FFFFF3AAH
A/D conversion result register 6H
ADCR6H
FFFFF3ACH
A/D conversion result register 7
ADCR7
FFFFF3AEH
A/D conversion result register 7H
ADCR7H
FFFFF41AH
Port X
PX
FFFFF43AH
Port X mode register
PMX
FFFFF45AH
Port X mode control register
PMCX
FFFFF580H
Port/control select register 0
PCS0
FFFFF582H
Port/control select register 1
FFFFF586H
00H
{
R
{
Undefined
Undefined
{
{
{
{
{
{
{
{
{
{
{
{
{
{
{
{
{
{
{
{
R/W
{
{
{
{
{
FFH
{
00H/E0H
{
{
00H
PCS1
{
{
Port/control select register 3
PCS3
{
{
FFFFF590H
Port/control select register 8
PCS8
{
{
FFFFF594H
Port/control select register 10
PCS10
{
{
98
User’s Manual U12688EJ4V0UM00
W
R/W
CHAPTER 3 CPU FUNCTION
(8/8)
Address
Function Register Name
Symbol
R/W
Bit Units for Manipulation
1 bit
8 bits
R/W
{
{
FFFFF596H
Port/control select register 11
PCS11
FFFFF5D0H
DMA disable status register
DDIS
R
{
{
FFFFF5D2H
DMA restart register
DRST
R/W
{
{
FFFFF5E0H
DMA trigger factor register 0
DTFR0
{
{
FFFFF5E2H
DMA trigger factor register 1
DTFR1
{
{
FFFFF5E4H
DMA trigger factor register 2
DTFR2
{
{
FFFFF5E6H
DMA trigger factor register 3
DTFR3
{
{
FFFFF5F0H
DMA channel control register 0
DCHC0
{
{
FFFFF5F2H
DMA channel control register 1
DCHC1
{
{
FFFFF5F4H
DMA channel control register 2
DCHC2
{
{
FFFFF5F6H
DMA channel control register 3
DCHC3
{
{
User’s Manual U12688EJ4V0UM00
16 bits
After
Reset
00H
99
CHAPTER 3 CPU FUNCTION
3.4.9 Specific registers
Specific registers are registers that are protected from being written with illegal data due to erroneous program
execution, etc. The write access of these specific registers is executed in a specific sequence, and if abnormal store
operations occur, the system status register (SYS) is notified. The V850E/MS1 has two specific registers, clock
control register (CKC) and the power save control register (PSC). For details of the CKC register, refer to 8.3.3 and
for details of the PSC register, refer to 8.5.2.
The access sequence to the specific registers is shown below.
The following sequence shows the data setting of the specific registers.
<1> Provide data in the desired general-purpose register to be set in the specific register.
<2> Write the general-purpose register prepared in <1> in the command register (PRCMD).
<3> Write to the specific register using the general-purpose register prepared in <1> (do this using the following
instructions).
• Store instruction (ST/SST instruction)
• Bit operation instruction (SET1/CLR1/NOT1 instruction)
<4> If the system moves to the IDLE or software STOP mode, insert a NOP instruction (1 instruction).
Example <1> MOV
0x04, r10
<2> ST.B
r10, PRCMD [r0]
<3> ST.B
r10, PSC [r0]
<4> NOP
No special sequence is required when reading the specific registers.
Caution Do not write to the PRCMD register or to a specific register by DMA transfer.
Remarks 1. A store instruction to a command register will not be received with an interrupt.
This presupposes that this is done with the continuous store instructions in <1> and <2> above in
the program. If another instruction is placed between <1> and <2>, when an interrupt is received by
that instruction, the above sequence may not be established, and cause a malfunction, so caution is
necessary.
2. The data written in the PRCMD register is dummy data, but use the same general-purpose register
for writing to the PRCMD register (<2> in the example above) as was used in setting data in the
specific register (<3> in the example above). Addressing is the same in the case where a generalpurpose register is used.
3. It is necessary to insert 1 or more NOP instructions just after a store instruction to the PSC register
for setting it in the software STOP or IDLE mode. When releasing each power save mode by
interrupt, or when resetting after executing interrupt processing, start execution from the next
instruction without executing the instruction just after the store instruction.
100
User’s Manual U12688EJ4V0UM00
CHAPTER 3 CPU FUNCTION
[Example of Description]
ST reg_code, PRCMD
; PRCMD write
ST data, PSC
; Setting of the PSC register
(reg_code: Registration code)
NOP
; Dummy instruction (1 instruction)
(next instruction)
; Execution routine after releasing the software
STOP/IDLE mode
...
...
The case where bit operation instructions are used in the PSC register settings is the same.
(1) Command register (PRCMD)
The command register (PRCMD) is a register used when write-accessing the specific register to prevent
incorrect writing to the specific registers due to the erroneous program execution.
This register can be written in 8-bit units. It becomes undefined in a read cycle.
Occurrence of illegal store operations can be checked by the PRERR bit of the SYS register.
PRCMD
7
6
5
4
3
2
1
0
REG7
REG6
REG5
REG4
REG3
REG2
REG1
REG0
Bit Position
7 to 0
Bit Name
REG7 to
REG0
Address
FFFFF170H
After reset
Undefined
Function
Registration Code
Specific Register
Registration Code
CKC
Any 8-bit data
PSC
Any 8-bit data
User’s Manual U12688EJ4V0UM00
101
CHAPTER 3 CPU FUNCTION
(2) System status register (SYS)
This register is assigned status flags showing the operating state of the entire system. This register can be
read/written in 8- or 1-bit units.
SYS
7
6
5
4
3
2
1
0
0
0
0
PRERR
0
0
0
UNLOCK
Bit Position
4
Bit Name
PRERR
Address
FFFFF078H
After reset
0000000×B
Function
Protection Error Flag
This is a cumulative flag that shows that writing to a specific register was not done in the
Note
correct sequence and that a protection error occurred .
0: Protection error did not occur
1: Protection error occurred
0
UNLOCK
Unlock Status Flag
This is an exclusive read out flag. It shows that the PLL is in the unlocked state (for
details, refer to 8.4 PLL Lockup).
0: Locked.
1: Unlocked.
Note Operation conditions of PRERR flag
• Set conditions
(PRERR = “1”)
<1> If the store instruction most recently executed to peripheral I/O does not
write data to the PRCMD register, but to the specific register.
<2> If the first store instruction executed after the write operation to the
PRCMD register is to a peripheral I/O register other than the specific
registers.
• Reset conditions:
(PRERR = “0”)
102
<1> When “0” is written to the PRERR flag of the SYS register.
<2> At system reset.
User’s Manual U12688EJ4V0UM00
CHAPTER 4 BUS CONTROL FUNCTION
The V850E/MS1 is provided with an external bus interface function by which external memories such as ROM and
RAM, and I/O can be connected.
4.1
Features
• 16-bit/8-bit data bus sizing function
• 8-space chip select output function
• Wait function
• Programmable wait function, capable of inserting up to 7 wait states for each memory block
• External wait function via WAIT pin
• Idle state insertion function
• Bus mastership arbitration function
• Bus hold function
• Capable of connecting to external devices via alternate function pins
4.2
Bus Control Pins
The following pins are used for connecting to external devices:
Bus Control Pin (Function When in the Control Mode)
Function When in the Port
Mode
Register Which Performs
Port/Control Mode Switching
Data bus (D0 to D7)
P40 to P47 (Port 4)
MM
Data bus (D8 to D15)
P50 to P57 (Port 5)
MM
Address bus (A0 to A7)
PA0 to PA7 (Port A)
MM
Address bus (A8 to A15)
PB0 to PB7 (Port B)
MM
Address bus (A16 to A23)
P60 to P67 (Port 6)
MM
Chip select (CS0 to CS7, RAS0 to RAS7, IORD, IOWR)
P80 to P87 (Port 8)
PMC8
Read/write control (LCAS, UCAS, LWR, UWR, RD, WE, OE)
P90 to P93, P95 (Port 9)
PMC9
Bus cycle start (BCYST)
P94 (Port 9)
PMC9
External wait control (WAIT)
PX6 (Port X)
PMCX
Bus hold control (HLDAK, HLDRQ)
P96, P97 (Port 9)
PMC9
DRAM refresh control (REFRQ)
PX5 (Port X)
PMCX
Internal system clock (CLKOUT)
PX7 (Port X)
PMCX
Remark
In the case of single-chip mode 1 and ROM-less modes 0 and 1, when the system is reset, each bus
control pin becomes unconditionally valid (however, D8 to D15 are valid only in single-chip mode 1 and
ROM-less mode 0). For details, refer to 3.4.6 External expansion mode.
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CHAPTER 4 BUS CONTROL FUNCTION
4.3
Memory Block Function
The 64 MB memory space is divided into memory blocks of 2 MB, 4 MB, and 8 MB units. The programmable wait
function and bus cycle operation mode can be independently controlled for each individual memory block.
3FFFFFFH
3E00000H
3DFFFFFH
3C00000H
3BFFFFFH
Block 7
(2 MB)
3FFFFFFH
Block 6
(2 MB)
3FFF000H
3FFEFFFH
Internal peripheral I/O area
Internal RAM area
Block 5
(4 MB)
3FFE000H
3800000H
37FFFFFH
Block 4
(8 MB)
3000000H
2FFFFFFH
External memory area
Reserved area
1000000H
0FFFFFFH
Block 3
(8 MB)
0800000H
07FFFFFH
Block 2
(4 MB)
0400000H
03FFFFFH
0200000H
01FFFFFH
0000000H
Block 1
(2 MB)
Block 0
(2 MB)
Internal ROM areaNote
Note When in single-chip mode 1 and ROM-less modes 0 and 1, this becomes an external memory area.
When in single-chip mode 1, addresses 0100000H to 01FFFFF become internal ROM area.
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4.4
Bus Cycle Type Control Function
In the V850E/MS1, the following external devices can be connected directly to each memory block.
• SRAM, external ROM, external I/O
• Page ROM
• DRAM
Connected external devices are specified by the bus cycle type configuration register (BCT).
4.4.1 Bus cycle type configuration register (BCT)
This register can be read /written in 16-bit units.
15
BCT
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
BT71 BT70 BT61 BT60 BT51 BT50 BT41 BT40 BT31 BT30 BT21 BT20 BT11 BT10 BT01 BT00
Memory
block
7
Bit Position
15 to 0
6
5
4
3
2
1
Bit Name
BTn1,
BTn0
(n = 7 to 0)
Address
FFFFF064H
After reset
0000H
0
Function
Bus Cycle Type
Specifies the external device connected to memory block n.
BTn1
BTn0
External Device Connected Directly to Memory Block n
0
0
SRAM, external ROM, external I/O
0
1
Page ROM
1
0
DRAM
1
1
Setting prohibited
Note
Note Using the DTC register, one DRAM access type setting can be selected out of 4 types for each memory
block (refer to 5.3.5 DRAM type configuration register (DTC)).
Caution Write to the BCT register after reset, and then do not change the set value. Also, do not access
an external memory area other than the one for this initialization routine until the initial setting
of the BCT register is complete. However, it is possible to access an external memory area
whose initialization is complete.
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CHAPTER 4 BUS CONTROL FUNCTION
The chip select signal (CS0/RAS0 to CS7/RAS7) is output as follows in correspondence with blocks 0 to 7.
External Device
SRAM, External ROM, External I/O
Page ROM
Memory Block
Note 1
DRAM
Block 0
CS0
RAS0
Block 1
CS1
RAS1
Block 2
CS2
RAS2
Block 3
CS3
RAS3
Block 4
CS4
RAS4
Block 5
CS5
RAS5
Block 6
CS6
RAS6
CS7
RAS7
Note 2
Block 7
Notes 1. Except internal ROM area.
2. Except internal RAM area and internal peripheral I/O area.
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CHAPTER 4 BUS CONTROL FUNCTION
4.5
Bus Access
4.5.1 Number of access clocks
The number of basic clocks necessary for accessing each resource is as follows.
Bus Cycle Configuration
Instruction Fetch
Normal
Access
Resource (Bus Width)
Operand Data Access
Burst Access
Normal
Access
Burst
Access
Internal ROM (32 bits)
1
3
Internal RAM (32 bits)
1 or 2
1
Internal peripheral I/O (16 bits)
3+n
External
device
2+n
2+n
2+n
Page ROM (16/8 bits)
2+n
2+n
2+n
2+n
High-speed page DRAM (16/8 bits)
3+n
2+n
3+n
2+n
During read
3+n
2+n
During write
3+n
3+n
3+n
1+n
3+n
1+n
During read
3+n
2+n
During write
3+n
3+n
SRAM, external ROM, external I/O (16/8 bits)
During DMA flyby transfer
During DMA flyby
transfer
EDO DRAM (16/8 bits)
During DMA flyby
transfer
Remarks 1. Unit: Clock/access
2. n:
Number of wait insertions
(1) Internal peripheral I/O interface
The contents of the access to internal peripheral I/O are not output to the external bus. Therefore, during
instruction fetch access, internal peripheral I/O access can be performed in parallel.
Internal peripheral I/O access is basically 3-clock access. However, on some occasions, access to internal
peripheral I/O registers with timer/counter functions also involves a wait.
Internal Peripheral I/O Register
Access
Waits
Clock Cycles
CC1n0 to CC1n3,
TM1n (n = 0 to 5)
Read
1
4
Write
0/1
3/4
CM40, CM41
Read
0
3
Write
0/1
3/4
Read
0/1
3/4
Write
0
3
Read
0
3
Write
0
3
TM40, TM41
Other
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CHAPTER 4 BUS CONTROL FUNCTION
4.5.2 Bus sizing function
The V850E/MS1 is provided with a bus sizing function that is used to control the data bus width of each memory
block.
The data bus width is specified by using the bus size configuration register (BSC).
(1) Bus size configuration register (BSC)
This register can be read/written in 16-bit units.
15
BSC
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
BS71 BS70 BS61 BS60 BS51 BS50 BS41 BS40 BS31 BS30 BS21 BS20 BS11 BS10 BS01 BS00
Memory
block
7
6
5
4
3
2
1
Address
FFFFF066H
After reset
Note
0
Note When in single-chip modes 0, 1: 5555H
When in ROM-less mode 0:
5555H
When in ROM-less mode 1:
0000H
Bit Position
15 to 0
Bit Name
BSn1,
BSn0
(n = 7 to 0)
Function
Data Bus Width
Sets the data bus width of memory block n.
BSn1
BSn0
Data Bus Width of Memory Block n
0
0
8 bits
0
1
16 bits
1
Optional
RFU (Reserved)
Cautions 1. Write to the BSC register after reset, and then do not change the set value. Also, do not
access an external memory area other than the one for this initialization routine until the
initial setting of the BSC register is complete. However, it is possible to access an external
memory area whose initialization is complete.
2. The in-circuit emulator (IE-703102-MC) for the V850E/MS1 does not support 8-bit width
external ROM emulation.
3. When 8-bit data bus width is selected, only the write signal LWR becomes active, UWR
does not become active.
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CHAPTER 4 BUS CONTROL FUNCTION
4.5.3 Bus width
V850E/MS1 carries out peripheral I/O access and external memory access in 8, 16, or 32 bits. The following
shows the operation for each access. All data is accessed in order from the lower side.
(1) Byte access (8 bits)
(a) When the data bus width is 16 bits
<1> Access to address 2n (even address)
<2> Access to address 2n + 1 (odd address)
Address
15
8
7
8
7
7
7
2n
0
External
data bus
0
Byte
data
Remark
Address
15
0
Byte
data
2n + 1
0
External
data bus
n = 0, 1, 2, 3, ···
(b) When the data bus width is 8 bits
<1> Access to address 2n (even address)
<2> Access to address 2n + 1 (odd address)
Address
7
0
Byte
data
Remark
Address
7
7
2n
0
External
data bus
7
0
Byte
data
2n + 1
0
External
data bus
n = 0, 1, 2, 3, ···
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CHAPTER 4 BUS CONTROL FUNCTION
(2) Halfword access (16 bits)
In halfword access to external memory, data is exchanged as is, or accessed in the order of lower byte, then
higher byte.
(a) When the data bus width is 16 bits
<1> Access to address 2n (even address)
<2> Access to address 2n + 1 (odd address)
First
Address
Remark
15
15
8
7
8
7
0
Halfword
data
0
2n + 1
2n
External
data bus
Second
Address
15
15
8
7
8
7
0
Halfword
data
0
2n + 1
External
data bus
15
15
8
7
8
7
0
Halfword
data
0
Address
2n + 2
External
data bus
n = 0, 1, 2, 3, ···
(b) When the data bus width is 8 bits
<1> Access to address 2n (even address)
First
Second
15
8
7
0
Halfword
data
Remark
<2> Access to address 2n + 1 (odd address)
First
15
Address
7
0
2n
External
data bus
8
7
0
Halfword
data
Second
15
Address
7
0
2n + 1
External
data bus
8
7
0
Halfword
data
15
Address
7
0
2n + 1
External
data bus
8
7
0
Halfword
data
Address
7
0
2n + 2
External
data bus
n = 0, 1, 2, 3, ···
(3) Word access (32 bits)
In word access to external memory, data is accessed in order from the lower halfword, then the higher
halfword, or in order from the lowest byte to the highest byte.
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CHAPTER 4 BUS CONTROL FUNCTION
(a) When the data bus width is 16 bits
<1> Access to address 4n
First
31
31
24
23
Second
24
23
Address
16
15
15
8
7
8
7
0
Word
data
0
4n + 1
4n
Address
16
15
15
8
7
8
7
0
Word
data
External
data bus
4n + 3
4n + 2
0
External
data bus
<2> Access to address 4n + 1
31
First
31
24
23
Second
31
24
23
Address
16
15
15
8
7
8
7
0
Word
data
0
4n + 1
External
data bus
Third
24
23
Address
16
15
15
8
7
8
7
0
Word
data
0
4n + 3
4n + 2
External
data bus
Address
16
15
15
8
7
8
7
0
Word
data
0
4n + 4
External
data bus
<3> Access to address 4n + 2
31
First
31
24
23
Second
24
23
Address
16
15
15
8
7
8
7
0
Word
data
0
4n + 3
4n + 2
External
data bus
Address
16
15
15
8
7
8
7
0
Word
data
0
4n + 5
4n + 4
External
data bus
<4> Access to address 4n + 3
31
First
31
24
23
Remark
Second
31
24
23
Address
16
15
15
8
7
8
7
0
Word
data
0
4n + 3
External
data bus
Third
24
23
Address
16
15
15
8
7
8
7
0
Word
data
0
4n + 5
4n + 4
External
data bus
Address
16
15
15
8
7
8
7
0
Word
data
0
4n + 6
External
data bus
n = 0, 1, 2, 3, ···
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CHAPTER 4 BUS CONTROL FUNCTION
(b) When the data bus width is 8 bits
<1> Access to address 4n
31
First
31
Second
31
Third
31
24
23
24
23
24
23
24
23
16
15
16
15
16
15
16
15
8
7
0
Word
data
Address
7
4n
0
External
data bus
8
7
0
Word
data
Address
7
0
4n + 1
External
data bus
8
7
0
Word
data
Address
7
4n + 2
0
External
data bus
8
7
0
Word
data
Fourth
Address
7
4n + 3
0
External
data bus
<2> Access to address 4n + 1
31
First
31
Second
31
Third
31
24
23
24
23
24
23
24
23
16
15
16
15
16
15
16
15
8
7
0
Word
data
Address
7
4n + 1
0
External
data bus
8
7
0
Word
data
Address
7
0
4n + 2
External
data bus
8
7
0
Word
data
Address
7
4n + 3
0
External
data bus
8
7
0
Word
data
Fourth
Address
7
4n + 4
0
External
data bus
<3> Access to address 4n + 2
31
First
31
Second
31
Third
31
24
23
24
23
24
23
24
23
16
15
16
15
16
15
16
15
8
7
0
Word
data
Address
7
4n + 2
0
External
data bus
8
7
0
Word
data
Address
7
0
4n + 3
External
data bus
8
7
0
Word
data
Address
7
4n + 4
0
External
data bus
8
7
0
Word
data
Fourth
Address
7
4n + 5
0
External
data bus
<4> Access to address 4n + 3
31
Second
31
Third
31
24
23
24
23
24
23
16
15
16
15
16
15
16
15
0
Word
data
112
31
24
23
8
7
Remark
First
Address
7
0
4n + 3
External
data bus
8
7
0
Word
data
Address
7
0
4n + 4
External
data bus
8
7
0
Word
data
Address
7
4n + 5
0
External
data bus
n = 0, 1, 2, 3, ···
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8
7
0
Word
data
Fourth
Address
7
0
4n + 6
External
data bus
CHAPTER 4 BUS CONTROL FUNCTION
4.6
Wait Function
4.6.1 Programmable wait function
With the aim of realizing easy interfacing with low-speed memory or with I/Os, it is possible to insert up to 7 data
wait states with respect to the starting bus cycle for each memory block.
The number of wait states can be set by data wait control registers 1 and 2 (DWC1, DWC2) and can be specified
by program. Just after system reset, all blocks have 7 data wait states inserted.
(1) Data wait control registers 1, 2 (DWC1, DWC2)
It is possible to read/write the DWC1 register in 16-bit units and the DWC2 register in 8/1-bit units.
14
15
DWC1
11
10
9
8
7
5
4
3
2
1
0
6
5
4
3
2
1
0
7
6
5
4
3
2
1
0
DW72
DW62
DW52
DW42
DW32
DW22
DW12
DW02
7
6
5
4
3
2
1
0
Register
Name
Bit
Position
Bit Name
15 to 0
DWn1,
DWn0
(n = 7 to 0)
7 to 0
DWn2
(n = 7 to 0)
Address
FFFFF060H
After reset
FFFFH
Address
FFFFF06AH
After reset
FFH
Function
Data Wait
Specifies the number of wait states inserted in memory block n.
Registers DWC1 and DWC2 are set in combination.
DWn2
DWC2
6
7
Memory
block
DWC1
12
DW71 DW70 DW61 DW60 DW51 DW50 DW41 DW40 DW31 DW30 DW21 DW20 DW11 DW10 DW01 DW00
Memory
block
DWC2
13
DWn1
DWn0
Number of Wait States Inserted in
Memory Block n
0
0
0
0
0
0
1
1
0
1
0
2
0
1
1
3
1
0
0
4
1
0
1
5
1
1
0
6
1
1
1
7
Cautions 1. The internal ROM area and internal RAM area are not subject to programmable waits and
ordinarily no wait access is carried out. Neither is the internal peripheral I/O area subject
to programmable wait states, with wait control performed only by each peripheral function.
2. In the following cases, the settings of registers DWC1 and DWC2 are invalid (wait control
is performed by each memory controller).
• DRAM access
• Page ROM on-page access
3. Write to the DWC1 and DWC2 registers after reset, and then do not change the set values.
Also, do not access an external memory area other than the one for this initialization
routine until the initial setting of the DWC1 and DWC2 registers is complete. However, it is
possible to access an external memory area whose initialization is complete.
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CHAPTER 4 BUS CONTROL FUNCTION
4.6.2 External wait function
When an extremely slow device, I/O, or asynchronous system is connected, any number of wait states can be
inserted in a bus cycle by the external wait pin (WAIT) to synchronize with the external device.
Just as with programmable waits, access to internal ROM, internal RAM and internal peripheral I/O areas cannot
be controlled by external waits.
Input of the external WAIT signal can be done asynchronously to CLKOUT and is sampled at the falling edge of the
clock in the T1 and TW states of a bus cycle. If the setup/hold time in the sampling timing is not satisfied, a wait may
or may not be inserted in the next state.
4.6.3 Relationship between programmable wait and external wait
A wait cycle is inserted as a result of an OR operation between the wait cycle specified by the set value of
programmable wait and the wait cycle controlled by the WAIT pin. In other words, the number of wait cycles is
determined by whichever has the most cycles.
Programmable wait
Wait control
Wait by WAIT pin
For example, if the programmable wait is two waits, and the timing of the WAIT pin input signal is as illustrated
below, three wait states will be inserted in the bus cycle.
Figure 4-1. Example of Inserting Wait States
T1
TW
TW
CLKOUT
WAIT pin
Wait by WAIT pin
Programmable wait
Wait control
Remark
114
{: Sampling timing
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TW
T2
CHAPTER 4 BUS CONTROL FUNCTION
4.6.4 Bus cycles in which the wait function is valid
In the V850E/MS1, the number of waits can be specified according to the type of memory specified for each
memory block.
The registers which set the bus cycles and waits in which the wait function is valid are as shown below.
Table 4-1. Bus Cycles in Which the Wait Function Is Valid (1/2)
Bus Cycle
Type of Wait
Programmable Wait Setting
Higher Order: Register
Lower Order: Bit
SRAM, external ROM, external I/O cycle
Data access wait
DWC1, DWC2
Page ROM cycle
Off-page
Data access wait
DWC1, DWC2
On-page
Data access wait
PRC
Number
of Waits
Wait by
WAIT Pin
0 to 7
{
0 to 7
{
0 to 7
{
0 to 3
×
0 to 3
×
0 to 3
Note
0 to 3
×
0 to 3
×
0 to 3
×
0 to 3
Note
0 to 3
×
0 to 3
×
0 to 3
×
0 to 3
×
0 to 7
×
DWxx
DWxx
PRW0 to PRW2
EDO DRAM, highspeed page DRAM
cycle
Read access
Off-page
RAS pre-charge
DRCn
RPC0n, RPC1n
Row address hold
DRCn
Data access wait
DRCn
CAS pre-charge
DRCn
Data access wait
DRCn
RAS pre-charge
DRCn
RHC0n, RHC1n
DAC0n, DAC1n
On-page
CPC0n, CPC1n
DAC0n, DAC1n
Write access
Off-page
RPC0n, RPC1n
Row address hold
DRCn
RHC0n, RHC1n
Data access wait
DRCn
DAC0n, DAC1n
On-page
CAS pre-charge
DRCn
Data access wait
DRCn
RAS pre-charge
RWC
RAS active width
RWC
CPC0n, CPC1n
DAC0n, DAC1n
CBR refresh cycle
RRW0, RRW1
RCW0 to RCW2
×
Note EDO DRAM cycle:
High-speed page DRAM cycle:{
Remarks 1. {: Valid
×: Invalid
2. n = 0 to 3
xx = 00 to 02, 10 to 12, 20 to 22, 30 to 32, 40 to 42, 50 to 52, 60 to 62, 70 to 72
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CHAPTER 4 BUS CONTROL FUNCTION
Table 4-1. Bus Cycles in Which the Wait Function Is Valid (2/2)
Bus Cycle
Type of Wait
Programmable Wait Setting
Higher Order: Register
Lower Order: Bit
CBR self-refresh cycle
RAS pre-charge
RWC
Number
of Waits
Wait by
WAIT Pin
0 to 3
×
0 to 7
×
0 to 14
×
0 to 7
{
0, 1
×
0 to 3
×
0 to 3
×
0 to 3
{
0, 1
×
0 to 3
×
0 to 3
{
0, 1
×
0 to 3
×
0 to 3
{
0 to 3
×
0, 1
×
1 to 3
{
0 to 3
×
0, 1
×
RRW0, RRW1
RAS active width
RWC
Self-refresh
release width
RWC
RCW0 to RCW2
DMA flyby transfer
cycle
External I/O ↔ SRAM
Data access
wait
SRW0 to SRW2
TW
DWC1, DWC2
DWxx
TF
FDW
FDWm
DRAM →
External I/O
Off-page
RAS pre-charge
DRCn
RPC0n, RPC1n
Row address hold
DRCn
RHC0n, RHC1n
Data access
wait
TW
DRCn
DAC0n, DAC1n
TF
FDW
FDWm
On-page
CAS pre-charge
DRCn
CPC0n, CPC1n
Data access
wait
TW
DRCn
DAC0n, DAC1n
TF
FDW
FDWm
External I/O
→ DRAM
Off-page
RAS pre-charge
DRCn
RPC0n, RPC1n
Row address hold
DRCn
RHC0n, RHC1n
Data access
wait
TW
DRCn
DAC0n, DAC1n
TF
FDW
FDWm
On-page
CAS pre-charge
DRCn
Data access
wait
DRCn
CPC0n, CPC1n
TW
DAC0n, DAC1n
TF
FDW
FDWm
Remarks 1. {: Valid
×: Invalid
2. n = 0 to 3
m = 0 to 7
xx = 00 to 02, 10 to 12, 20 to 22, 30 to 32, 40 to 42, 50 to 52, 60 to 62, 70 to 72
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CHAPTER 4 BUS CONTROL FUNCTION
4.7
Idle State Insertion Function
To facilitate interfacing with low-speed memory devices, an idle state (TI) can be inserted into the current bus cycle
after the T2 state in order to meet the data output float delay time (tDF) on memory read accesses for each memory
block. The bus cycle following the T2 state starts after the idle state is inserted.
Specifying insertion of the idle state is programmable by setting the bus cycle control register (BCC).
Immediately after the system reset is cancelled, idle state insertion is automatically programmed for all memory
blocks.
The idle state is inserted only if the read cycle is followed by a write cycle.
(1) Bus cycle control register (BCC)
This register can be read/written in 16-bit units.
14
15
BCC
13
12
11
10
9
8
7
6
5
4
3
2
1
0
BC71 BC70 BC61 BC60 BC51 BC50 BC41 BC40 BC31 BC30 BC21 BC20 BC11 BC10 BC01 BC00
Memory
block
7
Bit Position
15 to 0
6
5
4
3
2
Bit Name
BCn1,
BCn0
(n = 7 to 0)
1
Address
FFFFF062H
After reset
5555H
0
Function
Bus Cycle
Specifies insertion of an idle state in memory block n.
BCn1
BCn0
Idle State in Memory Block n
0
0
Not inserted
0
1
Inserted
1
Optional
RFU (Reserved)
Cautions 1. The internal ROM area, internal RAM area and internal peripheral I/O area are not subject to
insertion of an idle state.
2. Write to the BCC register after reset, and then do not change the set value. Also, do not
access an external memory area other than the one for this initialization routine until the
initial setting of the BCC register is complete.
However, it is possible to access an
external memory area whose initialization is complete.
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CHAPTER 4 BUS CONTROL FUNCTION
(2) Idle state insertion timing
T1
T2
TI
T1
T2
CLKOUT
A0 to A23
Address
Address
BCYST
CSn/RASn
RD
OE
WE
UWR/UCAS
LWR/LCAS
IORD
IOWR
D0 to D15
Data
WAIT
Remarks 1. The circle indicates the sampling timing.
2. The broken lines indicate high impedance.
3. n = 0 to 7
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4.8
Bus Hold Function
4.8.1 Outline of function
If pins P96 and P97 are specified in the control mode, the HLDAK and HLDRQ functions become valid.
If it is determined that the HLDRQ pin has become active (low level) as a bus acquisition request from another bus
master, the external address/data bus and each strobe pin are shifted to high impedance and released (bus hold
state). If the HLDRQ pin becomes inactive (high level) and the bus acquisition request is canceled, driving of these
pins begins again.
During the bus hold interval, internal operations in the V850E/MS1 continue until there is external memory access.
The bus hold state can be known by the HLDAK pin becoming active (low level).
In a multiprocessor configuration, etc., a system that has multiple bus masters can be configured.
Note that bus hold requests are not received with the following timings.
Caution The HLDRQ function is invalid during the reset period. When the RESET pin and HLDRQ pin are
made active simultaneously, and then the RESET pin is made inactive, the HLDAK pin becomes
active after a one-clock idle cycle has been inserted. Note that for a power-on reset, even if the
RESET pin and HLDRQ pin are made active simultaneously, and then the RESET pin is made
inactive, the HLDAK pin does not become active. When a bus master other than the V850E/MS1
is externally connected, execute arbitration at the moment of power-on using the RESET signal.
State
CPU bus lock
Data Bus Width
16 bits
Access Configuration
Timing in Which Bus Hold
Request Will Not Be Received
Word access to even address
Between 1st and 2nd times
Word access to odd address
Between 1st and 2nd times
Between 2nd and 3rd times
8 bits
Halfword access to odd address
Between 1st and 2nd times
Word access
Between 1st and 2nd times
Between 2nd and 3rd times
Between 3rd and 4th times
Halfword access
Read modify write access to
bit operation instruction
Between 1st and 2nd times
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access
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4.8.2 Bus hold procedure
The procedure of the bus hold function is illustrated below.
<1> HLDRQ = 0 accepted
<2> All bus cycle start request pending
<3> End of current bus cycle
Normal state
<4> Transition to bus idle state
<5> HLDAK = 0
Bus hold state
<6> HLDRQ = 1 accepted
<7> HLDAK = 1
<8> Clears bus cycle start request pending
Normal state
<9> Start of bus cycle
HLDRQ (Input)
HLDAK (Output)
<1> <2> <3><4><5>
<6> <7><8><9>
4.8.3 Operation in power save mode
In the STOP or IDLE mode, the internal system clock is stopped. Consequently, the bus hold state is not accepted
and set even if the HLDRQ pin becomes active.
In the HALT mode, the HLDAK pin immediately becomes active when the HLDRQ pin becomes active, and the bus
hold state is set. When the HLDRQ pin becomes inactive, the HLDAK pin becomes inactive. As a result, the bus hold
state is cleared, and the HALT mode is set again.
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4.8.4 Bus hold timing
TO1
TO2
TI
TH
TH
TH
TI
CLKOUT
HLDRQ
Note
Note
HLDAK
A0 to A23
Column address
Undefined
BCYST
CSn/RASn
RD
OE
WE
UWR/UCAS
LWR/LCAS
IORD
IOWR
D0 to D15
Data
WAIT
Note If HLDRQ signal is inactive (high level) at this sampling timing, bus hold state is not entered.
Remarks 1. The circle indicates the sampling timing.
2. The broken lines indicate high impedance.
3. n = 0 to 7
4. Timing from DRAM access to bus hold state.
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4.9
Bus Priority Order
There are five external bus cycles: bus hold, instruction fetch, operand data access, DMA cycle and refresh cycle.
Bus hold has the highest priority, then the refresh cycle, DMA cycle, instruction fetch and operand data access, in
descending order.
Between read access and write access in read modify write access, an instruction fetch may be inserted.
Also, between bus access and bus access during CPU bus lock, an instruction fetch may be inserted.
Table 4-2. Bus Priority Order
Priority Order
High
Low
External Bus Cycle
Bus Master
Bus hold
External device
Refresh cycle
DRAM controller
DMA cycle
DMA controller
Instruction fetch
CPU
Operand data access
CPU
4.10 Boundary Operation Conditions
4.10.1 Program space
(1) Branching to the peripheral I/O area or successive fetch from the internal RAM area to the internal peripheral
I/O area is prohibited. In terms of hardware, fetching the NOP op code continues, and fetching from the
external memory is not performed.
(2) If a branch instruction exists at the upper limit of the internal RAM area, a pre-fetch operation (invalid fetch)
that straddles over the internal peripheral I/O area does not occur when instruction fetch is performed.
(3) In burst fetch mode, if an instruction fetch is performed for contiguous memory blocks, the burst fetch is
terminated at the upper limit of a block, and the start-up cycle is started at the lower limit of the next block.
(4) Burst fetch is valid only in the external memory area. In memory block 7, it is terminated when the internal
address count value has reached the upper limit of the external memory area.
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4.10.2 Data space
The V850E/MS1 incorporates an address misalign function.
Through this function, regardless of the data format (word data, halfword data), data can be placed in all
addresses. However, in the case of word data and halfword data, if data is not subject to boundary alignment, the bus
cycle will be generated at least 2 times and bus efficiency will drop.
(1) In the case of halfword length data access
When the address’s lowest bit is a 1, the byte length bus cycle will be generated 2 times.
(2) In the case of word length data access
(a) When the address’s lowest bit is a 1, bus cycles will be generated in the order of byte length bus cycle,
halfword length bus cycle, and byte length bus cycle.
(b) When the address’s lower 2 bits are 10, the halfword length bus cycle will be generated 2 times.
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[MEMO]
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5.1
SRAM, External ROM, External I/O Interface
5.1.1 SRAM connections
An example of connection to SRAM is shown below.
Figure 5-1. Example of Connection to SRAM
A1 to A17
A0 to A16
D0 to D7
I/O1 to I/O8
D8 to D15
CSn
CS
UWR
LWR
WE
RD
HVDD
OE
5V
5V
VCC
1 Mbit (128 K × 8) SRAM
V850E/MS1
A0 to A16
I/O1 to I/O8
CS
WE
OE
5V
VCC
1 Mbit (128 K × 8) SRAM
Remark
n = 0 to 7
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5.1.2 SRAM, external ROM, external I/O access
Figure 5-2. SRAM, External ROM, External I/O Access Timing (1/4)
(a) During read
T1
T2
T1
TW
T2
CLKOUT
A0 to A23
Address
Address
BCYST
CSn/RASn
RD
OE
WE
UWR/UCAS
LWR/LCAS
IORD
IOWR
D0 to D15
Data
WAIT
Remarks 1. The circle indicates the sampling timing.
2. The broken lines indicate high impedance.
3. n = 0 to 7
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CHAPTER 5 MEMORY ACCESS CONTROL FUNCTION
Figure 5-2. SRAM, External ROM, External I/O Access Timing (2/4)
(b) During write
T1
T2
T1
TW
T2
CLKOUT
A0 to A23
Address
Address
BCYST
CSn/RASn
RD
OE
WE
UWR/UCAS
LWR/LCAS
IORD
IOWR
D0 to D15
Data
Data
WAIT
Remarks 1. The circle indicates the sampling timing.
2. The broken lines indicate high impedance.
3. n = 0 to 7
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Figure 5-2. SRAM, External ROM, External I/O Access Timing (3/4)
(c) During DMA flyby transfer (SRAM → External I/O)
T1
T2
T1
T2
TF
T1
TW
CLKOUT
A0 to A23
Address
Address
Address
BCYST
CSn/RASn
RD
OE
WE
UWR/UCAS
LWR/LCAS
IORD
IOWR
D0 to D15
Data
Data
WAIT
DMAAKm
Remarks 1. The circle indicates the sampling timing.
2. The broken lines indicate high impedance.
3. n = 0 to 7
4. m = 0 to 3
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T2
CHAPTER 5 MEMORY ACCESS CONTROL FUNCTION
Figure 5-2. SRAM, External ROM, External I/O Access Timing (4/4)
(d) During DMA flyby transfer (External I/O → SRAM)
T1
T2
T1
T2
TF
T1
TW
T2
CLKOUT
Address
A0 to A23
Address
Address
Data
Data
BCYST
CSn/RASn
RD
OE
WE
UWR/UCAS
LWR/LCAS
IORD
IOWR
Data
D0 to D15
WAIT
DMAAKm
Remarks 1. The circle indicates the sampling timing.
2. The broken lines indicate high impedance.
3. n = 0 to 7
4. m = 0 to 3
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CHAPTER 5 MEMORY ACCESS CONTROL FUNCTION
5.2
Page ROM Controller (ROMC)
The page ROM controller (ROMC) is for access to ROM (page ROM) with a page access function.
Comparison of addresses with the immediately previous bus cycle is carried out and wait control for normal access
(off-page) and page access (on-page) is executed. This controller is capable of handling page widths of from 8 to 64
bytes.
5.2.1 Features
• It can connect directly to 8-bit/16-bit page ROM.
• When the bus width is 16 bits, it can handle 4/8/16/32-word page access.
When the bus width is 8 bits, it can handle 8/16/32/64-word page access.
• Individual wait settings (0 to 7 waits) for off-page and on-page are possible.
5.2.2 Page ROM connections
Examples of page ROM connections are shown below.
Figure 5-3. Example of Page ROM Connections (1/2)
(a) In the case of 16 Mbit (1 M × 16) page ROM
A1 to A20
A0 to A19
D0 to D15
O1 to O16
RD
OE
CSn
CE
VDD
WORD/BYTE
16 Mbit page-ROM (1 M × 16)
V850E/MS1
Remark
130
n = 0 to 7
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CHAPTER 5 MEMORY ACCESS CONTROL FUNCTION
Figure 5-3. Example of Page ROM Connections (2/2)
(b) In the case of 16 Mbit (2 M × 8) page ROM
A1 to A20
A0 to A19
D0 to D7
O0 to O7
RD
OE
CSn
CE
WORD/BYTE
D8 to D15
16 Mbit page-ROM (2 M × 8)
V850E/MS1
A0 to A19
O0 to O7
OE
CE
WORD/BYTE
16 Mbit page-ROM (2 M × 8)
Remark
n = 0 to 7
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5.2.3 On-page/off-page judgment
Whether a page ROM cycle is on-page or off-page is judged by latching the address of the previous cycle and
comparing it with the address of the current cycle.
Using the page ROM configuration register (PRC), one of the addresses (A3 to A5) is set as the masking address
(no comparison is made) according to the configuration of the connected page ROM and the number of continuously
readable bits.
Figure 5-4. On-Page/Off-Page Judgment for Page ROM Connection (1/2)
(a) In the case of 16 Mbit (1 M × 16) page ROM (4-word page access)
Internal address latch
a23
a22
a21
a20
a19
a18
a5
a4
a3
MA5 MA4 MA3
0
0
0
PRC register setting
Comparison
A23
A22
A21
A20
A19
A18
A5
A4
A3
A2
A1
Page ROM address
A19
A18
A17
A4
A3
A2
A1
A0
A0
V850E/MS1
address output
Off-page address
On-page address
Continuous reading possible:
16-bit data bus width × 4 words
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Figure 5-4. On-Page/Off-Page Judgment for Page ROM Connection (2/2)
(b) In the case of 16 Mbit (2 M × 8) page ROM (8-word page access)
Internal address latch
a23
a22
a21
a20
a19
a18
a5
a4
a3
MA5 MA4 MA3
0
0
0
PRC register setting
Comparison
V850E/MS1
address output
A23
A22
A21
A20
A19
A18
A5
A4
A3
A2
A1
A0
Page ROM address
A19
A18
A17
A4
A3
A2
A1
A0
A–1
Off-page address
On-page address
Continuous reading possible:
8-bit data bus width × 8 words
(c) In the case of 16 Mbit (1 M × 16) Page ROM (8-word page access)
Internal address latch
a23
a22
a21
a20
a19
a18
a5
a4
a3
MA5 MA4 MA3
0
0
1
PRC register setting
Comparison
V850E/MS1
address output
A23
A22
A21
A20
A19
A18
A5
A4
A3
A2
A1
Page ROM address
A19
A18
A17
A4
A3
A2
A1
A0
Off-page address
A0
On-page address
Continuous reading possible:
16-bit data bus width × 8 words
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CHAPTER 5 MEMORY ACCESS CONTROL FUNCTION
5.2.4 Page ROM configuration register (PRC)
This specifies whether page ROM on-page access is enabled or disabled. Also, if on-page access is enabled, the
masked addresses (no comparison is made) out of the addresses (A3 to A5) corresponding to the configuration of the
connected page ROM and the number of bits that can be read continuously, as well as the number of waits
corresponding to the internal system clock, are set.
This register can be read/written in 8- or 1-bit units.
PRC
7
6
5
4
3
2
1
0
PAE
PRW2
PRW1
PRW0
0
MA5
MA4
MA3
Bit Position
7
6 to 4
2 to 0
Bit Name
Address
FFFFF224H
After reset
70H
Function
PAE
Page ROM On-page Access Enable
Specifies whether page ROM on-page access is enabled or disabled.
0: Disable
1: Enable
PRW2 to
PRW0
Page-ROM On-page Access Wait Control
Sets the number of waits corresponding to the internal system clock.
The waits set by this bit are inserted only for on-page access. For off-page access, the
waits set by registers DWC1 and DWC2 are inserted (refer to 4.6 Wait Function).
MA5 to
MA3
PRW2
PRW1
PRW0
Number of Inserted Wait Cycles
0
0
0
0
0
0
1
1
0
1
0
2
0
1
1
3
1
0
0
4
1
0
1
5
1
1
0
6
1
1
1
7
Mask Address
Each address (A5 to A3) corresponding to MA5 to MA3 is masked (by 1). The masked
address is not subject to comparison during on/off-page judgment. It is set according to
the number of continuously readable bits.
MA5
MA4
MA3
Number of Continuously Readable Bits
0
0
0
4 words × 16 bits (8 words × 8 bits)
0
0
1
8 words × 16 bits (16 words × 8 bits)
0
1
1
16 words × 16 bits (32 words × 8 bits)
1
1
1
32 words × 16 bits (64 words × 8 bits)
Caution Write to the PRC register after reset, and then do not change the set value. Also, do not access
an external memory area other than the one for this initialization routine until the initial setting
of the PRC register is complete. However, it is possible to access an external memory area
whose initialization is complete.
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CHAPTER 5 MEMORY ACCESS CONTROL FUNCTION
5.2.5 Page ROM access
Figure 5-5. Page ROM Access Timing
T1
TW
T2
TO1
TO2
CLKOUT
A0 to A23
Off-page address
On-page address
On-page address
BCYST
CSn/RASn
RD
OE
WE
UWR/UCAS
LWR/LCAS
IORD
IOWR
Data
D0 to D15
Data
WAIT
Remarks 1. The circle indicates the sampling timing.
2. The broken lines indicate high impedance.
3. n = 0 to 7
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CHAPTER 5 MEMORY ACCESS CONTROL FUNCTION
5.3
DRAM Controller
5.3.1 Features
{ Generates the RAS, LCAS and UCAS signals.
{ Can be connected directly to high-speed page DRAM and EDO DRAM.
{ Supports the RAS hold mode.
{ 4 types of DRAM can be assigned to 8 memory block spaces.
{ Can handle 2CAS type DRAM
{ Can be switched between row and column address multiplex widths.
{ Waits (0 to 3 waits) can be inserted at the following timings.
• Row address precharge wait
• Row address hold wait
• Data access wait
• Column address precharge wait
{ Supports CBR refresh and CBR self-refresh.
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5.3.2 DRAM connections
Examples of connections to DRAM are shown below.
Figure 5-6. Examples of Connections to DRAM
(a) In the case of 16 Mbit (1 M × 16) DRAM
A1 to A10
A0 to A9
D0 to D15
I/O1 to I/O16
RASn
RAS
LCAS
UCAS
WE
OE
LCAS
UCAS
WE
OE
16 Mbit (1 M × 16) DRAM
V850E/MS1
(b) In the case of 4 Mbit (1 M × 4) DRAM
A1 to A10
A0 to A9
A0 to A9
I/O1 to I/O4
I/O1 to I/O4
RASn
RAS
RAS
LCAS
CAS
CAS
WE
WE
WE
OE
OE
OE
D0 to D7
D8 to D15
UCAS
V850E/MS1
4 Mbit (1 M × 4) DRAM
A0 to A9
A0 to A9
I/O1 to I/O4
I/O1 to I/O4
RAS
RAS
CAS
CAS
WE
WE
OE
OE
4 Mbit (1 M × 4) DRAM
Remark
4 Mbit (1 M × 4) DRAM
4 Mbit (1 M × 4) DRAM
n = 0 to 7
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CHAPTER 5 MEMORY ACCESS CONTROL FUNCTION
5.3.3 Address multiplex function
Depending on the value of the DAW0n and DAW1n bits in DRAM configuration register n (DRCn), the row address,
column address output in the DRAM cycle is multiplexed as shown in Figure 5-7 (n = 0 to 3). In Figure 5-7, a0 to a23
show the addresses output from the CPU and A0 to A23 show the V850E/MS1’s address pins. For example, when
DAW0n and DAW1n = 11, it indicates that a12 to a22 are output from the address pins (A1 to A11) as row addresses
and a1 to a11 are output as column addresses.
Table 5-1 shows the relationship between connectable DRAM and the address multiplex width. Depending on the
DRAM being connected, DRAM space is from 128 KB to 8 MB.
Figure 5-7. Row Address/Column Address Output
Address pin
A23 to A18 A17 A16 A15 A14 A13 A12 A11 A10 A9
A8 A7
A6
A5 A4
A3
A2
A1
A0
Row address
(DAW1n, DAW0n = 11)
a23 to a18 a17 a16 a15 a25 a24 a23 a22 a21 a20 a19 a18 a17 a16 a15 a14 a13 a12 a11
Row address
(DAW1n, DAW0n = 10)
a23 to a18 a17 a16 a25 a24 a23 a22 a21 a20 a19 a18 a17 a16 a15 a14 a13 a12 a11 a10
Row address
(DAW1n, DAW0n = 01)
a23 to a18 a17 a25 a24 a23 a22 a21 a20 a19 a18 a17 a16 a15 a14 a13 a12 a11 a10 a9
Row address
(DAW1n, DAW0n = 00)
a23 to a18 a25 a24 a23 a22 a21 a20 a19 a18 a17 a16 a15 a14 a13 a12 a11 a10 a9
a8
Column address
a23 to a18 a17 a16 a15 a14 a13 a12 a11 a10 a9
a0
a8
a7
a6
a5
a4
a3
a2
a1
Table 5-1. Example of DRAM and Address Multiplex Width
Address
Multiplex Width
DRAM Capacity (Bits) and Configuration
256 K
8 bits
64 K × 4
9 bits
10 bits
11 bits
138
DRAM Space
(Bytes)
1M
4M
16 M
64 M
128 K
256 K × 16
512 K
512 K × 8
1M
4 M × 16
8M
1 M × 16
2M
2M×8
4M
256 K × 4
4 M × 16
8M
4M×4
8M
1M×4
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5.3.4 DRAM configuration registers 0 to 3 (DRC0 to DRC3)
This sets the type of DRAM to be connected.
These registers can be read/written in 16-bit units.
Caution If the object of access is a DRAM area, the wait set in registers DWC1 and DWC2 becomes invalid.
In this case, waits are controlled by registers DRC0 to DRC3.
5
4
DRC0 PAE PAE RPC RPC RHC RHC DAC DAC CPC CPC
10 00 10 00 10 00 10 00 10 00
0
RHD
0
0
DRC1 PAE PAE RPC RPC RHC RHC DAC DAC CPC CPC
11 01 11 01 11 01 11 01 11 01
0
RHD
1
DRC2 PAE PAE RPC RPC RHC RHC DAC DAC CPC CPC
12 02 12 02 12 02 12 02 12 02
0
DRC3 PAE PAE RPC RPC RHC RHC DAC DAC CPC CPC
13 03 13 03 13 03 13 03 13 03
0
15
Bit Position
15, 14
13, 12
Remark
14
13
12
11
10
9
8
7
6
RPC1n,
RPC0n
2
1
0
0
DAW DAW
10 00
Address
FFFFF200H
After reset
3FC1H
0
0
DAW DAW
11 01
FFFFF202H
3FC1H
RHD
2
0
0
DAW DAW
12 02
FFFFF204H
3FC1H
RHD
3
0
0
DAW DAW
13 03
FFFFF206H
3FC1H
Bit Name
PAE1n,
PAE0n
3
Function
DRAM On-page Access Mode Control
Controls the on-page access cycle.
PAE1n
PAE0n
Access Mode
0
0
On-page access disabled.
0
1
High-speed page DRAM
1
0
EDO DRAM
1
1
Setting prohibited
Row Address Precharge Control
Specifies the number of wait states inserted as row address precharge time.
RPC1n
RPC0n
Number of Wait States Inserted
0
0
0
0
1
1
1
0
2
1
1
3
n = 0 to 3
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CHAPTER 5 MEMORY ACCESS CONTROL FUNCTION
Bit Position
11, 10
9, 8
7, 6
Bit Name
RHC1n,
RHC0n
DAC1n,
DAC0n
CPC1n,
CPC0n
Function
Row Address Hold Wait Control
Specifies the number of wait states inserted as row address hold time.
RHC1n
RHC0n
Number of Wait States Inserted
0
0
0
0
1
1
1
0
2
1
1
3
Data Access Programmable Wait Control
Specifies the number of wait states inserted as data access time in DRAM access.
DAC1n
DAC0n
Number of Wait States Inserted
0
0
0
0
1
1
1
0
2
1
1
3
Column Address Pre-charge Control
Specifies the number of wait states inserted as column address precharge time.
CPC1n
CPC0n
Number of Wait States Inserted
Note
0
0
0
0
1
1
1
0
2
1
1
3
Note 1 wait is inserted during DRAM write access in DMA flyby transfer.
4
Remark
140
RHDn
RAS Hold Disable
Sets the RAS hold mode.
If access to DRAM during on-page operation is not continuous, and access enters
another space midway, the RASm signal (m = 0 to 7) is maintained in the active state
(low level) during the time the other space is being accessed in the RAS hold mode
state. In this way, if access continues in the same DRAM row address following access
of the other space, on-page operation can be continued.
0: RAS hold mode enabled
1: RAS hold mode disabled
n = 0 to 3
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Bit Position
1, 0
Bit Name
DAW1n,
DAW0n
Function
DRAM Address Multiplex Width Control
This sets the address multiplex width (refer to 5.3.3 Address multiplex function).
DAW1n
DAW0n
Address Multiplex Width
0
0
8 bits
0
1
9 bits
1
0
10 bits
1
1
11 bits
Caution Write to the DRCn register after reset, and then do not change the set value. Also, do not
access an external memory area other than the one for this initialization routine until the initial
setting of the DRCn register is complete. However, it is possible to access an external memory
area whose initialization is complete.
Remark
n = 0 to 3
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5.3.5 DRAM type configuration register (DTC)
This controls the relationship between DRAM configuration register n (DRCn) and memory block m (n = 0 to 3, m =
0 to 7).
These registers can be read/written in 16-bit units.
15
DTC
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
DC DC DC DC DC DC DC DC DC DC DC DC DC DC DC DC
71 70 61 60 51 50 41 40 31 30 21 20 11 10 01 00
Memory
block
7
Bit Position
15 to 0
6
5
4
3
2
Bit Name
DCm1,
DCm0
1
Address
FFFFF220H
After reset
0000H
0
Function
DRAM Type Configuration
Specifies the DRAM configuration register n (DRCn) corresponding to memory block m.
Furthermore, it has no meaning if the memory block m is not specified in the DRAM
area.
DCm1
DCm0
DRAM Configuration Register n (DRCn) Corresponding
to Memory Block m
0
0
DRC0
0
1
DRC1
1
0
DRC2
1
1
DRC3
Caution Write to the DTC register after reset, and then do not change the set value. Also, do not access
an external memory area other than the one for this initialization routine until the initial setting
of the DTC register is complete. However, it is possible to access an external memory area
whose initialization is complete.
Remark
n = 0 to 3
m = 0 to 7
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5.3.6 DRAM access
Figure 5-8. High-Speed Page DRAM Access Timing (1/4)
(a) Read timing 1
T1
T3
T2
TO1
TO2
TO1
TO2
CLKOUT
A0 to A23
Row
address
Column address
Column address
Column address
Data
Data
Data
BCYST
CSn/RASn
RD
OE
WE
UWR/UCAS
LWR/LCAS
IORD
IOWR
D0 to D15
WAIT
Remarks 1. This is the timing in the case of no waits.
2. The circle indicates the sampling timing.
3. The broken lines indicate high impedance.
4. n = 0 to 7
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Figure 5-8. High-Speed Page DRAM Access Timing (2/4)
(b) Read timing 2
TRPW
T1
TRHW
T2
TDAW
T3
TCPW TO1 TDAW TO2 TCPW TO1 TDAW TO2
CLKOUT
A0 to A23
Row address
Column address
Column address
Column address
BCYST
CSn/RASn
RD
OE
WE
UWR/UCAS
LWR/LCAS
IORD
IOWR
D0 to D15
Data
Data
WAIT
Remarks 1. This is the timing in the following cases (×× = 00 to 03, 10 to 13).
Number of waits according to bit RPC×× (TRPW): 1
Number of waits according to bit RHC×× (TRHW): 1
Number of waits according to bit DAC×× (TDAW): 1
Number of waits according to bit CPC×× (TCPW): 1
2. The circle indicates the sampling timing.
3. The broken lines indicate high impedance.
4. n = 0 to 7
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Figure 5-8. High-Speed Page DRAM Access Timing (3/4)
(c) Write timing 1
T1
T2
T3
TO1
TO2
TO1
TO2
CLKOUT
A0 to A23
Row
address
Column address
Column address
Column address
Data
Data
BCYST
CSn/RASn
RD
OE
WE
UWR/UCAS
LWR/LCAS
IORD
IOWR
D0 to D15
Data
WAIT
Remarks 1. This is the timing in the case of no waits.
2. The circle indicates the sampling timing.
3. The broken lines indicate high impedance.
4. n = 0 to 7
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Figure 5-8. High-Speed Page DRAM Access Timing (4/4)
(d) Write timing 2
TRPW
T1
TRHW
T2
TDAW
T3
TCPW TO1 TDAW TO2 TCPW TO1 TDAW TO2
CLKOUT
A0 to A23
Row address
Column address
Column address
Column address
BCYST
CSn/RASn
RD
OE
WE
UWR/UCAS
LWR/LCAS
IORD
IOWR
D0 to D15
Data
Data
WAIT
Remarks 1. This is the timing in the following cases (×× = 00 to 03, 10 to 13).
Number of waits according to bit RPC×× (TRPW): 1
Number of waits according to bit RHC×× (TRHW): 1
Number of waits according to bit DAC×× (TDAW): 1
Number of waits according to bit CPC×× (TCPW): 1
2. The circle indicates the sampling timing.
3. The broken lines indicate high impedance.
4. n = 0 to 7
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Figure 5-9. EDO DRAM Access Timing (1/4)
(a) Read timing 1
T1
T2
TB
TB
Column
address
Column
address
TE
CLKOUT
Row
address
A0 to A23
Column address
BCYST
CSn/RASn
RD
OE
WE
UWR/UCAS
LWR/LCAS
IORD
IOWR
Data
D0 to D15
WAIT
Data
Data
Optional
Remarks 1. This is the timing in the case of no waits.
2. The circle indicates the sampling timing.
3. The broken lines indicate high impedance.
4. n = 0 to 7
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Figure 5-9. EDO DRAM Access Timing (2/4)
(b) Read timing 2
TRPW
T1
TRHW
T2
TDAW TCPW
TB
TDAW TCPW
TB
TDAW
CLKOUT
Row address
A0 to A23
Column address
Column address
Column address
BCYST
CSn/RASn
RD
OE
WE
UWR/UCAS
LWR/LCAS
IORD
IOWR
D0 to D15
Data
Data
WAIT Optional
Remarks 1. This is the timing in the following cases (×× = 00 to 03, 10 to 13).
Number of waits according to bit RPC×× (TRPW): 1
Number of waits according to bit RHC×× (TRHW): 1
Number of waits according to bit DAC×× (TDAW): 1
Number of waits according to bit CPC×× (TCPW): 1
2. The circle indicates the sampling timing.
3. The broken lines indicate high impedance.
4. n = 0 to 7
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CHAPTER 5 MEMORY ACCESS CONTROL FUNCTION
Figure 5-9. EDO DRAM Access Timing (3/4)
(c) Write timing 1
T1
T2
TB
Column
address
Column
address
TB
TE
CLKOUT
Row
address
A0 to A23
Column address
BCYST
CSn/RASn
RD
OE
WE
UWR/UCAS
LWR/LCAS
IORD
IOWR
Data
D0 to D15
WAIT
Data
Data
Optional
Remarks 1. This is the timing in the case of no waits.
2. The broken lines indicate high impedance.
3. n = 0 to 7
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CHAPTER 5 MEMORY ACCESS CONTROL FUNCTION
Figure 5-9. EDO DRAM Access Timing (4/4)
(d) Write timing 2
TRPW
T1
TRHW
T2
TDAW TCPW
TB
TDAW TCPW
TB
TDAW
CLKOUT
Row address
A0 to A23
Column address
Column address
Column address
BCYST
CSn/RASn
RD
OE
WE
UWR/UCAS
LWR/LCAS
IORD
IOWR
D0 to D15
Data
Data
WAIT Optional
Remarks 1. This is the timing in the following cases (×× = 00 to 03, 10 to 13).
Number of waits according to bit RPC×× (TRPW): 1
Number of waits according to bit RHC×× (TRHW): 1
Number of waits according to bit DAC×× (TDAW): 1
Number of waits according to bit CPC×× (TCPW): 1
2. The broken lines indicate high impedance.
3. n = 0 to 7
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5.3.7 DRAM access during DMA flyby transfer
Figure 5-10. DRAM Access Timing During DMA Flyby Transfer (1/2)
(a) In the case of DRAM → External I/O
T1
T2
T3
TF
TO1
TO2
TF
TO1
TO2
TF
CLKOUT
A0 to A23
Row
address
Column address
Column address
Column address
BCYST
CSn/RASn
RD
OE
WE
UWR/UCAS
LWR/LCAS
IORD
IOWR
D0 to D15
Data
Data
Data
WAIT
DMAAKm
Remarks 1. This is the timing in the case where wait (TF) insertion setting was carried out according to the
FDW register.
2. The circle indicates the sampling timing.
3. The broken lines indicate high impedance.
4. n = 0 to 7
m = 0 to 3
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Figure 5-10. DRAM Access Timing During DMA Flyby Transfer (2/2)
(b) In the case of external I/O → DRAM
T1
T2
T3
TCPWNote
TO1
TO2
TCPW
TO1
TO2
CLKOUT
A0 to A23
Row
address
Column address
Column address
Column address
BCYST
CSn/RASn
RD
OE
WE
UWR/UCAS
LWR/LCAS
IORD
IOWR
D0 to D15
Data
Data
Data
WAIT
DMAAKm
Note A minimum of 1 clock cycle is inserted for the TCPW cycle regardless of the CPC0m and CPC1m bit
settings in the DRCm register.
Remarks 1. This is the timing in the case where the number of waits according to the CPC×× bit (TCPW) is 1
(×× = 00 to 03, 10 to 13).
2. In the case of external I/O → DRAM, the FDW register setting is invalid.
3. The circle indicates the sampling timing.
4. The broken lines indicate high impedance.
5. n = 0 to 7
m = 0 to 3
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5.3.8 Refresh control function
V850E/MS1 can create a CBR (CAS-before-RAS) refresh cycle. The refresh cycle is set with the refresh control
register (RFC).
When another bus master occupies the external bus, the DRAM controller cannot occupy the external bus. In this
case, the DRAM controller sends a refresh request to the bus master by changing the REFRQ signal to active (low
level).
During the refresh interval, the address bus maintains the state it was in just before the refresh cycle.
(1) Refresh control registers 0 to 3 (RFC0 to RFC3)
These set whether refresh is enabled or disabled, and the refresh interval. The refresh interval is determined
by the following calculation formula.
Refresh interval (µs) = Refresh count clock (TRCY) × Interval factor
The refresh count clock and interval factor are determined by the RENn bit and RIn bit, respectively, of the
RFCn register.
Note that n corresponds to the register number (0 to 3) of DRAM configuration registers 0 to 3 (DRC0 to
DRC3).
These registers can be read/written in 16-bit units.
7
6
5
4
3
2
1
0
RCC RCC
01 00
0
0
RI
05
RI
04
RI
03
RI
02
RI
01
RI
00
Address
FFFFF210H
After reset
0000H
0
RCC RCC
11 10
0
0
RI
15
RI
14
RI
13
RI
12
RI
11
RI
10
FFFFF212H
0000H
0
0
RCC RCC
21 20
0
0
RI
25
RI
24
RI
23
RI
22
RI
21
RI
20
FFFFF214H
0000H
0
0
RCC RCC
31 30
0
0
RI
35
RI
34
RI
33
RI
32
RI
31
RI
30
FFFFF216H
0000H
14
13
12
11
10
RFC0 REN
0
0
0
0
0
0
RFC1 REN
1
0
0
0
0
RFC2 REN
2
0
0
0
REN
3
0
0
0
15
RFC3
Bit Position
15
Remark
Bit Name
RENn
9
8
Function
Refresh Enable
Specifies whether CBR refresh is enabled or disabled.
0: Refresh disabled
1: Refresh enabled
n = 0 to 3
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Bit Position
9, 8
Bit Name
RCCn1,
RCCn0
5 to 0
RIn5 to
RIn0
Function
Refresh Count Clock
Specifies the refresh count clock (T RCY).
RCCn1
RCCn0
Refresh Count Clock (TRCY)
0
0
32/φ
0
1
128/φ
1
0
256/φ
1
1
Setting prohibited
Refresh Interval
Sets the interval factor of the interval timer for generation of refresh timing.
RIn5
RIn4
RIn3
RIn2
RIn1
RIn0
0
0
0
0
0
0
1
0
0
0
0
0
1
2
0
0
0
0
1
0
3
0
0
0
0
1
1
4
...
...
...
...
...
...
...
Interval Factor
1
1
1
1
1
1
64
Caution After refresh enable, if changing the refresh count clock or the interval factor, first clear the
RENn bit (0) (refresh disable state), then perform reset.
Remark
n = 0 to 3
φ = Internal system clock frequency
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Example An example of the DRAM refresh interval and an example of setting the interval factor are shown below.
Table 5-2. Example of DRAM Refresh Interval
DRAM Capacity (bits)
Refresh Cycle (Cycles/ms)
Refresh Interval (µs)
256 K
256/4
15.6
1M
512/8
15.6
512/64
125
512/128
250
1 K/16
15.6
1 K/128
125
1 K/256
250
2 K/256
125
4 K/64
15.6
4 K/256
62.5
4 K/64
15.6
4M
16 M
64 M
Table 5-3. Example of Interval Factor Settings
Specified Refresh
Interval Value (µs)
15.6
Refresh Count
Clock (TRCY)
Notes 1, 2
Interval Factor Value
When φ = 16 MHz
When φ = 20 MHz
When φ = 33 MHz
When φ = 40 MHz
32/φ
7 (14)
9 (14.4)
15 (14.5)
19 (15.2)
128/φ
1 (8)
2 (12.8)
3 (11.6)
4 (12.8)
1 (12.8)
1 (7.8)
2 (12.8)
256/φ
62.5
32/φ
30 (60)
38 (60.8)
63 (61.1)
128/φ
7 (56)
9 (57.6)
15 (58.2)
19 (60.8)
256/φ
3 (48)
4 (51.2)
7 (54.3)
9 (57.6)
32/φ
125
128/φ
15 (120)
19 (121.6)
32 (124.1)
39 (124.8)
256/φ
7 (112)
9 (115.2)
16 (124.1)
19 (121.6)
32/φ
250
128/φ
31 (248)
38 (243.2)
64 (248.2)
256/φ
15 (240)
19 (243.2)
32 (248.2)
39 (249.6)
Notes 1. The interval factor is set by bits RIn0 to RIn5 of the RFCn register (n = 0 to 3).
2. The values in parentheses are the calculated value (µs) for the refresh interval.
Refresh Interval (µs) = Refresh count clock (TRCY) × Interval factor
Remark
φ: Internal system clock frequency
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(2) Refresh wait control register (RWC)
This specifies insertion of wait states during the refresh cycle. The register can be read/written in 8- or 1-bit units.
RWC
7
6
5
4
3
2
1
0
RRW1
RRW0
RCW2
RCW1
RCW0
SRW2
SRW1
SRW0
Bit Position
7, 6
Bit Name
RRW1,
RRW0
5 to 3
2 to 0
RCW2 to
RCW0
SRW2 to
SRW0
Address
FFFFF218H
After reset
00H
Function
Refresh RAS Wait Control
Specifies the number of wait states inserted as hold time for the RASm signal’s high
level width during CBR refresh.
RRW1
RRW0
0
0
0
Number of Insertion Wait States
0
1
1
1
0
2
1
1
3
Refresh Cycle Wait Control
Specifies the number of wait states inserted as hold time for the RASm signal’s low level
width during CBR refresh.
RCW2
RCW1
RCW0
Number of Insertion Wait States
0
0
0
0
0
0
1
1
0
1
0
2
0
1
1
3
1
0
0
4
1
0
1
5
1
1
0
6
1
1
1
7
Self-refresh Release Wait Control
Specifies the number of wait states inserted as CBR self-refresh release time.
SRW2
SRW1
SRW0
Number of Insertion Wait States
0
0
0
0
0
0
1
1
0
1
0
2
0
1
1
3
1
0
0
4
1
0
1
5
1
1
0
6
1
1
1
7
Caution Write to the RWC register after reset, and then do not change the set value. Also, do not
access an external memory area other than the one for this initialization routine until the initial
setting of the RWC register is complete. However, it is possible to access an external memory
area whose initialization is complete.
Remark
156
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(3) Refresh timing
Figure 5-11. CBR Refresh Timing
TRRW
T1
T2
TRCWNote
TRCW
T3
TI
CLKOUT
REFRQ
A0 to A23
BCYST
CSn/RASn
RD
OE
WE
UWR/UCAS
LWR/LCAS
IORD
IOWR
D0 to D15
WAIT Optional
Note A minimum of 1 clock cycle is inserted for the TRCW cycle regardless of the RCW0 to RCW2 bit
settings in the RWC register.
Remarks 1. This is the timing in the case where the number of waits (TRCW) according to the bits RCW0 to
RCW2 is 1.
2. n = 0 to 7
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5.3.9 Self-refresh functions
In the case of IDLE mode and software STOP mode, the DRAM controller generates a CBR self-refresh cycle.
However, the RASn pulse width of DRAM should meet the specifications to enter a self-refresh operation mode (n
= 0 to 7).
To release the self-refresh cycle, follow either of two methods below.
(1) Release by NMI input
(a) In the case of self-refresh cycle with IDLE mode
Set the RASn, LCAS, UCAS signals to inactive (high level) immediately to release the self-refresh cycle.
(b) In the case of self-refresh cycle with software STOP mode
Set the RASn, LCAS, UCAS signals to inactive (high level) after stabilizing oscillation to release the selfrefresh cycle.
(2) Release by RESET input
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Figure 5-12. CBR Self-Refresh Timing (1/2)
(a) In the case of release according to the NMI input (in the IDLE Mode)
TRRW
TH
TH
TH
TH
TH
TH
TRCW
TH
TI
TSRW TSRW
CLKOUT
NMI
REFRQ
A0 to A23
BCYST
CSn/RASn
RD
OE
WE
UWR/UCAS
LWR/LCAS
IORD
IOWR
D0 to D15
WAIT
Remarks 1. This is the timing in the following cases.
Number of waits according to bits RRW0 and RRW1 (TRRW): 1
Number of waits according to bits RCW0 to RCW2 (TRCW): 1
Number of waits according to bits SRW0 to SRW2 (TSRW): 2
2. n = 0 to 7
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Figure 5-12. CBR Self-Refresh Timing (2/2)
(b) In the case of release according to the NMI input (in the software STOP Mode)
TRRW
TH
TH
TH
TH
TH
TH
TRCW
CLKOUT
NMI
REFRQ
A0 to A23
BCYST
CSn/RASn
RD
OE
WE
UWR/UCAS
LWR/LCAS
IORD
IOWR
D0 to D15
WAIT
Remarks 1. This is the timing in the following cases.
Number of waits according to bits RRW0 and RRW1 (TRRW): 1
Number of waits according to bits RCW0 to RCW2 (TRCW): 1
Number of waits according to bits SRW0 to SRW2 (TSRW): 2
2. n = 0 to 7
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TH
TI
TSRW TSRW
CHAPTER 6 DMA FUNCTIONS (DMA CONTROLLER)
The V850E/MS1 includes a DMA (Direct Memory Access) controller (DMAC), which executes and controls DMA
transfer.
The DMAC (DMA controller) transfers data between memory and I/O, or within memory, based on DMA requests
issued by the internal peripheral I/O (serial interface and real-time pulse unit), DMARQ0 to DMARQ3 pins, or
software triggers.
6.1
Features
{ 4 independent DMA channels
{ Transfer unit: 8/16 bits
16
{ Maximum transfer count: 65,536 (2 )
{ Two types of transfer
• Flyby (one-cycle) transfer
• Two-cycle transfer
{ Three transfer modes
• Single transfer mode
• Single-step transfer mode
• Block transfer mode
{ Transfer requests
• DMARQ0 to DMARQ3 pin (× 4)
• Requests from internal peripheral I/O (serial interface and real-time pulse unit)
• Requests from software
{ Transfer objects
• Memory to I/O and vice versa
• Memory to memory
{ DMA transfer end output signal (TC0 to TC3)
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6.2
Configuration
Internal
peripheral I/O
Internal RAM
Internal bus
Internal peripheral I/O bus
CPU
Data
control
Address
control
DMA source address
register (DSAnH/DSAnL)
DMA destination address
register (DDAnH/DDAnL)
TCn
Count
control
DMA byte count register
(DBCn)
DMA addressing control
register (DADCn)
DMA channel control
register (DCHCn)
NMI
INTPmn
Internal peripheral
I/O request
Channel
control
DMARQn
DMAAKn
DMA disable status
register (DDIS)
DMA restart register
(DRST)
DMA trigger factor
register (DTFRn)
DMAC
Bus interface
V850E/MS1
External bus
External I/O
Remark
External
RAM
External
ROM
m = 10 to 15
n = 0 to 3
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6.3
Control Registers
6.3.1 DMA source address registers 0 to 3 (DSA0 to DSA3)
These registers are used to set the DMA source addresses (26 bits each) for DMA channel n (n = 0 to 3). They
are divided into two 16-bit registers, DSAnH and DSAnL.
During DMA transfer, the registers store the next DMA source addresses.
When flyby transfer between external memory and external I/O is specified with the TTYP bits of DMA addressing
control register n (DADCn), the external memory addresses are set with the DSAn register. The setting made with
DMA destination address register n (DDAn) is ignored.
(1) DMA source address registers 0H to 3H (DSA0H to DSA3H)
These registers can be read/written in 16-bit units.
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
DSA0H
0
0
0
0
0
0
SA
25
SA
24
SA
23
SA
22
SA
21
SA
20
SA
19
SA
18
SA
17
SA
16
Address
FFFFF1A0H
After reset
Undefined
DSA1H
0
0
0
0
0
0
SA
25
SA
24
SA
23
SA
22
SA
21
SA
20
SA
19
SA
18
SA
17
SA
16
FFFFF1A8H
Undefined
DSA2H
0
0
0
0
0
0
SA
25
SA
24
SA
23
SA
22
SA
21
SA
20
SA
19
SA
18
SA
17
SA
16
FFFFF1B0H
Undefined
DSA3H
0
0
0
0
0
0
SA
25
SA
24
SA
23
SA
22
SA
21
SA
20
SA
19
SA
18
SA
17
SA
16
FFFFF1B8H
Undefined
Bit Position
9 to 0
Bit Name
SA25 to SA16
Function
Source Address
Sets the DMA source address (A25 to A16). During DMA transfer, it stores the
next DMA source address. During flyby transfer between external memory and
external I/O, it stores a memory address.
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CHAPTER 6 DMA FUNCTIONS (DMA CONTROLLER)
(2) DMA source address registers 0L to 3L (DSA0L to DSA3L)
These registers can be read/written in 16-bit units.
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
DSA0L
SA
15
SA
14
SA
13
SA
12
SA
11
SA
10
SA
9
SA
8
SA
7
SA
6
SA
5
SA
4
SA
3
SA
2
SA
1
SA
0
Address
FFFFF1A2H
After reset
Undefined
DSA1L
SA
15
SA
14
SA
13
SA
12
SA
11
SA
10
SA
9
SA
8
SA
7
SA
6
SA
5
SA
4
SA
3
SA
2
SA
1
SA
0
FFFFF1AAH
Undefined
DSA2L
SA
15
SA
14
SA
13
SA
12
SA
11
SA
10
SA
9
SA
8
SA
7
SA
6
SA
5
SA
4
SA
3
SA
2
SA
1
SA
0
FFFFF1B2H
Undefined
DSA3L
SA
15
SA
14
SA
13
SA
12
SA
11
SA
10
SA
9
SA
8
SA
7
SA
6
SA
5
SA
4
SA
3
SA
2
SA
1
SA
0
FFFFF1BAH
Undefined
Bit Position
15 to 0
164
Bit Name
SA15 to SA0
Function
Source Address
Sets the DMA source address (A15 to A0). During DMA transfer, it stores the
next DMA source address. During flyby transfer between external memory and
external I/O, it stores a memory address.
User’s Manual U12688EJ4V0UM00
CHAPTER 6 DMA FUNCTIONS (DMA CONTROLLER)
6.3.2 DMA destination address registers 0 to 3 (DDA0 to DDA3)
These registers are used to set the DMA destination addresses (26 bits each) for DMA channel n (n = 0 to 3).
They are divided into two 16-bit registers, DDAnH and DDAnL.
During DMA transfer, the registers store the next DMA destination addresses.
When flyby transfer between external memory and external I/O is specified with the TTYP bits of DMA addressing
control register n (DADCn), the setting of these registers are ignored. But when flyby transfer between internal RAM
and internal peripheral I/O has been set, the DMA destination address registers (DDA0 to DDA3) must be set.
(1) DMA destination address registers 0H to 3H (DDA0H to DDA3H)
These registers can be read/written in 16-bit units.
15
14
13
12
11
10
9
8
7
6
5
DDA0H
0
0
0
0
0
0
DA
25
DA
24
DA
23
DA
22
DA
21
DA DA
20 19
DA DA
18 17
DA
16
Address
FFFFF1A4H
After reset
Undefined
DDA1H
0
0
0
0
0
0
DA
25
DA
24
DA
23
DA
22
DA
21
DA DA
20 19
DA DA
18 17
DA
16
FFFFF1ACH
Undefined
DDA2H
0
0
0
0
0
0
DA
25
DA
24
DA
23
DA
22
DA
21
DA DA
20 19
DA DA
18 17
DA
16
FFFFF1B4H
Undefined
DDA3H
0
0
0
0
0
0
DA
25
DA
24
DA
23
DA
22
DA
21
DA DA
20 19
DA DA
18 17
DA
16
FFFFF1BCH
Undefined
Bit Position
9 to 0
Bit Name
DA25 to DA16
4
3
2
1
0
Function
Destination Address
Sets the DMA destination address (A25 to A16). During DMA transfer, it stores
the next DMA destination address. This is disregarded during flyby transfer
between external memory and external I/O, but be sure to set this register during
flyby transfer between internal RAM and internal peripheral I/O.
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CHAPTER 6 DMA FUNCTIONS (DMA CONTROLLER)
(2) DMA destination address registers 0L to 3L (DDA0L to DDA3L)
These registers can be read/written in 16-bit units.
15
14
13
12
11
DDA0L
DA DA
15 14
DA
13
DA
12
DDA1L
DA DA
15 14
DA
13
DDA2L
DA DA
15 14
DDA3L
DA DA
15 14
Bit Position
15 to 0
166
10
9
8
7
6
5
4
3
DA DA
11 10
DA
9
DA
8
DA
7
DA
6
DA
5
DA DA
4
3
DA DA
2
1
DA
0
Address
FFFFF1A6H
After reset
Undefined
DA
12
DA DA
11 10
DA
9
DA
8
DA
7
DA
6
DA
5
DA DA
4
3
DA DA
2
1
DA
0
FFFFF1AEH
Undefined
DA
13
DA
12
DA DA
11 10
DA
9
DA
8
DA
7
DA
6
DA
5
DA DA
4
3
DA DA
2
1
DA
0
FFFFF1B6H
Undefined
DA
13
DA
12
DA DA
11 10
DA
9
DA
8
DA
7
DA
6
DA
5
DA DA
4
3
DA DA
2
1
DA
0
FFFFF1BEH
Undefined
Bit Name
DA15 to DA0
2
1
0
Function
Destination Address
Sets the DMA destination address (A15 to A0). During DMA transfer, it stores
the next DMA destination address. This is disregarded during flyby transfer
between external memory and external I/O, but be sure to set this register
during flyby transfer between internal RAM and internal peripheral I/O.
User’s Manual U12688EJ4V0UM00
CHAPTER 6 DMA FUNCTIONS (DMA CONTROLLER)
6.3.3 DMA byte count registers 0 to 3 (DBC0 to DBC3)
These 16-bit registers are used to set the byte transfer counts for DMA channel n (n = 0 to 3).
They store the remaining transfer counts during DMA transfer.
These registers are decremented by 1 for byte transfer and by two for 16-bit transfer. Transfer ends when a
borrow occurs. Thus, “transfer count –1” should be set for byte transfer and “(transfer count –1) × 2” for 16-bit
transfer.
These registers can be read/written in 16-bit units.
15
14
13
12
11
DBC0
BC BC
15 14
BC
13
BC
12
DBC1
BC BC
15 14
BC
13
DBC2
BC BC
15 14
DBC3
BC BC
15 14
Bit Position
15 to 0
10
9
8
7
6
5
BC BC
11 10
BC
9
BC
8
BC
7
BC
6
BC
5
BC BC
4
3
BC BC
2
1
BC
0
Address
FFFFF1E0H
After reset
Undefined
BC
12
BC BC
11 10
BC
9
BC
8
BC
7
BC
6
BC
5
BC BC
4
3
BC BC
2
1
BC
0
FFFFF1E2H
Undefined
BC
13
BC
12
BC BC
11 10
BC
9
BC
8
BC
7
BC
6
BC
5
BC BC
4
3
BC BC
2
1
BC
0
FFFFF1E4H
Undefined
BC
13
BC
12
BC BC
11 10
BC
9
BC
8
BC
7
BC
6
BC
5
BC BC
4
3
BC BC
2
1
BC
0
FFFFF1E6H
Undefined
Bit Name
BC15 to
BC0
4
3
2
0
Function
Byte Count
Sets the byte transfer count. During DMA transfer, it stores the remaining byte transfer
count.
DBCn
States
0000H
Byte transfer count 1 or the remaining byte transfer count
0001H
Byte transfer count 2 or the remaining byte transfer count
:
FFFFH
Remark
1
:
16
Byte transfer count 65,536 (2 ) or the remaining byte transfer count
n = 0 to 3
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CHAPTER 6 DMA FUNCTIONS (DMA CONTROLLER)
6.3.4 DMA addressing control registers 0 to 3 (DADC0 to DADC3)
These 16-bit registers are used to control the DMA transfer operation modes for DMA channel n (n = 0 to 3).
These registers can be read/written in 16-bit units.
Caution During DMA transfer, do not perform writing to these registers.
15
14
13
12
11
10
9
8
DADC0
0
0
0
0
0
0
0
DS
SAD SAD DAD DAD TM
1
0
1
0
1
TM
TTYP TDIR
0
Address
FFFFF1F0H
After reset
0000H
DADC1
0
0
0
0
0
0
0
DS
SAD SAD DAD DAD TM
1
0
1
0
1
TM
TTYP TDIR
0
FFFFF1F2H
0000H
DADC2
0
0
0
0
0
0
0
DS
SAD SAD DAD DAD TM
1
0
1
0
1
TM
TTYP TDIR
0
FFFFF1F4H
0000H
DADC3
0
0
0
0
0
0
0
DS
SAD SAD DAD DAD TM
1
0
1
0
1
TM
TTYP TDIR
0
FFFFF1F6H
0000H
Bit Position
8
7, 6
Remark
168
7
6
5
Bit Name
4
3
2
1
0
Function
DS
Data Size
Sets the transfer data size for DMA transfer.
0: 8 bits
1: 16 bits
SAD1,
SAD0
Source Address count Direction
Sets the count direction of the source address for DMA channel n.
SAD1
SAD0
Count Direction
0
0
Increment
0
1
Decrement
1
0
Fixed
1
1
Setting prohibited
n = 0 to 3
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CHAPTER 6 DMA FUNCTIONS (DMA CONTROLLER)
Bit Position
5, 4
3, 2
Bit Name
DAD1,
DAD0
TM1, TM0
Function
Destination Address count Direction
Sets the count direction of the destination address for DMA channel n.
DAD1
DAD0
Count Direction
0
0
Increment
0
1
Decrement
1
0
Fixed
1
1
Setting prohibited
Transfer Mode
Sets the transfer mode during DMA transfer.
TM1
TM0
Transfer Mode
0
0
Single transfer mode
0
1
Single-step transfer mode
1
0
Block transfer mode
1
1
Setting prohibited
1
TTYP
Transfer Type
Sets the DMA transfer type.
0: Two-cycle transfer
1: Flyby transfer
0
TDIR
Transfer Direction
Sets the transfer direction during transfer between I/O and memory. The setting is valid
during flyby transfer only and ignored during two-cycle transfer.
0: Memory → I/O (read)
1: I/O → memory (write)
Remark
n = 0 to 3
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CHAPTER 6 DMA FUNCTIONS (DMA CONTROLLER)
6.3.5 DMA channel control registers 0 to 3 (DCHC0 to DCHC3)
These 8-bit registers are used to control the DMA transfer operation mode for DMA channel n (n = 0 to 3).
These registers can be read/written in 8-bit units. (However, bit 7 is read-only and bits 2 and 1 are write-only.
When the DMA channel control registers are read, bits 2 and 1 are always 0.)
7
6
5
4
3
2
1
0
DCHC0
TC0
0
0
0
0
INIT0
STG0
EN0
Address
FFFFF5F0H
After reset
00H
DCHC1
TC1
0
0
0
0
INIT1
STG1
EN1
FFFFF5F2H
00H
DCHC2
TC2
0
0
0
0
INIT2
STG2
EN2
FFFFF5F4H
00H
DCHC3
TC3
0
0
0
0
INIT3
STG3
EN3
FFFFF5F6H
00H
Bit Position
Remark
170
Bit Name
Function
7
TCn
Terminal Count
This status bit indicates whether DMA transfer through DMA channel n has
ended or not.
This bit can only be read. It is set (1) when DMA transfer ends with a terminal
count and reset (0) when it is read.
0: DMA transfer has not ended.
1: DMA transfer has ended.
2
INITn
Initialize
If this bit is set (1), the DMA transfer is forcibly terminated.
1
STGn
Software Trigger
In DMA transfer enable state (TCn bit = 0, ENn bit = 1), if this bit is set (1), DMA
transfer can be started by software.
0
ENn
Enable
Specifies whether DMA transfer through DMA channel n is to be enabled or
disabled. It is reset (0) when DMA transfer ends with a terminal count. It is also
reset (0) when transfer is forcibly ended by means of setting (1) NMI input or
INITn bit.
0: DMA transfer disabled.
1: DMA transfer enabled.
n = 0 to 3
User’s Manual U12688EJ4V0UM00
CHAPTER 6 DMA FUNCTIONS (DMA CONTROLLER)
6.3.6 DMA trigger factor registers 0 to 3 (DTFR0 to DTFR3)
These 8-bit registers are used to control the DMA transfer start trigger through interrupt requests from peripheral
I/O.
The interrupt requests that are set with these registers start DMA transfer.
These registers can be read/written in 8- or 1-bit units.
7
6
5
4
3
2
1
0
DTFR0
0
0
IFC05
IFC04
IFC03
IFC02
IFC01
IFC00
Address
FFFFF5E0H
After reset
00H
DTFR1
0
0
IFC15
IFC14
IFC13
IFC12
IFC11
IFC10
FFFFF5E2H
00H
DTFR2
0
0
IFC25
IFC24
IFC23
IFC22
IFC21
IFC20
FFFFF5E4H
00H
DTFR3
0
0
IFC35
IFC34
IFC33
IFC32
IFC31
IFC30
FFFFF5E6H
00H
Bit Position
5 to 0
Bit Name
IFCn5 to
IFCn0
Function
Interrupt Factor Code
This code indicates the source of the DMA transfer trigger.
IFCn5
IFCn4
IFCn3
IFCn2
IFCn1
IFCn0
0
0
0
0
0
0
DMA request from
internal peripheral I/O
disabled.
0
0
0
0
0
1
INTCM40
0
0
0
0
1
0
INTCM41
0
0
0
0
1
1
INTCSI0
0
0
0
1
0
0
INTSR0
0
0
0
1
0
1
INTST0
0
0
0
1
1
0
INTCSI1
0
0
0
1
1
1
INTSR1
0
0
1
0
0
0
INTST1
0
0
1
0
0
1
INTCSI2
0
0
1
0
1
0
INTCSI3
0
0
1
0
1
1
INTP100/INTCC100
0
0
1
1
0
0
INTP101/INTCC101
0
0
1
1
0
1
INTP102/INTCC102
0
0
1
1
1
0
INTP103/INTCC103
0
0
1
1
1
1
INTP110/INTCC110
0
1
0
0
0
0
INTP111/INTCC111
0
1
0
0
0
1
INTP112/INTCC112
0
1
0
0
1
0
INTP113/INTCC113
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Interrupt Source
171
CHAPTER 6 DMA FUNCTIONS (DMA CONTROLLER)
Bit Position
5 to 0
Bit Name
IFCn5 to
IFCn0
Function
IFCn5
IFCn4
IFCn3
IFCn2
IFCn1
IFCn0
0
1
0
0
1
1
INTP120/INTCC120
0
1
0
1
0
0
INTP121/INTCC121
0
1
0
1
0
1
INTP122/INTCC122
0
1
0
1
1
0
INTP123/INTCC123
0
1
0
1
1
1
INTP130/INTCC130
0
1
1
0
0
0
INTP131/INTCC131
0
1
1
0
0
1
INTP132/INTCC132
0
1
1
0
1
0
INTP133/INTCC133
0
1
1
0
1
1
INTP140/INTCC140
0
1
1
1
0
0
INTP141/INTCC141
0
1
1
1
0
1
INTP142/INTCC142
0
1
1
1
1
0
INTP143/INTCC143
0
1
1
1
1
1
INTP150/INTCC150
1
0
0
0
0
0
INTP151/INTCC151
1
0
0
0
0
1
INTP152/INTCC151
1
0
0
0
1
0
intp153/intcc153
1
0
0
0
1
1
INTAD
Other than above
Interrupt Source
Setting prohibited
Remark
n = 0 to 3
Remark
The relationship between the DMARQn signal and the interrupt source which becomes the DMA
transfer start trigger is as follows (n = 0 to 3).
DMARQn
Interrupt source
Selector
Internal DMA request signal
IFCn0 to IFCn5
172
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CHAPTER 6 DMA FUNCTIONS (DMA CONTROLLER)
6.3.7 DMA disable status register (DDIS)
This register holds the contents of the ENn bit of the DCHCn register during NMI input (n = 0 to 3). It is read-only,
in 8- or 1-bit units.
DDIS
7
6
5
4
3
2
1
0
0
0
0
0
CH3
CH2
CH1
CH0
Bit Position
3 to 0
Bit Name
CHn
(n = 3 to 0)
Address
FFFFF5D0H
After reset
00H
Function
NMI Interruption Status
Reflects the contents of the ENn bit of the DCHCn register during NMI input.
The contents of this register are held until the next NMI input or until the next
system reset.
6.3.8 DMA restart register (DRST)
This register is used to restart DMA transfer that was forcibly interrupted during NMI input. The RENn bit of this
register and the ENn bit of the DCHCn register are linked to each other (n = 0 to 3). After NMI is completed, the
DDIS register is referred to and the DMA channel that was interrupted is confirmed, then by setting the RENn bit in
the corresponding channel (1), DMA transfer can be restarted. The register can be read/written in 8- or 1-bit units.
DRST
7
6
5
4
3
2
1
0
0
0
0
0
REN3
REN2
REN1
REN0
Bit Position
3 to 0
Bit Name
RENn
(n = 3 to 0)
Address
FFFFF5D2H
After reset
00H
Function
Restart Enable
This sets DMA transfer enable/disable in DMA channel n. If DMA transfer is
completed in accordance with the terminal count, it is reset (0). It is also reset
(0) when DMA is forcibly terminated by NMI input or by setting of the INITn bit
(1) in the DCHCn register.
0: DMA transfer disabled.
1: DMA transfer enabled.
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CHAPTER 6 DMA FUNCTIONS (DMA CONTROLLER)
6.3.9 Flyby transfer data wait control register (FDW)
To prevent illegal writing during flyby transfer, this register sets the insertion of wait states (TF) for securing the
time from when the write signal (IOWR, UWR, LWR, WE) becomes inactive until the read signal (RD, IORD, OE)
becomes inactive. This register can be read/written in 8- or 1-bit units.
FDW
7
6
5
4
3
2
1
0
FDW7
FDW6
FDW5
FDW4
FDW3
FDW2
FDW1
FDW0
7
6
5
4
3
2
1
0
Memory Block
Bit Position
7 to 0
Bit Name
FDWn
(n = 7 to 0)
Address
FFFFF06CH
After reset
00H
Function
Flyby Data Wait
Sets wait state insertion for memory block n.
0: Wait state not inserted.
1: Wait state inserted.
Caution Write to the FDW register after reset, and then do not change the value. Also, do not access an
external memory area until the initial setting of the FDW register is complete. (However, the
memory area 0000000H to 01FFFFFH is excluded.)
Remark
Setting of the FDW register is valid during the DMA transfers shown below.
Type of Memory
SRAM, Page ROM
DRAM
Object of Transfer
174
Memory → I/O
Valid
Valid
I/O → Memory
Valid
Invalid
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CHAPTER 6 DMA FUNCTIONS (DMA CONTROLLER)
6.4
DMA Bus States
6.4.1 Types of bus states
The DMAC bus cycle consists of the following 25 states:
(1) TI state
The TI state is idle state, during which no access request is issued.
The DMARQ0 to DMARQ3 signals are sampled at the falling edge of the CLKOUT signal.
(2) T0 state
DMA transfer ready state. (A DMA transfer request has been issued, causing bus mastership to be acquired
for the first DMA transfer).
(3) T1R state
The bus enters the T1R state at the beginning of a read operation in two-cycle transfer mode. Address
driving starts. After entering the T1R state, the bus invariably enters the T2R state.
(4) T1RI state
T1RI is a state in which the bus is waiting for the acknowledge in response to an external memory read
request. After entering the last T1RI state, the bus invariably enters the T2R state.
(5) T2R state
The T2R state corresponds to the last state of a read operation in two-cycle transfer mode, or to a wait state.
In the last T2R state, read data is sampled. After entering the last T2R state, the bus invariably enters the
T1W state.
(6) T2RI state
Internal peripheral I/O or internal RAM DMA transfer ready state (Bus mastership is acquired for DMA transfer
to internal peripheral I/O or internal RAM). After entering the last T2RI state, the bus invariably enters the
T1W state.
(7) T1W state
The bus enters the T1W state at the beginning of a write operation in two-cycle transfer mode. Address
driving starts. After entering the T1W state, the bus invariably enters the T2W state.
(8) T1WI state
T1WI is a state in which the bus is waiting for the acknowledge signal in response to an external memory
write request. After entering the last T1WI state, the bus invariably enters the T2W state.
(9) T2W state
The T2W state corresponds to the last state of a write operation in two-cycle transfer mode, or to a wait state.
In the last T2W state, the write strobe signal is made inactive.
(10) T1F state
The bus enters the T1F state at the beginning of a flyby transfer from internal peripheral I/O to internal RAM.
The read cycle from internal peripheral I/O is started. After entering the T1F state, the bus invariably enters
the T2F state.
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CHAPTER 6 DMA FUNCTIONS (DMA CONTROLLER)
(11) T2F state
The T2F state corresponds to the middle state of a flyby transfer from internal peripheral I/O to internal RAM.
The write cycle to internal RAM is started. After entering the T2F state, the bus invariably enters the T3F
state.
(12) T3F state
The T3F state corresponds to the last state of a flyby transfer from internal peripheral I/O to internal RAM, or
a wait state. In the last T3F state, the write strobe signal is made inactive.
(13) T1FR state
The bus enters the T1FR state at the beginning of a flyby transfer from internal RAM to internal peripheral I/O.
The read cycle from internal RAM is started. After entering the T1FR state, the bus invariably enters the
T2FR state.
(14) T2FR state
The T2FR state corresponds to the middle state of a flyby transfer from internal RAM to internal peripheral
I/O. The write cycle to internal peripheral I/O is started. After entering the T2FR state, the bus invariably
enters the T3FR state.
(15) T3FR state
T3FR is a state in which it is judged whether a flyby transfer from internal RAM to internal peripheral I/O is
continued or not. If the next transfer is executed in block transfer mode, the bus enters the T1FRB state after
the T3FR state, otherwise, the bus enters the T4 state.
(16) T1FRB state
The bus enters the T1FRB state at the beginning of a flyby block transfer from internal RAM to internal
peripheral I/O. The read cycle from internal RAM is started.
(17) T1FRBI state
The T1FRBI state corresponds to a wait state of a flyby block transfer from internal RAM to internal peripheral
I/O.
A wait state requested by peripheral hardware is generated, and the bus enters the T2FRB state.
(18) T2FRB state
The T2FRB state corresponds to the middle state of a flyby block transfer from internal RAM to internal
peripheral I/O. The write cycle to internal peripheral I/O is started. After entering the T2FRB state, the bus
invariably enters the T3FRB state.
(19) T3FRB state
T3FRB is a state in which it is judged whether a flyby transfer from internal RAM to internal peripheral I/O is
continued or not. If the next transfer is executed in block transfer mode, the bus enters the T1FRB state after
the T3FRB state, otherwise, the bus enters the T4 state.
(20) T4 state
The T4 state corresponds to a wait state of a flyby transfer from internal RAM to internal peripheral I/O. A
wait state requested by peripheral hardware is generated, and the bus enters the T3 state.
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(21) T1FH state
The T1FH state corresponds to the standard state of a flyby transfer between external memory and external
I/O, and is the executing cycle of this transfer. After entering the T1FH state, the bus enters the T2FH state.
(22) T1FHI state
The T1FHI state corresponds to the last state of a flyby transfer between external memory and external I/O,
and is a state in which the bus is waiting for end of DMA flyby transfer. After entering the T1FHI state, the
bus is released, and enters the TE state.
(23) T2FH state
T2FH is a state in which it is judged whether a flyby transfer between external memory and external I/O is
continued or not. If the next transfer is executed in block transfer mode, the bus enters the T1FH state after
the T2FH state, otherwise, when a wait is issued, the bus enters the T1FHI state. When a wait is not issued,
the bus is released, and enters the TE state.
(24) T3 state
The bus enters the T3 state when a DMA transfer has been completed, and the bus has been released. After
entering the T3 state, the bus invariably enters the TE state.
(25) TE state
The TE state corresponds to the output state. In the TE state, the DMAC outputs the DMA transfer end signal
(TCn), and initializes miscellaneous internal signals (n = 0 to 3).
After entering the TE state, the bus
invariably enters the TI state.
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CHAPTER 6 DMA FUNCTIONS (DMA CONTROLLER)
6.4.2 DMAC state transition
Except block transfer mode, each time the processing for a DMA service is completed, the bus is released (the
bus enters bus release mode).
Figure 6-1. DMAC Bus Cycle State Transition Diagram
(a) Two-cycle transfer
(b) Flyby transfer
TI
TI
T0
T0
T1FR
T1R
T1RI
T2FR
T1F
T1FH
T2R
T3FR
T2F
T2RI
T1FRB
T1W
T3F
T1FRBI
T1WI
T2W
T2FRB
T1FHI
T3FRB
T3
T4
T3
TE
TE
TI
TI
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CHAPTER 6 DMA FUNCTIONS (DMA CONTROLLER)
6.5
Transfer Mode
6.5.1 Single transfer mode
In single transfer mode, the DMAC releases the bus at each byte/halfword transfer. If there is a subsequent DMA
transfer request, transfer is performed again. This operation continues until a terminal count occurs.
When the DMAC has released the bus, if another higher priority DMA transfer request is issued, the higher priority
DMA request always takes precedence.
Figures 6-2 and 6-3 show examples of single transfer. Figure 6-3 shows an example of single transfer in which a
higher priority DMA request is issued. DMA channels 0 to 2 are in block transfer mode and channel 3 is in single
transfer mode.
Figure 6-2. Single Transfer Example 1
DMARQ3
CPU CPU DMA3 CPU DMA3 CPU DMA3 CPU CPU CPU CPU CPU CPU DMA3 CPU DMA3 CPU CPU CPU
DMA channel 3 terminal count
Figure 6-3. Single Transfer Example 2
DMARQ0
DMARQ1
DMARQ2
DMARQ3
Note
Note
Note
Note
CPU CPU CPU DMA3 CPU DMA0 DMA0 CPU DMA1 DMA1 CPU DMA2 DMA2 CPU DMA3 CPU DMA3
DMA channel 1
terminal count
DMA channel 0
terminal count
DMA channel 3
terminal count
DMA channel 2
terminal count
Note The bus is always released.
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CHAPTER 6 DMA FUNCTIONS (DMA CONTROLLER)
6.5.2 Single-step transfer mode
In single-step transfer mode, DMAC releases the bus at each byte/halfword transfer. Once a request signal
(DMARQ0 to DMARQ3) is received, this operation continues until a terminal count occurs.
When the DMAC has released the bus, if another higher priority DMA transfer request is issued, the higher priority
DMA request always takes precedence.
Figures 6-4 and 6-5 show examples of single-step transfer.
Figure 6-4. Single-Step Transfer Example 1
DMARQ1
CPU CPU CPU DMA1 CPU DMA1 CPU DMA1 CPU DMA1 CPU CPU CPU CPU CPU CPU CPU
DMA channel 1 terminal count
Figure 6-5. Single-Step Transfer Example 2
DMARQ0
DMARQ1
CPU CPU CPU DMA1 CPU DMA1 CPU DMA0 CPU DMA0 CPU DMA0 CPU DMA1 CPU DMA1 CPU
DMA channel 0
terminal count
DMA channel 1
terminal count
6.5.3 Block transfer mode
In block transfer mode, once transfer starts, the transfer continues without the bus being released, until a terminal
count occurs. No other DMA requests are accepted during block transfer.
After the block transfer ends and DMAC releases the bus, another DMA transfer can be accepted.
Figures 6-6 shows an example of block transfer. In this block transfer example, a high priority DMA request is
issued. DMA channels 2 and 3 are in block transfer mode.
Note that caution is required when in block transfer mode. For details, refer to 6.19 Precautions.
Figure 6-6. Block Transfer Example
DMARQ2
DMARQ3
CPU CPU CPU DMA3 DMA3 DMA3 DMA3 DMA3 DMA3 DMA3 DMA3 CPU DMA2 DMA2 DMA2 DMA2 DMA2
DMA channel 3
terminal count
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The bus is always released.
CHAPTER 6 DMA FUNCTIONS (DMA CONTROLLER)
6.6
Transfer Types
6.6.1 Two-cycle transfer
In two-cycle transfer, data transfer is performed in two-cycles, source to DMAC then DMAC to destination.
In the first cycle, the source address is output to perform reading from the source to DMAC. In the second cycle,
the destination address is output to perform writing from DMAC to the destination.
Figure 6-7 shows examples of two-cycle transfer.
Note that caution is required when in two-cycle transfer. For details, refer to 6.19 Precautions.
Figure 6-7. Timing of Two-Cycle Transfer (1/4)
(a) Block transfer mode (SRAM → DRAM)
BCU states
DMAC states
CLKOUT
TI
TI
TI
TI
T0
T1
T2
T1
T2
T3
T1 TW T2 TO1 TO2
T1R T2R T1W T2W T2W T1R T2R T2R T1W T2W
TE
TI
DMARQn
Internal DMA
request signal
DMAAKn
TCn
Address
A0 to A23
D0 to D15
Row
address
Data
Column address
Data
Address
Data
Column address
Data
DRAM area
CSj/RASj
SRAM area
CSk/RASk
BCYST
RD
OE
WE
UWR/UCAS
LWR/LCAS
IORD
IOWR
WAIT
Remarks 1. The circles indicate the sampling timing.
2. Broken lines indicate high impedance.
3. n = 0 to 3
j = 0 to 7, k = 0 to 7 (However, j ≠ k.)
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CHAPTER 6 DMA FUNCTIONS (DMA CONTROLLER)
Figure 6-7. Timing of Two-Cycle Transfer (2/4)
(b) Single-step transfer mode (External I/O → SRAM)
BCU states
DMAC states
TI
TI
TI
TI
T1 T2 T1 T2
T0 T1R T2R T1W T2W TE
TI
T1 TW T2 T1 TW T2
T0 T1R T2R T2R T1W T2W T2W TE
CLKOUT
DMARQn
Internal DMA
request signal
DMAAKn
TCn
Address
A0 to A23
Address
Address
Data
Data
Data
D0 to D15
External I/O area
CSj/RASj
SRAM area
CSk/RASk
BCYST
RD
OE
WE
UWR/UCAS
LWR/LCAS
IORD
IOWR
WAIT
Remarks 1. The circles indicate the sampling timing.
2. Broken lines indicate high impedance.
3. n = 0 to 3
j = 0 to 7, k = 0 to 7 (However, j ≠ k.)
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Address
Data
TI
CHAPTER 6 DMA FUNCTIONS (DMA CONTROLLER)
Figure 6-7. Timing of Two-Cycle Transfer (3/4)
(c) Single transfer mode (Internal peripheral I/O → DRAM)
CPU states
DMAC states
CLKOUT
TI
TI
TI
TI
T0
T0
T1R
T2R
T2
T1
T3
T2R T1W T2W T2W
T3
T3
TE
TI
DMARQn
Internal DMA
request signal
DMAAKn
TCn
Row
address
A0 to A23
Column address
Data
D0 to D15
CSm/RASm
BCYST
RD
OE
WE
UWR/UCAS
LWR/LCAS
IORD
IOWR
WAIT
Remarks 1. The circles indicate the sampling timing.
2. Broken lines indicate high impedance.
3. n = 0 to 3
m = 0 to 7
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CHAPTER 6 DMA FUNCTIONS (DMA CONTROLLER)
Figure 6-7. Timing of Two-Cycle Transfer (4/4)
(d) Single transfer mode (DRAM → Internal peripheral I/O)
CPU states
DMAC states
CLKOUT
TI
TI
TI
TI
T0
T1
T1R
T2
T2R
T3
T2R T2RI T1W T2W T2W
DMARQn
Internal DMA
request signal
DMAAKn
TCn
Row
address
A0 to A23
Column address
Data
D0 to D15
CSm/RASm
BCYST
RD
OE
WE
UWR/UCAS
LWR/LCAS
IORD
IOWR
WAIT
Remarks 1. The circles indicate the sampling timing.
2. Broken lines indicate high impedance.
3. n = 0 to 3
m = 0 to 7
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T3
T3
TE
TI
CHAPTER 6 DMA FUNCTIONS (DMA CONTROLLER)
6.6.2 Flyby transfer
The V850E/MS1 supports flyby transfer between external memory and external I/O, and internal RAM and internal
peripheral I/O.
(1) Flyby transfer between external memory and external I/O
This data transfer between memory and I/O is performed in one cycle. To achieve single-cycle transfer, the
memory address is always output irrespective of whether it is that of the source or the destination, and the
read/write strobe signals for the memory and I/O are made active at the same time.
The external I/O is selected with the DMAAK0 to DMAAK3 signal.
Figure 6-8 shows examples of flyby DMA transfer for an external device.
Figure 6-8. Timing of Flyby Transfer (DRAM → External I/O) (1/3)
(a) Block transfer mode
CPU states
DMAC states
TI
TI
TI
TI
T0
T1
T2
T3
TO1 TW
TO2
T1FH T2FH T2FH T1FH T1FHI T1FHI
TE
TI
CLKOUT
DMARQn
Internal DMA
request signal
DMAAKn
TCn
Row
address
A0 to A23
D0 to D15
Column address
Column address
Data
Data
CSm/RASm
BCYST
RD
OE
WE
UWR/UCAS
LWR/LCAS
IORD
IOWR
WAIT
Remarks 1. The circles indicate the sampling timing.
2. Broken lines indicate high impedance.
3. n = 0 to 3
m = 0 to 7
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CHAPTER 6 DMA FUNCTIONS (DMA CONTROLLER)
Figure 6-8. Timing of Flyby Transfer (DRAM → External I/O) (2/3)
(b) Single transfer mode
CPU states
DMAC states
TI
TI
TI
TI
T1 T2 T3
T0 T1FH T1FHI T1FHI TE
TI
TI
TI
TI
T1 T2 T3
T0 T1FH T1FHI T1FHI TE
CLKOUT
DMARQn
Internal DMA
request signal
DMAAKn
TCn
Row
address
A0 to A23
Column address
Data
D0 to D15
CSm/RASm
BCYST
RD
OE
WE
UWR/UCAS
LWR/LCAS
IORD
IOWR
WAIT
Remarks 1. The circles indicate the sampling timing.
2. Broken lines indicate high impedance.
3. n = 0 to 3
m = 0 to 7
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Row
address
Column address
Data
TI
TI
CHAPTER 6 DMA FUNCTIONS (DMA CONTROLLER)
Figure 6-8. Timing of Flyby Transfer (DRAM → External I/O) (3/3)
(c) Single-step transfer mode
CPU states
DMAC states
CLKOUT
TI
TI
TI
TI
T0
T2
T3
T1
T1FH T1FHI T1FHI
TE
TI
T0
T1
T2
T3
T1FH T1FHI T1FHI
TE
TI
TI
DMARQn
Internal DMA
request signal
DMAAKn
TCn
Row
address
A0 to A23
Column address
D0 to D15
Data
Row
address
Column address
Data
CSm/RASm
BCYST
RD
OE
WE
UWR/UCAS
LWR/LCAS
IORD
IOWR
WAIT
Remarks 1. The circles indicate the sampling timing.
2. Broken lines indicate high impedance.
3. n = 0 to 3
m = 0 to 7
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CHAPTER 6 DMA FUNCTIONS (DMA CONTROLLER)
(2) Flyby transfer between internal RAM and internal peripheral I/O
Internal RAM and internal peripheral I/O are mapped on different address spaces.
Therefore, different
addresses are always output, and the read/write strobe signals for internal RAM and internal peripheral I/O
are controlled at the same time.
Figure 6-9 shows an example of flyby DMA transfer (block transfer mode) between internal RAM and internal
peripheral I/O.
Figure 6-9. Timing of Flyby Transfer (Internal Peripheral I/O → Internal RAM)
TI
TI
TI
TI
T0
T0
T1F
T2F T3F
T1F
T2F T3F
T3F
T3
T3
TE
TI
CLKOUT
DMARQn
Internal DMA
request signal
DMAAKn
H
TCn
Internal
address bus
Internal data bus
Address
Address
Data
Internal peripheral
I/O address bus
Address
Data
Address
Data
Data
Remarks 1. The circles indicate the sampling timing.
2. Broken lines indicate high impedance.
3. n = 0 to 3
4. With this timing, the external bus operates independently of the internal bus, so there is no
influence on the external bus.
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CHAPTER 6 DMA FUNCTIONS (DMA CONTROLLER)
6.7
Transfer Objects
6.7.1 Transfer type and transfer objects
Table 6-1 lists the relationship between transfer type and transfer object.
Cautions 1. Among the transfer destinations and sources shown in Table 6-1, when an “×
×” is indicated
for a combination, that operation is not guaranteed.
2. Make the data bus width of the transfer destination and source the same (for two-cycle
transfer and flyby transfer).
Table 6-1. Relationship Between Transfer Type and Transfer Object
(a) Two-cycle transfer
(b) Flyby transfer
Destination
Internal
RAM
External
memory
Internal
peripheral I/O
×
×
{
{
External I/O
×
×
{
{
Internal RAM
{
{
{
{
External
memory
{
{
{
{
Remark
{:
Possible
×:
Impossible
Internal External
I/O
peripheral
I/O
Source
Source
Internal External
I/O
peripheral
I/O
Destination
Internal
RAM
External
memory
Internal
peripheral I/O
×
×
{
×
External I/O
×
×
×
{
Internal RAM
{
×
×
×
External
memory
×
{
×
×
6.7.2 External bus cycle during DMA transfer
The external bus cycle during DMA transfer is as follows.
Table 6-2. External Bus Cycle During DMA Transfer
Transfer Type
Two-cycle transfer
Flyby transfer
Transfer Object
External Bus Cycle
Internal peripheral I/O, Internal
RAM
None
External I/O
Yes
External memory
Yes
Note
SRAM cycle
Memory access cycle set in the BCT register
Note
Between internal RAM and
internal peripheral I/O
None
Between external memory and
external I/O
Yes
The memory access DMA flyby transfer cycle
set by the BCT register as external memory
Note Other external bus cycles, such as a CPU-based bus cycle, can be started.
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CHAPTER 6 DMA FUNCTIONS (DMA CONTROLLER)
6.8
DMA Channel Priorities
The DMA channel priorities are fixed, as follows:
DMA channel 0 > DMA channel 1 > DMA channel 2 > DMA channel 3
These priorities are valid in the TI state only. In block transfer mode, the channel used for transfer is never
switched.
In single-step transfer mode, if a higher priority DMA transfer request is issued while the bus is released (in the TI
state), the higher priority DMA transfer request is accepted.
6.9
Next Address Setting Function
The DMA source address registers (DSAnH, DSAnL) DMA destination address registers (DDAnH, DDAnL) and
DMA byte count register (DBCn) are buffer registers with a 2-stage FIFO configuration (n = 0 to 3).
When the terminal count is issued, these registers are rewritten with the value that was set just previously.
Therefore, during DMA transfer, these registers’ contents do not become valid even if they are rewritten. When
starting DMA transfer with the rewritten contents of these registers, set the ENn bit (1) of the DCHCn register.
Figure 6-10 shows the buffer register configuration.
Figure 6-10. Buffer Register Configuration
Internal bus
Reading of data
190
Writing of data
Master
register
Slave
register
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count
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CHAPTER 6 DMA FUNCTIONS (DMA CONTROLLER)
6.10 DMA Transfer Start Factors
There are 3 types of DMA transfer start factors, as shown below.
(1) Request from an external pin (DMARQn)
Although requests from the DMARQn pin are sampled each time the CLKOUT signal falls, sampling should
be continued until the DMAAKn signal becomes active (n = 0 to 3).
If a state in which the ENn bit of the DCHCn register = 1 and the TCn bit = 0 is set, the DMARQn signal in the
T1 state becomes active. If the DMARQn signal becomes active in the T1 state, it changes to the T0 state
and DMA transfer starts.
(2) Request from software
If the STGn, ENn and TCn bits of the DCHCn register are set as follows, DMA transfer starts (n = 0 to 3).
• STGn bit = 1
• ENn bit = 1
• TCn bit = 0
(3) Request from internal peripheral I/O
If, when the ENn and TCn bits of the DCHCn register are set as shown below, an interrupt request is issued
from the internal peripheral I/O that is set in the DTFRn register, DMA transfer starts (n = 0 to 3).
• ENn bit = 1
• TCn bit = 0
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CHAPTER 6 DMA FUNCTIONS (DMA CONTROLLER)
6.11 Interrupting DMA Transfer
6.11.1 Interruption factors
DMA transfer is interrupted if the following factors occur.
• Bus hold
• Refresh cycle
If the factor that is interrupting DMA transfer disappears, DMA transfer promptly restarts.
6.11.2 Forcible interruption
DMA transfer can be forcibly interrupted by an NMI input during DMA transfer.
At such a time, the DMAC resets the ENn bit of the DCHCn register of all channels (0) and activates the DMA
transfer disabled state, after which the DMA transfer being executed when the NMI was input is terminated (n = 0 to
3).
When in the single step mode or block transfer mode, the DMA transfer request is held in the DMAC. If the ENn
bit is reset (1), DMA transfer restarts from the point where it was interrupted.
When in the single transfer mode, if the ENn bit is set (1), the next DMA transfer request is received and DMA
transfer starts.
6.12 Terminating DMA Transfer
6.12.1 DMA transfer end interrupt
When DMA transfer ends and the TC bit of the corresponding DCHCn register is set (1), a DMA transfer end
interrupt (INTDMAn) is issued (n = 0 to 3) to the interrupt controller (INTC).
6.12.2 Terminal count output
In the TI state directly after the cycle when DMA transfer ends (TE state), the TCn signal output becomes active
for 1 clock cycle.
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6.12.3 Forcible termination
In addition to forcible interruption of DMA transfer by NMI input, DMA transfer can also be terminated forcibly by
the INITn bit of the DCHCn register. Examples of the forcible termination operation are shown below (n = 0 to 3).
Figure 6-11. Example of Forcible Termination of DMA Transfer
(a) During block transfer through DMA channel 2, transfer through DMA channel 3 is started.
DSA2, DDA2, DBC2,
DADC2, DCHC2
DCHC2
(INIT2 bit = 1)
Register set
DMARQ2
Register set
EN2 bit → 0
TC2 bit = 0
EN2 bit = 1
TC2 bit = 0
DSA3, DDA3, DBC3,
DADC3, DCHC3
Register set
DMARQ3
EN3 bit → 0
TC3 bit → 1
EN3 bit = 1
TC3 bit = 0
CPU CPU CPU CPU DMA2 DMA2 DMA2 DMA2 DMA2 CPU DMA3 DMA3 DMA3 DMA3 CPU CPU CPU
DMA channel 3 transfer termination
DMA channel 3 transfer start
DMA channel 2 transfer is forcibly terminated.
The bus is released.
(b) During block transfer through DMA channel 1, transfer is terminated, and a different
conditional transfer is executed.
DSA1, DDA1, DBC1,
DADC1, DCHC1
Register set
DMARQ1
EN1 bit = 1
TC1 bit = 0
DSA1, DDA1,
DBC1
DCHC1
(INIT1 bit = 1)
Register set
DADC1,
DCHC1
Register set Register set
EN1 bit → 0
TC1 bit = 0
EN1 bit → 0
TC1 bit → 1
EN1 bit = 1
TC1 bit = 0
CPU CPU CPU CPU DMA1 DMA1 DMA1 DMA1 DMA1 DMA1 CPU CPU CPU CPU DMA1 DMA1 DMA1 CPU
DMA channel 1 transfer termination
DMA channel 1 transfer is forcibly terminated.
The bus is released.
Remark
During DMA transfer, the next condition can be set, because the DSAn, DDAn, DBCn registers are
buffered registers, but the setting to the DADCn register is ignored (refer to 6.9 Next Address
Setting Function).
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CHAPTER 6 DMA FUNCTIONS (DMA CONTROLLER)
6.13 Boundary of Memory Area
The transfer operation is not guaranteed if the source or the destination address is over the area of DMA objects
(external memory, internal RAM, external I/O, or internal peripheral I/O) during DMA transfer.
6.14 Transfer of Misalign Data
16-bit DMA transfer of misalign data is not supported. If the source or the destination address is set to an odd
address, the LSB bit of the address is forcibly accepted as “0”.
6.15 Clocks of DMA Transfer
Table 6-3 lists the overhead before and after DMA transfer and minimum execution clock for DMA transfer.
Table 6-3. Minimum Execution Clock in DMA Cycle
From accepting DMARQn to falling edge of DMAAKn
4 clocks
External memory access
Refer to miscellaneous memory and I/O cycle
Internal RAM access
2 clocks
Internal peripheral I/O access
3 clocks
From rising edge of DMAAKn to falling edge of TCn
1 clock
Remark
n = 0 to 3
6.16 Maximum Response Time to DMA Request
Under the conditions shown below, the response time to a DMA request becomes the maximum time (this is the
state permitted by the DRAM refresh cycle).
(1) Condition 1
Condition
Instruction fetch from external memory at the 8-bit data bus width
Response time
Tinst × 4 + Tref
DMARQn (input)
DMAAKn (output)
D0 to D15 (input/output)
194
Fetch (1/4) Fetch (2/4) Fetch (3/4) Fetch (4/4)
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DMA cycle
CHAPTER 6 DMA FUNCTIONS (DMA CONTROLLER)
(2) Condition 2
Condition
Word data access with external memory at the 8-bit data bus width
Response time
Tdata × 4 + Tref
DMARQn (input)
DMAAKn (output)
D0 to D15 (input/output)
Data (1/4)
Data (2/4)
Data (3/4)
Data (4/4)
Refresh
DMA cycle
(3) Condition 3
Condition
Instruction fetch from external memory at the 8-bit data bus width.
Execution of the bit manipulation instruction (SET1, CLR1, NOT1).
Response time
Tinst × 4 + Tdata × 2 + Tref
DMARQn (input)
DMAAKn (output)
D0 to D15 (input/output)
Remarks 1. Tinst:
Data read Fetch (1/4) Fetch (2/4) Fetch (3/4)
Fetch (4/4)
Data write
Refresh
DMA cycle
The number of clocks per bus cycle during instruction fetch.
Tdata: The number of clocks per bus cycle during data access.
Tref:
The number of clocks per refresh cycle.
2. n = 0 to 3
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6.17 One Time Single Transfer with DMARQ0 to DMARQ3
To execute one time single transfer to external memory via DMARQn signal input, DMARQn should be inactive
within the clock time shown in Table 6-4 from when DMAAKn becomes active (n = 0 to 3). If DMARQn is active for
more than the clock time shown in Table 6-4, single transfers are continuously executed.
Time for a single transfer
one time only.
DMARQn (input)
DMAAKn (output)
Table 6-4. DMAAKn Active → DMARQn Inactive Time for Single Transfer to External Memory
Transfer Type
Two-cycle transfer
Flyby transfer
Source
Destination
DRAM (off page)
All objects
5 clocks
DRAM (on page)
All objects
4 clocks
SRAM or external I/O
All objects
4 clocks
Internal RAM or internal peripheral
I/O
DRAM (off page)
7 clocks
Internal RAM or internal peripheral
I/O
DRAM (on page)
6 clocks
Internal RAM
SRAM or external I/O
6 clocks
Internal peripheral I/O
SRAM
6 clocks
DRAM (off page) ↔ External I/O
3 clocks
DRAM (on page) ↔ External I/O
2 clocks
SRAM ↔ External I/O
2 clocks
Note When inserting waits, add the number of waits together.
Remark
196
DMAAKn Signal Active →
Note
DMARQn Inactive Time (Max.)
n = 0 to 3
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CHAPTER 6 DMA FUNCTIONS (DMA CONTROLLER)
Also, if a single transfer is executed between internal RAM and internal peripheral I/O, it is necessary that the
DMARQn signal be inactivated within 8 clock cycles after it is activated. If 8 clock cycles are exceeded, transfer may
continue. Note that the DMAAKn signal does not become active at this time.
Time for a single transfer
one time only.
8 clocks (MAX.)
DMARQn (input)
DMAAKn (output)
H
6.18 Bus Arbitration for CPU
The CPU can access any external memory, external I/O, internal RAM, and internal peripheral I/O not undergoing
DMA transfer.
While data is being transferred between external memory and external I/O, the CPU can access internal RAM and
internal peripheral I/O.
While data transfer is being executed between internal RAM and internal peripheral I/O, the CPU can access
external memory and external I/O.
6.19 Precaution
If a DMA transfer which satisfies all the following conditions is interrupted by NMI input, the DMAAKn signal may
become active and remain so until the next DMA transfer (n = 0 to 3).
• Two-cycle transfer
• Block transfer mode
• Transfer from external memory to external memory, or from external I/O to external I/O
• The destination side is EDO DRAM, with no-wait on-page access.
Note that device operations other than the DMAAKn signal are not influenced.
Change the DMAAKn signal to inactive by executing the routine shown below in the NMI handler, etc.
LD.B
DDIS[r0], reg ; Confirm the interrupted DMA channel by NMI input.
ST.B
reg, DRST[r0] ; Restart transfer in the interrupted channel.
ST.B
r0, DRST[r0] ; By immediately interrupting transfer again, after DMA transfer only once, the DMAAKn
signal becomes inactive.
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[MEMO]
198
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CHAPTER 7 INTERRUPT/EXCEPTION PROCESSING FUNCTION
The V850E/MS1 is provided with a dedicated interrupt controller (INTC) for interrupt processing and can process a
total of 48 interrupt requests.
An interrupt is an event that occurs independently of program execution, and an exception is an event that is
dependent on program execution. Generally, an exception takes precedence over an interrupt.
The V850E/MS1 can process interrupt requests from the internal peripheral hardware and external sources.
Moreover, exception processing can be started by the TRAP instruction (software exception) or by the generation of
an exception event (fetching of an illegal op code), which is known as an exception trap.
7.1
Features
{ Interrupts
• Non-maskable interrupts: 1 source
• Maskable interrupts: 47 sources
• 8 levels of programmable priorities
• Mask specification for interrupt requests according to priority
• Mask can be specified for each maskable interrupt request.
• Noise elimination, edge detection, and valid edge of external interrupt request signal can be specified.
{ Exceptions
• Software exceptions: 32 sources
• Exception trap: 1 source (illegal op code exception)
Interrupt/exception sources are listed in Table 7-1.
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CHAPTER 7 INTERRUPT/EXCEPTION PROCESSING FUNCTION
Table 7-1. Interrupt List (1/3)
Type
Classification
Interrupt/Exception Source
Name
Controlling
Source
Generating
Register
Default
Exception
Handler
Priority
Code
Address
Restored PC
Unit
Reset
Interrupt
RESET
—
RESET input
Pin
—
0000H
00000000H Undefined
Non-maskable
Interrupt
NMI
—
NMI input
Pin
—
0010H
00000010H nextPC
Software
exception
Exception
Note
TRAP0
Note
—
TRAP instruction
—
—
Note
00000040H nextPC
Note
00000050H nextPC
004n
H
Exception
TRAP1n
—
TRAP instruction
—
—
005n
Exception trap
Exception
ILGOP
—
Illegal op code
—
—
0060H
00000060H nextPC
Maskable
Interrupt
INTOV10
OVIC10
Timer 10 overflow
RPU
0
0080H
00000080H nextPC
Interrupt
INTOV11
OVIC11
Timer 11 overflow
RPU
1
0090H
00000090H nextPC
Interrupt
INTOV12
OVIC12
Timer 12 overflow
RPU
2
00A0H
000000A0H nextPC
Interrupt
INTOV13
OVIC13
Timer 13 overflow
RPU
3
00B0H
000000B0H nextPC
Interrupt
INTOV14
OVIC14
Timer 14 overflow
RPU
4
00C0H
000000C0H nextPC
Interrupt
INTOV15
OVIC15
Timer 15 overflow
RPU
5
00D0H
000000D0H nextPC
INTP100/
P10IC0
Match of INTP100
Pin/RPU
6
0100H
00000100H nextPC
Pin/RPU
7
0110H
00000110H nextPC
Pin/RPU
8
0120H
00000120H nextPC
Pin/RPU
9
0130H
00000130H nextPC
Pin/RPU
10
0140H
00000140H nextPC
Pin/RPU
11
0150H
00000150H nextPC
Pin/RPU
12
0160H
00000160H nextPC
Pin/RPU
13
0170H
00000170H nextPC
Pin/RPU
14
0180H
00000180H nextPC
Pin/RPU
15
0190H
00000190H nextPC
Pin/RPU
16
01A0H
000001A0H nextPC
Pin/RPU
17
01B0H
000001B0H nextPC
Pin/RPU
18
01C0H
000001C0H nextPC
Pin/RPU
19
01D0H
000001D0H nextPC
Interrupt
INTCC100
Interrupt
INTP101/
pin/CC100
P10IC1
INTCC101
Interrupt
INTP102/
INTP103/
P10IC2
INTP110/
P10IC3
INTP111/
P11IC0
INTP112/
P11IC1
INTP113/
P11IC2
INTP120/
P11IC3
INTP121/
P12IC0
INTP122/
P12IC1
INTP123/
P12IC2
INTP130/
P12IC3
INTP131/
INTCC131
Match of INTP123
pin/CC123
P13IC0
INTCC130
Interrupt
Match of INTP122
pin/CC122
INTCC123
Interrupt
Match of INTP121
pin/CC121
INTCC122
Interrupt
Match of INTP120
pin/CC120
INTCC121
Interrupt
Match of INTP113
pin/CC113
INTCC120
Interrupt
Match of INTP112
pin/CC112
INTCC113
Interrupt
Match of INTP111
pin/CC111
INTCC112
Interrupt
Match of INTP110
pin/CC110
INTCC111
Interrupt
Match of INTP103
pin/CC103
INTCC110
Interrupt
Match of INTP102
pin/CC102
INTCC103
Interrupt
Match of INTP101
pin/CC101
INTCC102
Interrupt
Match of INTP130
pin/CC130
P13IC1
Match of INTP131
pin /CC131
Note n = 0 to FH
200
H
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CHAPTER 7 INTERRUPT/EXCEPTION PROCESSING FUNCTION
Table 7-1. Interrupt List (2/3)
Type
Classification
Interrupt/Exception Source
Name
Controlling
Source
Generating
Register
Maskable
Interrupt
INTP132/
P13IC2
INTCC132
Interrupt
INTP133/
INTP140/
P13IC3
INTP141/
P14IC0
INTP142/
P14IC1
INTP143/
P14IC2
INTP150/
P14IC3
INTP151/
P15IC0
INTP152/
P15IC1
INTP153/
20
01E0H
000001E0H
nextPC
Match of INTP133
Pin/RPU
21
01F0H
000001F0H
nextPC
Match of INTP140
Pin/RPU
22
0200H
00000200H
nextPC
Match of INTP141
Pin/RPU
23
0210H
00000210H
nextPC
Match of INTP142
Pin/RPU
24
0220H
00000220H
nextPC
Match of INTP143
Pin/RPU
25
0230H
00000230H
nextPC
Match of INTP150
Pin/RPU
26
0240H
00000240H
nextPC
Match of INTP151
Pin/RPU
27
0250H
00000250H
nextPC
Pin/RPU
28
0260H
00000260H
nextPC
Pin/RPU
29
0270H
00000270H
nextPC
pin/CC151
P15IC2
INTCC152
Interrupt
Pin/RPU
pin/CC150
INTCC151
Interrupt
Match of INTP132
pin/CC143
INTCC150
Interrupt
Unit
pin/CC142
INTCC143
Interrupt
PC
pin/CC141
INTCC142
Interrupt
Restored
Address
pin/CC140
INTCC141
Interrupt
Handler
Code
pin/CC133
INTCC140
Interrupt
Exception
Priority
pin/CC132
INTCC133
Interrupt
Default
Match of INTP152
pin/CC152
P15IC3
INTCC153
Match of INTP153
pin/CC153
Interrupt
INTCM40
CMIC40
CM40 match signal
RPU
30
0280H
00000280H
nextPC
Interrupt
INTCM41
CMIC41
CM41 match signal
RPU
31
0290H
00000290H
nextPC
Interrupt
INTDMA0
DMAIC0
DMA channel 0
DMAC
32
02A0H
000002A0H
nextPC
DMAC
33
02B0H
000002B0H
nextPC
DMAC
34
02C0H
000002C0H
nextPC
DMAC
35
02D0H
000002D0H
nextPC
SIO
36
0300H
00000300H
nextPC
SIO
37
0310H
00000310H
nextPC
SIO
38
0320H
00000320H
nextPC
SIO
39
0330H
00000330H
nextPC
transfer completion
Interrupt
INTDMA1
DMAIC1
DMA channel 1
transfer completion
Interrupt
INTDMA2
DMAIC2
DMA channel 2
transfer completion
Interrupt
INTDMA3
DMAIC3
DMA channel 3
transfer completion
Interrupt
INTCSI0
CSIC0
CSI0 transmission/
reception
completion
Interrupt
INTSER0
SEIC0
UART0 reception
error
Interrupt
INTSR0
SRIC0
UART0 reception
completion
Interrupt
INTST0
STIC0
UART0
transmission
completion
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CHAPTER 7 INTERRUPT/EXCEPTION PROCESSING FUNCTION
Table 7-1. Interrupt List (3/3)
Type
Classification
Interrupt/Exception Source
Name
Controlling
Source
Generating
Register
Maskable
Interrupt
INTCSI1
CSIC1
Default
Exception
Handler
Restored
Priority
Code
Address
PC
Unit
CSI1 transmission/
SIO
40
0340H
00000340H
nextPC
SIO
41
0350H
00000350H
nextPC
SIO
42
0360H
00000360H
nextPC
SIO
43
0370H
00000370H
nextPC
SIO
44
0380H
00000380H
nextPC
SIO
45
03C0H
000003C0H
nextPC
ADC
46
0400H
00000400H
nextPC
reception
completion
Interrupt
INTSER1
SEIC1
UART1 reception
error
Interrupt
INTSR1
SRIC1
UART1 reception
completion
Interrupt
INTST1
STIC1
UART1
transmission
completion
Interrupt
INTCSI2
CSIC2
CSI2 transmission/
reception
completion
Interrupt
INTCSI3
CSIC3
CSI3 transmission/
reception
completion
Interrupt
INTAD
ADIC
A/D conversion
completion
Caution INTP1mn (external interrupt) and INTCC1mn (compare register match interrupt) share a control
register (m = 0 to 5, n = 0 to 3). Set the valid interrupt request using bits 3 to 0 (IMS1mn) of timer
unit mode registers 10 to 15 (TUM10 to TUM15) (see 9.3 (1) Timer unit mode registers 10 to 15
(TUM10 to TUM15)).
Remarks 1. Default priority:
The priority order when two or more maskable interrupt requests occur at the
same time. The highest priority is 0.
Restored PC:
The value of the PC saved to EIPC or FEPC when interrupt/exception processing
is started. However, the value of the PC, which is saved when an interrupt is
acknowledged during division (DIV, DIVH, DIVU, and DIVHU) instruction
execution, is the value of the PC of the current instruction (DIV, DIVH, DIVU, and
DIVHU).
2. The execution address of the illegal instruction when an illegal op code exception occurs is d
202
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CHAPTER 7 INTERRUPT/EXCEPTION PROCESSING FUNCTION
Figure 7-1. Block Diagram of Interrupt Control Function
Internal bus
ISPR register
xxlCn register
DMAC
CSI0
UART0
CSI1
SIO
UART1
CSI2
CSI3
0
1
2
Selector
3
0
3210 3210
1
2
Selector
3
0
3210 3210
1
2
Selector
3
0
A/D converter
OVIF10
OVIF11
OVIF12
OVIF13
OVIF14
OVIF15
P10IF0
P10IF1
P10IF2
P10IF3
P11IF0
P11IF1
P11IF2
P11IF3
P12IF0
P12IF1
P12IF2
P12IF3
P13IF0
P13IF1
P13IF2
P13IF3
P14IF0
P14IF1
P14IF2
P14IF3
P15IF0
P15IF1
P15IF2
P15IF3
CMIF40
CMIF41
DMAIF0
DMAIF1
DMAIF2
DMAIF3
CSIF0
SEIF0
SRIF0
STIF0
CSIF1
SEIF1
SRIF1
STIF1
CSIF2
CSIF3
ADIF
Handler
address
generator
CPU
PSW
xxPRn0 to xxPRn3 (Interrupt priority order specification bit)
INTM6
3210 3210
(edge
detection)
1
Noise
elimination
2
INTP150
INTP151
INTP152
INTP153
INTM5
Selector
(edge
detection)
3
Noise
elimination
0
INTP140
INTP141
INTP142
INTP143
3210 3210
(edge
detection)
INTM4
1
Noise
elimination
2
INTP130
INTP131
INTP132
INTP133
INTM3
(edge
detection)
Selector
Noise
elimination
3
INTP120
INTP121
INTP122
INTP123
0
(edge
detection)
3210 3210
INTM2
1
Noise
elimination
2
INTP110
INTP111
INTP112
INTP113
INTM1
(edge
detection)
Selector
Noise
elimination
3210
RPU
INTP100
INTP101
INTP102
INTP103
3
3210
xxMKn (interrupt mask flag)
INTOV10
INTOV11
INTOV12
INTOV13
INTOV14
INTOV15
INTP100/INTCC100
INTP101/INTCC101
INTP102/INTCC102
INTP103/INTCC103
INTP110/INTCC110
INTP111/INTCC111
INTP112/INTCC112
INTP113/INTCC113
INTP120/INTCC120
INTP121/INTCC121
INTP122/INTCC122
INTP123/INTCC123
INTP130/INTCC130
INTP131/INTCC131
INTP132/INTCC132
INTP133/INTCC133
INTP140/INTCC140
INTP141/INTCC141
INTP142/INTCC142
INTP143/INTCC143
INTP150/INTCC150
INTP151/INTCC151
INTP152/INTCC152
INTP153/INTCC153
INTCM40
INTCM41
INTDMA0
INTDMA1
INTDMA2
INTDMA3
INTCSI0
INTSER0
INTSR0
INTST0
INTCSI1
INTSER1
INTSR1
INTST1
INTCSI2
INTCSI3
INTAD
ID
Interrupt
request
Interrupt
request
acknowledge
HALT mode
release signal
NMI
Remark
xx: OV, CM, P10 to P15, DMA, CS, SE, SR, ST, AD
n:
None, or 10 to 15, 40, 41, 0 to 3
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CHAPTER 7 INTERRUPT/EXCEPTION PROCESSING FUNCTION
7.2
Non-Maskable Interrupt
A non-maskable interrupt request is acknowledged unconditionally, even when interrupts are in the interrupt
disabled (DI) status. An NMI is not subject to priority control and takes precedence over all other interrupts.
A non-maskable interrupt request is input from the NMI pin. When the valid edge specified by bit 0 (ESN0) of the
external interrupt mode register 0 (INTM0) is detected on the NMI pin, the interrupt occurs.
While the service program of the non-maskable interrupt is being executed (PSW.NP = 1), the acknowledgement
of another non-maskable interrupt requests is held pending. The pending NMI is acknowledged after the original
service program of the non-maskable interrupt under execution has been terminated (by the RETI instruction), or
when PSW.NP is cleared to 0 by the LDSR instruction. Note that if two or more NMI requests are input during the
execution of the service program for an NMI, the number of NMIs that will be acknowledged after PSW.NP goes to
‘‘0’’, is only one.
Remark
204
PSW.NP: The NP bit of the PSW register.
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CHAPTER 7 INTERRUPT/EXCEPTION PROCESSING FUNCTION
7.2.1 Operation
If a non-maskable interrupt is generated, the CPU performs the following processing, and transfers control to the
handler routine:
(1) Saves the restored PC to FEPC.
(2) Saves the current PSW to FEPSW.
(3) Writes the exception code (0010H) to the higher halfword (FECC) of ECR.
(4) Sets the NP and ID bits of PSW and clears the EP bit.
(5) Sets the handler address (00000010H) corresponding to the non-maskable interrupt to the PC, and transfers
control.
The processing configuration of a non-maskable interrupt is shown in Figure 7-2.
Figure 7-2. Processing Configuration of Non-Maskable Interrupt
NMI input
NMI acknowledged
Non-maskable interrupt request
CPU processing
PSW.NP
1
0
FEPC
FEPSW
ECR.FECC
PSW.NP
PSW.EP
PSW.ID
PC
restored PC
PSW
0010H
1
0
1
00000010H
Interrupt request pending
Interrupt processing
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CHAPTER 7 INTERRUPT/EXCEPTION PROCESSING FUNCTION
Figure 7-3. Acknowledging Non-Maskable Interrupt Request
(a) If a new NMI request is generated while an NMI service program is being executed:
Main routine
(PSW. NP=1)
NMI request
NMI request
NMI request held pending because PSW. NP = 1
Pending NMI request processed
(b) If a new NMI request is generated twice while an NMI service program is being executed:
Main routine
NMI request
Held pending because NMI service program is being processed
NMI request
Held pending because NMI service program is being processed
NMI request
Only one NMI request is acknowledged even though
two or more NMI requests are generated
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CHAPTER 7 INTERRUPT/EXCEPTION PROCESSING FUNCTION
7.2.2 Restore
Execution is restored from the non-maskable interrupt processing by the RETI instruction.
When the RETI instruction is executed, the CPU performs the following processing, and transfers control to the
address of the restored PC.
(1) Restores the values of the PC and PSW from FEPC and FEPSW, respectively, because the EP bit of PSW is
0 and the NP bit of PSW is 1.
(2) Transfers control back to the address of the restored PC and PSW.
Figure 7-4 illustrates how the RETI instruction is processed.
Figure 7-4. RETI Instruction Processing
RETI instruction
1
PSW.EP
0
PSW.NP
1
0
PC
PSW
EIPC
EIPSW
PC
PSW
FEPC
FEPSW
Original processing restored
Caution When the PSW.EP bit and PSW.NP bit are changed by the LDSR instruction during nonmaskable interrupt processing, in order to restore the PC and PSW correctly during recovery
by the RETI instruction, it is necessary to set PSW.EP back to 0 and PSW.NP back to 1 using
the LDSR instruction immediately before the RETI instruction.
Remark
The solid line shows the CPU processing flow.
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CHAPTER 7 INTERRUPT/EXCEPTION PROCESSING FUNCTION
7.2.3 Non-maskable interrupt status flag (NP)
The NP flag is bit 7 of the PSW.
The NP flag is a status flag that indicates that non-maskable interrupt (NMI) processing is under execution. This
flag is set when the NMI interrupt has been acknowledged, and masks all interrupt requests and exceptions to
prohibit multiple interrupts from being acknowledged.
8 7 6 5 4 3 2 1 0
31
PSW
0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 NP EP ID SAT CY OV S Z
Bit Position
7
Bit Name
After reset
00000020H
Function
NP
NMI Pending
Indicates that NMI interrupt processing is in progress.
0: No NMI interrupt processing
1: NMI interrupt currently being processed
7.2.4 Noise elimination
NMI pin noise is eliminated with analog delay. The delay time is 60 to 220 ns. The signal input that changes
within the delay time is not internally acknowledged.
The NMI pin is used for releasing the software STOP mode. In the software STOP mode, the internal system
clock is not used for noise elimination because the internal system clock is stopped.
7.2.5 Edge detection function
INTM0 is a register that specifies the valid edge of the non-maskable interrupt (NMI). The NMI valid edge can be
specified to be either the rising edge or the falling edge by the ESN0 bit.
This register can be read/written in 8- or 1-bit units.
INTM0
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
ESN0
Bit Position
0
208
Bit Name
ESN0
Function
Edge Select NMI
Specifies the NMI pin’s valid edge.
0: Falling edge
1: Rising edge
User’s Manual U12688EJ4V0UM00
Address
FFFFF180H
After reset
00H
CHAPTER 7 INTERRUPT/EXCEPTION PROCESSING FUNCTION
7.3
Maskable Interrupts
Maskable interrupt requests can be masked by interrupt control registers. The V850E/MS1 has 47 maskable
interrupt sources.
If two or more maskable interrupt requests are generated at the same time, they are acknowledged according to
the default priority. In addition to the default priority, eight levels of priorities can be specified by using the interrupt
control registers (programmable priority control).
When an interrupt request has been acknowledged, the acknowledgement of other maskable interrupt requests is
disabled and the interrupt disabled (DI) status is set.
When the EI instruction is executed in an interrupt processing routine, the interrupt enabled (EI) status is set which
enables interrupts having a higher priority than the interrupt requests in progress (specified by the interrupt control
register). Note that only interrupts with a higher priority will have this capability; interrupts with the same priority level
cannot be nested.
However, if multiplexed interrupts are executed, the following processing is necessary.
<1> Save EIPC and EIPSW in memory or a general-purpose register before executing the EI instruction.
<2> Execute the DI instruction before executing the RETI instruction, then reset EIPC and EIPSW with the values
saved in <1>.
7.3.1 Operation
If a maskable interrupt occurs by INT input, the CPU performs the following processing, and transfers control to a
handler routine:
(1) Saves the restored PC to EIPC.
(2) Saves the current PSW to EIPSW.
(3) Writes an exception code to the lower halfword of ECR (EICC).
(4) Sets the ID bit of the PSW and clears the EP bit.
(5) Sets the handler address corresponding to each interrupt to the PC, and transfers control.
The processing configuration of a maskable interrupt is shown in Figure 7-5.
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CHAPTER 7 INTERRUPT/EXCEPTION PROCESSING FUNCTION
Figure 7-5. Maskable Interrupt Processing
INT input
INTC acknowledgement
xxIF=1
No
Interrupt request?
Yes
xxMK=0
Yes
Priority higher than
that of interrupt currently being
processed?
No
Is the interrupt
mask released?
No
Yes
Priority higher
than that of other interrupt
request?
No
Yes
Highest default
priority of interrupt requests
with the same priority?
No
Yes
Maskable interrupt request
Interrupt request pending
CPU processing
PSW.NP
1
0
PSW.ID
1
0
EIPC
EIPSW
ECR. EICC
PSW. EP
PSW. ID
PC
restored PC
PSW
exception code
0
1
handler address
Interrupt request pending
Interrupt processing
The INT input masked by the interrupt controllers and the INT input that occurs while another interrupt is being
processed (when PSW.NP = 1 or PSW.ID = 1) are held pending internally by the interrupt controller. When the
interrupts are unmasked, or when PSW.NP = 0 and PSW.ID = 0 are set by the RETI and LDSR instructions, input of
the pending INT starts the new maskable interrupt processing.
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CHAPTER 7 INTERRUPT/EXCEPTION PROCESSING FUNCTION
7.3.2 Restore
To restore from the maskable interrupt processing, the RETI instruction is used.
When the RETI instruction is executed, the CPU performs the following steps, and transfers control to the address
of the restored PC.
(1) Restores the values of the PC and PSW from EIPC and EIPSW because the EP bit of the PSW is 0 and the
NP bit of the PSW is 0.
(2) Transfers control to the address of the restored PC and PSW.
Figure 7-6 illustrates the processing of the RETI instruction.
Figure 7-6. RETI Instruction Processing
RETI instruction
1
PSW.EP
0
1
PSW.NP
0
PC
PSW
EIPC
EIPSW
PC
PSW
FEPC
FEPSW
Restores original processing
Caution When the PSW.EP bit and the PSW.NP bit are changed by the LDSR instruction during
maskable interrupt processing, in order to restore the PC and PSW correctly during recovery
by the RETI instruction, it is necessary to set PSW.EP back to 0 and PSW.NP back to 0 using
the LDSR instruction immediately before the RETI instruction.
Remark
The solid line shows the CPU processing flow.
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CHAPTER 7 INTERRUPT/EXCEPTION PROCESSING FUNCTION
7.3.3 Priorities of maskable interrupts
The V850E/MS1 provides multiple interrupt servicing whereby an interrupt is acknowledged while another interrupt
is being serviced. Multiple interrupts can be controlled by priority levels.
There are two types of priority level control: control based on the default priority levels, and control based on the
programmable priority levels which are specified by the interrupt priority level specification bit (xxPRn) of the interrupt
control register (xxICn). When two or more interrupts having the same priority level specified by the xxPRn bit are
generated at the same time, interrupts are serviced in order depending on the priority level allocated to each interrupt
request type (default priority level) beforehand. For more information, refer to Table 7-1. The programmable priority
control customizes interrupt requests into eight levels by setting the priority level specification flag.
Note that when an interrupt request is acknowledged, the ID flag of the PSW is automatically set to 1. Therefore,
when multiple interrupts are to be used, clear the ID flag to 0 beforehand (for example, by placing the EI instruction
into the interrupt service program) to set the interrupt enable mode.
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Figure 7-7. Example of Processing in Which Another Interrupt Request Is Issued While
Interrupt Is Being Processed (1/2)
Main routine
Processing of a
EI
Interrupt request a
(level 3)
Processing of b
EI
Interrupt
request b
(level 2)
Interrupt request b is acknowledged because the
priority ofb is higher than that of a and interrupts are
enabled.
Processing of c
Interrupt request c
(level 3)
Interrupt request d
(level 2)
Although the priority of interrupt request d is higher
than that of c, d is held pending because interrupts
are disabled.
Processing of d
Processing of e
EI
Interrupt request e
(level 2)
Interrupt request f
(level 3)
Interrupt request f is held pending even if interrupts are
enabled because its priority is lower than that of e.
Processing of f
Processing of g
EI
Interrupt request g
(level 1)
Interrupt request h
(level 1)
Processing of h
Interrupt request h is held pending even if interrupts are
enabled because its priority is the same as that of g.
Remarks 1. a to u in the figure are the names of interrupt requests shown for the sake of explanation.
2. The default priority in the figure indicates the relative priority between two interrupt requests.
Caution The values of the EIPC and EIPSW registers must be saved before executing multiple interrupts.
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CHAPTER 7 INTERRUPT/EXCEPTION PROCESSING FUNCTION
Figure 7-7. Example of Processing in Which Another Interrupt Request Is Issued While
Interrupt Is Being Processed (2/2)
Main routine
Processing of i
EI
Interrupt request i
(level 2)
Processing of k
EI
Interrupt
request j
(level 3)
Interrupt request k
(level 1)
Interrupt request j is held pending because its
priority is lower than that of i. k, which occurs after
j, is acknowledged because it has the higher
priority.
Processing of j
Processing of l
Interrupt request l
(level 2)
Interrupt requests m and n are held pending
because processing of l is performed in the
interrupt disabled status.
Interrupt
request m
(level 3)
Interrupt request n
(level 1)
Processing of n
Pending interrupt requests are acknowledged after
processing of interrupt request l.
At this time, interrupt requests n is acknowledged
first even though m has occurred first because the
priority of n is higher than that of m.
Processing of m
Interrupt request o
(level 3)
Interrupt
request p
(level 2)
Processing of o
Processing of p
EI
Processing of q
EI
Processing of r
EI
Interrupt
request q
EI
Interrupt
(level 1)
request r
(level 0)
If levels 3 to 0 are acknowledged
Processing of s
Interrupt request s
(level 1)
Interrupt
request t
(level 2)
Interrupt request u
(level 2)
Note 1
Pending interrupt requests t and u are
acknowledged after processing of s.
Because the priorities of t and u are the same, u is
acknowledged first because it has the higher
default priority, regardless of the order in which the
interrupt requests were generated.
Note 2
Processing of u
Processing of t
Notes 1. Lower default priority
2. Higher default priority
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CHAPTER 7 INTERRUPT/EXCEPTION PROCESSING FUNCTION
Figure 7-8. Example of Processing Interrupt Requests Simultaneously Generated
Main routine
EI
Interrupt request a (level 2)
Interrupt request b (level 1)
Interrupt request c (level 1)
Default priority
a>b>c
Processing of interrupt request b
Processing of interrupt request c
• Interrupt requests b and c are
acknowledged first according to
their priorities.
• Because the priorities of b and c
are the same, b is acknowledged
first because it has the higher
default priority.
Processing of interrupt request a
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CHAPTER 7 INTERRUPT/EXCEPTION PROCESSING FUNCTION
7.3.4 Interrupt control register (xxICn)
An interrupt control register is assigned to each interrupt request (maskable interrupt) and sets the control
conditions for each maskable interrupt request.
This register can be read/written in 8- or 1-bit units.
xxICn
7
6
5
4
3
2
1
0
xxIFn
xxMKn
0
0
0
xxPRn2
xxPRn1
xxPRn0
Bit Position
Bit Name
Address
FFFFF100H to
FFFFF15CH
After reset
47H
Function
7
xxIFn
Interrupt Request Flag
This is an interrupt request flag.
0: Interrupt request not issued
1: Interrupt request issued
The flag xxlFn is reset automatically by the hardware if an interrupt request is received.
6
xxMKn
Mask Flag
This is an interrupt mask flag.
0: Enables interrupt processing
1: Disables interrupt processing (pending)
xxPRn2 to
xxPRn0
Priority
8 levels of priority order are specified in each interrupt.
2 to 0
xxPRn2
xxPRn1
xxPRn0
Interrupt Priority Specification Bit
0
0
0
Specifies level 0 (highest).
0
0
1
Specifies level 1.
0
1
0
Specifies level 2.
0
1
1
Specifies level 3.
1
0
0
Specifies level 4.
1
0
1
Specifies level 5.
1
1
0
Specifies level 6.
1
1
1
Specifies level 7 (lowest).
Remark xx: Identification name of each peripheral unit (OV, P10 to P15, CM, CS, SE, SR, ST, AD, DMA)
n: Peripheral unit number (None, or 0 to 3, 10 to 15, 40, 41).
Address and bit of each interrupt control register is as follows:
Table 7-2. Interrupt Control Register Addresses and Bits (1/2)
Address
Register
Bit
6
5
4
3
1
0
FFFFF100H
OVIC10
OVIF10
OVMK10
0
0
0
OVPR102
OVPR101
OVPR100
FFFFF102H
OVIC11
OVIC11
OVMK11
0
0
0
OVPR112
OVPR111
OVPR110
FFFFF104H
OVIC12
OVIF12
OVMK12
0
0
0
OVPR122
OVPR121
OVPR120
7
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CHAPTER 7 INTERRUPT/EXCEPTION PROCESSING FUNCTION
Table 7-2. Interrupt Control Register Addresses and Bits (2/2)
Address
Register
Bit
7
6
5
4
3
2
1
0
FFFFF106H
OVIC13
OVIF13
OVMK13
0
0
0
OVPR132
OVPR131
OVPR130
FFFFF108H
OVIC14
OVIF14
OVMK14
0
0
0
OVPR142
OVPR141
OVPR140
FFFFF10AH OVIC15
OVIF15
OVMK15
0
0
0
OVPR152
OVPR151
OVPR150
FFFFF10CH CMIC40
CMIF40
CMMK40
0
0
0
CMPR402
CMPR401
CMPR400
FFFFF10EH CMIC41
CMIF41
CMMK41
0
0
0
CMPR412
CMPR411
CMPR410
FFFFF110H
P10IC0
P10IF0
P10MK0
0
0
0
P10PR02
P10PR01
P10PR00
FFFFF112H
P10IC1
P10IF1
P10MK1
0
0
0
P10PR12
P10PR11
P10PR10
FFFFF114H
P10IC2
P10IF2
P10MK2
0
0
0
P10PR22
P10PR21
P10PR20
FFFFF116H
P10IC3
P10IF3
P10MK3
0
0
0
P10PR32
P10PR31
P10PR30
FFFFF118H
P11IC0
P11IF0
P11MK0
0
0
0
P11PR02
P11PR01
P11PR00
FFFFF11AH P11IC1
P11IF1
P11MK1
0
0
0
P11PR12
P11PR11
P11PR10
FFFFF11CH P11IC2
P11IF2
P11MK2
0
0
0
P11PR22
P11PR21
P11PR20
FFFFF11EH P11IC3
P11IF3
P11MK3
0
0
0
P11PR32
P11PR31
P11PR30
FFFFF120H
P12IC0
P12IF0
P12MK0
0
0
0
P12PR02
P12PR01
P12PR00
FFFFF122H
P12IC1
P12IF1
P12MK1
0
0
0
P12PR12
P12PR11
P12PR10
FFFFF124H
P12IC2
P12IF2
P12MK2
0
0
0
P12PR22
P12PR21
P12PR20
FFFFF126H
P12IC3
P12IF3
P12MK3
0
0
0
P12PR32
P12PR31
P12PR30
FFFFF128H
P13IC0
P13IF0
P13MK0
0
0
0
P13PR02
P13PR01
P13PR00
FFFFF12AH P13IC1
P13IF1
P13MK1
0
0
0
P13PR12
P13PR11
P13PR10
FFFFF12CH P13IC2
P13IF2
P13MK2
0
0
0
P13PR22
P13PR21
P13PR20
FFFFF12EH P13IC3
P13IF3
P13MK3
0
0
0
P13PR32
P13PR31
P13PR30
FFFFF130H
P14IC0
P14IF0
P14MK0
0
0
0
P14PR02
P14PR01
P14PR00
FFFFF132H
P14IC1
P14IF1
P14MK1
0
0
0
P14PR12
P14PR11
P14PR10
FFFFF134H
P14IC2
P14IF2
P14MK2
0
0
0
P14PR22
P14PR21
P14PR20
FFFFF136H
P14IC3
P14IF3
P14MK3
0
0
0
P14PR32
P14PR31
P14PR30
FFFFF138H
P15IC0
P15IF0
P15MK0
0
0
0
P15PR02
P15PR01
P15PR00
FFFFF13AH P15IC1
P15IF1
P15MK1
0
0
0
P15PR12
P15PR11
P15PR10
FFFFF13CH P15IC2
P15IF2
P15MK2
0
0
0
P15PR22
P15PR21
P15PR20
FFFFF13EH P15IC3
P15IF3
P15MK3
0
0
0
P15PR32
P15PR31
P15PR30
FFFFF140H
DMAIC0
DMAIF0
DMAMK0
0
0
0
DMAPR02
DMAPR01
DMAPR00
FFFFF142H
DMAIC1
DMAIF1
DMAMK1
0
0
0
DMAPR12
DMAPR11
DMAPR10
FFFFF144H
DMAIC2
DMAIF2
DMAMK2
0
0
0
DMAPR22
DMAPR21
DMAPR20
FFFFF146H
DMAIC3
DMAIF3
DMAMK3
0
0
0
DMAPR32
DMAPR31
DMAPR30
FFFFF148H
CSIC0
CSIF0
CSMK0
0
0
0
CSPR02
CSPR01
CSPR00
FFFFF14AH CSIC1
CSIF1
CSMK1
0
0
0
CSPR12
CSPR11
CSPR10
FFFFF14CH CSIC2
CSIF2
CSMK2
0
0
0
CSPR22
CSPR21
CSPR20
FFFFF14EH CSIC3
CSIF3
CSMK3
0
0
0
CSPR32
CSPR31
CSPR30
FFFFF150H
SEIC0
SEIF0
SEMK0
0
0
0
SEPR02
SEPR01
SEPR00
FFFFF152H
SRIC0
SRIF0
SRMK0
0
0
0
SRPR02
SRPR01
SRPR00
FFFFF154H
STIC0
STIF0
STMK0
0
0
0
STPR02
STPR01
STPR00
FFFFF156H
SEIC1
SEIF1
SEMK1
0
0
0
SEPR12
SEPR11
SEPR10
FFFFF158H
SRIC1
SRIF1
SRMK1
0
0
0
SRPR12
SRPR11
SRPR10
FFFFF15AH STIC1
STIF1
STMK1
0
0
0
STPR12
STPR11
STPR10
FFFFF15CH ADIC
ADIF
ADMK
0
0
0
ADPR2
ADPR1
ADPR0
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CHAPTER 7 INTERRUPT/EXCEPTION PROCESSING FUNCTION
7.3.5 In-service priority register (ISPR)
This register holds the priority level of the maskable interrupt currently acknowledged. When an interrupt request
is acknowledged, the bit of this register corresponding to the priority level of that interrupt request is set (1) and
remains set while the interrupt is serviced.
When the RETI instruction is executed, the bit corresponding to the interrupt request having the highest priority is
automatically cleared (0) by hardware. However, it is not cleared (0) when execution is returned from non-maskable
interrupt servicing or exception processing.
This register is read-only in 8- or 1-bit units.
ISPR
7
6
5
4
3
2
1
0
ISPR7
ISPR6
ISPR5
ISPR4
ISPR3
ISPR2
ISPR1
ISPR0
Bit Position
Bit Name
7 to 0
ISPR7 to ISPR0
Remark
Address
FFFFF166H
After reset
00H
Function
In-Service Priority Flag
Indicates priority of interrupt currently acknowledged.
0: Interrupt request with priority n not acknowledged
1: Interrupt request with priority n acknowledged
n = 0 to 7 (priority level)
7.3.6 Maskable interrupt status flag (ID)
The ID flag is bit 5 of the PSW.
This controls the maskable interrupt’s operating state, and stores control information on enabling/disabling
acknowledgement of interrupt requests.
8 7 6 5 4 3 2 1 0
31
PSW
0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 NP EP ID SAT CY OV S Z
Bit Position
5
218
Bit Name
ID
After reset
00000020H
Function
Interrupt Disable
Indicates whether maskable interrupt processing is enabled or disabled.
0: Maskable interrupt acknowledgement enabled
1: Maskable interrupt acknowledgement disabled (pending)
It is set to 1 by the DI instruction and reset to 0 by the EI instruction. Its value is
also modified by the RETI instruction or LDSR instruction when referencing the
PSW.
Non-maskable interrupts and exceptions are acknowledged regardless of this
flag. When a maskable interrupt is acknowledged, the ID flag is automatically
set to 1 by hardware.
The interrupt request generated during the acknowledgement disabled period
(ID = 1) is acknowledged when the xxIFn bit of xxICn is set to 1, and the ID flag
is cleared to 0.
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CHAPTER 7 INTERRUPT/EXCEPTION PROCESSING FUNCTION
7.3.7 Noise elimination
Digital noise elimination circuits are added to each of the INTPn0 to INTPn3, TIn, TCLRn and ADTRG pins (n = 10
to 15). Using these circuits, these pins’ input level is sampled each sampling clock cycle (f SMP). If the same level
cannot be detected 3 times consecutively in the sampling results, that input pulse is removed as noise.
The noise elimination time at each pin is shown below.
Pin
Sampling Clock (fSMP)
TCLR10 to TCLR15
φ
TI10 to TI15
φ
INTP100 to INTP103, INTP110 to INTP113,
INTP120 to INTP123, INTP130 to INTP133,
INTP140 to INTP143, INTP150 to INTP152,
INTP153/ADTRG
φ
Remark
Noise Elimination Time
2×φ
to
3×φ
φ: Internal system clock
Figure 7-9. Example of Noise Elimination Timing
Sampling
clock (fSMP)
Input signal
Max. 3 clocksNote 1
Min. 2 clocksNote 2
Internal signal
Rising edge
detection
Falling edge
detection
Notes 1. Pulse width of unrecognizable noise.
2. Pulse width of recognizable signals.
Cautions 1. If the input pulse width is between 2 and 3 sampling clocks, whether the input pulse is
detected as a valid edge or eliminated as a noise is indefinite.
2. To securely detect the level as a pulse, the same level input of 3 sampling clocks or more is
required.
3. When noise is generated in synchronization with a sampling clock, this may not be
recognized as noise. In this case, eliminate the noise by attaching a filter to the input pin.
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CHAPTER 7 INTERRUPT/EXCEPTION PROCESSING FUNCTION
7.3.8 Edge detection function
The valid edge of pins INTPn0 to INTPn3 and ADTRG can be selected by program. The valid edge that can be
selected is one of the following (n = 10 to 15).
• Rising edge
• Falling edge
• Both the rising and falling edges
Edge detected INTPn0 to INTPn3 and ADTRG signals become interrupt factors or capture triggers. The block
Rising edge
detection
Noise
elimination
Input signal
fSMP
φ
Selector
diagram of the edge detectors for these pins is shown below.
Interrupt source
or various types
of trigger
Falling edge
detection
ESn1 ESn0 INTM1 to INTM6 registers
Remark
n = 00 to 03, 10 to 13, 20 to 23, 30 to 33, 40 to 43, 50 to 53
φ:
Internal system clock
fSMP: Sampling clock
Valid edges are specified in external interrupt mode registers 1 to 6 (INTM1 to INTM6).
(1) External interrupt mode registers 1 to 6 (INTM1 to INTM6)
These are registers that specify the valid edge for external interrupt requests (INTP100 to INTP103, INTP110
to INTP113, INTP120 to INTP123, INTP130 to INTP133, INTP140 to INTP143, INTP150 to INTP152,
INTP153/ADTRG), by external pins. The correspondence between each register and the external interrupt
requests which that register controls is shown below.
• INTM1: INTP100 to INTP103
• INTM2: INTP110 to INTP113
• INTM3: INTP120 to INTP123
• INTM4: INTP130 to INTP133
• INTM5: INTP140 to INTP143
• INTM6: INTP150 to INTP152, INTP153/ADTRG
INTP153 is used for both an A/D converter external trigger input (ADTRG) and a pin. Therefore, if the ES531
and ES530 bits of INTM6 are set in the external trigger mode by bits TRG0 to TRG2 of A/D converter mode
register 1 (ADM1), they specify the active edge of the external trigger input (ADTRG).
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The valid edge can be specified independently for each pin, as the rising edge, the falling edge or both the rising
and falling edges.
These registers can be read/written in 8- or 1-bit units.
INTM1
Control pins
INTM2
Control pins
INTM3
Control pins
INTM4
Control pins
INTM5
Control pins
INTM6
Control pins
7
6
5
4
3
2
1
0
ES031
ES030
ES021
ES020
ES011
ES010
ES001
ES000
INTP103
ES131
ES130
INTP113
ES231
ES230
INTP123
ES331
ES330
INTP133
ES431
ES430
INTP143
ES531
ES530
INTP153/ADTRG
Bit Position
Bit Name
7 to 0
ESmn1,
ESmn0
(m = 5 to 0,
n = 3 to 0)
INTP102
ES121
INTP101
ES120
ES111
INTP112
ES221
ES211
INTP122
ES321
ES311
INTP132
ES421
ES101
ES420
ES411
ES210
ES201
ES511
INTP152
FFFFF184H
00H
ES200
FFFFF186H
00H
FFFFF188H
00H
FFFFF18AH
00H
FFFFF18CH
00H
INTP120
ES310
ES301
ES300
INTP130
ES410
ES401
INTP141
ES520
ES100
INTP110
INTP131
INTP142
ES521
ES110
INTP121
ES320
After reset
00H
INTP100
INTP111
ES220
Address
FFFFF182H
ES400
INTP140
ES510
ES501
INTP151
ES500
INTP150
Function
Edge Select
Specifies the valid edge of the INTP1mn pins and ADTRG pin.
ESmn1
ESmn0
Operation
0
0
Falling edge
0
1
Rising edge
1
0
RFU (reserved)
1
1
Both the rising and falling edges
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CHAPTER 7 INTERRUPT/EXCEPTION PROCESSING FUNCTION
7.4
Software Exception
A software exception is generated when the CPU executes the TRAP instruction, and can be always
acknowledged.
7.4.1 Operation
If a software exception occurs, the CPU performs the following processing, and transfers control to the handler
routine:
(1) Saves the restored PC to EIPC.
(2) Saves the current PSW to EIPSW.
(3) Writes an exception code to the lower 16 bits (EICC) of ECR (interrupt source).
(4) Sets the EP and ID bits of the PSW.
(5) Sets the handler address (00000040H or 00000050H) corresponding to the software exception to the PC, and
transfers control.
Figure 7-10 illustrates how a software exception is processed.
Figure 7-10. Software Exception Processing
TRAP instructionNote
CPU processing
EIPC
EIPSW
ECR.EICC
PSW.EP
PSW.ID
PC
restored PC
PSW
exception code
1
1
handler address
Exception processing
Note TRAP Instruction Format: TRAP vector (however the vector is the value 0 to 1FH.)
The handler address is determined by the TRAP instruction’s operand (vector). If the vector is 0 to 0FH, it
becomes 00000040H, and if the vector is 10H to 1FH, it becomes 00000050H.
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7.4.2 Restore
To restore from the software exception processing, the RETI instruction is used.
By executing the RETI instruction, the CPU carries out the following processing and shifts control to the restored
PC’s address.
(1) Loads the restored PC and PSW from EIPC and EIPSW because the EP bit of PSW is 1.
(2) Transfers control to the address of the restored PC and PSW.
Figure 7-11 illustrates the processing of the RETI instruction.
Figure 7-11. RETI Instruction Processing
RETI instruction
1
PSW.EP
0
PSW.NP
1
0
PC
PSW
EIPC
EIPSW
PC
PSW
FEPC
FEPSW
Original processing restored
Caution When the PSW.EP bit and the PSW.NP bit are changed by the LDSR instruction during the
software exception process, in order to restore the PC and PSW correctly during recovery by the
RETI instruction, it is necessary to set PSW.EP back to 1 using the LDSR instruction immediately
before the RETI instruction.
Remark
The solid line shows the CPU processing flow.
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CHAPTER 7 INTERRUPT/EXCEPTION PROCESSING FUNCTION
7.4.3 Exception status flag (EP)
The EP flag is a status flag used to indicate that exception processing is in progress. It is set when an exception
occurs.
31
PSW
8 7 6 5 4 3 2 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 NP EP ID SAT CY OV S Z
Bit Position
6
224
Bit Name
EP
Function
Exception Pending
Shows that exception processing is in progress.
0: Exception processing not in progress.
1: Exception processing in progress.
User’s Manual U12688EJ4V0UM00
After reset
00000020H
CHAPTER 7 INTERRUPT/EXCEPTION PROCESSING FUNCTION
7.5
Exception Trap
The exception trap is an interrupt that is requested when illegal execution of an instruction takes place. In the
V850E/MS1, an illegal op code exception (ILGOP: ILleGal Opcode trap) is considered an exception trap.
An illegal op code exception is generated in the case where the sub op code of the following instruction is an
illegal op code when execution of that instruction is attempted.
7.5.1 Illegal op code definition
The illegal op code has a 32-bit long instruction format: bits 10 to 5 are 111111B and bits 26 to 23 are 0111B to
1111B, with bit 16 defined as an optional instruction code, 0B.
15
11 10
×××××
5 4
1 1 1 1 1 1
0 31
27 26
××××× ×××××
23 22
0 1 1 1
to
1 1 1 1
17 16
××××××
0
×: don’t care
Caution Since it is possible to assign this instruction to an illegal op code in the future, it is
recommended that it not be used.
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CHAPTER 7 INTERRUPT/EXCEPTION PROCESSING FUNCTION
7.5.2 Operation
If an exception trap occurs, the CPU performs the following processing, and transfers control to the handler
routine:
(1) Saves the restored PC to DBPC.
(2) Saves the current PSW to DBPC.
(3) Sets the NP, EP and ID bits of PSW.
(4) Sets the handler address (00000060H) corresponding to the exception trap to the PC, and transfers control.
Figure 7-12 illustrates how the exception trap is processed.
Figure 7-12. Exception Trap Processing
Exception trap (ILGOP) occurs
CPU processing
DBPC
DBPSW
PSW.NP
PSW.EP
PSW.ID
PC
restored PC
PSW
1
1
1
00000060H
Exception processing
7.5.3 Restore
Recovery from an exception trap is not possible. Perform system reset by RESET input.
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7.6
Multiple Interrupt Processing Control
Multiple interrupt processing control is a process by which the interrupt request currently being processed can be
interrupted during processing if there is an interrupt request with a higher priority level, and the higher priority
interrupt request is acknowledged and processed first.
If there is an interrupt request with a lower priority level than the interrupt request currently being processed, that
interrupt request is held pending.
Maskable interrupt multiple processing control is executed when an interrupt has an enable status (ID = 0). Thus,
if multiple interrupts are executed, it is necessary to have an interrupt enable status (ID = 0) even for an interrupt
processing routine.
If a maskable interrupt or a software exception is generated in a maskable interrupt or software exception service
program, it is necessary to save EIPC and EIPSW.
This is accomplished by the following procedure.
(1) To acknowledge maskable interrupts in a service program
Service program of maskable interrupt or exception
...
...
• EIPC saved to memory or register
• EIPSW saved to memory or register
• EI instruction (enables interrupt acknowledgement)
...
←
...
Maskable interrupt acknowledgement
...
...
• DI instruction (disables interrupt acknowledgement)
• Saved value restored to EIPSW
• Saved value restored to EIPC
• RETI instruction
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CHAPTER 7 INTERRUPT/EXCEPTION PROCESSING FUNCTION
(2) To generate an exception in a service program
Service program of maskable interrupt or exception
...
...
• EIPC saved to memory or register
• EIPSW saved to memory or register
...
• TRAP instruction
←
Exception such as TRAP instruction acknowledged.
...
• Saved value restored to EIPSW
• Saved value restored to EIPC
• RETI instruction
The priority order for multiple interrupt processing control has 8 levels, from 0 to 7 for each maskable interrupt
request (0 is the highest priority), which can be set as desired via software. The priority order level is set with
the xxPRn0 to xxPRn2 bits of the interrupt control request register (xxlCn), which is provided for each
maskable interrupt request. At system reset time, an interrupt request is masked by the xxMKn bit and the
priority order is set to level 7 by the xxPRn0 to xxPRn2 bits.
The priority order of maskable interrupts is as follows.
(High)
Level 0 > Level 1 > Level 2 > Level 3 > Level 4 > Level 5 > Level 6 > Level 7
(Low)
Interrupt processing that has been suspended as a result of multiple processing control is resumed after the
interrupt processing of the higher priority has been completed and the RETI instruction has been executed.
A pending interrupt request is acknowledged after the current interrupt processing has been completed and
the RETI instruction has been executed.
Caution In the non-maskable interrupt processing routine (time until the RETI instruction is
executed), maskable interrupts are not acknowledged but are held pending.
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7.7
Interrupt Latency Time
The following table describes the V850E/MS1 interrupt latency time (from interrupt generation to start of interrupt
processing).
Figure 7-13. Pipeline Operation at Interrupt Request Acknowledgement (Outline)
2 system
clocks
4 system
clocks
CLKOUT
Interrupt request
Instruction 1
Instruction 2
IF
ID
EX MEM WB
IF× ID×
Interrupt acknowledgement operation
INT1 INT2 INT3 INT4
IF
Instruction (start instruction of
interrupt processing routine)
Remark
EX
INT1 to INT4: Interrupt acknowledgement processing
IF×:
Invalid instruction fetch
ID×:
Invalid instruction decode
Interrupt Latency Time (Internal System Clock)
Internal interrupt
External interrupt
Minimum
5
7
Maximum
11
13
7.8
ID
Condition
The following cases are exceptions.
• In IDLE/software STOP mode
• External bus is accessed
• Two or more interrupt request non-sample instructions
are executed in succession
• Access to interrupt control register
Periods in Which Interrupt Is Not Acknowledged
An interrupt is acknowledged while an instruction is being executed. However, no interrupt will be acknowledged
between an interrupt non-sample instruction and the next instruction.
The interrupt request non-sampling instructions are as follows.
• EI instruction
• DI instruction
• LDSR reg2, 0x5 instruction (vs. PSW)
• The store instruction for the interrupt control register (xxlCn) and command register (PRCMD)
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[MEMO]
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CHAPTER 8 CLOCK GENERATOR FUNCTIONS
The clock generator (CG) generates and controls the internal system clock (φ) which is supplied to each internal
unit, of which the CPU is the primary unit.
8.1
Features
{ Multiplier function using a PLL (phase locked loop) synthesizer
{ Clock Source
• Oscillation by connecting an oscillator: fXX = φ/5
• External clock: fXX = 2 × φ, φ/5
{ Power save control
• HALT mode
• IDLE mode
• Software STOP mode
• Clock output inhibit function
{ Internal system clock output function
8.2
Configuration
φ
X1
(fXX)
X2
Clock
generator
(CG)
CPU, Internal peripheral I/O
CLKOUT
Time base counter (TBC)
CKSEL
Remark
φ:
Internal system clock frequency
fXX: External resonator or external clock frequency
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8.3
Input Clock Selection
The clock generator is configured from an oscillator and a PLL synthesizer. If, for example an 8 MHz crystal
resonator or ceramic resonator is connected to pins X1 and X2, an internal system clock (φ) of 40 MHz can be
generated.
Also, an external clock can be input directly to the oscillator. In this case, input a clock signal to the X1 pin only
and leave the X2 pin open.
Two types of mode, a PLL mode and a direct mode, are provided as the basic operation modes for the clock
generator. Selection of the operation mode is done by the CKSEL pin. The input of this pin latches at reset time.
CKSEL
Operation Mode
0
PLL mode
1
Direct mode
Caution Fix the input level of the CKSEL pin before use. If it is switched during operation, there is a
possibility of malfunction occurring.
8.3.1 Direct mode
In the direct mode, an external clock with double the internal system clock’s frequency is input.
Since the
oscillator and PLL synthesizer are not operating, a large amount of power can be saved. Mainly, the V850E/MS1 is
used in application systems where it operates at relatively low frequencies.
In consideration of EMI
countermeasures, if the external clock frequency (fXX) is 32 MHz (internal system clock (φ) = 16 MHz) or greater, the
PLL mode is recommended.
Caution In the direct mode, be sure to input an external clock (do not connect an external resonator).
8.3.2 PLL mode
In the PLL mode, by connecting an external resonator or inputting an external clock and multiplying this clock by
the PLL synthesizer, an internal system clock (φ) is generated.
At reset time, an internal system clock (φ) which is 5 times the frequency of the input clock’s frequency (fXX) (5 ×
fXX), is generated.
In the PLL mode, if the clock supply from an external resonator or external clock source stops, the internal system
clock (φ) continues to operate based on the self-propelled frequency of the clock generator’s internal voltage
controlled oscillator (VCO). In this case, φ = approx. 1 MHz (target). However, do not devise an application method
in which you expect to use this self-propelled frequency.
Example Clock used when in the PLL mode
System Clock Frequency (φ) [MHz]
232
External Resonator/External Clock Frequency (fXX) [MHz]
40.000
8.0000
32.768
6.5536
25.000
5.0000
20.000
4.0000
16.384
3.2768
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CHAPTER 8 CLOCK GENERATOR FUNCTIONS
8.3.3 Clock control register (CKC)
When in the PLL mode, this is an 8-bit register which controls the internal system clock frequency (φ), and it can
be written to only by a specific combination of instruction sequences so that it cannot be rewritten easily by mistake
due to program runaway.
This register can be read/written in 8- or 1-bit units.
Caution When in the direct mode, do not change the setting of this register.
CKC
7
6
5
4
3
2
0
0
0
0
0
0
Bit Position
1, 0
Bit Name
CKDIV1,
CKDIV0
1
0
CKDIV1 CKDIV0
Address
FFFFF072H
After reset
00H
Function
Clock Divide
Sets the internal system clock frequency (φ) when in the PLL mode.
Internal System Clock (φ)
CKDIV1
CKDIV0
0
0
5 × fXX
0
1
Setting prohibited
1
0
fXX
1
1
fXX/2
The sequence of setting data to this register is the same as for the power save control register (PSC). However,
the restrictions shown in Remark 2 of 3.4.9 Specific registers do not apply. For details, refer to 8.5.2 Control
registers.
Example Clock generator setting
Operation
Mode
CKSEL Pin
CKC Register
Input Clock
(fXX)
CKDIV1 Bit
CKDIV0 Bit
Internal System
Clock (φ)
Direct mode
High-level input
0
0
16 MHz
8 MHz
PLL mode
Low-level input
0
0
8 MHz
40 MHz
1
0
8 MHz
8 MHz
1
1
8 MHz
4 MHz
Other than above
Setting prohibited
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8.4
PLL Lockup
Lockup time (frequency stabilization time) is the amount of time from immediately after the software STOP mode is
released after the power is turned on, until the phase locks at the proper frequency and becomes stable. The state
until this stabilization occurs is called the unlocked state and the stabilized state is called the locked state.
There is an UNLOCK flag which reflects the PLL’s frequency stabilization state, and a PRERR flag which shows
when a protection error occurs, in the system status register (SYS).
This register can be read/written in 8- or 1-bit units.
SYS
7
6
5
4
3
2
1
0
0
0
0
PRERR
0
0
0
UNLOCK
Bit Position
0
Remark
Bit Name
UNLOCK
Address
FFFFF078H
After reset
0000000×B
Function
Unlock Status Flag
This is an exclusive read flag and shows the PLL’s unlocked state.
As long as the lockup state is maintained, it is kept at 0, and is not initialized
when system reset occurs.
0: Indicates that the PLL is in a locked state.
1: Indicates that the PLL is not locked (in an unlocked state).
For an explanation of the PRERR flag, refer to 3.4.9 (2) System status register (SYS).
If the clock stops, the power fails, or some other factor occurs to cause the unlocked state, in control processing
which depends on software execution speed such as real-time processing, be sure to begin processing after judging
the UNLOCK flag by software immediately after operation starts, and after waiting for the clock to stabilize again.
On the other hand, for static processing such as setting of internal hardware, or initialization of register data and
memory data, it is possible to execute these without waiting for the UNLOCK flag to be reset.
The relationship between the oscillation stabilization time (the time from when the resonator starts to oscillate until
the input waveform stabilizes) when a resonator is used, and the PLL lockup time (the time until the frequency is
stabilized) is shown below.
Oscillation stabilization time < PLL lockup time
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8.5
Power Saving Control
8.5.1 Outline
The V850E/MS1 standby function comprises the following three modes:
(1) HALT mode
In this mode, the clock generator (oscillator and PLL synthesizer) continues to operate, but the CPU’s
operation clock stops. Supply of the clock to the other internal peripheral functions is continued. Through
intermittent operation by combining with the normal operating mode, the system’s total power consumption
can be reduced.
The system is switched to the HALT mode via an exclusive instruction (the HALT instruction).
(2) IDLE mode
In this mode, the clock generator (oscillator and PLL synthesizer) continues to operate, but supply of the
internal system clock is stopped, which causes the system overall to stop.
When releasing the system from the IDLE mode, it is not necessary to secure the oscillation stabilization time
of the oscillator, so it is possible to switch to normal operation at high speed.
The system enters the IDLE mode in accordance with the settings in the PSC register (specific register).
The IDLE mode is positioned midway between the software STOP mode and the HALT mode in relation to
clock stabilization time and current consumption and is used for cases where the low current consumption
mode is used and where it is desired to eliminate the clock stabilization time after it is released.
(3) Software STOP mode
In this mode, the clock generator (oscillator and PLL synthesizer) is stopped and the system overall is
stopped, thus entering an ultra-low power consumption state where only leak current is lost.
It is possible to enter the software STOP mode by setting the PSC register (specific register).
(a) When in the PLL Mode
By setting the register by software, you can enter the software STOP mode. At the same time the
oscillator stops, the PLL synthesizer’s clock output stops. After releasing the software STOP mode, it is
necessary to secure oscillation stabilization time for the oscillator for a period of time until the system
clock stabilizes. Also, depending on the program, PLL lockup time may be required.
(4) Clock output inhibit mode
Internal system clock output from the CLKOUT pin is prohibited.
The operation of the clock generator in normal operation, and in the HALT, IDLE, and software STOP modes is
shown in Table 8-1.
By combining each of the modes and by switching modes according to the required usage, it is possible to realize
an effective low power consumption system.
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CHAPTER 8 CLOCK GENERATOR FUNCTIONS
Table 8-1. Clock Generator Operation by Power Save Control
Clock Source
PLL mode
Oscillation by
resonator
External clock
Direct mode
Power Save Mode
Oscillator
(OSC)
PLL
Synthesizer
Supply of
Clock to
Internal
Peripheral I/O
Supply of
Clock to the
CPU
(During normal operation)
{
{
{
{
HALT mode
{
{
{
×
IDLE mode
{
{
×
×
Software STOP mode
×
×
×
×
(During normal operation)
×
{
{
{
HALT mode
×
{
{
×
IDLE mode
×
{
×
×
Software STOP mode
×
×
×
×
(During normal operation)
×
×
{
{
HALT mode
×
×
{
×
IDLE mode
×
×
×
×
Software STOP mode
×
×
×
×
{: Operating
×:
Stopped
Figure 8-1. Power Save Mode State Transition Diagram
Released by RESET, NMI input
or maskable interrupt request
Normal operating mode
HALT mode setting
Released by RESET, NMI input
Software STOP mode setting
Released by RESET,
NMI input
IDLE mode setting
Software STOP mode
236
IDLE mode
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HALT mode
CHAPTER 8 CLOCK GENERATOR FUNCTIONS
8.5.2 Control registers
(1) Power save control register (PSC)
This is an 8-bit register that controls the power save mode.
This is one of the specific registers and is active only when accessed by a specific sequence during a write
operation. For details, refer to 3.4.9 Specific registers.
This register can be read/written in 8- or 1-bit units.
PSC
7
6
5
4
3
2
1
0
DCLK1
DCLK0
TBCS
CESEL
0
IDLE
STP
0
Bit Position
7, 6
Bit Name
DCLK1,
DCLK0
Address
FFFFF070H
After reset
00H
Function
Disable CLKOUT
This specifies the CLKOUT pin’s operating mode.
DCLK1
DCLK0
Mode
0
0
Normal output mode
0
1
RFU (reserved)
1
0
RFU (reserved)
1
1
Clock output inhibit mode
5
TBCS
Time Base Count Select
Selects the time base counter clock.
8
0: fXX/2
9
1: fXX/2
Details are shown in 8.6.2 Time base counter (TBC).
4
CESEL
Crystal/External Select
Specifies the function of pins X1 and X2.
0: An oscillator is connected to pins X1 and X2.
1: An external clock is connected to pin X1.
If CESEL = 1, the oscillator’s feedback loop is cut and current leakage is prevented
when in the software STOP mode. Also, the oscillation stabilization time count by the
time base counter (TBC) after the software STOP mode is released is not carried out.
2
IDLE
1
STP
Note
Note
IDLE Mode
Specifies the IDLE mode.
It enters the IDLE state if 1 is written.
It is automatically reset (0) if the IDLE mode is released.
STOP Mode
Specifies the software STOP mode.
It enters the STOP state if 1 is written.
It is automatically reset (0) if the software STOP mode is released.
Note If the IDLE bit is set at 1 and the STP bit is also set at 1, the system enters the software STOP mode.
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8.5.3 HALT mode
(1) Setting and operating state
In this mode, the clock generator (oscillator and PLL synthesizer) continues to operate, but the CPU’s
operation clock stops. Supply of the clock to other internal peripheral I/O functions is continued and their
operation continues. By setting the HALT mode during the time when CPU is idle, the system’s total power
consumption can be reduced.
Switching to the HALT mode is accomplished by executing the HALT instruction.
In the HALT mode, program execution stops, but all the contents of all the registers, internal RAM, and ports
are held in the state they were in just before the HALT mode was entered. Also, internal peripheral I/O (other
than the ports) that is not dependent on CPU instruction processing continues operation. The state of each
hardware unit when in the HALT mode is shown in Table 8-2.
Remark
Even after HALT instruction execution, instruction fetch operations continue until the internal
instruction prefetch queue becomes full. When the prefetch queue becomes full, it stops in the
state shown in Table 8-2.
Table 8-2. Operating States When in HALT Mode
Function
Operating State
Clock generator
Operating
Internal system clock
Operating
CPU
Stop
Port
Hold
Internal peripheral I/O (except ports)
Operating
Internal data
All the CPU’s registers, status, data, internal RAM
contents and other internal data, etc. are retained in the
state they were in before entering the HALT mode.
When in
external
expansion
mode
Operating
D0 to D15
A0 to A23
RD, WE, OE, BCYST
LWR, UWR, IORD, IOWR
CS0 to CS7
RAS0 to RAS7
LCAS, UCAS
REFRQ
HLDRQ
HLDAK
WAIT
CLKOUT
238
Clock output (when not in clock output inhibit)
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CHAPTER 8 CLOCK GENERATOR FUNCTIONS
(2) Releasing HALT mode
The HALT mode can be released by NMI pin input, an unmasked maskable interrupt request, or a RESET
signal input.
(a) Release by NMI pin input, maskable interrupt request
The HALT mode is unconditionally released by NMI pin input or an unmasked maskable interrupt request
regardless of the priority. However, if the HALT mode is set in an interrupt processing routine, the
operation will differ as follows:
(i)
If an interrupt request with a priority lower than that of the interrupt request under execution is
generated, the HALT mode is released, but the newly generated interrupt request is not
acknowledged. The new interrupt request will be kept pending.
(ii) If an interrupt request with a priority higher (including NMI request) than the interrupt request under
execution is generated, the HALT mode is released, and the interrupt request is also acknowledged.
Table 8-3. Operations after HALT Mode Is Released by Interrupt Request
Releasing Source
Interrupt Enable (EI) State
NMI request
Branch to handler address
Maskable interrupt
request
Branch to the handler address or
execute the next instruction.
Interrupt Disable (DI) State
Execute the next instruction.
(b) Release by RESET pin input
This operation is the same as a normal reset operation.
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CHAPTER 8 CLOCK GENERATOR FUNCTIONS
8.5.4 IDLE mode
(1) Settings and operating state
In this mode, the clock generator (oscillator and PLL synthesizer) continues to operate, but supply of the
internal system clock is stopped, which causes the system overall to stop.
When releasing the system from the IDLE mode, it is not necessary to secure the oscillation stabilization time
of the oscillator, so it is possible to switch to normal operation at high speed.
The IDLE mode is entered by the setting of the PSC register (specific register), set through a store instruction
(ST/SST instruction) or a bit operation instruction (SET1/CLR1/NOT1 instruction) (refer to 3.4.9 Specific
registers).
In the IDLE mode, program execution is stopped, but all the contents of all the registers, internal RAM, and
ports are held. Operation of the internal peripheral I/O (except the ports) is also stopped.
The state of each hardware unit when in IDLE mode is as shown in Table 8-4.
Table 8-4. Operating States When in IDLE Mode
Function
Operating State
Clock generator
Operating
Internal system clock
Stop
CPU
Stop
Port
Hold
Internal peripheral I/O (except ports)
Stop
Internal data
All the CPU’s registers, status, data, internal RAM contents
and other internal data, etc. are retained in the state they
were in before entering the HALT mode.
When in external
expansion mode
High-impedance
D0 to D15
A0 to A23
RD, WE, OE, BCYST
LWR, UWR, IORD, IOWR
High-level output
CS0 to CS7
RAS0 to RAS7
Operating
LCAS, UCAS
REFRQ
CLKOUT
240
HLDRQ
Input (no sampling)
HLDAK
High-impedance
WAIT
Input (no sampling)
Low-level output
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CHAPTER 8 CLOCK GENERATOR FUNCTIONS
(2) Releasing IDLE mode
The IDLE Mode is released by NMI pin input or RESET pin input.
(a) Release by NMI pin input
This is acknowledged as a NMI request together with a release of the IDLE mode.
However, in cases where setting the system in the IDLE mode is included in the NMI processing routine,
the IDLE mode is released only, and this interrupt is not acknowledged. The interrupt request itself is
held pending.
The interrupt processing that is started when the IDLE mode is released by NMI pin input is treated in the
same way as ordinary NMI interrupt processing in an emergency, etc. (since the NMI interrupt handler’s
address is unique). Consequently, in cases where it is necessary to distinguish between the two in a
program, it is necessary to prepare the software status in advance and set the status before setting the
PSC register using the store instruction or a bit operation instruction. By checking this status in NMI
interrupt processing, it is possible to distinguish it from an ordinary NMI.
(b) Release by RESET pin input
This is the same as an ordinary reset operation.
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8.5.5 Software STOP mode
(1) Settings and operating state
In this mode, the clock generator (oscillator and PLL synthesizer) is stopped. The system overall is stopped,
and it enters an ultra-low power consumption state where only device leakage current is lost.
It is possible to enter the software STOP mode by setting the PSC register (specific register) using a store
instruction (ST/SST instruction) or a bit manipulation instruction (SET1/CLR1/NOT1 instruction) in software
(refer to 3.4.9 Specific registers).
In the case of the PLL mode and oscillator connection mode (CESEL bit of the PSC register = 0), it is
necessary to secure the oscillation stabilization of the oscillator after releasing the software STOP mode.
In the software STOP mode, program execution stops, but all the contents of all the registers, internal RAM,
and ports are held in the state they were in just before entering the software STOP mode. Operation of the
internal peripheral I/O (except the ports) is also stopped.
The status of each hardware unit during the software STOP mode is as shown in Table 8-5.
Caution In the case of the direct mode (CKSEL pin = 1) or external clock connection mode (CESEL bit
of the PSC register = 1), the software STOP mode cannot be used.
Table 8-5. Operating States When in Software STOP Mode
Function
Operating State
Clock generator
Stop
Internal system clock
Stop
CPU
Stop
Port
Note
Hold
Internal peripheral I/O (except ports)
Stop
Note
Internal data
When in external
expansion mode
All the CPU’s registers, status, data, internal RAM contents,
other internal data, etc. are retained in the state they were
in before entering the HALT mode.
High-impedance
D0 to D15
A0 to A23
RD, WE, OE, BCYST
LWR, UWR, IORD, IOWR
High-level output
CS0 to CS7
Operating
RAS0 to RAS7
LCAS, UCAS
REFRQ
HLDRQ
Input (no sampling)
HLDAK
High-impedance
WAIT
Input (no sampling)
CLKOUT
Low-level output
Note If the VDD value is within the operable range.
However, even when it drops below the minimum operable voltage, if the data hold voltage VDDDR is
maintained, the contents of internal RAM only are held.
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(2) Releasing software STOP mode
The software STOP mode is released by NMI pin input or RESET pin input.
Also, when releasing the software STOP mode in the PLL mode and the oscillator connection mode (CESEL
bit of the PSC register = 0), it is necessary to secure oscillation stabilization time for the oscillator.
Note that depending on the program, PLL lockup time may also be necessary. For details, refer to 8.4 PLL
Lockup.
(a) Release by NMI Pin Input
An NMI pin input is acknowledged as an NMI request as well as a release of the software STOP mode.
However, if setting in the software STOP mode is included in an NMI processing routine, the software
STOP mode only is released and the interrupt is not acknowledged. The interrupt request itself is held
pending.
The interrupt processing started when the STOP mode is released by an NMI pin input is treated in the
same way as ordinary NMI interrupt processing in an emergency, etc. (since the NMI interrupt handler
address is unique). Consequently, in cases where it is necessary to distinguish between the two, it is
necessary to prepare the software status in advance and set the status before setting the PSC register
using the store instruction or a bit operation instruction.
By checking this status in NMI interrupt
processing, it is possible to distinguish it from an ordinary NMI.
(b) Release by RESET Pin Input
This is the same as an ordinary reset operation.
8.5.6 Clock output inhibit mode
If the DCLK0 bit and DCLK1 bit of the PSC register are set to 1, the system enters the clock output inhibit mode, in
which clock output from the CLKOUT pin is disabled.
This is most appropriate in single-chip mode 0 and 1 systems, or in systems which access instruction fetches or
data from external expansion devices asynchronously.
In this mode, since the CLKOUT signal output’s operation is completely stopped, much lower power consumption
and suppression of radiation noise from the CLKOUT pin is possible. Also, by combining this mode with the HALT,
IDLE, and software STOP mode, more effective power saving becomes possible (refer to 8.5.2 Control registers).
CLKOUT
(During normal
operation)
CLKOUT
(in the clock
output inhibit
mode)
Remark
L
(Fixed at the low level)
When in flash memory programming mode, the CLKOUT signal is not output regardless of the PSC
register setting.
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CHAPTER 8 CLOCK GENERATOR FUNCTIONS
8.6
Securing Oscillation Stabilization Time
8.6.1 Specifying securing of oscillation stabilization time
There are 2 methods for specifying securing of time for stabilizing the oscillator in the stop mode after releasing
the software STOP mode.
(1) If securing time by the internal time base counter (NMI pin input)
If the active edge of the NMI pin is input, the software STOP mode is released. When the inactive edge is
input to the pin, the time base counter (TBC) starts counting, and at that count time, the time until the clock
output from the oscillator stabilizes is secured.
Oscillation stabilization time ≅ (Active level width after NMI input active edge detection) + (TBC count time)
After the proper time, start internal system clock output and branch to the NMI interrupt handler address.
Software STOP mode setting
Oscillation waveform
Internal system clock
CLKOUT (output)
STOP state
NMI (input)
Oscillator stopped
Time base counter
current time
The NMI pin should normally be set at the inactive level (for example, so that it changes to high level when
the active edge is specified to be falling).
Furthermore, if an operation is executed which sets the system in the STOP mode for a time until an interrupt
is received from the CPU from the NMI active edge input timing, the software STOP mode is quickly released.
In the case of the PLL mode and the resonator connection mode (CESEL bit of PSC register = 0), program
execution starts after the oscillation stabilization time is secured by the time base counter after input of the
NMI pin’s inactive edge.
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CHAPTER 8 CLOCK GENERATOR FUNCTIONS
(2) If securing time by the signal level width (RESET pin input)
By inputting the falling edge to the RESET pin, the software STOP mode is released.
At the signal low level width input to the pin, enough time is secured until the clock output from the oscillator
stabilizes.
After inputting the rising edge to the RESET pin, supply of the internal system clock begins and the system
branches to the handler address that was set at system reset time.
Software STOP mode setting
Oscillation waveform
Internal system clock
Undefined
CLKOUT (output)
Undefined
STOP state
RESET (input)
Internal system
reset signal
Oscillator stopped
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time is secured by RESET
245
CHAPTER 8 CLOCK GENERATOR FUNCTIONS
8.6.2 Time base counter (TBC)
The time base counter (TBC) is used to secure the oscillation stabilization time of the oscillator when the software
STOP mode is released.
• Resonator connection time (PLL Mode, and CESEL bit of the PSC Register = 0)
After releasing the software STOP mode, the oscillation stabilization time is counted by the TBC and after
counting is ended, program execution begins.
The TBC count clock is selected by the TBCS bit in the PSC register, and it is possible to set the following count
times (refer to 8.5.2 (1) Power save control register (PSC)).
Table 8-6. Example of Count Time (φ = 5 × fXX)
TBCS Bit
0
1
Count Clock
Count Time
fXX = 3.2768 MHz
fXX = 5.0000 MHz
fXX = 6.5536 MHz
fXX = 8.0000 MHz
φ = 16.384 MHz
φ = 25.000 MHz
φ = 32.768 MHz
φ = 40.000 MHz
8
20.0 ms
13.1 ms
10.0 ms
8.1 ms
9
40.0 ms
26.2 ms
20.0 ms
16.3 ms
fXX/2
fXX/2
fXX: External resonator frequency
φ:
246
Internal system clock frequency
User’s Manual U12688EJ4V0UM00
CHAPTER 9 TIMER/COUNTER FUNCTION (REAL-TIME PULSE UNIT)
9.1
Features
{ Measures the pulse interval and frequency and outputs a programmable pulse.
• 16-bit measurements are possible.
• Pulse multiple states can be generated (interval pulse, one shot pulse)
{ Timer 1
• 16-bit timer/event counter
• Count clock sources: 2 types (internal system clock division selection, external pulse input)
• Capture/compare common registers: 24
• Count clear pins: TCLR10 to TCLR15
• Interrupt sources: 30 types
• External pulse outputs: 12
{ Timer 4
• 16-bit interval timer
• The count clock is selected from the internal system clock divisions.
• Compare registers: 2
• Interrupt sources: 2 types
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CHAPTER 9 TIMER/COUNTER FUNCTION (REAL-TIME PULSE UNIT)
9.2
Basic Configuration
The basic configuration is shown below.
Table 9-1. RPU Configuration List
Timer
Timer 1
Timer 4
Remark
Count Clock
φ/2
φ/4
φ/8
φ/16
φ/32
φ/64
TI1n Pin Input
(n = 0 to 5)
φ/32
φ/64
φ/128
φ/256
φ:
Register
Read/Write
Interrupt Signals
Generated
Timer
Output S/R
Other Functions
TM10
Read
INTOV10
CC100
Read/write
INTCC100
INTP100
TO100 (S)
CC101
Read/write
INTCC101
INTP101
TO100 (R)
CC102
Read/write
INTCC102
INTP102
TO101 (S)
CC103
Read/write
INTCC103
INTP103
TO101 (R)
TM11
Read
INTOV11
CC110
Read/write
INTCC110
INTP110
TO110 (S)
A/D conversion
start trigger
CC111
Read/write
INTCC111
INTP111
TO110 (R)
A/D conversion
start trigger
CC112
Read/write
INTCC112
INTP112
TO111 (S)
A/D conversion
start trigger
CC113
Read/write
INTCC113
INTP113
TO111 (R)
A/D conversion
start trigger
TM12
Read
INTOV12
CC120
Read/write
INTCC120
INTP120
TO120 (S)
CC121
Read/write
INTCC121
INTP121
TO120 (R)
CC122
Read/write
INTCC122
INTP122
TO121 (S)
CC123
Read/write
INTCC123
INTP123
TO121 (R)
TM13
Read
INTOV13
CC130
Read/write
INTCC130
INTP130
TO130 (S)
CC131
Read/write
INTCC131
INTP131
TO130 (R)
CC132
Read/write
INTCC132
INTP132
TO131 (S)
CC133
Read/write
INTCC133
INTP133
TO131 (R)
TM14
Read
INTOV14
CC140
Read/write
INTCC140
INTP140
TO140 (S)
CC141
Read/write
INTCC141
INTP141
TO140 (R)
CC142
Read/write
INTCC142
INTP142
TO141 (S)
CC143
Read/write
INTCC143
INTP143
TO141 (R)
TM15
Read
INTOV15
CC150
Read/write
INTCC150
INTP150
TO150 (S)
CC151
Read/write
INTCC151
INTP151
TO150 (R)
CC152
Read/write
INTCC152
INTP152
TO151 (S)
CC153
Read/write
INTCC153
INTP153
TO151 (R)
TM40
Read
CM40
Read/write
TM41
Read
CM41
Read/write
External clear
External clear
External clear
External clear
External clear
External clear
INTCM40
INTCM41
Internal system clock
S/R: Set/reset
248
Capture
Trigger
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CHAPTER 9 TIMER/COUNTER FUNCTION (REAL-TIME PULSE UNIT)
(1) Timer 1 (16-bit timer/event counter)
Internal system
clock
(φ )
TM10
TCLR10
Edge detection
PRS100, ETI10
PRS101
1/8
1/16
INTP100
INTP101
INTP102
Noise
elimination
Edge
detection
(INTM1)
INTP103
Clear &
start
Note 2
Note
1
OVF10
INTOV10
TM10 (16-bit)
ALV101 ALV100
CC100
CC101
S
Q
Note3
Q
R
CC102
S
Q
Note3
Q
R
CC103
Selector
1/4
Clear & count
control
Selector
1/2
1/4
Selector
Edge detection
φm
Selector
TI10
Selector
PRM
101
TO100
TO101
IMS100 IMS101 IMS102 IMS103
Selector
Selector
Selector
Selector
TM11
INTOV11
TO110
TO111
INTP110/INTCC110
INTP111/INTCC111
INTP112/INTCC112
INTP113/INTCC113
...
TCLR11
TI11
INTP110
INTP111
INTP112
INTP113
INTP100/INTCC100
INTP101/INTCC101
INTP102/INTCC102
INTP103/INTCC103
TCLR15
TI15
INTP150
INTP151
INTP152
INTP153
TM15
INTOV15
TO150
TO151
INTP150/INTCC150
INTP151/INTCC151
INTP152/INTCC152
INTP153/INTCC153
Notes 1. Internal count clock
2. External count clock
3. Reset priority
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CHAPTER 9 TIMER/COUNTER FUNCTION (REAL-TIME PULSE UNIT)
(2) Timer 4 (16-bit interval timer)
Internal system
clock
(φ )
TM40
1/4
1/8
PRS400
1/16
φm
1/32
Selector
1/2
Selector
PRM400, PRM401
Internal count
clock
TM40 (16-bit)
Clear &
start
CM40
INTCM40
TM41
INTCM41
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CHAPTER 9 TIMER/COUNTER FUNCTION (REAL-TIME PULSE UNIT)
9.2.1 Timer 1
(1) Timers 10 to 15 (TM10 to TM15)
TM1n functions as a 16-bit free running timer or as an event counter for an external signal. Mainly, besides
period measurement and frequency measurement, it can be used as a pulse output (n = 0 to 5). TM1n is
read-only, in 16-bit units.
15
0
TM10
TM11
TM12
TM13
TM14
TM15
Address
FFFFF250H
After reset
0000H
FFFFF270H
0000H
FFFFF290H
0000H
FFFFF2B0H
0000H
FFFFF2D0H
0000H
FFFFF2F0H
0000H
TM1n carries out count-up operations of the internal count clock or of an external count clock. Starting and
stopping of the timer is controlled by the CE1n bit of timer control register 1n (TMC1n).
Selection of internal or external count clocks is performed by the TMC1n register.
(a) Selection of an external count clock
TM1n operates as an event counter. The active edge is specified by the timer unit mode register 1n
(TUM1n) and through input of pin TI1n, TM1n is counted up.
(b) Selection of an internal count clock
TM1n operates as a free running timer. The counter clock can be selected from among the divisions
performed by the prescaler, φ/2, φ/4, φ/8, φ/16, φ/32, or φ/64, through the TMC1n register.
If the timer overflows, an overflow interrupt can be generated. Also, the timer can be stopped after an
overflow through the TUM1n register specification.
The timer can also be cleared and started using the external input TCLR1n. When this is done, the prescaler is cleared at the same time, so the time from TCLR1n input to timer count-up is constant
corresponding to the prescaler's dividing ratio.
The operation setting is carried out by the TUM1n
register.
Caution The count clock cannot be changed during timer operation.
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CHAPTER 9 TIMER/COUNTER FUNCTION (REAL-TIME PULSE UNIT)
(2) Capture/compare registers 1n0 to 1n3 (CC1n0 to CC1n3) (n = 0 to 5)
The capture/compare registers are 16-bit registers to which TM1n is connected. They can be used as either
a capture register or a compare register in accordance with the specification in timer unit mode register 1n
(TUM1n). These registers can be read/written in 16-bit units.
15
0
CC100 to
CC103
Address
FFFFF252H to
FFFFF258H
After reset
Undefined
CC110 to
CC113
FFFFF272H to
FFFFF278H
Undefined
CC120 to
CC123
FFFFF292H to
FFFFF298H
Undefined
CC130 to
CC133
FFFFF2B2H to
FFFFF2B8H
Undefined
CC140 to
CC143
FFFFF2D2H to
FFFFF2D8H
Undefined
CC150 to
CC153
FFFFF2F2H to
FFFFF2F8H
Undefined
(a) Set as a capture register
If set as a capture register, these registers detect the active edge of the corresponding signals in external
interrupts INTP1n0 to INTP1n3 as a capture trigger. Timer 1n is synchronized with the capture trigger
and latches a count value (capture operation). The capture operation is performed out of synch with the
count clock.
The latched value is held in the capture register until the next capture operation is
performed.
If the capture (latch) timing to the capture register and writing to the register in response to an instruction
are in contention, the latter has the priority and the capture operation is disregarded.
Also, specification of the active edge of external interrupts (rising, falling, or both edges) can be selected
by the external interrupt mode register (INTM1 to INTM6).
When there is a specification in the capture register, an interrupt is issued when the active edge of
INTP1n0 to INTP1n3 signals is detected. When this is done, an interrupt cannot be issued by INTCC1n0
to INTCC1n3, which are the compare register’s matching signals.
(b) Set as a compare register
If set as a compare register, these registers perform a comparison of the timer and register values at
each count clock of the timer, and issue an interrupt if the values match.
The compare registers are provided with a set/reset output function. In synch with matching signal
generation, the corresponding timer output (TO1n0, TO1n1) is set or reset.
The interrupt source differs with the function of the register.
If specified a compare register, these registers can be made interrupt signals by selecting, through the
specification of the TUM1n register, active edge detection of either the INTCC1n0 to INTCC1n3 signals,
which are the matching signals, or the INTP1n0 to INTP1n3 signals.
Furthermore, if the INTP1n0 to INTP1n3 signals are selected, acknowledgement of an external interrupt
request and timer output by the compare register’s set/reset output function can be carried out in parallel.
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CHAPTER 9 TIMER/COUNTER FUNCTION (REAL-TIME PULSE UNIT)
9.2.2 Timer 4
(1) Timers 40, 41 (TM40, TM41)
TM4n is a 16-bit timer. It can mainly be used as an interval timer for software (n = 0, 1).
TM4n is read-only in 16-bit units.
15
0
TM40
Address
FFFFF350H
After reset
0000H
TM41
FFFFF354H
0000H
Starting and stopping of TM4n is controlled by the CE4n bit of timer control register 4n (TMC4n).
The count clock can be selected from φ/32, φ/64, φ/128, or φ/256 divisions of the prescaler via register
TMC4n.
Caution Since the timer is cleared at the next count clock after a compare match is issued, when the
division ratio is large, even if the timer's value is read immediately after the match interrupt
is issued, the timer's value may not be 0.
Also, the count clock cannot be changed during timer operation.
(2) Compare registers 40, 41 (CM40, CM41)
CM4n is a 16-bit register and is connected to TM4n. This register can be read/written in 16-bit units.
15
0
CM40
Address
FFFFF352H
After reset
Undefined
CM41
FFFFF356H
Undefined
This register compares TM4n and CM4n each TM4n count clock and if they match, issues an interrupt
(INTCM4n). TM4n is cleared in synchronization with this match.
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CHAPTER 9 TIMER/COUNTER FUNCTION (REAL-TIME PULSE UNIT)
9.3
Control Registers
(1) Timer unit mode registers 10 to 15 (TUM10 to TUM15)
The TUM1n register is a register which controls the operation of timer 1 and specifies the capture/compare
register operation mode (n = 0 to 5).
These registers can be read/written in 16-bit units.
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
TUM10
0
0
ECLR TES TES CES CES CMS CMS CMS CMS IMS IMS IMS IMS
OST0
10 101 100 101 100 103 102 101 100 103 102 101 100
TUM11
0
0
OST1
ECLR TES TES CES CES CMS CMS CMS CMS IMS IMS IMS IMS
11 111 110 111 110 113 112 111 110 113 112 111 110
FFFFF260H
0000H
TUM12
0
0
OST2
ECLR TES TES CES CES CMS CMS CMS CMS IMS IMS IMS IMS
12 121 120 121 120 123 122 121 120 123 122 121 120
FFFFF280H
0000H
TUM13
0
0
OST3
ECLR TES TES CES CES CMS CMS CMS CMS IMS IMS IMS IMS
13 131 130 131 130 133 132 131 130 133 132 131 130
FFFFF2A0H
0000H
TUM14
0
0
OST4
ECLR TES TES CES CES CMS CMS CMS CMS IMS IMS IMS IMS
14 141 140 141 140 143 142 141 140 143 142 141 140
FFFFF2C0H
0000H
TUM15
0
0
OST5
ECLR TES TES CES CES CMS CMS CMS CMS IMS IMS IMS IMS
15 151 150 151 150 153 152 151 150 153 152 151 150
FFFFF2E0H
0000H
Bit Position
13
Bit Name
OSTn
Address
FFFFF240H
After reset
0000H
Function
Overflow Stop
Specifies the timer’s operation after overflow. This flag is valid only in TM1n.
0: Timer continues to count up after timer overflow.
1: Timer holds 0000H and is in the stopped state after timer overflow.
When this happens, the CE1 bit in the TMC1n register remains at 1.
Counting up resumes with the next operation.
When ECLR1n = 0: 1 write operation to the CE1n bit.
When ECLR1n = 1: Trigger input to the timer clear pin (TCLR1n).
12
ECLR1n
External Input Timer Clear
Clearing of the timer is enabled by the TM1n external clear input (TCLR1n).
0: Timer is not cleared by an external input.
1: TM1n is cleared by an external input.
Counting up starts after clearing.
Remark
254
n = 0 to 5
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CHAPTER 9 TIMER/COUNTER FUNCTION (REAL-TIME PULSE UNIT)
Bit Position
11, 10
9, 8
Bit Name
TES1n1,
TES1n0
CES1n1,
CES1n0
7 to 4
CMS1nm
(m = 3 to 0)
Function
TI1n Edge Select
Specifies the active edge of the external clock input (TI1n).
TES1n1
TES1n0
Active Edge
0
0
Falling edge
0
1
Rising edge
1
0
RFU (reserved)
1
1
Both the rising and falling edges
TCLR1n Edge Select
Specifies the active edge of the external clear input (TCLR1n).
CES1n1
CES1n0
Active Edge
0
0
Falling edge
0
1
Rising edge
1
0
RFU (reserved)
1
1
Both the rising and falling edges
Capture/Compare Mode Select
Selects the capture/compare register’s (CC1nm) operation mode.
0: Operates as a capture register. However, the capture operation when it is
specified as a capture register is performed only when the CE1n bit of the TMC1n
register = 1.
1: Operates as a compare register.
3 to 0
IMS1nm
(m = 3 to 0)
Interrupt Mode Select
Selects either INTP1nm or INTCC1nm as the interrupt source.
0: Makes the compare register’s matching signal INTCC1nm the interrupt request
signal.
1: It makes the external input signal INTP1nm the interrupt request signal.
Remark
n = 0 to 5
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CHAPTER 9 TIMER/COUNTER FUNCTION (REAL-TIME PULSE UNIT)
Remarks 1. If the A/D converter is set in the timer trigger mode, the compare register’s match interrupt becomes
the A/D conversion start trigger, starting the conversion operation.
When this happens, the
compare register’s match interrupt functions as a compare register match interrupt to the CPU. In
order for a compare register match interrupt not to be issued to the CPU, disable interrupts with the
interrupt mask bits (P11MK0 to P11MK3) of the interrupt control register (P11IC0 to P11IC3).
2. If the A/D converter is set in the external trigger mode, the external trigger input becomes the A/D
converter starting trigger, starting the conversion operation.
When this happens, the external
trigger input also functions as Timer 1’s capture trigger and as an external interrupt. In order for it
not to issue capture triggers or external interrupts, set Timer 1 in the compare register and disable
interrupts with the interrupt control register’s interrupt mask bit.
If Timer 1 is not set in the compare register, and if interrupts are not disabled in the interrupt control
register, the following will happen.
(a) If the TUM15 register’s interrupt mask bit (IMS153) is 0
It also functions as the compare register’s match interrupt with respect to the CPU.
(b) If the TUM15 register’s interrupt mask bit (IMS153) is 1
The A/D converter’s external trigger input also functions as an external interrupt to the CPU.
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CHAPTER 9 TIMER/COUNTER FUNCTION (REAL-TIME PULSE UNIT)
(2) Timer control registers 10 to 15 (TMC10 to TMC15)
TMC10 to 15 control the respective operations of TM10 to TM15.
These registers can be read/written in 8- or 1-bit units.
7
6
5
4
TMC10
CE10
0
0
ETI10
PRS101 PRS100 PRM101
0
TMC11
CE11
0
0
ETI11
PRS111 PRS110 PRM111
0
TMC12
CE12
0
0
ETI12
PRS121 PRS120 PRM121
0
TMC13
CE13
0
0
ETI13
PRS131 PRS130 PRM131
0
TMC14
CE14
0
0
ETI14
PRS141 PRS140 PRM141
0
TMC15
CE15
0
0
ETI15
PRS151 PRS150 PRM151
0
Bit Position
7
3
2
1
Bit Name
CE1n
0
Address
FFFFF242H
After reset
00H
FFFFF262H
00H
FFFFF282H
00H
FFFFF2A2H
00H
FFFFF2C2H
00H
FFFFF2E2H
00H
Function
Count Enable
Controls timer operation.
0: The timer is stopped in the 0000H state and does not operate.
1: The timer performs a count operation. However, when the ECLR1n bit of
the TUM1n register is 1, the timer does not start counting up until there is a
TCLR1n input.
When the ECLR1n bit is 0, the operation of setting (1) in the CE1n bit becomes
the count start trigger. Thus, after the CE1n bit is set (1) when the ECLR1n bit =
1, the timer will not start even if the ECLR1n bit is made 0.
4
ETI1n
External TI1n Input
Specifies whether switching of the count clock is external or internal.
0: Specifies the φ system (internal).
1: Specifies TI1n (external).
Caution Do not change the count clock during timer operation.
Remark
n = 0 to 5
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CHAPTER 9 TIMER/COUNTER FUNCTION (REAL-TIME PULSE UNIT)
Bit Position
3, 2
1
Bit Name
PRS1n1,
PRS1n0
PRM1n1
Function
Prescaler Clock Select
Selects the internal count clock (φm is the intermediate clock).
PRS1n1
PRS1n0
Internal Count Clock
0
0
φm
0
1
φm/4
1
0
φm/8
1
1
φm/16
Prescaler Clock Mode
Selects the intermediate count clock (φm). (φ is the internal system clock).
0: φ/2
1: φ/4
Caution Do not change the count clock during timer operation.
Remark
258
n = 0 to 5
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CHAPTER 9 TIMER/COUNTER FUNCTION (REAL-TIME PULSE UNIT)
(3) Timer control registers 40, 41 (TMC40, TMC41)
TMC40 and TMC41 control the operation of TM40 and TM41, respectively.
These registers can be read/written in 8- or 1-bit units.
7
6
5
4
3
TMC40
CE40
0
0
0
0
PRS400 PRM401 PRM400
TMC41
CE41
0
0
0
0
PRS410 PRM411 PRM410
Bit Position
2
Bit Name
1
0
Address
FFFFF342H
After reset
00H
FFFFF346H
00H
Function
7
CE4n
Count Enable
Controls timer operations.
0: The timer is stopped in the 0000H state and does not operate.
1: The timer performs a count operation.
2
PRS4n0
Prescaler Clock Select
Selects the internal count clock (φm is the intermediate clock).
0: φm/16
1: φm/32
1, 0
PRM4n1,
PRM4n0
Prescaler Clock Mode
Selects the intermediate count clock ((φm). (φ is the internal system clock).
φm
PRM4n1
PRM4n0
0
0
φ/2
0
1
φ/4
1
0
φ/8
1
1
RFU (reserved)
Caution Do not change the count clock during timer operation.
Remark
n = 0, 1
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CHAPTER 9 TIMER/COUNTER FUNCTION (REAL-TIME PULSE UNIT)
(4) Timer output control registers 10 to 15 (TOC10 to TOC15)
The TOC1n register controls the timer output from the TO1n0 and TO1n1 pins (n = 0 to 5).
These registers can be read/written in 8- or 1-bit units.
6
7
5
4
3
2
1
0
TOC10
ENTO101 ALV101 ENTO100 ALV100
0
0
0
0
Address
FFFFF244H
After reset
00H
TOC11
ENTO111 ALV111 ENTO110 ALV110
0
0
0
0
FFFFF264H
00H
TOC12
ENTO121 ALV121 ENTO120 ALV120
0
0
0
0
FFFFF284H
00H
TOC13
ENTO131 ALV131 ENTO130 ALV130
0
0
0
0
FFFFF2A4H
00H
TOC14
ENTO141 ALV141 ENTO140 ALV140
0
0
0
0
FFFFF2C4H
00H
TOC15
ENTO151 ALV151 ENTO150 ALV150
0
0
0
0
FFFFF2E4H
00H
Bit Position
7, 5
Bit Name
ENTO1n1,
ENTO1n0
Function
Enable TO pin
Enables output of each corresponding timer (TO1n0, TO1n1).
0: Timer output is disabled. The reverse phase level (inactive level) of the
ALV1n0 and ALV1n1 bits is output from the TO1n0 and TO1n1 pins. Even
if a match signal is generated by the corresponding compare register, the
level of the TO1n0 and TO1n1 pins does not change.
1: Timer output is enabled. If a match signal is generated from the
corresponding compare register, the timer’s output changes. From the
timer that timer output is enabled until match signals are first generated,
the reverse phase level (inactive level) of the ALV1n0 and ALV1n1 bits is
output.
6, 4
ALV1n1, ALV1n0
Active Level TO pin
Specifies the timer output’s active level.
0: The active level is the low level.
1: The active level is the high level.
Remarks 1. The TO1n0 and TO1n1 output flip-flop is reset priority.
2. n = 0 to 5
Caution The TO1n0 and TO1n1 output is not changed by an external interrupt signal (INTP1n0 to
INTP1n3).
When the TO1n0 and TO1n1 signals are used, specify the capture/compare
register as the compare register (CMS1n0 to CMS1n3 bit of the TUM1n register = 1).
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CHAPTER 9 TIMER/COUNTER FUNCTION (REAL-TIME PULSE UNIT)
(5) External interrupt mode registers 1 to 6 (INTM1 to INTM6)
If CC1n0 to CC1n3 of TM1n are used as a capture register, the active edge of the external interrupt INTP1n0
to
INTP1n3
signals
is
detected
as
a
capture
trigger
(for
details,
refer
to
CHAPTER
7
INTERRUPT/EXCEPTION PROCESSING FUNCTION) (n = 0 to 5).
(6) Timer overflow status register (TOVS)
This interrupts overflow flags from TM10 to TM15, TM40, and TM41.
The register can be read/written in 8- or 1-bit units.
By setting and resetting the TOVS register through software, polling of overflow occurrences can be
accomplished.
TOVS
7
6
5
4
3
2
1
0
OVF41
OVF40
OVF15
OVF14
OVF13
OVF12
OVF11
OVF10
Bit Position
Bit Name
7 to 0
OVF41, OVF40,
OVF15 to OVF10
Address
FFFFF230H
After reset
00H
Function
Overflow Flag
This is the overflow flag for TM41, TM40 and TM1n.
0: No overflow is generated.
1: Overflow is generated.
Caution
Interrupt requests (INTOV1n) for the interrupt controller are
generated in synch with an overflow from TM1n, but because
interrupt operations and the TOVS register are independent, the
overflow flag (OVF1n) from TM1n can be operated by software
just like other overflow flags.
At this time, the interrupt request flag (OVF1n) corresponding to
INTOV1n is not affected.
During CPU access interval, transfers to the TOVS register cannot be made.
Therefore, even if an overflow is generated during a readout from the TOVS
register, the flag’s value does not change and it is reflected in the next read
operation.
Remark
n = 0 to 5
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CHAPTER 9 TIMER/COUNTER FUNCTION (REAL-TIME PULSE UNIT)
9.4
Timer 1 Operation
9.4.1 Count operation
Timer 1 functions as a 16-bit free-running timer or an event counter for an external signal.
Whether the timer operates as a free-running timer or event counter is specified by timer control register 1n
(TMC1n) (n = 0 to 5).
When it is used as a free-running timer, and when the count values of TM1n match with the value of any of the
CC1n0 to CC1n3 registers, an interrupt signal is generated, and timer output signal TO1n0 and TO1n1 can be
set/reset. In addition, a capture operation that holds the current count value of TM1n and loads it into one of the four
registers CC1n0 to CC1n3, is performed in synchronization with the valid edge detected from the corresponding
external interrupt request pin as an external trigger. The captured value is retained until the next capture trigger is
generated.
Figure 9-1. Basic Operation of Timer 1
Count clock
TM1n
0000H 0001H 0002H 0003H
∆
Count starts
CE1n←1
Remark
262
FBFEH FBFFH
∆
Count disabled
CE1n←0
n = 0 to 5
User’s Manual U12688EJ4V0UM00
0000H
0001H 0002H 0003H
∆
Count starts
CE1n←1
CHAPTER 9 TIMER/COUNTER FUNCTION (REAL-TIME PULSE UNIT)
9.4.2 Count clock selection
The count clock input to Timer 1 is either internal or external, and can be selected by the ETI1n bit in the TMC1n
register (n = 0 to 5).
Caution Do not change the count clock during timer operation.
(1) Internal count clock (ETI1n bit = 0)
An internal count clock can be selected from among 6 possible clock rates, φ/2, φ/4, φ/8, φ/16, φ/32, or φ/64,
by the setting of the PRS1n1, PRS1n0, and PRM1n1 bits of the TMC1n register.
PRS1n1
PRS1n0
PRM1n1
0
0
0
φ/2
0
0
1
φ/4
0
1
0
φ/8
0
1
1
φ/16
1
0
0
φ/16
1
0
1
φ/32
1
1
0
φ/32
1
1
1
φ/64
Remark
Internal Count Clock
n = 0 to 5
(2) External count clock (ETI1n bit = 1)
This counts the signals input to the TI1n pin. At this time, Timer 1 can be operated as an event counter.
The TI1n active edge can be set by the TES1n1 and TES1n0 bits of the TUM1n register.
TES1n1
TES1n0
0
0
Rising edge
0
1
Falling edge
1
0
RFU (reserved)
1
1
Both the rising and falling edges
Remark
Active Edge
n = 0 to 5
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CHAPTER 9 TIMER/COUNTER FUNCTION (REAL-TIME PULSE UNIT)
9.4.3 Overflow
When the TM1n register counts the count clock to FFFFH and overflow occurs as a result, a flag is set in the
OVF1n bit of the TOVS register and an overflow interrupt (INTOV1n) is generated (n = 0 to 5).
Also, by setting the OSTn bit (1) in the TUM1n register, the timer can be stopped after overflow. If the timer is
stopped due to an overflow, the count operation does not resume until the CE1n bit in the TMC1n register is set (1).
Note that even if the CE1n bit is set (1) during a count operation, it has no influence on operation.
Figure 9-2. Operation after Overflow (If ECLR1n = 0 and OSTn = 1)
Overflow
Overflow
FFFFH
FFFFH
Count
start
TM1n
0
OSTn
1
CE1n
1
CE1n
INTOV1n
Remark
264
n = 0 to 5
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CHAPTER 9 TIMER/COUNTER FUNCTION (REAL-TIME PULSE UNIT)
9.4.4 Clearing/starting timer by TCLR1n signal input
Timer 1 ordinarily starts a counting operation when the CE1n bit in the TMC1n register is set (1), but TM1n can be
cleared and a count operation started by input of the TCLR1n signal (n = 0 to 5).
If the ECLR1n bit of the TUM1n register is set to 1, and the OSTn bit is set to 0, if the active edge is input to the
TCLR1n signal after the CE1n bit is set (1), the counting operation starts. Also, if the active edge is input to the
TCLR1n signal during operation, the TM1n’s value is cleared and the count operation resumes (refer to Figure 9-3).
If the ECLR1n bit of the TUM1n register is set to 1, and the OSTn bit is set to 1, the counting operation starts if the
active edge is input to the TCLR1n signal after the CE1n bit is set (1). If TM1n overflows, the count operation stops
once and it does not resume the count operation until the active edge is input again to the TCLR1n signal. If the
active edge of the TCLR1n signal is detected during a counting operation, TM1n is cleared and the count operation
continues (refer to Figure 9-4). Note that if the CE1n bit is set (1) after an overflow, the count operation does not
resume.
Figure 9-3. Timer Clear/Start Operation by TCLR1n Signal Input (If ECLR1n = 1 and OSTn = 0)
Overflow
FFFFH
Clear & start
Count
start
TM1n
0
INTOV1n ECLR1n
Remark
1
CE1n
1
TCLR1n
TCLR1n
n = 0 to 5
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CHAPTER 9 TIMER/COUNTER FUNCTION (REAL-TIME PULSE UNIT)
Figure 9-4. Relationship Between Clear/Start by TCLR1n Signal Input and Overflow Operation
(If ECLR1n = 1 and OSTn = 1)
Overflow
FFFFH
Count
start
TM1n
0
CE1n
1
TCLR1n
TCLR1n
TCLR1n
INTOV1n
Remark
n = 0 to 5
9.4.5 Capture operation
In synch with an external trigger, a capture operation is performed in which the TM1n count value is captured and
held in the capture register asynchronous to the count clock (n = 0 to 5). The active edge detected from external
interrupt request input pins INTP1n0 to INTP1n3 is used as the external trigger (capture trigger). In synch with that
capture trigger signal, the count value of TM1n, as it is counting, is captured and held in the capture register. The
value in the capture register is held until the next capture trigger is generated.
Also, interrupt requests (INTCC1n0 to INTCC1n3) are generated from the INTP1n0 to INTP1n3 signal inputs.
Table 9-2. Capture Trigger Signals (TM1n) to 16-Bit Capture Registers
Capture Register
Capture Trigger Signal
CC1n0
INTP1n0
CC1n1
INTP1n1
CC1n2
INTP1n2
CC1n3
INTP1n3
Remarks 1. CC1n0 to CC1n3 are the capture/compare registers. Which register is used is specified in timer
unit mode register 1n (TUM1n).
2. n = 0 to 5
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CHAPTER 9 TIMER/COUNTER FUNCTION (REAL-TIME PULSE UNIT)
The capture trigger’s active edge is set by the external interrupt mode register (INTM1 to INTM6). If both the rising
and falling edges are made capture triggers, the input pulse width from an external source can be measured. Also, if
the edge from one side is used as the capture trigger, the input pulse’s period can be measured.
Figure 9-5. Example of Capture Operation
n
TM11
0
CE11
CC110
n
INTP110
(Capture trigger)
Remark
(Capture trigger)
When the CE11 bit = 0, no capture operation is performed even if INTP110 is input.
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CHAPTER 9 TIMER/COUNTER FUNCTION (REAL-TIME PULSE UNIT)
Figure 9-6. Example of TM11 Capture Operation (When Both Edges Are Specified)
FFFFH
D1
TM11 count value
D0
D2
∆
CE11←1
(count start)
∆
OVF11←1
(overflow)
Interrupt request
(INTP110)
Capture register
(CC110)
Remark
268
D0
D1
D0 to D2: TM11 count value
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CHAPTER 9 TIMER/COUNTER FUNCTION (REAL-TIME PULSE UNIT)
9.4.6 Compare operation
Compare operations in which the value set in the compare register is compared with the TM1n count value are
performed (n = 0 to 5).
If the TM1n count value matches the value that has been previously set in the compare register, a match signal is
sent to the output control circuit (refer to Figure 9-7). The timer output pins (TO1n0, TO1n1) are changed by the
match signal and simultaneously issue interrupt request signals.
Table 9-3. Interrupt Request Signals (TM1n) from 16-Bit Compare Registers
Compare Register
Interrupt Request Signal
CC1n0
INTCC1n0
CC1n1
INTCC1n1
CC1n2
INTCC1n2
CC1n3
INTCC1n3
Remarks 1. CC1n0 to CC1n3 are capture/compare registers. Which register will be used is specified by the
timer unit mode register 1n (TUM1n).
2. n = 0 to 5
Figure 9-7. Example of Compare Operation
Count up
TM11
CC110
nÐ1
n
n+1
n
Match detected
(INTCC110)
Remark
A Match is detected immediately after counting up, then a match detection signal is generated.
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CHAPTER 9 TIMER/COUNTER FUNCTION (REAL-TIME PULSE UNIT)
Timer 1 has 12 timer output pins (TO1n0, TO1n1).
The TM1n count value and the CC1n0 value are compared and if they match, the output level of the TO1n0 pin is
set. Also, the TM1n count value and the CC1n1 value are compared, and if they match, the TO1n0 pin’s output level
is reset.
In the same way, the TM1n count value and the CC1n2 value are compared, and if they match, the TO1n1 pin’s
output level is set. Also, the TM1n counter value and the CC1n3 value are compared, and if they match, the TO1n1
pin’s output level is set.
The output level of pins TO1n0 and TO1n1 can also be specified by the TOC1n register.
Figure 9-8. Example of TM11 Compare Operation (Set/Reset Output Mode)
FFFFH
FFFFH
CC111
CC111
CC110
CC110
CC110
TM11 count value
0
∆
CE11←1
(count start)
∆
OVF11←1
(overflow)
Interrupt request
(INTCC110)
Interrupt request
(INTCC111)
TO110 pin
ENTO110 ←1
ALV110 ←1
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User’s Manual U12688EJ4V0UM00
∆
OVF11←1
(overflow)
CHAPTER 9 TIMER/COUNTER FUNCTION (REAL-TIME PULSE UNIT)
9.5
Timer 4 Operation
9.5.1 Count operation
Timer 4 functions as a 16-bit interval timer. Setting of its operation is specified in timer control register 4n
(TMC4n) (n = 0, 1).
In a timer 4 count operation, the internal count clock (φ/32 to φ/256) specified by the PRS4n0, PRM4n1, and
PRM4n0 bits of the TMC4n register is counted up.
If the count results in TM4n match the value in CM4n, TM4n is cleared. At the same time, a matching interrupt
(INTCM4n) is generated.
Figure 9-9. Basic Operation of Timer 4
Count clock
TM4n
0000H 0001H 0002H 0003H
FBFEH FBFFH
∆
Count start
CE4n ← 1
Remark
0000H
∆
Count disable
CE4n ← 0
0001H 0002H 0003H
∆
Count start
CE4n ← 1
n = 0, 1
9.5.2 Count clock selection
Using the setting of the TMC4n register’s PRS4n0, PRM4n1, and PRM4n0 bits, one of four possible internal count
clocks, φ/32, φ/64, φ/128 or φ/256, can be selected (n = 0, 1).
Caution Do not change the count clock during timer operation.
PRS4n0
PRM4n1
PRM4n0
0
0
0
φ/32
0
0
1
φ/64
0
1
0
φ/128
0
1
1
RFU (reserved)
1
0
0
φ/64
1
0
1
φ/128
1
1
0
φ/256
1
1
1
RFU (reserved)
Remark
Internal Count Clock
n = 0, 1
9.5.3 Overflow
If the TM4n overflows as a result of counting the internal count clock, the OVF4n bit of the TOVS register is set (1)
(n = 0, 1).
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CHAPTER 9 TIMER/COUNTER FUNCTION (REAL-TIME PULSE UNIT)
9.5.4 Compare operation
In Timer 4, a compare operation which compares the value set in the compare register (CM4n) with the TM4n
count value is performed (n = 0, 1).
If values are found to match in the compare operation, an interrupt (INTCM4n) is issued. By issuing an interrupt,
TM4n is cleared (0) with the following timing (refer to Figure 9-10 (a)). Through this function, Timer 4 is used as an
interval timer.
CM4n can also be set to 0. In this case, if TM4n overflows and becomes 0, a value match is detected and
INTCM4n is issued. Using the following count timing, the TM4n value is cleared (0), but with this match, INTCM4n is
not issued (refer to Figure 9-10 (b)).
Figure 9-10. Example of TM40 Compare Operation (1/2)
(a) If FFFFH is set in CM40
Count clock
Count up
TM40 clear
Clear
TM40
n
0
n
CM40
Match detected
(INTCM40)
Remark
Interval time = (n + 1) × count clock cycle
n = 1 to 65,535 (FFFFH)
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CHAPTER 9 TIMER/COUNTER FUNCTION (REAL-TIME PULSE UNIT)
Figure 9-10. Example of TM40 Compare Operation (2/2)
(b) If 0 is set in CM40
Count clock
Count up
TM40 clear
Clear
TM40
FFFFH
0
CM40
0
1
0
Match detected
(INTCM40)
Overflow
Remark
Interval time = (FFFFH + 1) × count clock cycle
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CHAPTER 9 TIMER/COUNTER FUNCTION (REAL-TIME PULSE UNIT)
9.6
Application Example
(1) Operation as an interval timer (Timer 4)
In this example, timer 4 is used as an interval timer that repeatedly issues an interrupt at intervals specified by
the count time preset in the compare register (CM4n) (n = 0, 1).
Figure 9-11. Example of Timing in Interval Timer Operation
n
n
∆
Clear
∆
Clear
TM40 count value
0
∆
Count start
Compare register
(CM40)
n
Interrupt request
(INTCM40)
t
Remark
n:
Value in the CM40 register
t:
Interval time = (n + 1) × count clock cycle
Figure 9-12. Example of Interval Timer Operation Setting Procedure
Interval timer initial setting
TMC4n register setting
; Specifies the count clock
Setting the count value in the CM4n register
CM4n ← Count value
Count start
TMC4n.CE4n ← 1
; Sets the CE4n bit (1)
INTCM4n interrupt
Remark
274
n = 0, 1
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CHAPTER 9 TIMER/COUNTER FUNCTION (REAL-TIME PULSE UNIT)
(2) Operation for pulse width measurement (Timer 1)
In measuring the pulse width, timer 1 is used.
Here, an example is given of measurement of high level or low level width of an external pulse input to the
INTP112 pin.
As shown in Figure 9-13, in synch with the active edge (specified as both the rising edge and falling edge) of
the INTP112 pin’s input, the value of the counting timer 1 (TM11) is fetched to and held in the
capture/compare register (CC112).
The pulse width is calculated by determining the difference between the count value of TM11 captured in the
CC112 register through active edge detection the nth time and the count value (Dn – 1) captured through
active edge detection the (n – 1)th time, then multiplying this value by the count clock.
Figure 9-13. Example of Pulse Measurement Timing
FFFFH
D3
D1
TM11 count value
D2
D0
0
Capture
Capture
Capture
Capture
External pulse input
(INTP112)
Capture/compare register
(CC112)
D0
D1
D2
t1
t2
t3
D3
t1 = (D1 – D0) × count clock cycle
t2 = {(10000H – D1) + D2} × count clock cycle
t3 = (D3 – D2) × count clock cycle
Remark
D0 to D3: TM11 count values
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CHAPTER 9 TIMER/COUNTER FUNCTION (REAL-TIME PULSE UNIT)
Figure 9-14. Example of Pulse Width Measurement Setting Procedure
Initial pulse width
measurement setting
Setting the TMC11 register
; Specifies the count clock
Setting the INTM2 register
INTM2.ES121 ← 1
INTM2.ES120 ← 1
; Specifies both edges of the INTP112
input signal as active edges
Setting the TUM11 register
TUM11.CMS112 ← 0
; Sets it as the capture register
Initializing buffer memory
for capture data storage
X0 ← 0
Count start
TMC11.CE11 ← 1
; Sets the CE11 bit (1)
Enabling interrupt
INTP112 interrupt
Figure 9-15. Example of Interrupt Request Processing Routine Which Calculates the Pulse Width
INTP112 interrupt processing
(both the rising and falling edges)
Calculating the pulse width
Yn = CC112 – Xn–1
tn = Yn × count clock period
; Xn, Yn: Variables
; tn: Pulse width
Storing of nth time capture data
in buffer memory
Xn ← CC112
RETI
Caution If 2 or more overflows occur between the (n – 1)th capture and the nth capture, the pulse
width cannot be measured.
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CHAPTER 9 TIMER/COUNTER FUNCTION (REAL-TIME PULSE UNIT)
(3) Operation as a PWM output (Timer 1)
Through a combination of timer 1 and the timer output function, the desired rectangular wave can be output to
the timer output pins (TO1n0, TO1n1) and used as a PWM output (n = 0 to 5).
Here an example is shown using the capture/compare registers CC100 and CC101.
In this case, a PWM signal with 16-bit precision can be output from the TO100 pin. The timing is shown in
Figure 9-16.
If used as a 16-bit timer, the PWM output’s rise timing set in the capture/compare register (CC100) is
determined as shown in Figure 9-16, and the fall timing is determined by the value set in the capture/compare
register (CC101).
Figure 9-16. Example of PWM Output Timing
FFFFH
FFFFH
FFFFH
CC101
CC101
CC100
CC100
TM10 count value
0
Capture/compare register
(CC100)
D10
D00
Matching
CC100
D11
D01
Matching
D00
Matching
D02
Matching
D01
Matching
D02
Interrupt request
(INTCC100)
Capture/compare register
(CC101)
D10
D11
D12
Interrupt request
(INTCC101)
Timer output
(TO100 pin)
t1
t2
Remark
D00 to D02, D10 to D12: Compare register setting values
t1 = {(10000H – D00) + D01} × count clock period
t2 = {(10000H – D10) + D11} × count clock period
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CHAPTER 9 TIMER/COUNTER FUNCTION (REAL-TIME PULSE UNIT)
Figure 9-17. Example of PWM Output Setting Procedure
PWM output initial setting
Setting the TOC10 register
TOC10.ENTO100 ← 1
TOC10.ALV100 ← 1
; Specifies the active level (high level)
and enables timer output
Setting the TUM10 register
TUM10.CMS100 ← 1
TUM10.CMS101 ← 1
; Specifies the operation of the CC100 and CC101 registers
(specifies compare operation)
Through the PMC0 register, the P00 pin is
designated as the timer output pin TO100
PMC0.PMC00 ← 1
; Specifies the TM10’s count clock
Setting of the TMC10 register
Setting of the count value
in the CC100 register
CC100 ← D00
Setting of the count value
in the CC101 register
CC101 ← D10
Count start
TMC10.CE10 ← 1
; Sets the CE10 bit (1)
Enabling interrupt
INTCC100 interrupt
INTCC101 interrupt
Figure 9-18. Example of Interrupt Request Processing Routine for Rewriting Compare Value
278
INTCC100 interrupt processing
INTCC101 interrupt processing
The amount of time until the next time the
TO100 output is reset (0) (the number of counts)
is set in compare register CC101
The amount of time until the next time the
TO100 output is set (1) (the number of counts)
is set in compare register CC100
RETI
RETI
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CHAPTER 9 TIMER/COUNTER FUNCTION (REAL-TIME PULSE UNIT)
(4) Operation for frequency measurement (Timer 1)
Timer 1 can measure the frequency of an external pulse’s input to pins INTP1n0 to INTP1n3 (n = 0 to 5).
Here, an example is shown where timer 1 and the capture/compare register CC110 are combined to measure
the frequency of an external pulse input to the INTP110 pin with 16-bit precision.
The active edge of the INTP110 input signal is specified to be the rising edge by the INTM2 register.
The frequency is calculated by determining the difference between the TM11 count value (Dn) captured in
the CC110 register from the nth rising edge, and the count value (Dn–1) captured from the rising edge the
(n – 1)th time, then multiplying this value by the count clock.
Figure 9-19. Example of Frequency Measurement Timing
FFFFH
FFFFH
FFFFH
TM11 count value
D2
D1
D0
0
Interrupt request
(INTP110)
Capture/compare register
(CC110)
t1
t2
D0
D1
D2
t1 = {(10000H – D0) + D1} × count clock cycle frequency
t2 = {(10000H – D0) + D2} × count clock cycle frequency
Remark
D0 to D2: TM11 count value
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CHAPTER 9 TIMER/COUNTER FUNCTION (REAL-TIME PULSE UNIT)
Figure 9-20. Example of Frequency Measurement Setting Procedure
Cycle measurement initial setting
Setting the TMC11 register
; Specifies the count clock.
Setting the TUM11 register
TUM11.CMS110 ← 0
; Specifies operation of the CC110 register as the capture register.
Setting the INTM2 register
INTM2.ES101 ← 0
INTM2.ES100 ← 1
; Specifies the rising edge of the INTP110 signal as the active edge.
Initializing buffer memory
for capture data storage
X0 ← 0
Count start
TMC11.CE11 ← 1
; Sets the CE11 bit (1).
Enabling interrupt
INTP110 interrupt
Figure 9-21. Example of Interrupt Request Processing Routine Which Calculates the Frequency
INTP110 interrupt processing
Calculating the period
Yn = (10000H – Xn–1) + CC110
tn = Yn × count clock period
; tn: Period
Storing of the nth time is
capture data in buffer memory
Xn ← CC110
RETI
280
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CHAPTER 9 TIMER/COUNTER FUNCTION (REAL-TIME PULSE UNIT)
9.7
Precaution
Match detection by the compare register is always performed immediately after timer count up. In the following
cases, a match does not occur.
(1) When rewriting the compare register (TM10 to TM15, TM40, TM41)
Count clock
Timer value
nÐ1
n
n+1
m
Compare register value
n
Writing to the register
Match detection
L
Match does not occur
Match does not occur
(2) During external clear (TM10 to TM15)
Count clock
Timer value
nÐ1
n
0
1
External clear input
Compare register value
Match detection
0000H
L
Match does not occur
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(3) When the timer is cleared (TM40, TM41)
Count clock
Timer value
FFFEH
FFFFH
0
0
1
Internal matching clear
Compare register value
0000H
Match detection
Match does not occur
Remark
When operating timer 1 as the free-running timer, the timer’s value becomes 0 when timer overflow
occurs.
Count clock
Timer value
FFFEH
FFFFH
0
Overflow interrupt
282
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2
3
CHAPTER 10 SERIAL INTERFACE FUNCTION
10.1 Features
Two types of serial interfaces with 6 transmit/receive channels are provided as the serial interface function, and up
to 4 channels can be used simultaneously.
The following two types of interface configuration are provided.
(1) Asynchronous serial interface (UART0, UART1):
2 channels
(2) Clocked serial interface (CSI0 to CSI3):
4 channels
UART0 and UART1 use the method of transmitting and receiving 1 byte of serial data following the start bit, and full
duplex communication is possible.
CSI0 to CSI3 carry out data transfer with 3 types of signal lines, a serial clock (SCK0 to SCK3), serial input (SI0 to
SI3), and serial output (SO0 to SO3) (3-wire serial I/O).
Caution UART0 and CSI0, and UART1 and CSI1 share the same pins, the use of which is specified with the
ASIM00 and ASIM10 registers.
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10.2 Asynchronous Serial Interfaces 0, 1 (UART0, UART1)
10.2.1 Features
{ Transfer rate 150 bps to 76,800 bps (using the exclusive baud rate generator when the internal system clock is
33 MHz)
Maximum 4.125 Mbps (using the φ/2 clock when the internal system clock is 33 MHz)
{ Full duplex communication On-chip receive buffer (RXBn)
{ 2-pin configuration TXDn: Transmit data output pin
RXDn: Receive data input pin
{ Receive error detection functions
• Parity error
• Framing error
• Overrun error
{ Interrupt sources: 3 types
• Receive error interrupt (INTSERn)
• Reception complete interrupt (INTSRn)
• Transmission complete interrupt (INTSTn)
{ The character length of transmit/receive data is specified by the ASIMn0 and ASIMn1 registers.
{ Character length 7, 8 bits
9 bits (when adding an expansion bit)
{ Parity function: odd, even, 0, none
{ Transmission stop bit: 1, 2 bits
{ On-chip dedicated baud rate generator
{ Serial clock (SCKn) output function
Remark
284
n = 0, 1
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10.2.2 Configuration
UARTn is controlled by the asynchronous serial interface mode registers (ASIMn0, ASIMn1) and the asynchronous
serial interface status registers (ASISn) (n = 0, 1). Receive data is held in the receive buffer (RXBn) and transmit data
is written in the transmit shift registers (TXSn).
The asynchronous serial interface is configured as shown in Figure 10-1.
(1) Asynchronous serial interface mode registers (ASIM00, ASIM01, ASIM10, ASIM11)
The ASIMn0 and ASIMn1 registers are 8-bit registers that specify asynchronous serial interface operations.
(2) Asynchronous serial interface status registers (ASIS0, ASIS1)
The ASISn registers are registers of flags that show the contents of errors when a receive error occurs and
transmission status flags. Each receive error flag is set (1) when a receive error occurs and is cleared (0) by
reading of data from the receive buffer (RXBn) or reception of the next new data (if there is an error in the next
data, that error flag will not be cleared (0) but left set (1)).
The transmit status flag is set (1) when transmission starts and is cleared (0) when transmission ends.
(3) Receive control parity check
Receive operations are controlled according to the contents set in the ASIMn0 and ASIMn1 registers. Also,
errors such as parity errors are checked during receive operations.
If an error is detected, a value
corresponding to the error content is set in the ASISn register.
(4) Receive shift register
This is a shift register that converts serial data input to the RXDn pin to parallel data. When 1 byte of data is
received, the receive data is transferred to the receive buffer.
This register cannot be directly manipulated.
(5) Receive buffers (RXB0, RXB0L, RXB1, RXB1L)
RXBn are 9-bit buffer registers that hold receive data, and when 7 or 8-bit character data is received, a 0 is
stored in the higher bits.
During 16-bit access of these registers, specify RXB0 and RXB1, and during lower 8-bit access, specify
RXB0L and RXB1L.
In the receive enabled state, 1 frame of receive data is transmitted to the receive buffer from the receive shift
register in synchronization with the termination of shift-in processing.
Also, a reception complete interrupt request (INTSRn) is generated when data is transmitted to the receive
buffer.
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(6) Transmit shift register (TXS0, TXS0L, TXS1, TXS1L)
TXSn are 9-bit shift registers for transmit processing. Writing of data to these registers starts a transmit
operation.
A transmission complete interrupt request (INTSTn) is generated in synchronization with termination of
transmission of 1 frame, which includes TXSn data.
During 16-bit access of these registers, specify TXS0 and TXS1, and during lower 8-bit access, specify TXS0L
and TXS1L.
(7) Adding transmit control parity
In accordance with the contents set in the ASIMn0 and ASIMn1 registers, start bits, parity bits, stop bits, etc.
are added to the data written to the TXSn or TXSnL register, and transmit operation control is carried out.
(8) Selector
This selects the serial clock source.
Figure 10-1. Block Diagram of Asynchronous Serial Interface
UART0
RXE0
RXD0
Receive shift
register
RXB0/RXB0L
Receive
buffer
TXS0/TXS0L
Transmit
shift register
TXD0
Transmit
control
parity added
INTST0
Receive
control
parity check
INTSER0
SCLS01, SCLS00
1/16
1/16
1/2
Selector
SCK0
INTSR0
Internal system
clock
(φ )
BRG0
INTST1
RXD1
INTSER1
TXD1
UART1
SCK1
286
INTSR1
BRG1
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CHAPTER 10 SERIAL INTERFACE FUNCTION
10.2.3 Control registers
(1) Asynchronous serial interface mode registers 00, 01, 10, 11 (ASIM00, ASIM01, ASIM10, ASIM11)
These registers specify the UART0 and UART1 transfer mode.
These registers can be read/written in 8- or 1-bit units.
7
6
5
4
3
2
ASIM00
TXE0
RXE0
PS01
PS00
CL0
SL0
SCLS01 SCLS00
Address
FFFFF0C0H
After reset
80H
ASIM10
TXE1
RXE1
PS11
PS10
CL1
SL1
SCLS11 SCLS10
FFFFF0D0H
80H
Bit Position
7, 6
Bit Name
TXEn,
RXEn
1
0
Function
Transmit/Receive Enable
Specifies the transmission/reception enable status/disable status.
TXEn
RXEn
Operation
0
0
Transmission/reception disabled (CSIn selected)
0
1
Reception enabled
1
0
Transmission enabled
1
1
Transmission/reception enabled
When reception is disabled, the receive shift register does not detect the start bit. The
receive buffer contents are held without shift-in processing or transmit processing to the
receive buffer being performed.
While in the reception enabled state, the receive shift operation is started in
synchronization with detection of the start bit and after 1 frame of data has been
received, the contents of the receive shift register are transmitted to the receive buffer.
Also, the reception complete interrupt (INTSRn) is generated in synchronization with
transmission to the receive buffer. The TXDn pin becomes high impedance when
transmission is disabled and a high level is output if it is not transmitting when
transmission is enabled.
Remark
n = 0, 1
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Bit Position
Bit Name
5, 4
PSn1, PSn0
Function
Parity Select
Specifies the parity bit length.
PSn1
PSn0
Operation
0
0
No parity, expansion bit operation
0
1
Specifies 0 parity
Transmission side → Transmits with parity bit at 0.
Reception side → Does not generate parity errors
during receiving.
1
0
Specifies odd parity.
1
1
Specifies even parity.
• Even parity
If the number of bits whose values are 1 in the transmit data is odd, a parity bit is set
(1). If the number of bits whose values are 1 is even, the parity bit is cleared (0). In
this way, the number of bits in the transmit data and the parity bit which are 1 is
controlled so that it is an even number. During receiving the number of bits in the
receive data and parity bit which are 1 is counted, and if it is an odd number, a parity
error is generated.
• Odd parity
This is the opposite of even parity, with the number of bits in the transmit data and
parity bit being controlled so that it is an odd number.
During receiving, if the number of bits in the receive data and parity bit which are 1
turns out to be an even number, a parity error is generated.
• 0 parity
During transmission, the parity bit is cleared (0) regardless of the transmit data.
During reception, since no parity bit check is performed, no parity error is generated.
• No parity
No parity bit is added to transmit data.
During reception, data are received as having no parity bit. Since there is no parity
bit, parity errors are not generated.
Expansion bit operations can be specified with the EBSn bit in the ASIMn1 register.
3
Remark
288
CLn
Character Length
Specifies the character length of 1 frame.
0: 7 bits
1: 8 bits
n = 0, 1
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CHAPTER 10 SERIAL INTERFACE FUNCTION
Bit Position
2
1, 0
Bit Name
Function
SLn
Stop Bit Length
Specifies the stop bit length.
0: 1 bit
1: 2 bits
SCLSn1,
SCLSn0
Serial Clock Source
Specifies the serial clock.
SCLSn1
SCLSn0
Serial Clock
0
0
Baud rate generator output
0
1
φ/2 (× 16 sampling rate)
1
0
φ/2 (× 8 sampling rate)
1
1
φ/2 (× 4 sampling rate)
• In the case of SCLSn1, SCLSn0 = 00
φ/2 is selected as the serial clock source. (φ: internal system clock). In the
asynchronous mode, ×16, ×8 and ×4 sampling rates are used, so the baud rate is
expressed by the following formula.
φ /2
Baud rate =
bps
sampling rate
Based on the formula above, the baud rate value in the case where a representative
clock is used is shown below.
×16
(01)
Note
Sampling Rate
Internal
System Clock (φ)
×4
(11)
×8
(10)
40 MHz
1,250 K
2,500 K
33 MHz
1,031 K
2,062 K
4,125 K
25 MHz
781 K
1,562 K
3,125 K
20 MHz
625 K
1,250 K
2,500 K
16 MHz
500 K
1,000 K
2,000 K
12.5 MHz
390 K
781 K
1,562 K
10 MHz
312 K
625 K
1,250 K
8 MHz
250 K
500 K
1,000 K
5 MHz
156 K
312 K
625 K
Note Values in ( ) are the set values for the SCLSn1 and SCLSn0 bits
• If SCLSn1, SCLSn0 = 00
The baud rate generator output is selected as the serial clock source. For details
concerning the baud rate generator, refer to 10.4 Dedicated Baud Rate Generators
0 to 2 (BRG0 to BRG2).
Caution UARTn operation is not guaranteed if this register is changed during UARTn transmission or
reception. Furthermore, if this register is changed during UARTn transmission or reception, a
transmission complete interrupt (INTSTn) is generated during transmission, and a reception
complete interrupt (INTSRn) is generated during reception.
Remark
n = 0, 1
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7
6
5
4
3
2
1
0
ASIM01
0
0
0
0
0
0
0
EBS0
Address
FFFFF0C2H
After reset
00H
ASIM11
0
0
0
0
0
0
0
EBS1
FFFFF0D2H
00H
Bit Position
0
Bit Name
EBSn
Function
Extended Bit Select
Specifies transmit/receive data expansion bit operation when no parity operation is
specified (PSn1, PSn0 = 00).
0: Expansion bit operation disabled.
1: Expansion bit operation enabled.
When expansion bit is specified, 1 data bit is added to the high-order of 8-bit
transmit/receive data, and communications by 9-bit data are enabled.
Expansion bit operation is enabled only in the case where no parity operations have
been specified in the ASIMn0 register. If 0 parity, or even/odd parity operation is
specified, the EBSn bit specification is made invalid and the expansion bit adding
operation is not performed.
Caution UARTn operation when this register has been changed during UARTn transmission/ reception
is not guaranteed.
Remark
290
n = 0, 1
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(2) Asynchronous serial interface status registers 0, 1 (ASIS0, ASIS1)
These registers are configured with 3-bit error flags (PEn, FEn, OVEn), which show the error status when
UARTn reception is terminated, and a transmit status flag (SOTn) (n = 0,1).
The status flag that shows a receive error always shows the state of the error that occurred most recently.
That is, if the same error occurred several times before reading of receive data, this flag would hold the status
of the error that occurred most recently.
If a receive error occurs, after reading the ASISn register, read the receive buffer (RXBn or RXBnL) and clear
the error flag.
These are read-only registers in 8- or 1-bit units.
7
6
5
4
3
2
1
0
ASIS0
SOT0
0
0
0
0
PE0
FE0
OVE0
Address
FFFFF0C4H
After reset
00H
ASIS1
SOT1
0
0
0
0
PE1
FE1
OVE1
FFFFF0D4H
00H
Bit Position
Bit Name
Function
7
SOTn
Status Of Transmission
This is a status flag that shows the transmission operation’s state.
Set (1): Transmission start timing (writing to the TXSn or TXSnL register)
Clear (0): Transmission end timing (generation of the INTSTn interrupt)
When about to start serial data transmission, use this as a means of judging whether
writing to the transmit shift register is enabled or not.
2
PEn
Parity Error
This is a status flag that shows a parity error.
Set (1): When transmit parity and receive parity do not match.
Clear (0): Data are read from the receive buffer and processed.
1
FEn
Framing Error
This is a status flag that shows a framing error.
Set (1): When a stop bit was not detected.
Clear (0): Data are read from the receive buffer and processed.
0
OVEn
Overrun Error
This is a status flag that shows an overrun error.
Set (1): When UARTn has finished the next receiving processing before fetching
receive data from the receive buffer.
Clear (0): Data are read from the receive buffer and processed.
Furthermore, due to the configuration where 1 frame at a tie is received, then the
contents of the receive shift register are transmitted to the receive buffer, when an
overrun error has occurred, the next receive data is written over the data existing in the
receive buffer, and the previous receive data is discarded.
Remark
n = 0, 1
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(3) Receive buffers 0, 0L, 1, 1L (RXB0, RXB0L, RXB1, RXB1L)
RXBn are 9-bit buffer registers that hold receive data, with a 0 stored in the higher bits when 7 or 8-bit
character data is received (n = 0, 1).
During 16-bit access of these registers, specify RXB0 and RXB1, and during lower 8-bit access, specify
RXB0L and RXB1L.
While in the reception enabled state, receive data is transmitted from the receive shift register to the receive
buffer in synchronization with the end of shift-in processing of 1 frame.
Also, a reception complete interrupt request (INTSRn) is generated by transfer of receive data to the receive
buffer.
In the reception disabled state, transmission of receive data to the receive buffer is not performed even if shiftin processing of 1 frame is completed, and the contents of the receive buffer are held.
Also, a reception complete interrupt request is not generated.
RXB0 and RXB1 are read-only registers in 16-bit units, and RXB0L and RXB1L are read-only registers in 8- or
1-bit units.
RXB0
15
14
13
12
11
10
9
0
0
0
0
0
0
0
8
7
RXB0L
RXB1
14
13
12
11
10
9
0
0
0
0
0
0
0
8
8
7 to 0
Remark
292
3
2
1
0
6
5
4
3
2
1
7
6
5
4
3
2
1
6
5
4
3
2
1
Address
FFFFF0C8H
After reset
Undefined
FFFFF0CAH
Undefined
FFFFF0D8H
Undefined
FFFFF0DAH
Undefined
0
0
RXEB1 RXB17 RXB16 RXB15 RXB14 RXB13 RXB12 RXB11 RXB10
RXB1L
Bit Name
4
RXB07 RXB06 RXB05 RXB04 RXB03 RXB02 RXB01 RXB00
7
Bit Position
5
RXEB0 RXB07 RXB06 RXB05 RXB04 RXB03 RXB02 RXB01 RXB00
7
15
6
0
RXB17 RXB16 RXB15 RXB14 RXB13 RXB12 RXB11 RXB10
Function
RXEBn
Receive Extended Buffer
This is the expansion bit during reception of 9-bit/character data.
A 0 can be read in reception of 7 and 8-bit/character data.
RXBn7 to
RXBn0
Receive Buffer
This stores receive data.
A 0 can be read when RXBn7 is receiving 7-bit/character data.
n = 0, 1
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(4) Transmit shift registers 0, 0L, 1, 1L (TXS0, TXS0L, TXS1, TXS1L)
TXSn are 9-bit shift registers for transmission processing and when transmission is enabled, transmission
operations are started (n = 0, 1) by writing of data to these registers.
When transmission is disabled, the values are disregarded even if writing is performed.
A transmission complete interrupt request (INTSTn) is generated in synchronization with the end of
transmission of 1 frame including TXS data.
During 16-bit access of these registers, specify TXS0 and TXS1, and during lower 8-bit access, specify TXS0L
and TXS1L.
TXS0 and TXS1 are write-only registers in 16-bit units, and TXS0L and TXS1L are write-only registers in 8-bit
units.
TXS0
15
14
13
12
11
10
9
0
0
0
0
0
0
0
8
7
TXS0L
TXS1
14
13
12
11
10
9
0
0
0
0
0
0
0
8
7 to 0
3
2
1
0
6
5
4
3
2
1
7
6
5
4
3
2
1
6
5
4
3
2
1
After reset
Undefined
FFFFF0CEH
Undefined
FFFFF0DCH
Undefined
FFFFF0DEH
Undefined
0
0
TXS17 TXS16 TXS15 TXS14 TXS13 TXS12 TXS11 TXS10
Bit Name
Address
FFFFF0CCH
0
TXED1 TXS17 TXS16 TXS15 TXS14 TXS13 TXS12 TXS11 TXS10
TXS1L
8
4
TXS07 TXS06 TXS05 TXS04 TXS03 TXS02 TXS01 TXS00
7
Bit Position
5
TXED0 TXS07 TXS06 TXS05 TXS04 TXS03 TXS02 TXS01 TXS00
7
15
6
Function
TXEDn
Transmit Extended Data
This is the expansion bit during transmission of 9-bit/character data.
TXSn7 to
TXSn0
(n = 0, 1)
Transmit Shifter
This writes transmission data.
Cautions 1. UARTn does not have a transmit buffer, so there is no interrupt request at the end of
transmission (to the buffer), and an interrupt request (INTSTn) is generated in
synchronization with the end of transmission of 1 frame of data.
2. If the UARTn registers are changed during transmission, UARTn operation is not
guaranteed.
Remark
n = 0, 1
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10.2.4 Interrupt request
UARTn generates the following three types of interrupt requests (n = 0, 1).
• Receive error interrupt (INTSERn)
• Reception complete interrupt (INTSRn)
• Transmission complete interrupt (INTSTn)
The priority order of these three interrupts is, from high to low: receive error interrupt, reception complete interrupt,
transmission complete interrupt.
Table 10-1. Default Priority of Interrupt
Interrupt
Priority
Receive error
1
Reception complete
2
Transmission complete
3
(1) Receive error interrupt (INTSERn)
In the reception enabled state, a receive error interrupt is generated by ORing the three receive errors.
In the reception disabled state, no receive error interrupt is generated.
(2) Reception completion interrupt (INTSRn)
In the reception enabled state, a reception complete interrupt is generated when data is shifted into the receive
shift register and transferred to the receive buffer.
This reception complete interrupt request is also generated when a receive error has occurred, but the receive
error interrupt has a higher servicing priority.
In the reception disabled state, no reception complete interrupt is generated.
(3) Transmission completion interrupt (INTSTn)
As this UARTn has no transmit buffer, a transmission complete interrupt is generated when one frame of
transmit data containing a 7-, 8-, or 9-bit character is shifted out of the transmit shift register.
A transmission complete interrupt is output at the start of transmission of the last bit of transmit data.
294
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10.2.5 Operation
(1) Data format
Transmission and reception of full duplex serial data are performed.
As shown in Figure 10-2, 1 data frame consists of a start bit, character bits, a parity bit, and a stop bit as the
format of transmit/receive data.
Specification of the character bit length within 1 data frame, parity selection and specification of the stop bit
length are performed by the asynchronous serial interface mode register (ASIMn0, ASIMn1) (n = 0, 1).
Figure 10-2. Transmission/Reception Data Format of Asynchronous Serial Interface
1 data frame
Start
bit
Parity/
D0
D1
D2
D3
D4
D5
D6
D7 expansion
Stop bit
bit
Character bits
INTSRn interrupt
INTSTn interrupt
• Start bit...........................1 bit
• Character bits ...............7 bits/8 bits
• Parity/expansion bit ........Even parity/odd parity/0 parity/no parity/expansion bit
• Stop bit ...........................1 bit/2 bits
Remark
n = 0, 1
(2) Transmission
Transmission starts when data is written to the transmit shift register (TXSn or TXSnL). With the transmission
complete interrupt (INTSTn) processing routine, the next data is written to the TXSn or TXSnL register (n = 0,
1).
(a) Transmit enable state
This is set with the TXEn bit of the ASIMn0 register.
TXEn = 1: Transmit enabled state
TXEn = 0: Transmit disabled state
However, when setting the transmit enabled state, be sure to set both the CTXEn and CRXEn bits of the
clocked serial interface mode register (CSIMn) of the channel in use to 0.
Note that since UARTn does not have CTS (transmit enabled signal) input pins, when the opposite party
wants to confirm the reception enabled state, use a port.
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(b) Starting a transmit operation
In the transmit enabled state, if data is written to the transmit shift register (TXSn or TXSnL), the transmit
operation starts.
Transmit data is transmitted from the start bit to the LSB header.
A start bit,
parity/expansion bit and stop bit are added automatically.
In the transmit disabled state, data is not written to the transmit shift register. Even if writing is done, the
values are disregarded.
(c) Transmission interrupt request
If the transmit shift register (TXSn or TXSnL) becomes empty, a transmission complete interrupt request
(INTSTn) is generated.
If the next transmit data is not written to the TXSn or TXSnL register, the transmit operation is interrupted.
After 1 transmission is ended, the transmission rate drops if the next transmit data is not written to the
TXSn or TSXnL register immediately.
Cautions
1. Normally, when the transmit shift register (TXSn or TXSnL) has become empty, a
transmission complete interrupt (INTSTn) is generated. However, when RESET is
input, if the transmit shift register (TXSn or TXSnL) has become empty, a
transmission complete interrupt (INTSTn) is not generated.
2. During a transmit operation before INTSTn generation, even if data is written to the
TXSn or TXSnL register, the written data is invalid.
Figure 10-3. Asynchronous Serial Interface Transmission Completion Interrupt Timing
(a) Stop bit length: 1
TXDn (output)
D0
D1
D2
D6
D7
Parity/
expansion
D6
D7
Parity/
expansion
Stop
Start
INTSTn interrupt
(b) Stop bit length: 2
TXDn (output)
D0
D1
D2
Start
INTSTn interrupt
Remark
296
n = 0, 1
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(3) Reception
If reception is enabled, sampling of the RXDn pin is started and if a start bit is detected, data reception begins.
When 1 frame of data reception is completed, the reception complete interrupt (INTSRn) is generated.
Normally, with this interrupt processing, receive data is transmitted from the receive buffer (RXBn or RXBnL)
to memory (n = 0, 1).
(a) Receive enabled state
Reception is enabled when the RXEn bit of the ASIMn0 register is set to 1.
RXEn = 1: Receive enabled state
RXEn = 0: Receive disabled state
However, when reception is enabled, be sure to set both the CTXEn and CRXEn bits of the clocked serial
interface mode register (CSIMn) of the channel in use to 0.
In the receive disabled state, the reception hardware stands by in the initial state.
At this time, no reception complete interrupts or reception error interrupts are generated, and the contents
of the receive buffer are retained.
(b) Start of receive operation
The receive operation is started by detection of the start bit.
The RXDn pin is sampled using the serial clock from the baud rate generator (BRGn). When an RXDn
pin low level is detected, the RXDn pin is sampled again after 8 serial clock cycles. If it is low this is
recognized as a start bit, the receive operation is started and the RXDn pin input is subsequently sampled
at intervals of 16 serial clock cycles.
If the RXDn pin input is found to be high when sampled again 8 serial clock cycles after an RXDn pin low
level is detected, this low level is not recognized as a start bit, the operation is stopped by initializing the
serial clock counter for sample timing generation, and the unit waits for the next low-level input.
(c) Reception complete interrupt request
When RXEn = 1, after one frame of data has been received, the receive data in the shift register is
transferred to RXBn and RXBnL a reception complete interrupt request (INTSRn) is generated.
Also, even if an error occurs, the receive data where the error occurred is transmitted to the receive buffer
(RXBn or RXBnL) and a reception complete interrupt (INTSRn) and receive error interrupt (INTSERn) are
generated simultaneously.
Furthermore, if the RXEn bit is reset (0) during a receive operation, the receive operation is stopped
immediately. At this time, the contents of the receive buffer (RXBn or RXBnL) and the asynchronous
serial interface status register (ASISn) do not change and the reception complete interrupt (INTSRn) and
receive error interrupt (INTSERn) are not generated.
When RXEn = 0 and reception is disabled, a reception complete interrupt request is not generated.
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Figure 10-4. Asynchronous Serial Interface Reception Complete Interrupt Timing
RXDn (input)
D0
D1
D2
D6
D7
Parity/
expansion
Stop
Start
INTSRn interrupt
Remark
n = 0, 1
(d) Receive error flag
In synchronization with the receive operation, three types of error flags, the parity error flag, framing error
flag, and overrun error flag, are affected.
A receive error interrupt request is generated by ORing these three error flags.
By reading out the contents of the ASISn register in the receive error interrupt (INTSERn), which error
occurred during reception can be detected.
As for the contents of the ASISn register, either the receive buffer (RXBn or RXBnL) are read or it is reset
(0) by reception of the next data (if there is an error in the next receive data, that error flag is set).
Receiving Error
Cause
Parity error
The parity specification during transmission does not match with
the parity of the receive data.
Framing error
A stop bit was not detected.
Overrun error
Reception of the next data was completed before data was read
from the receive buffer.
Figure 10-5. Receive Error Timing
RXDn (input)
D0
D1
D2
Start
INTSRn interrupt
INTSTn interrupt
Remark
298
n = 0, 1
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D7
Parity/
expansion
Stop
CHAPTER 10 SERIAL INTERFACE FUNCTION
10.3 Clocked Serial Interfaces 0 to 3 (CSI0 to CSI3)
10.3.1 Features
{ High transfer rate Max. 10 Mbps (when the internal system clock is operating at 40 MHz)
… µPD703100-40, 703100A-40
Max. 8.25 Mbps (when the internal system clock is operating at 33 MHz)
… other than above
{ Half-duplex communications
{ Character length: 8 bits
{ It is possible to switch MSB first or LSB first for data.
{ Either external serial clock input or internal serial clock output can be selected.
{ 3-wire type SOn: Serial data output
SIn:
Serial data input
SCKn: Serial clock input/output
{ Interrupt source 1 type
• Transmission/reception complete interrupt (INTCSIn)
Remark
10.3.2
n = 0 to 3
Configuration
CSIn are controlled by the clocked serial interface mode registers (CSIMn). Transmission/reception data can be
read from and written to the SIOn registers (n = 0 to 3).
(1) Clocked serial interface mode registers (CSIM0 to CSIM3)
The CSIMn registers are 8-bit registers that specify CSIn operations.
(2) Serial I/O shift registers (SIO0 to SIO3)
The SIOn registers are 8-bit registers that convert serial data to parallel data.
SIOn is used for both
transmission and reception.
Data is shifted in (received) or shifted out (transmitted) either from the MSB side or the LSB side.
Actual transmitting/receiving operations are controlled by reading from or writing to SIOn.
(3) Selector
This selects the serial clock to be used.
(4) Serial clock controller
This performs control of supply to the serial clock shift register. Also, when the internal clock is used, it
controls the clock that outputs to the SCKn pin.
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(5) Serial clock counter
Counts the serial clock that outputs, or is input during transmit/receive operations, and determines if 8-bit data
were transmitted or received.
(6) Interrupt control circuit
This circuit controls whether or not an interrupt request is generated when the serial clock counter counts 8
clocks.
Figure 10-6. Block Diagram of Clocked Serial Interface
CSI0
CTXE0
Internal system
clock
(φ )
SO0
CRXE0
SI0
SO Latch
Serial I/O shift
register (SIO0)
D
Q
CLS00, CLS01
SCK0
Selector
1/2
Serial clock controller
Serial clock counter
Interrupt
controller
1/4
BRG0
INTCSI0
1/2
SO1
1/4
SI1
CSI1
SCK1
BRG1
INTCSI1
1/2
SO2
1/4
SI2
CSI2
SCK2
BRG2
INTCSI2
1/2
SO3
1/4
SI3
CSI3
SCK3
300
INTCSI3
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10.3.3 Control registers
(1) Clocked serial interface mode registers 0 to 3 (CSIM0 to CSIM3)
These registers specify the basic operation mode of CSI0 to CSI3.
These registers can be read/written in 8- or 1-bit units (however, for bit 5, only reading is possible).
7
6
5
4
3
2
1
0
CSIM0
CTXE0
CRXE0
CSOT0
0
0
MOD0
CLS01
CLS00
Address
FFFFF088H
After reset
00H
CSIM1
CTXE1
CRXE1
CSOT1
0
0
MOD1
CLS11
CLS10
FFFFF098H
00H
CSIM2
CTXE2
CRXE2
CSOT2
0
0
MOD2
CLS21
CLS20
FFFFF0A8H
00H
CSIM3
CTXE3
CRXE3
CSOT3
0
0
MOD3
CLS31
CLS30
FFFFF0B8H
00H
Bit Position
Bit Name
Function
7
CTXEn
CSI Transmit Enable
Specifies the transmit enabled state/disabled state.
0: Transmission disabled state
1: Transmission enabled state
When CTXEn = 0, the impedance of both the SOn and SIn pins becomes high.
6
CRXEn
CSI Receive Enable
Specifies the receive enabled/disabled state.
0: Reception disabled state
1: Reception enabled state
When transmission is enabled (CTXEn = 1) and reception is disabled, if a serial clock is
being input, 0 is input to the shift register.
If reception is disabled (CRXEn = 0) while receiving data, the SIOn register’s contents
become undefined.
5
CSOTn
CSI Status Of Transmission
Shows that a transmit operation is in progress.
Set (1):
Transmit start timing (writing to the SIOn register)
Clear (0): Transmit end timing (INTCSIn generated)
If set in the transmission enabled state (CTXEn = 1), when the attempt is made to start
serial data transmission, this is used as a means of judging whether or not writing to
serial I/O shift register n (SIOn) is enabled.
2
MODn
Mode
Specifies the operating mode.
0: MSB first
1: LSB first
Remark
n = 0 to 3
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Bit Position
1, 0
Bit Name
CLSn1,
CLSn0
Function
Clock Source
Specifies the serial clock.
CLSn1
CLSn0
0
0
External clock
0
1
Internal
clock
1
1
Notes 1.
2.
Serial Clock Specification
SCK Pin
Input
Specified by the BPRMm
Note 1
register
Output
0
φ/4Note 2
Output
1
φ/2Note 2
Output
Refer to 10.4 Dedicated Baud Rate Generators 0 to 2 (BRG0 to BRG2)
concerning setting of the BPRMm registers (m = 0 to 2).
φ/4 and φ/2 are divider signals (φ: Internal system clock).
Cautions 1. When setting the CLSn1 and CLSn0 bits, do so in the transmission/reception disabled
(CTXEn bit = CRXEn bit = 0) state. If the CLSn1 and CLSn0 bits are set in a state other
than transmission/reception disabled, subsequent operation may not be normal.
2. If the values set in bits 0 to 2 of these registers are changed while CSIn is transmitting or
receiving, the operation of CSIn is not guaranteed.
Remark
302
n = 0 to 3
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(2) Serial I/O shift registers 0 to 3 (SIO0 to SIO3)
These registers convert 8-bit serial data to 8-bit parallel data and convert 8-bit parallel data to 8-bit serial data.
The actual transmit/receive operation is controlled by reading from or writing to the SIOn registers.
Shift operation is performed when CTXEn = 1 or CRXEn = 1.
These registers can be read/written in 8- or 1-bit units.
7
6
5
4
3
2
1
0
SIO0
SIO07
SIO06
SIO05
SIO04
SIO03
SIO02
SIO01
SIO00
Address
FFFFF08AH
After reset
Undefined
SIO1
SIO17
SIO16
SIO15
SIO14
SIO13
SIO12
SIO11
SIO10
FFFFF09AH
Undefined
SIO2
SIO27
SIO26
SIO25
SIO24
SIO23
SIO22
SIO21
SIO20
FFFFF0AAH
Undefined
SIO3
SIO37
SIO36
SIO35
SIO34
SIO33
SIO32
SIO31
SIO30
FFFFF0BAH
Undefined
Bit Position
7 to 0
Bit Name
SIOn7 to
SIOn0
(n = 0 to 3)
Function
Serial I/O
Data shift in (receiving) or shift out (transmitting) from the MSB or from the LSB.
Caution CSIn operation is not guaranteed if this register is changed during CSIn operation.
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10.3.4 Basic operation
(1) Transfer format
CSIn transmits/receives data with three lines: one clock line and two data lines (n = 0 to 3).
A serial transfer starts when an instruction that writes transfer data to the SIOn register is executed.
In the case of transmission, data is output from the SOn pin at each falling edge of SCKn.
In the case of reception, data is latched through the SIn pin at each rising edge of SCKn.
SCKn stops when the serial clock counter overflows (at the rising edge of the 8th count), and SCKn remains
high until the next data transmission or reception is started. At the same time, a transmission/reception
complete interrupt (INTCSIn) is generated.
Caution Even if CTXEn bit is changed from 0 to 1 after the transmit data is written to the SIOnL
registers, serial transfer will not begin.
SCKn
SIn
1
2
3
4
5
6
7
8
DI7 DI6 DI5 DI4 DI3 DI2 DI1 DI0
SOn
INTCSIn interrupt
Serial transmission/reception completed
Interrupt generation
Transfer start in synchronization with falling of SCKn
Execution of write instruction to SIOn register
Remark
304
n = 0 to 3
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(2) Transmission/reception enabled
CSIn each have only one 8-bit shift register and do not have any buffers, so basically, they conduct
transmission and reception simultaneously (n = 0 to 3).
(a) Transmission/reception enable conditions
Setting of the CSIn transmission and reception enable conditions is accomplished by the CTXEn and
CRXEn bits of the CSIMn registers.
However, it is necessary to set TXE0 bit = RXE0 bit = 0 in the ASIM00 register in the case of CSI0 and to
set TXE1 bit = RXE1 bit = 0 in the ASIM10 register in the case of CSI1.
CTXEn
CRXEn
0
0
Transmission/reception disabled
0
1
Reception enabled
1
0
Transmission enabled
1
1
Transmission/reception enabled
Remark
Remarks
Transmit/Receive Operation
n = 0 to 3
1. If the CTXEn bit = 0, CSIn becomes as follows.
• CSI0, CSI1: The serial output becomes high impedance or UARTn output (TXDn).
• CSI2, CSI3: The serial output becomes high impedance.
If the CTXEn bit = 1, the shift register data is output.
2. If the CRXEn bit = 0, the shift register input becomes 0.
If the CRXEn bit = 1, the serial input is input to the shift register.
3. In order to receive transmit data itself and check if a bus conflict is occurring, set CTXEn
bit = CRXEn bit = 1.
(3) Starting transmit/receive operations
Transmit or receive operations are started by reading/writing the SIOn registers. Transmission/reception start
control is carried out by setting the CTXEn and CRXEn bits of the CSIMn registers as shown below (n = 0 to
3).
CTXEn
CRXEn
0
0
Doesn’t start
0
1
Reads the SIOn register
1
0
Writes to the SIOn register
1
1
Writes to the SIOn register
0
0→1
Remark
Start Condition
Rewrites the CRXEn bit
n = 0 to 3
When the CTXEn bit is 0, the SIOn register is read/write, and even if it is set (1) afterward, transfer does not
start.
Also, when the CTXEn bit is 0, if the CRXEn bit is changed from 0 to 1, the serial clock is generated and
receive operation starts.
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10.3.5 Transmission by CSI0 to CSI3
After changing the settings to enable transmission by clocked serial interface mode register n (CSIMn), writing to
the SIOn registers starts the transmit operation (n = 0 to 3).
(1) Starting the transmit operation
Starting the transmit operation is accomplished by setting the CTXEn bit of clocked serial interface mode
register n (CSIMn) (setting the CRXEn bit to 0), and writing transmit data to shift register n (SIOn).
Note that when the CTXEn bit = 0, the impedance of the SOn pin becomes high.
(2) Transmitting data in synchronization with the serial clock
(a) If the internal clock is selected as the serial clock
When transmission is started, the serial clock is output from the SCKn pin and at the same time, data
from the SIOn register is output sequentially to the SOn pin in synchronization with the fall of the serial
clock.
(b) If an external clock is selected as the serial clock
When transmission is started, data from the SIOn register is output sequentially to the SOn pin in
synchronization with the fall of the serial clock input to the SCKn pin after transmission starts. When
transmission is not started, the shift operation is not performed even if the serial clock is input to the SCKn
pin and the SOn pin’s output level does not change.
Figure 10-7. Timing of 3-Wire Serial I/O Mode (Transmission)
SCKn
1
2
3
4
5
6
7
8
SIn
SOn
DO7 DO6 DO5 DO4 DO3 DO2 DO1 DO0
INTCSIn interrupt
Serial transmission/reception complete
interrupt generation
Transfer start in synchronization with falling of SCKn
Execution of write instruction to SIOn register
Remark
306
n = 0 to 3
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10.3.6 Reception by CSI0 to CSI3
When the reception disabled setting is changed to reception enabled for clocked serial interface mode register n
(CSIMn), and data is read from the SIOn register in the reception enabled state, a receive operation is started (n = 0
to 3).
(1) Starting the receive operation
The following 2 methods can be used to start receive operations.
<1> If the CRXEn bit of the CSIMn register is changed from the reception disabled state (0) to the reception
enabled state (1)
<2> If the CRXEn bit of the CSIMn register reads receive data from shift register n (SIOn) when in the
reception enabled state (1)
When the CRXEn bit of the CSIMn register is set (1), even if 1 is written again, a receive operation is not
started. Note that when the CRXEn bit = 0, the shift register input becomes 0.
(2) Receiving data in synchronization with the serial clock
(a) If the internal clock is selected as the serial clock
When reception is started, the serial clock is output from the SCKn pin and at the same time, data from
the SIn pin is fetched sequentially to the SIOn register in synchronization with the rise of the serial clock.
(b) If an external clock is selected as the serial clock
When reception is started, data from the SIn pin is fetched sequentially to the SIOn register in
synchronization with the rise of the serial clock input to the SCKn pin after reception starts.
When
reception has not started, the shift operation is not performed even if the serial clock is input to the SCKn
pin.
Figure 10-8. Timing of 3-Wire Serial I/O Mode (Reception)
SCKn
SIn
1
2
3
4
5
6
7
8
DI7 DI6 DI5 DI4 DI3 DI2 DI1 DI0
SOn
INTCSIn interrupt
Serial transmission/reception complete
interrupt generation
Transfer start in synchronization with falling of SCKn
Execution of write instruction to SIOn register
Remark
n = 0 to 3
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CHAPTER 10 SERIAL INTERFACE FUNCTION
10.3.7 Transmission and reception by CSI0 to CSI3
If both transmission and reception by clocked serial interface mode register n (CSIMn) are enabled, transmit and
receive operations can be carried out simultaneously (n = 0 to 3).
(1) Starting transmit and receive operations
When both the CTXEn bit and CRXEn bit of clocked serial interface mode register n (CSIMn) are set (1), both
transmit operations and receive operations can be performed simultaneously (transmit/receive operations).
Transmit and receive operations are started when both the CTXEn and CRXEn bits of the CSIMn register are
set to 1, enabling transmission and reception and when transmit data is written to shift register n (SIOn).
If the CRXEn bit of the CSIMn register is 1, even if data is written again, a transmit/receive operation is not
started.
(2) Transmitting data in synchronization with the serial clock
(a) If the internal clock is selected as the serial clock
When transmission/reception is started, the serial clock is output from the SCKn pin and at the same time,
data from the SIOn register is output sequentially to the SOn pin in synchronization with the fall of the
serial clock. Also, data from the SIn pin is fetched sequentially to the SIOn register in synchronization
with the rise of the serial clock.
(b) If an external clock is selected as the serial clock
When transmission/reception is started, data from the SIOn register is output sequentially to the SOn pin
in synchronization with the fall of the serial clock input to the SCKn pin after transmission/reception starts.
Also, data from the SIn pin is fetched sequentially to the SIOn register in synchronization with the rise of
the serial clock. When transmission/reception is not started, even if the serial clock is input to the SCKn
pin, shift operations are not performed and the output level of the SOn pin does not change.
308
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Figure 10-9. Timing of 3-Wire Serial I/O Mode (Transmission/Reception)
SCKn
1
2
3
4
5
6
7
8
SIn
DI7 DI6 DI5 DI4 DI3 DI2 DI1 DI0
SOn
DO7 DO6 DO5 DO4 DO3 DO2 DO1 DO0
INTCSIn interrupt
Serial transmission/reception complete
interrupt generation
Transfer start in synchronization with falling of SCKn
Execution of write instruction to SIOn register
Remark
n = 0 to 3
10.3.8 Example of system configuration
Using 3 signal lines, the serial clock (SCKn), serial input (SIn) and serial output (SOn), transfer of 8-bit data is
carried out. This is effective in cases where connections are made to peripheral I/O with the old type of clocked serial
interface built in, or with a display controller, etc. (n = 0 to 3).
If connecting to multiple devices, a line for handshake is necessary.
Since either the MSB or the LSB can be selected as the communication’s header bit, it is possible to communicate
with various types of device.
Figure 10-10. Example of CSI System Configuration
(3-wire serial I/O
3-wire serial I/O)
Master CPU
Slave CPU
SCK
SCK
SO
SI
SI
SO
Port
Port (interrupt)
Interrupt (port)
Port
Handshake line
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10.4 Dedicated Baud Rate Generators 0 to 2 (BRG0 to BRG2)
10.4.1 Configuration and function
A dedicated baud rate generator output or the internal system clock (φ) can be selected for the serial interface
serial clock for each channel.
The serial clock source is specified with the ASIM00 and ASIM10 registers for UART0 and UART1, and with the
CSIM0 to CSIM3 registers for CSI0 to CSI3.
If the dedicated baud rate generator output is specified, BRG0 to BRG2 are selected as the clock source.
Since 1 serial clock is used in common for 1 channel of transmission and reception, the baud rate is the same for
both transmission and for reception.
Figure 10-11. Block Diagram of Dedicated Baud Rate Generator
BRG0
BRGC0
CSI0
Match
UART0
BRCE0
BPR00 to BPR02
Internal system
clock
(φ )
Clear
TMBRG0
Prescaler
CSI1
BRG1
UART1
CSI2
BRG2
CSI3
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(1) Dedicated baud rate generators 0 to 2 (BRG0 to BRG2)
Dedicated baud rate generator BRGn (n = 0 to 2) consists of a dedicated 8-bit timer (TMBRGn) which
generates the transmission/reception shift clock plus a compare register (BRGCn) and prescaler.
(a) Input clock
Internal system clock (φ) is input to the BRGn.
(b) Value set to BRGn
(i)
UART0, UART1
When the dedicated baud rate generator is specified as the serial source clock with the UART0,
UART1, a sampling rate of ×16 is used, and therefore the baud rate is given by the following
expression.
Baud rate =
φ
[bps]
2 × j × 2k × 16 × 2
φ Internal system clock frequency [Hz]
j: Timer count value = BRGCn register setting value (1 ≤ j ≤ 256
Note
)
k: Prescaler setting value = BPRMn register setting value (k = 0, 1, 2, 3, 4)
Note The j = 256 setting results in writing 0 to the BRGCn register.
(ii) CSI0 to CSI3
If BRG0 to BRG2 are specified as the serial clock source in CSI0 to CSI3, the actual baud rate is
expressed by the following formula.
Baud rate =
φ
[bps]
2 × j × 2k × 2
φ: Internal system clock frequency [Hz]
j: Timer count value = BRGCn register setting value (1 ≤ j ≤ 256
Note
)
k: Prescaler setting value = BPRMn register setting value (k = 0, 1, 2, 3, 4)
Note The j = 256 setting results in writing 0 to the BRGCn register.
BRGn setting values when representative clock frequencies are used are shown below.
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Table 10-2. Baud Rate Generator Setup Values
φ = 33 MHz
Baud Rate [bps]
φ = 25 MHz
φ = 16 MHz
φ = 12.5 MHz
UART0,
UART1
CSI0 to
CSI3
BPR
BRG
Error
BPR
BRG
Error
BPR
BRG
Error
BPR
BRG
Error
110
1,760
—
—
—
4
222
0.02%
4
142
0.03%
3
222
0.02%
150
2,400
4
215
0.07%
4
163
0.15%
3
208
0.16%
3
163
0.15%
300
4,800
3
215
0.07%
3
163
0.15%
2
208
0.16%
2
163
0.15%
600
9,600
2
215
0.07%
2
163
0.15%
1
208
0.16%
1
163
0.15%
1,200
19,200
1
215
0.07%
1
163
0.15%
0
208
0.16%
0
163
0.15%
2,400
38,400
0
215
0.07%
0
163
0.15%
0
104
0.16%
0
81
0.47%
4,800
768,00
0
107
0.39%
0
81
0.47%
0
52
0.16%
0
41
0.76%
9,600
153,600
0
54
0.54%
0
41
0.76%
0
26
0.16%
0
20
1.73%
10,400
166,400
0
50
0.84%
0
38
1.16%
0
24
0.16%
0
19
1.16%
19,200
307,200
0
27
0.54%
0
20
1.73%
0
13
0.16%
0
10
1.73%
0
5
1.73%
6.99%
Note
38,400
614,400
0
13
3.29%
0
10
1.73%
0
7
76,800
1,228,800
0
7
4.09%
0
5
1.73%
—
—
—
0
3
153,600
2,457,600
0
3
11.90%
0
2
—
—
—
—
—
Note
φ = 40 MHz
Baud Rate [bps]
27.2%
Note
φ = 20 MHz
φ = 14.764 MHz
15.2%
Note
—
φ = 12.288 MHz
UART0,
UART1
CSI0 to
CSI3
BPR
BRG
Error
BPR
BRG
Error
BPR
BRG
Error
BPR
BRG
Error
110
1,760
—
—
—
4
178
0.25%
4
131
0.07%
3
218
0.08%
150
2,400
—
—
—
4
130
0.16%
3
192
0.0%
3
160
0.0%
300
4,800
4
130
0.16%
3
130
0.16%
2
192
0.0%
2
160
0.0%
600
9,600
4
65
0.16%
2
130
0.16%
1
192
0.0%
1
160
0.0%
1,200
19,200
3
65
0.16%
1
130
0.16%
0
192
0.0%
0
160
0.0%
2,400
38,400
2
65
0.16%
0
130
0.16%
0
96
0.0%
0
80
0.0%
4,800
76,800
1
65
0.16%
0
65
0.16%
0
48
0.0%
0
40
0.0%
9,600
153,600
0
65
0.16%
0
33
1.36%
0
24
0.0%
0
20
0.0%
10,400
166,400
0
60
0.16%
0
30
0.16%
0
22
0.7%
0
18
2.6%
19,200
307,200
0
32
1.73%
0
16
1.73%
0
12
0.0%
0
10
0.0%
38,400
614,400
0
16
1.73%
0
8
1.73%
0
6
0.0%
0
5
0.0%
76,800
1,228,800
0
8
1.73%
0
4
1.73%
0
3
0.0%
0
3
16.7%
153,600
2,457,600
0
4
1.73%
0
2
1.73%
0
2
25.0%
—
—
Note Cannot be used because the error is too great.
Remark
BPR: Prescaler setting value (Set in the BPRMn register (n = 0 to 2))
BRG: Timer count value (Set in the BRGCn register (n = 0 to 2))
φ:
312
Internal system clock frequency
User’s Manual U12688EJ4V0UM00
Note
—
Note
CHAPTER 10 SERIAL INTERFACE FUNCTION
(c) Baud rate error
The baud rate generator error is calculated as follows:
Actual baud rate (baud rate with error)
− 1 × 100
Desired
baud
rate
(normal
baud
rate)
Error [%] =
(9,520/9,600 – 1) × 100 = –0.833 [%]
Example:
(5,000/4,800 – 1) × 100 = +4.167 [%]
(2) Allowable error range of baud rate
The allowable error range depends on the number of bits of one frame.
The basic limit is ±5% of baud rate error and ±4.5% of sample timing with an accuracy of 16 bits. However,
the practical limit should be ±2.3% of baud rate error, assuming that both the transmission and reception sides
contain an error.
10.4.2 Baud rate generator compare registers 0 to 2 (BRGC0 to BRGC2)
These are 8-bit compare registers used to set the timer count value for the BRG0 to BRG2.
These registers can be read/written in 8- or 1-bit units.
7
6
5
4
3
2
1
0
BRGC0
BRG07
BRG06
BRG05
BRG04
BRG03
BRG02
BRG01
BRG00
Address
FFFFF084H
After reset
Undefined
BRGC1
BRG17
BRG16
BRG15
BRG14
BRG13
BRG12
BRG11
BRG10
FFFFF094H
Undefined
BRGC2
BRG27
BRG26
BRG25
BRG24
BRG23
BRG22
BRG21
BRG20
FFFFF0A4H
Undefined
Caution Do not change the values in the BRGCn (n = 0 to 2) register by software during a
transmit/receive operation, because writing this register causes the internal timer (TMBRGn) to
be cleared.
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CHAPTER 10 SERIAL INTERFACE FUNCTION
10.4.3 Baud rate generator prescaler mode registers 0 to 2 (BPRM0 to BPRM2)
These registers control BRG0 to BRG2 timer count operations and select the count clock.
These registers can be read/written in 8- or 1-bit units.
7
6
5
4
3
2
1
0
BPRM0
BRCE0
0
0
0
0
BPR02
BPR01
BPR00
Address
FFFFF086H
After reset
00H
BPRM1
BRCE1
0
0
0
0
BPR12
BPR11
BPR10
FFFFF096H
00H
BPRM2
BRCE2
0
0
0
0
BPR22
BPR21
BPR20
FFFFF0A6H
00H
Bit Position
7
2 to 0
Bit Name
Function
BRCEn
Baud Rate Generator Count Enable
Controls the BRGn count operations.
0: Stops count operations in the cleared state.
1: Enables the count operation.
BPRn2 to
BPRn0
Baud Rate Generator Prescaler
Specifies the count clock input to the internal timer (TMBRGn).
BPRn2
BPRn1
BPRn0
0
0
0
φ/2 (m = 0)
0
0
1
φ/4 (m = 1)
0
1
0
φ/8 (m = 2)
0
1
1
φ/16 (m = 3)
1
don’t care don’t care
m: Prescaler setting value
Count Clock
φ/32 (m = 4)
φ: Internal system clock frequency
Caution Do not change the count clock during a transmit/receive operation.
Remark
314
n = 0 to 2
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CHAPTER 11 A/D CONVERTER
11.1 Features
{ Analog input: 8 channels
{ 10-bit A/D converter
{ On-chip A/D conversion result register (ADCR0 to ADCR7)
10 bits × 8
{ A/D conversion trigger mode
A/D trigger mode
Timer trigger mode
External trigger mode
{ Successive approximation method
11.2 Configuration
The A/D converter of the V850E/MS1 adopts the successive approximation method, and uses the A/D converter
mode registers (ADM0, ADM1), and ADCRn register to perform A/D conversion operations (n = 0 to 7).
(1) Input circuit
Selects the analog input (ANI0 to ANI7) according to the mode set to the ADM0 and ADM1 registers and
sends the input to the sample and hold register.
(2) Sample and hold circuit
The sample and hold circuit samples each of the analog input signals sequentially sent from the input circuit,
and sends the sample to the voltage comparator. This circuit also holds the sampled analog input signal
voltage during A/D conversion.
(3) Voltage comparator
The voltage comparator compares the analog input signal with the output voltage of the series resistor string.
(4) Series resistor string
The series resistor string is used to generate voltages to match analog inputs.
The series resistor string is connected between the reference voltage pin (AVREF) for the A/D converter and the
GND pin (AVSS) for the A/D converter.
To make 1,024 equal voltage steps between these 2 pins, it is
configured from 1,023 equal resistors and 2 resistors with 1/2 of the resistance value.
The voltage tap of the series resistor string is selected by a tap selector controlled by a successive
approximation register (SAR).
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CHAPTER 11 A/D CONVERTER
(5) Successive approximation register (SAR)
The SAR is a 10-bit register in which is set series resistor string voltage tap data, which have values that
match analog input voltage values, 1 bit at a time beginning with the most significant bit (MSB).
If the data is set in the SAR all the way to the least significant bit (LSB) (A/D conversion completed), the
contents of that SAR (conversion results) are held in the A/D conversion results register (ADCRn).
(6) A/D conversion results register (ADCRn)
The ADCR is a 10-bit register that holds A/D conversion results. Each time A/D conversion is completed,
conversion results are loaded from the successive approximation register (SAR).
RESET input makes its contents undefined.
(7) Controller
Selects the analog input, generates the sample and hold circuit operation timing, and controls the conversion
trigger according to the mode set to the ADM0 and ADM1 registers.
(8) ANI0 to ANI7 pins
8-channel analog input pin for the A/D converter. Inputs the analog signal to be A/D converted.
Caution Make sure that the voltages input to ANI0 through ANI7 do not exceed the rated values. If a
voltage higher than VDD or lower than VSS (even within the range of the absolute maximum
ratings) is input to a channel, the conversion value of the channel is undefined, and the
conversion values of the other channels may also be affected.
(9) AVREF pin
Pin for inputting the reference voltage of the A/D converter. Converts signals input to the ANIn pin to digital
signals based on the voltage applied between AVREF and AVSS.
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CHAPTER 11 A/D CONVERTER
Figure 11-1. A/D Converter Block Diagram
Series resistor string
ANI0
Sample & hold circuit
Input circuit
ANI2
Tap selector
ANI1
ANI3
ANI4
ANI5
ANI6
R/2
R
R/2
Voltage comparator
ANI7
9
AVREF
AVSS
AVDD
0
SAR (10)
10
10
INTAD
9
0
ADCR0
INTCC110
INTCC111
INTCC112
INTCC113
ADCR1
Controller
ADCR2
ADCR3
ADTRG
Noise
Edge
elimination detection
ADCR4
ADCR5
7
0
7
0
ADM0 (8)
ADM1 (8)
8
8
ADCR6
ADCR7
10
Internal bus
Cautions 1. When noise is generated from the analog input pins (ANI0 to ANI7) and the reference voltage
input pin (AVREF), it may cause an illegal conversion result.
In order to avoid this illegal conversion result influencing the system, software processing is
required.
An example of the necessary software processing is as follows.
• Use the average value of the A/D conversion results after obtaining several A/D
conversion results.
• When an exceptional conversion result is obtained after performing A/D conversion
several times consecutively, omit it and use the rest of the conversion results.
• When an A/D conversion result that indicates a system malfunction is obtained, be sure to
recheck the abnormal generation before performing malfunction processing.
2. Make sure not to append the voltage that extends the value between AV SS to AVREF to the
pins used as A/D converter input pins.
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CHAPTER 11 A/D CONVERTER
11.3 Control Registers
(1) A/D converter mode register 0 (ADM0)
The ADM0 register is an 8-bit register that executes the selection of the analog input pin, specification of
operation mode, and conversion operations.
This register can be read/written in 8- or 1-bit units, However, when the data is written to the ADM0 register
during A/D conversion operations, the conversion operation is initialized and conversion is executed from the
beginning. Bit 6 cannot be written and writing executed is ignored.
ADM0
7
6
5
4
3
2
1
0
CE
CS
BS
MS
0
ANIS2
ANIS1
ANIS0
Bit Position
Bit Name
CE
Convert Enable
Enables or disables A/D conversion operation.
0: Disabled
1: Enabled
6
CS
Converter Status
Indicates the status of A/D converter. This bit is read only.
0: Stops
1: Operates
5
BS
Buffer Select
Specifies buffer mode in the select mode.
0: 1-buffer mode
1: 4-buffer mode
4
MS
Mode Select
Specifies operation mode of A/D converter.
0: Scan mode
1: Select mode
ANIS2 to
ANIS0
Analog Input Select
Specifies analog input pin to A/D convert.
ANIS2 ANIS1 ANIS0
Select Mode
A/D trigger
mode
318
After reset
00H
Function
7
2 to 0
Address
FFFFF380H
Timer trigger
mode
Scan Mode
A/D trigger
mode
Timer trigger
Note
mode
0
0
0
ANI0
ANI0
ANI0
1
0
0
1
ANI1
ANI1
ANI0, ANI1
2
0
1
0
ANI2
ANI2
ANI0 to ANI2
3
0
1
1
ANI3
ANI3
ANI0 to ANI3
4
1
0
0
ANI4
Setting
prohibited
ANI0 to ANI4
4 + ANI4
1
0
1
ANI5
Setting
prohibited
ANI0 to ANI5
4 + ANI4,
ANI5
1
1
0
ANI6
Setting
prohibited
ANI0 to ANI6
4 + ANI4 to
ANI6
1
1
1
ANI7
Setting
prohibited
ANI0 to ANI7
4 + ANI4 to
ANI7
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CHAPTER 11 A/D CONVERTER
Note In the timer trigger mode (4-trigger mode) during the scan mode, because the scanning sequence of the
ANI0 to ANI3 pins is specified by the sequence in which the match signals are generated from the
compare register, the number of trigger inputs should be specified instead of a certain analog input pin.
When ANIS2 is set to 1, the scan mode shifts to A/D trigger mode after counting the trigger four times,
and then starts converting.
Cautions 1.
When the CE bit is 1 in the timer trigger mode and external trigger mode, the trigger
signal standby state is set. To clear the CE bit, write 0 or reset.
In the A/D trigger mode, the conversion trigger is set by writing 1 to the CE bit. After the
operation, when the mode is changed to the timer trigger mode or external trigger mode
without clearing the CE bit, the trigger input standby state is set immediately after the
change.
2.
It takes 3 clocks for CS bit to become 1 after A/D conversion starts.
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CHAPTER 11 A/D CONVERTER
(2) A/D converter mode register 1 (ADM1)
The ADM1 register is an 8-bit register that specifies the conversion operation time and trigger mode.
This register can be read/written in 8- or 1-bit units. However, when the data is written to the ADM1 register
during an A/D conversion operation, the conversion operation is initialized and conversion is executed from the
beginning again.
ADM1
Bit Position
6 to 4
7
6
5
4
3
2
1
0
0
TRG2
TRG1
TRG0
0
FR2
FR1
FR0
Bit Name
TRG2 to
TRG0
Address
FFFFF382H
After reset
07H
Function
Trigger Mode
Specifies trigger mode.
TRG2
TRG1
TRG0
0
0
don’t
care
0
1
0
Timer trigger mode (1-trigger mode)
0
1
1
Timer trigger mode (4-trigger mode)
1
1
0
External trigger mode
Other than above
Trigger Mode
A/D trigger mode
Setting prohibited
Remark The valid edge of the external input signal during the external trigger mode is
specified by bits 7 and 6 (ES531, ES530) of the external interrupt mode
register (INTM6). For details, refer to 7.3.8 (1) External interrupt mode
registers 1 to 6 (INTM1 to INTM6).
2 to 0
FR2 to
FR0
Frequency
Specifies conversion operation time. These bits control the conversion time to be same
value irrespective of oscillation frequency.
FR2
FR1
FR0
Number of
Conversion
Clocks
Conversion Operation Time (µs)
Note
φ=
40 MHz
φ=
33 MHz
φ=
25 MHz
φ=
16 MHz
0
0
0
48 clocks
—
—
—
—
0
0
1
72 clocks
—
—
—
—
0
1
0
96 clocks
—
—
—
6.00
0
1
1
120 clocks
—
—
—
7.50
1
0
0
168 clocks
—
5.09
6.72
—
1
0
1
192 clocks
—
5.82
7.68
—
1
1
0
240 clocks
6.00
7.27
9.60
—
1
1
1
336 clocks
8.40
—
—
—
Note Figures under Conversion Operation Time are target values.
Remark φ:
Internal system clock frequency
—: Setting prohibited
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CHAPTER 11 A/D CONVERTER
(3) A/D conversion result registers (ADCR0 to ADCR7, ADCR0H to ADCR7H)
The ADCRn register is a 10-bit register holding the A/D conversion results. It is provided with eight 10-bit
registers (n = 0 to 7).
This register is read-only, in 16- or 8-bit units.
During 16-bit access to this register, the ADCRn register is specified, and during higher 8-bit access, the
ADCRnH register is specified.
When reading the 10-bit data of A/D conversion results from the ADCRn register, only the lower 10 bits are
valid and the higher 6 bits are always read as 0.
ADCRn
15
14
13
12
11
10
8
0
0
0
0
0
0 ADn9 ADn8 ADn7 ADn6 ADn5 ADn4 ADn3 ADn2 ADn1 ADn0
9
7
7
ADCRnH
Remark
6
6
5
5
4
4
3
3
2
2
1
1
0
Address
FFFFF390H to
FFFFF3ACH
After reset
Undefined
FFFFF392H to
FFFFF3AEH
Undefined
0
ADn9 ADn8 ADn7 ADn6 ADn5 ADn4 ADn3 ADn2
n = 0 to 7
The correspondence between each analog input pin and the ADCRn register (except the 4-buffer mode) is
shown below.
Analog Input Pin
ADCRn Register
ANI0
ADCR0, ADCR0H
ANI1
ADCR1, ADCR1H
ANI2
ADCR2, ADCR2H
ANI3
ADCR3, ADCR3H
ANI4
ADCR4, ADCR4H
ANI5
ADCR5, ADCR5H
ANI6
ADCR6, ADCR6H
ANI7
ADCR7, ADCR7H
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CHAPTER 11 A/D CONVERTER
Figure 11-2 shows the relationship between the analog input voltage and the A/D conversion results.
Figure 11-2. Relationship Between Analog Input Voltage and A/D Conversion Results
1,023
1,022
A/D conversion
1,021
results (ADCRn)
3
2
1
0
1
1
3
2
5
3
2,048 1,024 2,048 1,024 2,048 1,024
2,043 1,022 2,045 1,023 2,047 1
2,048 1,024 2,048 1,024 2,048
Input voltage/AVREF
Remark
322
n = 0 to 7
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CHAPTER 11 A/D CONVERTER
11.4 A/D Converter Operation
11.4.1 Basic operation of A/D converter
A/D conversion is executed in the following order.
(1) The selection of the analog input and specification of the operation mode, trigger mode, etc. should be set in
the ADM0 and ADM1 registers
Note 1
.
When the CE bit of the ADM0 register is set (1), A/D conversion starts in the A/D trigger mode. In the timer
trigger mode and external trigger mode, the trigger standby state
Note 2
is set.
(2) The voltage generated from the voltage tap of the series resistor string and analog input are compared by the
comparator.
(3) When the comparison of the 10 bits ends, the conversion results are stored in the ADCRn register. When A/D
conversion is performed for the specified number of times, the A/D conversion end interrupt (INTAD) is
generated (n = 0 to 7).
Notes 1. When the ADM0 and ADM1 registers are changed during an A/D conversion operation, the A/D
conversion operation before the change is stopped and the conversion results are not stored in the
ADCRn register.
2. In the timer trigger mode and external trigger mode, if the CE bit of the ADM0 register is set to 1, the
mode changes to the trigger standby state. The A/D conversion operation is started by the trigger
signal, and the trigger standby state is returned when the A/D conversion operation ends.
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CHAPTER 11 A/D CONVERTER
11.4.2 Operation mode and trigger mode
The A/D converter can specify various conversion operations by specifying the operation mode and trigger mode.
The operation mode and trigger mode are set by the ADM0 and ADM1 registers.
The following shows the relationship between the operation mode and trigger mode.
Trigger Mode
Operation Mode
Setting Value
ADM0 register
A/D trigger
Select
Timer trigger
1 trigger
Select
xx010xxxB
000x0xxxB
4 buffers
xx110xxxB
000x0xxxB
xxx00xxxB
000x0xxxB
1 buffer
xx010xxxB
00100xxxB
4 buffers
xx110xxxB
00100xxxB
xxx00xxxB
00100xxxB
1 buffer
xx010xxxB
00110xxxB
4 buffers
xx110xxxB
00110xxxB
xxx00xxxB
00110xxxB
1 buffer
xx010xxxB
01100xxxB
4 buffers
xx110xxxB
01100xxxB
xxx00xxxB
01100xxxB
Scan
4 triggers
Select
Scan
External trigger
Select
Scan
ADM1 register
1 buffer
Scan
Analog Input
ANI0 to ANI7
ANI0 to ANI3
(1) Trigger mode
There are three types of trigger modes that serve as the start timing of the A/D conversion processing: A/D
trigger mode, timer trigger mode, and external trigger mode. The ANI0 to ANI3 pins are able to specify all of
these modes, but pins ANI4 to ANI7 can only specify the A/D trigger mode. The timer trigger mode consists of
the 1-trigger mode and 4-trigger mode as the sub-trigger mode. These trigger modes are set by the ADM1
register.
(a) A/D trigger mode
Generates the conversion timing of the analog input for the ANI0 to ANI7 pins inside the A/D converter
unit. ANI4 to ANI7 pins are always set in this mode.
(b) Timer trigger mode
Specifies the conversion timing of the analog input set for the ANI0 to ANI3 pins using the values set to
the TM11 compare register. This mode can only be specified by pins ANI0 to ANI3.
This register creates the analog input conversion timing by generating the match interrupts of the four
capture/compare registers (CC110 to CC113) connected to the 16-bit TM11.
There are two types of sub-trigger modes: 1-trigger mode and 4-trigger mode.
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CHAPTER 11 A/D CONVERTER
• 1-trigger mode
Mode that uses one match interrupt from timer 11 as the A/D conversion start timing.
• 4-trigger mode
Mode that uses four match interrupts from timer 11 as the A/D conversion start timing.
(c) External trigger mode
Mode that specifies the conversion timing of the analog input to the ANI0 to ANI3 pins using the ADTRG
pin. This mode can be specified only with ANI0 to ANI3 pins.
(2) Operation mode
There are two types of operation modes that set the ANI0 to ANI7 pins: select mode and scan mode. The
select mode has sub-modes including the 1-buffer mode and 4-buffer mode. These modes are set by the
ADM0 register.
(a) Select mode
One analog input specified by the ADM0 register is A/D converted. The conversion results are stored in
the ADCRn register corresponding to the analog input (ANIn). For this mode, the 1-buffer mode and 4buffer mode are provided for storing the A/D conversion results (n = 0 to 7).
• 1-buffer mode
One analog input specified by the ADM0 register is A/D converted. The conversion results are stored
in the ADCRn register corresponding to the analog input (ANIn). The ANIn and ADCRn registers
correspond one to one, and an A/D conversion end interrupt (INTAD) is generated each time one A/D
conversion ends.
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CHAPTER 11 A/D CONVERTER
Figure 11-3. Select Mode Operation Timing: 1-Buffer Mode (ANI1)
ANI1
(input)
Data 4
Data 1
A/D
conversion
Data 1
(ANI1)
Data 2
Data 2
(ANI1)
Data 1
(ANI1)
ADCR1
register
Data 5
Data 3
Data 3
(ANI1)
Data 2
(ANI1)
Data 6
Data 4
(ANI1)
Data 5
(ANI1)
Data 3
(ANI1)
Data 7
Data 6
(ANI1)
Data 7
(ANI1)
Data 4
(ANI1)
Data 6
(ANI1)
INTAD
interrupt
CE bit set
CE bit set
CE bit set
CE bit set
Conversion start
(ADM0 register setting)
Analog input
ADCRn register
ANI0
ADCR0
ANI1
ADCR1
ANI2
ADCR2
ANI3
326
CE bit set
Conversion start
(ADM0 register setting)
A/D converter
ADCR3
ANI4
ADCR4
ANI5
ADCR5
ANI6
ADCR6
ANI7
ADCR7
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CHAPTER 11 A/D CONVERTER
• 4-buffer mode
One analog input is A/D converted four times and the results are stored in the ADCR0 to ADCR3
registers. The A/D conversion end interrupt (INTAD) is generated when the four A/D conversions end.
Figure 11-4. Select Mode Operation Timing: 4-Buffer Mode (ANI6)
ANI6
(input)
A/D
conversion
Data 4
Data 1
Data 2
Data 3
Data 1
(ANI6)
Data 2
(ANI6)
Data 3
(ANI6)
Data 4
(ANI6)
Data 1
(ANI6)
ADCR0
Data 2
(ANI6)
ADCR1
Data 3
(ANI6)
ADCR2
ADCRn
register
Data 5
Data 6
Data 5
(ANI6)
Data 6
(ANI6)
Data 4
(ANI6)
ADCR3
Data 7
Data 7
(ANI6)
Data 6
(ANI6)
ADCR0
INTAD
interrupt
Conversion start
(ADM0 register setting)
Conversion start
(ADM0 register setting)
Analog input
ADCRn register
ANI0
ADCR0
ANI1
ADCR1
ANI2
ADCR2
ANI3
A/D converter
ADCR3
ANI4
ADCR4
ANI5
ADCR5
ANI6
ADCR6
ANI7
ADCR7
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CHAPTER 11 A/D CONVERTER
(b) Scan mode
Selects the analog inputs specified by the ADM0 register sequentially from the ANI0 pin, and A/D
conversion is executed. The A/D conversion results are stored in the ADCRn register corresponding to
the analog input.
When the conversion of the specified analog input ends, the INTAD interrupt is
generated.
Figure 11-5. Scan Mode Operation Timing: 4-Channel Scan (ANI0 to ANI3)
ANI0
(input)
Data 1
Data 5
Data 6
ANI1
(input)
Data 7
Data 2
ANI2
(input)
Data 3
ANI3
(input)
A/D
conversion
Data 4
Data 1
(ANI0)
ADCRn
register
Data 2
(ANI1)
Data 3
(ANI2)
Data 4
(ANI3)
Data 1
(ANI0)
ADCR0
Data 2
(ANI1)
ADCR1
Data 3
(ANI2)
ADCR2
Data 5
(ANI0)
Data 6
(ANI0)
Data 4
(ANI3)
ADCR3
Data 7
(ANI1)
Data 6
(ANI0)
ADCR0
INTAD
interrupt
Conversion start
(ADM0 register setting)
Conversion start
(ADM0 register setting)
Analog input
ANI0
ADCR0
ANI1
ADCR1
ANI2
ADCR2
ANI3
328
ADCRn register
A/D converter
ADCR3
ANI4
ADCR4
ANI5
ADCR5
ANI6
ADCR6
ANI7
ADCR7
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CHAPTER 11 A/D CONVERTER
11.5 Operation in A/D Trigger Mode
When the CE bit of the ADM0 register is set to 1, A/D conversion starts.
11.5.1 Select mode operations
The analog input specified by the ADM0 register is A/D converted. The conversion results are stored in the
ADCRn register corresponding to the analog input. For the select mode, the 1-buffer mode and 4-buffer mode are
supported according to the storing method of the A/D conversion results (n = 0 to 7).
(1) 1-buffer mode (A/D trigger select: 1-buffer)
One analog input is A/D converted once. The conversion results are stored in one ADCRn register. The
analog input and ADCRn register correspond one to one.
Each time an A/D conversion is executed, an INTAD interrupt is generated and the AD conversion terminates.
Analog Input
ANIn
A/D Conversion Results Register
(n = 0 to 7)
ADCRn
If 1 is written to the CE bit of the ADM0 register, A/D conversion can be restarted. This is most appropriate for
applications in which the results of each first time A/D conversion are read.
Figure 11-6. Example of 1-Buffer Mode (A/D Trigger Select 1-Buffer) Operation
ADM0
ANI0
ADCR0
ANI1
ADCR1
ANI2
ADCR2
ANI3
A/D converter
ADCR3
ANI4
ADCR4
ANI5
ADCR5
ANI6
ADCR6
ANI7
ADCR7
(1)
CE bit of ADM0 is set to 1 (enable)
(2)
ANI2 A/D conversion
(3)
Conversion result is stored in ADCR2
(4)
INTAD interrupt generation
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CHAPTER 11 A/D CONVERTER
(2) 4-buffer mode (A/D trigger select: 4-buffer)
One analog input is A/D converted four times and the results are stored in the four ADCR0 to ADCR3
registers. When four A/D conversions end, an INTAD interrupt is generated and A/D conversion terminates.
Analog Input
A/D Conversion Result Register
ANIn
ADCR0
ANIn
ADCR1
ANIn
ADCR2
ANIn
ADCR3
(n = 0 to 7)
If 1 is written in the CE bit of the ADM0 register, A/D conversion can be restarted.
This is most appropriate for applications that determine the average A/D conversion results.
Figure 11-7. Example of 4-Buffer Mode (A/D Trigger Select 4-Buffer) Operation
ADM0
(×4)
ANI0
ADCR0
ANI1
ADCR1
ANI2
ADCR2
ANI3
ANI4
330
A/D converter
ADCR3
ADCR4
(×4)
ANI5
ADCR5
ANI6
ADCR6
ANI7
ADCR7
(1)
CE bit of ADM0 is set to 1 (enable)
(6)
ANI4 A/D conversion
(2)
ANI4 A/D conversion
(7)
Conversion result is stored in ADCR2
(3)
Conversion result is stored in ADCR0
(8)
ANI4 A/D conversion
(4)
ANI4 A/D conversion
(9)
Conversion result is stored in ADCR3
(5)
Conversion result is stored in ADCR1
(10) INTAD interrupt generation
User’s Manual U12688EJ4V0UM00
CHAPTER 11 A/D CONVERTER
11.5.2 Scan mode operations
The analog inputs specified by the ADM0 register are selected sequentially from the ANI0 pin, and A/D conversion
is executed. The A/D conversion results are stored in the ADCRn register corresponding to the analog input (n = 0 to
7).
When the conversion of all the specified analog input ends, the INTAD interrupt is generated, and A/D conversion
terminates.
Analog Input
A/D Conversion Result Register
ANIn
ADCR0
|
|
Note
ANIn
(n = 0 to 7)
ADCRn
Note Set in the ANIS0 to ANIS2 bits of the ADM0 register.
If 1 is written in the CE bit of the ADM0 register, A/D conversion can be restarted.
This is most appropriate for applications that are constantly monitoring multiple analog inputs.
Figure 11-8. Example of Scan Mode (A/D Trigger Scan) Operation
ADM0
ANI0
ADCR0
ANI1
ADCR1
ANI2
ADCR2
ANI3
A/D converter
ADCR3
ANI4
ADCR4
ANI5
ADCR5
ANI6
ADCR6
ANI7
ADCR7
(1)
CE bit of ADM0 is set to 1 (enable)
(8)
ANI3 A/D conversion
(2)
ANI0 A/D conversion
(9)
Conversion result is stored in ADCR3
(3)
Conversion result is stored in ADCR0
(10) ANI4 A/D conversion
(4)
ANI1 A/D conversion
(11) Conversion result is stored in ADCR4
(5)
Conversion result is stored in ADCR1
(12) ANI5 A/D conversion
(6)
ANI2 A/D conversion
(13) Conversion result is stored in ADCR5
(7)
Conversion result is stored in ADCR2
(14) INTAD interrupt generation
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CHAPTER 11 A/D CONVERTER
11.6 Operation in Timer Trigger Mode
The A/D converter is the match interrupt signal of the TM11 compare register, and can set conversion timings to a
maximum of four channel analog inputs (ANI0 to ANI3).
TM11 and four capture/compare registers (CC110 to CC113) are used for the timer for specifying the analog
conversion trigger.
The following two modes are provided according to the value set in the TUM11 register.
(1) 1-shot mode
To use the 1-shot mode, the OST bit of the TUM11 register should be set to 1 (1-shot mode).
When the A/D conversion period is longer than the TM11 period, the TM11 generates an overflow, holds
0000H, and stops. Thereafter, TM11 does not output the match interrupt signal (A/D conversion trigger) of the
compare register, and the A/D converter also enters the A/D conversion standby state. The TM11 count
operation restarts when the valid edge of the TCLR11 pin input is detected or when 1 is written to the CE11 bit
of the TMC11 register.
(2) Loop mode
To use the loop mode, the OST bit of the TUM11 register should be set to 0 (normal mode).
When the TM11 generates an overflow, the TM11 starts counting from 0000H again, and the match interrupt
signal (A/D conversion trigger) of the compare register is repeatedly output and A/D conversion is also
repeated.
332
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CHAPTER 11 A/D CONVERTER
11.6.1 Select mode operations
One analog input (ANI0 to ANI3) specified by the ADM0 register is A/D converted. The conversion results are
stored in the ADCRn register corresponding to the analog input. For the select mode, the 1-buffer mode and 4-buffer
mode are provided according to the storing method of the A/D conversion results (n = 0 to 3).
(1) 1-buffer mode operations (Timer trigger select: 1-buffer)
One analog input is A/D converted once and the conversion results are stored in one ADCRn register.
There are two modes in 1-buffer modes, the 1-trigger mode and 4-trigger mode, according to the number of
triggers.
(a) 1-trigger mode (Timer trigger select: 1-buffer, 1-trigger)
One analog input is A/D converted once using the trigger of the match interrupt signal (INTCC110) and
the results are stored in one ADCRn register.
An INTAD interrupt is generated for each A/D conversion and A/D conversion terminates.
Trigger
INTCC110 interrupt
Analog Input
ANIn
A/D Conversion Result Register
(n = 0 to 3)
ADCRn
When the TM11 is set to the 1-shot mode, A/D conversion ends after one conversion. To restart A/D
conversion, input the valid edge to the TCLR11 pin or write 1 to the CE11 bit of the TMC11 register.
When set to the loop mode, unless the CE bit of the ADM0 register is set to 0, A/D conversion is repeated
each time the match interrupt is generated.
Figure 11-9. Example of 1-Trigger Mode (Timer Trigger Select 1-Buffer 1-Trigger) Operation
INTCC110
ANI0
ADCR0
ANI1
ADCR1
ANI2
ADCR2
ANI3
A/D converter
ADCR3
ADCR4
ADCR5
ADCR6
ADCR7
(1)
CE bit of ADM0 is set to 1 (enable)
(2)
CC110 compare generation
(3)
ANI1 A/D conversion
(4)
Conversion result is stored in ADCR1
(5)
INTAD interrupt generation
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CHAPTER 11 A/D CONVERTER
(b) 4-trigger mode (Timer trigger select: 1-buffer, 4-trigger)
One analog input is A/D converted four times using four match interrupt signals (INTCC110 to INTCC113)
as triggers and the results are stored in one ADCRn register. The INTAD interrupt is generated with each
A/D conversion, and the CS bit of the ADM0 register is reset (0). The results of one A/D conversion are
held by the ADCRn register until the next A/D conversion ends. Perform transmission of the conversion
results to the memory and other operations using the INTAD interrupt after each A/D conversion ends.
Trigger
Analog Input
A/D Conversion Result Register
INTCC110 interrupt
ANIn
ADCRn
INTCC111 interrupt
ANIn
ADCRn
INTCC112 interrupt
ANIn
ADCRn
INTCC113 interrupt
ANIn
ADCRn
(n = 0 to 3)
When the TM11 is set to the 1-shot mode, A/D conversion ends after four conversions. To restart A/D
conversion, input the valid edge to the TCLR11 pin or write 1 to the CE11 bit of the TMC11 register to
restart the TM11. When the first match interrupt after TM11 is restarted is generated, the CS bit is set (1)
and A/D conversion is started.
When set to the loop mode, unless the CE bit of the ADM0 register is set to 0, A/D conversion is repeated
each time the match interrupt is generated.
The match interrupts (INTCC110 to INTCC113) can be generated in any order. The same trigger, even
when it enters several times consecutively, is accepted as a trigger each time.
Figure 11-10. Example of 4-Trigger Mode (Timer Trigger Select 1-Buffer 4-Trigger) Operation
No particular
order
ANI0
ADCR0
ANI1
ADCR1
INTCC110
ANI2
INTCC111
ANI3
(×4)
(×4)
A/D converter
ADCR2
ADCR3
INTCC112
ADCR4
INTCC113
ADCR5
ADCR6
ADCR7
(1)
334
CE bit of ADM0 is set to 1 (enable)
(10) CC113 compare generation (random)
(2)
CC112 compare generation (random)
(11) ANI2 A/D conversion
(3)
ANI2 A/D conversion
(12) Conversion result is stored in ADCR2
(4)
Conversion result is stored in ADCR2
(13) INTAD interrupt generation
(5)
INTAD interrupt generation
(14) CC110 compare generation (random)
(6)
CC111 compare generation (random)
(15) ANI2 A/D conversion
(7)
ANI2 A/D conversion
(16) Conversion result is stored in ADCR2
(8)
Conversion result is stored in ADCR2
(17) INTAD interrupt generation
(9)
INTAD interrupt generation
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CHAPTER 11 A/D CONVERTER
(2) 4-buffer mode operations (Timer trigger select: 4-buffer)
One analog input is A/D converted four times, and the results are stored in the ADCR0 to ADCR3 registers.
There are two 4-buffer modes, 1-trigger mode and 4-trigger mode, according to the number of triggers.
This mode is suitable for applications that calculate the average of the A/D conversion result.
(a) 1-trigger mode
One analog input is A/D converted four times using the match interrupt signal (INTCC110) as a trigger,
and the results are stored in the ADCR0 to ADCR3 registers.
An INTAD interrupt is generated when the four A/D conversions end and A/D conversion terminates.
Trigger
Analog Input
A/D Conversion Result Register
INTCC110 interrupt
ANIn
ADCR0
INTCC110 interrupt
ANIn
ADCR1
INTCC110 interrupt
ANIn
ADCR2
INTCC110 interrupt
ANIn
ADCR3
(n = 0 to 3)
When the TM11 is set to the 1-shot mode, and less than four match interrupts are generated, if the CE bit
is set to 0, the INTAD interrupt is not generated and the standby state is set.
Figure 11-11. Example of 1-Trigger Mode (Timer Trigger Select 4-Buffer 1-Trigger) Operation
ANI0
ADCR0
ANI1
INTCC110
(×4)
ADCR1
ANI2
ADCR2
(×4)
ANI3
A/D converter
ADCR3
ADCR4
ADCR5
ADCR6
ADCR7
(1)
CE bit of ADM0 is set to 1 (enable)
(8)
CC110 compare generation
(2)
CC110 compare generation
(9)
ANI2 A/D conversion
(3)
ANI2 A/D conversion
(10) Conversion result is stored in ADCR2
(4)
Conversion result is stored in ADCR0
(11) CC110 compare generation
(5)
CC110 compare generation
(12) ANI2 A/D conversion
(6)
ANI2 A/D conversion
(13) Conversion result is stored in ADCR3
(7)
Conversion result is stored in ADCR1
(14) INTAD interrupt generation
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CHAPTER 11 A/D CONVERTER
(b) 4-trigger mode
One analog input is A/D converted four times using four match interrupt signals (INTCC110 to INTCC113)
as triggers and the results are stored in four ADCRn registers. The INTAD interrupt is generated when
the four A/D conversions end, the CS bit is reset (0), and A/D conversion terminates.
Trigger
Analog Input
A/D Conversion Result Register
INTCC110 interrupt
ANIn
ADCR0
INTCC111 interrupt
ANIn
ADCR1
INTCC112 interrupt
ANIn
ADCR2
INTCC113 interrupt
ANIn
ADCR3
(n = 0 to 3)
When the TM11 is set to the 1-shot mode, A/D conversion ends after four conversions. To restart A/D
conversion, input the valid edge to the TCLR11 pin or write 1 to the CE11 bit of the TMC11 register to
restart the TM11. When the first match interrupt after TM11 is restarted is generated, the CS bit is set (1)
and A/D conversion is started.
When set to the loop mode, unless the CE bit is set to 0, A/D conversion is repeated each time the match
interrupt is generated.
Whichever the order of occurrence of match interrupts (INTCC110 to INTCC113), there is no problem,
and the conversion results are stored in the ADCRn register corresponding to the input trigger. Also,
even in cases where the same trigger is input continuously, it is received as a trigger.
Figure 11-12. Example of 4-Trigger Mode (Timer Trigger Select 4-Buffer 4-Trigger) Operation
No particular
order
ANI0
No particular
order
ADCR0
ANI1
ADCR1
INTCC110
ANI2
ADCR2
INTCC111
ANI3
A/D converter
ADCR3
INTCC112
ADCR4
INTCC113
ADCR5
ADCR6
ADCR7
336
(1)
CE bit of ADM0 is set to 1 (enable)
(8)
CC112 compare generation (random)
(2)
CC111 compare generation (random)
(9)
ANI2 A/D conversion
(3)
ANI2 A/D conversion
(10) Conversion result is stored in ADCR2
(4)
Conversion result is stored in ADCR1
(11) CC110 compare generation (random)
(5)
CC113 compare generation (random)
(12) ANI2 A/D conversion
(6)
ANI2 A/D conversion
(13) Conversion result is stored in ADCR0
(7)
Conversion result is stored in ADCR3
(14) INTAD interrupt generation
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CHAPTER 11 A/D CONVERTER
11.6.2 Scan mode operations
The analog inputs specified by the ADM0 register are selected sequentially from the ANI0 pin and A/D converted
for the specified number of times using the match interrupt signal as a trigger.
In the conversion operation, first the analog input lower channels (ANI0 to ANI3) are A/D converted for the
specified number of times. In the ADM0 register, if the lower channels (ANI0 to ANI3) of the analog input are set so
that they are scanned, and when the set number of A/D conversions ends, the INTAD interrupt is generated and A/D
conversion ends.
When the higher channels (ANI4 to ANI7) of the analog input are set so that they are scanned in the ADM0
register, after the conversion of the lower channel ends, the mode is shifted to the A/D trigger mode, and the
remaining A/D conversions are executed.
The conversion results are stored in the ADCRn register corresponding to the analog input. When the conversion
of all the specified analog inputs has ended, the INTAD interrupt is generated and A/D conversion terminates (n = 0 to
7).
There are two scan modes, 1-trigger mode and 4-trigger mode, according to the number of triggers.
This is most appropriate for applications that are constantly monitoring multiple analog inputs.
(1) 1-trigger mode (Timer trigger scan: 1-trigger)
The analog inputs are A/D converted for the specified number of times using the match interrupt signal
(INTCC110) as a trigger.
The analog input and ADCRn register correspond one to one.
When all the A/D conversions specified have ended, the INTAD interrupt is generated and A/D conversion
ends.
Trigger
Analog Input
A/D Conversion Result Register
INTCC110 interrupt
ANI0
ADCR0
INTCC110 interrupt
ANI1
ADCR1
INTCC110 interrupt
ANI2
ADCR2
INTCC110 interrupt
ANI3
ADCR3
(A/D trigger mode)
ANI4
ADCR4
ANI5
ADCR5
ANI6
ADCR6
ANI7
ADCR7
When the match interrupt is generated after all the specified A/D conversions end, A/D conversion is restarted.
When the TM11 is set to the 1-shot mode, and less than a specified number of match interrupts are generated,
if the CE bit is set to 0, the INTAD interrupt is not generated and the standby state is set.
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CHAPTER 11 A/D CONVERTER
Figure 11-13. Example of 1-Trigger Mode (Timer Trigger Scan 1-Trigger) Operation
(a) Setting when scanning ANI0 to ANI3
INTCC110
ANI0
ADCR0
ANI1
ADCR1
ANI2
ADCR2
ANI3
(1)
A/D converter
ADCR3
ANI4
ADCR4
ANI5
ADCR5
ANI6
ADCR6
ANI7
ADCR7
CE bit of ADM0 is set to 1 (enable)
(8)
CC110 compare generation
ANI2 A/D conversion
(2)
CC110 compare generation
(9)
(3)
ANI0 A/D conversion
(10) Conversion result is stored in ADCR2
(4)
Conversion result is stored in ADCR0
(11) CC110 compare generation
(5)
CC110 compare generation
(12) ANI3 A/D conversion
(6)
ANI1 A/D conversion
(13) Conversion result is stored in ADCR3
(7)
Conversion result is stored in ADCR1
(14) INTAD interrupt generation
Caution The analog input enclosed in the broken lines cannot be used with INTCC11n as the trigger (n
= 0 to 3). When a setting is made to scan ANI0 to ANI7, ANI4 to ANI7 are converted in A/D
trigger mode (see (b)).
(b) Setting when scanning ANI0 to ANI7
INTCC110
ANI0
ADCR0
ANI1
ADCR1
ANI2
ADCR2
ANI3
A/D converter
ANI4
ADCR4
ANI5
ADCR5
ANI6
ADCR6
ANI7
ADCR7
(1) to (13) Same as (a)
338
ADCR3
(18) ANI6 A/D conversion
(14) ANI4 A/D conversion
(19) Conversion result is stored in ADCR6
(15) Conversion result is stored in ADCR4
(20) ANI7 A/D conversion
(16) ANI5 A/D conversion
(21) Conversion result is stored in ADCR7
(17) Conversion result is stored in ADCR5
(22) INTAD interrupt generation
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CHAPTER 11 A/D CONVERTER
(2) 4-trigger mode
The analog inputs are A/D converted for the number of times specified using the match interrupt signal
(INTCC110 to INTCC113) as a trigger.
The analog input and ADCRn register correspond one to one.
When all the A/D conversions specified have ended, the INTAD interrupt is generated and A/D conversion
ends.
Trigger
Analog Input
A/D Conversion Result Register
INTCC110 interrupt
ANI0
ADCR0
INTCC111 interrupt
ANI1
ADCR1
INTCC112 interrupt
ANI2
ADCR2
INTCC113 interrupt
ANI3
ADCR3
(A/D trigger mode)
ANI4
ADCR4
ANI5
ADCR5
ANI6
ADCR6
ANI7
ADCR7
To restart conversion when TM11 is set to the 1-shot mode, restart TM11. If set to the loop mode and the CE
bit is 1, A/D conversion is restarted when a match interrupt is generated after conversion ends.
The match interrupt can be generated in any order. However, because the trigger signal and the analog input
correspond one to one, the scanning sequence is determined according to the order in which the match
signals of the compare register are generated.
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CHAPTER 11 A/D CONVERTER
Figure 11-14. Example of 4-Trigger Mode (Timer Trigger Scan 4-Trigger) Operation
(a) Setting when scanning ANI0 to ANI3
No particular order
INTCC110
INTCC111
INTCC112
ANI0
ADCR0
ANI1
ADCR1
ANI2
ADCR2
ANI3
A/D converter
ADCR3
ANI4
ADCR4
ANI5
ADCR5
ANI6
ADCR6
ANI7
ADCR7
INTCC113
(1)
CE bit of ADM0 is set to 1 (enable)
(8)
CC110 compare generation (random)
ANI0 A/D conversion
(2)
CC111 compare generation (random)
(9)
(3)
ANI1 A/D conversion
(10) Conversion result is stored in ADCR0
(4)
Conversion result is stored in ADCR1
(11) CC112 compare generation (random)
(5)
CC113 compare generation (random)
(12) ANI2 A/D conversion
(6)
ANI3 A/D conversion
(13) Conversion result is stored in ADCR2
(7)
Conversion result is stored in ADCR3
(14) INTAD interrupt generation
Caution The analog input enclosed in the broken lines cannot be used with INTCC11n as the trigger (n
= 0 to 3). When a setting is made to scan ANI0 to ANI7, ANI4 to ANI7 are converted in A/D
trigger mode (see (b)).
(b) Setting when scanning ANI0 to ANI7
No particular order
INTCC110
INTCC111
INTCC112
INTCC113
340
ANI0
ADCR0
ANI1
ADCR1
ANI2
ADCR2
ANI3
A/D converter
ADCR3
ANI4
ADCR4
ANI5
ADCR5
ANI6
ADCR6
ANI7
ADCR7
(1) to (13) Same as (a)
(18) ANI6 A/D conversion
(14) ANI4 A/D conversion
(19) Conversion result is stored in ADCR6
(15) Conversion result is stored in ADCR4
(20) ANI7 A/D conversion
(16) ANI5 A/D conversion
(21) Conversion result is stored in ADCR7
(17) Conversion result is stored in ADCR5
(22) INTAD interrupt generation
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CHAPTER 11 A/D CONVERTER
11.7 Operation in External Trigger Mode
In the external trigger mode, the analog inputs (ANI0 to ANI3) are A/D converted by the ADTRG pin input timing.
The ADTRG pin is also used as the P127 and INTP153 pins. To set the external trigger mode, set the PMC127 bit
of the PMC12 register to 1 and bits TRG2 to TRG0 of the ADM1 register to 110.
For the valid edge of the external input signal in the external trigger mode, the rising edge, falling edge, or both
rising and falling edges can be specified using bits ES531 and ES530 of the INTM6 register. For details, refer to 7.3.8
(1) External interrupt mode registers 1 to 6 (INTM1 to INTM6).
11.7.1 Select mode operations (external trigger select)
One analog input (ANI0 to ANI3) specified by the ADM0 register is A/D converted. The conversion results are
stored in the ADCRn register corresponding to the analog input. There are two select modes, 1-buffer mode and 4buffer mode, storing the conversion results (n = 0 to 3).
(1) 1-buffer mode (External trigger select: 1-buffer)
One analog input is A/D converted using the ADTRG signal as a trigger. The conversion results are stored in
one ADCRn register. The analog input and the A/D conversion results register correspond one to one. INTAD
interrupts are generated after each A/D conversion, and A/D conversion ends.
Trigger
ADTRG signal
Analog Input
ANIn
A/D Conversion Result Register
(n = 0 to 3)
ADCRn
While the CE bit of the ADM0 register is 1, the A/D conversion is repeated every time a trigger is input from the
ADTRG pin.
This is most appropriate for applications that read the results each time there is an A/D conversion.
Figure 11-15. Example of 1-Buffer Mode (External Trigger Select 1-Buffer) Operation
ANI0
ADCR0
ANI1
ADCR1
ANI2
ADCR2
ANI3
A/D converter
ADCR3
ADCR4
ADCR5
ADCR6
ADTRG
ADCR7
(1)
CE bit of ADM0 is set to 1 (enable)
(2)
External trigger generation
(3)
ANI2 A/D conversion
(4)
Conversion result is stored in ADCR2
(5)
INTAD interrupt generation
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CHAPTER 11 A/D CONVERTER
(2) 4-buffer mode (External trigger select: 4-buffer)
One analog input is A/D converted four times using the ADTRG signal as a trigger and the results are stored in
the ADCR0 to ADCR3 registers. The INTAD interrupt is generated and conversion ends when the four A/D
conversions end.
Trigger
Analog Input
A/D Conversion Result Register
ADTRG signal
ANIn
ADCR0
ADTRG signal
ANIn
ADCR1
ADTRG signal
ANIn
ADCR2
ADTRG signal
ANIn
ADCR3
(n = 0 to 3)
While the CE bit of the ADM0 register is 1, A/D conversion is repeated every time a trigger is input from the
ADTRG pin.
This is most appropriate for applications that determine the average A/D conversion results.
Figure 11-16. Example of 4-Buffer Mode (External Trigger Select 4-Buffer) Operation
ANI0
ADCR0
ANI1
ADCR1
(×4)
ANI2
ANI3
ADCR2
A/D converter
ADCR3
ADCR4
(×4)
ADCR5
ADCR6
ADTRG
342
ADCR7
(1)
CE bit of ADM0 is set to 1 (enable)
(8)
External trigger generation
(2)
External trigger generation
(9)
ANI2 A/D conversion
(3)
ANI2 A/D conversion
(10) Conversion result is stored in ADCR2
(4)
Conversion result is stored in ADCR0
(11) External trigger generation
(5)
External trigger generation
(12) ANI2 A/D conversion
(6)
ANI2 A/D conversion
(13) Conversion result is stored in ADCR3
(7)
Conversion result is stored in ADCR1
(14) INTAD interrupt generation
User’s Manual U12688EJ4V0UM00
CHAPTER 11 A/D CONVERTER
11.7.2 Scan mode operations (external trigger scan)
The analog inputs specified by the ADM0 register are selected sequentially from the ANI0 pin using the ADTRG
signal as a trigger, and A/D converted. The A/D conversion results are stored in the ADCRn register corresponding to
the analog input (n = 0 to 7).
When the lower 4 channels (ANI0 to ANI3) of the analog input are set so that they are scanned in the ADM0
register, the INTAD interrupt is generated when the number of A/D conversions specified end, and A/D conversion
ends.
When the higher 4 channels (ANI4 to ANI7) of the analog input are set so that they are scanned in the ADM0
register, after the conversion of the lower 4 channels ends, the mode is shifted to the A/D trigger mode, and the
remaining A/D conversions are executed. The conversion results are stored in the ADCRn register corresponding to
the analog input.
Trigger
Analog Input
A/D Conversion Result Register
ADTRG signal
ANI0
ADCR0
ADTRG signal
ANI1
ADCR1
ADTRG signal
ANI2
ADCR2
ADTRG signal
ANI3
ADCR3
(A/D trigger mode)
ANI4
ADCR4
ANI5
ADCR5
ANI6
ADCR6
ANI7
ADCR7
When the conversion of all the specified analog inputs ends, the INTAD interrupt is generated and A/D conversion
ends.
When a trigger is input to the ADTRG pin while the CE bit of the ADM0 register is 1, the A/D conversion is started
again.
This is most appropriate for applications that are constantly monitoring multiple analog inputs.
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CHAPTER 11 A/D CONVERTER
Figure 11-17. Example of Scan Mode (External Trigger Scan) Operation
(a) Setting when scanning ANI0 to ANI3
ANI0
ADCR0
ANI1
ADCR1
ANI2
ADCR2
ANI3
ADTRG
A/D converter
ADCR3
ANI4
ADCR4
ANI5
ADCR5
ANI6
ADCR6
ANI7
ADCR7
(1)
CE bit of ADM0 is set to 1 (enable)
(8)
External trigger generation
(2)
External trigger generation
(9)
ANI2 A/D conversion
(3)
ANI0 A/D conversion
(10) Conversion result is stored in ADCR2
(4)
Conversion result is stored in ADCR0
(11) External trigger generation
(5)
External trigger generation
(12) ANI3 A/D conversion
(6)
ANI1 A/D conversion
(13) Conversion result is stored in ADCR3
(7)
Conversion result is stored in ADCR1
(14) INTAD interrupt generation
Caution The analog input enclosed in the broken lines cannot be used with ADTRG as the trigger.
When a setting is made to scan ANI0 to ANI7, ANI4 to ANI7 are converted in A/D trigger mode
(see (b)).
(b) Setting when scanning ANI0 to ANI7
ANI0
ADCR0
ANI1
ADCR1
ANI2
ADCR2
ANI3
ADTRG
A/D converter
ANI4
ADCR4
ANI5
ADCR5
ANI6
ADCR6
ANI7
ADCR7
(1) to (13) Same as (a)
344
ADCR3
(18) ANI6 A/D conversion
(14) ANI4 A/D conversion
(19) Conversion result is stored in ADCR6
(15) Conversion result is stored in ADCR4
(20) ANI7 A/D conversion
(16) ANI5 A/D conversion
(21) Conversion result is stored in ADCR7
(17) Conversion result is stored in ADCR5
(22) INTAD interrupt generation
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CHAPTER 11 A/D CONVERTER
11.8 Operating Precautions
11.8.1 Stopping conversion operation
When 0 is written to the CE bit of the ADM0 register during a conversion operation, the conversion operation stops
and the conversion results are not stored in the ADCRn register (n = 0 to 7).
11.8.2 External/timer trigger interval
Set the interval (input time interval) of the trigger in the external or timer trigger mode longer than the conversion
time specified by the FR2 to FR0 bits of the ADM1 register.
(1) When interval = 0
When several triggers are input simultaneously, the analog input with the smaller ANIn pin number is
converted. The other trigger signals input simultaneously are ignored, and the number of trigger inputs is not
counted. Therefore, the generation of interrupts and storage of results in the ADCRn register will become
abnormal (n = 0 to 7).
(2) When 0 < interval ≤ conversion operation time
When the timer trigger is input during a conversion operation, the conversion operation stops and the
conversion starts according to the last timer trigger input.
When a conversion operation stops, the conversion results are not stored in the ADCRn register. However,
the number of trigger inputs is counted, and when the interrupt is generated, the value at which conversion
ended is stored in the ADCRn register.
11.8.3 Operation of standby mode
(1) HALT mode
The A/D conversion operation continues. When released by the NMI input, the ADM0 and ADM1 registers
and ADCRn register hold the value (n = 0 to 7).
(2) IDLE mode, STOP mode
As clock supply to the A/D converter is stopped, no conversion operations are performed. When these modes
are released using the NMI input, the ADM0 and ADM1 registers and the ADCRn register hold the value.
However, when the IDLE and software STOP modes are set during a conversion operation, the conversion
operation stops. At this time, if released using the NMI input, the conversion operation resumes, but the
conversion result written to the ADCRn register will become undefined.
In the IDLE and software STOP modes, operation of the comparator is also stopped to reduce the power
consumption, and to further reduce current consumption, set the voltage of the AVREF to VSS.
11.8.4 Compare match interrupt when in timer trigger mode
The compare register’s match interrupt becomes an A/D conversion start trigger and starts the conversion
operation. When this happens, the compare register’s match interrupt functions even if it is a compare register match
interrupt directed to the CPU. In order to prevent match interrupts from the compare register being directed to the
CPU, disable interrupts by the interrupt mask bits (P11MK0 to P11MK3) of the interrupt control register (P11IC0 to
P11IC3).
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CHAPTER 11 A/D CONVERTER
11.8.5 Timer 1 functions when in external trigger mode
The external trigger input becomes an A/D conversion start trigger. At this time, the external trigger input also
functions as a timer 15 (TM15) capture trigger external interrupt. In order to prevent it from generating capture trigger
external interrupts, set TM15 as a compare register and disable interrupts by the interrupt mask bit of the interrupt
control register.
The operation if TM15 is not set as a compare register and interrupts are not disabled by the interrupt control
register is as follows.
(a) If the TUM15 register’s interrupt mask bit (IMS153) is 0
It also functions to generate compare register match interrupts to the CPU.
(b) If the TUM15 register’s interrupt mask bit (IMS153) is 1
The A/D converter’s external trigger input also functions as an external interrupt to the CPU.
Figure 11-18. Relationship of A/D Converter and Port, INTC and RPU
RPU
Edge
selection
External interrupt request
PCS1m
(PCS1)
PMC1m
(PMC1)
P1m/INTP11n/
DMAAKn
Noise
elimination
Edge
selection
CMS11n
(TUM11)
IMS11n
TM11
Capture
(TUM11)
trigger
Capture Timer interrupt
request
Compare
External interrupt request
A/D converter
ES531, ES530
(INTM6)
P15MK3
(P15IC3)
Interrupt
enable/disable
P11MKn
(P11ICn)
Interrupt
enable/disable
TRG0 to TRG2
(ADM1)
Timer
trigger
External trigger
Remarks 1. m = 4 to 7, n = 0 to 3
2. Items in parentheses (
346
) show the register names.
User’s Manual U12688EJ4V0UM00
Interrupt
control
ES1n1, ES1n0
(INTM2)
Selector
Noise
elimination
P127/INTP153/
ADTRG
CMS153
(TUM15)
IMS153
Capture
TM15
(TUM15)
trigger
Capture Timer interrupt
request
Compare
Selector
PMC127
(PMC12)
INTC
Selector
Port
A/D conversion
trigger
CHAPTER 12 PORT FUNCTIONS
12.1 Features
• Number of ports Input-only ports
I/O ports
9
114
• Function alternately as the input/output pins of other peripheral functions.
• It is possible to specify input and output in bit units.
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CHAPTER 12 PORT FUNCTIONS
12.2 Port Configuration
This product incorporates a total of 123 input/output ports (including 9 input-only ports) named ports 0 through 12,
and A, B and X. The port configuration is shown below.
Port 0
Port 1
Port 2
Port 3
Port 4
Port 5
Port 6
Port 7
348
P00
P80
to
to
P07
P87
P10
P90
to
to
P17
P97
P20
P21
to
P27
P100
P30
P110
to
to
Port 9
Port 10
P107
to
P37
P117
P40
P120
to
Port 8
to
P47
P127
P50
PA0
to
to
P57
PA7
P60
PB0
to
to
P67
PB7
P70
PX5
to
PX6
P77
PX7
User’s Manual U12688EJ4V0UM00
Port 11
Port 12
Port A
Port B
Port X
CHAPTER 12 PORT FUNCTIONS
(1) Function of each port
The port functions of this product are shown below.
8/1-bit operations are possible on all ports, allowing various kinds of control to be performed. In addition to
their port functions, these pins also function as internal peripheral I/O input/output pins in the control mode.
Port Name
Pin Name
Port Function
Function in Control Mode
Note
Block Type
Port 0
P00 to P07
8-bit I/O
Input/output of real-time pulse unit (RPU)
External interrupt input
DMA control (DMAC) input
A, B, M
Port 1
P10 to P17
8-bit I/O
Input/output of real-time pulse unit (RPU)
External interrupt input
DMA control (DMAC) output
A, B, K
Port 2
P20 to P27
1-bit input,
7-bit I/O
NMI input
Serial interface (UART0/CSI0, UART1/CSI1)
input/output
C, D, I, J, Q
Port 3
P30 to P37
8-bit I/O
Input/output of real-time pulse unit (RPU)
External interrupt input
Serial interface (CSI2) input/output
A, B, K, M, N
Port 4
P40 to P47
8-bit I/O
External data bus (D0 to D7)
E
Port 5
P50 to P57
8-bit I/O
External data bus (D8 to D15)
E
Port 6
P60 to P67
8-bit I/O
External address bus (A16 to A23)
F
Port 7
P70 to P77
8-bit input
A/D converter (ADC) analog input
G
Port 8
P80 to P87
8-bit I/O
External bus interface control signal output
O, P
Port 9
P90 to P97
8-bit I/O
External bus interface control signal input/output
H, O
Port 10
P100 to P107
8-bit I/O
Input/output of real-time pulse unit (RPU)
External interrupt input
DMA control (DMAC) output
A, B, K
Port 11
P110 to P117
8-bit I/O
Input/output of real-time pulse unit (RPU)
External interrupt input
Serial interface (CSI3) input/output
A, B, K, M, N
Port 12
P120 to P127
8-bit I/O
Input/output of real-time pulse unit (RPU)
External interrupt input
A/D converter (ADC) external trigger input
A, B
Port A
PA0 to PA7
8-bit I/O
External address bus (A0 to A7)
F
Port B
PB0 to PB7
8-bit I/O
External address bus (A8 to A15)
F
Port X
PX5 to PX7
3-bit I/O
Refresh request signal output
Wait insertion signal input
Internal system clock output
A, L
Note Refer to 12.2 (3) Block diagram of port.
Caution When switching to the control mode, be sure to set ports that operate as output pins, or as
input/output pins in the control mode, by the following procedure.
<1> Set the inactive level for the signal output in the control mode in the relevant bits of port n
(Pn) (n = 0 to 6, 8 to 12, A, B, X).
<2> Switch to the control mode from the port n mode control register (PMCn).
If <1> above is not performed, when switching from the port mode to the control mode, the
contents of port n (Pn) will be output instantaneously.
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CHAPTER 12 PORT FUNCTIONS
(2) Function when each port’s pins are reset and register which sets the port/control mode
(1/3)
Port
Name
Port 0
Port 1
Port 2
Port 3
Pin Name
Pin Function After Reset
Single-chip
Mode 0
Single-chip
Mode 1
ROM-less
Mode 0
P00/TO100
P00 (input mode)
P01/TO101
P01 (input mode)
P02/TCLR10
P02 (input mode)
P03/TI10
P03 (input mode)
P04/INTP100/DMARQ0
P04 (input mode)
P05/INTP101/DMARQ1
P05 (input mode)
P06/INTP102/DMARQ2
P06 (input mode)
P07/INTP103/DMARQ3
P07 (input mode)
P10/TO110
P10 (input mode)
P11/TO111
P11 (input mode)
P12/TCLR11
P12 (input mode)
P13/TI11
P13 (input mode)
P14/INTP110/DMAAK0
P14 (input mode)
P15/INTP111/DMAAK1
P15 (input mode)
P16/INTP112/DMAAK2
P16 (input mode)
P17/INTP113/DMAAK3
P17 (input mode)
P20/NMI
NMI
P21
P21 (input mode)
P22/TXD0/SO0
P22 (input mode)
P23/RXD0/SI0
P23 (input mode)
P24/SCK0
P24 (input mode)
PMC2
P25/TXD1/SO1
P25 (input mode)
PMC2, ASIM10
P26/RXD1/SI1
P26 (input mode)
P27/SCK1
P27 (input mode)
PMC2
P30/TO130
P30 (input mode)
PMC3
P31/TO131
P31 (input mode)
P32/TCLR13
P32 (input mode)
P33/TI13
P33 (input mode)
P34/INTP130
P34 (input mode)
P35/INTP131/SO2
P35 (input mode)
P36/INTP132/SI2
P36 (input mode)
P37/INTP133/SCK2
P37 (input mode)
PMC0
Note
PMC0, PCS0
PMC1
Note
PMC1, PCS1
—
Note Selects the pin function when in the control mode.
350
ROM-less
Mode 1
Register Which
Sets the Mode
User’s Manual U12688EJ4V0UM00
PMC2, ASIM00
Note
Note
PMC3, PCS3
CHAPTER 12 PORT FUNCTIONS
(2/3)
Port
Name
Pin Name
Pin Function After Reset
Single-chip
Mode 0
Single-chip
Mode 1
ROM-less
Mode 0
ROM-less
Mode 1
Register Which
Sets the Mode
Port 4
P40/D0 to P47/D7
P40 to P47
(input mode)
D0 to D7
Port 5
P50/D8 to P57/D15
P50 to P57
(input mode)
D8 to D15
Port 6
P60/A16 to P67/A23
P60 to P67
(input mode)
A16 to A23
Port 7
P70/ANI0 to P77/ANI7
P70/ANI0 to P77/ANI7
Port 8
P80/CS0/RAS0
P80 (input mode)
CS0/RAS0
P81/CS1/RAS1
P81 (input mode)
CS1/RAS1
P82/CS2/RAS2
P82 (input mode)
CS2/RAS2
P83/CS3/RAS3
P83 (input mode)
CS3/RAS3
P84/CS4/RAS4/IOWR
P84 (input mode)
CS4/RAS4
P85/CS5/RAS5/IORD
P85 (input mode)
CS5/RAS5
P86/CS6/RAS6
P86 (input mode)
CS6/RAS6
P87/CS7/RAS7
P87 (input mode)
CS7/RAS7
P90/LCAS/LWR
P90 (input mode)
LCAS/LWR
P91/UCAS/UWR
P91 (input mode)
UCAS/UWR
P92/RD
P92 (input mode)
RD
P93/WE
P93 (input mode)
WE
P94/BCYST
P94 (input mode)
BCYST
PMC9
P95/OE
P95 (input mode)
OE
PMC9
P96/HLDAK
P96 (input mode)
HLDAK
P97/HLDRQ
P97 (input mode)
HLDRQ
P100/TO120
P100 (input mode)
P101/TO121
P101 (input mode)
P102/TCLR12
P102 (input mode)
P103/TI12
P103 (input mode)
P104/INTP120/TC0
P104 (input mode)
P105/INTP121/TC1
P105 (input mode)
P106/INTP122/TC2
P106 (input mode)
P107/INTP123/TC3
P107 (input mode)
Port 9
Port 10
MM
P50 to P57
(input mode)
MM
MM
—
PMC8
Note
PMC8, PCS8
PMC8
PMC9
PMC10
PMC10,
Note
PCS10
Note Selects the pin function when in the control mode.
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CHAPTER 12 PORT FUNCTIONS
(3/3)
Port
Name
Port 11
Pin Name
Pin Function After Reset
Single-chip
Mode 0
Single-chip
Mode 1
ROM-less
Mode 0
ROM-less
Mode 1
Register Which
Sets the Mode
PMC11
P110/TO140
P110 (input mode)
P111/TO141
P111 (input mode)
P112/TCLR14
P112 (input mode)
P113/TI14
P113 (input mode)
P114/INTP140
P114 (input mode)
P115/INTP141/SO3
P115 (input mode)
P116/INTP142/SI3
P116 (input mode)
P117/INTP143/SCK3
P117 (input mode)
P120/TO150
P120 (input mode)
P121/TO151
P121 (input mode)
P122/TCLR15
P122 (input mode)
P123/TI15
P123 (input mode)
P124/INTP150
P124 (input mode)
P125/INTP151
P125 (input mode)
P126/INTP152
P126 (input mode)
P127/INTP153/ADTRG
P127 (input mode)
Port A
PA0/A0 to PA7/A7
PA0 to PA7
(input mode)
A0 to A7
MM
Port B
PB0/A8 to PB7/A15
PB0 to PB7
(input mode)
A8 to A15
MM
Port X
PX5/REFRQ
PX5 (input mode)
REFRQ
PMCX
PX6/WAIT
PX6 (input mode)
WAIT
PX7/CLKOUT
PX7 (input mode)
CLKOUT
Port 12
PMC11,
Note
PCS11
PMC12
PMC12,
Note
ADM1
Note Selects the pin function when in the control mode.
352
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CHAPTER 12 PORT FUNCTIONS
(3) Block diagram of port
Figure 12-1. Type A Block Diagram
WRPMC
PMCmn
WRPM
Output signal
in control
mode
Selector
Pmn
RDIN
Remark
Pmn
Selector
WRPORT
Selector
Internal bus
PMmn
Address
m: Port number
n:
Bit number
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CHAPTER 12 PORT FUNCTIONS
Figure 12-2. Type B Block Diagram
WRPMC
PMCmn
WRPM
WRPORT
Pmn
Selector
Pmn
Selector
Internal bus
PMmn
Address
RDIN
Input signal in
control mode
Remark
m: Port number
n:
354
Noise elimination
edge detection
Bit number
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CHAPTER 12 PORT FUNCTIONS
Figure 12-3. Type C Block Diagram
WRPMC
SCKx output
enable signal
PMCmn
WRPM
Output signal in
control mode
Selector
Pmn
Pmn
Selector
WRPORT
Selector
Internal bus
PMmn
Address
RDIN
Input signal in
control mode
Remark
mn:
24, 27
x:
0 (when mn = 24), 1 (when mn = 27)
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CHAPTER 12 PORT FUNCTIONS
Figure 12-4. Type D Block Diagram
WRPMC
PMCmn
WRPM
WRPORT
Pmn
Selector
Pmn
Selector
Internal bus
PMmn
Address
RDIN
Input signal in
control mode
Remark
m: Port number
n:
356
Bit number
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CHAPTER 12 PORT FUNCTIONS
Figure 12-5. Type E Block Diagram
MODE0 to MODE3
MM0 to MM3
I/O controller
WRPM
Output signal in
control mode
Selector
Pmn
Pmn
Selector
WRPORT
Selector
Internal bus
PMmn
Address
RDIN
Input signal in
control mode
Remark
m: Port number
n:
Bit number
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CHAPTER 12 PORT FUNCTIONS
Figure 12-6. Type F Block Diagram
MODE0 to MODE3
MM0 to MM3
I/O controller
WRPM
Output signal in
control mode
Selector
Pmn
Pmn
Selector
WRPORT
Selector
Internal bus
PMmn
Address
RDIN
Remark
m: Port number
n:
Bit number
Internal bus
Figure 12-7. Type G Block Diagram
P7n
RDIN
Input signal in
control mode
Remark
358
Sample & hold
circuit
n = 0 to 7
User’s Manual U12688EJ4V0UM00
ANIn
CHAPTER 12 PORT FUNCTIONS
Figure 12-8. Type H Block Diagram
MODE0 to MODE3
MM0 to MM3
I/O controller
WRPM
WRPORT
Pmn
P97
Selector
Selector
Internal bus
PMmn
Address
RDIN
Input signal in
control mode
Selector
Internal bus
Figure 12-9. Type I Block Diagram
1
Noise
elimination
P20
Address
RDIN
NMI
Edge detection
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CHAPTER 12 PORT FUNCTIONS
Figure 12-10. Type J Block Diagram
WRPM
WRPORT
Pmn
RDIN
Remark
Address
m: Port number
n:
360
Selector
Pmn
Selector
Internal bus
PMmn
Bit number
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CHAPTER 12 PORT FUNCTIONS
Figure 12-11. Type K Block Diagram
WRPCS
PCSmn
WRPMC
PMCmn
Internal bus
WRPM
PMmn
Output signal in
control mode
Selector
Selector
Pmn
Pmn
Selector
WRPORT
Address
RDIN
Input signal in
control mode
Remark
Noise elimination
edge detection
m: Port number
n:
Bit number
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CHAPTER 12 PORT FUNCTIONS
Figure 12-12. Type L Block Diagram
WRPMC
PMCmn
WRPM
WRPORT
Pmn
Selector
Pmn
Selector
Internal bus
PMmn
Address
RDIN
Input signal in
control mode
Remark
m: Port number
n:
362
Bit number
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CHAPTER 12 PORT FUNCTIONS
Figure 12-13. Type M Block Diagram
WRPCS
PCSmnNote
WRPMC
PMCmn
Internal bus
WRPM
PMmn
WRPORT
Pmn
Selector
Selector
Pmn
Address
RDIN
INTP100 to INTP103,
INTP132, INTP142
Noise elimination
edge detection
DMARQ0 to DMARQ3,
SI2, SI3
Note When mn = 36:
PCS35
When mn = 116: PCS115
Remark
mn: 04 to 07, 36, 116
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CHAPTER 12 PORT FUNCTIONS
Figure 12-14. Type N Block Diagram
WRPCS
PCSm5
SCKx output
enable signal
WRPMC
PMCmn
Internal bus
WRPM
Output signal in
control mode
Selector
Pmn
Pmn
Selector
WRPORT
Selector
PMmn
Address
RDIN
INTP133, INTP143
Noise elimination
edge detection
SCK2, SCK3
Remark
364
mn:
37, 117
x:
2 (when mn = 37), 3 (when mn = 117)
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CHAPTER 12 PORT FUNCTIONS
Figure 12-15. Type O Block Diagram
MODE0 to MODE3
WRPMC
PMCmn
MM0 to MM3
I/O controller
WRPM
Output signal in
control mode
Selector
Pmn
Pmn
Selector
WRPORT
Selector
Internal bus
PMmn
Address
RDIN
Remark
m: Port number
n:
Bit number
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CHAPTER 12 PORT FUNCTIONS
Figure 12-16. Type P Block Diagram
WRPCS
PCSmn
MODE0 to MODE3
MM0 to MM3
WRPMC
I/O controller
PMCmn
Internal bus
WRPM
Selector
Pmn
Address
RDIN
Remark
m: Port number
n:
366
Bit number
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Pmn
Selector
Output signal in
control mode
Selector
WRPORT
Selector
PMmn
CHAPTER 12 PORT FUNCTIONS
Figure 12-17. Type Q Block Diagram
WRPMC
Serial output
enable signal
PMCmn
WRPM
Output signal in
control mode
Selector
Pmn
RDIN
Remark
Pmn
Selector
WRPORT
Selector
Internal bus
PMmn
Address
m: Port number
n:
Bit number
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12.3 Port Pin Functions
12.3.1 Port 0
Port 0 is an 8-bit input/output port that can be set to input or output in 1-bit units.
P0
7
6
5
4
3
2
1
0
P07
P06
P05
P04
P03
P02
P01
P00
Bit Position
7 to 0
Bit Name
Address
FFFFF000H
After reset
Undefined
Function
P0n (n = 7 to 0)
Port 0
Input/output port
In addition to their function as port pins, the port 0 pins can also operate as real-time pulse unit (RPU)
inputs/outputs, external interrupt request inputs, and DMA request inputs in the control mode.
(1) Operation in control mode
Port
Port 0
Control Mode
P00
TO100
P01
TO101
P02
TCLR10
P03
TI10
P04 to P07
INTP100/DMARQ0 to
INTP103/DMARQ3
Remark
Block Type
Real-time pulse unit (RPU) output
A
Real-time pulse unit (RPU) input
B
External interrupt request
input/DMA request input
M
(2) Input/output mode/control mode setting
Port 0 input/output mode setting is performed by means of the port 0 mode register (PM0), and control mode
setting is performed by means of the port 0 mode control register (PMC0) and port/control select register 0
(PCS0).
(a) Port 0 mode register (PM0)
This register can be read/written in 8- or 1-bit units.
PM0
368
7
6
5
4
3
2
1
0
PM07
PM06
PM05
PM04
PM03
PM02
PM01
PM00
Bit Position
Bit Name
7 to 0
PM0n (n = 7 to 0)
Function
Port Mode
Specifies the input/output mode of pin P0n.
0: Output mode (output buffer ON)
1: Input mode (output buffer OFF)
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Address
FFFFF020H
After reset
FFH
CHAPTER 12 PORT FUNCTIONS
(b) Port 0 mode control register (PMC0)
This register can be read/written in 8- or 1-bit units.
PMC0
7
6
5
4
3
2
1
0
PMC07
PMC06
PMC05
PMC04
PMC03
PMC02
PMC01
PMC00
Bit Position
7 to 4
Bit Name
Address
FFFFF040H
After reset
00H
Function
PMC0n
(n = 7 to 4)
Port Mode Control
Specifies the operation mode of pin P0n. Sets in combination with the PCS0
register.
0: Input/output port mode
1: External interrupt request (INTP103 to INTP100) input mode/DMA request
(DMARQ3 to DMARQ0) input mode
3
PMC03
Port Mode Control
Sets operation mode of P03 pin.
0: Input/output port mode
1: TI10 input mode
2
PMC02
Port Mode Control
Sets operation mode of P02 pin.
0: Input/output port mode
1: TCLR10 input mode
1
PMC01
Port Mode Control
Sets operation mode of P01 pin.
0: Input/output port mode
1: TO101 output mode
0
PMC00
Port Mode Control
Sets operation mode of P00 pin.
0: Input/output port mode
1: TO100 output mode
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(c) Port/control select register 0 (PCS0)
This register can be read/written in 8- or 1-bit units. However, bits 3 to 0 are fixed at 0, so even if 1 is
written, it is disregarded.
PCS0
7
6
5
4
3
2
1
0
PCS07
PCS06
PCS05
PCS04
0
0
0
0
Bit Position
Bit Name
Address
FFFFF580H
After reset
00H
Function
7
PCS07
Port Control Select
Specifies the operating mode when pin P07 is in the control mode.
0: INTP103 input mode
1: DMARQ3 input mode
6
PCS06
Port Control Select
Specifies the operating mode when pin P06 is in the control mode.
0: INTP102 input mode
1: DMARQ2 Input mode
5
PCS05
Port Control Select
Specifies the operating mode when pin P05 is in the control mode.
0: INTP101 input mode
1: DMARQ1 input mode
4
PCS04
Port Control Select
Specifies the operating mode when pin P04 is in the control mode.
0: INTP100 input mode
1: DMARQ0 input mode
Caution When the port mode is specified by the PMC0 register, the settings of this register are ignored.
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12.3.2 Port 1
Port 1 is an 8-bit input/output port that can be set to input or output in 1-bit units.
P1
7
6
5
4
3
2
1
0
P17
P16
P15
P14
P13
P12
P11
P10
Bit Position
Bit Name
7 to 0
Address
FFFFF002H
After reset
Undefined
Function
P1n (n = 7 to 0)
Port 1
Input/output port
In addition to their function as port pins, the port 1 pins can also operate as real-time pulse unit (RPU)
inputs/outputs, external interrupt request inputs, and DMA acknowledge outputs in the control mode.
(1) Operation in control mode
Port
Port 1
Control Mode
P10
TO110
P11
TO111
P12
TCLR11
P13
TI11
P14 to P17
INTP110/DMAAK0 to
INTP113/DMAAK3
Remark
Block Type
Real-time pulse unit (RPU) output
A
Real-time pulse unit (RPU) input
B
External interrupt input/DMA
acknowledge output
K
(2) Input/output mode/control mode setting
Port 1 input/output mode setting is performed by means of the port 1 mode register (PM1), and control mode
setting is performed by means of the port 1 mode control register (PMC1) and port/control select register 1
(PCS1).
(a) Port 1 mode register (PM1)
This register can be read/written in 8- or 1-bit units.
PM1
7
6
5
4
3
2
1
0
PM17
PM16
PM15
PM14
PM13
PM12
PM11
PM10
Bit Position
Bit Name
7 to 0
PM1n (n = 7 to 0)
Address
FFFFF022H
After reset
FFH
Function
Port Mode
Sets P1n in input/output mode.
0: Output mode (output buffer ON)
1: Input mode (output buffer OFF)
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(b) Port 1 mode control register (PMC1)
This register can be read/written in 8- or 1-bit units.
PMC1
7
6
5
4
3
2
1
0
PMC17
PMC16
PMC15
PMC14
PMC13
PMC12
PMC11
PMC10
Bit Position
7 to 4
372
Bit Name
Address
FFFFF042H
Function
PMC1n
(n = 7 to 4)
Port Mode Control
Sets operation mode of P1n pin. Set in combination with PCS1.
0: Input/output port mode
1: External interrupt request (INTP113 to INTP110) input mode/
DMA acknowledge (DMAAK3 to DMAAK0) output mode
3
PMC13
Port Mode Control
Sets operation mode of P13 pin.
0: Input/output port mode
1: TI11 input mode
2
PMC12
Port Mode Control
Sets operation mode of P12 pin.
0: Input/output port mode
1: TCLR11 input mode
1
PMC11
Port Mode Control
Sets operation mode of P11 pin.
0: Input/output port mode
1: TO111 output mode
0
PMC10
Port Mode Control
Sets operation mode of P10 pin.
0: Input/output port mode
1: TO110 output mode
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00H
CHAPTER 12 PORT FUNCTIONS
(c) Port/control select register 1 (PCS1)
This register can be read/written in 8- or 1-bit units. However, bits 3 to 0 are fixed at 0, so even if 1 is
written, it is disregarded.
PCS1
7
6
5
4
3
2
1
0
PCS17
PCS16
PCS15
PCS14
0
0
0
0
Bit Position
Bit Name
Address
FFFFF582H
After reset
00H
Function
7
PCS17
Port Control Select
Specifies the operating mode when pin P17 is in the control mode.
0: INTP113 input mode
1: DMAAK3 output mode
6
PCS16
Port Control Select
Specifies the operating mode when pin P16 is in the control mode.
0: INTP112 input mode
1: DMAAK2 output mode
5
PCS15
Port Control Select
Specifies the operating mode when pin P15 is in the control mode.
0: INTP111 input mode
1: DMAAK1 output mode
4
PCS14
Port Control Select
Specifies the operating mode when pin P14 is in the control mode.
0: INTP110 input mode
1: DMAAK0 output mode
Caution When the port mode is specified by the PMC1 register, the settings of this register are ignored.
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12.3.3 Port 2
Port 2 is an 8-bit input/output port that can be set to input or output in 1-bit units. However, P20 always operates
as an NMI input if the edge is input.
P2
7
6
5
4
3
2
1
0
P27
P26
P25
P24
P23
P22
P21
P20
Bit Position
7 to 1
0
Bit Name
Address
FFFFF004H
After reset
Undefined
Function
P2n (n = 7 to 1)
Port 2
Input/output port
P20
Fix to NMI input mode.
In addition to their function as port pins, the port 2 pins can also operate as serial interface (UART0/CSI0,
UART1/CSI1) inputs/outputs in the control mode. Note that pin P21 does not have an alternate function and operates
only in the port mode.
(1) Operation in control mode
Port
Port 2
P20
Control Mode
NMI
P21
374
—
Remark
Block Type
Non-maskable interrupt request
input
I
Fixed to port mode
J
Input/output for serial interface
(UART0/CSI0, UART1/CSI1)
Q
P22
TXD0/SO0
P23
RXD0/SI0
P24
SCK0
C
P25
TXD1/SO1
Q
P26
RXD1/SI1
D
P27
SCK1
C
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CHAPTER 12 PORT FUNCTIONS
(2) Input/output mode/control mode setting
Port 2 input/output mode setting is performed by means of the port 2 mode register (PM2), and control mode
setting is performed by means of the port 2 mode control register (PMC2). Pin P20 is fixed to NMI input mode.
(a) Port 2 mode register (PM2)
This register can be read/written in 8- or 1-bit units. However, bit 0 is fixed at 1 by hardware, so writing 0
to this bit is ignored.
PM2
7
6
5
4
3
2
1
0
PM27
PM26
PM25
PM24
PM23
PM22
PM21
1
Bit Position
Bit Name
7 to 1
PM2n (n = 7 to 1)
Address
FFFFF024H
After reset
FFH
Function
Port Mode
Sets P2n in input/output mode.
0: Output mode (output buffer ON)
1: Input mode (output buffer OFF)
Caution When the serial interface is used, use the following bits in the state when they are set to 1 (initial
value).
When UART0 is used: PM22
When UART1 is used: PM25
When CSI0 is used:
PM24 to PM22
When CSI1 is used:
PM27 to PM25
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CHAPTER 12 PORT FUNCTIONS
(b) Port 2 mode control register (PMC2)
This register can be read/written in 8- or 1-bit units. However, bit 0 is fixed to 1 by hardware, so writing 0
to this bit is ignored. Bit 1 is fixed to 0, so writing 1 to this bit is ignored.
PMC2
7
6
5
4
3
2
1
0
PMC27
PMC26
PMC25
PMC24
PMC23
PMC22
0
1
Bit Position
Remark
Bit Name
Address
FFFFF044H
After reset
01H
Function
7
PMC27
Port Mode Control
Sets operation mode of P27 pin.
0: Input/output port mode
1: SCK1 input/output mode
6
PMC26
Port Mode Control
Sets operation mode of P26 pin.
0: Input/output port mode
1: RXD1/SI1 input mode
5
PMC25
Port Mode Control
Sets operation mode of P25 pin.
0: Input/output port mode
1: TXD1/SO1 output mode
4
PMC24
Port Mode Control
Sets operation mode of P24 pin.
0: Input/output port mode
1: SCK0 input/output mode
3
PMC23
Port Mode Control
Sets operation mode of P23 pin.
0: Input/output port mode
1: RXD0/SI0 input mode
2
PMC22
Port Mode Control
Sets operation mode of P22 pin.
0: Input/output port mode
1: TXD0/SO0 output mode
UART0 and CSI0, and UART1 and CSI1 share the same pins respectively. Either one of these is
selected according to the ASIM00 and ASIM10 registers (refer to 10.2.3 Control registers).
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12.3.4 Port 3
Port 3 is an 8-bit input/output port that can be set to input or output in 1-bit units.
P3
7
6
5
4
3
2
1
0
P37
P36
P35
P34
P33
P32
P31
P30
Bit Position
7 to 0
Bit Name
P3n (n = 7 to 0)
Address
FFFFF006H
After reset
Undefined
Function
Port 3
Input/output port
In addition to their function as port pins, the port 3 pins can also operate as the input/output signals of the real-time
pulse unit (RPU), the input signals of external interrupt, and the input/output lines of the serial interface (CSI2) when in
the control mode.
(1) Operation in control mode
Port
Port 3
Control Mode
Remark
P30
TO130
P31
TO131
P32
TCLR13
P33
TI13
P34
INTP130
External interrupt input
P35
INTP131/SO2
P36
INTP132/SI2
External interrupt input/serial
interface (CSI2) input/output
P37
INTP133/SCK2
Block Type
Real-time pulse unit (RPU) output
A
Real-time pulse unit (RPU) input
B
K
M
N
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(2) Input/output mode/control mode setting
Port 3 input/output mode setting is performed by means of the port 3 mode register (PM3), and control mode
setting is performed by means of the port 3 mode control register (PMC3) and port/control select register 3
(PCS3).
(a) Port 3 mode register (PM3)
This register can be read/written in 8- or 1-bit units.
PM3
378
7
6
5
4
3
2
1
0
PM37
PM36
PM35
PM34
PM33
PM32
PM31
PM30
Bit Position
Bit Name
7 to 0
PM3n (n = 7 to 0)
Function
Port Mode
Sets P3n in input/output mode.
0: Output mode (output buffer ON)
1: Input mode (output buffer OFF)
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Address
FFFFF026H
After reset
FFH
CHAPTER 12 PORT FUNCTIONS
(b) Port 3 mode control register (PMC3)
This register can be read/written in 8- or 1-bit units.
PMC3
7
6
5
4
3
2
1
0
PMC37
PMC36
PMC35
PMC34
PMC33
PMC32
PMC31
PMC30
Bit Position
7 to 5
Bit Name
Address
FFFFF046H
After reset
00H
Function
PMC3n
(n = 7 to 5)
Port Mode Control
Sets operation mode of P3n pin. Set in combination with PCS3.
0: Input/output port mode
1: External interrupt request (INTP133 to INTP131) input mode/CSI2 (SCK2,
SI2, SO2) input/output mode
4
PMC34
Port Mode Control
Sets operation mode of P34 pin.
0: Input/output port mode
1: INTP130 input mode
3
PMC33
Port Mode Control
Sets operation mode of P33 pin.
0: Input/output port mode
1: TI13 input mode
2
PMC32
Port Mode Control
Sets operation mode of P32 pin.
0: Input/output port mode
1: TCLR13 input mode
1
PMC31
Port Mode Control
Sets operation mode of P31 pin.
0: Input/output port mode
1: TO131 output mode
0
PMC30
Port Mode Control
Sets operation mode of P30 pin.
0: Input/output port mode
1: TO130 output mode
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(c) Port/control select register 3 (PCS3)
This register can be read/written in 8- or 1-bit units. However, except for bit 5, all the bits are fixed at 0,
so even if 1 is written, it is disregarded.
PCS3
7
6
5
4
3
2
1
0
0
0
PCS35
0
0
0
0
0
Bit Position
Bit Name
5
PCS35
Address
FFFFF586H
After reset
00H
Function
Port Control Select
Specifies the operating mode when pins P37 to P35 are in the control mode.
0: INTP133 input mode (P37)
INTP132 input mode (P36)
INTP131 input mode (P35)
1: SCK2 input/output mode (P37)
SI2 input mode (P36)
SO2 output mode (P35)
Caution When the port mode is specified by the PMC3 register, the settings of this register are ignored.
12.3.5 Port 4
Port 4 is an 8-bit input/output port that can be set to input or output in 1-bit units.
P4
7
6
5
4
3
2
1
0
P47
P46
P45
P44
P43
P42
P41
P40
Bit Position
7 to 0
Bit Name
P4n (n = 7 to 0)
Address
FFFFF008H
After reset
Undefined
Function
Port 4
Input/output port
In addition to their function as port pins, the port 4 pins can also operate in the control mode (external expansion
mode) as a data bus used when memory is expanded externally.
(1) Operation in control mode
Port
Port 4
380
P40 to P47
Control Mode
D0 to D7
Remark
Data bus in memory expansion
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CHAPTER 12 PORT FUNCTIONS
(2) Input/output mode/control mode setting
Port 4 input/output mode setting is performed by means of the port 4 mode register (PM4), and control mode
(external expansion mode) setting is performed by means of the mode specification pins (MODE0 to MODE3)
and the memory expansion mode register (MM: refer to 3.4.6 (1)).
(a) Port 4 mode register (PM4)
This register can be read/written in 8- or 1-bit units.
PM4
7
6
5
4
3
2
1
0
PM47
PM46
PM45
PM44
PM43
PM42
PM41
PM40
Bit Position
Bit Name
7 to 0
PM4n (n = 7 to 0)
Address
FFFFF028H
After reset
FFH
Function
Port Mode
Sets P4n in input/output mode.
0: Output mode (output buffer ON)
1: Input mode (output buffer OFF)
(b) Operation mode of port 4
Bit of MM Register
MM3
don’t
care
Operation Mode
MM2
MM1
MM0
0
0
0
0
0
1
0
1
0
0
1
1
1
0
0
1
0
1
1
1
0
1
1
1
P40
P41
P42
P43
P44
P45
P46
P47
Port (P40 to P47)
Data bus (D0 to D7)
For the details of mode selection by the MODE0 to MODE3 pins, refer to 3.3.2 Operating mode
specification.
In ROM-less modes 0 or 1, or single-chip mode 1, the MM0 to MM3 bits are initialized to 111× at system
reset, enabling the external expansion mode. External expansion can be disabled by programming the
MM0 to MM3 bits and setting the port mode. If MM0 to MM3 are set to 000×, the subsequent external
instruction cannot be fetched.
Remark
×: don’t care
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CHAPTER 12 PORT FUNCTIONS
12.3.6 Port 5
Port 5 is an 8-bit input/output port that can be set to input or output in 1-bit units.
P5
7
6
5
4
3
2
1
0
P57
P56
P55
P54
P53
P52
P51
P50
Bit Position
7 to 0
Bit Name
P5n (n = 7 to 0)
Address
FFFFF00AH
After reset
Undefined
Function
Port 5
Input/output port
In addition to their function as port pins, the port 5 pins can also operate in the control mode (external expansion
mode) as a data bus used when memory is expanded externally.
(1) Operation in control mode
Port
Port 5
382
P50 to P57
Control Mode
D8 to D15
Remark
Data bus in memory expansion
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CHAPTER 12 PORT FUNCTIONS
(2) Input/output mode/control mode setting
Port 5 input/output mode setting is performed by means of the port 5 mode register (PM5), and control mode
(external expansion mode) setting is performed by means of the mode specification pins (MODE0 to MODE3)
and the memory expansion mode register (MM: refer to 3.4.6 (1)).
(a) Port 5 mode register (PM5)
This register can be read/written in 8- or 1-bit units.
PM5
7
6
5
4
3
2
1
0
PM57
PM56
PM55
PM54
PM53
PM52
PM51
PM50
Bit Position
Bit Name
7 to 0
PM5n (n = 7 to 0)
Address
FFFFF02AH
After reset
FFH
Function
Port Mode
Sets P5n in input/output mode.
0: Output mode (output buffer ON)
1: Input mode (output buffer OFF)
(b) Operation mode of port 5
Bit of MM Register
Operation Mode
MM3
MM2
MM1
MM0
0
0
0
0
0
0
0
1
0
0
1
0
0
0
1
1
0
1
0
0
0
1
0
1
0
1
1
0
0
1
1
1
1
don’t care
P50
P51
P52
P53
P54
P55
P56
P57
Port (P50 to P57)
Data bus (D8 to D15)
Port (50 to P57)
For the details of mode selection by the MODE0 to MODE3 pins, refer to 3.3.2 Operating mode
specification.
In ROM-less mode 0 or single-chip mode 1, the MM0 to MM3 bits are initialized to 1110 at system reset,
enabling the external expansion mode. External expansion can be disabled by programming the MM0 to
MM3 bits and setting the port mode. If MM0 to MM3 are set to ×××1 or 0000, the subsequent external
instruction cannot be fetched.
Remark
×: don’t care
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12.3.7 Port 6
Port 6 is an 8-bit input/output port that can be set to input or output in 1-bit units.
P6
7
6
5
4
3
2
1
0
P67
P66
P65
P64
P63
P62
P61
P60
Bit Position
7 to 0
Bit Name
P6n (n = 7 to 0)
Address
FFFFF00CH
After reset
Undefined
Function
Port 6
Input/output port
In addition to their function as port pins, the port 6 pins can also operate in the control mode (external expansion
mode) as an address bus used when memory is expanded externally.
(1) Operation in control mode
Port
Port 6
384
P60 to P67
Control Mode
A16 to A23
Remark
Address bus in memory expansion
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CHAPTER 12 PORT FUNCTIONS
(2) Input/output mode/control mode setting
Port 6 input/output mode setting is performed by means of the port 6 mode register (PM6), and control mode
(external expansion mode) setting is performed by means of the mode specification pins (MODE0 to MODE3)
and the memory expansion mode register (MM: refer to 3.4.6 (1)).
(a) Port 6 mode register (PM6)
This register can be read/written in 8- or 1-bit units.
PM6
7
6
5
4
3
2
1
0
PM67
PM66
PM65
PM64
PM63
PM62
PM61
PM60
Bit Position
Bit Name
7 to 0
PM6n (n = 7 to 0)
Address
FFFFF02CH
After reset
FFH
Function
Port Mode
Sets P6n in input/output mode.
0: Output mode (output buffer ON)
1: Input mode (output buffer OFF)
(b) Operation mode of port 6
Bit of MM Register
MM3
don’t
care
Operation Mode
MM2
MM1
MM0
0
0
0
0
0
1
0
1
0
0
1
1
1
0
0
1
0
1
1
1
0
1
1
1
P60
P61
P62
P63
P64
P65
P66
P67
P64
P65
P66
P67
A20
A21
A22
A23
Port (P60 to P67)
A16
A17
P62
P63
A18
A19
For the details of mode selection by the MODE0 to MODE3 pins, refer to 3.3.2 Operating mode
specification.
In ROM-less modes 0 or 1, or single-chip mode 1, the MM0 to MM3 bits are initialized to 111× at system
reset, enabling the external expansion mode. External expansion can be disabled by programming the
MM0 to MM3 bits and setting the port mode.
Remark
×: don’t care
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12.3.8 Port 7
Port 7 is an 8-bit input only port and all pins of port 7 are fixed in the input mode.
P7
7
6
5
4
3
2
1
0
P77
P76
P75
P74
P73
P72
P71
P70
Address
FFFFF00EH
After reset
Undefined
In addition to their function as port pins, the port 7 pins can also operate as analog inputs for A/D converter.
This port is used also as the analog input pins (ANI0 to ANI7), but the port and analog input pins cannot be
switched. By reading the port, the state of each pin can be read.
(1) Operation in control mode
Port
Port 7
386
P70 to P77
Control Mode
ANI0 to ANI7
Remark
Analog input for A/D converter
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CHAPTER 12 PORT FUNCTIONS
12.3.9 Port 8
Port 8 is an 8-bit input/output port that can be set to input or output in 1-bit units.
P8
7
6
5
4
3
2
1
0
P87
P86
P85
P84
P83
P82
P81
P80
Bit Position
7 to 0
Bit Name
P8n (n = 7 to 0)
Address
FFFFF010H
After reset
Undefined
Function
Port 8
Input/output port
In addition to their function as port pins, in the control mode, the port 8 pins operate as chip select signal outputs,
row address strobe signal outputs for DRAM, and read/write strobe signal outputs for external I/O.
(1) Operation in control mode
Port
Port 8
Control Mode
Remark
Block Type
P80 to P83
CS0/RAS0 to CS3/RAS3
Chip select signal output
Row address signal output
O
P84
CS4/RAS4/IOWR
Chip select signal output
Row address signal output
Write strobe signal output
P
P85
CS5/RAS5/IORD
Chip select signal output
Row address signal output
Read strobe signal output
P86, P87
CS6/RAS6, CS7/RAS7
Chip select signal output
Row address signal output
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CHAPTER 12 PORT FUNCTIONS
(2) Input/output mode/control mode setting
Port 8 input/output mode setting is performed by means of the port 8 mode register (PM8), and control mode
(external expansion mode) setting is performed by means of the mode specification pins (MODE0 to MODE3)
and the port 8 mode control register (PMC8).
(a) Port 8 mode register (PM8)
This register can be read/written in 8- or 1-bit units.
PM8
388
7
6
5
4
3
2
1
0
PM87
PM86
PM85
PM84
PM83
PM82
PM81
PM80
Bit Position
Bit Name
7 to 0
PM8n (n = 7 to 0)
Function
Port Mode
Sets P8n pin in input/output mode.
0: Output mode (output buffer ON)
1: Input mode (output buffer OFF)
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Address
FFFFF030H
After reset
FFH
CHAPTER 12 PORT FUNCTIONS
(b) Port 8 mode control register (PMC8)
This register can be read/written in 8- or 1-bit units.
PMC8
7
6
5
4
3
2
1
0
PMC87
PMC86
PMC85
PMC84
PMC83
PCM82
PMC81
PMC80
Address
FFFFF050H
After reset
Note
Note Single-chip mode 0: 00H
Single-chip mode 1: FFH
ROM-less mode 0, 1: FFH
Bit Position
Bit Name
Function
7
PMC87
Port Mode Control
Sets operation mode of P87 pin.
0: Input/output port mode
1: CS7/RAS7 output mode
6
PMC86
Port Mode Control
Sets operation mode of P86 pin.
0: Input/output port mode
1: CS6/RAS6 output mode
5
PMC85
Port Mode Control
Sets operation mode of P85 pin. Set in combination with PCS8.
0: Input/output port mode
1: CS5/RAS5 output mode/IORD output mode
4
PMC84
Port Mode Control
Sets operation mode of P84 pin. Set in combination with PCS8.
0: Input/output port mode
1: CS4/RAS4 output mode/IOWR output mode
3
PMC83
Port Mode Control
Sets operation mode of P83 pin.
0: Input/output port mode
1: CS3/RAS3 output mode
2
PMC82
Port Mode Control
Sets operation mode of P82 pin.
0: Input/output port mode
1: CS2/RAS2 output mode
1
PMC81
Port Mode Control
Sets operation mode of P81 pin.
0: Input/output port mode
1: CS1/RAS1 output mode
0
PMC80
Port Mode Control
Sets operation mode of P80 pin.
0: Input/output port mode
1: CS0/RAS0 output mode
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(c) Port/control select register 8 (PCS8)
This register can be read/written in 8- or 1-bit units. However, all the bits except for bits 5 and 4 are fixed
at 0, so even if 1 is written, it is disregarded.
PCS8
7
6
5
4
3
2
1
0
0
0
PCS85
PCS84
0
0
0
0
Bit Position
Bit Name
Address
FFFFF590H
After reset
00H
Function
5
PCS85
Port Control Select
Specifies the operating mode when pin P85 is in the control mode.
0: CS5/RAS5 output mode
1: IORD output mode
4
PCS84
Port Control Select
Specifies the operating mode when pin P84 is in the control mode.
0: CS4/RAS4 output mode
1: IOWR output mode
Caution When the port mode is specified by the PMC8 register, the settings of this register are ignored.
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12.3.10 Port 9
Port 9 is an 8-bit input/output port that can be set to input or output in 1-bit units.
P9
7
6
5
4
3
2
1
0
P97
P96
P95
P94
P93
P92
P91
P90
Bit Position
7 to 0
Bit Name
P9n (n = 7 to 0)
Address
FFFFF012H
After reset
Undefined
Function
Port 9
Input/output port
In addition to their function as port pins, the port 9 pins can also operate in the control mode (external expansion
mode) as control signal outputs and bus hold control signal output used when memory is expanded externally.
(1) Operation in control mode
Port
Port 9
Control Mode
Remark
Control signal output in memory
expansion
P90
LWR/LCAS
P91
UWR/UCAS
P92
RD
P93
WE
P94
BCYST
P95
OE
P96
HLDAK
Bus hold acknowledge signal output
P97
HLDRQ
Bus hold request signal input
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H
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(2) Input/output mode/control mode setting
Port 9 input/output mode setting is performed by means of the port 9 mode register (PM9), and control mode
(external expansion mode) setting is performed by means of the mode specification pins (MODE0 to MODE3)
and the port 9 mode control register (PMC9).
(a) Port 9 mode register (PM9)
This register can be read/written in 8- or 1-bit units.
PM9
392
7
6
5
4
3
2
1
0
PM97
PM96
PM95
PM94
PM93
PM92
PM91
PM90
Bit Position
Bit Name
7 to 0
PM9n (n = 7 to 0)
Function
Port Mode
Sets P9n pin in input/output mode.
0: Output mode (output buffer ON)
1: Input mode (output buffer OFF)
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Address
FFFFF032H
After reset
FFH
CHAPTER 12 PORT FUNCTIONS
(b) Port 9 mode control register (PMC9)
This register can be read/written in 8- or 1-bit units.
PMC9
7
6
5
4
3
2
1
0
PMC97
PMC96
PMC95
PMC94
PMC93
PCM92
PMC91
PMC90
Address
FFFFF052H
After reset
Note
Note Single-chip mode 0: 00H
Single-chip mode 1: FFH
ROM-less mode 0, 1: FFH
Bit Position
Bit Name
Function
7
PMC97
Port Mode Control
Sets operation mode of P97 pin.
0: Input/output port mode
1: HLDRQ input mode
6
PMC96
Port Mode Control
Sets operation mode of P96 pin.
0: Input/output port mode
1: HLDAK output mode
5
PMC95
Port Mode Control
Sets operation mode of P95 pin.
0: Input/output port mode
1: OE output mode
4
PMC94
Port Mode Control
Sets operation mode of P94 pin.
0: Input/output port mode
1: BCYST output mode
3
PMC93
Port Mode Control
Sets operation mode of P93 pin.
0: Input/output port mode
1: WE output mode
2
PMC92
Port Mode Control
Sets operation mode of P92 pin.
0: Input/output port mode
1: RD output mode
1
PMC91
Port Mode Control
Sets operation mode of P91 pin.
0: Input/output port mode
1: UWR/UCAS output mode
0
PMC90
Port Mode Control
Sets operation mode of P90 pin.
0: Input/output port mode
1: LWR/LCAS output mode
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12.3.11 Port 10
Port 10 is an 8-bit input/output port that can be set to input or output in 1-bit units.
P10
7
6
5
4
3
2
1
0
P107
P106
P105
P104
P103
P102
P101
P100
Bit Position
Bit Name
7 to 0
P10n (n = 7 to 0)
Address
FFFFF014H
After reset
Undefined
Function
Port 10
Input/output port
In addition to their function as port pins, the port 10 pins can also operate as real-time pulse unit (RPU)
inputs/outputs, external interrupt inputs, and DMA (terminal count) outputs in the control mode.
(1) Operation in control mode
Port
Port 10
Control Mode
P100
TO120
P101
TO121
P102
TCLR12
P103
TI12
P104 to
P107
INTP120/TC0 to
INTP123/TC3
Remark
Block Type
Real-time pulse unit (RPU) output
A
Real-time pulse unit (RPU) input
B
External interrupt input/DMA
(terminal count) output
K
(2) Input/output mode/control mode setting
Port 10 input/output mode setting is performed by means of the port 10 mode register (PM10), and control
mode setting is performed by means of the port 10 mode control register (PMC10) and port/control select
register 10 (PCS10).
(a) Port 10 mode register (PM10)
This register can be read/written in 8- or 1-bit units.
PM10
7
6
5
4
3
2
1
0
PM107
PM106
PM105
PM104
PM103
PM102
PM101
PM100
Bit Position
7 to 0
394
Bit Name
PM10n
(n = 7 to 0)
Function
Port Mode
Sets P10n pin in input/output mode.
0: Output mode (output buffer ON)
1: Input mode (output buffer OFF)
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Address
FFFFF034H
After reset
FFH
CHAPTER 12 PORT FUNCTIONS
(b) Port 10 mode control register (PMC10)
This register can be read/written in 8- or 1-bit units.
7
PMC10
6
5
4
3
2
1
0
PMC107 PMC106 PMC105 PMC104 PMC103 PMC102 PMC101 PMC100
Bit Position
7 to 4
Bit Name
Address
FFFFF054H
After reset
00H
Function
PMC10n
(n = 7 to 4)
Port Mode Control
Sets operation mode of P10n pin. Set in combination with PCS10.
0: Input/output port mode
1: External interrupt request (INTP123 to INTP120) input mode/DMA terminal
signal (TC3 to TC0) output mode
3
PMC103
Port Mode Control
Sets operation mode of P103 pin.
0: Input/output port mode
1: TI12 input mode
2
PMC102
Port Mode Control
Sets operation mode of P102 pin.
0: Input/output port mode
1: TCLR12 input mode
1
PMC101
Port Mode Control
Sets operation mode of P101 pin.
0: Input/output port mode
1: TO121 output mode
0
PMC100
Port Mode Control
Sets operation mode of P100 pin.
0: Input/output port mode
1: TO120 output mode
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(c) Port/control select register 10 (PCS10)
This register can be read/written in 8- or 1-bit units. However, bits 3 to 0 are fixed at 0, so even if 1 is
written, it is disregarded.
7
PCS10
6
5
4
PCS107 PCS106 PCS105 PCS104
Bit Position
3
2
1
0
0
0
0
0
Bit Name
Address
FFFFF594H
After reset
00H
Function
7
PCS107
Port Control Select
Specifies the operating mode when pin P107 is in the control mode.
0: INTP123 input mode
1: TC3 output mode
6
PCS106
Port Control Select
Specifies the operating mode when pin P106 is in the control mode.
0: INTP122 input mode
1: TC2 output mode
5
PCS105
Port Control Select
Specifies the operating mode when pin P105 is in the control mode.
0: INTP121 input mode
1: TC1 output mode
4
PCS104
Port Control Select
Specifies the operating mode when pin P104 is in the control mode.
0: INTP120 input mode
1: TC0 output mode
Caution When the port mode is specified by the PMC10 register, the settings of this register are ignored.
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12.3.12 Port 11
Port 11 is an 8-bit input/output port that can be set to input or output in 1-bit units.
P11
7
6
5
4
3
2
1
0
P117
P116
P115
P114
P113
P112
P111
P110
Bit Position
Bit Name
7 to 0
P11n (n = 7 to 0)
Address
FFFFF016H
After reset
Undefined
Function
Port 11
Input/output port
In addition to their function as port pins, the port 11 pins can also operate as real-time pulse unit (RPU)
inputs/outputs, external interrupt request inputs, and serial interface (CSI3) inputs/outputs in the control mode.
(1) Operation in control mode
Port
Port 11
Control Mode
Remark
P110
TO140
P111
TO141
P112
TCLR14
P113
TI14
P114
INTP140
External interrupt input
P115
INTP141/SO3
P116
INTP142/SI3
External interrupt input/serial
interface (CSI3) input/output
P117
INTP143/SCK3
Block Type
Real-time pulse unit (RPU) output
A
Real-time pulse unit (RPU) input
B
K
M
N
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(2) Input/output mode/control mode setting
Port 11 input/output mode setting is performed by means of the port 11 mode register (PM11), and control
mode setting is performed by means of the port 11 mode control register (PMC11) and port/control select
register 11 (PCS11).
(a) Port 11 mode register (PM11)
This register can be read/written in 8- or 1-bit units.
PM11
7
6
5
4
3
2
1
0
PM117
PM116
PM115
PM114
PM113
PM112
PM111
PM110
Bit Position
7 to 0
398
Bit Name
PM11n
(n = 7 to 0)
Function
Port Mode
Sets P11n pin in input/output mode.
0: Output mode (output buffer ON)
1: Input mode (output buffer OFF)
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FFFFF036H
After reset
FFH
CHAPTER 12 PORT FUNCTIONS
(b) Port 11 mode control register (PMC11)
This register can be read/written in 8- or 1-bit units.
7
PMC11
6
5
4
3
2
1
0
PMC117 PMC116 PMC115 PMC114 PMC113 PMC112 PMC111 PMC110
Bit Position
7 to 5
Bit Name
Address
FFFFF056H
After reset
00H
Function
PMC11n
(n = 7 to 5)
Port Mode Control
Sets operation mode of P11n pin. Set in combination with PCS11.
0: Input/output port mode
1: External interrupt request (INTP143 to INTP141) input mode/CSI3 (SCK3,
SI3, SO3) input/output mode
4
PMC114
Port Mode Control
Sets operation mode of P114 pin.
0: Input/output port mode
1: INTP140 input mode
3
PMC113
Port Mode Control
Sets operation mode of P113 pin.
0: Input/output port mode
1: TI14 input mode
2
PMC112
Port Mode Control
Sets operation mode of P112 pin.
0: Input/output port mode
1: TCLR14 input mode
1
PMC111
Port Mode Control
Sets operation mode of P111 pin.
0: Input/output port mode
1: TO141 output mode
0
PMC110
Port Mode Control
Sets operation mode of P110 pin.
0: Input/output port mode
1: TO140 output mode
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(c) Port/control select register 11 (PCS11)
This register can be read/written in 8- or 1-bit units. However, except for bit 5, all bits are fixed at 0, so
even if 1 is written, it is disregarded.
PCS11
7
6
5
4
3
2
1
0
0
0
PCS115
0
0
0
0
0
Bit Position
5
Bit Name
PCS115
Address
FFFFF596H
After reset
00H
Function
Port Control Select
Specifies the operating mode when pins P117 to P115 are in the control mode.
0: INTP143 input mode (P117)
INTP142 input mode (P116)
INTP141 input mode (P115)
1: SCK3 input/output mode (P117)
SI3 input mode (P116)
SO3 output mode (P115)
Caution When the port mode is specified by the PMC11 register, the settings of this register are ignored.
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12.3.13 Port 12
Port 12 is an 8-bit input/output port that can be set to input or output in 1-bit units.
P12
7
6
5
4
3
2
1
0
P127
P126
P125
P124
P123
P122
P121
P120
Bit Position
Bit Name
7 to 0
P12n (n = 7 to 0)
Address
FFFFF018H
After reset
Undefined
Function
Port 12
Input/output port
In addition to their function as port pins, the port 12 pins can also operate as real-time pulse unit (RPU)
inputs/outputs, external interrupt request inputs, and A/D converter trigger input in the control mode.
(1) Operation in control mode
Port
Port 12
Control Mode
Remark
Block Type
P120
TO150
P121
TO151
P122
TCLR15
P123
TI15
P124 to P126
INTP150 to INTP152
External interrupt input
P127
INTP153/ADTRG
External interrupt input/AD converter
external trigger input
Real-time pulse unit (RPU) output
A
Real-time pulse unit (RPU) input
B
(2) Input/output mode/control mode setting
Port 12 input/output mode setting is performed by means of the port 12 mode register (PM12), and control
mode setting is performed by means of the port 12 mode control register (PMC12).
(a) Port 12 mode register (PM12)
This register can be read/written in 8- or 1-bit units.
PM12
7
6
5
4
3
2
1
0
PM127
PM126
PM125
PM124
PM123
PM122
PM121
PM120
Bit Position
7 to 0
Bit Name
PM12n
(n = 7 to 0)
Address
FFFFF038H
After reset
FFH
Function
Port Mode
Sets P12n pin in input/output mode.
0: Output mode (output buffer ON)
1: Input mode (output buffer OFF)
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(b) Port 12 mode control register (PMC12)
This register can be read/written in 8- or 1-bit units.
7
PMC12
6
5
4
3
2
1
0
PMC127 PMC126 PMC125 PMC124 PMC123 PMC122 PMC121 PMC120
Bit Position
7
Bit Name
Address
FFFFF058H
Function
PMC127
Port Mode Control
Sets operation mode of P127 pin.
0: Input/output port mode
1: External interrupt request (INTP153) input mode
Note
A/D converter external trigger (ADRTG) input mode
PMC12n
(n = 6 to 4)
Port Mode Control
Sets operation mode of P12n pin.
0: Input/output port mode
1: External interrupt request (INTP152 to INTP150) input mode
3
PMC123
Port Mode Control
Sets operation mode of P123 pin.
0: Input/output port mode
1: TI15 input mode
2
PMC122
Port Mode Control
Sets operation mode of P122 pin.
0: Input/output port mode
1: TCLR15 input mode
1
PMC121
Port Mode Control
Sets operation mode of P121 pin.
0: Input/output port mode
1: TO151 output mode
0
PMC120
Port Mode Control
Sets operation mode of P120 pin.
0: Input/output port mode
1: TO150 output mode
6 to 4
After reset
00H
Note If the TRG bit of the A/D converter mode register (ADM1) is set in the external trigger mode when bit
PMC127 = 1, it functions as an A/D converter external trigger input (ADTRG).
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12.3.14 Port A
Port A is an 8-bit input/output port that can be set to input or output in 1-bit units.
PA
7
6
5
4
3
2
1
0
PA7
PA6
PA5
PA4
PA3
PA2
PA1
PA0
Bit Position
Bit Name
7 to 0
PAn (n = 7 to 0)
Address
FFFFF01CH
After reset
Undefined
Function
Port A
Input/output port
In addition to their function as port pins, the port A pins can also operate in the control mode (external expansion
mode) as an address bus used when memory is expanded externally.
(1) Operation in control mode
Port
Port A
Control Mode
PA0 to PA7
Remark
A0 to A7
Block Type
Address bus in memory expansion
F
(2) Input/output mode/control mode setting
Port A input/output mode setting is performed by means of the port A mode register (PMA), and control mode
(external expansion mode) setting is performed by means of the mode specification pins (MODE0 to MODE3)
and the memory expansion mode register (MM: refer to 3.4.6 (1)).
(a) Port A mode register (PMA)
This register can be read/written in 8- or 1-bit units.
PMA
7
6
5
4
3
2
1
0
PMA7
PMA6
PMA5
PMA4
PMA3
PMA2
PMA1
PMA0
Bit Position
7 to 0
Bit Name
PMAn
(n = 7 to 0)
Address
FFFFF03CH
After reset
FFH
Function
Port Mode
Sets PAn pin in input/output mode.
0: Output mode (output buffer ON)
1: Input mode (output buffer OFF)
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(b) Operation mode of port A
Bit of MM Register
MM3
don’t
care
Operation Mode
MM2
MM1
MM0
0
0
0
0
0
1
0
1
0
0
1
1
1
0
0
1
0
1
1
1
0
1
1
1
PA0
PA1
PA2
PA3
PA4
PA5
PA6
PA7
Port (PA0 to PA7)
Address bus (A0 to A7)
For the details of mode selection by the MODE0 to MODE3 pins, refer to 3.3.2 Operating mode
specification.
In ROM-less modes 0 or 1, or single-chip mode 1, the MM0 to MM3 bits are initialized to 111× at system
reset, enabling the external address output mode. If MM0 to MM3 are set to 000× by the program, the
port mode can be changed to, but the subsequent external instruction cannot be fetched from data bus.
Remark
404
×: don’t care
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12.3.15 Port B
Port B is an 8-bit input/output port that can be set to input or output in 1-bit units.
PB
7
6
5
4
3
2
1
0
PB7
PB6
PB5
PB4
PB3
PB2
PB1
PB0
Bit Position
Bit Name
7 to 0
Address
FFFFF01EH
After reset
Undefined
Function
PBn (n = 7 to 0)
Port B
Input/output port
In addition to their function as port pins, the port B pins can also operate in the control mode (external expansion
mode) as an address bus used when memory is expanded externally.
(1) Operation in control mode
Port
Port B
Control Mode
PB0 to PB7
Remark
A8 to A15
Block Type
Address bus in memory expansion
F
(2) Input/output mode/control mode setting
Port B input/output mode setting is performed by means of the port B mode register (PMB), and control mode
(external expansion mode) setting is performed by means of the mode specification pins (MODE0 to MODE3)
and the memory expansion mode register (MM: refer to 3.4.6 (1)).
(a) Port B mode register (PMB)
This register can be read/written in 8- or 1-bit units.
PMB
7
6
5
4
3
2
1
0
PMB7
PMB6
PMB5
PMB4
PMB3
PMB2
PMB1
PMB0
Bit Position
7 to 0
Bit Name
PMBn
(n = 7 to 0)
Address
FFFFF03EH
After reset
FFH
Function
Port Mode
Sets PBn pin in input/output mode.
0: Output mode (output buffer ON)
1: Input mode (output buffer OFF)
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CHAPTER 12 PORT FUNCTIONS
(b) Operation mode of port B
Bit of MM Register
MM3
don’t
care
Operation Mode
MM2
MM1
MM0
0
0
0
0
0
1
0
1
0
0
1
1
1
0
0
1
0
1
1
1
0
1
1
1
PB0
PB1
PB2
PB3
PB4
PB5
PB6
PB7
PB4
PB5
PB6
PB7
A12
A13
A14
A15
Port (PB0 to PB7)
A8
A9
A10
A11
For the details of mode selection by the MODE0 to MODE3 pins, refer to 3.3.2 Operating mode
specification.
In ROM-less modes 0 or 1, or single-chip mode 1, the MM0 to MM3 bits are initialized to 111× at system
reset, enabling the external address output mode. If MM0 to MM3 are set to 000× by the program, the
port mode can be changed to, but the subsequent external instruction cannot be fetched from data bus.
Also, if MM0 to MM3 are set to 100x or 010x, the subsequent external address output from port B is
disabled.
Remark
406
×: don’t care
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CHAPTER 12 PORT FUNCTIONS
12.3.16 Port X
Port X is a 3-bit input/output port that can be set to input or output in 1-bit units.
PX
7
6
5
4
3
2
1
0
PX7
PX6
PX5
—
—
—
—
—
Bit Position
7 to 5
Bit Name
PXn (n = 7 to 5)
Address
FFFFF41AH
After reset
Undefined
Function
Port X
Input/output port
In addition to their function as port pins, the port X pins can also operate as DRAM refresh request signal output,
wait control input, and internal system clock output in the control mode. Lower 5 bits of port X are always undefined in
the case of 8-bit access.
(1) Operation in control mode
Port
Port X
Control Mode
Remark
Block Type
PX5
REFRQ
DRAM refresh request signal output
A
PX6
WAIT
Wait control input
L
PX7
CLKOUT
Internal system clock output
A
(2) Input/output mode/control mode setting
Port X input/output mode setting is performed by means of the port X mode register (PMX), and control mode
setting is performed by means of the port X mode control register (PMCX).
(a) Port X mode register (PMX)
This register is write-only, in 8-bit units. However, the lower 5 bits are fixed at 1 by hardware, so even if 0
is written, it is disregarded.
PMX
7
6
5
4
3
2
1
0
PMX7
PMX6
PMX5
1
1
1
1
1
Bit Position
7 to 5
Bit Name
PMXn
(n = 7 to 5)
Address
FFFFF43AH
After reset
FFH
Function
Port Mode
Sets PXn pin in input/output mode.
0: Output mode (output buffer ON)
1: Input mode (output buffer OFF)
Caution Do not change the port mode using a bit manipulation instruction (CLR1, NOT1, SET1, TST1).
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CHAPTER 12 PORT FUNCTIONS
(b) Port X mode control register (PMCX)
This register is write-only, in 8-bit units. However, the lower 5 bits are fixed at 0 by hardware, so even if 1
is written, it is disregarded.
PMCX
7
6
5
4
3
2
1
0
PMCX7
PMCX6
PMCX5
0
0
0
0
0
Note Single-chip mode 0:
00H
Single-chip mode 1:
E0H
ROM-less mode 0, 1:
E0H
Bit Position
Bit Name
Address
FFFFF45AH
After reset
Note
Function
7
PMCX7
Port Mode Control
Sets operation mode of PX7 pin.
0: Input/output port mode
1: CLKOUT output mode
6
PMCX6
Port Mode Control
Sets operation mode of PX6 pin.
0: Input/output port mode
1: WAIT input mode
5
PMCX5
Port Mode Control
Sets operation mode of PX5 pin.
0: Input/output port mode
1: REFRQ output mode
Caution Do not change the operation mode using a bit manipulation instruction (CLR1, NOT1, SET1,
TST1).
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CHAPTER 13 RESET FUNCTIONS
When a low-level signal is input to the RESET pin, a system reset is effected and the hardware is initialized.
When the RESET signal level changes from low to high, the reset state is released and program execution is
started. Register contents must be initialized as required in the program.
13.1 Features
The reset pin (RESET) incorporates a noise eliminator which uses analog delay (≅ 60 ns) to prevent malfunction
due to noise.
13.2 Pin Functions
Note
During a system reset, most pins (all but the CLKOUT
, RESET, X2, HVDD, VDD, VSS, CVDD, CVSS, AVDD, AVSS,
and AVREF pins) enter the high impedance state. Therefore, when memory is connected externally, a pull-up or pulldown resistor must be connected to the specified pins of ports 4, 5, 6, 8, 9, A, B, and X. If no resister is connected
there, memory contents may be lost when these pins enter high impedance state. For the same reason, the output
pins of the internal peripheral I/O functions and output ports should be handled in the same manner.
Note In ROM-less modes 0 and 1, and in single-chip mode 1, the CLKOUT signal is output even during reset. In
single-chip mode 0, the CLKOUT signal is not output until the PMCX register is set.
Table 13-1 shows the operating state of each output pin and each input/output pin during reset.
Table 13-1. Operating State of Each Pin During Reset
Pin Name
Pin State
When in SingleChip Mode 0
When in SingleChip Mode 1
D0 to D7, A0 to A23, CS0 to CS7, RAS0
to RAS7, LCAS, LWR, UCAS, UWR, RD,
WE, BCYST, OE, HLDAK, REFRQ
(Port mode)
High-impedance
D8 to D15
(Port mode)
High-impedance
WAIT, HLDRQ
(Port mode)
(Input)
CLKOUT
(Port mode)
Operating
Port pin
Ports 0 to 3, 10 to 12
(Input)
Ports 4, 6, 8, 9, A, B, X
(Input)
(Control mode)
Port 5
(Input)
(Control mode)
User’s Manual U12688EJ4V0UM00
When in ROMless Mode 0
When in ROMless Mode 1
(Port mode)
(Input)
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CHAPTER 13 RESET FUNCTIONS
(1) Receiving the reset signal
RESET (input)
Analog
delay
Analog
delay
Analog
delay
Eliminate as a noise
Internal system
reset signal
Note
∆
∆
Reset
acceptance
Reset
release
Note The internal system reset signal continues in the active state for at least 4 system clock cycles after
reset clear timing by the RESET signal.
(2) Reset during power on
In the reset operation during power on (when the power is turned on), in accordance with the low-level width of
the RESET signal, it is necessary to secure an oscillation stabilization time of 10 ms or greater from power rise
to the reception of the reset.
HVDD
RESET (input)
Oscillation stabilization
time
Analog delay
∆
Reset release
13.3 Initialization
The initial values of the CPU, internal RAM and internal peripheral I/O after reset are shown in Table 13-2.
Initialize the contents of each register as necessary during program operation. Particularly, the registers shown
below are related to system settings, so set them as necessary.
{ Power save control register (PSC): Sets the functions of pins X1 and X2, the operation of the CLKOUT pin, etc.
{ Data wait control register (DWC): Sets the number of data wait states.
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CHAPTER 13 RESET FUNCTIONS
Table 13-2. Initial Values of CPU, Internal RAM, and Internal Peripheral I/O after Reset (1/2)
Internal Hardware
CPU
Program registers
System registers
Register Name
General-purpose register (r0)
00000000H
General-purpose registers (r1 to r31)
Undefined
Program counter (PC)
00000000H
Status saving register during interrupt (EIPC, EIPSW)
Undefined
Status saving register during NMI (FEPC, FEPSW)
Undefined
Interrupt control register (ECR)
00000000H
Program status word (PSW)
00000020H
Status saving register during CALLT execution (CTPC, CTPSW)
Undefined
Status saving register during exception trap (DBPC, DBPSW)
Undefined
CALLT base pointer (CTBP)
Undefined
Internal RAM
Internal peripheral I/O
Bus control
functions
Memory control
functions
DMA functions
Interrupt/exception
control functions
Initial Value After Reset
—
Undefined
Command register (PRCMD)
Undefined
Data wait control register (DWC1)
FFFFH
Data wait control register (DWC2)
FFH
Bus cycle control register (BCC)
5555H
Bus cycle type configuration register (BCT)
0000H
Bus size configuration register (BSC)
5555H/0000H
DRAM configuration registers (DRC0 to DRC3)
3FC1H
DRAM type configuration register (DTC)
0000H
Page ROM configuration register (PRC)
E0H
Refresh control registers (RFC0 to RFC3)
0000H
Refresh wait control register (RWC)
00H
Control registers (DADC0 to DADC3)
0000H
Source address registers (DSA0H to DSA3H, DSA0L to DSA3L)
Undefined
Channel control registers (DCHC0 to DCHC3)
00H
Destination address registers (DDA0H to DDA3H, DDA0L to DDA3L)
Undefined
Trigger factor registers (DTFR0 to DTFR3)
00H
Byte count registers (DBC0 to DBC3)
Undefined
Fly-by transfer data wait control register (FDW)
00H
DMA disable status register (DDIS)
00H
DMA restart register (DRST)
00H
In-service priority register (ISPR)
00H
External interrupt mode registers (INTM0 to INTM6)
00H
Interrupt control registers (OVIC10 to OVIC15, CMIC40, CMIC41,
P10IC0 to P10IC3, P11IC0 to P11IC3, P12IC0 to P12IC3, P13IC0 to
P13IC3, P14IC0 to P14IC3, P15IC0 to P15IC3, DMAIC0 to DMAIC3,
CSIC0 to CSIC3, SEIC0, STIC0, SRIC0, SRIC1, SEIC1, STIC1,
ADIC)
47H
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CHAPTER 13 RESET FUNCTIONS
Table 13-2. Initial Values of CPU, Internal RAM, and Internal Peripheral I/O after Reset (2/2)
Internal Hardware
Internal
peripheral
I/O
Clock generator
functions
Timer/counter
functions
Serial interface
functions
A/D converters
Port functions
Register Name
Initial Value After Reset
System status register (SYS)
0000000×B
Clock control register (CKC)
00H
Power save control register (PSC)
00H
Capture/compare registers (CC100 to CC103, CC110 to CC113,
CC120 to CC123, CC130 to CC133, CC140 to CC143, CC150 to
CC153)
Undefined
Compare registers (CM40, CM41)
Undefined
Timer overflow status register (TOVS)
00H
Timer control register (TMC10 to TMC15, TMC40, TMC41)
00H
Timer unit mode register (TUM10 to TUM15)
0000H
Timers (TM10 to TM15, TM40, TM41)
0000H
Timer output control registers (TOC10 to TOC15)
00H
Asynchronous serial interface status registers (ASIS0, ASIS1)
00H
Asynchronous serial interface mode registers (ASIM00, ASIM10)
80H
Asynchronous serial interface mode registers (ASIM01, ASIM11)
00H
Receive buffers (RXB0, RXB1, RXB0L, RXB1L)
Undefined
Transmit shift registers (TXS0, TXS1, TXS0L, TXS1L)
Undefined
Clocked serial interface mode registers (CSIM0 to CSIM3)
00H
Serial I/O shift registers (SIO0 to SIO3)
Undefined
Baud rate generator compare registers (BRGC0 to BRGC2)
Undefined
Baud rate generator prescaler mode registers (BPRM0 to BPRM2)
00H
Mode register (ADM0)
00H
Mode register (ADM1)
07H
A/D conversion result registers (ADCR0 to ADCR7, ADCR0H to
ADCR7H)
Undefined
Ports (P0 to P12, PA, PB, PX)
Undefined
Port/control select registers (PCS0, PCS1, PCS3, PCS8, PCS10,
PCS11)
00H
Mode registers (PM0 to PM12, PMA, PMB, PMX)
FFH
Mode control registers (PMC0, PMC1, PMC3, PMC10 to PMC12)
00H
Mode control register (PMC2)
01H
Mode control registers (PMC8, PCM9)
00H/FFH
Mode control register (PMCX)
00H/E0H
Memory expansion mode register (MM)
00H/07H/0FH
Caution “Undefined” in the above table is undefined during power-on reset, or undefined as a result of
data destruction when RESET is input and the data writing timing has been synchronized. For
other RESETs, data is held in the same state it was in before the RESET operation.
Remark
412
×: Undefined
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CHAPTER 14 FLASH MEMORY (µPD70F3102, 70F3102A)
The µPD70F3102 and 70F3102A are V850E/MS1 on-chip flash memory products with a 128KB flash memory. In
the instruction fetch to this flash memory, 4 bytes can be accessed by a single clock, just as in the mask ROM
version.
Writing to flash memory can be performed with the device mounted on the target system (on board). A dedicated
flash programmer is connected to the target system to perform writing.
The following can be considered as the development environment and applications of flash memory.
• Software can be altered after the V850E/MS1 is solder-mounted on the target system.
• Small-scale production of various models is made easier by differentiating software.
• Data adjustment in starting mass production is made easier.
14.1 Features
• 4-byte/1-clock access (in instruction fetch access)
• All area one-shot erase
• Erase in 4KB block units
• Communication through serial interface from the dedicated flash programmer
• Erase/write voltage: VPP = 7.8 V
• On-board programming
• Number of rewrites: 100 times (target)
14.2 Writing by Flash Programmer
Writing can be performed either on-board or off-board by the dedicated flash programmer.
(1) On-board programming
The contents of the flash memory are rewritten after the V850E/MS1 is mounted on the target system. Mount
connectors, etc., on the target system to connect the dedicated flash programmer.
(2) Off-board programming
Writing to flash memory is performed by the dedicated program adapter (FA Series), etc., before mounting the
V850E/MS1 on the target system.
Remark
The FA Series is a product of Naito Densei Machida Mfg. Co., Ltd.
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CHAPTER 14 FLASH MEMORY (µPD70F3102, 70F3102A)
14.3 Programming Environment
The following shows the environment required for writing programs to the flash memory of the V850E/MS1.
VPP
VDD
RS-232-C
VSS
RESET
UART0/CSI0
Host machine
Dedicated flash
programmer
V850E/MS1
A host machine is required for controlling the dedicated flash programmer.
UART0 or CSI0 is used for the interface between the dedicated flash programmer and the V850E/MS1 to perform
writing, erasing, etc. A dedicated program adapter (FA Series) is required for off-board writing.
14.4 Communication System
(1) UART0
Transfer rate: 4,800 to 76,800 bps (LSB first)
VPP
VDD
VSS
RESET
TXD0
Dedicated flash
programmer
RXD0
V850E/MS1
Clock
(2) CSI0
Transfer rate: up to 10 Mbps (MSB first)
VPP
VDD
VSS
RESET
SO0
Dedicated flash
programmer
SI0
SCK0
V850E/MS1
Clock
The dedicated flash programmer outputs the transfer clock, and the V850E/MS1 operates as a slave.
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CHAPTER 14 FLASH MEMORY (µPD70F3102, 70F3102A)
14.5 Pin Handling
When performing on-board writing, install a connector on the target system to connect to the dedicated flash
programmer. Also, install a function on-board to switch from the normal operation mode (single-chip modes 0 and 1
or ROM-less modes 0 and 1) to the flash memory programming mode.
When switched to the flash memory programming mode, all the pins not used for the flash memory programming
become the same status as that immediately after reset of single-chip mode 0. Therefore, all the ports become output
high-impedance status, so that pin handling is required when the external device does not acknowledge the output
high-impedance status.
14.5.1 MODE3/VPP pin
In the normal operation mode, 0 V is input to the MODE3/VPP pin. In the flash memory programming mode, 7.8 V
writing voltage is supplied to the MODE3/VPP pin.
The following shows an example of the connection of the
MODE3/VPP pin.
V850E/MS1
Dedicated flash programmer connection pin
MODE3/VPP
Pull-down resistor (RVPP)
14.5.2 Serial interface pin
The following shows the pins used by each serial interface.
Serial Interface
Pins Used
CSI0
SO0, SI0, SCK0
UART0
TXD0, RXD0
When connecting a dedicated flash programmer to a serial interface pin that is connected to other devices onboard, care should be taken to avoid the conflict of signals and the malfunction of other devices, etc.
(1) Conflict of signals
When connecting a dedicated flash programmer (output) to a serial interface pin (input) which is connected to
another device (output), conflict of signals occurs. To avoid the conflict of signals, isolate the connection to the
other device or set the other device to the output high-impedance status.
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CHAPTER 14 FLASH MEMORY (µPD70F3102, 70F3102A)
V850E/MS1
Conflict of signals
Dedicated flash programmer connection pin
Input pin
Other device
Output pin
In the flash memory programming mode, the signal that the
dedicated flash programmer sends out conflicts with signals the
other device outputs. Therefore, isolate the signals on the other
device side.
(2) Malfunction of the other device
When connecting a dedicated flash programmer (output or input) to a serial interface pin (input or output)
connected to another device (input), the signal output to the other device may cause the device to malfunction.
To avoid this, isolate the connection to the other device or make the setting so that the input signal to the other
device is ignored.
V850E/MS1
Dedicated flash programmer connection pin
Output pin
Other device
Input pin
In the flash memory programming mode, if the signal the
V850E/MS1 outputs affects the other device, isolate the
signal on the other device side.
V850E/MS1
Dedicated flash programmer connection pin
Input pin
Other device
Input pin
In the flash memory programming mode, if the signal the
dedicated flash programmer outputs affects the other
device, isolate the signal on the other device side.
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CHAPTER 14 FLASH MEMORY (µPD70F3102, 70F3102A)
14.5.3 RESET pin
When connecting the reset signals of the dedicated flash programmer to the RESET pin that is connected to the
reset signal generation circuit on-board, conflict of signals occurs.
To avoid the conflict of signals, isolate the
connection to the reset signal generator.
When reset signal is input from the user system during the flash memory programming mode, programming
operation will not be performed correctly. Therefore, do not input signals other than the reset signals from the
dedicated flash programmer.
V850E/MS1
Conflict of signals
Dedicated flash programmer connection pin
RESET
Reset signal generator
Output pin
In the flash memory programming mode, the signal
the reset signal generation circuit outputs conflicts
with the signal the dedicated flash programmer
outputs. Therefore, isolate the signals on the reset
signal generator side.
14.5.4 NMI pin
Do not change the input signal to the NMI pin during the flash memory programming mode. If the NMI pin is
changed during the flash memory programming mode, the programming may not be performed correctly.
14.5.5 MODE0 to MODE2 pins
If MODE0 to MODE2 are set as follows and a write voltage (7.8 V) is applied to the MODE3/VPP pin and reset is
canceled, these pins change to the flash memory programming mode.
• MODE0: Low-level input
• MODE1: High-level input
• MODE2: Low-level input
14.5.6 Port pin
When the flash memory programming mode is set, all the port pins except the pins which communicate with the
dedicated flash programmer become output high-impedance status.
necessary.
The treatment of these port pins is not
If problems such as disabling output high-impedance status should occur to the external devices
connected to the port, connect them to VDD or VSS through resistors.
14.5.7 WAIT pin
Input high- or low-level signals relative to HVDD to WAIT pin.
14.5.8 Other signal pins
Connect X1, X2, and AVREF to the same status as that in the normal operation mode.
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CHAPTER 14 FLASH MEMORY (µPD70F3102, 70F3102A)
14.5.9 Power supply
Supply the power supply (VDD, HVDD, VSS, AVDD, AVSS, CVDD, and CVSS) the same as that in normal operation
mode. Connect VDD and GND of the dedicated flash programmer to VDD and VSS. (VDD of the dedicated flash
programmer is provided with power supply monitoring function.)
14.6 Programming Method
14.6.1 Flash memory control
The following shows the procedure for manipulating the flash memory.
Start
Supply RESET pulse
Switch to flash memory programming mode
Select communication system
Manipulate flash memory
End?
Yes
Ends
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CHAPTER 14 FLASH MEMORY (µPD70F3102, 70F3102A)
14.6.2 Flash memory programming mode
When rewriting the contents of flash memory using the dedicated flash programmer, set the V850E/MS1 in the
flash memory programming mode. When switching modes, set the MODE0 to MODE2 and MODE3/VPP pins before
releasing reset.
When performing on-board writing, change modes using a jumper, etc.
• MODE0: Low-level input
• MODE1: High-level input
• MODE2: Low-level input
• MODE3/VPP: 7.8 V
Flash memory programming mode
××0
MODE0 to MODE2
010
7.8 V
1
2
…
n
MODE3/VPP 3 V
0V
RESET
Remark
×: don’t care
14.6.3 Selection of communication mode
In the V850E/MS1, a communication mode is selected by inputting pulses (16 pulses max.) to VPP pin after
switching to the flash memory programming mode. The VPP pulse is generated by the dedicated flash programmer.
The following shows the relationship between the number of pulses and the communication modes.
Table 14-1. List of Communication Modes
VPP Pulse
Communication Mode
Remarks
0
CSI0
V850E/MS1 performs slave operation, MSB first
8
UART0
Communication rate: 9600 bps (after reset), LSB first
Others
RFU (reserved)
Setting prohibited
Caution When UART0 is selected, the receive clock is calculated based on the reset command sent from
the dedicated flash programmer after receiving the V PP pulse.
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CHAPTER 14 FLASH MEMORY (µPD70F3102, 70F3102A)
14.6.4 Communication command
The V850E/MS1 communicates with the dedicated flash programmer by means of commands. A command sent
from the dedicated flash programmer to the V850E/MS1 is called a “command”. The response signal sent from the
V850E/MS1 to the dedicated flash programmer is called a “response command”.
Command
Response
command
Dedicated flash programmer
V850E/MS1
The following shows the commands of the firmware for flash memory control of the V850E/MS1. All of these
commands are issued from the dedicated flash programmer, and the V850E/MS1 performs the various processing
corresponding to the commands.
Category
Verify
Erase
Blank check
Data write
System setting and control
420
Command Name
Function
One-shot verify command
Compares the contents of the entire memory and
the input data.
Block verify command
Compares the contents of the specified memory
block and the input data.
One-shot erase command
Erases the contents of the entire memory.
Block erase command
Erases the contents of the specified memory block
setting 4 Kbytes as one memory block.
Write back command
Writes back the contents that is over-erased.
One-shot blank check command
Checks the erase state of the entire memory.
Block blank check command
Checks the erase of the specified memory block.
High-speed write command
Writes data by the specification of the write
address and the number of bytes to be written,
and executes verify check.
Continuous write command
Writes data from the address following the highspeed write command executed immediately
before, and executes verify check.
Status read out command
Acquires the status of operations.
Oscillating frequency setting command
Sets the oscillating frequency.
Erasing time setting command
Sets the erasing time of one-shot erase.
Writing time setting command
Sets the writing time of data write.
Write back time setting command
Sets the write back time.
Baud rate setting command
Sets the baud rate when using UART0.
Silicon signature command
Reads outs the silicon signature information.
Reset command
Escapes from each state.
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CHAPTER 14 FLASH MEMORY (µPD70F3102, 70F3102A)
The V850E/MS1 sends back response commands to the commands issued from the dedicated flash programmer.
The following shows the response commands the V850E/MS1 sends out.
Response Command Name
Function
ACK (acknowledge)
Acknowledges command/data, etc.
NAK (not acknowledge)
Acknowledges illegal command/data, etc.
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[MEMO]
422
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APPENDIX A REGISTER INDEX
(1/8)
Register Symbol
Register Name
Unit
Page
ADCR0
A/D conversion result register 0
ADC
321
ADCR0H
A/D conversion result register 0H
ADC
321
ADCR1
A/D conversion result register 1
ADC
321
ADCR1H
A/D conversion result register 1H
ADC
321
ADCR2
A/D conversion result register 2
ADC
321
ADCR2H
A/D conversion result register 2H
ADC
321
ADCR3
A/D conversion result register 3
ADC
321
ADCR3H
A/D conversion result register 3H
ADC
321
ADCR4
A/D conversion result register 4
ADC
321
ADCR4H
A/D conversion result register 4H
ADC
321
ADCR5
A/D conversion result register 5
ADC
321
ADCR5H
A/D conversion result register 5H
ADC
321
ADCR6
A/D conversion result register 6
ADC
321
ADCR6H
A/D conversion result register 6H
ADC
321
ADCR7
A/D conversion result register 7
ADC
321
ADCR7H
A/D conversion result register 7H
ADC
321
ADIC
Interrupt control register
INTC
217
ADM0
A/D converter mode register 0
ADC
318
ADM1
A/D converter mode register 1
ADC
320
ASIM00
Asynchronous serial interface mode register 00
UART0
287
ASIM01
Asynchronous serial interface mode register 01
UART0
290
ASIM10
Asynchronous serial interface mode register 10
UART1
287
ASIM11
Asynchronous serial interface mode register 11
UART1
290
ASIS0
Asynchronous serial interface status register 0
UART0
291
ASIS1
Asynchronous serial interface status register 1
UART1
291
BCC
Bus cycle control register
BCU
117
BCT
Bus cycle type configuration register
BCU
105
BPRM0
Baud rate generator prescaler mode register 0
BRG0
314
BPRM1
Baud rate generator prescaler mode register 1
BRG1
314
BPRM2
Baud rate generator prescaler mode register 2
BRG2
314
BRGC0
Baud rate generator compare register 0
BRG0
313
BRGC1
Baud rate generator compare register 1
BRG1
313
BRGC2
Baud rate generator compare register 2
BRG2
313
BSC
Bus size configuration register
BCU
108
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APPENDIX A REGISTER INDEX
(2/8)
Register Symbol
Register Name
Unit
Page
CC100
Capture/compare register 100
RPU
252
CC101
Capture/compare register 101
RPU
252
CC102
Capture/compare register 102
RPU
252
CC103
Capture/compare register 103
RPU
252
CC110
Capture/compare register 110
RPU
252
CC111
Capture/compare register 111
RPU
252
CC112
Capture/compare register 112
RPU
252
CC113
Capture/compare register 113
RPU
252
CC120
Capture/compare register 120
RPU
252
CC121
Capture/compare register 121
RPU
252
CC122
Capture/compare register 122
RPU
252
CC123
Capture/compare register 123
RPU
252
CC130
Capture/compare register 130
RPU
252
CC131
Capture/compare register 131
RPU
252
CC132
Capture/compare register 132
RPU
252
CC133
Capture/compare register 133
RPU
252
CC140
Capture/compare register 140
RPU
252
CC141
Capture/compare register 141
RPU
252
CC142
Capture/compare register 142
RPU
252
CC143
Capture/compare register 143
RPU
252
CC150
Capture/compare register 150
RPU
252
CC151
Capture/compare register 151
RPU
252
CC152
Capture/compare register 152
RPU
252
CC153
Capture/compare register 153
RPU
252
CKC
Clock control register
CG
233
CM40
Compare register 40
RPU
253
CM41
Compare register 41
RPU
253
CMIC40
Interrupt control register
INTC
217
CMIC41
Interrupt control register
INTC
217
CSIC0
Interrupt control register
INTC
217
CSIC1
Interrupt control register
INTC
217
CSIC2
Interrupt control register
INTC
217
CSIC3
Interrupt control register
INTC
217
CSIM0
Clocked serial interface mode register 0
CSI0
301
CSIM1
Clocked serial interface mode register 1
CSI1
301
CSIM2
Clocked serial interface mode register 2
CSI2
301
CSIM3
Clocked serial interface mode register 3
CSI3
301
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User’s Manual U12688EJ4V0UM00
APPENDIX A REGISTER INDEX
(3/8)
Register Symbol
Register Name
Unit
Page
CTBP
CALLT base pointer
CPU
72
CTPC
Status saving register during CALLT execution
CPU
72
CTPSW
Status saving register during CALLT execution
CPU
72
DADC0
DMA addressing control register 0
DMAC
168
DADC1
DMA addressing control register 1
DMAC
168
DADC2
DMA addressing control register 2
DMAC
168
DADC3
DMA addressing control register 3
DMAC
168
DBC0
DMA byte count register 0
DMAC
167
DBC1
DMA byte count register 1
DMAC
167
DBC2
DMA byte count register 2
DMAC
167
DBC3
DMA byte count register 3
DMAC
167
DBPC
Status saving register during exception trap
CPU
72
DBPSW
Status saving register during exception trap
CPU
72
DCHC0
DMA channel control register 0
DMAC
170
DCHC1
DMA channel control register 1
DMAC
170
DCHC2
DMA channel control register 2
DMAC
170
DCHC3
DMA channel control register 3
DMAC
170
DDA0H
DMA destination address register 0H
DMAC
165
DDA0L
DMA destination address register 0L
DMAC
166
DDA1H
DMA destination address register 1H
DMAC
165
DDA1L
DMA destination address register 1L
DMAC
166
DDA2H
DMA destination address register 2H
DMAC
165
DDA2L
DMA destination address register 2L
DMAC
166
DDA3H
DMA destination address register 3H
DMAC
165
DDA3L
DMA destination address register 3L
DMAC
166
DDIS
DMA disable status register
BCU
173
DMAIC0
Interrupt control register
INTC
217
DMAIC1
Interrupt control register
INTC
217
DMAIC2
Interrupt control register
INTC
217
DMAIC3
Interrupt control register
INTC
217
DRC0
DRAM configuration register 0
BCU
139
DRC1
DRAM configuration register 1
BCU
139
DRC2
DRAM configuration register 2
BCU
139
DRC3
DRAM configuration register 3
BCU
139
DRST
DMA restart register
BCU
173
DSA0H
DMA source address register 0H
DMAC
163
DSA0L
DMA source address register 0L
DMAC
164
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APPENDIX A REGISTER INDEX
(4/8)
Register Symbol
Register Name
Unit
Page
DSA1H
DMA source address register 1H
DMAC
163
DSA1L
DMA source address register 1L
DMAC
164
DSA2H
DMA source address register 2H
DMAC
163
DSA2L
DMA source address register 2L
DMAC
164
DSA3H
DMA source address register 3H
DMAC
163
DSA3L
DMA source address register 3L
DMAC
164
DTC
DRAM type configuration register
BCU
142
DTFR0
DMA trigger factor register 0
DMAC
171
DTFR1
DMA trigger factor register 1
DMAC
171
DTFR2
DMA trigger factor register 2
DMAC
171
DTFR3
DMA trigger factor register 3
DMAC
171
DWC1
Data wait control register 1
BCU
113
DWC2
Data wait control register 2
BCU
113
ECR
Interrupt source register
CPU
72
EIPC
Status saving register during interrupt
CPU
72
EIPSW
Status saving register during interrupt
CPU
72
FDW
Flyby transfer data wait control register
BCU
174
FEPC
Status saving register during NMI
CPU
72
FEPSW
Status saving register during NMI
CPU
72
INTM0
External interrupt mode register 0
INTC
208
INTM1
External interrupt mode register 1
INTC
221
INTM2
External interrupt mode register 2
INTC
221
INTM3
External interrupt mode register 3
INTC
221
INTM4
External interrupt mode register 4
INTC
221
INTM5
External interrupt mode register 5
INTC
221
INTM6
External interrupt mode register 6
INTC
221
ISPR
In-service priority register
INTC
218
MM
Memory expansion mode register
Port
87
OVIC10
Interrupt control register
INTC
216
OVIC11
Interrupt control register
INTC
216
OVIC12
Interrupt control register
INTC
216
OVIC13
Interrupt control register
INTC
217
OVIC14
Interrupt control register
INTC
217
OVIC15
Interrupt control register
INTC
217
P0
Port 0
Port
368
P1
Port 1
Port
371
P2
Port 2
Port
374
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APPENDIX A REGISTER INDEX
(5/8)
Register Symbol
Register Name
Unit
Page
P3
Port 3
Port
377
P4
Port 4
Port
380
P5
Port 5
Port
382
P6
Port 6
Port
384
P7
Port 7
Port
386
P8
Port 8
Port
387
P9
Port 9
Port
391
P10
Port 10
Port
394
P10IC0
Interrupt control register
INTC
217
P10IC1
Interrupt control register
INTC
217
P10IC2
Interrupt control register
INTC
217
P10IC3
Interrupt control register
INTC
217
P11
Port 11
Port
397
P11IC0
Interrupt control register
INTC
217
P11IC1
Interrupt control register
INTC
217
P11IC2
Interrupt control register
INTC
217
P11IC3
Interrupt control register
INTC
217
P12
Port 12
Port
401
P12IC0
Interrupt control register
INTC
217
P12IC1
Interrupt control register
INTC
217
P12IC2
Interrupt control register
INTC
217
P12IC3
Interrupt control register
INTC
217
P13IC0
Interrupt control register
INTC
217
P13IC1
Interrupt control register
INTC
217
P13IC2
Interrupt control register
INTC
217
P13IC3
Interrupt control register
INTC
217
P14IC0
Interrupt control register
INTC
217
P14IC1
Interrupt control register
INTC
217
P14IC2
Interrupt control register
INTC
217
P14IC3
Interrupt control register
INTC
217
P15IC0
Interrupt control register
INTC
217
P15IC1
Interrupt control register
INTC
217
P15IC2
Interrupt control register
INTC
217
P15IC3
Interrupt control register
INTC
217
PA
Port A
Port
403
PB
Port B
Port
405
PC
Program counter
CPU
71
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427
APPENDIX A REGISTER INDEX
(6/8)
Register Symbol
Register Name
Unit
Page
PCS0
Port/control select register 0
Port
370
PCS1
Port/control select register 1
Port
373
PCS3
Port/control select register 3
Port
380
PCS8
Port/control select register 8
Port
390
PCS10
Port/control select register 10
Port
396
PCS11
Port/control select register 11
Port
400
PM0
Port 0 mode register
Port
368
PM1
Port 1 mode register
Port
371
PM2
Port 2 mode register
Port
375
PM3
Port 3 mode register
Port
378
PM4
Port 4 mode register
Port
381
PM5
Port 5 mode register
Port
383
PM6
Port 6 mode register
Port
385
PM8
Port 8 mode register
Port
388
PM9
Port 9 mode register
Port
392
PM10
Port 10 mode register
Port
394
PM11
Port 11 mode register
Port
398
PM12
Port 12 mode register
Port
401
PMA
Port A mode register
Port
403
PMB
Port B mode register
Port
405
PMC0
Port 0 mode control register
Port
369
PMC1
Port 1 mode control register
Port
372
PMC2
Port 2 mode control register
Port
376
PMC3
Port 3 mode control register
Port
379
PMC8
Port 8 mode control register
Port
389
PMC9
Port 9 mode control register
Port
393
PMC10
Port 10 mode control register
Port
395
PMC11
Port 11 mode control register
Port
399
PMC12
Port 12 mode control register
Port
402
PMCX
Port X mode control register
Port
408
PMX
Port X mode register
Port
407
PRC
Page ROM configuration register
BCU
134
PRCMD
Command register
CPU
101
PSC
Power save control register
CPU
237
PSW
Program status word
CPU
73
PX
Port X
Port
407
r0 to r31
General register
CPU
71
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User’s Manual U12688EJ4V0UM00
APPENDIX A REGISTER INDEX
(7/8)
Register Symbol
Register Name
Unit
Page
RFC0
Refresh control register 0
BCU
153
RFC1
Refresh control register 1
BCU
153
RFC2
Refresh control register 2
BCU
153
RFC3
Refresh control register 3
BCU
153
RWC
Refresh wait control register
BCU
156
RXB0
Receive buffer 0 (9 bits)
UART0
292
RXB0L
Receive buffer 0L (Lower order 8 bits)
UART0
292
RXB1
Receive buffer 1 (9 bits)
UART1
292
RXB1L
Receive buffer 1L (Lower order 8 bits)
UART1
292
SEIC0
Interrupt control register
INTC
217
SEIC1
Interrupt control register
INTC
217
SIO0
Serial I/O shift register 0
CSI0
303
SIO1
Serial I/O shift register 1
CSI1
303
SIO2
Serial I/O shift register 2
CSI2
303
SIO3
Serial I/O shift register 3
CSI3
303
SRIC0
Interrupt control register
INTC
217
SRIC1
Interrupt control register
INTC
217
STIC0
Interrupt control register
INTC
217
STIC1
Interrupt control register
INTC
217
SYS
System status register
CPU
102
TM10
Timer 10
RPU
251
TM11
Timer 11
RPU
251
TM12
Timer 12
RPU
251
TM13
Timer 13
RPU
251
TM14
Timer 14
RPU
251
TM15
Timer 15
RPU
251
TM40
Timer 40
RPU
253
TM41
Timer 41
RPU
253
TMC10
Timer control register 10
RPU
257
TMC11
Timer control register 11
RPU
257
TMC12
Timer control register 12
RPU
257
TMC13
Timer control register 13
RPU
257
TMC14
Timer control register 14
RPU
257
TMC15
Timer control register 15
RPU
257
TMC40
Timer control register 40
RPU
259
TMC41
Timer control register 41
RPU
259
TOC10
Timer output control register 10
RPU
260
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APPENDIX A REGISTER INDEX
(8/8)
Register Symbol
Register Name
Unit
Page
TOC11
Timer output control register 11
RPU
260
TOC12
Timer output control register 12
RPU
260
TOC13
Timer output control register 13
RPU
260
TOC14
Timer output control register 14
RPU
260
TOC15
Timer output control register 15
RPU
260
TOVS
Timer overflow status register
RPU
261
TUM10
Timer unit mode register 10
RPU
254
TUM11
Timer unit mode register 11
RPU
254
TUM12
Timer unit mode register 12
RPU
254
TUM13
Timer unit mode register 13
RPU
254
TUM14
Timer unit mode register 14
RPU
254
TUM15
Timer unit mode register 15
RPU
254
TXS0
Transmit shift register 0 (9 bits)
UART0
293
TXS0L
Transmit shift register 0L (Lower order 8 bits)
UART0
293
TXS1
Transmit shift register 1 (9 bits)
UART1
293
TXS1L
Transmit shift register 1L (Lower order 8 bits)
UART1
293
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User’s Manual U12688EJ4V0UM00
APPENDIX B INSTRUCTION SET LIST
B.1 General Examples
(1) Register symbols used to describe operands
Register Symbol
Explanation
reg1
General registers (r0 to r31): Used as source registers.
reg2
General registers (r0 to r31): Used mainly as destination registers.
reg3
General registers (r0 to r31): Used mainly to store the remainders of division results and the higher order 3
bits of multiplication results.
immX
X bit immediate
dispX
X bit displacement
regID
System register number
bit#3
3-bit data for specifying the bit number
ep
Element pointer (r30)
cccc
4-bit data which show the conditions code
vector
5-bit data which specify the trap vector (00H to 1FH)
listX
X item register list
(2) Register symbols used to describe op codes
Register Symbol
Explanation
R
1-bit data of a code which specifies reg1 or regID
r
1-bit data of the code which specifies reg2
w
1-bit data of the code which specifies reg3
d
1-bit displacement data
i
1-bit immediate data
cccc
4-bit data which show the conditions code
bbb
3-bit data for specifying the bit number
L
1-bit data which specifies a register list
(3) Register symbols used in operation (1/2)
Register Symbol
Explanation
←
Input for
GR [ ]
General register
SR [ ]
System register
zero-extend (n)
Expand n with zeros until word length.
sign-extend (n)
Expand n with signs until word length.
load-memory (a, b)
Read data from address a until size b.
store-memory (a, b, c)
Write data b in address a to size c.
load-memory-bit (a, b)
Read bit b of address a.
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APPENDIX B INSTRUCTION SET LIST
(3) Register symbols used in operation (2/2)
Register Symbol
Explanation
store-memory-bit (a, b, c)
Write bit b of address a to c.
saturated (n)
Execute saturated processing of n (n is a 2’s complement).
If, as a result of calculations,
n ≥ 7FFFFFFFH, let it be 7FFFFFFFH.
n ≤ 80000000H, let it be 80000000H.
result
Reflects the results in a flag.
Byte
Byte (8 bits)
Half-word
Half word (16 bits)
Word
Word (32 bits)
+
Addition
–
Subtraction
ll
Bit concatenation
×
Multiplication
÷
Division
%
Remainder from division results
AND
Logical product
OR
Logical sum
XOR
Exclusive OR
NOT
Logical negation
logically shift left by
Logical shift left
logically shift right by
Logical shift right
arithmetically shift right by
Arithmetic shift right
(4) Register symbols used in an execution clock
Register Symbol
Explanation
i : issue
If executing another instruction immediately after executing the first instruction.
r : repeat
If repeating execution of the same instruction immediately after executing the first instruction.
l : latency
If referring to the results of instruction execution immediately after execution using another instruction.
(5) Register symbols used in flag operations
Identifier
Explanation
(Blank)
No change
0
Clear to 0
X
Set or cleared in accordance with the results.
R
Previously saved values are restored.
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User’s Manual U12688EJ4V0UM00
APPENDIX B INSTRUCTION SET LIST
(6) Condition codes
Condition Name
(cond)
Condition Code
(cccc)
Condition Formula
Explanation
V
0 0 0 0
OV = 1
Overflow
NV
1 0 0 0
OV = 0
No overflow
C/L
0 0 0 1
CY = 1
Carry
Lower (Less than)
NC/NL
1 0 0 1
CY = 0
No carry
Not lower (Greater than or equal)
Z/E
0 0 1 0
Z=1
Zero
Equal
NZ/NE
1 0 1 0
Z=0
Not zero
Not equal
NH
0 0 1 1
(CY or Z) = 1
Not higher (Less than or equal)
H
1 0 1 1
(CY or Z) = 0
Higher (Greater than)
N
0 1 0 0
S=1
Negative
P
1 1 0 0
S=0
Positive
T
0 1 0 1
SA
1 1 0 1
SAT = 1
Saturated
LT
0 1 1 0
(S xor OV) = 1
Less than signed
GE
1 1 1 0
(S xor OV) = 0
Greater than or equal signed
LE
0 1 1 1
((S xor OV) or Z) = 1
Less than or equal signed
GT
1 1 1 1
((S xor OV) or Z) = 0
Greater than signed
—
Always (Unconditional)
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APPENDIX B INSTRUCTION SET LIST
B.2 Instruction Set (in Alphabetical Order)
(1/6)
Mnemonic
Operand
Op Code
Operation
Flags
Execution
Clock
ADD
ADDI
i
r
l
CY OV S
Z SAT
reg1,reg2
rrrrr001110RRRRR
GR[reg2]←GR[reg2]+GR[reg1]
1
1
1
×
×
×
×
imm5,reg2
rrrrr010010iiiii
GR[reg2]←GR[reg2]+sign-extend(imm5)
1
1
1
×
×
×
×
rrrrr110000RRRRR
GR[reg2]←GR[reg1]+sign-extend(imm16)
1
1
1
×
×
×
×
imm16,reg1,reg2
i i i i i i i i i i i i i i i i
AND
reg1,reg2
rrrrr001010RRRRR
GR[reg2]←GR[reg2]AND GR[reg1]
1
1
1
0
×
×
ANDI
imm16,reg1,reg2
rrrrr110110RRRRR
GR[reg2]←GR[reg1]AND zero-extend(imm16)
1
1
1
0
0
×
2
2
2
i i i i i i i i i i i i i i i i
Bcond
disp9
ddddd1011dddc ccc
if conditions are satisfied
Note 1 then PC←PC+sign-extend(disp9)
When conditions
are satisfied
When conditions
Note 2 Note 2 Note 2
1
1
1
1
1
1
×
0
×
×
1
1
1
×
0
×
×
4
4
4
3
3
3
are not satisfied
BSH
BSW
CALLT
reg2,reg3
reg2,reg3
imm6
rrrrr11111100000
GR[reg3]←GR[reg2] (23 : 16) ll GR[reg2] (31 : 24) ll
wwwww01101000010
GR[reg2] (7 : 0) ll GR[reg2] (15 : 8)
rrrrr11111100000
GR[reg3]←GR[reg2] (7 : 0) ll GR[reg2] (15 : 8) ll GR
wwwww01101000000
[reg2] (23 : 16) ll GR[reg2] (31 : 24)
0000001000iiiiii
CTPC←PC+2(return PC)
CTPSW←PSW
adr←CTBP+zero-extend(imm6 logically shift left by 1)
PC←CTBP+zero-extend(Load-memory(adr,Half-word))
CLR1
bit#3, disp16[reg1]
10bbb111110RRRRR adr←GR[reg1]+sign-extend(disp16)
dddddddddddddddd
Z flag←Not(Load-memory-bit(adr,bit#3))
×
Note 3 Note 3 Note 3
Store-memory-bit(adr,bit#3,0)
reg2,[reg1]
rrrrr111111RRRRR
adr←GR[reg1]
0000000011100100
Z flag←Not(Load-memory-bit(adr,reg2))
rrrrr111111iiiii
if conditions are satisfied
wwwww011000cccc0
then GR[reg3]←sign-extended(imm5)
3
3
×
3
Note 3 Note 3 Note 3
Store-memory-bit(adr,reg2,0)
CMOV
cccc,imm5,reg2,reg3
1
1
1
1
1
1
else GR[reg3]←GR[reg2]
cccc,reg1,reg2,reg3 r r r r r 1 1 1 1 1 1 R R R R R
if conditions are satisfied
wwwww011001cccc0 then GR[reg3]←GR[reg1]
else GR[reg3]←GR[reg2]
CMP
CTRET
DI
reg1,reg2
rrrrr001111RRRRR
result←GR[reg2]–GR[reg1]
1
1
1
×
×
×
×
imm5,reg2
rrrrr010011iiiii
result←GR[reg2]–sign-extend(imm5)
1
1
1
×
×
×
×
0000011111100000
PC←CTPC
3
3
3
R
R
R
R
0000000101000100
PSW←CTPSW
0000011111100000
PSW.ID←1
1
1
1
0000000101100000
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R
APPENDIX B INSTRUCTION SET LIST
(2/6)
Mnemonic
Operand
Op Code
Operation
Execution
Flags
Clock
i
DISPOSE
imm5,list12
r
l
0000011001iiiiiL
sp←sp+zero-extend(imm5 logically shift left by 2)
N+1 N+1 N+1
LLLLLLLLLLL00000
GR[reg in list12]←Load-memory(sp,Word)
Note 4 Note 4 Note 4
CY OV S
Z SAT
sp←sp+4
repeat 2 steps above until all regs in list12 is loaded
imm5,list12,[reg1]
0000011001iiiiiL
sp←sp+zero-extend(imm5 logically shift left by 2)
N+3 N+3 N+3
LLLLLLLLLLLRRRRR
GR[reg in list12]←Load-memory(sp,Word)
Note 4 Note 4 Note 4
Note 5 sp←sp+4
repeat 2 steps above until all regs in list12 is loaded
PC←GR[reg1]
DIV
DIVH
DIVHU
DIVU
reg1,reg2,reg3
35 35 35
×
×
×
Note 6
35 35 35
×
×
×
Note 6
35 35 35
×
×
×
34 34 34
×
×
×
34 34 34
×
×
×
0
×
×
rrrrr111111RRRRR
GR[reg2]←GR[reg2}÷GR[reg1]
wwwww01011000000
GR[reg3]←GR[reg2]%GR[reg1]
reg1,reg2
rrrrr000010RRRRR
GR[reg2]←GR[reg2]÷GR[reg1]
reg1,reg2,reg3
rrrrr111111RRRRR
GR[reg2]←GR[reg2]÷GR[reg1]
wwwww01010000000
GR[reg3]←GR[reg2]%GR[reg1]
rrrrr111111RRRRR
GR[reg2]←GR[reg2]÷GR[reg1]
wwwww01010000010
GR[reg3]←GR[reg2]%GR[reg1]
rrrrr111111RRRRR
GR[reg2]←GR[reg2]÷GR[reg1]
wwwww01011000010
GR[reg3]←GR[reg2]%GR[reg1]
1000011111100000
PSW.ID←0
1
1
1
Stop
1
1
1
GR[reg3]←GR[reg2](15 : 0) ll GR[reg2] (31 : 16)
1
1
1
rrrrr11110dddddd
GR[reg2]←PC+4
2
2
2
ddddddddddddddd0
PC←PC+sign-extend(disp22)
reg1,reg2,reg3
reg1,reg2,reg3
EI
Note 6
0000000101100000
HALT
0000011111100000
0000000100100000
HSW
reg2,reg3
rrrrr11111100000
×
wwwww01101000100
JARL
disp22,reg2
Note 7
JMP
[reg1]
00000000011RRRRR
PC←GR[reg1]
3
3
3
JR
disp22
0000011110dddddd
PC←PC+sign-extend(disp22)
2
2
2
adr←GR[reg1]+sign-extend(disp16)
1
1
n
1
1
1
1
ddddddddddddddd0
Note 7
LD.B
disp16[reg1],reg2
LD.BU
disp16[reg1],reg2
rrrrr111000RRRRR
dddddddddddddddd
GR[reg2]←sign-extend(Load-memory(adr,Byte))
rrrrr11110bRRRRR
adr←GR[reg1]+sign-extend(disp16)
ddddddddddddddd1
GR[reg2]←zero-extend(Load-memory(adr,Byte))
Note 9
Notes 8, 10
LD.H
disp16[reg1],reg2
n
Note11
rrrrr111001RRRRR
adr←GR[reg1]+sign-extend(disp16)
ddddddddddddddd0
GR[reg2]←sign-extend(Load-memory(adr,Half-
Note 8 word))
User’s Manual U12688EJ4V0UM00
n
Note 9
435
APPENDIX B INSTRUCTION SET LIST
(3/6)
Mnemonic
Operand
Op Code
Operation
Execution
Flags
Clock
LD.HU
disp16[reg1],reg2
rrrrr111111RRRRR
adr←GR[reg1]+sign-extend(disp16)
ddddddddddddddd1
GR[reg2]←zero-extend(Load-memory(adr,Half-
i
r
l
1
1
n
1
1
1
1
Note 8 word))
LD.W
disp16[reg1],reg2
MOV
reg2,regID
adr←GR[reg1]+sign-exend(disp16)
ddddddddddddddd1
GR[reg2]←Load-memory(adr,Word)
rrrrr111111RRRRR
Z SAT
Note11
rrrrr111001RRRRR
Note 8
LDSR
CY OV S
n
Note 9
SR[regID]←GR[reg2]
Other than
0000000000100000
regID=PSW
Note 12
regID=PSW
1
×
reg1,reg2
rrrrr000000RRRRR
GR[reg2]←GR[reg1]
1
1
1
imm5,reg2
rrrrr010000iiiii
GR[reg2]←sign-extend(imm5)
1
1
1
imm32,reg1
00000110001RRRRR GR[reg1]←imm32
2
2
2
GR[reg2]←GR[reg1]+sign-extend(imm16)
1
1
1
GR[reg2]←GR[reg1]+(imm16 ll 016)
1
1
1
GR[reg3] ll GR[reg2]←GR[reg2]xGR[reg1]
1
2
2
GR[reg3] ll GR[reg2]←GR[reg2]xsign-extend(imm9)
1
×
×
×
0
×
×
i i i i i i i i i i i i i i i i
i i i i i i i i i i i i i i i i
MOVEA
imm16,reg1,reg2
MOVHI
imm16,reg1,reg2
rrrrr110001RRRRR
i i i i i i i i i i i i i i i i
rrrrr110010RRRRR
i i i i i i i i i i i i i i i i
MUL
reg1,reg2,reg3
rrrrr111111RRRRR
wwwww01000100000
imm9,reg2,reg3
rrrrr111111iiiii
Note14
Note 13
wwwww01001llll00
MULH
MULHI
reg1,reg2
rrrrr000111RRRRR
Note 6
2
2
Note14
GR[reg2]←GR[reg2]
Note 6
1
1
2
1
1
2
GR[reg3] ll GR[reg2]←GR[reg2]xGR[reg1]
1
2
2
GR[reg3] ll GR[reg2]←GR[reg2]xzero-extend(imm9)
1
xGR[reg1]
imm5,reg2
rrrrr010111iiiii
GR[reg2]←GR[reg2]
Note 6
imm16,reg1,reg2
rrrrr110111RRRRR
GR[reg2]←GR[reg1]
Note 6
1
xsign-extend(imm5)
ximm16
1
2
i i i i i i i i i i i i i i i i
MULU
reg1,reg2,reg3
rrrrr111111RRRRR
wwwww01000100010
imm9,reg2,reg3
rrrrr111111iiiii
Note 14
Note 13
wwwww01001llll10
NOP
0000000000000000 Pass at least one clock cycle doing nothing.
NOT
reg1,reg2
rrrrr000001RRRRR
NOT1
bit#3,disp16[reg1]
01bbb111110RRRRR adr←GR[reg1]+sign-extend(disp16)
GR[reg2]←NOT(GR[reg1])
dddddddddddddddd
Z flag←Not(Load-memory-bit(adr,bit#3))
rrrrr111111RRRRR
adr←GR[reg1]
0000000011100010
Z flag←Not(Load-memory-bit(adr,reg2))
2
2
Note 14
1
1
1
1
1
1
3
3
3
×
Note 3 Note 3 Note 3
Store-memory-bit(adr,bit#3,Z flag)
reg2,[reg1]
3
3
×
3
Note 3 Note 3 Note 3
Store-memory-bit(adr,reg2,Z flag)
OR
436
reg1,reg2
rrrrr001000RRRRR
GR[reg2]←GR[reg2]OR GR[reg1]
User’s Manual U12688EJ4V0UM00
1
1
1
0
×
×
×
APPENDIX B INSTRUCTION SET LIST
(4/6)
Mnemonic
Operand
Op Code
Operation
Execution
Flags
Clock
ORI
imm16,reg1,reg2
rrrrr110100RRRRR
GR[reg2]←GR[reg1]OR zero-extend(imm16)
i
r
l
CY OV S
Z SAT
1
1
1
0
×
×
i i i i i i i i i i i i i i i i
PREPARE list12,imm5
0000011110iiiiiL
Store-memory(sp–4,GR[reg in list12],Word)
LLLLLLLLLLL00001 sp←sp–4
N+1 N+1 N+1
Note 4 Note 4 Note 4
repeat 1 step above until all regs in list12 is stored
sp←sp-zero-extend(imm5)
list12,imm5,
Note 15
sp/imm
0000011110iiiiiL
Store-memory(sp–4,GR[reg in list12],Word)
N+2 N+2 N+2
LLLLLLLLLLLff011
sp←sp–4
Note 4 Note 4 Note 4
imm16/imm32
repeat 1 step above until all regs in list12 is stored
Note17 Note17 Note17
sp←sp-zero-extend(imm5)
Note 16 ep←sp/imm
RETI
0000011111100000 if PSW.EP=1
0000000101000000 then PC
PSW
3
3
3
R
R
R
R
1
1
1
×
0
×
×
1
1
1
×
0
×
×
1
1
1
R
←EIPC
←EIPSW
else if PSW.NP=1
then
PC
←FEPC
PSW ←FEPSW
else
PC
←EIPC
PSW ←EIPSW
SAR
reg1,reg2
rrrrr111111RRRRR
GR[reg2]←GR[reg2]arithmetically shift right
0000000010100000
imm5,reg2
rrrrr010101iiiii
by GR[reg1]
GR[reg2]←GR[reg2]arithmetically shift right
by zero-extend (imm5)
SASF
cccc,reg2
rrrrr1111110cccc
if conditions are satisfied
0000001000000000
then GR[reg2]←(GR[reg2]Logically shift left by 1)
OR 00000001H
else GR[reg2]←(GR[reg2]Logically shift left by 1)
OR 00000000H
reg1,reg2
rrrrr000110RRRRR
GR[reg2]←saturated(GR[reg2]+GR[reg1])
1
1
1
×
×
×
×
×
imm5,reg2
rrrrr010001iiiii
GR[reg2]←saturated(GR[reg2]+sign-extend(imm5)
1
1
1
×
×
×
×
×
SATSUB
reg1,reg2
rrrrr000101RRRRR
GR[reg2]←saturated(GR[reg2]–GR[reg1])
1
1
1
×
×
×
×
×
SATSUBI
imm16,reg1,reg2
rrrrr110011RRRRR
GR[reg2]←saturated(GR[reg1]–sign-extend(imm16)
1
1
1
×
×
×
×
×
×
×
×
×
×
SATADD
i i i i i i i i i i i i i i i i
SATSUBR reg1,reg2
rrrrr000100RRRRR
GR[reg2]←saturated(GR[reg1]–GR[reg2])
1
1
1
SETF
rrrrr1111110cccc
If conditions are satisfied
1
1
1
0000000000000000
then GR[reg2]←00000001H
cccc,reg2
else GR[reg2]←00000000H
User’s Manual U12688EJ4V0UM00
437
APPENDIX B INSTRUCTION SET LIST
(5/6)
Mnemonic
Operand
Op Code
Operation
Execution
Flags
Clock
SET1
bit#3,disp16[reg1]
00bbb111110RRRRR adr←GR[reg1]+sign-extend(disp16)
dddddddddddddddd
Z flag←Not (Load-memory-bit(adr,bit#3))
i
r
l
3
3
3
CY OV S
Z SAT
×
Note 3 Note 3 Note 3
Store-memory-bit(adr,bit#3,1)
reg2,[reg1]
rrrrr111111RRRRR
adr←GR[reg1]
3
0000000011100000
Z flag←Not(Load-memory-bit(adr,reg2))
3
×
3
Note 3 Note 3 Note 3
Store-memory-bit(adr,reg2,1)
SHL
reg1,reg2
rrrrr111111RRRRR
GR[reg2]←GR[reg2] logically shift left by GR[reg1]
1
1
1
×
0
×
×
GR[reg2]←GR[reg2] logically shift left
1
1
1
×
0
×
×
GR[reg2]←GR[reg2] logically shift right by GR[reg1]
1
1
1
×
0
×
×
GR[reg2]←GR[reg2] logically shift right
1
1
1
×
0
×
×
1
1
0000000011000000
imm5,reg2
rrrrr010110iiiii
by zero-extend(imm5)
SHR
reg1,reg2
rrrrr111111RRRRR
0000000010000000
imm5,reg2
rrrrr010100iiiii
by zero-extend(imm5)
SLD.B
disp7[ep],reg2
rrrrr0110ddddddd
adr←ep+zero-extend(disp7)
GR[reg2]←sign-extend(Load-memory(adr,Byte))
SLD.BU
disp4[ep],reg2
SLD.H
disp8[ep],reg2
rrrrr0000110dddd
adr←ep+zero-extend(disp4)
rrrrr1000ddddddd
adr←ep+zero-extend(disp8)
Note 18
n
Note 9
1
1
1
1
GR[reg2]←zero-extend(Load-memory(adr,Byte))
n
Note 9
Note 19 GR[reg2]←sign-extend(Load-memory(adr,Half-
n
Note 9
word))
SLD.HU
disp5[ep],reg2
rrrrr0000111dddd
Notes 18, 20
adr←ep+zero-extend(disp5)
1
1
GR[reg2]←zero-extend(Load-memory(adr,Half-
n
Note 9
word))
SLD.W
disp8[ep],reg2
rrrrr1010dddddd0
SST.B
reg2,disp7[ep]
rrrrr0111ddddddd
adr←ep+zero-extend(disp8)
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
Note 21 GR[reg2]←Load-memory(adr,Word)
adr←ep+zero-extend(disp7)
n
Note 9
Store-memory(adr,GR[reg2],Byte)
SST.H
reg2,disp8[ep]
rrrrr1001ddddddd
SST.W
reg2,disp8[ep]
rrrrr1010dddddd1
adr←ep+zero-extend(disp8)
Note 19 Store-memory(adr,GR[reg2],Half-word)
adr←ep+zero-extend(disp8)
Note 21 Store-memory(adr,GR[reg2],Word)
ST.B
ST.H
reg2,disp16[reg1]
reg2,disp16[reg1]
rrrrr111010RRRRR
adr←GR[reg1]+sign-extend(disp16)
dddddddddddddddd
Store-memory(adr,GR[reg2],Byte)
rrrrr111011RRRRR
adr←GR[reg1]+sign-extend(disp16)
ddddddddddddddd0
Store-memory (adr,GR[reg2], Half-word)
Note 8
ST.W
reg2,disp16[reg1]
rrrrr111011RRRRR
adr←GR[reg1]+sign-extend(disp16)
ddddddddddddddd1
Store-memory (adr,GR[reg2], Word)
Note 8
STSR
regID,reg2
rrrrr111111RRRRR
GR[reg2]←SR[regID]
0000000001000000
438
User’s Manual U12688EJ4V0UM00
APPENDIX B INSTRUCTION SET LIST
(6/6)
Mnemonic
Operand
Op Code
Operation
Execution
Flags
Clock
i
r
l
CY OV S
Z SAT
SUB
reg1,reg2
rrrrr001101RRRRR
GR[reg2]←GR[reg2]–GR[reg1]
1
1
1
×
×
×
×
SUBR
reg1,reg2
rrrrr001100RRRRR
GR[reg2]←GR[reg1]–GR[reg2]
1
1
1
×
×
×
×
SWITCH
reg1
00000000010RRRRR
adr←(PC+2) + (GR [reg1] logically shift left by 1)
5
5
5
1
1
1
1
1
1
3
3
3
0
×
×
PC←(PC+2) + (sign-extend
(Load-memory (adr,Half-word)))
logically shift left by 1
SXB
reg1
00000000101RRRRR
GR[reg1]←sign-extend
(GR[reg1] (7 : 0))
SXH
reg1
00000000111RRRRR
GR[reg1]←sign-extend
TRAP
vector
00000111111iiiii
EIPC
←PC+4 (Return PC)
0000000100000000
EIPSW
←PSW
(GR[reg1] (15 : 0))
ECR.EICC ←Interrupt Code
PSW.EP
←1
PSW.ID
←1
PC
←00000040H (when vector is 00H to
0FH)
00000050H (when vector is 10H to
1FH)
TST
reg1,reg2
rrrrr001011RRRRR
TST1
bit#3,disp16[reg1]
11bbb111110RRRRR adr←GR[reg1]+sign-extend(disp16)
reg2, [reg1]
result←GR[reg2] AND GR[reg1]
dddddddddddddddd
Z flag←Not (Load-memory-bit (adr,bit#3))
rrrrr111111RRRRR
adr←GR[reg1]
1
1
1
3
3
3
×
Note 3 Note 3 Note 3
3
3
×
3
0000000011100110
Z flag←Not (Load-memory-bit (adr,reg2))
XOR
reg1,reg2
rrrrr001001RRRRR
GR[reg2]←GR[reg2] XOR GR[reg1]
1
1
1
0
×
×
XORI
imm16,reg1,reg2
rrrrr110101RRRRR
GR[reg2]←GR[reg1] XOR zero-extend (imm16)
1
1
1
0
×
×
Note 3 Note 3 Note 3
i i i i i i i i i i i i i i i i
ZXB
reg1
00000000100RRRRR
GR[reg1]←zero-extend (GR[reg1] (7 : 0))
1
1
1
ZXH
reg1
00000000110RRRRR
GR[reg1]←zero-extend (GR[reg1] (15 : 0))
1
1
1
Notes 1. dddddddd: Higher 8 bits of disp9.
2. 3 clocks if the final instruction includes PSW write access.
3. If there is no wait state (3 + the number of read access wait states).
4. N is the total number of list 12 read registers. (According to the number of wait states. Also, if there are
no wait states, N is the number of list 12 registers.)
5. RRRRR: other than 00000.
6. The lower halfword data only are valid.
7. ddddddddddddddddddddd: The higher 21 bits of disp22.
8. ddddddddddddddd: The higher 15 bits of disp16.
9. According to the number of wait states (1 if there are no wait states).
10. b: bit 0 of disp16.
11. According to the number of wait states (2 if there are no wait states).
User’s Manual U12688EJ4V0UM00
439
APPENDIX B INSTRUCTION SET LIST
Notes 12. In this instruction, for convenience of mnemonic description, the source register is made reg2, but the
reg1 field is used in the op code. Therefore, the meaning of register specification in the mnemonic
description and in the op code differs from other instructions.
r r r r r = regID specification
RRRRR = reg2 specification
13. i i i i i: Lower 5 bits of imm9.
I I I I: Lower 4 bits of imm9.
14. In the case of r = w (the lower 32 bits of the results are not written in the register) or w = r0 (the higher
32 bits of the results are not written in the register), 1.
15. sp/imm: specified by bits 19 and 20 of the sub op code.
16. ff = 00: Load sp in ep.
01: Load sign expanded 16-bit immediate data (bits 47 to 32) in ep.
10: Load 16-bit logically left shifted 16-bit immediate data (bits 47 to 32) in ep.
11: Load 32-bit immediate data (bits 63 to 32) in ep.
17. If imm = imm32, N + 3 blocks.
18. r r r r r : Other than 00000.
19. ddddddd: Higher 7 bits of disp8.
20. dddd: Higher 4 bits of disp5.
21. dddddd: Higher 6 bits of disp8.
440
User’s Manual U12688EJ4V0UM00
APPENDIX C INDEX
[A]
BCT........................................................................ 105
A/D conversion result registers .............................. 321
BCYST ..................................................................... 57
A/D converter ......................................................... 315
Block diagram of port ............................................. 353
A/D converter mode register 0 ............................... 318
Block transfer mode ............................................... 180
A/D converter mode register 1 ............................... 320
Boundary of memory area...................................... 194
A/D trigger mode .................................................... 324
Boundary operation conditions............................... 122
A0 to A7 ................................................................... 61
BPRM0 to BPRM2 ................................................. 314
A8 to A15 ................................................................ 61
BPRn2 to BPRn0 (n = 0 to 2) ................................. 314
A16 to A23 ............................................................... 54
BRCE0 to BRCE2 .................................................. 314
ADn0 to ADn9 (n = 0 to 7)...................................... 321
BRG0 to BRG2 ...................................................... 310
ADCR0 to ADCR7.................................................. 321
BRGC0 to BRGC2 ................................................. 313
ADCR0H to ADCR7H............................................. 321
BRGn0 to BRGn7 (n = 0 to 2) ................................ 313
Address multiplex function ..................................... 138
BS .......................................................................... 318
Address space ......................................................... 76
BSC........................................................................ 108
ADIC ...................................................................... 217
BSn0, BSn1 (n = 0 to 7) ......................................... 108
ADIF....................................................................... 217
BTn0, BTn1 (n = 0 to 7) ......................................... 105
ADM0 ..................................................................... 318
Bus access............................................................. 107
ADM1 ..................................................................... 320
Bus arbitration for CPU .......................................... 197
ADMK..................................................................... 217
Bus control function ............................................... 103
ADPR0 to ADPR2 .................................................. 217
Bus control pins ..................................................... 103
ADTRG..................................................................... 60
Bus cycle control register ....................................... 117
ALV1n0, ALV1n1 (n = 0 to 5) ................................. 260
Bus cycle type configuration register ..................... 105
ANI0 to ANI7 ............................................................ 54
Bus cycle type control function............................... 105
ANIS0 to ANIS2 ..................................................... 318
Bus cycles in which the wait function is valid ......... 115
Applications.............................................................. 30
Bus hold function ................................................... 119
ASIM00, ASIM01, ASIM10, ASIM11 ...................... 287
Bus hold timing ...................................................... 121
ASIS0, ASIS1......................................................... 291
Bus priority order.................................................... 122
Assembler-reserved register .................................... 71
Bus size configuration register ............................... 108
Asynchronous serial interfaces 0, 1 ....................... 284
Bus sizing function ................................................. 108
Asynchronous serial interface mode
Bus width ............................................................... 109
registers 00, 01, 10, 11 .......................................... 287
Byte access............................................................ 109
Asynchronous serial interface status
registers 0, 1 .......................................................... 291
[C]
AVDD ......................................................................... 64
CALLT base pointer ................................................. 72
AVREF ....................................................................... 64
Capture/compare registers 1n0 to 1n3
AVSS ......................................................................... 64
(n = 0 to 5) ............................................................. 252
Capture operation (timer 1) .................................... 266
[B]
CBR refresh timing................................................. 157
Basic operation of A/D converter............................ 323
CBR self-refresh timing .......................................... 159
Baud rate generator compare registers 0 to 2........ 313
CC1n0 to CC1n3 (n = 0 to 5) ................................. 252
Baud rate generator prescaler mode
CE .......................................................................... 318
registers 0 to 2 ....................................................... 314
CE10 to CE15 ........................................................ 257
BC0 to BC15 .......................................................... 167
CE40, CE41 ........................................................... 259
BCC ....................................................................... 117
CES1n0, CES1n1 (n = 0 to 5) ................................ 255
BCn0, BCn1 (n = 0 to 7)......................................... 117
CESEL ................................................................... 237
User’s Manual U12688EJ4V0UM00
441
APPENDIX C INDEX
CG ..........................................................................231
CTBP........................................................................72
CH0 to CH3 ............................................................173
CTPC .......................................................................72
CKC........................................................................233
CTPSW ....................................................................72
CKDIV0, CKDIV1 ...................................................233
CTXE0 to CTXE3 ...................................................301
CKSEL .....................................................................62
CVDD .........................................................................64
CL0, CL1 ................................................................288
CVSS .........................................................................64
Clearing/starting timer (timer1) ...............................265
CY ............................................................................73
CLKOUT...................................................................62
Clock control register..............................................233
[D]
Clock generator ......................................................231
D0 to D7 ...................................................................53
Clock generator functions.......................................231
D8 to D15 .................................................................53
Clock output inhibit mode .......................................243
DA0 to DA15 ..........................................................166
Clock selection .......................................................232
DA16 to DA25 ........................................................165
Clocked serial interfaces 0 to 3 ..............................299
DAC0n, DAC1n (n = 0 to 3)....................................140
Clocked serial interface mode registers 0 to 3........301
DAD0, DAD1 ..........................................................169
Clocks of DMA transfer...........................................194
DADC0 to DADC3 ..................................................168
CLSn0, CLSn1 (n = 0 to 3) .....................................302
Data wait control registers 1, 2...............................113
CM40, CM41 ..........................................................253
DAW0n, DAW1n (n = 0 to 3) ..................................141
CMIC40, CMIC41 ...................................................217
DBC0 to DBC3 .......................................................167
CMIF40, CMIF41....................................................217
DBPC .......................................................................72
CMMK40, CMMK41................................................217
DBPSW ....................................................................72
CMPR40n, CMPR41n (n = 0 to 2) ..........................217
DCHC0 to DCHC3..................................................170
CMS1n0 to CMS1n3 (n = 0 to 5) ............................255
DCLK0, DCLK1 ......................................................237
Command register..................................................101
DCm0, DCm1 (m = 0 to 7)......................................142
Compare operation (timer 1) ..................................269
DDA0 to DDA3 .......................................................165
Compare operation (timer 4) ..................................272
DDIS.......................................................................173
Compare registers 40, 41 .......................................253
Dedicated baud rate generators 0 to 2 ...................310
Control register (CG) ..............................................237
Direct mode............................................................232
Control register (DMAC) .........................................163
DMA addressing control registers 0 to 3 ................168
Control register (RPU) ............................................254
DMA bus states ......................................................175
Count clock selection (timer 1) ...............................263
DMA byte count registers 0 to 3 .............................167
Count clock selection (timer 4) ...............................271
DMA channel control registers 0 to 3 .....................170
Count operation (timer 1)........................................262
DMA channel priorities ...........................................190
Count operation (timer 4)........................................271
DMA controller .......................................................161
CPC0n, CPC1n (n = 0 to 3)....................................140
DMA destination address registers 0 to 3...............165
CPU address space .................................................76
DMA disable status register ...................................173
CPU function ............................................................69
DMA functions........................................................161
CPU register set .......................................................70
DMA restart register ...............................................173
CRXE0 to CRXE3 ..................................................301
DMA source address registers 0 to 3 .....................163
CS ..........................................................................318
DMA transfer start factors ......................................191
CS0 to CS7 ..............................................................55
DMA trigger factor registers 0 to 3..........................171
CSI0 to CSI3 ..........................................................299
DMAAK0 to DMAAK3...............................................50
CSIC0 to CSIC3 .....................................................217
DMAC.....................................................................161
CSIF0 to CSIF3 ......................................................217
DMAC bus cycle state transition diagram...............178
CSIM0 to CSIM3 ....................................................301
DMAIC0 to DMAIC3 ...............................................217
CSMK0 to CSMK3..................................................217
DMAIF0 to DMAIF3 ................................................217
CSOT0 to CSOT3 ..................................................301
DMAMK0 to DMAMK3............................................217
CSPRmn (m = 0 to 3, n = 0 to 2) ............................217
DMAPRmn to DMAPRmn (m = 0 to 3, n = 0 to 2)....217
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APPENDIX C INDEX
DMARQ0 to DMARQ3.............................................. 49
FECC ....................................................................... 72
DRAM access ........................................................ 143
FEPC ....................................................................... 72
DRAM access during DMA flyby transfer ............... 151
FEPSW .................................................................... 72
DRAM connections ................................................ 137
Flash memory ........................................................ 413
DRAM controller..................................................... 136
Flash memory programming mode .................. 74, 419
DRAM configuration registers 0 to 3 ...................... 139
Flyby transfer ......................................................... 185
DRAM type configuration register .......................... 142
Flyby transfer data wait control register ................. 174
DRC0 to DRC3....................................................... 139
FR2 to FR0 ............................................................ 320
DRST ..................................................................... 173
Frequency measurement ....................................... 279
DS .......................................................................... 168
DSA0 to DSA3 ....................................................... 163
[G]
DTC........................................................................ 142
General-purpose registers ....................................... 71
DTFR0 to DTFR3 ................................................... 171
Global pointer........................................................... 71
DWC1, DWC2 ........................................................ 113
DWn0 to DWn2 (n = 0 to 7).................................... 113
[H]
Halfword access..................................................... 110
[E]
HALT mode............................................................ 238
EBS0, EBS1........................................................... 290
High-speed page DRAM access timing.................. 143
Edge detection function.................................. 208, 220
HLDAK ..................................................................... 57
ECLR10 to ECLR15 ............................................... 254
HLDRQ .................................................................... 57
ECR ......................................................................... 72
HVDD......................................................................... 64
EDO DRAM access timing ..................................... 147
EICC ........................................................................ 72
[I]
EIPC......................................................................... 72
ID ............................................................................. 73
EIPSW ..................................................................... 72
IDLE ....................................................................... 237
Element pointer ........................................................ 71
IDLE mode ............................................................. 240
EN0 to EN3 ............................................................ 170
Idle state insertion function .................................... 117
ENTO1n0, ENTO1n1 (n = 0 to 5)........................... 260
Idle state insertion timing ....................................... 118
EP ............................................................................ 73
IFCn5 to IFCn0 (n = 0 to 3) .................................... 171
ESmn0, ESmn1 (m = 0 to 5, n = 0 to 3) ................. 221
Illegal op code definition......................................... 225
ESN0...................................................................... 208
Image ....................................................................... 77
ETI10 to ETI15 ....................................................... 257
IMS1n0 to IMS1n3 (n = 0 to 5) ............................... 255
Example of DRAM refresh interval ......................... 155
In-service priority register....................................... 218
Example of interval factor settings ......................... 155
Initialization ............................................................ 410
Exception trap ........................................................ 225
INIT0 to INIT3 ........................................................ 170
External bus cycle during DMA transfer ................. 189
INTC....................................................................... 199
External expansion mode......................................... 87
Internal block diagram.............................................. 35
External interrupt mode registers 1 to 6 ......... 220, 261
Internal peripheral I/O area ...................................... 85
External I/O interface ............................................. 125
Internal peripheral I/O interface.............................. 107
External memory area.............................................. 86
Internal RAM area.................................................... 85
External ROM interface.......................................... 125
Internal ROM area ................................................... 80
External trigger mode............................................. 325
Internal ROM area relocation function...................... 84
External wait function ............................................. 114
Interrupt control register ......................................... 216
Interrupt latency time.............................................. 229
[F]
Interrupt stack pointer .............................................. 71
FDW....................................................................... 174
Interrupt source register ........................................... 72
FDW0 to FDW7...................................................... 174
Interrupting DMA transfer....................................... 192
FE0, FE1................................................................ 291
Interrupt/exception processing function.................. 199
User’s Manual U12688EJ4V0UM00
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APPENDIX C INDEX
Interrupt/exception table ...........................................83
[O]
Interval timer...........................................................274
OE ............................................................................57
INTM0.....................................................................208
One time single transfer with DMARQ0 to
INTM1 to INTM6.............................................220, 261
DMARQ3 ................................................................196
INTP100 to INTP103 ................................................49
On-page/off-page judgment ...................................132
INTP110 to INTP113 ................................................50
Operation in A/D trigger mode................................329
INTP120 to INTP123 ................................................58
Operation in external trigger mode .........................341
INTP130 to INTP133 ................................................52
Operation in timer trigger mode..............................332
INTP140 to INTP143 ................................................59
Operation modes......................................................74
INTP150 to INTP153 ................................................60
Ordering information.................................................30
INTSER0, INTSER1 ...............................................294
OST0 to OST5 .......................................................254
INTSR0, INTSR1....................................................294
OV ............................................................................73
INTST0, INTST1.....................................................294
OVE0, OVE1 ..........................................................291
IORD ........................................................................55
Overflow (timer 1)...................................................264
IOWR........................................................................56
Overflow (timer 4)...................................................271
ISPR .......................................................................218
OVFn (n = 10 to 15, 40, 41)....................................261
ISPR0 to ISPR7......................................................218
OVIC10 to OVIC12.................................................214
OVIC13 to OVIC15.................................................215
[L]
OVIF10 to OVIF12..................................................216
LCAS ........................................................................56
OVIF13 to OVIF15..................................................217
Link pointer...............................................................71
OVMK10 to OVMK12 .............................................216
LWR .........................................................................56
OVMK13 to OVMK15 .............................................217
OVPR1mn (m = 0 to 2, n = 0 to 2)..........................216
[M]
OVPR1mn (m = 3 to 5, n = 0 to 2)..........................217
MA5 to MA3............................................................134
Maskable interrupts ................................................209
[P]
Maskable interrupt status flag.................................218
P0...........................................................................368
Maximum response time to DMA request...............194
P1...........................................................................371
Memory access control function .............................125
P2...........................................................................374
Memory block function............................................104
P3...........................................................................377
Memory expansion mode register ............................87
P4...........................................................................380
Memory map ............................................................79
P5...........................................................................382
MM ...........................................................................87
P6...........................................................................384
MM3 to MM0 ............................................................88
P7...........................................................................386
MOD0 to MOD3......................................................301
P8...........................................................................387
MODE0 to MODE3 ...................................................63
P9...........................................................................391
MS ..........................................................................318
P10.........................................................................394
Multiple interrupt processing control.......................227
P11.........................................................................397
P12.........................................................................401
[N]
P00 to P07 ....................................................... 49, 368
Next address setting function .................................190
P10 to P17 ....................................................... 50, 371
NMI...........................................................................51
P20 to P27 ....................................................... 51, 374
Noise elimination ............................................208, 219
P30 to P37 ....................................................... 52, 377
Non-maskable interrupt ..........................................204
P40 to P47 ....................................................... 53, 380
Normal operation mode ...........................................74
P50 to P57 ....................................................... 53, 382
NP ............................................................................73
P60 to P67 ....................................................... 54, 384
Number of access clocks........................................107
P70 to P77 ....................................................... 54, 386
P80 to P87 ....................................................... 55, 387
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APPENDIX C INDEX
P90 to P97 ....................................................... 56, 391
PCS104 to PCS107 ............................................... 396
P100 to P107 ................................................... 58, 394
PCS115.................................................................. 400
P110 to P117 ................................................... 59, 397
PE0, PE1 ............................................................... 291
P120 to P127 ................................................... 60, 401
Periods where interrupt is not acknowledged......... 227
P10IC0 to P10IC3 .................................................. 217
Peripheral I/O registers ............................................ 92
P10IF0 to P10IF3 ................................................... 217
Pin configuration ...................................................... 31
P10MK0 to P10MK3............................................... 217
Pin functions ............................................................ 39
P10PRmn (m = 0 to 3, n = 0 to 2) .......................... 217
Pin input/output circuit.............................................. 67
P11IC0 to P11IC3 .................................................. 217
Pin input/output circuit types .................................... 65
P11IF0 to P11IF3 ................................................... 217
Pin name.................................................................. 34
P11MK0 to P11MK3............................................... 217
Pin status ................................................................. 47
P11PRmn (m = 0 to 3, n = 0 to 2) .......................... 217
PLL lockup ............................................................. 233
P12IC0 to P12IC3 .................................................. 217
PLL mode............................................................... 231
P12IF0 to P12IF3 ................................................... 217
PM0........................................................................ 368
P12MK0 to P12MK3............................................... 217
PM1........................................................................ 371
P12PRmn (m = 0 to 3, n = 0 to 2) .......................... 217
PM2........................................................................ 375
P13IC0 to P13IC3 .................................................. 217
PM3........................................................................ 378
P13IF0 to P13IF3 ................................................... 217
PM4........................................................................ 381
P13MK0 to P13MK3............................................... 217
PM5........................................................................ 383
P13PRmn (m = 0 to 3, n = 0 to 2) .......................... 217
PM6........................................................................ 385
P14IC0 to P14IC3 .................................................. 217
PM8........................................................................ 388
P14IF0 to P14IF3 ................................................... 217
PM9........................................................................ 392
P14MK0 to P14MK3............................................... 217
PM10 (register) ...................................................... 394
P14PRmn (m = 0 to 3, n = 0 to 2) .......................... 217
PM11...................................................................... 398
P15IC0 to P15IC3 .................................................. 217
PM12...................................................................... 401
P15IF0 to P15IF3 ................................................... 217
PM00 to PM07 ....................................................... 368
P15MK0 to P15MK3............................................... 217
PM10 to PM17 (bit) ................................................ 371
P15PRmn (m = 0 to 3, n = 0 to 2) .......................... 217
PM21 to PM27 ....................................................... 375
PA .......................................................................... 403
PM30 to PM37 ....................................................... 378
PA0 to PA7 ...................................................... 61, 403
PM40 to PM47 ....................................................... 381
PAE........................................................................ 134
PM50 to PM57 ....................................................... 383
PAE0n, PAE1n (n = 0 to 3) .................................... 139
PM60 to PM67 ....................................................... 385
Page ROM access ................................................. 135
PM80 to PM87 ....................................................... 388
Page ROM configuration register ........................... 134
PM90 to PM97 ....................................................... 392
Page ROM controller.............................................. 130
PM100 to PM107 ................................................... 394
PB .......................................................................... 405
PM110 to PM117 ................................................... 398
PB0 to PB7 ...................................................... 61, 405
PM120 to PM127 ................................................... 401
PC ............................................................................ 71
PMA ....................................................................... 403
PCS0...................................................................... 370
PMA0 to PMA7 ...................................................... 403
PCS04 to PCS07 ................................................... 370
PMB ....................................................................... 405
PCS1...................................................................... 373
PMB0 to PMB7 ...................................................... 405
PCS3...................................................................... 380
PMC0 ..................................................................... 369
PCS8...................................................................... 390
PMC1 ..................................................................... 372
PCS10.................................................................... 396
PMC2 ..................................................................... 376
PCS11.................................................................... 400
PMC3 ..................................................................... 379
PCS14 to PCS17 ................................................... 373
PMC8 ..................................................................... 389
PCS35.................................................................... 380
PMC9 ..................................................................... 393
PCS84, PCS85 ...................................................... 390
PMC10 (register).................................................... 395
User’s Manual U12688EJ4V0UM00
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APPENDIX C INDEX
PMC11 ...................................................................399
Port 0 mode register ..............................................368
PMC12 ...................................................................402
Port 1 mode register...............................................371
PMC00 to PMC07 ..................................................369
Port 2 mode register...............................................375
PMC10 to PMC17 (bit) ...........................................372
Port 3 mode register...............................................378
PMC22 to PMC27 ..................................................376
Port 4 mode register...............................................381
PMC30 to PMC37 ..................................................379
Port 5 mode register...............................................383
PMC80 to PMC87 ..................................................389
Port 6 mode register...............................................385
PMC90 to PMC97 ..................................................393
Port 8 mode register...............................................388
PMC100 to PMC107 ..............................................395
Port 9 mode register...............................................392
PMC110 to PMC117 ..............................................399
Port 10 mode register.............................................394
PMC120 to PMC127 ..............................................402
Port 11 mode register.............................................398
PMCX .....................................................................408
Port 12 mode register.............................................401
PMCX5 to PMCX7..................................................408
Port A mode register ..............................................403
PMX........................................................................407
Port B mode register ..............................................405
PMX5 to PMX7.......................................................407
Port X mode register ..............................................407
Port/control select register 0...................................370
Power saving control ..............................................235
Port/control select register 1...................................373
Power save control register....................................237
Port/control select register 3...................................380
PRC........................................................................134
Port/control select register 8...................................390
PRCMD ..................................................................101
Port/control select register 10.................................396
Precaution (A/D converter).....................................345
Port/control select register 11.................................400
Precaution (DMA)...................................................197
Port 0......................................................................367
Precaution (RPU) ...................................................281
Port 1 .....................................................................371
PRERR...................................................................102
Port 2......................................................................374
Priorities of maskable interrupts .............................212
Port 3......................................................................377
PRM1n1 (n = 0 to 5)...............................................258
Port 4 .....................................................................380
PRM4n0, PRM4n1 (n = 0, 1) ..................................259
Port 5......................................................................382
Program counter ......................................................71
Port 6......................................................................384
Program register set.................................................71
Port 7......................................................................386
Program status word ................................................73
Port 8......................................................................387
Programmable wait function...................................113
Port 9......................................................................391
Programming environment .....................................414
Port 10....................................................................394
Programming method.............................................418
Port 11....................................................................397
PRS1n0, PRS1n1 (n = 0 to 5) ................................258
Port 12....................................................................401
PRS400, PRS410...................................................259
Port A .....................................................................403
PRW0 to PRW2 .....................................................134
Port B .....................................................................405
PS00, PS01, PS10, PS11 ......................................288
Port X .....................................................................407
PSC........................................................................237
Port functions .........................................................347
PSW .........................................................................73
Port 0 mode control register ...................................369
PWM output ...........................................................277
Port 1 mode control register ...................................372
PX ..........................................................................407
Port 2 mode control register ...................................376
PX5 to PX7....................................................... 62, 407
Port 3 mode control register ...................................379
Pulse width measurement ......................................275
Port 8 mode control register ...................................389
Port 9 mode control register ...................................393
[R]
Port 10 mode control register .................................395
r0 to r31....................................................................71
Port 11 mode control register .................................399
RAS0 to RAS7 .........................................................55
Port 12 mode control register .................................402
RCCn0, RCCn1 (n = 0 to 3) ...................................154
Port X mode control register...................................408
RCW0 to RCW2 .....................................................156
446
User’s Manual U12688EJ4V0UM00
APPENDIX C INDEX
RD............................................................................ 57
SEIF0, SEIF1 ......................................................... 217
Real-time pulse unit ............................................... 247
Select mode ........................................................... 325
Receive buffers 0, 0L, 1, 1L ................................... 292
Self-refresh functions ............................................. 158
Receive error interrupt ........................................... 294
SEMK0, SEMK1..................................................... 217
Reception completion interrupt............................... 294
SEPR0n, SEPR1n (n = 0 to 2) ............................... 217
Recommended connection of unused pins .............. 65
Serial I/O shift registers 0 to 3................................ 303
Refresh control function ......................................... 153
Serial interface function.......................................... 283
Refresh control registers 0 to 3 .............................. 153
SI0, SI1 .................................................................... 51
Refresh timing ........................................................ 157
SI2............................................................................ 52
Refresh wait control register .................................. 156
SI3............................................................................ 59
REFRQ..................................................................... 62
Single-chip modes 0, 1............................................. 74
REG0 to REG7....................................................... 101
Single-step transfer mode ...................................... 180
Relationship between analog input voltage and
Single transfer mode .............................................. 179
A/D conversion results ........................................... 322
SIO0 to SIO3.......................................................... 303
Relationship between programmable wait and
SIOn0 to SIOn7 (n = 0 to 3) ................................... 303
external wait ........................................................... 114
SL0, SL1 ................................................................ 289
REN0 to REN3 (DRST register) ............................. 173
SO0, SO1................................................................. 51
RENn (RFCn register) (n = 0 to 3) ......................... 153
SO2.......................................................................... 52
RESET ..................................................................... 64
SO3.......................................................................... 59
Reset functions ...................................................... 409
Software exception ................................................ 222
RFC0 to RFC3 ....................................................... 153
Software STOP mode ............................................ 242
RHC0n, RHC1n (n = 0 to 3) ................................... 140
SOT0, SOT1 .......................................................... 291
RHD0 to RHD3....................................................... 140
Specific registers.................................................... 100
RIn0 to RIn5 (n = 0 to 3)......................................... 154
SRAM interface...................................................... 125
ROMC ................................................................... 130
SRAM connections ................................................ 125
ROM-less modes 0, 1 .............................................. 74
SRIC0, SRIC1........................................................ 217
RPC0n, RPC1n (n = 0 to 3).................................... 139
SRIF0, SRIF1......................................................... 217
RRW0, RRW1 ........................................................ 156
SRMK0, SRMK1 .................................................... 217
RWC ...................................................................... 156
SRPR0n, SRPR1n (n = 0 to 2)............................... 217
RXB0, RXB0L, RXB1, RXB1L................................ 292
SRW2 to SRW0 ..................................................... 156
RXBn0 to RXBn7 (n = 0, 1) .................................... 292
Stack pointer ............................................................ 71
RXD0, RXD1 ............................................................ 51
Status saving register during CALLT execution ....... 72
RXE0, RXE1 .......................................................... 287
Status saving register during exception trap ............ 72
RXEB0, RXEB1...................................................... 292
Status saving register during interrupt...................... 72
Status saving register during NMI ............................ 72
[S]
STG0 to STG3 ....................................................... 170
S............................................................................... 73
STIC0, STIC1......................................................... 217
SA0 to SA15........................................................... 164
STIF0, STIF1 ......................................................... 217
SA16 to SA25......................................................... 163
STMK0, STMK1 ..................................................... 217
SAD0, SAD1 .......................................................... 168
STP ........................................................................ 237
SAT .......................................................................... 73
STPR0n, STPR1n (n = 0 to 2)................................ 217
Scan mode ............................................................. 328
SYS........................................................................ 102
SCK0, SCK1 ............................................................ 51
System register set .................................................. 72
SCK2........................................................................ 52
System status register............................................ 102
SCK3........................................................................ 59
SCLS00, SCLS01, SCLS10, SCLS11.................... 289
[T]
Securing oscillation stabilization time..................... 244
TBC........................................................................ 246
SEIC0, SEIC1 ........................................................ 217
TBCS ..................................................................... 237
User’s Manual U12688EJ4V0UM00
447
APPENDIX C INDEX
TC0 to TC3...............................................................58
Transfer types ........................................................181
TC0 to TC3.............................................................170
Transmission completion interrupt..........................294
TCLR10 ....................................................................49
Transmit shift registers 0, 0L, 1, 1L ........................293
TCLR11 ....................................................................50
TRG2 to TRG0 .......................................................320
TCLR12 ....................................................................58
Trigger mode..........................................................324
TCLR13 ....................................................................52
TTYP ......................................................................169
TCLR14 ....................................................................59
TUM10 to TUM15...................................................254
TCLR15 ....................................................................60
Two-cycle transfer ..................................................181
TDIR .......................................................................169
TXD0, TXD1.............................................................51
Terminating DMA transfer ......................................192
TXE0, TXE1 ...........................................................287
TES1n0, TES1n1 (n = 0 to 5) .................................255
TXED0, TXED1 ......................................................293
Text pointer ..............................................................71
TXS0, TXS0L, TXS1, TXS1L .................................293
TI10 ..........................................................................49
TXSn7 to TXSn0 (n = 0, 1) .....................................293
TI11 ..........................................................................50
TI12 ..........................................................................58
[U]
TI13 ..........................................................................52
UART0, UART1......................................................284
TI14 ..........................................................................59
UCAS .......................................................................56
TI15 ..........................................................................60
UNLOCK ................................................................102
Time base counter..................................................246
UWR.........................................................................56
Timer control registers 10 to 15..............................257
Timer control registers 40, 41.................................259
[V]
Timer output control registers 10 to 15 ...................260
VDD ...........................................................................64
Timer overflow status register ................................261
VPP............................................................................64
Timer trigger mode .................................................324
VSS............................................................................64
Timer unit mode registers 10 to 15.........................254
Timer 1 ...................................................................251
[W]
Timer 1 operation ...................................................262
WAIT ........................................................................62
Timer 4 ...................................................................253
Wait function ..........................................................113
Timer 4 operation ...................................................271
WE ...........................................................................57
Timers 10 to 15 ......................................................251
Word access ..........................................................110
Timers 40, 41 .........................................................253
Wrap-around ............................................................78
Timer/counter function............................................247
Writing by flash programmer ..................................413
TM0, TM1 ...............................................................169
TM10 to TM15 ........................................................251
TM40, TM41 ...........................................................253
[X]
X1, X2 ......................................................................64
TMC10 to TMC15...................................................257
TMC40, TMC41......................................................259
[Z]
TO100, TO101 .........................................................49
Z ...............................................................................73
TO110, TO111 .........................................................50
Zero register.............................................................71
TO120, TO121 .........................................................58
TO130, TO131 .........................................................52
TO140, TO141 .........................................................59
TO150, TO151 .........................................................60
TOC10 to TOC15 ...................................................260
TOVS......................................................................261
Transfer mode ........................................................179
Transfer objects......................................................189
Transfer of misalign data ........................................194
448
User’s Manual U12688EJ4V0UM00
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CS 99.1