Hitachi Single-Chip Microcomputer
H8/325 Series
H8/3257,H8/3256
H8/325,H8/324,H8/323,H8/322
Hardware Manual
Hitachi Micro Systems, Incorporated
Notice
When using this document, keep the following in mind:
1. This document may, wholly or partially, be subject to change without notice.
2. All rights are reserved: No one is permitted to reproduce or duplicate, in any form, the
whole or part of this document without Hitachi’s permission.
3. Hitachi will not be held responsible for any damage to the user that may result from
accidents or any other reasons during operation of the user’s unit according to this document.
4. Circuitry and other examples described herein are meant merely to indicate the
characteristics and performance of Hitachi’s semiconductor products. Hitachi assumes no
responsibility for any intellectual property claims or other problems that may result from
applications based on the examples described herein.
5. No license is granted by implication or otherwise under any patents or other rights of any
third party or Hitachi, Ltd.
6. MEDICAL APPLICATIONS: Hitachi’s products are not authorized for use in MEDICAL
APPLICATIONS without the written consent of the appropriate officer of Hitachi’s sales
company. Such use includes, but is not limited to, use in life support systems. Buyers of
Hitachi’s products are requested to notify the relevant Hitachi sales offices when planning to
use the products in MEDICAL APPLICATIONS.
Table Of Contents
Preface ....... .....................................................................................................1
Section 1. Overview ........................................................................................3
1.1 Overview ........................................................................................................................ 3
1.2 Block Diagram................................................................................................................ 7
1.3 Pin Assignments and Functions....................................................................................... 8
1.3.1 Pin Arrangement................................................................................................ 8
1.3.2 Pin Functions ..................................................................................................... 11
Section 2. MCU Operating Modes and Address Space.....................................17
2.1 Overview ........................................................................................................................ 17
2.2 Mode Descriptions .......................................................................................................... 18
2.3 Address Space Map......................................................................................................... 18
2.3.1 Access Speed ..................................................................................................... 18
2.3.2 IOS .................................................................................................................... 19
2.4 Mode and System Control Registers (MDCR and SYSCR) ............................................. 26
2.4.1 Mode Control Register (MDCR)—H’FFC5........................................................ 26
2.4.2 System Control Register (SYSCR)—H’FFC4 .................................................... 27
Section 3. CPU................................................................................................29
3.1 Overview ........................................................................................................................ 29
3.1.1 Features ............................................................................................................. 29
3.2 Register Configuration .................................................................................................... 30
3.2.1 General Registers............................................................................................... 30
3.2.2 Control Registers ............................................................................................... 31
3.2.3 Initial Register Values ....................................................................................... 32
3.3 Addressing Modes........................................................................................................... 33
3.4 Data Formats................................................................................................................... 35
3.4.1 Data Formats in General Registers ..................................................................... 36
3.4.2 Memory Data Formats ....................................................................................... 37
3.5 Instruction Set................................................................................................................. 38
3.5.1 Data Transfer Instructions.................................................................................. 40
3.5.2 Arithmetic Operations........................................................................................ 42
3.5.3 Logic Operations ............................................................................................... 43
3.5.4 Shift Operations................................................................................................. 43
3.5.5 Bit Manipulations .............................................................................................. 45
3.5.6 Branching Instructions ....................................................................................... 51
3.5.7 System Control Instructions ............................................................................... 53
3.5.8 Block Data Transfer Instruction ......................................................................... 54
i
3.6 CPU States...................................................................................................................... 56
3.6.1 Program Execution State.................................................................................... 57
3.6.2 Exception-Handling State .................................................................................. 57
3.6.3 Power-Down State ............................................................................................. 58
3.7 Access Timing and Bus Cycle......................................................................................... 58
3.7.1 Access to On-Chip Memory (RAM and ROM) .................................................. 58
3.7.2 Access to On-Chip Register Field and External Devices ................................... 60
Section 4. Exception Handling ........................................................................63
4.1 Overview ........................................................................................................................ 63
4.2 Reset............................................................................................................................... 63
4.2.1 Overview ........................................................................................................... 63
4.2.2 Reset Sequence .................................................................................................. 63
4.2.3 Disabling of Interrupts after Reset...................................................................... 66
4.3 Interrupts ........................................................................................................................ 66
4.3.1 Overview ........................................................................................................... 66
4.3.2 Interrupt-Related Registers ................................................................................ 67
4.3.3 External Interrupts ............................................................................................. 70
4.3.4 Internal Interrupts .............................................................................................. 71
4.3.5 Interrupt Handling ............................................................................................. 72
4.3.6 Interrupt Response Time.................................................................................... 77
4.4 Note on Stack Handling .................................................................................................. 77
Section 5. I/O Ports .........................................................................................79
5.1 Overview ........................................................................................................................ 79
5.2 Port 1 .............................................................................................................................. 80
Port 1 Data Direction Register (P1DDR)—H’FFB0 ..................................................... 81
5.3 Port 2 .............................................................................................................................. 83
5.4 Port 3 .............................................................................................................................. 86
5.5 Port 4 .............................................................................................................................. 89
5.6 Port 5 .............................................................................................................................. 96
5.7 Port 6 .............................................................................................................................. 101
5.8 Port 7 .............................................................................................................................. 106
Section 6. Parallel Handshaking Interface........................................................115
6.1 Overview ........................................................................................................................ 115
6.1.1 Features ............................................................................................................. 115
6.1.2 Block Diagram................................................................................................... 116
6.1.3 Input and Output Pins ........................................................................................ 117
6.2 Register Descriptions ...................................................................................................... 117
6.2.1 Port 3 Data Direction Register (P3DDR)............................................................ 117
6.2.2 Port 3 Data Register (P3DR) .............................................................................. 118
6.2.3 Handshake Control/Status Register (HCSR)....................................................... 118
ii
6.3 Operation ........................................................................................................................ 120
6.3.1 Output Timing of Output Strobe Signal.............................................................. 120
6.3.2 Busy Signal Output Timing................................................................................ 121
6.3.3 Operation in Software Standby Mode................................................................. 121
6.3.4 Sample Application ........................................................................................... 122
6.3.5 Interrupts ........................................................................................................... 123
Section 7. 16-BIT Free-Running Timer ............................................................125
7.1 Overview ......................................................................................................................... 125
7.1.1 Features .............................................................................................................. 125
7.1.2 Block Diagram.................................................................................................... 125
7.1.3 Input and Output Pins ......................................................................................... 127
7.1.4 Register Configuration........................................................................................ 127
7.2 Register Descriptions............................................................................................. 128
7.2.1 Free-Running Counter (FRC) - H'FF92 ............................................................... 128
7.2.2 Output Compare Registers A and B
(OCRA and OCRB) - H'FF94 and H'FF96 ................................................................... 128
7.2.3 Input Capture Register (ICR) - H'FF98 ............................................................... 129
7.2.4 Timer Control Register (TCR) - H'FF90 ............................................................. 130
7.2.5 Timer Control/Status Register (TCSR) - H'FF91................................................. 132
7.2.6 FRT Noise Canceler Control Register (FNCR) - H'FFFF .................................... 135
7.3 CPU Interface ........................................................................................................ 135
7.4 Operation............................................................................................................... 138
7.4.1 FRC Incrementation Timing ............................................................................... 138
7.4.2 Output Compare Timing ..................................................................................... 140
7.4.3 FRC Clear Timing .............................................................................................. 140
7.4.4 Input Capture Timing.......................................................................................... 141
7.4.5 Timing of Input Capture Flag (ICF) Setting ........................................................ 142
7.4.6 Setting of FRC Overflow Flag (OVF) ................................................................. 143
7.5 Interrupts ......................................................................................................................... 144
7.6 Noise Canceler................................................................................................................ 144
7.7 Sample Application.......................................................................................................... 146
7.8 Application Notes ............................................................................................................ 147
Section 8. 8-Bit Timers ...................................................................................151
8.1 Overview ........................................................................................................................ 151
8.1.1 Features ............................................................................................................. 151
8.1.2 Block Diagram................................................................................................... 151
8.1.3 Input and Output Pins ........................................................................................ 152
8.1.4 Register Configuration....................................................................................... 153
8.2 Register Descriptions ...................................................................................................... 153
8.2.1 Timer Counter (TCNT) – H’FFC8 (TMR0), H’FFD0 (TMR1) ........................... 153
iii
8.3
8.4
8.5
8.6
8.2.2
Time Constant Registers A and B (TCORA and TCORB)
– H’FFCA and H’FFCB (TMR0), H’FFD2 and H’FFD3 (TMR1) ................................ 154
8.2.3 Timer Control Register (TCR)
– H’FFC8 (TMR0), H’FFD0 (TMR1) .......................................................................... 154
8.2.4 Timer Control/Status Register (TCSR)
– H’FFC9 (TMR0), H’FFD1 (TMR1) .......................................................................... 156
Operation ........................................................................................................................ 158
8.3.1 TCNT Incrementation Timing ........................................................................... 158
8.3.2 Compare Match Timing ..................................................................................... 159
8.3.3 External Reset of TCNT .................................................................................... 161
8.3.4 Setting of TCSR Overflow Flag ......................................................................... 162
Interrupts ........................................................................................................................ 163
Sample Application......................................................................................................... 163
Application Notes ........................................................................................................... 164
Section 9. Serial Communication Interface......................................................169
9.1 Overview ........................................................................................................................ 169
9.1.1 Features ............................................................................................................. 169
9.1.2 Block Diagram................................................................................................... 170
9.1.3 Input and Output Pins ........................................................................................ 170
9.1.4 Register Configuration....................................................................................... 171
9.2 Register Descriptions ...................................................................................................... 171
9.2.1 Receive Shift Register (RSR)............................................................................. 171
9.2.2 Receive Data Register (RDR) – H’FFDD........................................................... 172
9.2.3 Transmit Shift Register (TSR) ........................................................................... 172
9.2.4 Transmit Data Register (TDR) – H’FFDB.......................................................... 172
9.2.5 Serial Mode Register (SMR) – H’FFD8 ............................................................. 173
9.2.6 Serial Control Register (SCR) – H’FFDA .......................................................... 175
9.2.7 Serial Status Register (SSR) – H’FFDC ............................................................. 177
9.2.8 Bit Rate Register (BRR) – H’FFD9.................................................................... 179
9.3 Operation ........................................................................................................................ 183
9.3.1 Overview ........................................................................................................... 183
9.3.2 Asynchronous Mode .......................................................................................... 184
9.3.3 Synchronous Mode ............................................................................................ 188
9.4 Interrupts ........................................................................................................................ 192
9.5 Application Notes ........................................................................................................... 193
Section 10. RAM.............................................................................................197
10.1
10.2
10.3
10.4
iv
Overview ...................................................................................................................... 197
Block Diagram.............................................................................................................. 197
RAM Enable Bit (RAME)............................................................................................. 198
Operation ...................................................................................................................... 198
10.4.1 Expanded Modes (Modes 1 and 2) ................................................................... 198
10.4.2 Single-Chip Mode (Mode 3) ............................................................................ 199
Section 11. ROM.............................................................................................201
11.1 Overview ...................................................................................................................... 201
11.1.1 Block Diagram................................................................................................. 202
11.2 PROM Mode................................................................................................................. 202
11.2.1 PROM Mode Setup.......................................................................................... 202
11.2.2 Socket Adapter Pin Assignments and Memory Map......................................... 203
11.3 Programming ................................................................................................................ 208
11.3.1 Selection of Sub-Modes in PROM Mode.......................................................... 208
11.3.2 Writing and Verifying...................................................................................... 209
11.3.3 Notes on Writing.............................................................................................. 215
11.3.4 Reliability of Written Data............................................................................... 215
11.3.5 Erasing of Data ................................................................................................ 216
11.4 Handling of Windowed Packages.................................................................................. 216
Section 12. Power-Down State ........................................................................219
12.1 Overview ...................................................................................................................... 219
12.2 System Control Register: Power-Down Control Bits .................................................... 220
12.3 Sleep Mode ................................................................................................................... 221
12.3.1 Transition to Sleep Mode ................................................................................. 222
12.3.2 Exit from Sleep Mode ...................................................................................... 222
12.4 Software Standby Mode ................................................................................................ 222
12.4.1 Transition to Software Standby Mode .............................................................. 223
12.4.2 Exit from Software Standby Mode ................................................................... 223
12.4.3 Sample Application of Software Standby Mode .............................................. 223
12.4.4 Notes on Current Dissipation ........................................................................... 224
12.5 Hardware Standby Mode............................................................................................... 225
12.5.1 Transition to Hardware Standby Mode............................................................. 225
12.5.2 Recovery from Hardware Standby Mode.......................................................... 226
12.5.3 Timing Relationships ....................................................................................... 226
Section 13. E-Clock Interface..........................................................................227
13.1 Overview ...................................................................................................................... 227
Section 14. Clock Pulse Generator ..................................................................231
14.1 Overview ...................................................................................................................... 231
14.1.1 Block Diagram................................................................................................. 231
14.2 Oscillator Circuit........................................................................................................... 231
14.3 System Clock Divider ................................................................................................... 234
Section 15. Electrical Specifications................................................................235
15.1 Absolute Maximum Ratings.......................................................................................... 235
v
15.2 Electrical Characteristics............................................................................................... 235
15.2.1 DC Characteristics ........................................................................................... 235
15.2.2 AC Characteristics ........................................................................................... 242
15.3 MCU Operational Timing ............................................................................................. 246
15.3.1 Bus Timing ...................................................................................................... 246
15.3.2 Control Signal Timing ..................................................................................... 248
15.3.3 16-Bit Free-Running Timer Timing ................................................................. 251
15.3.4 8-Bit Timer Timing.......................................................................................... 252
15.3.5 Serial Communication Interface Timing .......................................................... 253
15.3.6 I/O Port Timing ............................................................................................... 254
15.3.7 Parallel Handshake Interface Timing ............................................................... 254
Appendix A. CPU Instruction Set....................................................................257
A.1 Instruction Set List ......................................................................................................... 257
A.2 Operation Code Map ...................................................................................................... 265
A.3 Number of States Required for Execution ..................................................................... 266
Appendix B. Register Field .............................................................................273
B.1 Register Addresses and Bit Names ................................................................................. 273
B.2 Register Descriptions...................................................................................................... 277
TCR—Timer Control Register..................................................................................... 278
TCSR—Timer Control/Status Register
................. 279
FRC (H and L)—Free-Running Counter ...................................................................... 280
OCRA (H and L)—Output Compare Register A .......................................................... 280
OCRB (H and L)—Output Compare Register B .......................................................... 280
ICR (H and L)—Input Capture Register ...................................................................... 280
P1DDR—Port 1 Data Direction Register ..................................................................... 281
P2DDR—Port 2 Data Direction Register ..................................................................... 281
P2DR—Port 2 Data Register ....................................................................................... 282
P3DDR—Port 3 Data Direction Register ..................................................................... 282
P3DR—Port 3 Data Register ....................................................................................... 282
P4DDR—Port 4 Data Direction Register ..................................................................... 283
P4DR—Port 4 Data Register ....................................................................................... 283
P5DDR—Port 5 Data Direction Register ..................................................................... 283
P5DR—Port 5 Data Register ....................................................................................... 284
P6DDR—Port 6 Data Direction Register ..................................................................... 284
P6DR—Port 6 Data Register ....................................................................................... 284
P7DDR—Port 7 Data Direction Register ..................................................................... 284
P7DR—Port 7 Data Register ....................................................................................... 285
SYSCR—System Control Register .............................................................................. 285
MDCR—Mode Control Register ................................................................................. 286
ISCR—IRQ Sense Control Register............................................................................. 287
IER—IRQ Enable Register.......................................................................................... 288
vi
TCR—Timer Control Register..................................................................................... 289
TCSR—Timer Control/Status Register ........................................................................ 290
TCORA—Time Constant Register A........................................................................... 291
TCORB—Time Constant Register B ........................................................................... 291
TCNT—Timer Counter ............................................................................................... 291
TCR—Timer Control Register..................................................................................... 291
TCSR—Timer Control/Status Register ........................................................................ 292
TCORA—Time Constant Register A .......................................................................... 292
TCORB—Time Constant Register B ........................................................................... 292
TCNT—Timer Counter ............................................................................................... 293
SMR—Serial Mode Register ....................................................................................... 294
TDR—Transmit Data Register .................................................................................... 295
BRR—Bit Rate Register.............................................................................................. 295
SCR—Serial Control Register ..................................................................................... 296
SSR—Serial Status Register ........................................................................................ 297
RDR—Receive Data Register...................................................................................... 298
SMR—Serial Mode Register ....................................................................................... 298
BRR—Bit Rate Register.............................................................................................. 298
SCR—Serial Control Register ..................................................................................... 298
TDR—Transmit Data Register .................................................................................... 299
SSR—Serial Status Register ........................................................................................ 299
RDR—Receive Data Register...................................................................................... 299
HCSR—Handshake Control/Status Register ................................................................ 300
FNCR—FRT Noise Canceler Control Register ............................................................ 301
Appendix C. Pin States....................................................................................303
C.1 Pin States in Each Mode................................................................................................. 303
Appendix D.
Timing of Transition to and Recovery from Hardware Standby Mode..............305
Appendix E. Package Dimensions ...................................................................307
vii
viii
Preface
The H8/325 Series is a family of high-performance single-chip microcomputers ideally suited
for embedded control of industrial equipment. The chips are built around an H8/300 CPU core: a
high-speed processor. On-chip supporting modules provides ROM, RAM, two types of timers,
I/O ports, and a serial communication interface for easy implementation of compact, high-speed
control systems.
The H8/325 Series offers a selection of on-chip memory.
H8/3257: 60-kbyte ROM; 2-kbyte RAM
H8/3256: 48-kbyte ROM; 2-kbyte RAM
H8/325: 32-kbyte ROM; 1-kbyte RAM
H8/324: 24-kbyte ROM; 1-kbyte RAM
H8/323: 16-kbyte ROM; 512-byte RAM
H8/322: 8-kbyte ROM; 256-byte RAM
The H8/3257, H8/3256, H8/325, H8/323, and H8/322 chips are available with either electrically
programmable or mask-programmable ROM. Manufacturers can use the electrically
programmable ZTATTM (Zero Turn-Around Time*) version to get production off to a fast start
and make software changes quickly, then switch over to the masked version for full-scale
production runs.
This manual describes the H8/325 Series hardware. Refer to the H8/300 Series Programming
Manual for a detailed description of the instruction set.
* ZTAT is a registered trademark of Hitachi, Ltd.
1
2
Section 1. Overview
1.1 Overview
The H8/325 Series is a series of single-chip microcomputers integrating a CPU core together
with a variety of peripheral functions needed in control systems.
The H8/300 CPU is a high-speed processor featuring powerful bit-manipulation instructions,
ideally suited for realtime control applications. The on-chip supporting modules include ROM,
RAM, two types of timers (16-bit free-running timer and 8-bit timer), a serial communication
interface, I/O ports, and a parallel handshaking interface. The on-chip memory sizes of the three
chips in the H8/325 Series are:
H8/3257: 60-kbyte ROM;
H8/3256: 48-kbyte ROM;
H8/325: 32-kbyte ROM;
H8/324: 24-kbyte ROM;
H8/323: 16-kbyte ROM;
H8/322: 8-kbyte ROM;
2-kbyte RAM
2-kbyte RAM
1-kbyte RAM
1-kbyte RAM
512-byte RAM
256-byte RAM
The H8/325 Series can operate in single-chip mode or in two expanded modes, depending on the
memory requirements of the application. The operating mode is referred to in this manual as the
MCU mode (MCU: MicroComputer Unit).
The H8/3257, H8/3256, H8/325, H8/323, and H8/322 are available in a masked ROM version, or
a ZTAT™* version with electrically programmable ROM that can be programmed at the user
site.
* ZTAT is a registered trademark of Hitachi, Ltd.
Table 1-1 lists the features of the H8/325 Series.
3
Table 1-1. Features
Feature
Description
CPU
General register architecture
•
•
Eight 16-bit general registers, or
Sixteen 8-bit general registers
High speed
•
•
•
Maximum clock rate: 10 MHz
Add/subtract: 0.2 µs
Multiply/divide: 1.4 µs
Concise, streamlined instruction set
•
•
•
All instructions are 2 or 4 bytes long
Register-register arithmetic and logic operations
Register-memory data transfer by MOV instruction
Instruction set features
•
•
•
•
Memory
Multiply instruction (8 bits × 8 bits)
Divide instruction (16 bits ÷ 8 bits)
Bit-accumulator instructions
Register-indirect specification of bit positions
H8/3257
•
•
ROM: 60 kbytes
RAM: 2 kbytes
H8/3256
•
•
ROM: 48 kbytes
RAM: 2 kbytes
H8/325
•
•
ROM: 32 kbytes
RAM: 1 kbyte
H8/324
•
•
ROM: 24 kbytes
RAM: 1 kbyte
H8/323
•
•
ROM: 16 kbytes
RAM: 512 bytes
H8/322
•
•
ROM: 8 kbytes
RAM: 256 bytes
16-Bit free-running
timer module
(FRT: 1 channel)
•
•
•
One 16-bit free-running counter (also usable for external event counting)
Two compare outputs
One capture input
8-Bit timer module
(2 channels)
Each channel has:
4
•
•
One 8-bit up-counter (also usable for external event counting)
Two time constant registers
Table 1-1. Features (cont.)
Feature
Description
Serial communication interface
(SCI: 2 channels)
•
Selection of asynchronous and synchronous modes
•
Simultaneous transmit and receive (full duplex operation)
•
On-chip baud rate generator
•
53 input/output pins (of which 16 can drive large current loads)
•
All input pins have programmable input pull-ups
•
Built-in parallel handshaking is available at port 3
I/O ports
Parallel handshaking interface
Interrupts
Operating modes
Power-down
state
Other features
Product lineup
•
Four external interrupt pins: 10,, ,54 to ,54
•
Seventeen on-chip interrupt sources
•
Mode 1: expanded mode with on-chip ROM disabled
•
Mode 2: expanded mode with on-chip ROM enabled
•
Mode 3: single-chip mode
•
Sleep mode
•
Software standby mode
•
Hardware standby mode
•
On-chip clock oscillator
•
E clock output
Type code
(5V series)
Type code
(3V series)
Package
ROM
HD6473257C
HD6473257VC
64-Pin windowed shrink
DIP(DC-64S)
PROM
HD6473257P
HD6473257VP
64-Pin shrink DIP (DP-64S)
HD6473257F
HD6473257VF
64-Pin QFP (FP-64A)
HD6473257CP
HD6473257VCP
68-Pin PLCC (CP-68)
HD6433257P
HD6433257VP
64-Pin shrink DIP (DP-64S)
HD6433257F
HD6433257VF
64-Pin QFP (FP-64A)
HD6433257CP
HD6433257VCP
68-Pin PLCC (CP-68)
HD6473256P
HD6473256VP
64-Pin shrink DIP (DP-64S)
HD6473256F
HD6473256VF
64-Pin QFP (FP-64A)
HD6473256CP
HD6473256VCP
68-Pin PLCC (CP-68)
HD6433256P
HD6433256VP
64-Pin shrink DIP (DP-64S)
HD6433256F
HD6433256VF
64-Pin QFP (FP-64A)
HD6433256CP
HD6433256VCP
68-Pin PLCC (CP-68)
Masked
ROM
PROM
Masked
ROM
5
Table 1-1. Features (cont.)
Feature
Description
Product lineup
(cont.)
Type code (5V
series)
6
Type code Package
(3V series)
ROM
HD6473258C
64-Pin windowed shrink
DIP(DC-64S)
HD6473258P
64-Pin shrink DIP (DP-64S)
HD6473258F
64-Pin QFP (FP-64A)
HD6473258CP
68-Pin PLCC (CP-68)
HD6433258P
HD6433258F
HD6433258CP
64-Pin shrink DIP (DP-64S)
64-Pin QFP (FP-64A)
68-Pin PLCC (CP-68)
Masked ROM
HD6413258P
HD6413258F
HD6413258CP
64-Pin shrink DIP (DP-64S)
64-Pin QFP (FP-64A)
68-Pin PLCC (CP-68)
No ROM
HD6433248P
HD6433248F
HD6433248CP
64-Pin shrink DIP (DP-64S)
64-Pin QFP (FP-64A)
68-Pin PLCC (CP-68)
Masked ROM
HD6473238P
HD6473238F
HD6473238CP
64-Pin shrink DIP (DP-64S)
64-Pin QFP (FP-64A)
68-Pin PLCC (CP-68)
PROM
HD6433238P
HD6433238F
HD6433238CP
64-Pin shrink DIP (DP-64S)
64-Pin QFP (FP-64A)
68-Pin PLCC (CP-68)
Masked ROM
HD6413238P
HD6413238F
HD6413238CP
64-Pin shrink DIP (DP-64S)
64-Pin QFP (FP-64A)
68-Pin PLCC (CP-68)
No ROM
HD6473228P
HD6473228F
HD6473228CP
64-Pin shrink DIP (DP-64S)
64-Pin QFP (FP-64A)
68-Pin PLCC (CP-68)
PROM
HD6433228P
HD6433228F
HD6433228CP
64-Pin shrink DIP (DP-64S)
64-Pin QFP (FP-64A)
68-Pin PLCC (CP-68)
Masked ROM
PROM
1.2 Block Diagram
Clock
pulse
generator
STBY
V
cc
V
cc
V
ss
V
ss
RES
MD
0
MD
1
NMI
CPU
P1 / A
1
P1 / A
2
P1 / A
3
P1 / A
4
P1 / A
5
P1 / A
6
P1 / A
7
0
1
RAM
2
3
4
Port 2
0
P7 / IS
0
P7 / OS
1
P7 / BUSY
2
Port 7
Data bus (low)
P1 / A
Address bus
H8/300
Data bus (High)
XTAL
EXTAL
Figure 1-1 shows a block diagram of the H8/325 Series.
3
P7 / AS
4
P7 / WR
5
PROM*
(or masked
P7 / RD
6
P7 / WAIT
ROM)
5
P7 / IOS
7
16-Bit
free-running timer
6
7
P3 / D
0
Port 3
7
0
1
2
3
4
5
6
7
15
7
1
P4 / E
6
1
P4 / ø
5
0
0
P4 / TMRI
4
P4 / TMO
3
2
0
P4 / TMCI
1
0
P4 / TMRI
P4 / TMO
P4 / TMCI
1
2
6
5
P6 / IRQ
P6 / IRQ
3
0
4
P6 / FTI
2
P6 / IRQ
1
P6 / FTOB
0
P6 / FTOA
P6 / FTCI
1
5
1
Port 4
Port 6
1
Port 5
4
7
P3 / D
14
P5 / SCK
P2 / A
4
6
1
6
3
P3 / D
P3 / D
13
P5 / RxD
P2 / A
P3 / D
5
0
5
2
8-Bit timer
(2 channels)
P3 / D
3
P2 / A
12
P5 / TxD
4
0
P2 / A
11
2
3
0
P2 / A
10
1
2
0
P2 / A
P3 / D
Serial
communication
(2 channels)
9
P5 / SCK
1
1
P5 / RxD
P2 / A
P3 / D
8
P5 / TxD
0
Port 2
P2 / A
Memory size
H8/3257
H8/3256
H8/325
H8/324
H8/323
H8/322
ROM
60 kbytes
48 kbytes
32 kbytes
24 kbytes
16 kbytes
8 kbytes
RAM
2 kbytes
2 kbytes
1 kbyte
1 kbytes
512 bytes
256 bytes
* H8/3257, H8/3256, H8/325, H8/323 and H8/322 are available with PROM.
Figure 1-1. Block Diagram
7
1.3 Pin Assignments and Functions
1.3.1 Pin Arrangement
Figure 1-2 shows the pin arrangement of the H8/325 Series in the DC-64S and DP-64S packages.
Figure 1-3 shows the pin arrangement in the FP-64A package. Figure 1-4 shows the pin
arrangement in the CP-68 package.
P6 0 /FTCI
1
64
P3 7 /D 7
P6 1 /FTOA
2
63
P3 6 /D 6
P6 2 /FTOB
3
62
P3 5 /D 5
P6 3 /FTI
4
61
P3 4 /D 4
P6 4 /IRQ 0
5
60
P3 3 /D 3
P6 5 /IRQ 1
6
59
P3 2 /D 2
P6 6/IRQ 2
7
58
P3 1 /D 1
RES
8
57
P3 0 /D 0
XTAL
9
56
P1 0 /A 0
EXTAL
10
55
P1 1 /A 1
MD1
11
54
P1 2 /A 2
MD0
12
53
P1 3 /A 3
NMI
13
52
P1 4 /A 4
V CC
14
51
P1 5 /A 5
STBY
15
50
P1 6 /A 6
V SS
16
49
P1 7 /A 7
P4 0 /TMCI0
17
48
VSS
P4 1 /TMO 0
18
47
P20 /A 8
P4 2 /TMRI0
19
46
P21 /A 9
P4 3 /TMCI1
20
45
P22 /A 10
P4 4 /TMO 1
21
44
P23 /A 11
P4 5 /TMRI1
22
43
P24 /A 12
P4 6 /ø
23
42
P25 /A 13
P4 7 /E
24
41
P26 /A 14
P5 0 /TxD 0
25
40
P27 /A 15
P5 1 /RxD 0
26
39
VCC
P5 2 /SCK 0
27
38
P77 /WAIT
P5 3 /TxD 1
28
37
P76 /RD
P5 4 /RxD 1
29
36
P75 /WR
P5 5 /SCK 1
30
35
P74 /AS
P7 0 /IS
31
34
P73 /IOS
P7 1 /OS
32
33
P72 /BUSY
Figure 1-2. Pin Arrangement (DC-64S, DP-64S, Top View)
8
RES
P6 6 /IRQ 2
P6 5 /IRQ 1
P6 4 /IRQ 0
P6 3 /FTI
P6 2 /FTOB
P6 1 /FTOA
P6 0 /FTCI
P3 7 /D 7
P3 6 /D 6
P3 5 /D 5
P3 4 /D 4
P3 3 /D 3
P3 2 /D 2
P3 1 /D 1
P3 0 /D 0
64
63
62
61
60
59
58
57
56
55
54
53
52
51
50
49
XTAL
1
48
P1 0 /A 0
EXTAL
2
47
P1 1 /A 1
MD1
3
46
P1 2 /A 2
MD0
4
45
P1 3 /A 3
NMI
5
44
P1 4 /A 4
V CC
6
43
P1 5 /A 5
STBY
7
42
P1 6 /A 6
V SS
8
41
P1 7 /A 7
P40 /TMCI0
9
40
V SS
P41 /TMO0
10
39
P2 0 /A 8
P4 2 /TMRI0
11
38
P2 1 /A 9
P4 3 /TMCI1
12
37
P2 2 /A 10
28
29
30
31
32
P76 /RD
P77 /WAIT
V CC
P2 7/A15
26
P73 /IOS
27
25
P72 /BUSY
P7 4 /AS
24
P75 /WR
23
P70 /IS
22
P71 /OS
21
P5 4 /RxD1
P2 6 /A 14
P5 5 /SCK1
P2 5 /A 13
33
20
34
16
19
15
P5 3 /TxD1
P4 6 /ø
P4 7/E
P5 2 /SCK0
P2 4 /A 12
18
P2 3 /A 11
35
17
36
14
P50 /TxD0
13
P5 1 /RxD0
P4 4 /TMO1
P4 5 /TMRI1
Figure 1-3. Pin Arrangement (FP-64A, Top View)
9
P3 5 /D 5
P3 4 /D 4
P3 3 /D 3
P3 2 /D 2
P3 1 /D 1
P3 0 /D 0
65
64
63
62
61
P6 0 /FTCI
2
P3 6 /D 6
P6 1 /FTOA
3
66
P6 2 /FTOB
4
67
P6 3 /FTI
5
P3 7 /D 7
P6 4 /IRQ 0
6
NC
P6 5 /IRQ 1
7
1
P6 6 /IRQ 2
8
68
RES
9
• PLCC-68
XTAL
10
60
P1 0 /A 0
EXTAL
11
59
P1 1 /A 1
MD1
12
58
P1 2 /A 2
MD0
13
57
P1 3 /A 3
NMI
14
56
P1 4 /A 4
V CC
15
55
P1 5 /A 5
STBY
16
54
P1 6 /A 6
V SS
17
53
P1 7 /A 7
NC
18
52
V SS
P40 /TMCI0
19
51
NC
37
38
39
40
41
42
43
P73 /IOS
P7 4 /AS
P75 /WR
P76 /RD
P77 /WAIT
V CC
P2 7/A15
P50 /TxD0
36
P2 6 /A 14
35
44
NC
26
P72 /BUSY
P4 7/E
34
P2 5 /A 13
33
P2 4 /A 12
45
P70 /IS
46
25
P71 /OS
24
P4 6 /ø
32
P4 5 /TMRI1
31
P2 3 /A 11
P5 4 /RxD1
P2 2 /A 10
47
P5 5 /SCK1
48
23
30
22
P4 4 /TMO1
29
P4 3 /TMCI1
P5 3 /TxD1
P2 1 /A 9
28
P2 0 /A 8
49
P5 1 /RxD0
50
21
P5 2 /SCK0
20
27
P41 /TMO0
P4 2 /TMRI0
Figure 1-4. Pin Arrangement (CP-68, Top View)
10
1.3.2 Pin Functions
(1) Pin Assignments in Each Operating Mode: Table 1-2 lists the assignments of the pins of
the DC-64S, DP-64S, FP-64A, and CP-68 packages in each operating mode.
Table 1-2. Pin Assignments in Each Operating Mode (1)
Pin no.
Expanded modes
Single-chip mode
DC-64S
DP-64S
FP-64A
CP-68
Mode 1
—
—
1
NC
NC
NC
NC
1
57
2
P60/FTCI
P60/FTCI
P60/FTCI
NC
2
58
3
P61/FTOA
P61/FTOA
P61/FTOA
NC
3
59
4
P62/FTOB
P62/FTOB
P62/FTOB
NC
4
60
5
P63/FTI
P63/FTI
P63/FTI
NC
5
61
6
6
62
7
P65/,54
P65/,54
NC
7
63
8
8
64
9
5(6
VPP
Mode 2
P64/,54
P64/,54
P66/,54
P66/,54
P65/,54
5(6
5(6
Mode 3
P64/,54
P66/,54
PROM
mode
NC
NC
9
1
10
XTAL
XTAL
XTAL
NC
10
2
11
EXTAL
EXTAL
EXTAL
NC
11
3
12
MD1
MD1
MD1
VSS
12
4
13
MD0
MD0
13
5
14
10,
MD0
14
6
15
VCC
15
7
16
16
8
17
VSS
—
—
18
NC
17
9
19
P40/TMCI0
18
10
20
19
11
21
20
12
21
67%<
10,
VCC
67%<
10,
VCC
VSS
EA9
VCC
67%<
VSS
VSS
VSS
VSS
NC
NC
NC
P40/TMCI0
P40/TMCI0
EO0
P41/TMO0
P41/TMO0
P41/TMO0
EO1
P42/TMRI0
P42/TMRI0
P42/TMRI0
EO2
22
P43/TMCI1
P43/TMCI1
P43/TMCI1
EO3
13
23
P44/TMO1
P44/TMO1
P44/TMO1
EO4
22
14
24
P45/TMRI1
P45/TMRI1
P45/TMRI1
EO5
23
15
25
φ
φ
P46/φ
EO6
24
16
26
P47/E
P47/E
P47
EO7
25
17
27
P50/TxD0
P50/TxD0
P50/TxD0
NC
26
18
28
P51/RxD0
P51/RxD0
P51/RxD0
NC
27
19
29
P52/SCK0
P52/SCK0
P52/SCK0
NC
Notes: 1. Pins marked NC should be left unconnected.
2. The PROM mode is a non-operating mode used for programming the on-chip ROM.
See section 11, ROM for details.
11
Table 1-2. Pin Assignments in Each Operating Mode (1)
Pin no.
Expanded modes
Single-chip mode
DC-64S
DP-64S
FP-64A
CP-68
Mode 1
Mode 2
Mode 3
PROM
mode
28
20
30
P53/TxD1
P53/TxD1
P53/TxD1
NC
29
21
31
P54/RxD1
P54/RxD1
P54/RxD1
NC
30
22
32
P55/SCK1
P55/SCK1
P55/SCK1
NC
31
23
33
P70/,6
P70/,6
P70/,6
VCC
32
24
34
P71
P71
P71/26
VCC
—
—
35
NC
NC
NC
NC
33
25
36
P72
P72
NC
34
26
37
P73/,26
35
27
38
36
28
39
37
29
40
38
30
41
$6
:5
5'
:$,7
P73/,26
$6
:5
5'
:$,7
P72/%86<
39
31
42
VCC
40
32
43
A15
41
33
44
42
34
45
43
35
44
36
45
P73
NC
P74
NC
P75
NC
P76
NC
P77
NC
VCC
VCC
VCC
P27/A15
P27
CE
A14
P26/A14
P26
EA14
A13
P25/A13
P25
EA13
46
A12
P24/A12
P24
EA12
47
A11
P23/A11
P23
EA11
37
48
A10
P22/A10
P22
EA10
46
38
49
A9
P21/A9
P21
OE
47
39
50
A8
P20/A8
P20
EA8
—
—
51
NC
NC
NC
NC
48
40
52
VSS
VSS
VSS
VSS
49
41
53
A7
P17/A7
P17
EA7
50
42
54
A6
P16/A6
P16
EA6
51
43
55
A5
P15/A5
P15
EA5
52
44
56
A4
P14/A4
P14
EA4
53
45
57
A3
P13/A3
P13
EA3
54
46
58
A2
P12/A2
P12
EA2
Notes: 1. Pins marked NC should be left unconnected.
2. The PROM mode is a non-operating mode used for programming the on-chip ROM.
See section 11, ROM for details.
12
Table 1-2. Pin Assignments in Each Operating Mode (1)
Pin no.
Expanded modes
Single-chip mode
DC-64S
DP-64S
FP-64A
CP-68
Mode 1
Mode 2
Mode 3
PROM
mode
55
47
59
A1
P11/A1
P11
EA1
56
48
60
A0
P10/A0
P10
EA0
57
49
61
D0
D0
P30
NC
58
50
62
D1
D1
P31
NC
59
51
63
D2
D2
P32
NC
60
52
64
D3
D3
P33
NC
61
53
65
D4
D4
P34
NC
62
54
66
D5
D5
P35
NC
63
55
67
D6
D6
P36
NC
64
56
68
D7
D7
P37
NC
Notes: 1. Pins marked NC should be left unconnected.
2. The PROM mode is a non-operating mode used for programming the on-chip ROM.
See section 11, ROM for details.
13
(2) Pin Functions: Table 1-3 gives a concise description of the function of each pin.
Table 1-3. Pin Functions (1)
Type
Symbol
I/O
Name and function
Power
VCC
I
Power: Connected to the power supply (+5 V or +3 V).
Connect both VCC pins to the system power supply (+5 V or +3
V).
VSS
I
Ground: Connected to ground (0 V). Connect both VSS pins to
the system power supply (0 V).
XTAL
I
Crystal: Connected to a crystal oscillator. The crystal
frequency must be double the desired system clock frequency.
If an external clock is input at the EXTAL pin, a reverse-phase
clock should be input at the XTAL pin.
EXTAL
I
External crystal: Connected to a crystal oscillator or external
clock. The frequency of the external clock must be double the
desired system clock frequency. See section 14, Clock Pulse
Generator for examples of connections to a crystal and
external clock.
φ
O
System clock: Supplies the system clock to peripheral devices
E
O
Enable clock: Supplies an E clock to peripheral devices.
5(6
67%<
I
Reset: A low input causes the chip to reset.
I
Standby: A transition to the hardware standby mode (a powerdown state) occurs when a low input is received at the 67%<
pin.
A15 to A0
O
Address bus: Address output pins.
I/O
Data bus: 8-Bit bidirectional data bus.
:$,7
I
Wait: Requests the CPU to insert TW states into the bus cycle
when an off-chip address is accessed.
5'
O
Read: Goes low to indicate that the CPU is reading an external
address
:5
O
Write: Goes low to indicate that the CPU is writing to an
external address
$6
O
Address Strobe: Goes low to indicate that there is a valid
address on the address bus
Clock
System
control
Address
bus
Data bus D7 to D0
Bus
control
14
Table 1-3. Pin Functions (2)
Type
Symbol
I/O
Name and function
Bus control
,26
O
I/O Select: Goes low when the CPU accesses addresses H’FF00
to H’FFFF in expanded mode. Can be used as a chip select
signal replacing the upper 8 bits of the address bus when external
devices are mapped onto high addresses.
10,
I
NonMaskable Interrupt: Highest-priority interrupt request. The
NMIEG bit in the system control register determines whether the
interrupt is requested on the rising or falling edge of the 10,
input.
,54 to
,54
I
Interrupt Request 0 to 2: Maskable interrupt request pins.
I
Mode: Input pins for setting the MCU operating mode according
to the table below.
Interrupt
signals
Operating
mode
control
MD1,
MD0
MD1
MD0
Mode
Description
0
1
Mode 1
Expanded mode with
on-chip ROM disabled
1
0
Mode 2
Expanded mode with
on-chip ROM enabled
1
1
Mode 3
Single-chip mode
The inputs at these pins are latched in mode select bits 1 to 0
(MDS1 and MDS0) of the mode control register (MDCR) on the
rising edge of the 5(6 signal.
16-Bit free- FTCI
running
timer
I
FRT counter Clock Input: Input pin for an external clock signal
for the free-running timer.
FTOA,
FTOB
O
FRT Output compare A and B: Output pins controlled by
comparators A and B of the free-running timer.
FTI
I
FRT Input capture: Input capture pin for the free-running timer.
O
8-bit TiMer Output (channels 0 and 1): Compare-match output
pins for the 8-bit timers.
TMCI0,
TMCI1
I
8-bit TiMer Clock Input (channels 0 and 1):
External clock input pins for the 8-bit timer counters.
TMRI0,
TMRI1
I
8-bit TiMer Reset Input (channels 0 and 1): High input at these
pins resets the 8-bit timers.
8-Bit timer TMO0,
TMO1
15
Table 1-3. Pin Functions (3)
Type
Symbol
I/O
Name and function
Serial communication
interface
TxD0
TxD1
O
Serial Transmit Data (channels 0 and 1): Data output
pins for the serial communication interface.
RxD0
RxD1
I
Serial Receive Data (channels 0 and 1): Data input
pins for the serial communication interface.
SCK0
SCK1
I/O
Serial ClocK (channels 0 and 1): Input/output pins for
the serial clock signals.
P17 to P10
I/O
Port 1: An 8-bit input/output port with programmable
MOS input pull-ups and LED driving capability. The
direction of each bit can be selected in the port 1 data
direction register (P1DDR).
P27 to P20
I/O
Port 2: An 8-bit input/output port with programmable
MOS input pull-ups and LED driving capability. The
direction of each bit can be selected in the port 2 data
direction register (P2DDR).
P37 to P30
I/O
Port 3: An 8-bit input/output port with programmable
MOS input pull-ups. The direction of each bit can be
selected in the port 3 data direction register (P3DDR).
P47 to P40
I/O
Port 4: An 8-bit input/output port with programmable
MOS input pull-ups. The direction of each bit (except
P46) can be selected in the port 4 data direction register
(P4DDR).
P55 to P50
I/O
Port 5: A 6-bit input/output port with programmable MOS
input pull-ups. The direction of each bit can be selected
in the port 5 data direction register (P5DDR).
P66 to P60
I/O
Port 6: A 7-bit input/output port with programmable MOS
input pull-ups. The direction of each bit can be selected
in the port 6 data direction register (P6DDR).
P77 to P70
I/O
Port 7: An 8-bit input/output port with programmable
MOS input pull-ups. The direction of each bit can be
selected in the port 7 data direction register (P7DDR).
P37 to P30
I/O
Data Input/Output: Data input/output pins for the parallel
handshaking interface.
,6
I
Input Strobe: Strobe input signal from an external
device.
26
O
Output Strobe: Strobe output signal to an external
device.
%86<
O
Busy: Notifies an external device that the H8/325 Series
chip is not ready to receive data.
Generalpurpose I/O
Parallel handshaking interface
16
Section 2. MCU Operating Modes and Address Space
2.1 Overview
The H8/325 Series operates in three modes numbered 1, 2, and 3. An additional non-operating
mode (mode 0) is used for programming the PROM version of the H8/325. The mode is selected
by the inputs at the mode pins (MD1 and MD0) at the instant when the chip comes out of a reset.
As indicated in table 2-1, the mode determines the size of the address space and the usage of onchip ROM and on-chip RAM. The ROMless versions (HD6413258, HD6413238) are used only
in mode 1 (expanded mode with on-chip ROM disabled).
Table 2-1. Operating Modes
MD1
MD0
Mode
Address space On-chip ROM
On-chip RAM
Low
Low
Mode 0
—
—
—
Low
High
Mode 1
Expanded
Disabled
Enabled*
High
Low
Mode 2
Expanded
Enabled
Enabled*
High
High
Mode 3
Single-chip
Enabled
Enabled
* If the RAME bit in the system control register (SYSCR) is cleared to 0, off-chip memory can be
accessed instead.
Modes 1 and 2 are expanded modes that permit access to off-chip memory and peripheral
devices. The maximum address space supported by these externally expanded modes is 64
kbytes.
In mode 3 (single-chip mode), only on-chip ROM and RAM and the on-chip register field are
used. All ports are available for general-purpose input and output.
Mode 0 is inoperative in the H8/325 Series. Avoid setting the mode pins to mode 0.
17
2.2 Mode Descriptions
Mode 1 (Expanded Mode without On-Chip ROM): Mode 1 supports a 64-kbyte address space
most of which is off-chip. In particular, the interrupt vector table is located in off-chip memory.
The on-chip ROM is not used. Software can select whether to use the on-chip RAM. Ports 1, 2, 3
and 7 are used for the address and data bus lines and control signals as follows:
Ports 1 and 2: Address bus
Port 3:
Data bus
Port 7 (partly): Bus control signals
Mode 2 (Expanded Mode with On-Chip ROM): Mode 2 supports a 64-kbyte address space
which includes the on-chip ROM. Software can select whether or not to use the on-chip RAM,
and can select the usage of pins in ports 1 and 2.
Ports 1 and 2:
Address bus (see note)
Port 3:
Data bus
Port 7 (partly): Bus control signals
Note: In mode 2, ports 1 and 2 are initially general-purpose input ports. Software must change
the desired pins to output before using them for the address bus. See section 5, I/O Ports
for details.
Mode 3 (Single-Chip Mode): In this mode all memory is on-chip. Since no off-chip memory is
accessed, there is no external address bus. All ports are available for general-purpose input and
output.
2.3 Address Space Map
Figures 2-1 to 2-6 show memory maps of the H8/3257, H8/3256, H8/325, H8/324, H8/323, and
H8/322 in each of the three operating modes. The on-chip register field consists of control,
status, and data registers for the on-chip supporting modules and I/O ports.
Off-chip addresses can be accessed only in the expanded modes. Access to an off-chip address in
the single-chip mode does not cause an address error, but all 1 data are returned.
2.3.1 Access Speed
On-chip ROM and RAM are accessed a word (16 bits) at a time in two states. (A “state” is one
system clock cycle.) The on-chip register field is accessed a byte at a time in three states.
18
External memory is accessed a byte at a time in three or more states. The basic bus cycle is three
states, but additional wait states can be inserted on request.
2.3.2
,26
There are two gaps in the on-chip address space above the on-chip RAM. Addresses H’FF80 to
H’FF8F, situated between the on-chip RAM and register field, are off-chip. Addresses H’FFA0
to H’FFAF are also off-chip. These 32 addresses can be conveniently assigned to external I/O
devices. To simplify the addressing of devices at these addresses, an ,26 signal is provided that
goes low when the CPU accesses addresses H’FF00 to H’FFFF. The ,26 signal can be used in
place of the upper 8 bits of the address bus.
19
Mode 1
Expand mode without on-chip ROM
H'0000
Mode 3
Single-chip mode
Mode 2
Expand mode with on-chip ROM
H'0000
H'0000
Vector table
Vector table
H'002F
H'0030
Vector table
H'002F
H'0030
H'002F
H'0030
On-chip ROM,
60 Kbytes
On-chip ROM,
60 Kbytes
External address
space
H'EFFF
H'F000
H'EFFF
External address
space
H'F77F
H'F780
H'F77F
H'F780
On - chip RAM*,
2 Kbytes
On - chip RAM*,
2 Kbytes
H'FF7F
H'FF80
External address space
External address space
H'FF8F
H'FF90
On-chip register field
H'FF90
On-chip register field
On-chip register field
H'FF9F
H'FFA0
H'FF9F
H'FF9F
H'FFA0
External address space
H'FFAF
H'FFB0
On - chip RAM,
2 Kbytes
H'FF7F
H'FF7F
H'FF80
H'FF8F
H'FF90
External address space
H'FFAF
H'FFB0
On-chip register field
H'FFFF
H'F780
H'FFB0
On-chip register field
On-chip register field
H'FFFF
H'FFFF
* External memory can be accessed at these addresses when the RAME bit in the system control
register (SYSCR) is cleared to 0.
Figure 2-1. H8/3257 Address Space Map
20
Mode 1
Expand mode without on-chip ROM
H'0000
Mode 3
Single-chip mode
Mode 2
Expand mode with on-chip ROM
H'0000
H'0000
Vector table
Vector table
H'002F
H'0030
Vector table
H'002F
H'0030
H'002F
H'0030
On-chip ROM,
48 Kbytes
On-chip ROM,
48 Kbytes
External address
space
H'BFFF
H'C000
H'BFFF
External address
space
H'F77F
H'F780
H'F77F
H'F780
On - chip RAM*,
2 Kbytes
On - chip RAM*,
2 Kbytes
H'FF7F
H'FF80
External address space
External address space
H'FF8F
H'FF90
On-chip register field
H'FF90
On-chip register field
On-chip register field
H'FF9F
H'FFA0
H'FF9F
H'FF9F
H'FFA0
External address space
H'FFAF
H'FFB0
On - chip RAM,
2 Kbytes
H'FF7F
H'FF7F
H'FF80
H'FF8F
H'FF90
External address space
H'FFAF
H'FFB0
On-chip register field
H'FFFF
H'F780
H'FFB0
On-chip register field
On-chip register field
H'FFFF
H'FFFF
* External memory can be accessed at these addresses when the RAME bit in the system control
register (SYSCR) is cleared to 0.
Figure 2-2. H8/3256 Address Space Map
21
Mode 1
Expand mode without on-chip ROM
H'0000
H'0000
H'0000
Vector table
H'002F
H'0030
Mode 3
Single-chip mode
Mode 2
Expand mode with on-chip ROM
Vector table
Vector table
H'002F
H'0030
H'002F
H'0030
On-chip ROM,
32 Kbytes
On-chip ROM,
32 Kbytes
External address
space
H'7FFF
H'8000
H'7FFF
External address
space
H'FB7F
H'FB80
H'FB7F
H'FB80
On - chip RAM*,
1 Kbyte
On - chip RAM*,
1 Kbyte
H'FF7F
H'FF80
External address space
External address space
H'FF8F
H'FF90
On-chip register field
H'FF9F
H'FFA0
H'FF90
On-chip register field
On-chip register field
H'FF9F
H'FF9F
H'FFA0
External address space
H'FFAF
H'FFB0
On - chip RAM,
1 Kbyte
H'FF7F
H'FF7F
H'FF80
H'FF8F
H'FF90
External address space
H'FFAF
H'FFB0
On-chip register field
H'FFFF
H'FB80
H'FFB0
On-chip register field
On-chip register field
H'FFFF
H'FFFF
* External memory can be accessed at these addresses when the RAME bit in the system control
register (SYSCR) is cleared to 0.
Figure 2-3. H8/325 Address Space Map
22
Mode 2
Expand mode with on-chip ROM
Mode 1
Expand mode without on-chip ROM
H'0000
H'0000
H'0000
Vector table
Mode 3
Single-chip mode
Vector table
H'002F
H'0030
Vector table
H'002F
H'0030
H'002F
H'0030
On-chip ROM,
24 Kbytes
H'5FFF
H'6000
External address
space
H'7FFF
H'8000
On-chip ROM,
24 Kbytes
H'5FFF
Reserved
*2
External address
space
H'FB7F
H'FB80
H'FB7F
H'FB80
On - chip RAM,
1 Kbyte
*1
On - chip RAM,
1 Kbyte
*1
H'FF7F
H'FF80
H'FF7F
H'FF80
External address space
External address space
On-chip register field
H'FF90
External address space
H'FF9F
External address space
H'FFAF
H'FFB0
H'FFAF
H'FFB0
On-chip register field
On-chip register field
H'FF9F
H'FFA0
H'FF9F
H'FFA0
On - chip RAM,
1 Kbyte
H'FF7F
H'FF8F
H'FF90
H'FF8F
H'FF90
On-chip register field
H'FFFF
H'FB80
H'FFB0
On-chip register field
On-chip register field
H'FFFF
H'FFFF
*1 This area can be used as external address space when the RAME bit of SYSCR is 0.
*2 Data read or write is not permitted in these modes.
Figure 2-4. H8/324 Address Space Map
23
Mode 2
Expand mode with on-chip ROM
Mode 1
Expand mode without on-chip ROM
H'0000
H'0000
H'0000
Vector table
H'002F
H'0030
Mode 3
Single-chip mode
Vector table
Vector table
H'002F
H'0030
H'002F
H'0030
On-chip ROM,
16 Kbytes
H'3FFF
H'4000
On-chip ROM,
16 Kbytes
H'3FFF
External address
space
External address
space
H'FD7F
H'FD80
H'FD7F
H'FD80
On - chip RAM*,
512 bytes
External address space
H'FF7F
External address space
H'FF8F
H'FF90
H'FF8F
H'FF90
On-chip register field
H'FF90
External address space
H'FF9F
External address space
H'FFAF
H'FFB0
H'FFAF
H'FFB0
On-chip register field
On-chip register field
H'FF9F
H'FFA0
H'FF9F
H'FFA0
On - chip RAM,
512 bytes
On - chip RAM*,
512 bytes
H'FF7F
H'FF80
H'FF7F
H'FF80
On-chip register field
H'FFFF
H'FD80
H'FFB0
On-chip register field
On-chip register field
H'FFFF
H'FFFF
* External memory can be accessed at these addresses when the RAME bit in the system control
register (SYSCR) is cleared to 0.
Figure 2-5. H8/323 Address Space Map
24
H'0000
H'0000
H'0000
Vector table
H'002F
H'0030
Mode 3
Single-chip mode
Mode 2
Expand mode with on-chip ROM
Mode 1
Expand mode without on-chip ROM
Vector table
H'002F
H'0030
On-chip ROM,
8 Kbytes
H'1FFF
H'2000
Reserved
H'3FFF
Vector table
H'002F
H'0030
On-chip ROM,
8 Kbytes
*2
H'1FFF
External address
space
External address
space
H'FD7F
H'FD80
H'FD7F
H'FD80
Reserved
H'FE7F
H'FE80
On - chip RAM, *1
256 bytes
H'FF7F
H'FF80
H'FD80
*1 *2
Reserved
H'FE7F
H'FE80
On - chip RAM, *1
256 bytes
H'FF7F
H'FF80
External address space
*1 *2
On-chip register field
External address space
External address space
On-chip register field
H'FFB0
On-chip register field
On-chip register field
H'FFFF
H'FFFF
On-chip register field
H'FF9F
H'FFAF
H'FFB0
H'FFAF
H'FFB0
On - chip RAM,
256 bytes
H'FF90
On-chip register field
H'FF9F
H'FFA0
H'FF9F
H'FFA0
H'FE80
H'FF7F
*2
External address space
H'FF8F
H'FF90
H'FF8F
H'FF90
Reserved
H'FFFF
*1
External memory can be accessed at these addresses when the RAME bit in the system control
register (SYSCR) is cleared to 0.
*2
Data read or write is not permitted in these modes.
Figure 2-6. H8/322 Address Space Map
25
2.4 Mode and System Control Registers (MDCR and SYSCR)
Two of the control registers in the register field are the mode control register (MDCR) and
system control register (SYSCR). The mode control register controls the MCU mode: the
operating mode of the H8/325 Series chip. The system control register has a bit that enables or
disables the on-chip RAM. Table 2-2 lists the attributes of these registers.
Table 2-2. Mode and System Control Registers
Name
Abbreviation
Read/Write
Address
Mode control register
MDCR
R
H’FFC5
System control register
SYSCR
R/W
H’FFC4
2.4.1 Mode Control Register (MDCR)—H’FFC5
Bit
7
6
5
4
3
2
1
0
—
—
—
—
—
—
MDS1
MDS0
Initial value
1
1
1,
0
0
1
*
*
Read/Write
R
R
R
R
R
R
R
R
* Initialized according to MD1 and MD0 inputs.
Bits 7 to 5 and 2—Reserved: These bits cannot be modified and are always read as 1.
Bits 4 and 3—Reserved: These bits cannot be modified and are always read as 0.
Bits 1 and 0—Mode Select 1 and 0 (MDS1 and MDS0): These bits indicate the values of the
mode pins (MD1 and MD0) latched on the rising edge of the 5(6 signal. These bits can be read
but not written.
Coding Example: To test whether the MCU is operating in mode 1:
MOV.B @H’FFC5, R0L
CMP.B #H’E5, R0L
The comparison is with H’E5 instead of H’01 because bits 7, 6, 5, and 2 are always read as 1.
26
2.4.2 System Control Register (SYSCR)—H’FFC4
By setting or clearing bit 0 of the system control register, software can enable or disable the onchip RAM.
The other bits in the system control register concern the software standby mode and the valid
edge of the 10, signal. These bits will be described in section 4, Exception Handling and
section 12, Power-Down State.
Bit
7
6
5
4
3
2
1
0
SSBY
STS2
STS1
STS0
—
NMIEG
—
RAME
Initial value
0
0
0
0
1
0
1
1
Read/Write
R/W
R/W
R/W
R/W
—
R/W
—
R/W
Bit 0—RAM Enable (RAME): This bit enables or disables the on-chip RAM. When the onchip RAM is disabled, accesses to the corresponding addresses are directed off-chip.
The RAME bit is initialized to 1 by a reset, enabling the on-chip RAM. The setting of the
RAME bit is not altered in the sleep mode or software standby mode. It should be cleared to 0
before entering the hardware standby mode. See section 12, Power-Down State.
Bit 0
RAME
Description
0
The on-chip RAM is disabled.
1
The on-chip RAM is enabled.
(Initial state)
Coding Example: To disable the on-chip RAM:
BCLR #0, @H’FFC4
27
28
Section 3. CPU
3.1 Overview
The H8/325 Series has the generic H8/300 CPU: an 8-bit central processing unit with a speedoriented architecture featuring sixteen general registers. This section describes the CPU features
and functions, including a concise description of the addressing modes and instruction set. For
further details on the instructions, see the H8/300 Series Pro gramming Manual.
3.1.1 Features
The main features of the H8/300 CPU are listed below.
• Two-way register configuration
Sixteen 8-bit general registers, or
Eight 16-bit general registers
• Instruction set with 57 basic instructions, including:
Multiply and divide instructions
Powerful bit-manipulation instructions
• Eight addressing modes
Register direct (Rn)
Register indirect (@Rn)
Register indirect with displacement (@(d:16, Rn))
Register indirect with post-increment or pre-decrement (@Rn+ or @–Rn)
Absolute address (@aa:8 or @aa:16)
Immediate (#xx:8 or #xx:16)
PC-relative (@(d:8, PC))
Memory indirect (@@aa:8)
• Maximum 64K-byte address space
• High-speed operation
All frequently-used instructions are executed two to four states
The maximum clock rate is 10MHz
• 8- or 16-bit register-register add or subtract: 0.2µs
• 8 × 8-bit multiply: 1.4µs
• 16 ÷ 8-bit divide: 1.4µs
• Power-down mode
SLEEP instruction
29
3.2 Register Configuration
Figure 3-1 shows the register structure of the CPU. There are two groups of registers: the
general registers and control registers.
7
0 7
0
R0H
R0L
R1H
R2H
R1L
R2L
R3H
R3L
R4H
R4L
R5H
R5L
R6H
R7H
R6L
(SP)
15
R7L
SP: Stack Pointer
0
PC
7 5 3 2 1 0
CCR I U H U N Z V C
PC: Program Counter
CCR: Condition Code Register
Carry flag
Overflow flag
Zero flag
Negative flag
Half-carry flag
Interrupt mask bit
User bit
User bit
Figure 3-1. CPU Registers
3.2.1 General Registers
All the general registers can be used as both data registers and address registers. When used as
address registers, the general registers are accessed as 16-bit registers (R0 to R7). When used as
data registers, they can be accessed as 16-bit registers, or the high and low bytes can be accessed
separately as 8-bit registers.
R7 also functions as the stack pointer, used implicitly by hardware in processing interrupts and
subroutine calls. In assembly-language coding, R7 can also be denoted by the letters SP. As
indicated in figure 3-2, R7 (SP) points to the top of the stack.
30
Unused area
SP
(R7)
Stack area
Figure 3-2. Stack Pointer
3.2.2 Control Registers
The CPU control registers include a 16-bit program counter (PC) and an 8-bit condition code
register (CCR).
(1) Program Counter (PC): This 16-bit register indicates the address of the next instruction
the CPU will execute. Each instruction is accessed in 16 bits (1 word), so the least
significant bit of the PC is ignored (always regarded as 0).
(2) Condition Code Register (CCR): This 8-bit register contains internal status information,
including carry (C), overflow (V), zero (Z), negative (N), and half-carry (H) flags and the
interrupt mask bit (I).
Bit 7—Interrupt Mask Bit (I): When this bit is set to “1,” all interrupts except NMI are
masked. This bit is set to “1” automatically by a reset and at the start of interrupt handling.
Bit 6—User Bit (U): This bit can be written and read by software for its own purposes.
Bit 5—Half-Carry (H): This bit is set to “1” when the ADD.B, ADDX.B, SUB.B,
SUBX.B, NEG.B, or CMP.B instruction causes a carry or borrow out of bit 3, and is cleared
to “0” otherwise. Similarly, it is set to “1” when the ADD.W, SUB.W, or CMP.W
instruction causes a carry or borrow out of bit 11, and cleared to “0” otherwise. It is used
implicitly in the DAA and DAS instructions.
Bit 4—User Bit (U): This bit can be written and read by software for its own purposes.
Bit 3—Negative (N): This bit indicates the most significant bit (sign bit) of the result of an
instruction.
31
Bit 2—Zero (Z): This bit is set to “1” to indicate a zero result and cleared to “0” to indicate
a nonzero result.
Bit 1—Overflow (V): This bit is set to “1” when an arithmetic overflow occurs, and
cleared to “0” at other times.
Bit 0—Carry (C): This bit is used by:
Add and subtract instructions, to indicate a carry or borrow at the most significant bit of
the result
Shift and rotate instructions, to store the value shifted out of the most significant or least
significant bit
Bit manipulation and bit load instructions, as a bit accumulator
The LDC, STC, ANDC, ORC, and XORC instructions enable the CPU to load and store the
CCR, and to set or clear selected bits by logic operations.
Some instructions leave some or all of the flag bits unchanged. The action of each
instruction on the flag bits is shown in Appendix A.1, “Instruction Set List.” See the H8/300
Series Programming Manual for further details.
3.2.3 Initial Register Values
When the CPU is reset, the program counter (PC) is loaded from the vector table and the
interrupt mask bit (I) in the CCR is set to “1.” The other CCR bits and the general registers are
not initialized.
In particular, the stack pointer (R7) is not initialized. To prevent program crashes the stack
pointer should be initialized by software, by the first instruction executed after a reset.
32
3.3 Addressing Modes
The H8/325 supports eight addressing modes. Each instruction uses a subset of these addressing
modes.
(1) Register Direct—Rn: The register field of the instruction specifies an 8- or 16-bit general
register containing the operand. In most cases the general register is accessed as an 8-bit
register. Only the MOV.W, ADD.W, SUB.W, CMP.W, ADDS, SUBS, MULXU (8 bits × 8
bits), and DIVXU (16 bits ÷ 8 bits) instructions have 16-bit operands.
(2) Register indirect—@Rn: The register field of the instruction specifies a 16-bit general
register containing the address of the operand.
(3) Register Indirect with Displacement—@(d:16, Rn): This mode, which is used only in
MOV instructions, is similar to register indirect but the instruction has a second word (bytes
3 and 4) which is added to the contents of the specified general register to obtain the operand
address. For the MOV.W instruction, the resulting address must be even.
(4) Register Indirect with Post-Increment or Pre-Decrement—@Rn+ or @–Rn:
Register indirect with Post-Increment—@Rn+
The @Rn+ mode is used with MOV instructions that load registers from memory.
It is similar to the register indirect mode, but the 16-bit general register specified in the
register field of the instruction is incremented after the operand is accessed. The size of
the increment is 1 or 2 depending on the size of the operand: 1 for MOV.B; 2 for
MOV.W. For MOV.W, the original contents of the 16-bit general register must be even.
Register Indirect with Pre-Decrement—@–Rn
The @–Rn mode is used with MOV instructions that store register contents to memory.
It is similar to the register indirect mode, but the 16-bit general register specified in the
register field of the instruction is decremented before the operand is accessed. The size
of the decrement is 1 or 2 depending on the size of the operand: 1 for MOV.B; 2 for
MOV.W. For MOV.W, the original contents of the 16-bit general register must be even.
(5) Absolute Address—@aa:8 or @aa:16: The instruction specifies the absolute address of
the operand in memory. The MOV.B instruction uses an 8-bit absolute address of the form
H’FFxx. The upper 8 bits are assumed to be 1, so the possible address range is H’FF00 to
H’FFFF (65280 to 65535). The MOV.B, MOV.W, JMP, and JSR instructions can use 16-bit
absolute addresses.
33
(6) Immediate—#xx:8 or #xx:16: The instruction contains an 8-bit operand in its second byte,
or a 16-bit operand in its third and fourth bytes. Only MOV.W instructions can contain 16bit immediate values.
The ADDS and SUBS instructions implicitly contain the value 1 or 2 as immediate data.
Some bit manipulation instructions contain 3-bit immediate data (#xx:3) in the second or
fourth byte of the instruction, specifying a bit number.
(7) PC-Relative—@(d:8, PC): This mode is used to generate branch addresses in the Bcc and
BSR instructions. An 8-bit value in byte 2 of the instruction code is added as a signextended value to the program counter contents. The result must be an even number. The
possible branching range is –126 to +128 bytes (–63 to +64 words) from the current address.
(8) Memory Indirect—@@aa:8: This mode can be used by the JMP and JSR instructions.
The second byte of the instruction code specifies an 8-bit absolute address from H’0000 to
H’00FF (0 to 255). The word located at this address contains the branch address. Note that
addresses H’0000 to H’003D (0 to 61) are located in the vector table.
If an odd address is specified as a branch destination or as the operand address of a MOV.W
instruction, the least significant bit is regarded as “0,” causing word access to be performed
at the address preceding the specified address. See section 3.4.2, “Memory Data Formats”
for further information.
34
3.4 Data Formats
The H8/300 CPU can process 1-bit data, 4-bit (BCD) data, 8-bit (byte) data, and 16-bit (word)
data.
• Bit manipulation instructions operate on 1-bit data specified as bit n (n = 0, 1, 2, ..., 7) in a
byte operand.
• All arithmetic and logic instructions except ADDS and SUBS can operate on byte data.
• The DAA and DAS instruction perform decimal arithmetic adjustments on byte data in
packed BCD form. Each nibble of the byte is treated as a decimal digit.
• The MOV.W, ADD.W, SUB.W, CMP.W, ADDS, SUBS, MULXU (8 bits × 8 bits), and
DIVXU (16 bits ÷ 8 bits) instructions operate on word data.
35
3.4.1 Data Formats in General Registers
Data of all the sizes above can be stored in general registers as shown in figure 3-3.
Data Type
Register No.
1-Bit data
RnH
1-Bit data
RnL
Byte data
RnH
Byte data
RnL
Data format
7
7
0
6
5
4
3
2
1
0
Don't - care
7
0
7
Don't - care
7
6
5
4
3
2
L
S
B
Don't - care
0
L
S
B
M
S
B
Don't - care
15
Rn
4-Bit BCD data
RnH
4-Bit BCD data
RnL
0
L
S
B
M
S
B
7
4
Upper digit
0
3
Don't - care
Lower digit
7
Don't - care
4 3
Upper digit
Figure 3-3. Register Data Formats
Note:
RnH: Upper digit of general register
RnL: Lower digit of general register
MSB: Most significant Bit
LSB: Least significant Bit
36
0
0
M
S
B
7
Word data
1
0
Lower digit
3.4.2 Memory Data Formats
Figure 3-4 indicates the data formats in memory.
Word data stored in memory must always begin at an even address. In word access the least
significant bit of the address is regarded as “0.” If an odd address is specified, no address error
occurs but the access is performed at the preceding even address. This rule affects MOV.W
instructions and branching instructions, and implies that only even addresses should be stored in
the vector table.
Data Type
Address
1-Bit data
Address n
7
Byte data
Address n
M
S
B
Even address
M
S
B
Data Format
7
Word data
Odd address
Even address
Byte data (CCR) on stack
Odd address
Word data on stack
Even address
0
6
5
4
3
2
0
L
S
B
Upper 8 bits
Lower 8 bits
M
S
B
M
S
B
1
CCR
CCR*
L
S
B
L
S
B
L
S
B
M
S
B
Odd address
L
S
B
CCR : Condition code register
* :
Ignored when return
Figure 3-4. Memory Data Formats
The stack must always be accessed a word at a time. When the CCR is pushed on the stack, two
identical copies of the CCR are pushed to make a complete word. When they are returned, the
lower byte is ignored.
37
3.5 Instruction Set
Table 3-1 lists the H8/325 Series instruction set.
Table 3-1. Instruction Classification
Function
Data transfer
Instructions
Types
1
MOV, MOVTPE, MOVFPE, PUSH* , POP*
1
3
Arithmetic operations ADD, SUB, ADDX, SUBX, INC, DEC, ADDS, SUBS,
DAA, DAS, MULXU, DIVXU, CMP, NEG
14
Logic operations
AND, OR, XOR, NOT
4
Shift
SHAL, SHAR, SHLL, SHLR, ROTL, ROTR, ROTXL,
ROTXR
8
Bit manipulation
BSET, BCLR, BNOT, BTST, BAND, BIAND, BOR,
BIOR, BXOR, BIXOR, BLD, BILD, BST, BIST
14
Branch
Bcc* , JMP, BSR, JSR, RTS
5
System control
RTE, SLEEP, LDC, STC, ANDC, ORC, XORC, NOP
8
Block data transfer
EEPMOV
1
2
1
* PUSH Rn is equivalent to MOV.W Rn, @–SP.
POP Rn is equivalent to MOV.W @SP+, Rn.
2
* Bcc is a conditional branch instruction in which cc represents a condition code.
The following sections give a concise summary of the instructions in each category, and indicate
the bit patterns of their object code. The notation used is defined next.
38
Operation Notation
Rd
General register (destination)
Rs
General register (source)
Rn, Rm
General register
rn, rm
General register field
<EAs>
Effective address: general
register or memory location
(EAd)
Destination operand
(EAs)
Source operand
SP
Stack pointer
PC
Program counter
CCR
Condition code register
N
N (negative) bit of CCR
Z
Z (zero) bit of CCR
V
V (overflow) bit of CCR
C
C (carry) bit of CCR
#imm
Immediate data
#xx:3
3-Bit immediate data
#xx:8
8-Bit immediate data
#xx:16
16-Bit immediate data
op
Operation field
disp
Displacement
abs
Absolute address
B
Byte
W
Word
+
Addition
–
Subtraction
×
Multiplication
÷
Division
∧
AND logical
∨
OR logical
⊕
Exclusive OR logical
→
Move
↔
Exchange
¬
Not
cc
Condition field
39
3.5.1 Data Transfer Instructions
Table 3-2 describes the data transfer instructions. Figure 3-5 shows their object code formats.
Table 3-2. Data Transfer Instructions
Instruction Size*
Function
MOV
B/W
(EAs) → Rd, Rs → (EAd)
Moves data between two general registers or between a general register
and memory, or moves immediate data to a general register.
The Rn, @Rn, @(d:16, Rn), @aa:16, #xx:8 or #xx:16, @–Rn, and @Rn+
addressing modes are available for byte or word data. The @aa:8
addressing mode is available for byte data only.
The @–R7 and @R7+ modes require word operands. Do not specify byte
size for these two modes.
MOVTPE
B
Rs → (EAd)
Transfers data from a general register to memory in synchronization with
the E clock.
MOVFPE
B
(EAs) → Rd
Transfers data from memory to a general register in synchronization with
the E clock.
PUSH
W
Rn → @–SP
Pushes a 16-bit general register onto the stack. Equivalent to MOV.W Rn,
@–SP.
POP
W
@SP+ → Rn
Pops a 16-bit general register from the stack. Equivalent to MOV.W @SP+,
Rn.
* Size: operand size
B: Byte
W: Word
40
15
8
7
0
MOV
Op
rm
rn
Rm
Rn
Op
rm
rn
Rn
@Rm, or @Rm
rm
rn
@(d:16,Rm)
Rn, or
Rn
@(d:16,Rm)
rm
rn
@ Rm+
Rn, or Rn
@-Rm
@ aa :8
Rn, or Rn
@ aa :8
Op
Rn
disp.
Op
rn
Op
abs.
rn
Op
@ aa :16
Rn, or
Rn
@ aa :16
abs.
Op
#imm.
rn
# xx:8
Rn
rn
Op
# xx:16
Rn
#imm.
rn
Op
abs.
Op
Notation
Op
d
r m , rn
disp.
abs.
#imm.
:
:
:
:
:
:
rn
MOVFPE, MOVTPE
MOVFPE: d = 0
MOVTPE: d = 1
PUSH, POP
Operation field
Direction field (0-load from; 1-store to)
Register field
Displacement
Absolute address
Immediate data
Figure 3-5. Data Transfer Instruction Codes
41
3.5.2 Arithmetic Operations
Table 3-3 describes the arithmetic instructions. See figure 3-6 in section 3.5.4, “Shift
Operations” for their object codes.
Table 3-3. Arithmetic Instructions
Instruction
Size*
Function
ADD
SUB
B/W
Rd ±Rs → Rd, Rd + #imm → Rd
Performs addition or subtraction on data in two general registers, or
addition on immediate data and data in a general register. Immediate data
cannot be subtracted from data in a general register. Word data can be
added or subtracted only when both words are in general registers.
ADDX
SUBX
B
Rd ±Rs ± C → Rd, Rd ± #imm ± C → Rd
Performs addition or subtraction with carry or borrow on byte data in two
general registers, or addition or subtraction on immediate data and data in
a general register.
INC
DEC
B
Rd ± #1 → Rd
Increments or decrements a general register.
ADDS
SUBS
W
Rd ± #imm → Rd
Adds or subtracts immediate data to or from data in a general register.
The immediate data must be 1 or 2.
DAA
DAS
B
Rd decimal adjust → Rd
Decimal-adjusts (adjusts to packed BCD) an addition or subtraction result
in a general register by referring to the CCR.
MULXU
B
Rd × Rs → Rd
Performs 8-bit × 8-bit unsigned multiplication on data in two general
registers, providing a 16-bit result.
DIVXU
B
Rd ÷ Rs → Rd
Performs 16-bit ÷ 8-bit unsigned division on data in two general registers,
providing an 8-bit quotient and 8-bit remainder.
CMP
B/W
Rd – Rs, Rd – #imm
Compares data in a general register with data in another general register
or with immediate data. Word data can be compared only between two
general registers.
NEG
B
0 – Rd → Rd
Obtains the two’s complement (arithmetic complement) of data in a general
register.
* Size: operand size
B: Byte
W: Word
42
3.5.3 Logic Operations
Table 3-4 describes the four instructions that perform logic operations. See figure 3-6 in section
3.5.4, “Shift Operations” for their object codes.
Table 3-4. Logic Operation Instructions
Instruction Size*
Function
AND
B
Rd ∧ Rs → Rd,
Rd ∧ #imm → Rd
Performs a logical AND operation on a general register and another
general register or immediate data.
OR
B
Rd ∨ Rs → Rd,
Rd ∨ #imm → Rd
Performs a logical OR operation on a general register and another
general register or immediate data.
XOR
B
Rd ⊕ Rs → Rd,
Rd ⊕ #imm → Rd
Performs a logical exclusive OR operation on a general register and
another general register or immediate data.
NOT
B
¬ (Rd) → (Rd)
Obtains the one’s complement (logical complement) of general register
contents.
3.5.4 Shift Operations
Table 3-5 describes the eight shift instructions. Figure 3-6 shows the object code formats of the
arithmetic, logic, and shift instructions.
Table 3-5. Shift Instructions
Instruction
Size*
Function
SHAL
SHAR
B
Rd shift → Rd
Performs an arithmetic shift operation on general register contents.
SHLL
SHLR
B
Rd shift → Rd
Performs a logical shift operation on general register contents.
ROTL
ROTR
B
Rd rotate → Rd
Rotates general register contents.
ROTXL
ROTXR
B
Rd rotate through carry → Rd
Rotates general register contents through the C (carry) bit.
* Size: operand size
B: Byte
43
15
8
7
0
r
m
Op
r
Op
r
Op
r
ADDS, SUBS, INC, DEC, DAA
DAS, NEG, NOT
n
ADD, ADDX, SUBX, CMP
(#xx:8)
r
m
r
Op
Notation
Op
:
rm , rn :
#imm. :
ADD, SUB, CMP
ADDX, SUBX, MULXU, DIVXU
#imm.
n
Op
Op
n
n
r
n
AND, OR, XOR (Rm)
AND, OR, XOR (#xx:8)
#imm.
r
n
SHAL, SHAR, SHLL, SHLR,
ROTL, ROTR, ROTXL, ROTXR
Operation field
Register field
Immediate data
Figure 3-6. Arithmetic, Logic, and Shift Instruction Codes
44
3.5.5 Bit Manipulations
Table 3-6 describes the bit-manipulation instructions. Figure 3-7 shows their object code
formats.
Table 3-6. Bit-Manipulation Instructions (1)
Instruction Size*
Function
BSET
B
1 → (<bit-No.> of <EAd>)
Sets a specified bit in a general register or memory to “1.” The bit is
specified by a bit number, given in 3-bit immediate data or the lower
three bits of a general register.
BCLR
B
0 → (<bit-No.> of <EAd>)
Clears a specified bit in a general register or memory to “0.” The bit is
specified by a bit number, given in 3-bit immediate data or the lower
three bits of a general register.
BNOT
B
¬ (<bit-No.> of <EAd>) → (<bit-No.> of <EAd>)
Inverts a specified bit in a general register or memory. The bit is
specified by a bit number, given in 3-bit immediate data or the lower
three bits of a general register
BTST
B
¬ (<bit-No.> of <EAd>) → Z
Tests a specified bit in a general register or memory and sets or clears
the Z flag accordingly. The bit is specified by a bit number, given in 3bit immediate data or the lower three bits of a general register.
BAND
B
C ∧ (<bit-No.> of <EAd>) → C
ANDs the C flag with a specified bit in a general register or memory.
C ∧ [¬ (<bit-No.> of <EAd>)] → C
ANDs the C flag with the inverse of a specified bit in a general register
or memory.
The bit number is specified by 3-bit immediate data.
BIAND
BOR
B
C ∨ [¬ (<bit-No.> of <EAd>)] → C
ORs the C flag with the inverse of a specified bit in a general register or
memory.
The bit number is specified by 3-bit immediate data.
BIOR
BXOR
C ∨ (<bit-No.> of <EAd>) → C
ORs the C flag with a specified bit in a general register or memory.
B
C ⊕ (<bit-No.> of <EAd>) → C
XORs the C flag with a specified bit in a general register or memory.
* Size: operand size
B: Byte
45
Table 3-6. Bit-Manipulation Instructions (2)
Instruction Size*
Function
BIXOR
B
C ⊕ ¬ [(<bit-No.> of <EAd>)] → C
XORs the C flag with the inverse of a specified bit in a general register
or memory.
The bit number is specified by 3-bit immediate data.
BLD
B
(<bit-No.> of <EAd>) → C
Copies a specified bit in a general register or memory to the C flag.
¬ (<bit-No.> of <EAd>) → C
Copies the inverse of a specified bit in a general register or memory to
the C flag.
The bit number is specified by 3-bit immediate data.
BILD
B
BST
C → (<bit-No.> of <EAd>)
Copies the C flag to a specified bit in a general register or memory.
¬ C → (<bit-No.> of <EAd>)
Copies the inverse of the C flag to a specified bit in a general register or
memory.
The bit number is specified by 3-bit immediate data.
BIST
* Size: operand size
B: Byte
Notes on Bit Manipulation Instructions: BSET, BCLR, BNOT, BST, and BIST are readmodify-write instructions. They read a byte of data, modify one bit in the byte, then write the
byte back. Care is required when these instructions are applied to registers with write-only bits
and to the I/O port registers.
Read
Read one data byte at the specified address
Modify
Modify one bit in the data byte
Write
Write the modified data byte back to the specified address
Example 1: BCLR is executed to clear bit 0 in the port 4 data direction register (P4DDR) under
the following conditions.
P47:
P46:
P45 – P40:
Input pin, Low, MOS pull-up transistor on
Input pin, High, MOS pull-up transistor off
Output pins, Low
The intended purpose of this BCLR instruction is to switch P40 from output to input.
46
Before Execution of BCLR Instruction
P47
P46
P45
P44
P43
P42
P41
P40
Input/output
Input
Input
Output Output Output Output Output Output
Pin state
Low
High
Low
Low
Low
Low
Low
Low
DDR
0
0
1
1
1
1
1
1
DR
1
0
0
0
0
0
0
0
Pull-up Mos
On
Off
Off
Off
Off
Off
Off
Off
Execution of BCLR Instruction
BCLR.B
#0, @P4DDR ;clear bit 0 in data direction register
After Execution of BCLR Instruction
P47
P46
P45
P44
P43
P42
P41
P40
Input/output
Output
Output Output Output Output Output Output Input
Pin state
Low
High
Low
Low
Low
Low
Low
High
DDR
1
1
1
1
1
1
1
0
DR
1
0
0
0
0
0
0
0
Pull-up Mos
Off
Off
Off
Off
Off
Off
Off
Off
Explanation: To execute the BCLR instruction, the CPU begins by reading P4DDR. Since
P4DDR is a write-only register, it is read as H'FF, even though its true value is H'3F.
Next the CPU clears bit 0 of the read data, changing the value to H'FE.
Finally, the CPU writes this value (H'FE) back to P4DDR to complete the BCLR instruction.
As a result, P40DDR is cleared to "0," making P40 an input pin. In addition, P47DDR and
P46DDR are set to "1," making P47 and P46 output pins.
Example 2: BSET is executed to set bit 0 in the port 4 data register (P4DR) under the following
conditions.
P47:
Input pin, Low, MOS pull-up transistor on
P46:
Input pin, High, MOS pull-up transistor off
P45 – P40: Output pins, Low
The intended purpose of this BSET instruction is to switch the output level at P40 from Low to
High.
47
Before Execution of BSET Instruction
P47
P46
P45
P44
P43
P42
P41
P40
Input/output
Input
Input
Output Output Output Output Output Output
Pin state
Low
High
Low
Low
Low
Low
Low
Low
DDR
0
0
1
1
1
1
1
1
DR
1
0
0
0
0
0
0
0
Pull-up Mos
On
Off
Off
Off
Off
Off
Off
Off
P41
P40
Execution of BSET Instruction
BSET.B
#0, @PORT4 ;set bit 0 in data register
After Execution of BSET Instruction
P47
P46
P45
P44
P43
P42
Input/output
Input
Input
Output Output Output Output Output Output
Pin state
Low
High
Low
Low
Low
Low
Low
High
DDR
0
0
1
1
1
1
1
1
DR
0
1
0
0
0
0
0
1
Pull-up
Off
On
Off
Off
Off
Off
Off
Off
Explanation: To execute the BSET instruction, the CPU begins by reading port 4. Since P47
and P46 are input pins, the CPU reads the level of these pins directly, not the value in the data
register. It reads P47 as Low ("0") and P46 as High ("1").
Since P45 to P40 are output pins, for these pins the CPU reads the value in the data register ("0").
The CPU therefore reads the value of port 4 as H'40, although the actual value in P4DR is H'80.
Next the CPU sets bit 0 of the read data to "1," changing the value to H'41.
Finally, the CPU writes this value (H'41) back to P4DR to complete the BSET instruction.
As a result, bit P40 is set to "1," switching pin P40 to High output. In addition, bits P47 and P46
are both modified, changing the on/off settings of the MOS pull-up transistors of pins P4 7 and
P46.
Programming Solution: The switching of the pull-ups for P47 and P46 in example 2 can be
avoided by reserving a byte in RAM as a temporary register for P4DR and using it as follows.
RAM0 is a symbol for the user-selected address of the temporary register.
48
Before Execution of BSET Instruction
MOV.B
#80, R0L
MOV.B
R0L, @RAM0
MOV.B
R0L, @PORT4
;write data (H'80) for data register
;write to DR temporary register (RAM0)
;write to DR
P47
P46
P45
P44
P43
P42
P41
P40
Input/output
Input
Input
Output Output Output Output Output Output
Pin state
Low
High
Low
Low
Low
Low
Low
Low
DDR
0
0
1
1
1
1
1
1
DR
1
0
0
0
0
0
0
0
Pull-up Mos
On
Off
Off
Off
Off
Off
Off
Off
RAM0
1
0
0
0
0
0
0
0
Execution of BSET Instruction
BSET.B
#0, @RAM0
;set bit 0 in DR temporary register (RAM0)
After Execution of BSET Instruction
MOV.B
@RAM0, R0L
MOV.B
R0L,
;obtain value of temporary register RAM0
@PORT4
;write value to DR
P47
P46
P45
Input/output
Input
Input
Output Output Output Output Output Output
Pin state
Low
High
Low
Low
Low
Low
Low
Low
DDR
0
0
1
1
1
1
1
1
DR
1
0
0
0
0
0
0
1
Pull-up Mos
On
Off
Off
Off
Off
Off
Off
Off
RAM0
1
0
0
0
0
0
0
1
P44
P43
P42
P41
P40
49
15
8
7
0
Op
Op
rm
Op
rn
0
0
0
0
Operand: register indirect (@Rn)
#imm.
0
0
0
0
Bit No.: immediate (#xx:3)
Op
rn
0
0
0
0
Operand: register indirect (@Rn)
Op
rm
0
0
0
0
Bit No.: register direct (Rm)
0
0
0
0
0
0
Op
Op
0
Bit No.: immediate (#xx:3)
Operand: absolute (@aa:8)
abs.
rm
Op
0
Bit No.: register direct (Rm)
BAND, BOR, BXOR, BLD, BST
Operand: register direct (Rn)
Bit No.: immediate (#xx:3)
rn
#imm.
Op
rn
0
0
0
0
Operand: register indirect (@Rn)
Op
#imm.
0
0
0
0
Bit No.: immediate (#xx:3)
Op
Operand: absolute (@aa:8)
abs.
Op
#imm.
Op
0
0
0
0
Bit No.: immediate (#xx:3)
BIAND, BIOR, BIXOR, BILD, BIST
Operand: register direct (Rn)
Bit No.: immediate (#xx:3)
rn
#imm.
Op
rn
0
0
0
0
Operand: register indirect (@Rn)
Op
#imm.
0
0
0
0
Bit No.: immediate (#xx:3)
0
0
0
Op
Operand: absolute (@aa:8)
abs.
Op
:
Operand: absolute (@aa:8)
abs.
#imm.
Op
:
:
:
Operand: register direct (Rn)
Bit No.: register direct (Rm)
rn
Op
Op
Notation
Op
r m , rn
abs.
#imm.
rn
#imm.
BSET, BCLR, BNOT, BTST
Operand: register direct (Rn)
Bit No.: immediate (#xx:3)
#imm.
0
Bit No.: immediate (#xx:3)
Operation field
Register field
Absolute address
Immediate data
Figure 3-7. Bit Manipulation Instruction Codes
50
3.5.6 Branching Instructions
Table 3-7 describes the branching instructions. Figure 3-8 shows their object code formats.
Table 3-7. Branching Instructions
Instruction
Size
Function
Bcc
—
Branches if condition cc is true.
Mnemonic
cc Field
Description
Condition
BRA (BT)
0000
Always (True)
Always
BRN (BF)
0001
Never (False)
Never
BHI
0010
High
C∨Z=0
BLS
0011
Low or Same
C∨Z=1
BCC (BHS)
0100
Carry Clear
(High or Same)
C=0
BCS (BLO)
0101
Carry Set (Low)
C=1
BNE
0110
Not Equal
Z=0
BEQ
0111
Equal
Z=1
BVC
1000
Overflow Clear
V=0
BVS
1001
Overflow Set
V=1
BPL
1010
Plus
N=0
BMI
1011
Minus
N=1
BGE
1100
Greater or Equal N ⊕ V = 0
BLT
1101
Less Than
N⊕V=1
BGT
1110
Greater Than
Z ∨ (N ⊕ V) = 0
BLE
1111
Less or Equal
Z ∨ (N ⊕ V) = 1
JMP
—
Branches unconditionally to a specified address.
JSR
—
Branches to a subroutine at a specified address.
BSR
—
Branches to a subroutine at a specified displacement from the current
address.
RTS
—
Returns from a subroutine
51
15
8 7
Op
0
cc
disp.
rm
Op
0 0 0 0
Op
abs.
JMP (@aa:16)
abs.
JMP (@@aa:8)
Op
disp.
BSR
rm
0 0 0 0
Op
abs.
Op
JSR (@Rm)
JSR (@aa:16)
abs.
Op
Operation field
Condition field
Register field
Displacement
Absolute address
Figure 3-8. Branching Instruction Codes
52
JMP (@Rm)
Op
Op
Notation
Op
:
cc
:
rm
:
disp.
:
abs.
:
Bcc
JSR (@@aa:8)
RTS
3.5.7 System Control Instructions
Table 3-8 describes the system control instructions. Figure 3-9 shows their object code formats.
Table 3-8. System Control Instructions
Instruction Size
Function
RTE
—
Returns from an exception-handling routine.
SLEEP
—
Causes a transition to the power-down state.
LDC
B
Rs → CCR, #imm → CCR
Moves immediate data or general register contents to the condition code
register.
STC
B
CCR → Rd
Copies the condition code register to a specified general register.
ANDC
B
CCR ∧ #imm → CCR
Logically ANDs the condition code register with immediate data.
ORC
B
CCR ∨ #imm → CCR
Logically ORs the condition code register with immediate data.
XORC
B
CCR ⊕ #imm → CCR
Logically exclusive-ORs the condition code register with immediate data.
NOP
—
PC + 2 → PC
Only increments the program counter.
* Size: operand size
B: Byte
53
15
8
7
0
Op
RTE, SLEEP, NOP
rn
Op
Op
Notation
Op
:
rn
:
#imm. :
#imm.
LDC, STC (Rn)
ANDC, ORC,XORC, LDC
(#xx:8)
Operation field
Register field
Immediate data
Figure 3-9. System Control Instruction Codes
3.5.8 Block Data Transfer Instruction
Table 3-9 describes the EEPMOV instruction. Figure 3-10 shows its object code format.
Table 3-9. Block Data Transfer Instruction/EEPROM Write Operation
Instruction
Size
Function
EEPMOV
—
if R4L ≠ 0 then
repeat @R5+ → @R6+
R4L – 1 → R4L
until R4L = 0
else next;
Moves a data block according to parameters set in general
registers R4L, R5, and R6.
R4L:
size of block (bytes)
R5:
starting source address
R6:
starting destination address
Execution of the next instruction starts as soon as the block
transfer is completed.
54
15
8
7
0
Op
EEPROM
Op
Notation
Op: Operation field
Figure 3-10. Block Data Transfer Instruction/EEPROM Write Operation Code
Notes on EEPMOV Instruction
Note 1
• The EEPMOV instruction is a block data transfer instruction. It moves the number of bytes
specified by R4L from the address specified by R5 to the address specified by R6.
R5
R6
R5 + R4L
R6 + R4L
• When setting R4L and R6, make sure that the final destination address (R6 + R4L) does not
exceed H'FFFF. The value in R6 must not change from H'FFFF to H'0000 during execution
of the instruction.
R5
R6
R5 + R4L
H'FFFF
R6 + R4L
Not allowed
Note 2
CPU will malfunction after EEPMOV instruction execution, in the following conditions.
EPMOV instruction performs block data transfer function.
• Condition
When the following conditions are all true:
The LSI is set to expanded mode (i.e. mode 1 or mode 2).
The destination address of EEPMOV instruction is external area.
At least one wait state is inserted to the last write bus cycle to the destination address by
EEPMOV instruction.
55
• Phenomenon
H8/300 CPU will malfunction after EEPMOV instruction execution.
• Counter Measures by Software or Circuitry
Please take at least one counter measure from the followings.
Please use EEPMOV when the destination is in the internal area (e.g. internal RAM).
When the destination is the external area, please avoid wait state insertion to the bus
cycle.
When the case that wait state(s) is required, please substitute EEPMOV by MOV and
other instructions as follows:
Example
LOOP:MOV.B @R5+, R4H
MOV.B R4H, @R6
ADDS
#1,
INC
R4L
BNE
LOOP
R6
3.6 CPU States
The CPU has three states: the program execution state, exception-handling state, and powerdown state. The power-down state is further divided into three modes: the sleep mode, software
standby mode, and hardware standby mode. Figure 3-11 summarizes these states, and figure 312 shows a map of the state transitions.
State
Program execution state
The CPU executes successive program instructions.
Exception handling state
A transient state triggered by a reset or interrupt. The CPU executes a hardware
sequence that includes loading the program counter from the vector table.
Power down state
A state in which some or all of the chip
functions are stopped to conserve power.
Sleep mode
Software standby mode
Hardware standby mode
Figure 3-11. Operating States
56
SLEEP instruction
with SSBY bit set
Program
execution state
SLEEP
instruction
Interrupt
request
Exception
handling
Exceptionhandling state
RES=1
Interrupt request
NMI or IRQ 0
to IRQ 2 input
strobe interrupt
STBY=1 or RES=0
Reset state
Sleep mode
Software
standby mode
Hardware
standby mode
Power - down state
Notes:
1. A transition to the reset state occurs when RES goes Low, except when the chip is in the hardware standby mode.
2. A transition from any state to the hardware standby mode occurs when STBY goes Low.
Figure 3-12. State Transitions
3.6.1 Program Execution State
In this state the CPU executes program instructions in sequence. The main program,
subroutines, and interrupt-handling routines are all executed in this state.
3.6.2 Exception-Handling State
The exception-handling state is a transient state that occurs when the CPU is reset or accepts an
interrupt. In this state the CPU carries out a hardware-controlled sequence that prepares it to
execute a user-coded exception-handling routine.
In the hardware exception-handling sequence the CPU does the following:
(1) Saves the program counter and condition code register to the stack (except in the case of a
reset).
(2) Sets the interrupt mask (I) bit in the condition code register to “1.”
(3) Fetches the start address of the exception-handling routine from the vector table.
(4) Branches to that address, returning to the program execution state.
See section 4, “Exception Handling,” for further information on the exception-handling state.
57
3.6.3 Power-Down State
The power-down state includes three modes: the sleep mode, the software standby mode, and
the hardware standby mode.
(1) Sleep Mode: The sleep mode is entered when a SLEEP instruction is executed. The CPU
halts, but CPU register contents remain unchanged and the on-chip supporting modules
continue to function.
When an interrupt or reset signal is received, the CPU returns through the exception-handling
state to the program execution state.
(2) Software Standby Mode: The software standby mode is entered if the SLEEP instruction
is executed while the SSBY (Software Standby) bit in the system control register (SYSCR) is
set. The CPU and all on-chip supporting modules halt. The on-chip supporting modules are
initialized, but the contents of the on-chip RAM and CPU registers remain unchanged. I/O
port outputs also remain unchanged.
(3) Hardware Standby Mode: The hardware standby mode is entered when the input at the
67%< pin goes Low. All chip functions halt, including I/O port output. The on-chip
supporting modules are initialized, but on-chip RAM contents are held.
See section 12, “Power-Down State” for further information.
3.7 Access Timing and Bus Cycle
The CPU is driven by the system clock (φ). The period from one rising edge of the system clock
to the next is referred to as a “state.”
Memory access is performed in a two-or three-state bus cycle as described below. For more
detailed timing diagrams of the bus cycles, see section 15, “Electrical Specifications.”
3.7.1 Access to On-Chip Memory (RAM and ROM)
On-chip ROM and RAM are accessed in a cycle of two states designated T1 and T2. Either byte
or word data can be accessed, via a 16-bit data bus. Figure 3-13 shows the on-chip memory
access cycle. Figure 3-14 shows the associated pin states.
58
Bus cycle
T1 state
T2 state
Ø
Internal address bus
Address
Internal read signal
Internal data bus (read)
Read data
Internal write signal
Write data
Internal data bus (write)
Figure 3-13. On-Chip Memory Access Cycle
Bus cycle
T1 state
T2 state
∅
Address bus
Address
AS : High
RD : High
WR : High
Data bus : High impedance state
Figure 3-14. Pin States during On-Chip Memory Access Cycle
59
3.7.2 Access to On-Chip Register Field and External Devices
The on-chip register field (I/O ports, dual-port RAM, on-chip supporting module registers, etc.)
and external devices are accessed in a cycle consisting of three states: T1, T2, and T3. Only one
byte of data can be accessed per cycle, via an 8-bit data bus. Access to word data or instruction
codes requires two consecutive cycles (six states).
Wait States: If requested, additional wait states (TW) are inserted between T2 and T3. The
:$,7 pin is sampled at the center of state T2. If it is Low, a wait state is inserted after T2. The
:$,7 pin is also sampled at the center of each wait state and if it is still Low, another wait state
is inserted. An external device can have any number of wait states inserted by holding :$,7
Low for the necessary duration.
The bus cycle for the MOVTPE and MOVFPE instructions will be described in section 15,
"E-Clock Interface."
Figure 3-15 shows the access cycle for the on-chip register field. Figure 3-16 shows the
associated pin states. Figures 3-17 (a) and (b) show the read and write access timing for external
devices.
Bus cycle
T1 state
T2 state
T3 state
∅
Internal address bus
Address
Internal read signal
Internal data bus (read)
Read data
Internal write signal
Internal data bus (write)
Write data
Figure 3-15. On-Chip Register Field Access Cycle
60
Bus cycle
T1 state
T2 state
T3 state
∅
Address bus
Address
AS : High
RD : High
WR : High
Data bus :high impedance state
Figure 3-16. Pin States during On-Chip Register Field Access Cycle
Read cycle
T1 state
T2 state
T3 state
∅
Address bus
Address
AS : High
RD : High
WR : High
Data bus
Read data
Figure 3-17 (a). External Device Access Timing (read)
61
Write cycle
T1 state
T2 state
T3 state
∅
Address bus
Address
AS
RD : High
WR
Data bus
Write data
Figure 3-17 (b). External Device Access Timing (write)
62
Section 4. Exception Handling
4.1 Overview
The H8/325 Series recognizes only two kinds of exceptions: interrupts and the reset. Table 4-1
indicates their priority and the timing of their hardware exception-handling sequence. The
ROMless versions (HD6413258, HD6413238) are used only in mode 1 (expanded mode with onchip ROM disabled).
Table 4-1. Reset and Interrupt Exceptions
Priority
Type of
exception Timing of exception-handling sequence
High
Reset
↑
↑
↓
↓
Low
Interrupt
When 5(6 goes low, the chip enters the reset state immediately. The
hardware exception-handling sequence (reset sequence) begins as soon
as 5(6 goes high again.
When an interrupt is requested, the hardware exception-handling sequence
(interrupt sequence) begins at the end of the current instruction, or at the
end of the current hardware exception-handling sequence.
4.2 Reset
4.2.1 Overview
A reset has the highest exception-handling priority. When the 5(6 pin goes low, all current
processing stops and the chip enters the reset state. The internal state of the CPU and the
registers of the on-chip supporting modules are initialized. When 5(6 returns from low to high,
the chip comes out of the reset state via the reset exception-handling sequence.
4.2.2 Reset Sequence
The reset state begins when 5(6 goes low. To ensure correct resetting, at power-on the 5(6 pin
should be held low for at least 20ms. In a reset during operation, the 5(6 pin should be held low
for at least 10 system clock (φ) cycles.
When 5(6 returns from low to high, hardware carries out the following reset exception-handling
sequence.
63
(1) The value at the mode pins (MD1 and MD0) is latched in bits MDS1 and MDS0 of the mode
control register (MDCR).
(2) In the condition code register (CCR), the I bit is set to 1 to mask interrupts.
(3) The registers of the I/O ports and on-chip supporting modules are initialized.
(4) The CPU loads the program counter with the first word in the vector table (stored at
addresses H’0000 and H’0001) and starts program execution.
The 5(6 pin should be held low when power is switched off, as well as when power is switched
on.
Figure 4-1 indicates the timing of the reset sequence when the vector table and reset routine are
located in on-chip ROM. Figure 4-2 indicates the timing when they are in off-chip memory.
Vector
fetch
Internal
processing
Instruction
prefetch
RES
Ø
Internal address
bus
(1)
(2)
Internal Read
signal
Internal Write
signal
Internal data bus
(16 bits)
(2)
(3)
(1) Reset vector address (H'0000)
(2) Starting address of reset routine (contents of H'0000 - H'0001)
(3) First instruction of reset routine
Figure 4-1. Reset Sequence (Mode 2 or 3, Reset Routine in On-Chip ROM)
64
Internal
processing
Vector fetch
Instruction prefetch
RES
∅
A 15 to A 0
(1)
(3)
(5)
(7)
RD
WR
D 7 to D 0
(8 bits)
(2)
(4)
(6)
(8)
(1), (3) Reset vector address : (1) = H'0000, (3) = H'0001
(2), (4) Starting address of reset routine (contents of reset vector): (2) = upper byte, (4) = lower byte
(5), (7) Starting address of reset routine : (5) = (2) (4), (7) = (2) (4) + 1
(6), (8) First instruction of reset routine : (6) = first byte, (8) = second byte
Figure 4-2. Reset Sequence (Mode 1)
65
4.2.3 Disabling of Interrupts after Reset
All interrupts, including NMI, are disabled immediately after a reset. The first program
instruction, located at the address specified at the top of the vector table, is therefore always
executed. To prevent program crashes, this instruction should initialize the stack pointer
(example: MOV.W #xx:16, SP). After execution of this instruction, the NMI interrupt is
enabled. Other interrupts remain disabled until their enable bits are set to 1.
4.3 Interrupts
4.3.1 Overview
There are four input pins for external interrupts (NMI, IRQ0 to IRQ2). There are also 17 internal
interrupts originating on-chip. The features of these interrupts are:
• All internal and external interrupts except NMI can be masked by the I bit in the CCR.
• IRQ0 to IRQ2 can be rising-edge-sensed, falling-edge-sensed, or level-sensed. The type of
sensing can be selected for each interrupt individually. NMI is edge-sensed, and either the
rising or falling edge can be selected.
• Interrupts are individually vectored. The software interrupt-handling routine does not have to
determine what type of interrupt has occurred.
Table 4-2 lists all the interrupts in their order of priority and gives their vector numbers and the
addresses of their entries in the vector table.
66
Table 4-2. Interrupts
Interrupt source
No.
Address of entry in
vector table
NMI
IRQ0
IRQ1
IRQ2
3
4
5
6
H'0006–H'0007
H'0008–H'0009
H'000A–H'000B
H'000C–H'000D
Port
ISI (Input strobe)
7
H'000E–H'000F
16-Bit freerunning timer
ICI (Input capture)
OCIA (Output compare A)
OCIB (Output compare B)
FOVI (Overflow)
8
9
10
11
H'0010–H'0011
H'0012–H'0013
H'0014–H'0015
H'0016–H'0017
8-Bit timer 0
CMI0A (Compare-match A)
CMI0B (Compare-match B)
OVI0 (Overflow)
12
13
14
H'0018–H'0019
H'001A–H'001B
H'001C–H'001D
8-Bit timer 1
CMI1A (Compare-match A)
CMI1B (Compare-match B)
OVI1 (Overflow)
15
16
17
H'001E–H'001F
H'0020–H'0021
H'0022–H'0023
Serial
communication
interface 0
ERI0 (Receive error)
RXI0 (Receive end)
TXI0 (Transmit end)
18
19
20
H'0024–H'0025
H'0026–H'0027
H'0028–H'0029
Serial
communication
interface 1
ERI1 (Receive error)
RXI1 (Receive end)
TXI1 (Transmit end)
21
22
23
H'002A–H'002B
H'002C–H'002D
H'002E–H'002F
Priority
High
↑
↓
Low
Notes:
1. H'0000 and H'0001 contain the reset vector.
2. H'0002 to H'0005 are reserved in the H8/325 Series and are not available to the user.
4.3.2 Interrupt-Related Registers
The interrupt controller refers to three registers in addition to the CCR. The names and attributes
of these registers are listed in table 4-3.
67
Table 4-3. Registers Read by Interrupt Controller
Name
Abbreviation
Read/Write
Address
System control register
SYSCR
R/W
H’FFC4
IRQ sense control register
ISCR
R/W
H’FFC6
IRQ enable register
IER
R/W
H’FFC7
(1) System Control Register (SYSCR)—H’FFC4
Bit
7
6
5
4
3
2
1
0
SSBY
STS2
STS1
STS0
—
NMIEG
—
RAME
Initial value
0
0
0
0
1
0
1
1
Read/Write
R/W
R/W
R/W
R/W
—
R/W
—
R/W
Bit 2 (NMIEG) is the only bit read by the interrupt controller.
Bit 2—Nonmaskable Interrupt Edge (NMIEG): Determines whether a nonmaskable
interrupt is generated on the falling or rising edge of the 10, input signal.
Bit 2
NMIEG
Description
0
An interrupt is generated on the falling edge of 10,.
1
An interrupt is generated on the rising edge of 10,.
(Initial state)
See section 10, RAM and section 12, Power-Down State for information on the other SYSCR
bits.
(2) IRQ Sense Control Register (ISCR)—H’FFC6
Bit
7
6
5
4
3
2
1
0
—
IRQ2EG
IRQ1EG
IRQ0EG
—
IRQ2SC
IRQ1SC
IRQ0SC
Initial value
1
0
0
0
1
0
0
0
Read/Write
—
R/W
R/W
R/W
—
R/W
R/W
R/W
Bits 6 and 2—IRQ2 Sense Control (IRQ2SC and IRQ2EG): These bits select how the input
at the ,54 pin is sensed.
68
Bit 2
IRQ2SC
Bit 6
IRQ2EG
Description
0
0
The low level of ,54 generates an interrupt request.
0
1
1
0
The falling edge of ,54 generates an interrupt request.
1
1
The rising edge of ,54 generates an interrupt request.
(Initial state)
Bits 5 and 1—IRQ1 Sense Control (IRQ1SC and IRQ1EG): These bits select how the input
at the ,54 pin is sensed.
Bit 1
IRQ1SC
Bit 5
IRQ1EG
Description
0
0
The low level of ,54 generates an interrupt request.
0
1
1
0
The falling edge of ,54 generates an interrupt request.
1
1
The rising edge of ,54 generates an interrupt request.
(Initial state)
Bits 4 and 0—IRQ0 Sense Control (IRQ0SC and IRQ0EG): These bits select how the input
at the ,54 pin is sensed.
Bit 0
Bit 4
IRQ0SC
IRQ0EG
Description
0
0
The low level of ,54 generates an interrupt request.
0
1
1
0
The falling edge of ,54 generates an interrupt request.
1
1
The rising edge of ,54 generates an interrupt request.
(Initial state)
(3) IRQ Enable Register (IER)—H’FFC7
Bit
7
6
5
4
3
2
1
0
—
—
—
—
—
IRQ2E
IRQ1E
IRQ0E
Initial value
1
1
1
1
1
0
0
0
Read/Write
—
—
—
—
—
R/W
R/W
R/W
Bits 0 to 2—IRQ0 to IRQ2 Enable (IRQ0E to IRQ2E): These bits enable or disable the
IRQ0, IRQ1, and IRQ2 interrupts individually.
69
Bit i (i = 0 to 2)
IRQiE
Description
0
IRQi is disabled.
1
IRQi is enabled.
(Initial state)
Edge-sensed interrupt signals are latched (if enabled) and held until the interrupt is served.
They are latched even if the interrupt mask bit (I) is set in the CCR, and even if bits IRQ0E to
IRQ2E are cleared to 0. Level-sensed interrupts are not latched.
4.3.3 External Interrupts
The external interrupts are NMI and IRQ0 to IRQ2.
While the CPU is waiting for one of these interrupts, it is possible to conserve power by entering
software standby mode. When the interrupt arrives, the chip will recover automatically to the
program execution state, handle the interrupt, then continue executing the main program. See
section 12, Power-Down State for further information on software standby mode.
(1) NMI: A nonmaskable interrupt is generated on the rising or falling edge of the 10, input
signal regardless of whether the I (interrupt mask) bit is set in the CCR. The valid edge is
selected by the NMIEG bit in the system control register.
An NMI has highest priority and is always accepted as soon as the current instruction ends,
unless the current instruction is an ANDC, ORC, XORC, or LDC instruction. When an NMI
interrupt is accepted the interrupt mask (I bit) is set, so the NMI handling routine cannot be
interrupted except by another NMI.
The NMI vector number is 3. Its entry is located at address H’0006 in the vector table.
(2) IRQ0 to IRQ2: These interrupt signals are level-sensed or sensed on the rising or falling edge
of the input, as selected by the ISCR bits. These interrupts can be masked collectively by the
I bit in the CCR, and can be enabled and disabled individually by setting and clearing the
bits in the IRQ enable register. When one of these interrupts is accepted, the I bit is set to 1
to mask further interrupts (except 10,).
These interrupts are second in priority to NMI. Among them, IRQ0 has the highest priority
and IRQ2 the lowest priority. Interrupts IRQ0 to IRQ2 do not depend on whether pins ,54 to
,54 are input or output pins. When using external interrupts IRQ0 to IRQ2, clear the
corresponding DDR bits to 0 to set these pins to the input state.
70
4.3.4 Internal Interrupts
Seventeen internal interrupts can be requested by the on-chip supporting modules. All of them
are masked when the I bit in the CCR is set. In addition, they can all be enabled or disabled by
bits in the control registers of the on-chip supporting modules. When one of these interrupts is
accepted, the I bit is set to 1 to mask further interrupts (except 10,).
Power can be conserved by waiting for an internal interrupt in sleep mode, in which the CPU
halts but the on-chip supporting modules continue to run. When the interrupt arrives, the CPU
returns to the program-execution state, services the interrupt, then resumes execution of the main
program. See section 12, Power-Down State for further information on the sleep mode.
The input strobe interrupt (ISI) can also be waited for in software standby mode. The chip
recovers from software standby mode when an input strobe interrupt is requested.
The internal interrupt signals received by the interrupt controller are generated from flag bits in
the registers of the on-chip supporting modules. The interrupt controller does not reset these flag
bits when accepting the interrupt.
For the vector numbers and priority order of these interrupts, see table 4-2.
Note: When disabling internal interrupts, note the following points.
1. Set the interrupt mask (I) to 1 before disabling an internal interrupt or clearing its interrupt
flag.
2. If an instruction that disables or clears an internal interrupt is executed while the interrupt
mask (I) is cleared to 0, and the interrupt is requested during execution of the
instruction, the CPU resolves this conflict as follows:
[1] If one or more other interrupts are also requested, the other interrupt with the highest
priority is served.
[2] If no other interrupt is requested, the CPU branches to the reset address.
Example: A sample program for disabling the output compare A interrupt is shown below. The
OCIAE bit in the TCR should be cleared only when I = 1, as in this example.
ORC #80, CCR ; Set I bit
BCLR #5, @TCR ; Disable output compare A interrupt
ANDC #7F, CCR ; Clear I bit
71
Note: Interrupt requests are not detected immediately after the ANDC, ORC, XORC, and LDC
instructions.
4.3.5 Interrupt Handling
Figure 4-3 shows a block diagram of the interrupt controller. Figure 4-4 is a flowchart showing
the operation of the interrupt controller and the sequence by which an interrupt is accepted. This
sequence is outlined below.
(1) The interrupt controller receives an interrupt request signal. Interrupt request signals can be
generated by 10, input, or by other interrupt sources if enabled.
(2) When notified of an interrupt, the interrupt controller scans the interrupt signals in priority
order and selects the one with the highest priority. (See table 4-2 for the priority order.)
Other requested interrupts remain pending.
(3) The interrupt controller accepts the interrupt if it is an NMI, or if it is another interrupt and
the I bit in the CCR is cleared to 0. If the interrupt is not an NMI and the I bit is set to 1, the
interrupt is held pending.
(4) When an interrupt is accepted, after completion of the current instruction, first the PC then
the CCR is pushed onto the stack. See figure 4-5. The stacked PC indicates the address of
first instruction executed after return from the interrupt-handling routine.
(5) The interrupt controller sets the I bit in the CCR to 1, masking all further interrupts except
NMI during the interrupt-handling routine.
(6) The interrupt controller generates the vector address of the interrupt and loads the word at
this address into the program counter.
72
The timing of this sequence is shown in figure 4-6 for the case in which the program and vector
table are in on-chip ROM and the stack is in on-chip RAM.
Interrupt
controller
NMI interrupt
IRQ0 flag
IRQ0E
CPU
Interrupt request
IRQ0
interrupt
Priority
decision
Vector number
ADF
ADIE
ADI
interrupt
I (CCR)
Figure 4-3. Block Diagram of Interrupt Controller
73
Program execution
Interrupt
request
present ?
N
Y
NMI?
Y
N
IRQ 0 ?
Y
N
IRQ 1 ?
Y
N
TXI 1 ?
Y
I = 0 in
CCR?
Y
Save PC
Save CCR
N
Pending
PC: Program Counter
CCR: Condition Code Register
I: Interrupt mask bit
I 1, masking all
interrupts except NMI
To software
interrupt-handling routine
Figure 4-4. Hardware Interrupt-Handling Sequence
74
SP-4
SP(R7)
CCR
SP-3
SP+1
CCR*
SP-2
SP+2
PC (upper byte)
SP-1
SP+3
PC (lower byte)
SP(R7)
SP+4
Even address
Stack area
Before interrupt
is accepted
Pushed onto stack
After interrupt
is accepted
PC :
Program counter
CCR : Condition code register
SP :
Stack pointer
* : Ignored on return.
Notes : 1. The PC contains the address of the first instruction
executed after return.
2. Registers must be saved and restored by word
access at an even address.
Figure 4-5. Usage of Stack in Interrupt Handling
75
Interrupt
accepted
Interrupt priority
decision. Wait for
end of instruction
Instruction
fetch
Internal
processing
Vector
Table
fetch
Stack
Internal
processing
Instruction fetch
( first instruction of
interrupt-handling
routine)
Interrupt request
signal
∅
Internal address
bus
(1)
(3)
(6)
(5)
(8)
(9)
Internal read
signal
Internal write
signal
Internal 16 - bit
data bus
(1)
(2) (4)
(3)
(5)
(6)
(7)
(8)
(9)
(10)
(2)
(4)
(1)
(7)
(9)
Instruction prefetch address (Pushed on stack. Instruction is executed on return from
Interrupt-handling routine.)
Instruction code (Not executed)
Instruction prefetch address (Not executed)
SP - 2
SP - 4
CCR
Address of vector table entry
Vector table entry ( address of first instruction interrupt - handling routine)
First instruction of interrupt - handling routine
Figure 4-6. Timing of Interrupt Sequence
76
(10)
4.3.6 Interrupt Response Time
Table 4-4 indicates the time that elapses from an interrupt request signal until the first
instruction of the software interrupt-handling routine is executed. Since the H8/325 Series
accesses its on-chip memory 16 bits at a time, very fast interrupt service can be obtained by
placing interrupt-handling routines in on-chip ROM and the stack in on-chip RAM.
Table 4-4. Number of States before Interrupt Service
Number of states
No. Reason for wait
On-chip memory
3
External memory
2*
3
1
Interrupt priority decision
2*
2
Wait for completion of
current instruction*1
1 to 13
5 to 17*
3
Save PC and CCR
4
12*
4
Fetch vector
2
6*
5
Fetch instruction
4
12*
6
Internal processing
4
4
Total
17 to 29
41 to 53*
2
2
2
2
2
Notes: 1. These values do not apply if the current instruction is an EEPMOV, MOVFPE, or
MOVTPE instruction.
2. If wait states are inserted in external memory access, these values may be longer.
3. 1 for internal interrupts.
4.4 Note on Stack Handling
In word access, the least significant bit of the address is always assumed to be 0. The stack is
always accessed by word access. Care should be taken to keep an even value in the stack pointer
(general register R7). Use the PUSH and POP (or MOV.W Rn, @–SP and MOV.W @SP+, Rn)
instructions to push and pop registers on the stack.
Setting the stack pointer to an odd value can cause programs to crash. Figure 4-7 shows an
example of damage caused when the stack pointer contains an odd address.
77
PC H
SP
SP
PC L
R1 L
H'FEFC
PC L
H'FEFD
H'FEFF
SP
BSR instruction
H'FEFF set in SP
PC
PC
R1
SP
H
L
L
MOV. B R1L,@-R7
PC is improperly stored
beyond top of stack
PC is lost
H
: Upper byte of program counter
: Lower byte of program counter
: General register
: Stack pointer
Figure 4-7. Example of Damage Caused by Setting an Odd Address in R7
Although the CCR consists of only one byte, it is treated as word data when pushed on the stack.
In the hardware interrupt exception-handling sequence, two identical CCR bytes are pushed onto
the stack to make a complete word. When popped from the stack by an RTE instruction, the
CCR is loaded from the byte stored at the even address. The byte stored at the odd address is
ignored.
78
Section 5. I/O Ports
5.1 Overview
The H8/325 Series has seven parallel I/O ports, including:
• Five 8-bit input/output ports—ports 1, 2, 3, 4, and 7
• One 7-bit input/output port—port 6
• One 6-bit input/output port—port 5
All ports have programmable MOS input pull-ups. Ports 1 and 2 can drive LEDs.
Input and output are memory-mapped. The CPU views each port as a data register (DR) located
in the register field at the high end of the address space. Each port also has a data direction
register (DDR) which determines which pins are used for input and which for output.
Output: To send data to an output port, the CPU selects output in the data direction register and
writes the desired data in the data register, causing the data to be held in a latch. The latch
output drives the pin through a buffer amplifier. If the CPU reads the data register of an output
port, it obtains the data held in the latch rather than the actual level of the pin.
Input: To read data from an I/O port, the CPU selects input in the data direction register and
reads the data register. This causes the input logic level at the pin to be placed directly on the
internal data bus. There is no intervening input latch, except for port 3 when parallel
handshaking is used.
MOS Pull-Up: The MOS pull-ups for input pins are controlled as follows. To turn on the pullup transistor for a pin, software must first clear its data direction bit to 0 to make the pin an input
pin, then write a 1 in the data bit for that pin. The pull-up can be turned off by writing a 0 in the
data bit, or a 1 in the data direction bit. The pull-ups are also turned off by a reset and by entry
to the hardware standby mode.
The data direction registers are write-only registers; their contents are invisible to the CPU. If
the CPU reads a data direction register all bits are read as 1, regardless of their true values. Care
is required if bit manipulation instructions are used to set and clear the data direction bits. See
the note on bit manipulation instructions in section 3.5.5, Bit Manipulations.
Auxiliary Functions: In addition to their general-purpose input/output functions, all of the I/O
ports have auxiliary functions. Most of the auxiliary functions are software-selectable and must
be enabled by setting bits in control registers. When selected, an auxiliary function usually
replaces the general-purpose input/output function, but in some cases both functions operate
simultaneously. Table 5-1 summarizes the auxiliary functions of the ports.
79
Table 5-1. Auxiliary Functions of Input/Output Ports
I/O Port
Auxiliary functions
Port 1
Address bus (low)
(Note 1)
Port 2
Address bus (high)
(Note 1)
Port 3
Data bus or parallel handshaking data lines
(Note 2)
Port 4
System clock and E clock output, 8-bit timer input and output
Port 5
Serial communication interface
Port 6
Free-running timer input and output, IRQ2 to IRQ0
Port 7
Bus control and parallel handshaking control
Notes:
*1 Selected automatically in mode 1; software-selectable in mode 2
*2 Data bus function is selected automatically in modes 1 and 2
5.2 Port 1
Port 1 is an 8-bit input/output port that also provides the low bits of the address bus. The
function of port 1 depends on the MCU mode as indicated in table 5-2.
Table 5-2. Functions of Port 1
Mode 1
Mode 2
Mode 3
Address bus (low)
(A7 to A0)
Input port or Address bus (low)
(A7 to A0)*
Input/output port
* Depending on the bit settings in the data direction register: 0—input pin; 1—address pin
Pins of port 1 can drive a single TTL load and a 90-pF capacitive load when they are used as
output pins. They can also drive light-emitting diodes or a Darlington pair.
80
Table 5-3 details the port 1 registers.
Table 5-3. Port 1 Registers
Name
Abbreviation Read/Write Initial value
Port 1 data direction register P1DDR
W
Port 1 data register
R/W
P1DR
Address
H’FF (mode 1)
H’FFB0
H’00 (modes 2 and 3)
H’00
H’FFB2
Port 1 Data Direction Register (P1DDR)—H’FFB0
Bit
7
6
5
4
3
2
1
0
P17DDR
P16DDR
P15DDR
P14DDR
P13DDR
P12DDR
P11DDR
P10DDR
Initial value
1
1
1
1
1
1
1
1
Read/Write
—
—
—
—
—
—
—
—
Initial value
0
0
0
0
0
0
0
0
Read/Write
W
W
W
W
W
W
W
W
Mode 1
Modes 2 and 3
P1DDR is an 8-bit register that selects the direction of each pin in port 1. A pin functions as an
output pin if the corresponding bit in P1DDR is set to 1, and as an input pin if the bit is cleared
to 0.
Port 1 Data Register (P1DR)—H’FFB2
Bit
7
6
5
4
3
2
1
0
P17
P16
P15
P14
P13
P12
P11
P10
Initial value
0
0
0
0
0
0
0
0
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
P1DR is an 8-bit register containing output data for pins P17 to P10, and controlling their input
pull-ups.
MOS Pull-Ups: Are available for input pins in modes 2 and 3. Software can turn on the MOS
pull-up by writing a 1 in P1DR, and turn it off by writing a 0. The pull-ups are automatically
turned off for output pins in modes 2 and 3, and for all pins in mode 1.
Mode 1: In mode 1 (expanded mode without on-chip ROM), port 1 is automatically used for
address output. The port 1 data direction register is unwritable. All bits in P1DDR are
automatically set to 1 and cannot be cleared to 0.
81
Mode 2: In mode 2 (expanded mode with on-chip ROM), the usage of port 1 can be selected on
a pin-by-pin basis. A pin is used for general-purpose input if its data direction bit is cleared to 0,
or for address output if its data direction bit is set to 1.
Mode 3: In the single-chip mode port 1 is a general-purpose input/output port.
Reset: A reset clears P1DDR and P1DR to all 0, placing all pins in the input state with the MOS
pull-ups off. In mode 1, when the chip comes out of reset P1DDR is set to all 1, making all pins
address output pins.
Hardware Standby Mode: All pins are placed in the high-impedance state with the MOS pullups off.
Software Standby Mode: P1DDR and P1DR remain in their previous state. Address output pins
are low. General-purpose output pins continue to output the data in P1DR. The MOS pull-ups of
input pins are on or off depending on the values in P1DR.
Figure 5-1 shows a schematic diagram of port 1.
82
Mode 1
Q
Reset
S
R
D
P1nDDR
C
Mode 3
Reset
R
Q
P1n
D
P1nDR
C
Mode 1 or 2
Internal data bus
WP1D
Internal lower address bus
Hardware standby
WP1
RP1
WP1D: Write Port 1 DDR
WP1: Write Port 1
RP1: Read Port 1
n = 0 to 7
* Set-priority
Figure 5-1. Port 1 Schematic Diagram
5.3 Port 2
Port 2 is an 8-bit input/output port that also provides the high bits of the address bus. The
function of port 2 depends on the MCU mode as indicated in table 5-4.
Table 5-4. Functions of Port 2
Mode 1
Mode 2
Mode 3
Address bus (high)
(A15 to A8)
Input port or Address bus (high) Input/output port
(A15 to A8)*
* Depending on the bit settings in the data direction register: 0—input pin; 1—address pin
83
Pins of port 2 can drive a single TTL load and a 90-pF capacitive load when they are used as
output pins. They can also drive light-emitting diodes or a Darlington pair.
Table 5-5 details the port 2 registers.
Table 5-5. Port 2 Registers
Name
Abbreviation Read/Write Initial value
Address
Port 2 data direction register P2DDR
W
H’FF (mode 1)
H’FFB1
H’00 (modes 2 and 3)
Port 2 data register
R/W
H’00
P2DR
H’FFB3
Port 2 Data Direction Register (P2DDR)—H’FFB1
Bit
7
6
5
4
3
2
1
0
P27DDR
P26DDR
P25DDR
P24DDR
P23DDR
P22DDR
P21DDR
P20DDR
Initial value
1
1
1
1
1
1
1
1
Read/Write
—
—
—
—
—
—
—
—
Initial value
0
0
0
0
0
0
0
0
Read/Write
W
W
W
W
W
W
W
W
Mode 1
Modes 2 and 3
P2DDR is an 8-bit register that selects the direction of each pin in port 2. A pin functions as an
output pin if the corresponding bit in P2DDR is set to 1, and as an input pin if the bit is cleared
to 0.
Port 2 Data Register (P2DR)—H’FFB3
Bit
7
6
5
4
3
2
1
0
P27
P26
P25
P24
P23
P22
P21
P20
Initial value
0
0
0
0
0
0
0
0
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
P2DR is an 8-bit register containing output data for pins P27 to P20, and controlling their input
pull-ups.
MOS Pull-Ups: Are available for input pins in modes 2 and 3. Software can turn on the MOS
pull-up by writing a 1 in P2DR, and turn it off by writing a 0. The pull-ups are automatically
turned off for output pins in modes 2 and 3, and for all pins in mode 1.
84
Mode 1: In mode 1 (expanded mode without on-chip ROM), port 2 is automatically used for
address output. The port 2 data direction register is unwritable. All bits in P2DDR are
automatically set to 1 and cannot be cleared to 0.
Mode 2: In mode 2 (expanded mode with on-chip ROM), the usage of port 2 can be selected on
a pin-by-pin basis. A pin is used for general-purpose input if its data direction bit is cleared to 0,
or for address output if its data direction bit is set to 1.
Mode 3: In single-chip mode port 2 is a general-purpose input/output port.
Reset: A reset clears P2DDR and P2DR to all 0, placing all pins in the input state with the MOS
pull-ups off. In mode 1, when the chip comes out of reset P2DDR is set to all 1, making all pins
address output pins.
Hardware Standby Mode: All pins are placed in the high-impedance state with the MOS pullups off.
Software Standby Mode: P2DDR and P2DR remain in their previous state. Address output pins
are low. General-purpose output pins continue to output the data in P2DR. The MOS pull-ups of
input pins are on or off depending on the values in P2DR.
Figure 5-2 shows a schematic diagram of port 2.
85
Hardware standby
Mode 1
Q
Reset
S
R
D
P2nDDR
Reset
R
Q
P2 n
P2nDR
C
Mode 1 or 2
D
Internal data bus
Mode 3
Internal address bus
C
WP2D
WP2
RP2
WP2D: Write Port 2 DDR
WP2: Write Port 2
RP2: Read Port 2
n = 0 to 7
* Set-priority
Figure 5-2. Port 2 Schematic Diagram
5.4 Port 3
Port 3 is an 8-bit input/output port that also provides the external data bus and data pins for the
parallel handshaking interface. The function of port 3 depends on the MCU mode as indicated in
table 5-6. For further information on parallel handshaking, see section 6, Parallel Handshaking
Interface.
Table 5-6. Functions of Port 3
Mode 1
Mode 2
Mode 3
Data bus
Data bus
General-purpose input/output port or parallel handshaking port
Pins of port 3 can drive a single TTL load and a 90-pF capacitive load when they are used as
output pins. They can also drive a Darlington pair.
86
Table 5-7 details the port 3 registers.
Table 5-7. Port 3 Registers
Name
Abbreviation
Read/Write
Initial value
Address
Port 3 data direction register P3DDR
W
H’FF
H’FFB4
Port 3 data register
R/W
H’00
H’FFB6
P3DR
Port 3 Data Direction Register (P3DDR)—H’FFB4
Bit
7
6
5
4
3
2
1
0
P37DDR
P36DDR
P35DDR
P34DDR
P33DDR
P32DDR
P31DDR
P30DDR
Initial value
0
0
0
0
0
0
0
0
Read/Write
W
W
W
W
W
W
W
W
P3DDR is an 8-bit register that selects the direction of each pin in port 3. A pin functions as an
output pin if the corresponding bit in P3DDR is set to 1, and as an input pin if the bit is cleared
to 0.
Port 3 Data Register (P3DR)—H’FFB6
Bit
7
6
5
4
3
2
1
0
P37
P36
P35
P34
P33
P32
P31
P30
Initial value
0
0
0
0
0
0
0
0
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
P3DR is an 8-bit register containing output data for pins P37 to P30 in mode 3, and controlling
their input pull-ups.
MOS Pull-Ups: Are available for input pins in mode 3. Software can turn on the MOS pull-up
by writing a 1 in P3DR, and turn it off by writing a 0. The pull-ups are automatically turned off
for output pins in mode 3, and for all pins in modes 1 and 2.
Modes 1 and 2: In the expanded modes, port 3 is automatically used as the data bus. The values
in P3DDR and P3DR are ignored.
Mode 3: In the single-chip mode, port 3 can be used as a general-purpose input/output port, or a
parallel-handshaking input or output port.
87
Input Latches: All pins of port 3 have input latches which can be enabled by the LTE bit in the
handshake control/status register (HCSR) in mode 3. When the LTE bit is set to 1, input data are
latched on the falling edge of the input strobe (,6) signal and held in the input strobe latch until
read. When the LTE bit is cleared to 0, input data are passed through the input strobe latch
without being held.
See section 6, Parallel Handshaking Interface for further information.
Reset and Hardware Standby Mode: P3DDR and P3DR are cleared to all 0, and all parallel
handshaking functions are disabled. All pins are placed in the input (high-impedance) state with
the MOS pull-ups off.
Software Standby Mode: P3DDR and P3DR remain in their previous state. In modes 1 and 2,
all pins are placed in the input (high-impedance) state. In mode 3, all pins remain in their
previous input or output state.
Figure 5-3 shows a schematic diagram of port 3.
88
Mode 3
Mode 3
Reset
R
Q
External
address
write
D
P3nDDR
C
Mode 3
Reset
P3nDR
C
Mode 1 or 2
D
D
WP3
RP3
External
address read
Reset
WP3D: Write Port 3 DDR
WP3: Write Port 3
RP3: Read Port 3
n = 0 to 7
R
Q
P3 n
Internal data bus
WP3D
R
Q
Input latch
C
Control logic
IS input
Figure 5-3. Port 3 Schematic Diagram
5.5 Port 4
Port 4 is an 8-bit input/output port that also provides input and output pins for the 8-bit timers
and output pins for the system clock and E clock. The pin functions depend on the MCU mode
and output select bits in the timer control/status registers. Table 5-8 lists the pin functions.
89
Table 5-8. Port 4 Pin Functions
Usage
Pin Functions
I/O port
P40
P41
P42
P43
P44
P45
P46
P47
Timer or clock
TMCI0
TMO0
TMRI0
TMCI1
TMO1
TMRI1
φ clock
E clock
See section 8, 8-Bit Timer Module for details of the timer output select bits.
Pins of port 4 can drive a single TTL load and a 90-pF capacitive load when they are used as
output pins. They can also drive a Darlington pair.
Table 5-9 details the port 4 registers.
Table 5-9. Port 4 Registers
Name
Abbreviation Read/Write Initial value
Address
Port 4 data direction register P4DDR
W
H’80 (modes 1 and 2) H’FFB5
H'00 (mode 3)
Port 4 data register
R/W
H’00
P4DR
H’FFB7
Port 4 Data Direction Register (P4DDR)—H’FFB5
Bit
7
6
5
4
3
2
1
0
P47DDR
P46DDR
P45DDR
P44DDR
P43DDR
P42DDR
P41DDR
P40DDR
Initial value
1
0
0
0
0
0
0
0
Read/Write
W
W
W
W
W
W
W
W
Initial value
0
0
0
0
0
0
0
0
Read/Write
W
W
W
W
W
W
W
W
Modes 1 and 2
Mode 3
P4DDR is an 8-bit register that selects the direction of each pin in port 4. A pin functions as an
output pin if the corresponding bit in P4DDR is set to 1, and as an input pin if the bit is cleared
to 0.
90
Port 4 Data Register (P4DR)—H’FFB7
Bit
7
6
5
4
3
2
1
0
P47
P46
P45
P44
P43
P42
P41
P40
Initial value
0
0
0
0
0
0
0
0
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
P4DR is an 8-bit register containing output data for pins P47 to P40, and controlling their input
pull-ups. When the CPU reads P4DR, for output pins (P4DDR = 1) it reads the value in the
P4DR latch, but for input pins (P4DDR = 0), it obtains the logic level directly from the pin,
bypassing the P4DR latch. This also applies to pins used for timer or clock input or output.
MOS Pull-Ups: Are available for input pins, including timer input pins, in all modes. Software
can turn the MOS pull-up on by writing a 1 in P4DR, and turn it off by writing a 0. The pull-ups
are automatically turned off for output pins.
Pins P40, P42, P43, and P45: As indicated in table 5-8, these pins can be used for general-purpose
input or output, or input of 8-bit timer clock and reset signals. When a pin is used for timer
signal input, its P4DDR bit should normally be cleared to 0; otherwise the timer will receive the
value in P4DR. If input pull-up is not desired, the P4DR bit should also be cleared to 0.
Pins P41 and P44: As indicated in table 5-8, these pins can be used for general-purpose input or
output, or for 8-bit timer output. Pins used for timer output are unaffected by the values in
P4DDR and P4DR, and their MOS pull-ups are automatically turned off.
Pin P46: In modes 1 and 2 (expanded modes) this pin is used for system clock (φ) output,
regardless of the value in P46DDR. The MOS pull-up is automatically turned off.
In mode 3 (single-chip mode) this pin is used for general-purpose input if P46DDR is cleared to
0, or system clock output if P46DDR is set to 1. It cannot be used for general-purpose output.
Pin P47: In modes 1 and 2 (expanded modes) pin P47 is used for E clock output if P47DDR is set
to 1, and for general-purpose input if P47DDR is cleared to 0. It cannot be used for generalpurpose output.
In mode 3 (single-chip mode) pin P47 is used for general-purpose input/output.
91
Reset: P4DDR and P4DR and the 8-bit timer control registers are initialized, making pins P40 to
P45 into input port pins with the MOS pull-ups off. When the chip comes out of reset into singlechip mode (mode 3), P46 and P47 also become input port pins with the MOS pull-ups off. When
the chip comes out of reset into an expanded mode (mode 1 or 2), the system clock and E clock
are output at P46 and P47.
Hardware Standby Mode: All pins are placed in the high-impedance state with the MOS pullups off.
Software Standby Mode: The 8-bit timer control registers are initialized but P4DDR and P4DR
remain in their previous states. Pins P40 to P45 become input or output port pins depending on
the setting of P4DDR. Pins P46 and P47 remain in their previous states, with system clock output
remaining high and E clock output remaining low. The MOS pull-ups of input pins are on or off
depending on the values in P4DR.
Figures 5-4 to 5-7 show schematic diagrams of port 4.
92
Reset
R
Q
D
P4nDDR
C
Reset
P4 n
R
Q
P4nDR
C
D
Internal data bus
WP4D
WP4
RP4
8-bit timer module
WP4D: Write Port 4 DDR
WP4: Write Port 4
RP4: Read Port 4
n = 0, 2, 3, 5
Counter clock
input
Counter reset
input
Figure 5-4. Port 4 Schematic Diagram (Pins P40, P42, P43, and P45)
93
Reset
R
Q
D
P4nDDR
C
Reset
R
Q
P4 n
P4nDR
C
D
Internal data bus
WP4D
WP4
RP4
WP4D: Write Port 4 DDR
WP4: Write Port 4
RP4: Read Port 4
n = 1, 4
Figure 5-5. Port 4 Schematic Diagram (Pins P41 and P44)
94
8-Bit timer module
Output enable
8-Bit timer output
Hardware standby
Reset
Mode 1 or 2
R
P46DDR
C
WP4D
Reset
R
Q
Internal data bus
D
Q
D
P46DR
C
WP4
P4 6
Ø
RP4
WP4D: Write Port 4 DDR
WP4: Write Port 4
RP4: Read Port 4
Figure 5-6. Port 4 Schematic Diagram (Pin P46)
95
Mode 3
Mode
1or 2
Reset
Hardware standby
Q
S
R
D
P47DDR
R
Q
P4 7
D
P47DR
C
Mode 1 or 2
Internal data bus
C
WP4D
Reset
Mode 3
WP4
E
RP4
WP4D: Write Port 4 DDR
WP4: Write Port 4
RP4: Read Port 4
Figure 5-7. Port 4 Schematic Diagram (Pin P47)
5.6 Port 5
Port 5 is a 6-bit input/output port that also provides the input and output pins for the serial
communication interface. The pin functions depend on control bits in the serial control registers.
Pins not used for serial communication are available for general-purpose input/output. Table 510 lists the pin functions, which are the same in both the expanded and single-chip modes.
Table 5-10. Port 5 Pin Functions (Modes 1 to 3)
Usage
Pin functions
I/O port
P50
P51
P52
P53
P54
P55
Serial communication
TxD0
RxD0
SCK0
TxD1
RxD1
SCK1
96
See section 9, Serial Communication Interface for details of the serial control bits. Pins used by
the serial communication interface are switched between input and output without regard to the
values in the data direction register.
Pins of port 5 can drive a single TTL load and a 30-pF capacitive load when they are used as
output pins. They can also drive a Darlington pair.
Table 5-11 details the port 5 registers.
Table 5-11. Port 5 Registers
Name
Abbreviation
Read/Write
Initial value
Address
Port 5 data direction register P5DDR
W
H’C0
H’FFB8
Port 5 data register
R/W
H’C0
H’FFBA
P5DR
Port 5 Data Direction Register (P5DDR)—H’FFB8
Bit
7
6
5
4
3
2
1
0
—
—
P55DDR
P54DDR
P53DDR
P52DDR
P51DDR
P50DDR
Initial value
1
1
0
0
0
0
0
0
Read/Write
—
—
W
W
W
W
W
W
P5DDR is an 8-bit register that selects the direction of each pin in port 5. A pin functions as an
output pin if the corresponding bit in P5DDR is set to 1, and as an input pin if the bit is cleared
to 0.
Port 5 Data Register (P5DR)—H’FFBA
Bit
7
6
5
4
3
2
1
0
P53
P52
P51
P50
—
—
P55
P54
Initial value
1
1
0
0
0
0
0
0
Read/Write
—
—
R/W
R/W
R/W
R/W
R/W
R/W
P5DR is an 8-bit register containing output data for pins P55 to P50, and controlling their input
pull-ups. When the CPU reads P5DR, for output pins (P5DDR = 1) it reads the value in the
P5DR latch, but for input pins (P5DDR = 0), it obtains the logic level directly from the pin,
bypassing the P5DR latch. This also applies to pins used for serial communication.
MOS Pull-Ups: Are available for input pins, including serial communication input pins.
Software can turn the MOS pull-up on by writing a 1 in P5DR, and turn it off by writing a 0. The
pull-ups are automatically turned off for output pins.
97
Pins P50 and P53: These pins can be used for general-purpose input or output, or for output of
serial transmit data (TxD). When used for TxD output, these pins are unaffected by the values in
P5DDR and P5DR, and their MOS pull-ups are automatically turned off.
Pins P51 and P54: These pins can be used for general-purpose input or output, or for input of
serial receive data (RxD). When used for RxD input, these pins are unaffected by P5DDR and
P5DR, except that software can turn on their MOS pull-ups by clearing their data direction bits
to 0 and setting their data bits to 1.
Pins P52 and P55: These pins can be used for general-purpose input or output, or for serial clock
input or output (SCK). When used for SCK output, these pins are unaffected by P5DDR and
P5DR. When these pins are used for SCK input, software can turn on their MOS pull-ups by
clearing their data direction bits to 0 and setting their data bits to 1.
Reset and Hardware Standby Mode: P5DDR and P5DR are cleared to all 0 and the serial
control registers are initialized. All pins are placed in the input port (high-impedance) state with
the MOS pull-ups off.
Software Standby Mode: The serial control registers are initialized but P5DDR and P5DR
remain in their previous states. All pins become input or output port pins depending on the
setting of P5DDR. Output pins output the values in P5DR. The MOS pull-ups of input pins are
on or off depending on the values in P5DR.
Figures 5-8 to 5-10 show schematic diagrams of port 5.
98
Reset
R
Q
D
P5nDDR
C
Reset
R
Q
P5 n
P5nDR
C
D
Internal data bus
WP5D
WP5
SCI module
Output enable
Serial Tx data
RP5
WP5D: Write Port 5 DDR
WP5: Write Port 5
RP5: Read Port 5
n = 0, 3
Figure 5-8. Port 5 Schematic Diagram (Pins P50 and P53)
99
Reset
R
Q
D
P5nDDR
SCI module
WP5D
Reset
P5 n
R
Q
P5nDR
C
D
Internal data bus
C
Input enable
WP5
RP5
WP5D: Write Port 5 DDR
WP5: Write Port 5
RP5: Read Port 5
n = 1,4
Figure 5-9. Port 5 Schematic Diagram (Pins P51 and P54)
100
Serial Rx Data
Reset
R
Q
D
P5nDDR
SCI module
C
WP5D
Reset
R
Q
P5n
P5nDR
C
D
Internal data bus
Clock input
enable
WP5
Clock output
enable
Clock output
RP5
Clock input
WP5D: Write Port 5 DDR
WP5: Write Port 5
RP5: Read Port 5
n = 2, 5
Figure 5-10. Port 5 Schematic Diagram (Pins P52 and P55)
5.7 Port 6
Port 6 is a 7-bit input/output port that also provides input and output pins for the free-running
timer, and interrupt request input pins (,54 to ,54). The pin functions depend on control bits
in the free-running timer control registers and IRQ enable register. Pins not used for timer or
interrupt functions are available for general-purpose input/output. Table 5-12 lists the pin
functions, which are the same in both the expanded and single-chip modes.
101
Table 5-12. Port 6 Pin Functions
Usage
Pin functions (Modes 1 to 3)
I/O port
P60
Timer/interrupt FTCI
P61
P62
P63
P64
P65
P66
FTOA
FTOB
FTI
,54
,54
,54
See section 4, Exception Handling and section 7, Free-Running Timer Module for details of the
free-running timer and interrupts.
Pins of port 6 can drive a single TTL load and a 90-pF capacitive load when they are used as
output pins. They can also drive a Darlington pair.
Table 5-13 details the port 6 registers.
Table 5-13. Port 6 Registers
Name
Abbreviation Read/Write
Initial value
Address
Port 6 data direction register P6DDR
W
H’80
H’FFB9
Port 6 data register
R/W
H’80
H’FFBB
P6DR
Port 6 Data Direction Register (P6DDR)—H’FFB9
Bit
Initial value
Read/Write
7
6
5
4
3
2
1
0
—
P66DDR
P65DDR
P64DDR
P63DDR
P62DDR
P61DDR
P60DDR
1
—
0
W
0
W
0
W
0
W
0
W
0
W
0
W
P6DDR is an 8-bit register that selects the direction of each pin in port 6. A pin functions as an
output pin if the corresponding bit in P6DDR is set to 1, and as an input pin if the bit is cleared
to 0.
Port 6 Data Register (P6DR)—H’FFBB
Bit
7
—
6
P66
Initial value
Read/Write
0
—
0
R/W
5
4
3
2
1
0
P65
0
R/W
P64
0
R/W
P63
0
R/W
P62
0
R/W
P61
0
R/W
P60
0
R/W
P6DR is an 8-bit register containing output data for pins P66 to P60, and controlling their input
pull-ups. When the CPU reads P6DR, for output pins (P6DDR = 1) it reads the value in the
P6DR latch, but for input pins (P6DDR = 0), it obtains the logic level directly from the pin,
bypassing the P6DR latch. This also applies to pins used for input and output of timer and
interrupt signals.
102
MOS Pull-Ups: Are available for input pins, including pins used for input of timer or interrupt
signals. Software can turn the MOS pull-up on by writing a 1 in P6DR, and turn it off by writing
a 0. The pull-ups are automatically turned off for output pins.
Pins P60 and P63: As indicated in table 5-12, these pins can be used for general-purpose input or
output, or for input of free-running timer clock and input capture signals. When a pin is used for
free-running timer input, its P6DDR bit should be cleared to 0; otherwise the free-running timer
will receive the value in P6DR. If input pull-up is not desired, the P6DR bit should also be
cleared to 0.
Pin P61 and P62: These pins can be used for general-purpose input or output, or for the output
compare signals (FTOA and FTOB) of the free-running timer. When used for FTOA or FTOB
output, these pins are unaffected by the values in P6DDR and P6DR, and their MOS pull-ups are
automatically turned off.
Pins P64 to P66: These pins can be used for general-purpose input or output, or input of interrupt
request signals (,54 to ,54). When they are used for interrupt request input, their data
direction bits should normally be cleared to 0, so that the value in P6DR will not generate
interrupts.
Reset and Hardware Standby Mode: P6DDR and P6DR are cleared to all 0. Timer output and
interrupt request input are disabled. All pins are placed in the input port (high-impedance) state
with the MOS pull-ups off.
Software Standby Mode: The free-running timer control registers are initialized but P6DDR,
P6DR, and the interrupt control registers remain in their previous states. All pins become input
or output port pins or interrupt request pins depending on the settings of P6DDR and the IRQ
enable register. Output pins output the values in P6DR. The MOS pull-ups of input pins are on
or off depending on the values in P6DR.
Figures 5-11 to 5-13 shows schematic diagrams of port 6.
103
Reset
R
Q
D
P6nDDR
C
Reset
P6 n
R
Q
D
P6nDR
C
Internal data bus
WP6D
WP6
RP6
Free-running
timer module
WP6D: Write Port 6 DDR
WP6: Write Port 6
RP6: Read Port 6
n = 0, 3
Figure 5-11. Port 6 Schematic Diagram (Pins P60 and P63)
104
Input-capture
input,
Counter clock
input
Reset
R
Q
D
P6nDDR
C
Reset
R
Q
P6 n
P6nDR
C
D
Internal data bus
WP6D
WP6
Free-running
timer module
Output enable
Output-compare
output
RP6
WP6D: Write Port 6 DDR
WP6: Write Port 6
RP6: Read Port 6
n = 1, 2
Figure 5-12. Port 6 Schematic Diagram (Pins P61 and P62)
105
Reset
R
Q
D
P6nDDR
C
Reset
P6 n
R
Q
D
P6nDR
C
Internal data bus
WP6D
WP6
RP6
WP6D: Write Port 6 DDR
WP6: Write Port 6
RP6: Read Port 6
n = 4 to 6
IRQ0 input
IRQ1 input
IRQ2 input
IRQ enable
register
IRQ0 enable
IRQ1 enable
IRQ2 enable
Figure 5-13. Port 6 Schematic Diagram (Pins P64, P65, and P66)
5.8 Port 7
Port 7 is an 8-bit input/output port that also provides bus control signals (in the expanded
modes), and parallel handshaking control signals. Table 5-14 lists the pin functions.
106
Table 5-14. Port 7 Pin Functions
Pin
Expanded modes
Single-chip mode
P70
P70 input/output or ,6 input
P71 input/output
P70 input/output or ,6 input
P71
P72
P72 input/output
P73 input or ,26 output
P72 input/output or %86< output
P73
P74
P75
P76
P77
P71 input/output or 26 output
P73 input/output
$6 output
:5 output
5' output
:$,7 input
P74 input/output
P75 input/output
P76 input/output
P77 input/output
Pins of port 7 can drive a single TTL load and a 90-pF capacitive load when they are used as
output pins.
Table 5-15 details the port 7 registers.
Table 5-15. Port 7 Registers
Name
Abbreviation Read/Write
Initial value
Address
Port 7 data direction register P7DDR
W
H’00
H’FFBC
Port 7 data register
R/W
H’00
H’FFBE
P7DR
Port 7 Data Direction Register (P7DDR)—H’FFBC
Bit
Initial value
Read/Write
7
6
5
4
3
2
1
0
P77DDR
P76DDR
P75DDR
P74DDR
P73DDR
P72DDR
P71DDR
P70DDR
0
W
0
W
0
W
0
W
0
W
0
W
0
W
0
W
P7DDR is an 8-bit register that selects the direction of each pin in port 7. A pin functions as an
output pin if the corresponding bit in P7DDR is set to 1, and as in input pin if the bit is cleared to
0.
Port 7 Data Register (P7DR)—H’FFBE
Bit
7
6
5
4
3
2
1
0
P77
P76
P75
P74
P73
P72
P71
P70
Initial value
0
0
0
0
0
0
0
0
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
107
P7DR is an 8-bit register containing output data for pins P77 to P70, and controlling their input
pull-ups. When the CPU reads P7DR, for output pins (P7DDR = 1) it reads the value in the
P7DR latch, but for input pins (P7DDR = 0), it obtains the logic level directly from the pin,
bypassing the P7DR latch. This also applies to pins used for control signal input or output.
MOS Pull-Ups: Are available for input pins, including pins used for input of the ,6 and :$,7
signals. Software can turn the MOS pull-up on by writing a 1 in P7DR, and turn it off by writing
a 0. The pull-ups are automatically turned off for output pins.
Pin P70: Can be used for general-purpose input or output, or input of the input strobe (,6)
parallel handshake signal. When P70 is used for ,6 input, P70DDR should be cleared to 0, so that
output from P7DR will not cause unintended strobes. If input pull-up is not desired, P70DR
should also be cleared to 0.
Pins P71 and P72: In modes 1 and 2 (expanded modes), these pins can be used for generalpurpose input or output.
In mode 3 (single-chip mode), these pins can be used for general-purpose input or output or for
output of the 26 and %86< parallel handshake signals, depending on the OSE and BSE bits in
the handshake control/status register. See section 6, Parallel Handshaking Interface, for further
information. Pins used for parallel handshaking output are unaffected by the values in P7DDR
and P7DR, and their MOS pull-ups are automatically turned off.
Pin P73: In modes 1 and 2 (expanded modes) P73 is used for ,26 output if P73DDR is set to 1,
and for general-purpose input if P73DDR is cleared 0. It cannot be used for general-purpose
output.
In mode 3 (single-chip mode), pin P73 can be used for general-purpose input or output.
Pins P74, P75, and P76: In modes 1 and 2 (expanded modes), these pins are used for output of
the $6, 5', and :5 bus control signals. They are unaffected by the values in P7DDR and
P7DR, and their MOS pull-ups are automatically turned off.
In mode 3 (single-chip mode), these pins can be used for general-purpose input or output.
Pin P77: In modes 1 and 2, this pin is used for input of the :$,7 bus control signal. It is
unaffected by the values in P7DDR and P7DR, except that software can turn on its MOS pull-up
by clearing its data direction bit to 0 and setting its data bit to 1.
108
In mode 3 (single-chip mode), this pin can be used for general-purpose input or output.
Reset: In the single-chip mode (mode 3), a reset initializes all pins of port 7 to the generalpurpose input state with the MOS pull-ups off. In the expanded modes (modes 1 and 2), P70 to
P73 are initialized as input port pins, and P74 to P77 are initialized to their bus control functions.
Hardware Standby Mode: All pins are placed in the high-impedance state with the MOS pullups off.
Software Standby Mode: All pins remain in their previous state. For 5', :5, and $6 this
means the high output state.
Figures 5-14 to 5-18 show schematic diagrams of port 7.
109
Reset
R
Q
D
P70DDR
C
Reset
P7 0
R
Q
P70DR
C
D
Internal data bus
WP7D
WP7
RP7
WP7D: Write Port 7 DDR
WP7: Write Port 7
RP7: Read Port 7
Figure 5-14. Port 7 Schematic Diagram (Pin P70)
110
IS input
Reset
R
Q
D
P7nDDR
C
Reset
R
Q
P7 n
P7nDR
C
D
Internal data bus
WP7D
WP7
Handshake control
status register
OSE
BSE
OS output
BUSY output
RP7
WP7D: Write Port 7 DDR
WP7: Write Port 7
RP7: Read Port 7
n = 1, 2
Figure 5-15. Port 7 Schematic Diagram (Pins P71 and P72)
111
Reset
Q
S
R
D
P73DDR
C
Mode 3
Reset
R
Q
P7 3
D
P73DR
C
Mode 1 or 2
WP7
RP7
WP7D: Write Port 7 DDR
WP7: Write Port 7
RP7: Read Port 7
Figure 5-16. Port 7 Schematic Diagram (Pin P73)
112
Internal data bus
WP7D
IOS output
Mode 1 or 2
Hardware standby
Reset
R
Q
D
P7nDDR
R
Q
P7n
P7nDR
C
Mode 1 or 2
D
Internal data bus
C
WP7D
Reset
Mode 3
WP7
AS output
WR output
RD output
RP7
WP7D: Write Port 7 DDR
WP7: Write Port 7
RP7: Read Port 7
n = 4, 5, 6
Figure 5-17. Port 7 Schematic Diagram (Pins P74, P75, and P76)
113
Mode 1 or 2
Reset
R
Q
D
P77DDR
P77
R
Q
P77DR
C
D
Internal data bus
C
WP7D
Reset
WP7
RP7
WAIT input
WP7D: Write Port 7 DDR
WP7: Write Port 7
RP7: Read Port 7
Figure 5-18. Port 7 Schematic Diagram (Pin P77)
114
Section 6. Parallel Handshaking Interface
6.1 Overview
In single-chip mode (mode 3), the H8/325 Series chips can interface to another device by
parallel handshaking, using port 3.
6.1.1 Features
• Built-in latch circuits
Data input to port 3 can be latched on the falling edge of the ,6 signal.
• Strobe signal output
A strobe signal can be output on the 26 line when port 3 is written or read.
• Busy signal output
A busy signal is output on the %86< line from the time when data are latched on the falling
edge of ,6 until the latched data are read, unlocking the latch.
• Input strobe interrupt
An input strobe interrupt can be generated at the falling edge of the ,6 signal.
• Recovery from software standby mode
The input strobe interrupt can be used to recover from software standby mode.
115
6.1.2 Block Diagram
Figure 6-1 is a block diagram of the parallel handshaking interface.
OS
BUSY
IS
HCSR
Control
logic
ISI interrupt
signal
D
C
Q
RP3
Reset
R
Q
P3n
D
P3nDR
C
WP3
Reset
R
Q
P3nDDR
C
Port 3
WP3D
WP3: Write Port 3
RP3: Read Port 3
WP3D: Write Port 3 DDR
n = 0 to 7
Figure 6-1. Block Diagram of Parallel Handshaking Interface
116
D
Internal data bus
Input
latch
6.1.3 Input and Output Pins
Table 6-1 lists the input and output pins used by the parallel handshaking interface.
Table 6-1. Input and Output Pins of Parallel Handshaking Interface
Name
Abbreviation
I/O
Function
Data input/output pins
P37 – P30
I/O
Data input and output
I
Strobe for input data
O
Strobe for output data
O
Busy signal
,6
26
%86<
Input strobe
Output strobe
Busy
6.1.4 Register Configuration
Table 6-2 lists information about the parallel handshaking interface registers.
Table 6-2. Register Configuration
Name
Abbreviation
R/W
Initial value
Address
Port 3 data direction register
P3DDR
W
H'00
H'FFB4
Port 3 data register
P3DR
R/W
H'00
H'FFB6
Handshake control/status register HCSR
R/W
H'03
H'FFFE
6.2 Register Descriptions
6.2.1 Port 3 Data Direction Register (P3DDR)
bit
7
6
5
4
3
2
1
0
P37DDR
P36DDR
P35DDR
P34DDR
P33DDR
P32DDR
P31DDR
P30DDR
Initial value
0
0
0
0
0
0
0
0
Read/Write
W
W
W
W
W
W
W
W
To use the parallel handshaking interface for input, clear P3DDR to H'00. For output, set
P3DDR to H'FF. Do not set the bits individually.
See Section 5.4, Port 3 for further information.
117
6.2.2 Port 3 Data Register (P3DR)
Bit
7
6
5
4
3
2
1
0
P37
P36
P35
P34
P33
P32
P31
P30
Initial value
0
0
0
0
0
0
0
0
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
When the parallel handshaking interface is used for output (P3DDR = H'FF), P3DR stores the
output data. If port 3 is read, the P3DR data are obtained.
When the parallel handshaking interface is used for input (P3DDR = H'00), P3DR has separate
latches for reading and writing. The data written in P3DR control the MOS input pull-ups. When
P3DR is read, data are obtained from the separate input latches if the input strobe flag (ISF) is
set to 1, or directly from the input pins if ISF is cleared to 0.
See Section 5.4, Port 3 for further information.
6.2.3 Handshake Control/Status Register (HCSR)
Bit
7
6
5
4
3
2
1
0
ISF
ISIE
OSE
OSS
LTE
BSE
—
—
Initial value
0
0
0
0
0
0
1
1
Read/Write
R
R/W
R/W
R/W
R/W
R/W
—
—
HCSR is an 8-bit register containing control and status information for parallel handshaking. In
the reset and hardware standby modes, HCSR is initialized to H'03. In the software standby
mode it retains its previous value.
Bit 7—Input Strobe Flag (ISF): Indicates that the input strobe signal (,6) has gone low.
ISF is a read-only bit that is set and cleared by hardware. It is set by strobe input. It is cleared
when the port 3 data register is written or read. (The handshake control/status register must be
read first.)
Bit 7
ISF
0
Description
To clear ISF, the CPU must read HCSR after ISF has been
set to 1, then read or write the port 3 data register (P3DR).
1
118
ISF is set to 1 on the falling edge of
,6.
(Initial value)
Bit 6—Input Strobe Interrupt Enable (ISIE): Enables or disables the handshake interrupt
request (ISI).
Bit 6
ISIE
Description
0
The handshake interrupt request (ISI) is disabled.
1
The handshake interrupt request (ISI) is enabled.
(Initial value)
Bit 5—Output Strobe Enable (OSE): Enables or disables output of the output strobe signal. Do
not set OSE to 1 in the expanded modes (modes 1 and 2).
Bit 5
OSE
Description
0
The output strobe signal is disabled.
1
The output strobe signal is enabled.
(Initial value)
Bit 4—Output Strobe Select (OSS): Selects whether to generate an output strobe signal when
the port 3 data register (P3DR) is written, or when it is read.
Bit 4
OSS
Description
0
An output strobe signal is output when P3DR is read.
1
An output strobe signal is output when P3DR is written.
(Initial value)
Bit 3—Latch Enable (LTE): Controls the input latches of port 3. Do not set LTE to 1 in the
expanded modes (modes 1 and 2).
When LTE is set to 1, input data are latched on the falling edge of ,6. The data are retained in
the input latch until the port 3 data register (P3DR) is read, after which the next data can be
latched.
Bit 3
LTE
Description
0
Port 3 input data are not latched.
1
Port 3 input data are latched on the falling edge of
(Initial value)
,6.
119
Bit 2—Busy Enable (BSE): This bit enables or disables output of the busy signal. Do not set
BSE to 1 in the expanded modes (modes 1 and 2).
Bit 2
ISIE
Description
0
Busy signal output is disabled.
1
Busy signal output is enabled.
(Initial value)
Bits 1 and 0—Reserved: These bits cannot be modified and are always read as 1.
6.3 Operation
6.3.1 Output Timing of Output Strobe Signal
The output strobe signal is output when the port 3 data register (P3DR) is written or read. The
output strobe signal goes low at the seventh system clock cycle after P3DR is written or read,
remains low for eight system clock cycles, then goes high. Figure 6-2 shows how the output
strobe signal is output after P3DR is written (when OSS = 1).
Note the following point when reading or writing P3DR twice consecutively.
If P3DR is written or read once, then written or read again within 15 states, the output strobe
signal is not output for the second write or read. Figure 6-3 shows an example of this when OSS
= 1.
Port 3 write
Ø
Port 3
OS
7 system clocks
8 system clocks
Figure 6-2. Output Strobe Output Timing (When OSS = 1)
120
Port 3 write
Port 3 write
Ø
Port 3
OS
Not output
Figure 6-3. Output Strobe Output Timing
(Consecutive Writing of Port 3 When OSS = 1)
6.3.2 Busy Signal Output Timing
The busy signal remains low from the fall of the input strobe signal until the data latched in port
3 have been read, unlocking the latch. Figure 6-4 shows an example.
While the busy signal is low, data input to port 3 are not latched, even if the input strobe signal
goes low again.
Port 3 read
Ø
IS
BUSY
Figure 6-4. Busy Signal Output Timing
6.3.3 Operation in Software Standby Mode
In software standby mode, the 26 and %86< output pins retain their previous states. For timing
of the output strobe signal, the entire time during when the chip is in software standby mode is
counted as zero system clock cycles. Figure 6-5 shows an example.
121
Port 3 write
Ø
Port 3
Same data held
Same state held
OS
T1
T2
Software
standby mode
Clock
settling time
T1 + T2 = 7 system clocks
Figure 6-5. Output Strobe Timing in Software Standby Mode
When the ISIE and LTE bits in the handshake control/status register (HCSR) are both set to 1, if
a high-to-low transition of the ,6 signal occurs during software standby mode, an input strobe
interrupt is requested and the chip recovers from software standby mode to handle the interrupt.
If the parallel handshaking interface is set for input, the port 3 input data are also latched.
If either the ISIE or LTE bit is cleared to 0, then high-to-low transitions of the ,6 signal are
ignored during software standby mode.
6.3.4 Sample Application
Figure 6-6 shows an example in which the parallel handshaking interface is used to interconnect
two H8/325 chips. Figure 6-7 shows the interface timing.
P3 7 to P3 0
P3 7 to P3 0
OS
IS
IS
OS
H8/325 (sending chip)
H8/325 (receiving chip)
Figure 6-6. Sample Usage of Parallel Handshaking Interface
122
Sending H8/325
Receiving H8/325
Interrupt
request
Write
P3DR
Interrupt
request
Read
HCSR
Read
HCSR
Write
P3DR
Read
P3DR
P3 7 to P3 0
P3 7 to P3 0
OS
IS
IS
OS
H8/325
(sending chip)
H8/325
(receiving chip)
P3DR: Port 3 data register
HCSR: Handshake control/Status register
Figure 6-7. Parallel Handshaking Interface Timing Chart (Example)
1. The sending and receiving H8/325s set their HCSR bits as follows:
Sending H8/325: ISIE = 1, OSE = 1, OSS = 1, LTE = 0, BSE = 0.
Receiving H8/325: ISIE = 1, OSE = 1, OSS = 0, LTE = 1, BSE = 0.
2. The sending H8/325 writes the transmit data in the port 3 data register (P3DR). This generates
an output strobe signal, notifying the receiving H8/325 of data output.
3. The receiving H8/325 receives the strobe on its input strobe line and latches the data in port .
ISF is set to 1, generating an input strobe interrupt.
4. The receiving H8/325 reads HCSR, then reads the received data from P3DR. This clears ISF
to 0 and generates an output strobe signal, notifying the sending H8/325 that the data have
been received.
5. The input strobe line of the sending H8/325 goes low, setting ISF and generating an input
strobe interrupt.
6. The sending H8/325 reads HCSR, then writes the next transmit data in P3DR. (If it has no
next data to send, it should read P3DR.) This clears ISF to 0 and generates an output strobe
signal. The process now returns to step 3.
6.3.5 Interrupts
Regardless of the operating mode or the value of the LTE bit, ISF is always set to 1 when the ,6
input changes from high to low. If ISIE is set to 1, an input strobe interrupt (ISI) is requested. In
the software standby mode, LTE must also be set. See section 6.3.3, Operation in Software
Standby Mode.
123
124
Section 7. 16-BIT Free-Running Timer
7.1 Overview
The H8/325 Series has an on-chip 16-bit free-running timer (FRT) module that uses a 16-bit
free-running counter as a time base. Applications of the FRT module include rectangular-wave
output (up to two independent waveforms), input pulse width measurement, and measurement of
external clock periods.
7.1.1 Features
The features of the free-running timer module are listed below.
• Selection of four clock sources
The free-running counter can be driven by an internal clock source (0/2, 0/8, or 0/32), or an
external clock input (enabling use as an external event counter).
• Two independent comparators
Each comparator can generate an independent waveform.
• Input capture
The current count can be captured on the rising or falling edge (selectable) of an input signal.
• Counter can be cleared under program control
The free-running counter can be cleared on compare-match A.
• Four interrupt sources
Compare-match A and B, input capture, and overflow interrupts are requested independently.
• Noise canceler
A built-in noise canceler can remove high-frequency noise from the pulse signal input at the
input capture pin.
7.1.2 Block Diagram
Figure 7-1 shows a block diagram of the free-running timer.
125
Internal
clock sources
Ø/2
Ø/8
Ø / 32
External
clock source
FTCI
Clock select
Clock
OCRA (H/L)
Comparematch A
Comparator A
FTOA
Overflow
FTOB
Clear
Comparematch B
Control
logic
Comparator B
OCRB (H/L)
Capture
ICR (H/L)
Module data bus
FTI
Bus interface
FRC (H/L)
TCSR
TCR
ICI
OCIA
OCIB
FOVI
Interrupt signals
Legend
OCRA:
OCRB:
FRC:
ICR:
TCSR:
TCR:
Output Compare Register A
Output Compare Register B
Free-Running Counter
Input Capture Register
Timer Control / Status Register
Time Control Register
Figure 7-1. Block Diagram of 16-Bit Free-Running Timer
126
Internal
data bus
7.1.3 Input and Output Pins
Table 7-1 lists the input and output pins of the free-running timer module.
Table 7-1. Input and Output Pins of Free-Running Timer Module
Name
Abbreviation
I/O
Function
Counter clock input
FTCI
Input
Input of external free-running counter
clock signal
Output compare A
FTOA
Output
Output controlled by comparator A
Output compare B
FTOB
Output
Output controlled by comparator B
Input capture
FTI
Input
Input capture trigger
7.1.4 Register Configuration
Table 7-2 lists the registers of the free-running timer module.
Table 7-2. Register Configuration
Name
Abbreviation
R/W
Initial
value
Address
Timer control register
TCR
R/W
H'00
H'FF90
Timer control/status register
TCSR
R/(W)*
H'00
H'FF91
Free-running counter (high)
FRC (H)
R/W
H'00
H'92
Free-running counter (low)
FRC (L)
R/W
H'00
H'FF93
Output compare register A (high)
OCRA (H)
R/W
H'FF
H'FF94
Output compare register A (low)
OCRA (L)
R/W
H'FF
H'FF95
Output compare register B (high)
OCRB (H)
R/W
H'FF
H'FF96
Output compare register B (low)
OCRB (L)
R/W
H'FF
H'FF97
Input capture register (high)
ICR (H)
R
H'00
H'FF98
Input capture register (low)
ICR (L)
R
H'00
H'FF99
FRT noise canceler control register
FNCR
R/W
H'FC
H'FFFF
* Software can write a 0 to clear bits 7 to 4, but cannot write a 1 in these bits.
127
7.2 Register Descriptions
7.2.1 Free-Running Counter (FRC) - H'FF92
Bit
15
14
13
12
11
10
9
8
7
6
5
Initial
value
Read/
Write
0
0
0
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
4
3
2
1
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
The FRC is a 16-bit readable/writable up-counter that increments on an internal pulse generated
from a clock source. The clock source is selected by the clock select 1 and 0 bits (CKS1 and
CKS0) of the timer control register (TCR).
When the FRC overflows from H'FFFF - to H'0000, the overflow flag (OVF) in the timer
control/status register (TCSR) is set to l.
Because the FRC is a 16-bit register, a temporary register (TEMP) is used when the FRC is
written or read. See section 7.3, CPU Interface for details.
The FRC is initialized to H'0000 at a reset and in the standby modes. It can also be cleared by
compare-match A.
7.2.2 Output Compare Registers A and B (OCRA and OCRB) - H'FF94 and H'FF96
Bit
15
14
13
12
11
10
9
8
7
6
5
Initial
value
Read/
Write
1
1
1
1
1
1
1
1
1
1
1
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
4
3
2
1
0
1
1
1
1
1
R/W
R/W
R/W
R/W
R/W
OCRA and OCRB are 16-bit readable/writable registers, the contents of which are continually
compared with the value in the FRC. When a match is detected, the corresponding output
compare flag (OCFA or OCFB) is set in the timer control/status register (TCSR).
128
In addition, if the output enable bit (OEA or OEB) in the timer output compare control register
(TCR) is set to 1, when the output compare register and FRC values match, the logic level
selected by the output level bit (OLVLA or OLVLB) in the TCSR is output at the output
compare pin (FTOA or FTOB).
Because OCRA and OCRB are 16-bit registers, a temporary register (TEMP) is used for write
access, as explained in section 7.3, CPU Interface.
OCRA and OCRB are initialized to H'FFFF at a reset and in the standby modes.
7.2.3 Input Capture Register (ICR) - H'FF98
Bit
15
14
13
12
11
10
9
8
7
6
5
Initial
value
Read/
Write
0
0
0
0
0
0
0
0
0
0
0
R
R
R
R
R
R
R
R
R
R
R
4
3
2
1
0
0
0
0
0
0
R
R
R
R
R
The input capture register is a 16-bit read-only register.
When the rising or falling edge of the signal at the input capture pin (FTI) is detected, the
current value of the FRC is copied to the input capture register (ICR). At the same time, the
input capture flag (ICF) in the timer control/status register (TCSR) is set to 1. The input capture
edge is selected
by the input edge select bit (IEDG) in the TCSR.
Because the input capture register is a 16-bit register, a temporary register (TEMP) is used when
it is read. See Section 7.3, CPU Interface for details.
To ensure input capture, when the noise canceler is not used, the width of the input capture pulse
(FTI) should be at least 1.5 system clock cycles (1.5.∅).
129
Ø
FTIA, FTIB,
FTIC, OR FTID
Figure 7-2. Minimum Input Capture Pulse Width (Noise Canceler Disabled)
The input capture register is initialized to H'0000 at a reset and in the standby modes.
Note: When input capture is detected, the FRC value is transferred to the input capture register
even if the input capture flag is already set.
7.2.4 Timer Control Register (TCR) - H'FF90
7
Bit
ICIE
6
5
4
OCIEB OCIEA OVIE
3
2
1
0
OEB
OEA
CKS1
CKS0
Initial value
0
0
0
0
0
0
0
0
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
The TCR is an 8-bit readable/writable register that enables and disables output signals and
interrupts, and selects the timer clock source.
The TCR is initialized to H'00 at a reset and in the standby modes.
Bit 7 - Input Capture Interrupt Enable (ICIE): Selects whether to request an input capture
interrupt (ICI) when the input capture flag (ICF) in the timer status/control register (TCSR) is set
to 1.
Bit 7
ICIE
Description
0
Input capture interrupt request (ICI) is disabled.
1
Input capture interrupt request (ICI) is enabled.
(Initial value)
Bit 6 - Output Compare Interrupt B Enable (OCIBE): Selects whether to request output
compare interrupt B (OCIB) when output compare flag B (OCFB) in the timer status/control
register (TCSR) is set to 1.
130
Bit 6
OCIBE
Description
0
Output compare interrupt request B (OCIB) is disabled.
1
Output compare interrupt request B (OCIB) is enabled.
(Initial value)
Bit 5 - Output Compare Interrupt A Enable (OCIAE): Selects whether to request output
compare interrupt A (OCIA) when output compare flag A (OCFA) in the timer status/control
register (TCSR) is set to 1.
Bit 5
OCIAE
Description
0
Output compare interrupt request A (OCIA) is disabled.
1
Output compare interrupt request A (OCIA) is enabled.
(Initial value)
Bit 4 - Timer overflow Interrupt Enable (OVIE): Selects whether to request a free-running
timer overflow interrupt (FOVI) when the timer overflow flag (OVF) in the timer status/control
register (TCSR) is set to 1.
Bit 4
OVIE
Description
0
Timer overflow interrupt request (FOVI) is disabled.
1
Timer overflow interrupt request (FOVI) is enabled.
(Initial value)
Bit 3 - Output Enable B (OEB): Enables or disables output of the output compare B signal
(FTOB). If output compare B is enabled, the FTOB pin is driven to the level selected by OLVLB
in the timer status/control register (TCSR) whenever the FRC value matches the value in output
compare register B (OCRB).
Bit 3
OEB
Description
0
Output compare B output is disabled.
1
Output compare B output is enabled.
(Initial value)
Bit 2 - Output Enable A (OEA): Enables or disables output of the output compare A signal
(FTOA). If output compare A is enabled, the FTOA pin is driven to the level selected by
OLVLA in the timer status/control register (TCSR) whenever the FRC value matches the value
in output compare register A (OCRA).
131
Bit 2
OEA
Description
0
Output compare A output is disabled.
1
Output compare A output is enabled.
(Initial value)
Bits 1 and 0 - Clock Select (CKS1 and CKS0): These bits select external clock input or one of
three internal clock sources for the FRC. External clock pulses are counted on the rising edge.
Bit 1
CKS1
Bit 0
CKS0
Description
0
0
∅/2 Internal clock source
0
1
∅/8 Internal clock source
1
0
∅/32 Internal clock source
1
1
External clock source (rising edge)
(Initial value)
7.2.5 Timer Control/Status Register (TCSR) - H'FF91
7
6
5
4
3
2
1
0
ICF
OCFB
OCFA
OVF
OLVLB
OLVLA
IEDG
CCLRA
Initial value
0
0
0
0
0
0
0
0
Read/Write
R/(W)*
R/(W)*
R/(W)*
R/(W)
R/(W)
R/(W)
R/W
Bit
R/(W)*
The TCSR is an 8-bit readable and partially writable register that contains the four interrupt
flags and selects the output compare levels, input capture edge, and whether to clear the counter
on compare-match A.
The TCSR is initialized to H'00 at a reset and in the standby modes.
Bit 7 - Input Capture Flag (ICF): This status bit is set to 1 to flag an input capture event,
indicating that the FRC value has been copied to the ICR.
ICF must be cleared by software. It is set by hardware, however, and cannot be set by software.
132
Bit 7
ICF
Description
0
To clear ICF, the CPU must read ICF after it has been set to 1
then write a O in this bit.
1
This bit is set to 1 when an FTI input signal causes the FRC value
to be copied to the ICR.
(Initial value)
Bit 6 - Output Compare Flag B (OCFB): This status flag is set to 1 when the FRC value
matches the OCRB value.
This flag must be cleared by software. It is set by hardware, however, and cannot be set by
software.
Bit 6
OCFB
Description
0
To clear OCFB, the CPU must read OCFB after it has been set to
1 then write a O in this bit.
1
This bit is set to 1 when FRC = OCRB.
(Initial value)
Bit 5 - Output Compare Flag A (OCFA): This status flag is set to 1 when the FRC value
matches the OCRA value.
This flag must be cleared by software. It is set by hardware, however, and cannot be set by
software.
Bit 5
OCFA
Description
0
To clear OCFA, the CPU must read OCFA after it has been set to
1, then write a O in this bit.
1
This bit is set to I when FRC = OCRA.
(Initial value)
Bit 4 - Timer Overflow Flag (OVF): This status flag is set to I when the FRC overflows
(changes from H'FFFF to H'0000).
This flag must be cleared by software. It is set by hardware, however, and cannot be set by
software.
133
Bit 4
OVF
Description
0
To clear OVF, the CPU must read OVF after it has been set to 1,
then write a O in this bit.
1
This bit is set to 1 when FRC changes from H'FFFF to H'0000.
(Initial value)
Bit 3 - Output Level B (OLVLB): Selects the logic level output at the FTOB pin when the FRC
and OCRB values match.
Bit 3
OLVLB
Description
0
A O logic level is output for compare-match B.
1
A I logic level is output for compare-match B.
(Initial value)
Bit 2 - Output Level A (OLVLA): Selects the logic level output at the FTOA pin when the
FRC and OCRA values match.
Bit 2
OLVLA
0
1
Description
A O logic level is output for compare-match A.
(Initial value)
A 1 logic level is output for compare-match A.
Bit 1 - Input Edge Select (IEDG): Selects the rising or falling edge of the input capture signal
(FTI).
Bit 1
IEDG
Description
0
FRC contents are transferred to ICR on the falling edge of FTI.
1
FRC contents are transferred to ICR on the rising edge of FTI.
(Initial value)
Bit 0 - Counter Clear A (CCLRA): Selects whether to clear the FRC at comparematch A (when the FRC and OCRA values match).
Bit 0
CCLRA
Description
0
The FRC is not cleared.
1
The FRC is cleared at compare-match A.
134
(Initial value)
7.2.6 FRT Noise Canceler Control Register (FNCR) - H'FFFF
Bit
7
Initial value
1
6
1
5
1
4
1
3
1
2
1
0
NCS1
NCS0
0
0
R/W
R/W
1
Read/Write
The FNCR is an 8-bit readable/writable register that controls the input capture noise canceler.
The FNCR is initialized to H'FC at a reset and in the standby modes.
Bits 7 to 2 - Reserved: These bits cannot be modified, and are always read as 1.
Bits 1 and 0 - Noise Canceler Select 1 and 0 (NCS1 and NCS0): Select the sampling clock
provided to the noise canceler. Three internal clock rates can be selected.
The noise canceler recognizes a level change only if it is observed in four consecutive samples.
When the noise canceler is enabled, the input capture pulse width must be at least four sampling
clock cycles. See section 7.6, Noise Canceler for further information.
The noise canceler can be disabled by clearing both NCS 1 and NCS0 to 0. The input capture
pulse width must then be at least 1.5 system clock cycles (1.5 0) to assure capture.
Bit 1
NCS1
Bit 0
NCS0
Description
0
0
Noise canceler is disabled.
0
1
Sampling clock frequency: ∅/32
1
0
Sampling clock frequency: ∅/64
1
1
Sampling clock frequency: ∅/128
(Initial value)
7.3 CPU Interface
The free-running counter (FRC), output compare registers (OCRA and OCRB), and input
capture register (ICR) are 1 6-bit registers, but they are connected to an 8-bit data bus. When the
CPU accesses these registers, to ensure that both bytes are written or read simultaneously, the
access is performed using an 8-bit temporary register (TEMP).
135
These registers are written and read as follows:
• Register Write
When the CPU writes to the upper byte, the byte of write data is placed in TEMP. Next,
when the CPU writes to the lower byte, this byte of data is combined with the byte in
TEMP and all 16 bits are written in the register simultaneously.
Register Read
When the CPU reads the upper byte, the upper byte of data is sent to the CPU and the
lower byte is placed in TEMP. When the CPU reads the lower byte, it receives the value
in TEMP.
(As an exception, when the CPU reads OCRA or OCRB, it reads both the upper and
lower bytes directly, without using TEMP.)
Programs that access these registers should normally use word access. Equivalently, they may
access first the upper byte, then the lower byte by two consecutive byte accesses. Data will not
be transferred correctly if the bytes are accessed in reverse order, if only one byte is accessed, or
if the upper and lower bytes are accessed separately and another register is accessed in between,
altering the value in TEMP.
Coding Examples
To write the contents of general register R0 to OCRA:
MOV.WR0,
@OCRA
To transfer the ICR contents to general register R0: MOV.W@ICR, R0
Figure 7-3 shows the data flow when the FRC is accessed. The other registers are accessed in the
same way.
136
(1) Upper byte write
CPU writes
data H'AA
Module data bus
Bus interface
TEMP
[H'AA]
FRC H
[
]
FRC L
[
]
(2) Lower byte write
CPU writes
data H'55
Module data bus
Bus interface
TEMP
[H'AA]
FRC H
[H'AA]
FRC L
[H'55]
Figure 7-3 (a). Write Access to FRC (When CPU Writes H'AA55)
137
(1) Upper byte read
CPU writes
data H'AA
Module data bus
Bus interface
TEMP
[H'55]
FRC H
[H'AA]
FRC L
[H'55]
(2) Lower byte read
CPU writes
data H'55
Module data bus
Bus interface
TEMP
[H'55]
FRC H
[
]
FRC L
[
]
Figure 7-3 (b). Read Access to FRC (When FRC Contains H'AA55)
7.4 Operation
7.4.1 FRC Incrementation Timing
The FRC increments on a pulse generated once for each cycle of the selected (internal or
external) clock source.
(1) Internal Clock Sources: Can be selected by the CKS1 and CKS0 bits in the TCR. Internal
clock sources are created by dividing the system clock (∅). Three internal clock sources are
available: ∅/2, ∅/8, and ∅/32. Figure 7-4 shows the increment timing.
138
Ø
Prescaler
output
FRC clock
pulse
FRC
N-1
N+1
N
Figure 7-4. Increment Timing for Internal Clock Source
(2) External Clock Input: Can be selected by the CKS1 and CKS0 bits in the TCR. The FRC
increments on the rising edge of the FTCI clock signal. The pulse width of the external clock
signal must be at least 1.5 system clock (0) cycles. The counter will not increment correctly
if the pulse width is shorter than this.
Figure 7-5 shows the increment timing. Figure 7-6 shows the minimum external clock pulse
width.
Ø
FTCI
FRC clock pulse
FRC
N
N+1
Figure 7-5. Increment Timing for External Clock Source
139
Ø
FTCI
Figure 7-6. Minimum External Clock Pulse Width
7.4.2 Output Compare Timing
When a compare-match occurs, the logic level selected by the output level bit (OLVLA or
OLVLB) in the TCSR is output at the output compare pin (FTOA or FTOB). Figure 7-7 shows
the timing of this operation for compare-match A.
Ø
FRC
N
OCRA
N
N+1
N
N+1
N
Internal comparematch A signal
Clear *
OLVLA
FTOA
* Cleared by software
Figure 7-7. Timing of Output Compare A
7.4.3 FRC Clear Timing
If the CCLRA bit in the TCSR is set to 1, the FRC is cleared when compare-match A occurs.
Figure 7-8 shows the timing of this operation.
140
Ø
Internal comparematch A signal
FRC
N
H'0000
Figure 7-8. Clearing of FRC by Compare-Match A
7.4.4 Input Capture Timing
(1) Input Capture Timing without Noise Canceler: An internal input capture signal is
generated from the rising or falling edge of the FTI input, as selected by the EDG bit in the
TCSR. Figure 7-9 shows the usual input capture timing when the rising edge is selected
(EDG = 1).
Ø
Input at FTI pin
Internal input
capture signal
Figure 7-9. Input Capture Timing (Usual Case)
If the upper byte of the ICR is being read when the internal input capture signal should be
generated, the internal input capture signal is delayed by one state. Figure 7-10 shows the
timing for this case.
141
ICR upper byte read cycle
T1
T2
T3
Ø
Input at FTI pin
Internal input
capture signal
Figure 7-10. Input Capture Timing (1-State Delay Due to ICR Read)
(2) Input Capture Timing with Noise Canceler: The noise canceler samples the FTI input, and
does generate an internal input capture signal until three to four sampling clock cycles after
the rise or fall of FTI. Figure 7-9 shows the timing.
If the upper byte of the ICR is being read when the internal input capture signal should be
generated, the internal input capture signal is additionally delayed by one system clock cycle
(∅).
FTI
Sampling clock
Noise canceler output
Internal input capture
signal
Figure 7-11. Input Capture Timing with Noise Cancellation
7.4.5 Timing of Input Capture Flag (ICF) Setting
The input capture flag ICF is set to 1 by the internal input capture signal. The FRC contents are
transferred to the ICR at the same time. Figure 7-12 shows the timing of this operation.
142
Ø
Internal input
capture signal
ICF
FRC
N
ICR
N
Figure 7-12. Setting of Input Capture Flag
7.4.6 Setting of FRC Overflow Flag (OVF)
The FRC overflow flag (OVF) is set to 1 when the FRC changes from H'FFFF to H'0000. Figure
7-13 shows the timing of this operation.
Ø
FRC
H'FFFF
H'0000
Internal overflow
signal
OVF
Figure 7-13. Setting of Overflow Flag (OVF)
143
7.5 Interrupts
The free-running timer channel can request four types of interrupts: input capture (ICI), output
compare A and B (OCIA and OCIB), and overflow (FOVI). Each interrupt is requested when the
corresponding flag bit is set, provided the corresponding enable bit is also set. Independent
signals are sent to the interrupt controller for each type of interrupt. Table 7-3 lists information
about these interrupts.
Table 7-3.
Free-Running Timer Interrupts
Interrupt
Description
Priority
ICI
Requested when ICF and ICIE are set
High
OCIA
Requestcd when OCFA and OCIAE are set
↑
OCIB
Requested when OCFB and OCIBE are set
↓
FOVI
Requested when OVF and OVE are set
Low
7.6 Noise Canceler
The noise canceler acts as a digital low-pass filter, rejecting high-frequency pulses received at
the input capture (FTI) pin. Figure 7-14 shows a block diagram of the noise canceler.
The noise canceler consists of four latches connected in series, and a circuit that detects when all
four latches contain the same value. The FTI input is sampled on the rising edge of the sampling
clock selected by the NCS 1 and NCSO bits. When all four latches contain the same value, this
value is regarded as valid and output from the noise canceler. If all four latches are not the same,
the noise canceler holds its previous output. Immediately after a reset, the noise canceler output
is 0.
To assure capture, the pulse input at the FTI pin must be at least four sampling clock cycles
wide. The noise canceler control register (FNCR) provides a selection of three sampling clock
rates and the option of disabling the noise canceler. Table 7-4 indicates the cycle times of the
sampling clock for various settings.
144
Sampling signal
FTI
input
D C Q
D C Q
D C Q
D C Q
Latch
Latch
Latch
Latch
Agreement
detector
Noise
canceler
output
t
Sampling signal
t : Selected by NCS1 and NCS0
Figure 7-14. Noise Canceler Block Diagram
Table 7-4.
Sampling Clock Cycle for Various System Clock Frequencies
System clock (0) frequency (MHz)
NCS1
NCS0
0
Sampling
clock
10
8
6
4
2
1
0.5
0 --
--
--
--
--
--
--
--
0
1
∅/32
3.2
4.0
5.3
8.0
16.0
32.0
64.0
1
0
∅/64
6.4
8.0
10.7
16.0
32.0
64.0
128.0
1
1
∅/128
12.8
16.0
21.3
32.0
64.0
128.0
256.0
(Unit: µs)
Figure 7-15 shows an example of noise cancellation. In this example, an input capture pulse
narrower than four sampling clock cycles is rejected as noise.
145
FTI
Sampling clock
Noise canceler output
Rejected as noise
Figure 7-15. Noise Cancellation (Example)
7.7
Sample Application
In the example below, the free-running timer channel is used to generate two square-wave
outputs with a 50% duty factor and arbitrary phase relationship. The programming is as follows:
(1) The CCLRA bit in the TCSR is set to 1.
(2) Each time a compare-match interrupt occurs, software inverts the corresponding output level
bit in the TCSR (OLVLA or OLVLB).
H'FFFF
FRC
Clear Counter
OCRA
OCRB
H'0000
FTOA
FTOB
Figure 7-16. Square-Wave Output (Example)
146
7.8
Application Notes
Application programmers should note that the following types of contention can occur in the
free-running timer.
(1) Contention between FRC Write and Clear: If an internal counter clear signal is generated
during the T3 state of a write cycle to the lower byte of the free running counter, the clear
signal takes priority and the write is not performed.
Figure 7-17 shows this type of contention.
FRC lower byte write cycle
T1
T2
T3
Ø
Internal address bus
FRC address
Internal write signal
FRC clear signal
FRC
N
H'0000
Figure 7-17. FRC Write-Clear Contention
(2) Contention between FRC Write and Increment: If an FRC increment pulse is generated
during the T3 state of a write cycle to the lower byte of the free-running counter, the write
takes priority and the FRC is not incremented.
Figure 7-18 shows this type of contention.
147
FRC lower byte write cycle
T1
T2
T3
Ø
Internal address bus
FRC address
Internal write signal
FRC clock pulse
FRC
N
M
Write data
Figure 7-18. FRC Write-Increment Contention
(3) Contention between OCR Write and Compare-Match: If a compare-match occurs during
the T3 state of a write cycle to the lower byte of OCRA or OCRB, the write takes precedence
and the compare-match signal is inhibited.
Figure 7-19 shows this type of contention.
148
OCRA or OCRB lower byte write cycle
T1
T2
T3
Ø
Internal address bus
OCR address
Internal write signal
FRC
N
N+1
OCRA or OCRB
N
M
Write data
Compare-match
A or B signal
Inhibited
Figure 7-19. Contention between OCR Write and Compare-Match
(4) Incrementation Caused by Changing of Internal Clock Source: When an internal clock
source is changed, the changeover may cause the FRC to increment. This depends on the
time at which the clock select bits (CKS I and CKS0) are rewritten, as shown in table 7-5.
The pulse that increments the FRC is generated at the falling edge of the internal clock
source. If clock sources are changed when the old source is high and the new source is low,
as in case No. 3 in table 7-5, the changeover generates a falling edge that triggers the FRC
increment clock pulse.
Switching between an internal and external clock source can also cause the FRC to
increment.
149
Table 7-5.
Effect of Changing Internal Clock Sources
No.
Description
1
Low →Low: CKS1 and CKS0
are rewritten while both clock
sources are low.
Timing Chart
Old clock
source
New clock
source
FRC clock
pulse
FRC
N
N+1
CKS rewrite
2
Low → High: CKS1 and CKS0
are rewritten while old clock
source is low and new clock
source is high.
Old clock
source
New clock
source
FRC clock
pulse
FRC
N
N+1
N+2
CKS rewrite
3
High → Low: CKS1 and CKS0
are rewritten while old clock
source is high and new clock
source is low.
Old clock
source
New clock
source
*
FRC clock
pulse
FRC
N
N+1
N+2
CKS rewrite
4
High →High: CKS1 and CKS0
are rewritten while both clock
sources are high.
Old clock
source
New clock
source
FRC clock
pulse
FRC
N
N+1
N+2
CKS rewrite
* The switching of clock sources is regarded as a falling edge that increments the FRC.
150
Section 8. 8-Bit Timers
8.1 Overview
The H8/325 series chips include an 8-bit timer module with two channels. Each channel has an
8-bit counter (TCNT) and two time constant registers (TCORA and TCORB) that are constantly
compared with the TCNT value to detect compare-match events. One application of the 8-bit
timer module is to generate a rectangular-wave output with an arbitrary duty factor.
8.1.1 Features
The features of the 8-bit timer module are listed below.
• Selection of four clock sources
The counters can be driven by an internal clock signal (φ/8, φ/64, or φ/1024) or an external
clock input (enabling use as an external event counter).
• Selection of three ways to clear the counters
The counters can be cleared on compare-match A or B, or by an external reset signal.
• Timer output controlled by two time constants
The timer output signal in each channel is controlled by two independent time constants,
enabling the timer to generate output waveforms with an arbitrary duty factor.
• Three independent interrupts
Compare-match A and B and overflow interrupts can be requested independently.
8.1.2 Block Diagram
Figure 8-1 shows a block diagram of one channel in the 8-bit timer module. The other channel
is identical.
151
Internal
clock sources
Ø/8
Ø / 64
Ø / 1024
External
clock source
TMCI
Clock
Clock select
TCORA
Comparematch A
Comparator A
TMO
Overflow
TCNT
TMRI
Comparator B
Comparematch B
TCORB
TCSR
Internal
data bus
Module data bus
Control
logic
Bus interface
Clear
TCR
CMIA
CMIB
OVI
Interrupt signals
Legend
TCR:
TCSR:
TCORA:
TCORB:
TCNT:
Timer Control Register ( 8 bits)
Timer Control Status Register (8 bits)
Timer Constant Register A (8 bits)
Timer Constant Register B (8 bits)
Timer Counter
Figure 8-1. Block Diagram of 8-Bit Timer
8.1.3 Input and Output Pins
Table 8-1 lists the input and output pins of the 8-bit timer.
Table 8-1. Input and Output Pins of 8-Bit Timer
Abbreviation
Name
TMR0
TMR1
I/O
Function
Timer output
TMO0
TMO1
Output
Output controlled by compare-match
Timer clock input TMCI0
TMCI1
Input
External clock source for the counter
Timer reset input TMRI0
TMRI1
Input
External reset signal for the counter
152
8.1.4 Register Configuration
Table 8-2 lists the registers of the 8-bit timer module. Each channel has an independent set of
registers.
Table 8-2. 8-Bit Timer Registers
Address
Name
Abbreviation R/W
Initial value
TMR0
TMR1
Timer control register
TCR
R/W
H’00
H’FFC8
H’FFD0
Timer control/status register
TCSR
R/(W)*
H’10
H’FFC9
H’FFD1
Timer constant register A
TCORA
R/W
H’FF
H’FFCA
H’FFD2
Timer constant register B
TCORB
R/W
H’FF
H’FFCB
H’FFD3
Timer counter
TCNT
R/W
H’00
H’FFCC
H’FFD4
* Software can write a 0 to clear bits 7 to 5, but cannot write a 1 in these bits.
8.2 Register Descriptions
8.2.1 Timer Counter (TCNT) – H’FFC8 (TMR0), H’FFD0 (TMR1)
Bit
7
6
5
4
3
2
1
0
Initial value
0
0
0
0
0
0
0
0
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Each timer counter (TCNT) is an 8-bit up-counter that increments on a pulse generated from one
of four clock sources. The clock source is selected by clock select bits 2 to 0 (CKS2 to CKS0)
of the timer control register (TCR). The CPU can always read or write the timer counter.
The timer counter can be cleared by an external reset input or by an internal compare-match
signal generated at a compare-match event. Counter clear bits 1 and 0 (CCLR1 and CCLR0) of
the timer control register select the method of clearing.
When a timer counter overflows from H’FF to H’00, the overflow flag (OVF) in the timer
control/status register (TCSR) is set to 1.
The timer counters are initialized to H’00 at a reset and in the standby modes.
153
8.2.2
Time Constant Registers A and B (TCORA and TCORB) – H’FFCA and H’FFCB
(TMR0), H’FFD2 and H’FFD3 (TMR1)
Bit
7
6
5
4
3
2
1
0
Initial value
1
1
1
1
1
1
1
1
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
TCORA and TCORB are 8-bit readable/writable registers. The timer count is continually
compared with the constants written in these registers. When a match is detected, the
corresponding compare-match flag (CMFA or CMFB) is set in the timer control/status register
(TCSR).
The timer output signal (TMO0 or TMO1) is controlled by these compare-match signals as
specified by output select bits 3 to 0 (OS3 to OS0) in the timer control/status register (TCSR).
TCORA and TCORB are initialized to H’FF at a reset and in the standby modes.
Compare-match is not detected during the T3 state of a write cycle to TCORA or TCORB. See
item (3) in section 8.6, Application Notes.
8.2.3 Timer Control Register (TCR) – H’FFC8 (TMR0), H’FFD0 (TMR1)
Bit
7
6
5
4
3
2
1
0
CMIEB
CMIEA
OVIE
CCLR1
CCLR0
CKS2
CKS1
CKS0
Initial value
0
0
0
0
0
0
0
0
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
TCR is an 8-bit readable/writable register that selects the clock source and the time at which the
timer counter is cleared, and enables interrupts.
TCR is initialized to H’00 at a reset and in the standby modes.
Bit 7 – Compare-match Interrupt Enable B (CMIEB): This bit selects whether to request
compare-match interrupt B (CMIB) when compare-match flag B (CMFB) in the timer
control/status register (TCSR) is set to 1.
154
Bit 7
CMIEB
Description
0
Compare-match interrupt request B (CMIB) is disabled.
1
Compare-match interrupt request B (CMIB) is enabled.
(Initial value)
Bit 6 – Compare-match Interrupt Enable A (CMIEA): This bit selects whether to request
compare-match interrupt A (CMIA) when compare-match flag A (CMFA) in the timer
control/status register (TCSR) is set to 1.
Bit 6
CMIEA
Description
0
Compare-match interrupt request A (CMIA) is disabled.
1
Compare-match interrupt request A (CMIA) is enabled.
(Initial value)
Bit 5 – Timer Overflow Interrupt Enable (OVIE): This bit selects whether to request a timer
overflow interrupt (OVI) when the overflow flag (OVF) in the timer control/status register
(TCSR) is set to 1.
Bit 5
OVIE
Description
0
The timer overflow interrupt request (OVI) is disabled.
1
The timer overflow interrupt request (OVI) is enabled.
(Initial value)
Bits 4 and 3 – Counter Clear 1 and 0 (CCLR1 and CCLR0): These bits select how the timer
counter is cleared: by compare-match A or B or by an external reset input.
Bit 4
CCLR1
Bit 3
CCLR0
Description
0
0
Not cleared.
0
1
Cleared on compare-match A.
1
0
Cleared on compare-match B.
1
1
Cleared on rising edge of external reset input signal.
(Initial value)
Bits 2, 1, and 0 – Clock Select (CKS2, CKS1, and CKS0): These bits select the internal or
external clock source for the timer counter. For the external clock source they select whether to
increment the count on the rising or falling edge of the clock input, or on both edges. For the
internal clock sources the count is incremented on the falling edge of the clock input.
155
Bit 2 Bit 1 Bit 0
CKS2 CKS1 CKS0 Description
0
0
0
No clock source (timer stopped)
(Initial value)
0
0
1
φ/8 Internal clock source, counted on the falling edge
0
1
0
φ/64 Internal clock source, counted on the falling edge
0
1
1
φ/1024 Internal clock source, counted on the falling edge
1
0
0
No clock source (timer stopped)
1
0
1
External clock source, counted on the rising edge
1
1
0
External clock source, counted on the falling edge
1
1
1
External clock source, counted on both the rising and
falling edges
8.2.4 Timer Control/Status Register (TCSR) – H’FFC9 (TMR0), H’FFD1 (TMR1)
Bit
7
6
5
4
3
2
1
0
CMFB
CMFA
OVF
—
OS3
OS2
OS1
OS0
Initial value
0
0
0
1
0
0
0
0
Read/Write
R/(W)*
R/(W)*
R/(W)*
—
R/W
R/W
R/W
R/W
* Software can write a 0 in bits 7 to 5 to clear the flags, but cannot write a 1 in these bits.
TCSR is an 8-bit readable and partially writable register that indicates compare-match and
overflow status and selects the effect of compare-match events on the timer output signal.
TCSR is initialized to H’10 at a reset and in the standby modes.
Bit 7 – Compare-Match Flag B (CMFB): This status flag is set to 1 when the timer count
matches the time constant set in TCORB. CMFB must be cleared by software. It is set by
hardware, however, and cannot be set by software.
Bit 7
CMFB
Description
0
To clear CMFB, the CPU must read CMFB after it has been set to
1, then write a 0 in this bit.
1
This bit is set to 1 when TCNT = TCORB.
(Initial value)
Bit 6 – Compare-Match Flag A (CMFA): This status flag is set to 1 when the timer count
matches the time constant set in TCORA. CMFA must be cleared by software. It is set by
hardware, however, and cannot be set by software.
156
Bit 6
CMFA
Description
0
To clear CMFA, the CPU must read CMFA after it has been set to (Initial value)
1, then write a 0 in this bit.
1
This bit is set to 1 when TCNT = TCORA.
Bit 5 – Timer Overflow Flag (OVF): This status flag is set to 1 when the timer count
overflows (changes from H’FF to H’00). OVF must be cleared by software. It is set by
hardware, however, and cannot be set by software.
Bit 5
OVF
Description
0
To clear OVF, the CPU must read OVF after it has been set to 1, then write (Initial value)
a 0 in this bit.
1
This bit is set to 1 when TCNT changes from H’FF to H’00.
Bit 4 – Reserved: This bit is always read as 1. It cannot be written.
Bits 3 to 0 – Output Select 3 to 0 (OS3 to OS0): These bits specify the effect of comparematch events on the timer output signal. Bits OS3 and OS2 control the effect of compare-match
B on the output level. Bits OS1 and OS0 control the effect of compare-match A on the output
level.
If compare-match A and B occur simultaneously, any conflict is resolved by giving highest
priority to toggle, second-highest priority to 1 output, and third-highest priority to 0 output, as
explained in item (4) in section 8.6, Application Notes.
After a reset, the timer output is 0 until the first compare-match event.
When all four output select bits are cleared to 0 the timer output signal is disabled.
Bit 3 Bit 2
OS3 OS2 Description
0
0
No change when compare-match B occurs.
0
1
Output changes to 0 when compare-match B occurs.
1
0
Output changes to 1 when compare-match B occurs.
1
1
Output inverts (toggles) when compare-match B occurs.
(Initial value)
157
Bit 1 Bit 0
OS1 OS0 Description
0
0
No change when compare-match A occurs.
0
1
Output changes to 0 when compare-match A occurs.
1
0
Output changes to 1 when compare-match A occurs.
1
1
Output inverts (toggles) when compare-match A occurs.
(Initial value)
8.3 Operation
8.3.1 TCNT Incrementation Timing
The timer counter increments on a pulse generated once for each period of the clock source
selected by bits CKS2 to CKS0 of the TCR.
Internal Clock: Internal clock sources are created from the system clock by a prescaler. The
counter increments on an internal TCNT clock pulse generated from the falling edge of the
prescaler output, as shown in figure 8-2. Bits CKS2 to CKS0 of the TCR can select one of the
three internal clocks (φ/8, φ/64, or φ/1024).
Ø
Internal
clock
TCNT clock
pulse
TCNT
N-1
N
N+1
Figure 8-2. Count Timing for Internal Clock Input
External Clock: If external clock input (TMCI) is selected, the timer counter can increment on
the rising edge, the falling edge, or both edges of the external clock signal. Figure 8-3 shows
incrementation on both edges of the external clock signal.
The external clock pulse width must be at least 1.5 system clock periods for incrementation on a
single edge, and at least 2.5 system clock periods for incrementation on both edges. See figure
8.4. The counter will not increment correctly if the pulse width is shorter than these values.
158
Ø
External clock
source
TCNT clock
pulse
N
N-1
TCNT
N+1
Figure 8-3. Count Timing for External Clock Input
Ø
TMCI
Minimum TMCI Pulse Width
(Single-Edge Incrementation)
Ø
TMCI
Minimum TMCI Pulse Width
(Double-Edge Incrementation)
Figure 8-4. Minimum External Clock Pulse Widths (Example)
8.3.2 Compare Match Timing
(1) Setting of Compare-Match Flags A and B (CMFA and CMFB): The compare-match
flags are set to 1 by an internal compare-match signal generated when the timer count
matches the time constant in TCNT or TCOR. The compare-match signal is generated at the
last state in which the match is true, just before the timer counter increments to a new value.
159
Accordingly, when the timer count matches one of the time constants, the compare-match
signal is not generated until the next period of the clock source. Figure 8-5 shows the timing
of the setting of the compare-match flags.
Ø
TCNT
N
TCOR
N
N+1
Internal
compare-match
signal
CMF
Figure 8-5. Setting of Compare-Match Flags
(2) Timing of Compare-Match Flag (CMFA or CMFB) Clearing: The compare-match flag
CMFA or CMFB is cleared when the CPU writes a 0 in this bit.
Write cycle: CPU writes 0 in CMFA or CMFB
T1
T2
T3
Ø
CMFA
or CMFB
Figure 8-6. Clearing of Compare-Match Flags
(3) Output Timing: When a compare-match event occurs, the timer output (TMO0 or TMO1)
changes as specified by the output select bits (OS3 to OS0) in the TCSR. Depending on
these bits, the output can remain the same, change to 0, change to 1, or toggle. If comparematch A and B occur simultaneously, the higher priority compare-match determines the
output level. See item (4) in section 8.6, Application Notes for details.
160
Figure 8-7 shows the timing when the output is set to toggle on compare-match A.
Ø
Internal
compare-match
A signal
Timer output
(TMO)
Figure 8-7. Timing of Timer Output
(4) Timing of Compare-Match Clear: Depending on the CCLR1 and CCLR0 bits in the TCR,
the timer counter can be cleared when compare-match A or B occurs. Figure 8-8 shows the
timing of this operation.
Ø
Internal
compare-match
signal
N
TCNT
H'00
Figure 8-8. Timing of Compare-Match Clear
8.3.3 External Reset of TCNT
When the CCLR1 and CCLR0 bits in the TCR are both set to 1, the timer counter is cleared on
the rising edge of an external reset input. Figure 8-9 shows the timing of this operation. The
timer reset pulse width must be at least 1.5 system clock periods.
161
Ø
External reset
input (TMRI)
Internal clear
pulse
TCNT
N-1
N
H'00
Figure 8-9. Timing of External Reset
8.3.4 Setting of TCSR Overflow Flag
(1) Setting of TCSR Overflow Flag (OVF): The overflow flag (OVF) is set to 1 when the
timer count overflows (changes from H’FF to H’00). Figure 8-10 shows the timing of this
operation.
Ø
TCNT
H'FF
H'00
Internal overflow
signal
OVF
Figure 8-10. Setting of Overflow Flag (OVF)
(2) Timing of TCSR Overflow Flag (OVF) Clearing: The overflow flag (OVF) is cleared
when the CPU writes a 0 in this bit.
162
When cycle: CPU writes "0" in OVF
T1
T2
T3
Ø
OVF
Figure 8-11. Clearing of Overflow Flag
8.4 Interrupts
Each channel in the 8-bit timer can generate three types of interrupts: compare-match A and B
(CMIA and CMIB), and overflow (OVI). Each interrupt is requested when the corresponding
enable bits are set in the TCR and TCSR. Independent signals are sent to the interrupt controller
for each interrupt. Table 8-3 lists information about these interrupts.
Table 8-3. 8-Bit Timer Interrupts
Interrupt
Description
Priority
CMIA
Requested when CMFA and CMIEA are set
High
↑
CMIB
Requested when CMFB and CMIEB are set
OVI
Requested when OVF and OVIE are set
↓
Low
8.5 Sample Application
In the example below, the 8-bit timer is used to generate a pulse output with a selected duty
factor. The control bits are set as follows:
(1) In the TCR, CCLR1 is cleared to 0 and CCLR0 is set to 1 so that the timer counter is cleared
when its value matches the constant in TCORA.
(2) In the TCSR, bits OS3 to OS0 are set to 0110, causing the output to change to 1 on comparematch A and to 0 on compare-match B.
With these settings, the 8-bit timer provides output of pulses at a rate determined by TCORA
with a pulse width determined by TCORB. No software intervention is required.
163
TCNT
H'FF
Clear Counter
TCORA
TCORB
H'00
TMO pin
Figure 8-12. Example of Pulse Output
8.6 Application Notes
Application programmers should note that the following types of contention can occur in the 8bit timer.
(1) Contention between TCNT Write and Clear: If an internal counter clear signal is
generated during the T3 state of a write cycle to the timer counter, the clear signal takes
priority and the write is not performed.
Figure 8-13 shows this type of contention.
Write cycle: CPU writes to TCNT
T1
T2
T3
Ø
Internal Address
bus
TCNT address
Internal write
signal
Counter clear
signal
TCNT
N
H'00
Figure 8-13. TCNT Write-Clear Contention
164
(2) Contention between TCNT Write and Increment: If a timer counter increment pulse is
generated during the T3 state of a write cycle to the timer counter, the write takes priority
and the timer counter is not incremented.
Figure 8-14 shows this type of contention.
Write cycle: CPU writes to TCNT
T1
T2
T3
Ø
Internal Address
bus
TCNT address
Internal write
signal
TCNT clock
pulse
TCNT
N
M
Write data
Figure 8-14. TCNT Write-Increment Contention
(3) Contention between TCOR Write and Compare-Match: If a compare-match occurs
during the T3 state of a write cycle to TCORA or TCORB, the write takes precedence and
the compare-match signal is inhibited.
Figure 8-15 shows this type of contention.
165
Write cycle: CPU writes to TCORA or TCORB
T1
T2
T3
Ø
Internal address
bus
TCOR address
Internal write
signal
TCNT
TCORA or
TCORB
N
N+1
N
M
TCOR write data
Compare-match
A or B signal
Inhibited
Figure 8-15. Contention between TCOR Write and Compare-Match
(4) Contention between Compare-Match A and Compare-Match B: If identical time
constants are written in TCORA and TCORB, causing compare-match A and B to occur
simultaneously, any conflict between the output selections for compare-match A and B is
resolved by following the priority order in table 8-4.
Table 8-4. Priority of Timer Output
Output selection Priority
Toggle
High
1 Output
↑
0 Output
↑
No change
Low
(5) Incrementation Caused by Changing of Internal Clock Source: When an internal clock
source is changed, the changeover may cause the timer counter to increment. This depends
on the time at which the clock select bits (CKS2 to CKS0) are rewritten, as shown in table 85.
166
The pulse that increments the timer counter is generated at the falling edge of the internal
clock source signal. If clock sources are changed when the old source is high and the new
source is low, as in case No. 3 in table 8-5, the changeover generates a falling edge that
triggers the TCNT clock pulse and increments the timer counter.
Switching between an internal and external clock source can also cause the timer counter to
increment. This type of switching should be avoided at external clock edges.
Table 8-5. Effect of Changing Internal Clock Sources
No.
Description
Timing chart
Low → Low* :
CKS1 and CKS0 are
rewritten while both
clock sources are low.
1
1
Old clock
source
New clock
source
TCNT clock
pulse
TCNT
N
N+1
CKS rewrite
Low → High* :
CKS1 and CKS0 are
rewritten while old
clock source is low and
new clock source is high.
2
2
Old clock
source
New clock
source
TCNT clock
pulse
TCNT
N
N+1
N+2
CKS rewrite
1
* Including a transition from low to the stopped state (CKS1 = 0, CKS0 = 0), or a transition from
the stopped state to low.
2
* Including a transition from the stopped state to high.
167
Table 8-5. Effect of Changing Internal Clock Sources (cont.)
No.
Description
Timing chart
3
High → Low* :
CKS1 and CKS0 are
rewritten while old
clock source is high and
new clock source is low.
1
Old clock
source
New clock
source
*2
TCNT clock
pulse
TCNT
N
N+1
N+2
CKS rewrite
High → High:
CKS1 and CKS0 are
rewritten while both
clock sources are high.
4
Old clock
source
New clock
source
TCNT clock
pulse
TCNT
N
N+1
N+2
CKS rewrite
1
* Including a transition from high to the stopped state.
2
* The switching of clock sources is regarded as a falling edge that increments the TCNT.
168
Section 9. Serial Communication Interface
9.1 Overview
The H8/325 series chips include a serial communication interface module (SCI) with two
channels for transferring serial data to and from other chips. Either synchronous or
asynchronous communication can be selected. Communication control functions are provided
by internal registers.
9.1.1 Features
The features of the on-chip serial communication interface are:
• Asynchronous and synchronous modes
Asynchronous mode
The SCI can communicate with a UART (Universal Asynchronous
Receiver/Transmitter), ACIA (Asynchronous Communication Interface Adapter), or other
chip that employs standard asynchronous serial communication. Eight data formats are
available.
• Data length: 7 or 8 bits
• Stop bit length: 1 or 2 bits
• Parity: Even, odd, or none
• Error detection: Parity, overrun, and framing errors
Synchronous mode
The SCI can communicate with chips able to perform clocked serial data transfer.
• Data length: 8 bits
• Error detection: Overrun errors
• Full duplex communication
The transmitting and receiving sections are independent, so the SCI can transmit and receive
simultaneously. Both the transmit and receive sections use double buffering, so continuous
data transfer is possible in either direction.
• Built-in baud rate generator
Any specified baud rate can be generated.
• Internal or external clock source
The baud rate generator can operate on an internal clock source, or an external clock signal
can be input at the SCK pin.
• Three interrupts
Transmit-end, receive-end, and receive-error interrupts are requested independently.
169
9.1.2 Block Diagram
Bus interface
Module data bus
RDR
TDR
Internal
data bus
SSR
BRR
SCR
RxD
RSR
Baud rate
generator
SMR
TSR
Ø
Ø/4
Ø/16
Ø/64
Communication
control
TxD
Internal
clock
sources
Parity
generate
Clock
Parity check
External clock source
SCK
RSR:
RDR:
TSR:
TDR:
SMR:
SCR:
SSR:
BRR:
Receive Shift Register
Receive Data Register
Transmit Shift Register
Transmit Data Register
Serial Mode Register
Serial Control Register
Serial Status Register
Bit Rate Register
TXI
RXI
ERI
Interrupt signals
Figure 9-1. Block Diagram of Serial Communication Interface
9.1.3 Input and Output Pins
Table 9-1 lists the input and output pins used by the SCI module.
Table 9-1. SCI Input/Output Pins
Abbreviation
Name
Channel 0
Channel 1 I/O
Function
Serial clock
SCK0
SCK1
Input/output
Serial clock input and output.
Serial receive data
RxD0
RxD1
Input
Receive data input.
Serial transmit data TxD0
TxD1
Output
Transmit data output.
170
9.1.4 Register Configuration
Table 9-2 lists the SCI registers.
Table 9-2. SCI Registers
Channel Name
0
1
Abbreviation R/W
Initial value
Address
Receive shift register
RSR
—
—
—
Receive data register
Transmit shift register
RDR
TSR
R
—
H’00
—
H’FFDD
—
Transmit data register
Serial mode register
Serial control register
TDR
SMR
SCR
R/W
R/W
R/W
H’FF
H’04
H’0C
H’FFDB
H’FFD8
H’FFDA
Serial status register
Bit rate register
Receive shift register
Receive data register
Transmit shift register
SSR
BRR
RSR
RDR
TSR
R/(W)*
R/W
—
R
—
H’87
H’FF
—
H’00
—
H’FFDC
H’FFD9
—
H’FFE5
—
Transmit data register
Serial mode register
Serial control register
TDR
SMR
SCR
R/W
R/W
R/W
H’FF
H’04
H’0C
H’FFE3
H’FFE0
H’FFE2
Serial status register
Bit rate register
SSR
BRR
R/(W)*
R/W
H’87
H’FF
H’FFE4
H’FFE1
Notes:
* Software can write a 0 to clear the status flag bits, but cannot write a 1.
9.2 Register Descriptions
9.2.1 Receive Shift Register (RSR)
Bit
7
6
5
4
3
2
1
0
Read/W
rite
—
—
—
—
—
—
—
—
The RSR receives incoming data bits. When one data character (1 byte) has been received, it is
transferred to the receive data register (RDR).
The CPU cannot read or write the RSR directly
171
9.2.2 Receive Data Register (RDR) – H’FFDD
Bit
7
6
5
4
3
2
1
0
Initial value
Read/Write
0
R
0
R
0
R
0
R
0
R
0
R
0
R
0
R
The RDR stores received data. As each character is received, it is transferred from the RSR to
the RDR, enabling the RSR to receive the next character. This double-buffering allows the SCI
to receive data continuously.
The CPU can read but not write the RDR. The RDR is initialized to H’00 at a reset and in the
standby modes.
9.2.3 Transmit Shift Register (TSR)
Bit
7
6
5
4
3
2
1
0
Read/Write
—
—
—
—
—
—
—
—
The TSR holds the character currently being transmitted. When transmission of this character is
completed, the next character is moved from the transmit data register (TDR) to the TSR and
transmission of that character begins. If the CPU has not written the next character in the TDR,
no data are transmitted.
The CPU cannot read or write the TSR directly.
9.2.4 Transmit Data Register (TDR) – H’FFDB
Bit
7
6
5
4
3
2
1
0
Initial value
Read/Write
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
1
R/W
The TDR is an 8-bit readable/writable register that holds the next character to be transmitted.
When the TSR becomes empty, the character written in the TDR is transferred to the TSR.
Continuous data transmission is possible by writing the next byte in the TDR while the current
byte is being transmitted from the TSR.
The TDR is initialized to H’FF at a reset and in the standby modes.
172
9.2.5 Serial Mode Register (SMR) – H’FFD8
Bit
7
6
5
4
3
2
1
0
C/$
CHR
PE
O/(
STOP
—
CKS1
CKS0
Initial value
0
0
0
0
0
1
0
0
Read/Write
R/W
R/W
R/W
R/W
R/W
—
R/W
R/W
The SMR is an 8-bit readable/writable register that controls the communication format and
selects the clock rate for the internal clock source. It is initialized to H’04 at a reset and in the
standby modes.
For further information on communication formats, see tables 9-5 and 9-7 section 9.3,
Operation.
Bit 7 – Communication Mode (C/$): This bit selects the asynchronous or synchronous
communication mode.
Bit 7
C/$ Description
0
Asynchronous communication.
1
Clock-synchronized communication.
(Initial value)
Bit 6 – Character Length (CHR): This bit selects the character length in asynchronous mode.
It is ignored in synchronous mode.
Bit 6
CHR Description
0
8 Bits per character.
1
7 Bits per character.
(Initial value)
Bit 5 – Parity Enable (PE): This bit selects whether to add a parity bit in asynchronous mode.
It is ignored in synchronous mode.
Bit 5
PE
Description
0
Transmit: No parity bit is added. Receive: Parity is not checked.
1
Transmit: A parity bit is added.
Receive: Parity is checked.
(Initial value)
173
Bit 4 – Parity Mode (O/( ): In asynchronous mode, when parity is enabled (PE = 1), this bit
selects even or odd parity.
Even parity means that a parity bit is added to the data bits for each character to make the total
number of 1’s even. Odd parity means that the total number of 1’s is made odd.
This bit is ignored when PE = 0, and in the synchronous mode.
Bit 4
O/( Description
0
Even parity.
1
Odd parity.
(Initial value)
Bit 3 – Stop Bit Length (STOP): This bit selects the number of stop bits. It is ignored in the
synchronous mode.
Bit 3
STOP Description
0
1 Stop bit.
1
2 Stop bits.
(Initial value)
Bit 2 – Reserved: This bit cannot be modified and is always read as 1.
Bits 1 and 0 – Clock Select 1 and 0 (CKS1 and CKS0): These bits select the internal clock
source when the baud rate generator is clocked internally.
Bit 1 Bit 0
CKS1 CKS0 Description
0
0
φ clock
0
1
φ/4 clock
1
0
φ/16 clock
1
1
φ/64 clock
(Initial value)
For further information about SMR settings, see tables 9-5 to 9-7 in Section 9.3, Operation.
174
9.2.6 Serial Control Register (SCR) – H’FFDA
Bit
7
6
5
4
3
2
1
0
TIE
RIE
TE
RE
—
—
CKE1
CKE0
Initial value
0
0
0
0
1
1
0
0
Read/Write
R/W
R/W
R/W
R/W
—
—
R/W
R/W
The SCR is an 8-bit readable/writable register that enables or disables various SCI functions. It
is initialized to H’0C at a reset and in the standby modes.
Bit 7 – Transmit Interrupt Enable (TIE): This bit enables or disables the transmit-end
interrupt (TXI) requested when the transmit data register empty (TDRE) bit in the serial status
register (SSR) is set to 1.
Bit 7
TIE Description
0
The transmit-end interrupt request (TXI) is disabled.
1
The transmit-end interrupt request (TXI) is enabled.
(Initial value)
Bit 6 – Receive Interrupt Enable (RIE): This bit enables or disables the receive-end interrupt
(RXI) requested when the receive data register full (RDRF) bit in the serial status register (SSR)
is set to 1, and the receive error interrupt (ERI) requested when the overrun error bit (ORER),
framing error bit (FER), or parity error bit (PER) is set to 1.
Bit 6
RIE Description
0
The receive-end interrupt (RXI) request is disabled.
1
The receive-end interrupt (RXI) request is enabled.
(Initial value)
Bit 5 – Transmit Enable (TE): This bit enables or disables the transmit function. When the
transmit function is enabled, the TxD pin is automatically used for output. When the transmit
function is disabled, the TxD pin can be used as a general-purpose I/O port.
Bit 5
TE
Description
0
The transmit function is disabled.
The TxD pin can be used for general-purpose I/O.
1
The transmit function is enabled.
The TxD pin is used for output.
(Initial value)
175
Bit 4 – Receive Enable (RE): This bit enables or disables the receive function. When the
receive function is enabled, the RxD pin is automatically used for input. When the receive
function is disabled, the RxD pin is available as a general-purpose I/O port.
Bit 4
RE
Description
0
The receive function is disabled. The RxD pin can be used for generalpurpose I/O.
1
The receive function is enabled. The RxD pin is used for input.
(Initial value)
Bits 3 and 2 – Reserved: These bits cannot be modified and are always read as 1.
Bit 1 – Clock Enable 1 (CKE1): This bit selects the internal or external clock source for the
baud rate generator. When the external clock source is selected, the SCK pin is automatically
used for input of the external clock signal.
Bit 1
CKE1 Description
0
Internal clock source.
When C/$ = 1, the clock is output at SCK.
When C/$ = 0, clock output depends on CKE0.
1
External clock source, input at SCK.
(Initial value)
Bit 0 – Clock Enable 0 (CKE0): When an internal clock source is used in asynchronous mode,
this bit enables or disables serial clock output at the SCK pin.
This bit is ignored when the external clock is selected, or when the synchronous mode is
selected.
Bit 0
CKE0 Description
0
The SCK pin is not used by the SCI (and is available as a general-purpose
I/O port).
1
The SCK pin is used for serial clock output.
(Initial value)
For further information on clock source selection, see table 9-6 in Section 9.3, Operation.
176
9.2.7 Serial Status Register (SSR) – H’FFDC
Bit
7
6
5
4
3
2
1
0
TDRE
RDRF
ORER
FER
PER
—
—
—
Initial value
1
0
0
0
0
1
1
1
Read/Write
R/(W)*
R/(W)*
R/(W)*
R/(W)*
R/(W)*
—
—
—
* Software can write a 0 to clear the flags, but cannot write a 1 in these bits.
The SSR is an 8-bit register that indicates transmit and receive status. It is initialized to H’87 at
a reset and in the standby modes.
Bit 7 – Transmit Data Register Empty (TDRE): This bit indicates when the TDR contents
have been transferred to the TSR and the next character can safely be written in the TDR.
Bit 7
TDRE Description
0
To clear TDRE, the CPU must read TDRE after it has been set to 1, then
write a 0 in this bit.
1
This bit is set to 1 at the following times:
(1) When TDR contents are transferred to the TSR.
(2) When the TE bit in the SCR is cleared to 0.
(Initial value)
Bit 6 – Receive Data Register Full (RDRF): This bit indicates when one character has been
received and transferred to the RDR.
Bit 6
RDRF Description
0
To clear RDRF, the CPU must read RDRF after it has been set to 1,
then write a 0 in this bit.
1
This bit is set to 1 when one character is received without error and
transferred from the RSR to the RDR.
(Initial value)
177
Bit 5 – Overrun Error (ORER): This bit indicates an overrun error during reception.
Bit 5
ORER Description
0
To clear ORER, the CPU must read ORER after it has been set to 1,
then write a 0 in this bit.
1
This bit is set to 1 if reception of the next character ends while the
receive data register is still full (RDRF = 1).
(Initial value)
Bit 4 – Framing Error (FER): This bit indicates a framing error during data reception in asynchronous mode. It has no meaning in synchronous mode.
Bit 4
FER Description
0
To clear FER, the CPU must read FER after it has been set to 1, then
write a 0 in this bit.
1
This bit is set to 1 if a framing error occurs (stop bit = 0).
(Initial value)
Bit 3 – Parity Error (PER): This bit indicates a parity error during data reception in asynchronous mode, when a communication format with parity bits is used.
This bit has no meaning in synchronous mode, or when a communication format without parity
bits is used.
Bit 3
PER Description
0
To clear PER, the CPU must read PER after it has been set to 1, then
write a 0 in this bit.
1
This bit is set to 1 when a parity error occurs (the parity of the received
data does not match the parity selected by the O/( bit
in the SMR).
Bits 2 to 0 – Reserved: These bits cannot be modified and are always read as 1.
178
(Initial value)
9.2.8 Bit Rate Register (BRR) – H’FFD9
Bit
7
6
5
4
3
2
1
0
Initial value
1
1
1
1
1
1
1
1
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
The BRR is an 8-bit register that, together with the CKS1 and CKS0 bits in the SMR, determines
the baud rate output by the baud rate generator.
The BRR is initialized to H’FF (the slowest rate) at a reset and in the standby modes.
Tables 9-3 and 9-4 show examples of BRR (N) and CKS (n) settings for commonly used bit
rates.
Table 9-3. Examples of BRR Settings in Asynchronous Mode (1)
XTAL Frequency (MHz)
2
Bit
rate
n
110
2.4576
4
N
Error
(%)
n
N
Error
(%)
1
70
+0.03
1
86
150
0
207 +0.16
0
300
0
103 +0.16
600
0
51
1200 0
2400 0
4.194304
N
Error
(%)
n
N
Error
(%)
+0.31 1
141
+0.03
1
148
–0.04
255
0
1
103
+0.16
1
108
+0.21
0
127
0
0
207
+0.16
0
217
+0.21
+0.16
0
63
0
0
103
+0.16
0
108
+0.21
25
+0.16
0
31
0
0
51
+0.16
0
54
–0.70
12
+0.16
0
15
0
0
25
+0.16
0
26
+1.14
4800 — —
—
0
7
0
0
12
+0.16
0
13
–2.48
9600 — —
—
0
3
0
—
—
—
—
—
—
19200 — —
—
0
1
0
—
—
—
—
—
—
31250 — —
—
—
—
—
0
1
0
—
—
—
38400 — —
—
0
0
0
—
—
—
—
—
—
n
179
Table 9-3. Examples of BRR Settings in Asynchronous Mode (2)
XTAL Frequency (MHz)
4.9152
6
Bit
rate
n
N
Error
(%)
110
1
174
150
1
300
0
600
7.3728
8
N
Error
(%)
n
N
Error
(%)
n
N
Error
(%)
–0.26 2
52
+0.50
2
64
+0.70
2
70
+0.03
127
0
1
155
+0.16
1
191
0
1
207 +0.16
255
0
1
77
+0.16
1
95
0
1
103 +0.16
0
127
0
0
155
+0.16
0
191
0
0
207 +0.16
1200
0
63
0
0
77
+0.16
0
95
0
0
103 +0.16
2400
0
31
0
0
38
+0.16
0
47
0
0
51
+0.16
4800
0
15
0
0
19
–2.34
0
23
0
0
25
+0.16
9600
0
7
0
—
—
—
0
11
0
0
12
+0.16
19200 0
3
0
—
—
—
0
5
0
—
—
—
31250 —
—
—
0
2
0
—
—
—
0
3
0
38400 0
1
0
—
—
—
0
2
0
—
—
—
n
Table 9-3. Examples of BRR Settings in Asynchronous Mode (3)
XTAL Frequency (MHz)
9.8304
Bit
rate
n
N
Error
(%)
110
2
86
150
1
300
10
12.288
N
Error
(%)
n
N
Error
(%)
n
N
Error
(%)
+0.31 2
88
–0.25
2
106 –0.44
2
108
+0.08
255
0
2
64
+0.16
2
77
0
2
79
0
1
127
0
1
129
+0.16
1
155 0
1
159
0
600
0
255
0
1
64
+0.16
1
77
1
79
0
1200
0
127
0
0
129
+0.16
0
155 +0.16
0
159
0
2400
0
63
0
0
64
+0.16
0
77
+0.16
0
79
0
4800
0
31
0
0
32
–1.36
0
38
+0.16
0
39
0
9600
0
15
0
0
15
+1.73
0
19
–2.34
0
19
0
19200 0
7
0
0
7
+1.73
—
—
—
0
4
0
31250 0
4
–1.70 0
4
0
0
5
0
0
5
+2.40
38400 0
3
0
3
+1.73
—
—
—
—
—
—
180
n
12
0
0
Table 9-3. Examples of BRR Settings in Asynchronous Mode (4)
XTAL Frequency (MHz)
14.7456
Bit
rate n
16
Error
(%)
N
19.6608
20
n
N
Error
(%)
n
N
Error
(%)
n
N
Error
(%)
110 2
13 –0.07
0
2
141
+0.03
2
174
–0.26
3
43
+0.88
150 2
95 0
2
103
+0.16
2
127
0
2
129
+0.16
300 1
19 0
1
1
207
+0.16
1
255
0
2
64
+0.16
600 1
95 0
1
103
+0.16
1
127
0
1
129
+0.16
1200 0
19 0
1
0
207
+0.16
0
255
0
1
64
+0.16
2400 0
95 0
0
103
+0.16
0
127
0
0
129
+0.16
4800 0
47 0
0
51
+0.16
0
63
0
0
64
+0.16
9600 0
23 0
0
25
+0.16
0
31
0
0
32
–1.36
1920 0
0
11 0
0
12
+0.16
0
15
0
0
15
+1.73
3125 — — —
0
0
7
0
0
9
–1.70
0
9
0
3840 0
0
—
—
—
0
7
0
0
7
+1.73
5
0
Note: If possible, the error should be within 1%.
B = OSC × 106/[64 × 22n × (N + 1)]
N: BRR value (0 ≤ N ≤ 255)
OSC: Crystal oscillator frequency in MHz
B: Bit rate (bits/second)
n: Internal clock source (0, 1, 2, or 3)
The meaning of n is given by the table below:
n
CKS1 CKS0 Clock
0
0
0
φ
1
0
1
φ/4
2
1
0
φ/16
3
1
1
φ/64
181
Table 9-4. Examples of BRR Settings in Synchronous Mode
XTAL Frequency (MHz)
2
Bit
rate
n
100
N
4
8
10
16
20
n
N
n
N
n
N
n
N
n
N
— —
—
—
—
—
—
—
—
—
—
—
250
1
249
2
124
2
249
—
—
3
124
—
—
500
1
124
1
249
2
124
—
—
2
249
—
—
1k
0
249
1
124
1
249
—
—
2
124
—
—
2.5k
0
99
0
199
1
99
1
124
1
199
1
249
5k
0
49
0
99
0
199
0
249
1
99
1
124
10k
0
24
0
49
0
99
0
124
0
199
0
249
25k
0
9
0
19
0
39
0
49
0
79
0
99
50k
0
4
0
9
0
19
0
24
0
39
0
49
100k — —
0
4
0
9
—
—
0
19
0
24
250k 0
0
1
0
3
0
4
0
7
0
9
0
0*
0
1
—
—
0
3
0
4
0
0*
—
—
0
1
—
—
0
0*
0*
500k
1M
2.5M
Notes:
Blank: No setting is available.
—: A setting is available, but the bit rate is inaccurate.
*: Continuous transfer is not possible.
B = OSC × 106/[8 × 22n × (N + 1)]
N: BRR value (0 ≤ N ≤ 255)
OSC: Crystal oscillator frequency in MHz
B: Bit rate (bits per second)
n: Internal clock source (0, 1, 2, or 3)
The meaning of n is given by the table below:
n
CKS1 CKS0 Clock
0
0
0
φ
1
0
1
φ/4
2
1
0
φ/16
3
1
1
φ/64
182
9.3 Operation
9.3.1 Overview
The SCI supports serial data transfer in both asynchronous and synchronous modes.
The communication format depends on settings in the SMR as indicated in table 9-5. The clock
source and usage of the SCK pin depend on settings in the SMR and SCR as indicated in table 96.
Table 9-5. Communication Formats Used by SCI
SMR
C/$
CHR
PE
STOP
0
0
0
0
Mode
1
8-Bit data
0
1
0
1
Yes
—
None
7-Bit data
0
—
—
1
1
2
1
2
Yes
1
—
—
1
1
Stop bit
length
2
Asynchronou
s
0
1
Parity
None
1
1
Format
2
Synchronous 8-Bit data
Table 9-6. SCI Clock Source Selection
SMR
C/$
SCR
CKE1 CKE0 Clock source
0
0
(Async
mode)
1
0
1
Internal
0
External
SCK pin
Input/output port*
Serial clock output
at bit rate
Serial clock input
at 16 × bit rate
1
1
(Sync
mode)
0
1
0
1
Internal
0
External
1
* Not used by the SCI.
Serial clock output
Serial clock input
183
Transmitting and receiving operations in the two modes are described next.
9.3.2 Asynchronous Mode
In asynchronous mode, each character is individually synchronized by framing it with a start bit
and stop bit.
Full duplex data transfer is possible because the SCI has independent transmit and receive
sections. Double buffering in both sections enables the SCI to be programmed for continuous
data transfer.
Figure 9-2 shows the general format of one character sent or received in the asynchronous mode.
The communication channel is normally held in the mark state (high). Character transmission or
reception starts with a transition to the space state (low).
The first bit transmitted or received is the start bit (low). It is followed by the data bits, in which
the least significant bit (LSB) comes first. The data bits are followed by the parity bit, if
present, then the stop bit or bits (high) confirming the end of the frame.
˜˜
In receiving, the SCI synchronizes on the falling edge of the start bit, and samples each bit at the
center of the bit (at the 8th cycle of the internal serial clock, which runs at 16 times the bit rate).
D0
D1
Dn
Parity bit
Stop bit
˜˜
Start bit
1 bit
7 or 8 bits
0 or1 bit
1or 2 bits
One character
Figure 9-2. Data Format in Asynchronous Mode
(1) Data Format: Table 9-7 lists the data formats that can be sent and received in
asynchronous mode. Eight formats can be selected by bits in the SMR.
184
Idle state
(mark)
Table 9-7. Data Formats in Asynchronous Mode
SMR bits
CHR
PE
STOP Data format
0
0
0
START
8-Bit data
STOP
0
0
1
START
8-Bit data
STOP
STOP
0
1
0
START
8-Bit data
P
STOP
0
1
1
START
8-Bit data
P
STOP
1
0
0
START
7-Bit data
STOP
1
0
1
START
7-Bit data
STOP
STOP
1
1
0
START
7-Bit data
P
STOP
1
1
1
START
7-Bit data
P
STOP
STOP
STOP
Note
START: Start bit
STOP: Stop bit
P: Parity bit
(2) Clock: In asynchronous mode it is possible to select either an internal clock created by the
on-chip baud rate generator, or an external clock input at the SCK pin. Refer to table 9-6.
If an external clock is input at the SCK pin, its frequency should be 16 times the desired baud
rate.
If the internal clock provided by the on-chip baud rate generator is selected and the SCK pin
is used for clock output, the output clock frequency is equal to the baud rate, and the clock
pulse rises at the center of the transmit data bits. Figure 9-3 shows the phase relationship
between the output clock and transmit data.
Output clock
Transmit data
Start bit
D1
D2
D3
Figure 9-3. Phase Relationship between Clock Output and Transmit Data
185
(3) Data Transmission and Reception
SCI Initialization: Before data can be transmitted or received, the SCI must be
initialized by software. To initialize the SCI, software must clear the TE and RE bits to
0, then execute the following procedure.
[1] Set the desired communication format in the SMR.
[2] Write the value corresponding to the desired baud rate in the BRR. (This step is not
necessary if an external clock is used.)
[3] Select the clock and enable desired interrupts in the SCR.
[4] Set the TE and/or RE bit in the SCR to 1.
The TE and RE bits must both be cleared to 0 whenever the operating mode or data format is
changed.
After changing the operating mode or data format, before setting the TE and RE bits to 1
software must wait for at least the transfer time for 1 bit at the selected baud rate, to make
sure the SCI is initialized. If an external clock is used, the clock must not be stopped.
When clearing the TDRE bit during data transmission, to assure transfer of the correct data,
do not clear the TDRE bit until after writing data in the TDR. Similarly, in receiving data,
do not clear the RDRF bit until after reading data from the RDR.
Data Transmission: The procedure for transmitting data is as follows.
[1] Set up the desired transmitting conditions in the SMR, SCR, and BRR.
[2] Set the TE bit in the SCR to 1.
The TxD pin will automatically be switched to output and one frame* of all 1’s will be
transmitted, after which the SCI is ready to transmit data.
[3] Check that the TDRE bit is set to 1, then write the first byte of transmit data in the
TDR. Next clear the TDRE bit to 0.
186
[4] The first byte of transmit data is transferred from the TDR to the TSR and sent in the
designated format as follows.
i) Start bit (one 0 bit).
ii) Transmit data (seven or eight bits, starting from bit 0)
iii) Parity bit (odd or even parity bit, or no parity bit)
iv) Stop bit (one or two consecutive 1 bits)
[5] Transfer of the transmit data from the TDR to the TSR makes the TDR empty, so the
TDRE bit is set to 1.
If the TIE bit is set to 1, a transmit-end interrupt (TXI) is requested.
When the transmit function is enabled but the TDR is empty (TDRE = 1), the output
at the TxD pin is held at 1 until the TDRE bit is cleared to 0.
* A frame is the data for one character, including the start bit and stop bit(s).
Data Reception: The procedure for receiving data is as follows.
[1] Set up the desired receiving conditions in the SMR, SCR, and BRR.
[2] Set the RE bit in the SCR to 1.
The RxD pin is automatically be switched to input and the SCI is ready to receive
data.
[3] The SCI synchronizes with the incoming data by detecting the start bit, and places the
received bits in the RSR. At the end of the data, the SCI checks that the stop bit is 1.
[4] When a complete frame has been received, the SCI transfers the received data from
the RSR to the RDR so that it can be read. If the character length is 7 bits, the most
significant bit of the RDR is cleared to 0.
At the same time, the SCI sets the RDRF bit in the SSR to 1. If the RIE bit is set to 1,
a receive-end interrupt (RXI) is requested.
[5] The RDRF bit is cleared to 0 when software reads the SSR, then writes a 0 in the
RDRF bit. The RDR is then ready to receive the next character from the RSR.
When a frame is not received correctly, a receive error occurs. There are three types
of receive errors, listed in table 9-8.
If a receive error occurs, the RDRF bit in the SSR is not set to 1. (For an overrun
error, RDRF is already set to 1.) The corresponding error flag is set to 1 instead. If
the RIE bit in the SCR is set to 1, a receive-error interrupt (ERI) is requested.
When a framing or parity error occurs, the RSR contents are transferred to the RDR. If
an overrun error occurs, however, the RSR contents are not transferred to the RDR.
187
If multiple receive errors occur simultaneously, all the corresponding error flags are set to
1.
To clear a receive-error flag (ORER, FER, or PER), software must read the SSR and then
write a 0 in the flag bit.
Table 9-8. Receive Errors
Name
Abbreviation Description
Overrun error ORER
Reception of the next frame ends while the RDRF bit is still set to
1. The RSR contents are not transferred to the RDR.
Framing error FER
A stop bit is 0.
The RSR contents are transferred to the RDR.
Parity error
The parity of a frame does not match the value
selected by the O/( bit in the SMR.
The RSR contents are transferred to the RDR.
PER
9.3.3 Synchronous Mode
The synchronous mode is suited for high-speed, continuous data transfer. Each bit of data is
synchronized with a serial clock pulse at the SCK pin.
Continuous data transfer is enabled by the double buffering employed in both the transmit and
receive sections of the SCI. Full duplex communication is possible because the transmit and
receive sections are independent.
(1) Data Format: Figure 9-4 shows the communication format used in the synchronous mode.
The data length is 8 bits for both the transmit and receive directions. The least significant bit
(LSB) is sent and received first. Each bit of transmit data is output from the falling edge of
the serial clock pulse to the next falling edge. Received bits are latched on the rising edge of
the serial clock pulse.
188
Transmission direction
Serial clock
Data
Bit 0
Bit 1
Bit 2
Bit 3
Bit 4
Bit 5
Bit 6
Don't - care
Bit 7
Don't - care
Figure 9-4. Data Format in Synchronous Mode
(2) Clock: Either the internal serial clock created by the on-chip baud rate generator or an
external clock input at the SCK pin can be selected in the synchronous mode. See table 9-6
for details.
(3) Data Transmission and Reception
SCI Initialization: Before data can be transmitted or received, the SCI must be
initialized by software. To initialize the SCI, software must clear the TE and RE bits to 0
to disable both the transmit and receive functions, then execute the following procedure.
[1] Write the value corresponding to the desired bit rate in the BRR. (This step is not
necessary if an external clock is used.)
[2] Select the clock and enable desired interrupts in the SCR. Leave bit 0 (CKE0) cleared
to 0.
[3] Select synchronous mode in the SMR.
[4] Set the TE and/or RE bit in the SCR to 1.
The TE and RE bits must both be cleared to 0 whenever the operating mode or data
format is changed. After changing the operating mode or data format, before setting the
TE and RE bits to 1 software must wait for at least 1 bit transfer time at the selected
communication speed, to make sure the SCI is initialized.
189
When clearing the TDRE bit during data transmission, to assure correct data transfer, do
not clear the TDRE bit until after writing data in the TDR. Similarly, in receiving data,
do not clear the RDRF bit until after reading data from the RDR.
Data Transmission: The procedure for transmitting data is as follows.
[1] Set up the desired transmitting conditions in the SMR, BRR, and SCR.
[2] Set the TE bit in the SCR to 1.
The TxD pin will automatically be switched to output, after which the SCI is ready to
transmit data.
[3] Check that the TDRE bit is set to 1, then write the first byte of transmit data in the
TDR. Next clear the TDRE bit to 0.
[4] The first byte of transmit data is transferred from the TDR to the TSR and sent, each
bit synchronized with a clock pulse. Bit 0 is sent first.
Transfer of the transmit data from the TDR to the TSR makes the TDR empty, so the
TDRE bit is set to 1. If the TIE bit is set to 1, a transmit-end interrupt (TXI) is requested.
The TDR and TSR function as a double buffer. Continuous data transmission can be
achieved by writing the next transmit data in the TDR and clearing the TDRE bit to 0
while the SCI is transmitting the current data from the TSR.
If an internal clock source is selected, after transferring the transmit data from the TDR to
the TSR, while transmitting the data from the TSR the SCI also outputs a serial clock
signal at the SCK pin. When all data bits in the TSR have been transmitted, if the TDR is
empty (TDRE = 1), serial clock output is suspended until the next data byte is written in
the TDR and the TDRE bit is cleared to 0. During this interval the TxD pin continues to
output the value of the last bit of the previous data.
If the external clock source is selected, data transmission is synchronized with the clock
signal input at the SCK pin. When all data bits in the TSR have been transmitted, if the
TDR is empty (TDRE = 1) but external clock pulses continue to arrive, the TxD pin
outputs the value of last bit of the previous data.
Data Reception: The procedure for receiving data is as follows.
190
[1] Set up the desired receiving conditions in the SMR, BRR, and SCR.
[2] Set the RE bit in the SCR to 1.
The RxD pin is automatically be switched to input and the SCI is ready to receive
data.
[3] Incoming data bits are latched in the RSR on eight clock pulses.
When 8 bits of data have been received, the SCI sets the RDRF bit in the SSR to 1. If
the RIE bit is set to 1, a receive-end interrupt (RXI) is requested.
[4] The SCI transfers the received data byte from the RSR to the RDR so that it can be
read.
The RDRF bit is cleared when software reads the RDRF bit in the SSR, then writes a
0 in the RDRF bit.
The RDR and RSR function as a double buffer. Data can be received continuously by
reading each byte of data from the RDR and clearing the RDRF bit to 0 before the last bit
of the next byte is received.
In general, an external clock source should be used for receiving data.
If an internal clock source is selected, the SCI starts receiving data as soon as the RE bit
is set to 1. The serial clock is also output at the SCK pin. The SCI continues receiving
until the RE bit is cleared to 0.
If the last bit of the next data byte is received while the RDRF bit is still set to 1, an
overrun error occurs and the ORER bit is set to 1. If the RIE bit is set to 1, a receiveerror interrupt (ERI) is requested. The data received in the RSR are not transferred to the
RDR when an overrun error occurs.
After an overrun error, reception of the next data is enabled when the ORER bit is cleared
to 0.
Simultaneous Transmit and Receive: The procedure for transmitting and receiving
simultaneously is as follows:
[1] Set up the desired communication conditions in the SMR, BRR, and SCR.
[2] Set the TE and RE bits in the SCR to 1.
The TxD and RxD pins are automatically switched to output and input, respectively,
and the SCI is ready to transmit and receive data.
191
[3] Data transmitting and receiving start when the TDRE bit in the SSR is cleared to 0.
[4] Data are sent and received in synchronization with eight clock pulses.
[5] First, the transmit data are transferred from the TDR to the TSR. This makes the
TDR empty, so the TDRE bit is set to 1. If the TIE bit is set to 1, a transmit-end
interrupt (TXI) is requested.
If continuous data transmission is desired, software must read the TDRE bit in the
SSR, write the next transmit data in the TDR, then clear the TDRE bit to 0.
If the TDRE bit is not cleared to 0 by the time the SCI finishes sending the current
byte from the TSR, the TxD pin continues to output the value of last bit of the
previous data.
[6] In the receiving section, when 8 bits of data have been received they are transferred
from the RSR to the RDR and the RDRF bit in the SSR is set to 1. If the RIE bit is
set to 1, a receive-end interrupt (RXI) is requested.
[7] To clear the RDRF bit software should read the RDRF bit in the SSR, read the data in
the RDR, then write a 0 in the RDRF bit.
For continuous data reception, software should clear the RDRF bit to 0 before
reception of the next 8 bits is completed.
If the last bit of the next byte is received while the RDRF bit is still set to 1, an overrun
error occurs. The error is handled as described under “Data Reception” above. The
overrun error does not affect the transmit section of the SCI, which continues to transmit
normally.
9.4 Interrupts
The SCI can request three types of interrupts: transmit-end (TXI), receive-end (RXI), and
receive-error (ERI). Interrupt requests are enabled or disabled by the TIE and RIE bits in the
SCR. Independent signals are sent to the interrupt controller for each type of interrupt. The
transmit-end and receive-end interrupt request signals are obtained from the TDRE and RDRF
flags. The receive-error interrupt request signal is the logical OR of the three error flags:
overrun error (ORER), framing error (FER), and parity error (PER). Table 9-9 lists information
about these interrupts.
192
Table 9-9. SCI Interrupts
Interrupt Description
Priority
ERI
High
Receive-error interrupt, requested when ORER, FER, or PER is set.
RIE must also be set.
RXI
Receive-end interrupt, requested when RDRF and RIE are set.
TXI
Transmit-end interrupt, requested when TDRE and TIE are set.
↑
↓
Low
9.5 Application Notes
Application programmers should note the following features of the SCI.
(1) TDR Write: The TDRE bit in the SSR is simply a flag that indicates that the TDR contents
have been transferred to the TSR. The TDR contents can be rewritten regardless of the
TDRE value. If a new byte is written in the TDR while the TDRE bit is 0, before the old
TDR contents have been moved into the TSR, the old byte will be lost. Normally, software
should check that the TDRE bit is set to 1 before writing to the TDR.
(2) Multiple Receive Errors: Table 9-10 lists the values of flag bits in the SSR when multiple
receive errors occur, and indicates whether the RSR contents are transferred to the RDR.
Table 9-10. SSR Bit States and Data Transfer When Multiple Receive Errors Occur
SSR Bits
ORER
FER
PER
RSR → RDR*
1*
1
0
0
No
Framing error
0
0
1
0
Yes
Parity error
0
Receive error
RDRF
Overrun error
1
2
0
0
1
Yes
1*
1
1
1
0
No
Overrun + parity errors
1*
1
1
0
1
No
Framing + parity errors
0
0
1
1
Yes
1
1
1
No
Overrun + framing errors
Overrun + framing + parity errors
1
1*
1
* Set to 1 before the overrun error occurs.
2
* Yes: The RSR contents are transferred to the RDR.
No: The RSR contents are not transferred to the RDR.
193
(3) Line Break Detection: When the RxD pin receives a continuous stream of 0’s in asynchronous mode (line-break state), a framing error occurs because the SCI detects a 0 stop bit.
The value H’00 is transferred from the RSR to the RDR. Software can detect the line-break
state as a framing error accompanied by H’00 data in the RDR.
The SCI continues to receive data, so if the FER bit is cleared to 0 another framing error will
occur.
(4) Sampling Timing and Receive Margin in Asynchronous Mode: The serial clock used by
the SCI in asynchronous mode runs at 16 times the baud rate. The falling edge of the start
bit is detected by sampling the RxD input on the falling edge of this clock. After the start bit
is detected, each bit of receive data in the frame (including the start bit, parity bit, and stop
bit or bits) is sampled on the rising edge of the serial clock pulse at the center of the bit. See
figure 9-6.
It follows that the receive margin can be calculated as in equation (1).
When the absolute frequency deviation of the clock signal is 0 and the clock duty factor is
0.5, data can theoretically be received with distortion up to the margin given by equation (2).
This is a theoretical limit, however. In practice, system designers should allow a margin of
20% to 30%.
194
0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 1 2 3 4 5
Basic clock
-7.5 pulses
+7.5 pulses
Receive data
Start bit
D0
D1
Sync sampling
Data sampling
Figure 9-5. Sampling Timing (Asynchronous Mode)
M = { (0.5 – 1/2N) – (D – 0.5)/N – (L – 0.5)F}
×
100 [%]
(1)
M: Receive margin
N: Ratio of basic clock to baud rate (N = 16)
D: Duty factor of clock—ratio of high pulse width to low width (0.5 to 1.0)
L: Frame length (9 to 12)
F: Absolute clock frequency deviation
When D = 0.5 and F= 0
M = (0.5 – 1/2 × 16) × 100 [%] = 46.875%
(2)
195
196
Section 10. RAM
10.1 Overview
The H8/3257 and H8/3256 have 2 Kbytes of on-chip static RAM, H8/325 and H8/324 have 1
Kbyte, the H8/323 has 512 bytes, and the H8/322 has 256 bytes. The on-chip RAM is connected
to the CPU by a 16-bit data bus. Both byte and word access to the on-chip RAM are performed
in two states, enabling rapid data transfer and instruction execution.
The on-chip RAM occupies the following addresses in the chip’s address space.
H8/3257, H8/3256: H'F780 to H'FF7F
H8/325, H8/324: H'FB80 to H'FF7F
H8/323: H'FD80 to H'FF7F
H8/322: H'FE80 to H'FF7F
The RAME bit in the system control register (SYSCR) can enable or disable the on-chip RAM,
permitting these addresses to be allocated to external memory instead, if so desired.
10.2 Block Diagram
Figure 10-1 is a block diagram of the on-chip RAM.
Internal data bus (upper 8 bits)
Internal data bus (lower 8 bits)
Address
H'F780
H'F780
H'F781
H'F782
H'F782
H'F783
On-chip RAM
H'FF7E
H'FF7E
H'FF7F
Even address
Odd address
Figure 10-1. Block Diagram of On-Chip RAM (H8/3257)
197
10.3 RAM Enable Bit (RAME)
The on-chip RAM is enabled or disabled by the RAME (RAM Enable) bit in the system control
register (SYSCR). Table 10-1 lists information about the system control register.
Table 10-1. System Control Register
Name
Abbreviation
R/W
Initial value
Address
System control register
SYSCR
R/W
H’0B
H’FFC4
Bit
7
6
5
4
3
2
1
0
SSBY
STS2
STS1
STS0
—
NMIEG
—
RAME
Initial value
0
0
0
0
1
0
1
1
Read/Write
R/W
R/W
R/W
R/W
—
R/W
—
R/W
The only bit in the system control register that concerns the on-chip RAM is the RAME bit.
See section 2.4.2, System Control Register for the other bits.
Bit 0 – RAM Enable (RAME): This bit enables or disables the on-chip RAM.
The RAME bit is initialized to 1 on the rising edge of the 5(6 signal, so a reset enables the onchip RAM. The RAME bit is not initialized in the software standby mode.
Bit 7
RAME
Description
0
On-chip RAM is disabled.
1
On-chip RAM is enabled.
(Initial value)
10.4 Operation
10.4.1 Expanded Modes (Modes 1 and 2)
If the RAME bit is set to 1, accesses to the following addresses are directed to the on-chip RAM.
H8/3257, H8/3256: H'F780 to H'FF7F
H8/325, H8/324: H'FB80 to H'FF7F
H8/323: H'FD80 to H'FF7F
H8/322: H'FE80 to H'FF7F
If the RAME bit is cleared to 0, accesses to these addresses are directed to the external data bus.
198
10.4.2 Single-Chip Mode (Mode 3)
If the RAME bit is set to 1, accesses to the following addresses are directed to the on-chip RAM.
H8/3257, H8/3256: H'F780 to H'FF7F
H8/325, H8/324: H'FB80 to H'FF7F
H8/323: H'FD80 to H'FF7F
H8/322: H'FE80 to H'FF7F
If the RAME bit is cleared to 0, the on-chip RAM data cannot be accessed. Attempted write
access has no effect. Attempted read access always results in H’FF data being read.
199
200
Section 11. ROM
11.1 Overview
The H8/3257 has 60 Kbytes of high-speed, on-chip ROM. The H8/3256 has 48 Kbytes. The
H8/325 has 32 Kbytes. The H8/324 has 24 Kbytes. The H8/323 has 16 Kbytes. The H8/322
has 8 Kbytes. The on-chip ROM is connected to the CPU via a 16-bit data bus. Both byte data
and word data are accessed in two states, enabling rapid data transfer and instruction fetching.
The H8/3257, H8/3256, H8/325, H8/323, and H8/322 are available in two versions: one with
electrically programmable ROM (PROM); the other with masked ROM. The PROM version has
a PROM mode in which the chip can be programmed with a standard PROM writer.
The on-chip ROM is enabled or disabled depending on the MCU operating mode, which is
determined by the inputs at the mode pins (MD1 and MD0) when the chip comes out of the reset
state. See table 11-1.
Table 11-1. On-Chip ROM Usage in Each MCU Mode
Mode pins
Mode
MD1
MD0
On-chip ROM
Mode 1 (expanded mode)
0
1
Disabled (external addresses)
Mode 2 (expanded mode)
1
0
Enabled
Mode 3 (single-chip mode) 1
1
Enabled
201
11.1.1 Block Diagram
Figure 11-1 is a block diagram of the on-chip ROM.
Internal data bus (upper 8 bits)
Internal data bus (lower 8 bits)
H'0000
H'0001
H'0002
H'0003
On-chip ROM
H'EFFE
Even addresses
H'EFFF
Odd addresses
Figure 11-1. Block Diagram of On-Chip ROM (H8/3257)
11.2 PROM Mode
11.2.1 PROM Mode Setup
In the PROM mode of the PROM version of the H8/3257 and H8/3256, the usual microcomputer
functions are halted to allow the on-chip PROM to be programmed. The programming method
is the same as for the HN27C101. In the PROM mode of the PROM version of the H8/325,
H8/323, and H8/322 the usual microcomputer functions are halted to allow the on-chip PROM to
be programmed. The programming method is the same as for the HN27C256.
To select the PROM mode, apply the signal inputs listed in table 11-2.
Table 11-2. Selection of PROM Mode
Pin
Input
Mode pin MD1
Low
Mode pin MD0
Low
67%< pin
Low
Pins P70 and P71
High
202
11.2.2 Socket Adapter Pin Assignments and Memory Map
The H8/3257, H8/3256, H8/325, H8/323, and H8/322 can be programmed with a generalpurpose PROM writer. Since the microcontroller package has 64 pins instead of 28 or 32 pins, a
socket adapter is necessary. Table 11-3 lists recommended socket adapters. Figures 11-2 and 113 show the socket adapter pin assignments by giving the correspondence between
microcontroller pins and HN27C101 or HN27C256 pin functions.
Figures 11-4 to 11-8 show memory maps in PROM mode. Since the H8/3257 has 60 Kbytes of
on-chip PROM, the address range should be specified as H’0000 to H’EFFF. H’FF data should
be specified for unused address areas.
The H8/3256 has only 48 Kbytes of PROM. The H8/325 has only 32 Kbytes. The H8/323 has
only 16 Kbytes. The H8/322 has only 8 Kbytes. When programming these microcontrollers with
a PROM writer, specify an address range of H’0000 to H’BFFF for the H8/3256, H’0000 to
H’7FFF for the H8/325, H’0000 to H’3FFF for the H8/323, or H’0000 to H’1FFF for the H8/322.
Specify H’FF data for addresses equal to or greater than H’C000 (H8/3256), H’8000 (H8/325),
H’4000 (H8/323) or H’2000 (H8/322). Also specify H’FF data for unused address areas. If these
areas are programmed by mistake, it may become impossible to write or verify PROM data. Be
particularly careful with microcontrollers in plastic packages, in which the PROM cannot be
reprogrammed.
Table 11-3. Recommended Socket Adapters
Type
Package
Recommended socket adapter
H8/3257
H8/3256
64-Pin windowed shrink DIP (DC-64S)
HS3257ESS01H
64-Pin shrink DIP (DP-64S)
H8/325
H8/323
H8/322
64-Pin QFP (FP-64A)
HS3257ESH01H
68-Pin PLCC (CP-68)
HS3257ESC01H
64-Pin windowed shrink DIP (DC-64S)
HS328ESS01H
64-Pin shrink DIP (DP-64S)
64-Pin QFP (FP-64A)
HS328ESH01H
68-Pin PLCC (CP-68)
HS328ESC01H
203
EPROM socket
H8/3257, H8/3256
CP-68
FP-64A DC-64S, DP-64S
Pin
RES
9
64
8
14
5
13
NMI
19
9
17
P4 0
20
10
18
P4 1
21
11
19
P4 2
22
12
20
P4 3
23
13
21
P4 4
24
14
22
P4 5
25
15
23
P4 6
26
16
24
P4 7
60
48
56
P1 0
59
47
55
P1 1
58
57
56
55
54
46
45
44
43
42
54
53
52
51
50
P1 2
P1 3
P1 4
P1 5
P1 6
53
41
49
P1 7
50
39
47
P2 0
49
38
46
P2 1
48
47
37
36
45
44
P2 2
12
EA 1
11
EA 2
10
EA 3
9
EA 4
8
EA 5
7
EA 6
6
EA 7
5
EA 8
27
OE
24
EA 10
23
EA 11
25
29
P2 6
CE
22
P2 7
EA 15
3
2
P2 4
P2 5
40
21
EA 0
EA 14
43
42
32
20
EO 7
4
34
43
19
EO 6
28
35
41
EO 5
EA 13
P2 3
46
33
HN27C101 (32 pins)
1
26
13
14
15
17
18
EA 12
45
44
Pin
V PP
EA 9
EO 0
EO 1
EO 2
EO 3
EO 4
27
17
25
P5 0
EA 16
28
29
18
19
26
27
P5 1
P5 2
PGM
31
V
CC
32
33
34
23
24
31
32
P7 0
P7 1
15
6
14
Vcc
42
31
39
13
4
12
Vcc
MD 0
12
3
11
MD 1
V
SS
16
16
7
15
STBY
17
8
16
Vss
52
40
48
Vss
Note: All pins not listed in this figure should
be left open.
Notation
VPP :
Programming voltage (12.5 V)
EO 7 to EO0 : Data input/output
EA 16 to EA0: Address input
OE :
Output enable
CE :
Chip enable
PGM :
Program enable
Figure 11-2. Socket Adapter Pin Assignments
204
HN27C256 (Pin 28)
H8/325, H8/323, H8/322
FP-64A
DC-64S, DP-64S CP-68
RES
64
8
5
13
14
NMI
9
17
19
P4 0
10
18
20
P4 1
11
19
21
P4 2
12
20
22
P4 3
13
21
23
P4 4
14
22
9
Pin
24
P4 5
15
23
25
P4 6
16
24
26
P4 7
48
56
60
P1 0
47
55
59
P1 1
46
45
44
43
42
54
53
52
51
50
58
57
56
55
54
P1 2
P1 3
P1 4
P1 5
P1 6
Pin
V PP
EA 9
EO 0
EO 1
EO 2
EO 3
EO 4
HN27C256H
1
24
11
12
13
15
16
EO 5
17
EO 6
18
EO 7
19
EA 0
10
EA 1
9
EA 2
8
EA 3
7
EA 4
6
EA 5
5
EA 6
4
EA 7
3
25
41
49
53
P1 7
EA 8
39
47
50
P2 0
OE
22
38
46
49
P2 1
EA 10
21
37
45
48
P2 2
36
44
47
P2 3
EA 11
23
35
43
46
P2 4
EA 12
2
EA 13
26
EA 14
27
34
42
45
P2 5
33
41
44
P2 6
32
40
43
P2 7
CE
20
23
31
33
P7 0
V
CC
28
24
32
34
P7 1
6
14
15
Vcc
31
39
42
4
12
13
Vcc
MD 0
V
SS
14
3
11
12
MD 1
7
15
16
STBY
8
16
17
Vss
40
48
52
Vss
Notation
VPP :
Programming voltage (12.5 V)
EO 7 to EO0 : Data input/output
EA 14 to EA0: Address input
OE :
Output enable
CE :
Chip enable
Note: All pins not listed in this figure should be left open.
Figure 11-3. Socket Adapter Pin Assignments
205
Address in PROM mode
Address in MCU mode
H'0000
H'0000
On-chip
PROM
H'EFFF
H'EFFF
Undetermined
output*
H'1FFFF
Note: If this address area is read in PROM mode, the output data are undetermined.
Figure 11-4. H8/3257 Memory Map in PROM Mode
Address in PROM mode
Address in MCU mode
H'0000
H'0000
On-chip
PROM
H'BFFF
H'BFFF
Undetermined
output*
H'1FFFF
Note: If this address area is read in PROM mode, the output data are undetermined.
Figure 11-5. H8/3256 Memory Map in PROM Mode
206
Address in PROM mode
Address in MCU mode
H'0000
H'0000
On-chip
PROM
H'7FFF
H'7FFF
Figure 11-6. Memory Map of the H8/325 in PROM Mode
Address in PROM mode
Address in MCU mode
H'0000
H'0000
On-chip
PROM
"1" output*
H'7FFF
H'7FFF
Note: In PROM mode, addresses in this area always read H'FF.
Figure 11-7. Memory Map of the H8/323 in PROM Mode
Address in PROM mode
Address in MCU mode
H'0000
On-chip PROM
H'1FFF
H'0000
H'1FFF
"1" output*
H'7FFF
H'7FFF
Note: In PROM mode, addresses in this area always read H'FF.
Figure 11-8. Memory Map of the H8/322 in PROM Mode
207
11.3 Programming
11.3.1 Selection of Sub-Modes in PROM Mode
(1) Case of H8/3257 and H8/3256
The write, verify, and other sub-modes of the PROM mode are selected as shown in table 114.
Table 11-4. Selection of Sub-Modes in PROM Mode
Pins
Sub-mode
&(
2(
Write
Low
Verify
Programming
inhibited
3*0
VPP
VCC
E07 to E00
EA16 to EA0
High Low
VPP
VCC
Data input
Address input
Low
Low
High
VPP
VCC
Data output
Address input
Low
Low
High
High
Low
High
Low
High
Low
High
Low
High
VPP
VCC
High-impedance Address input
Note: The VPP and VCC pins must be held at the VPP and VCC voltage levels.
The H8/3257 or H8/3256 PROM has the same standard read/write specifications as the
HN27C101 EPROM. Page programming is not supported, however, so do not select page
programming mode. PROM writers that provide only page programming cannot be used.
When selecting a PROM writer, check that it supports the byte-at-a-time high-speed
programming mode. Be sure to set the address range to H’0000 to H’EFFF for the H8/3257,
and to H’0000 to H’BFFF for the H8/3256.
208
(2) Case of H8/325, H8/323, and H8/322
The write, verify, inhibited, and read sub-modes of the PROM mode are selected as shown in
table 11-5.
Table 11-5. Selection of Sub-Modes in PROM Mode
Pins
Mode
&(
2(
VPP
VCC
E07 to E00
EA14 to EA0
Write
Low
High VPP
VCC
Data input
Address input
Verify
High Low
VPP
VCC
Data output
Address input
Programming inhibited High High VPP
VCC
High-impedance
Address input
Note: The VPP and VCC pins must be held at the VPP and VCC voltage levels.
The H8/325 PROM uses the same, standard read/write specifications as the HN27C256 and
HN27256.
11.3.2 Writing and Verifying
An efficient, high-speed programming procedure can be used to write and verify PROM data.
This procedure writes data quickly without subjecting the chip to voltage stress and without
sacrificing data reliability. It leaves the data H’FF written in unused addresses.
209
Figures 11-9 to 11-10 show the basic high-speed programming flowchart.
Tables 11-6 and 11-8 list the electrical characteristics of the chip in the PROM mode. Figure
11-11 shows a write/verify timing chart.
START
Set program/verify mode
VCC =6.0V+0.25V,
VPP =12.5V+0.3V
Address =0
n=0
n+1 n
Program t
PW
N
Y
n < 25 ?
N
= 0.2ms +- 5%
Verify OK?
Address +1
Address
Y
Program tOPW = 0.2n ms
Last address?
N
Y
Set read mode
VCC =5.0V , VPP = VCC + 0.6
Error
N
All addresses read?
Y
END
Figure 11-9. High-Speed Programming Flowchart (H8/3257, H8/3256)
210
START
Set program/verify mode
VCC =6.0V+0.25V,
VPP =12.5V+0.3V
Address =0
n=0
n+1 n
Write time t
N
Y
n < 25 ?
N
PW
= 1ms +- 5%
Verify OK?
Address +1
Address
Y
Write t OPW = 3n ms
Last address?
N
Y
Set read mode
VCC =5.0V +- 0.5 V ,
VPP = VCC + 0.6
Error
N
All addresses read?
Y
END
Figure 11-10. High-Speed Programming Flowchart (H8/325, H8/323, H8/322)
211
Table 11-6. DC Characteristics
(When VCC = 6.0V ±0.25V, VPP = 12.5V ±0.3V, VSS = 0V, Ta = 25°C ±5°C)
Item
Symbol
min
typ
max
Unit
VIH
2.4
—
VCC + 0.3
V
Measurement
conditions
Input high voltage
EO7 – EO0,
EA14 – EA0,
2(, &(
Input low voltage
EO7 – EO0, VIL
EA14 – EA0,
2(, &(
– 0.3
—
0.8
V
Output high voltage
EO7 – EO0
VOH
2.4
—
—
V
Output low voltage
EO7 – EO0
VOL
—
—
0.45
V
IOL = 1.6 mA
Input leakage current
EO7 – EO0,
EA14 – EA0,
2(, &(
|ILI|
—
—
2
µA
Vin = 5.25V/
0.5V
VCC current
ICC
—
—
40
mA
VPP current
IPP
—
—
40
mA
IOH = –200 µA
Table 11-7. AC Characteristics (H8/3257, H8/3256)
(When VCC = 6.0V ±0.25V, VPP = 12.5V ±0.3V, Ta = 25°C ±5°C)
Item
Symbol min
typ
max
Unit
Measurement
conditions
Address setup time
tAS
2
—
—
µs
See Figure 11-11*
2( setup time
tOES
2
—
—
µs
Data setup time
tDS
2
—
—
µs
Address hold time
tAH
0
—
—
µs
Data hold time
tDH
2
—
—
µs
Data output disable time
tDF
—
—
130
ns
Vpp setup time
tVPS
2
—
—
µs
Program pulse width
tPW
0.19
0.20
0.21
ms
2( pulse width for overwrite-
tOPW
0.19
—
5.25
ms
VCC setup time
tVCS
2
—
—
µs
&( setup time
tCES
2
—
—
µs
Data output delay time
tOE
0
—
150
ns
programming
* Input pulse level: 0.8V to 2.2V
Input rise/fall time ≤20 ns
Timing reference levels: input—1.0V, 2.0V; output—0.8V, 2.0V
212
Table 11-8. AC Characteristics (H8/325, H8/323, H8/322)
(When VCC = 6.0V ±0.25V, VPP = 12.5V ±0.3V, Ta = 25°C ±5°C)
Item
Symbol
min
typ
max
Unit
Measurement
conditions
Address setup time
tAS
2
—
—
µs
See Figure 11-11*
2( setup time
tOES
2
—
—
µs
Data setup time
tDS
2
—
—
µs
Address hold time
tAH
0
—
—
µs
Data hold time
tDH
2
—
—
µs
Data output disable time
tDF
—
—
130
ns
Vpp setup time
tVPS
2
—
—
µs
Program pulse width
tPW
0.95
1.0
1.05
ms
2( pulse width for overwrite-
tOPW
2.85
—
78.75
ms
Vcc setup time
tVCS
2
—
—
µs
Data output delay time
tOE
0
—
500
ns
programming
* Input pulse level: 0.8V to 2.2V
Input rise/fall time ≤20 ns
Timing reference levels: input—1.0V, 2.0V; output—0.8V, 2.0V
213
Write
Verify
Address
t AS
Data
t AH
Input data
t DS
VPP
VPP
VCC
VCC
VCC GND
Output data
t DF
t DH
t VPS
t VCS
CE
t OES
t OE
t PW
OE
t OPW
Figure 11-11. PROM Write/Verify Timing
214
11.3.3 Notes on Writing
(1) Write with the specified voltages and timing. The programming voltage (VPP) is 12.5 V.
Caution: Applied voltages in excess of the specified values can permanently destroy the
chip. Be particularly careful about the PROM writer’s overshoot characteristics.
If the PROM writer is set to Intel specifications or Hitachi HN27C101, HN27256 or
HN27C256 specifications, VPP will be 12.5 V.
(2) Before writing data, check that the socket adapter and chip are correctly mounted in
the PROM writer. Overcurrent damage to the chip can result if the index marks on the
PROM writer, socket adapter, and chip are not correctly aligned.
(3) Don’t touch the socket adapter or chip while writing. Touching either of these can cause
contact faults and write errors.
(4) Page programming is not supported. Do not select page programming mode.
11.3.4 Reliability of Written Data
An effective way to assure the data holding characteristics of the programmed chips is to bake
them at 150°C, then screen them for data errors. This procedure quickly eliminates chips with
PROM memory cells prone to early failure.
Figure 11-12 shows the recommended screening procedure.
Write program
Bake with power off
o
o
+ 8 Hr *
150 ± 10 C, 48 Hr - 0 Hr
Read and check program
Vcc = 4.5V and 5.5V
Install
Note: Baking time should be measured from the point when the baking oven reaches 150˚ C
Figure 11-12. Recommended Screening Procedure
215
If a series of write errors occurs while the same PROM writer is in use, stop programming and
check the PROM writer and socket adapter for defects, using a microcomputer chip with a
windowed package and on-chip EPROM.
Please inform Hitachi of any abnormal conditions noted during programming or in screening of
program data after high-temperature baking.
11.3.5 Erasing of Data
The windowed package enables data to be erased by illuminating the window with ultraviolet
light. Table 11-9 lists the erasing conditions.
Table 11-9. Erasing Conditions
Item
Value
Ultraviolet wavelength 253.7 nm
Minimum illumination
2
15W·s/cm
The conditions in table 11-9 can be satisfied by placing a 12000-µW/cm2 ultraviolet lamp 2 or 3
centimeters directly above the chip and leaving it on for about 20 minutes.
11.4 Handling of Windowed Packages
(1) Glass Erasing Window: Rubbing the glass erasing window of a windowed package with a
plastic material or touching it with an electrically charged object can create a static charge
on the window surface which may cause the chip to malfunction.
If the erasing window becomes charged, the charge can be neutralized by a short exposure to
ultraviolet light. This returns the chip to its normal condition, but it also reduces the charge
stored in the floating gates of the PROM, so it is recommended that the chip be
reprogrammed afterward.
Accumulation of static charge on the window surface can be prevented by the following
precautions:
[1] When handling the package, ground yourself. Don’t wear gloves. Avoid other possible
sources of static charge.
[2] Avoid friction between the glass window and plastic or other materials that tend to
accumulate static charge.
216
[3] Be careful when using cooling sprays, since they may have a slight ion content.
[4] Cover the window with an ultraviolet-shield label, preferably a label including a
conductive material. Besides protecting the PROM contents from ultraviolet light, the
label protects the chip by distributing static charge uniformly.
(2) Handling after Programming: Fluorescent light and sunlight contain small amounts of
ultraviolet, so prolonged exposure to these types of light can cause programmed data to
invert. In addition, exposure to any type of intense light can induce photoelectric effects that
may lead to chip malfunction. It is recommended that after programming the chip, you cover
the erasing window with a light-proof label (such as an ultraviolet-shield label).
217
218
Section 12. Power-Down State
12.1 Overview
The H8/325 series has a power-down state that greatly reduces power consumption by stopping
some or all of the chip functions. The power-down state includes three modes:
(1) Sleep mode – a software-triggered mode in which the CPU halts but the rest of the chip
remains active
(2) Software standby mode – a software-triggered mode in which the entire chip is inactive
(3) Hardware standby mode – a hardware-triggered mode in which the entire chip is inactive
Table 12-1 lists the conditions for entering and leaving the power-down modes. It also indicates
the status of the CPU, on-chip supporting modules, etc. in each power-down mode.
Table 12-1. Power-Down State
Mode
Sleep
mode
Software
standby
mode
Entering
procedure
CPU
Sup.
Clock CPU Reg’s. Mod.*
RAM
I/O
ports
Exiting
methods
Execute
SLEEP
instruction
Run
Held
Held
•
Interrupt
•
•
5(6
67%<
Set SSBY bit
in SYSCR to
1, then
execute
SLEEP
instruction
Halt
•
NMI
HardSet 67%< pin
ware
to low level
standby
mode
Halt
Halt
Halt
Halt
Held
Held
Not
held
Run
Halt and
initialized
Held
Halt
Held
and
initialized
Held
High
impedance
state
•
,54 – ,54
•
STBY
•
RES
•
IS
•
67%< high,
then 5(6
low → high
* On-chip supporting modules.
Notes
1. SYSCR: System control register
2. SSBY Software standby bit
219
12.2 System Control Register: Power-Down Control Bits
Bits 7 to 4 of the system control register (SYSCR) concern the power-down state. Specifically,
they concern the software standby mode.
Table 12-2 lists the attributes of the system control register.
Table 12-2. System Control Register
Name
Abbreviation
System control register SYSCR
Bit
R/W
Initial value
Address
R/W
H’0B
H’FFC4
7
6
5
4
3
2
1
0
SSBY
STS2
STS1
STS0
—
NMIEG
—
RAME
Initial value
0
0
0
0
1
0
1
1
Read/Write
R/W
R/W
R/W
R/W
—
R/W
—
R/W
Bit 7 – Software Standby (SSBY): This bit enables or disables the transition to the software
standby mode.
On recovery from the software standby mode by an external interrupt or input strobe interrupt,
SSBY remains set to 1. To clear this bit, software must write a 0.
Bit 7
SSBY Description
0
The SLEEP instruction causes a transition to the sleep mode.
1
The SLEEP instruction causes a transition to the software standby mode.
(Initial value)
Bits 6 to 4 – Standby Timer Select 2 to 0 (STS2 to STS0): These bits select the clock settling
time when the chip recovers from the software standby mode by an external interrupt. During
the selected time, the clock oscillator runs but clock pulses are not supplied to the CPU or the
on-chip supporting modules.
220
Bit 6 Bit 5 Bit 4
STS2 STS1 STS0
Description
0
0
0
Settling time = 8192 states
0
0
1
Settling time = 16384 states
0
1
0
Settling time = 32768 states
0
1
1
Settling time = 65536 states
1
—
—
Settling time = 131072 states
(Initial value)
When the on-chip clock generator is used, the STS bits should be set to allow a settling time of
at least 10 ms. Table 12-3 lists the settling times selected by these bits at several clock
frequencies and indicates the recommended settings.
When the chip is externally clocked, the STS bits can be set to any value. The minimum value
(STS2 = STS1 = STS0 = 0) is recommended.
Table 12-3. Times Set by Standby Timer Select Bits (Unit: ms)
System clock frequency (MHz)
STS2
STS1
STS0
Settling
time
(states)
0
0
0
8192
0.8
1.0
1.4
2.0
4.1
8.2
16.4
0
0
1
16384
1.6
2.0
2.7
4.1
8.2
16.4
32.8
0
1
0
32768
3.3
4.1
5.5
8.2
16.4
32.8
65.5
0
1
1
65536
6.6
8.2
10.9
16.4
32.8
65.5
131.1
1
—
—
131072
13.1
16.4
21.8
32.8
65.5
131.1
262.1
10
8
6
4
2
1
0.5
Notes:
1. All times are in milliseconds.
2. Recommended values are printed in boldface.
12.3 Sleep Mode
The sleep mode provides an effective way to conserve power while the CPU is waiting for an
external interrupt or an interrupt from an on-chip supporting module.
221
12.3.1 Transition to Sleep Mode
When the SSBY bit in the system control register is cleared to 0, execution of the SLEEP
instruction causes a transition from the program execution state to the sleep mode. After
executing the SLEEP instruction, the CPU halts, but the contents of its internal registers remain
unchanged. The on-chip supporting modules continue to operate normally.
12.3.2 Exit from Sleep Mode
The chip wakes up from the sleep mode when it receives an internal or external interrupt
request, or a low input at the 5(6 or 67%< pin.
(1) Wake-Up by Interrupt: An interrupt releases the sleep mode and starts the CPU’s
interrupt-handling sequence.
If an interrupt from an on-chip supporting module is disabled by the corresponding
enable/disable bit in the module’s control register, the interrupt cannot be requested, so it
cannot wake the chip up. Similarly, the CPU cannot be awoken by an interrupt other than
NMI if the I (interrupt mask) bit in the CCR (condition code register) is set when the SLEEP
instruction is executed.
(2) Wake-Up by 5(6 pin: When the 5(6 pin goes low, the chip exits from the sleep mode to
the reset state.
(3) Wake-Up by 67%< pin: When the 67%< pin goes low, the chip exits from the sleep mode
to the hardware standby mode.
12.4 Software Standby Mode
In the software standby mode, the system clock stops and chip functions halt, including both
CPU functions and the functions of the on-chip supporting modules. Power consumption is
reduced to an extremely low level. The on-chip supporting modules and their registers are reset
to their initial states, but as long as a minimum necessary voltage supply is maintained (at least
2V), the contents of the CPU registers and on-chip RAM remain unchanged. I/O ports also
remain unchanged.
222
12.4.1 Transition to Software Standby Mode
To enter the software standby mode, set the standby bit (SSBY) in the system control register
(SYSCR) to 1, then execute the SLEEP instruction.
12.4.2 Exit from Software Standby Mode
The chip can be brought out of the software standby mode by an input at one of seven pins:
10,, ,54, ,54, ,54, ,6, 5(6, or 67%<.
(1) Recovery by External Interrupt: When an 10,, ,54, ,54, ,54, or input strobe (ISI)
interrupt request signal is received, the clock oscillator begins operating. After the waiting
time set in the system control register (bits STS2 to STS0), clock pulses are supplied to the
CPU and on-chip supporting modules. The CPU executes the interrupt-handling sequence
for the requested interrupt, then returns to the instruction after the SLEEP instruction. The
SSBY bit is not cleared.
See Section 12.2, System Control Register: Power-Down Control Bits for information about
the STS bits.
(2) Recovery by 5(6 Pin: When the 5(6 pin goes low, the clock oscillator starts. Next, when
the 5(6 pin goes high, the CPU begins executing the reset sequence. The SSBY bit is
cleared to 0.
The 5(6 pin must be held low long enough for the clock to stabilize.
(3) Recovery by 67%< Pin: When the 67%< pin goes low, the chip exits from the software
standby mode to the hardware standby mode.
12.4.3 Sample Application of Software Standby Mode
In this example the chip enters the software standby mode when 10, goes low and exits when
10, goes high, as shown in figure 12-1.
223
The NMI edge bit (NMIEG) in the system control register is originally cleared to 0, selecting the
falling edge. When 10, goes low, the 10, interrupt handling routine sets NMIEG to 1
(selecting the rising edge), sets SSBY to 1, then executes the SLEEP instruction. The chip
enters the software standby mode. It recovers from the software standby mode on the next rising
edge of 10,.
Clock
generator
Ø
NMI
NMIEG
SSBY
Settling time
NMI interrupt handler
NMIEG = 1
SSBY = 1
Software standby mode
(power-down state)
NMI interrupt handler
SLEEP
Figure 12-1. Software Standby Mode NMI Timing (Example)
12.4.4 Notes on Current Dissipation
1. The I/O ports remain in their current states in software standby mode. If a port is in the high
output state, it continues to dissipate power in proportion to the output current.
2. When software standby mode is entered under condition (a) or (b) below, current dissipation
is higher (ICC = 100 to 300 µA) than normal in standby mode.
(a) In single-chip mode (mode 3): when software standby mode is entered by executing an
instruction stored in on-chip ROM, after even one instruction not stored in on-chip ROM
has been fetched (e.g. from on-chip RAM).
224
(b) In expanded mode with on-chip ROM enabled (mode 2): when software standby mode is
entered by executing an instruction stored in on-chip ROM, after even one instruction not
stored in on-chip ROM has been fetched (e.g. from external memory or on-chip RAM).
Note that the H8/300 CPU pre-fetches instructions. If an instruction stored in the last two
bytes of on-chip ROM is executed, the contents of the next two bytes, not in on-chip
ROM, will be fetched as the next instruction.
This problem does not occur in expanded mode when on-chip ROM is disabled (mode 1).
In hardware standby mode there is no additional current dissipation, regardless of the
conditions when hardware standby mode is entered.
12.5 Hardware Standby Mode
12.5.1 Transition to Hardware Standby Mode
Regardless of its current state, the chip enters the hardware standby mode whenever the 67%<
pin goes low.
The hardware standby mode reduces power consumption drastically by halting the CPU,
stopping all the functions of the on-chip supporting modules, and placing I/O ports in the highimpedance state. The registers of the on-chip supporting modules are reset to their initial values.
Only the on-chip RAM is held unchanged, provided the minimum necessary voltage supply is
maintained (at least 2V).
Notes: 1. The RAME bit in the system control register should be cleared to 0 before the 67%<
pin goes low, to disable the on-chip RAM during the hardware standby mode.
2. Do not change the inputs at the mode pins (MD1, MD0) during hardware standby mode.
Be particularly careful not to let both mode pins go low in hardware standby mode,
since that places the chip in PROM mode and increases current drain.
225
12.5.2 Recovery from Hardware Standby Mode
Recovery from the hardware standby mode requires inputs at both the 67%< and 5(6 pins.
When the 67%< pin goes high the clock oscillator begins running. The 5(6 pin should be low
at this time and should be held low long enough for the clock to stabilize. When the 5(6 pin
changes from low to high, the reset sequence is executed and the chip returns to the program
execution state.
12.5.3 Timing Relationships
Figure 12-2 shows the timing relationships in the hardware standby mode.
In the sequence shown, first 5(6 goes low, then 67%< goes low, at which point the chip enters
the hardware standby mode. To recover, first 67%< goes high, then after the clock settling
time, 5(6 goes high.
Clock pulse
generator
RES
STBY
Clock settling
time
Figure 12-2. Hardware Standby Mode Timing
226
Restart
Section 13. E-Clock Interface
13.1 Overview
For interfacing to peripheral devices that require it, the H8/325 series can generate an E clock
output. Special instructions (MOVTPE, MOVFPE) perform data transfers synchronized with the
E clock.
The E clock is created by dividing the system clock (φ) by 8. The E clock is output at the P47
pin when the P47DDR bit in the port 4 data direction register (P4DDR) is set to 1. It is output
only in the expanded modes (mode 1 and mode 2); it is not output in the single-chip mode.
Output begins immediately after a reset.
When the CPU executes an instruction that synchronizes with the E clock, the address strobe
($6), the address on the address bus, and the ,26 signal are output as usual, but the 5' and :5
signal lines and the data bus do not become active until the falling edge of the E clock is
detected. The length of the access cycle for an instruction synchronized with the E clock
accordingly varies from 9 to 16 states. Figures 15-1 and 15-2 show the timing in the cases of
maximum and minimum synchronization delay.
It is not possible to insert wait states (Tw) during the execution of an instruction synchronized
with the E clock by input at the :$,7 pin.
227
T1
T2
TE
TE
TE
TE
TE
TE
TE
TE
TE
TE
TE
TE
TE
T3
Ø
E
A15to A 0 , IOS
AS
RD (Read access)
WR (Write access)
D7 to D0
(Read access)
D7 to D0
(Write access)
Figure 13-1. Execution Cycle of Instruction Synchronized with E Clock in Expanded Modes
(Maximum Synchronization Delay)
228
Last state
T1
T2
TE
TE
TE
TE
TE
TE
T3
Ø
E
A15to A 0 , IOS
AS
RD (Read access)
WR (Write access)
D7 to D0
(Read access)
D7 to D0
(Write access)
Figure 13-2. Execution Cycle of Instruction Synchronized with E Clock in Expanded Modes
(Minimum Synchronization Delay)
229
230
Section 14. Clock Pulse Generator
14.1 Overview
The H8/325 series chips have a built-in clock pulse generator (CPG) consisting of an oscillator
circuit, a system clock divider, an E clock divider, and a prescaler. The prescaler generates
clock signals for the on-chip supporting modules.
14.1.1 Block Diagram
CPG
Prescaler
XTAL
EXTAL
Oscillator
circuit
Divider
÷2
Divider
÷8
Ø
E
Ø/2 to Ø/4096
Figure 14-1. Block Diagram of Clock Pulse Generator
14.2 Oscillator Circuit
If an external crystal is connected across the EXTAL and XTAL pins, the on-chip oscillator
circuit generates a clock signal for the system clock divider. Alternatively, an external clock
signal can be applied to the EXTAL pin.
(1) Connecting an External Crystal
[1] Circuit Configuration: An external crystal can be connected as in the example in
figure 14-2. An AT-cut parallel resonating crystal should be used.
231
CL1
EXTAL
XTAL
CL2
CL1 = CL2 =15 to 22 pF
Figure 14-2. Connection of Crystal Oscillator (Example)
[2] Crystal Oscillator: The external crystal should have the characteristics listed in table
16-1.
Table 14-1. External Crystal Parameters
Frequency (MHz)
2
4
8
Rs max (Ω)
500 120 60
C0 (pF)
12
16
20
40
30
20
7 pF max
CL
L
RS
XTAL
EXTAL
CO
AT - cut parallel resonating crystal
Figure 14-3. Equivalent Circuit of External Crystal
[3] Note on Board Design: When an external crystal is connected, other signal lines should
be kept away from the crystal circuit to prevent induction from interfering with correct
oscillation. See figure 14-4. The crystal and its load capacitors should be placed as close
as possible to the XTAL and EXTAL pins.
232
Not allowed
Signal A
Signal B
H8/325 series
CL2
XTAL
EXTAL
CL1
Figure 14-4. Notes on Board Design around External Crystal
(2) Input of External Clock Signal
[1] Circuit Configuration: Figure 14-5 shows examples of signal connections for external
clock input. In example (b), the external clock signal should be held high during the
standby modes.
(a)
(b)
EXTAL
External
clock
input
74HC04
XTAL
EXTAL
XTAL
External
clock
input
Open
Figure 14-5. External Clock Input (Example)
[2] External Clock Input
Frequency
Double the system clock (φ) frequency
Duty factor
45% to 55%
233
14.3 System Clock Divider
The system clock divider divides the crystal oscillator or external clock frequency by 2 to create
the system clock (φ).
An E clock signal is created by dividing the system clock by 8.
Figure 16-6 shows the phase relationship of the E clock to the system clock.
Ø
E
Figure 14-6. Phase Relationship of System Clock and E Clock
234
Section 15. Electrical Specifications
15.1 Absolute Maximum Ratings
Table 15-1 lists the absolute maximum ratings.
Table 15-1. Absolute Maximum Ratings
Item
Symbol Rating
Unit
Supply voltage
VCC
–0.3 to +7.0
V
Programming voltage
VPP
–0.3 to +13.5
V
Input voltage
Vin
–0.3 to VCC + 0.3
V
Regular specifications: –20 to +75
°C
Wide-range specifications: –40 to +85
°C
–55 to +125
°C
Operating temperature Topr
Storage temperature
Tstg
Note:The input pins have protection circuits that guard against high static voltages and electric
fields, but these high input-impedance circuits should never receive overvoltages
exceeding the absolute maximum ratings shown in table 15-1.
15.2 Electrical Characteristics
15.2.1 DC Characteristics
Tables 15-2 and 15-3 list the DC characteristics of the H8/325 series.
235
Table 15-2. DC Characteristics (5V Version)
Conditions: VCC = 5.0V ±10%, VSS = 0V, Ta = –20 to 75°C (regular specifications)
Ta = –40 to 85°C (wide-range specifications)
Item
Measurement
conditions
min
typ
max
Unit
1.0
–
–
V
–
–
VCC × 0.7
V
0.4
–
–
V
VIH
VCC – 0.7
–
VCC + 0.3
V
VIH
2.0
–
VCC + 0.3
V
VIL
–0.3
–
0.5
V
Input low voltage Input pins
other than (1)
and (3)
VIL
–0.3
–
0.8
V
Output high
voltage
VOH
VCC – 0.5
–
–
V
IOH = –200 µA
3.5
–
–
V
IOH = –1.0 mA
–
–
0.4
V
IOL = 1.6 mA
–
–
1.0
V
IOL = 10.0 mA
–
–
10.0
µA
Vin = 0.5 V to
–
–
1.0
µA
VCC – 0.5 V
Schmitt trigger
input voltage
(1)
Input high
voltage
(2)
Input high
voltage
Symbol
P66 to P63, P60,
P70
5(6, 67%<
MD1, MD0
EXTAL, 10,
Input pins
other than (1)
and (2)
Input low voltage 5(6, 67%<
(3)
MD1, MD0,
EXTAL
Output low
voltage
-
VT
+
VT
+
VT –VT
All output pins
All output pins
VOL
P17 to P10, P27 to
P20
Input leakage
current
5(6
|Iin|
67%<, 10,,
MD1, MD0
Leakage current Ports 1 to 7
in 3-state (off
state)
|ITSI|
–
–
1.0
µA
Vin = 0.5 V to
VCC – 0.5 V
Input pull-up
MOS current
-Ip
30
–
250
µA
Vin = 0 V
236
Ports 1 to 7
Table 15-2. DC Characteristics (5V Version) (cont.)
Conditions: VCC = AVCC = 5.0V ±10%, VSS = 0V, Ta = –20 to 75°C (regular
specifications)
Ta = –40 to 85°C (wide-range specifications)
Item
Input capacitance
5(6
10,
Symbol min typ
max Unit
Measurement
conditions
Cin
All input pins
except 5(6
and 10,
Current
1
dissipation*
Normal
operation
ICC
Sleep mode
Standby modes*
RAM standby
voltage
2
VRAM
–
–
60
pF
Vin = 0 V
–
–
30
pF
f = 1 MHz
–
–
15
pF
Ta = 25°C
–
12
25
mA
f = 6 MHz
–
16
30
mA
f = 8 MHz
–
20
40
mA
f = 10 MHz
–
8
15
mA
f = 6 MHz
–
10
20
mA
f = 8 MHz
–
12
25
mA
f = 10 MHz
–
0.01 5.0
µA
2.0
–
V
–
Notes: 1. Current dissipation values assume that VIH min. = VCC – 0.5V, VIL max. = 0.5V, all output pins
are in the no-load state, and all MOS input pull-ups are off.
2. For these values it is assumed that VRAM ≤ VCC < 4.5 V and VIH min = VCC × 0.9, VIL max =
0.3 V.
237
Table 15-3. DC Characteristics (3V Version for only H8/3257 and H8/3256)
Conditions: VCC = 2.7 to 3.6V, VSS = 0V, Ta = –20 to 75°C
Item
Symbol min
typ max
Unit
Schmitt trigger P66 to P63,
input voltage P60, P70
(1)
VT
-
VCC × 0.15
–
–
V
VT
+
–
–
VCC × 0.7
V
–
–
V
VT –VT- 0.2
+
Measurement
conditions
Input high
voltage (2)
RES, STBY
MD1, MD0
EXTAL, 10,
VIH
VCC × 0.9
–
VCC + 0.3
V
Input high
voltage
Input pins
VIH
other than (1)
and (2)
VCC × 0.7
–
VCC + 0.3
V
Input low
voltage (3)
RES, STBY
MD1, MD0,
EXTAL
VIL
–0.3
–
VCC × 0.1
V
Input low
voltage
Input pins
VIL
other than (1)
and (3)
–0.3
–
VCC × 0.15
V
Output high
voltage
All output pins VOH
VCC – 0.4
–
–
V
IOH = –200 µA
VCC – 0.9
–
–
V
IOH = –1.0 mA
–
–
0.4
V
IOL = 1.6 mA
–
–
0.4
V
IOL = 0.8 mA
–
–
10.0
µA
Vin = 0.5 V to
–
–
1.0
µA
VCC – 0.5 V
Output low
voltage
P17 to P10,
P27 to P20
VOL
All output pins
Input leakage RES
current
|Iin|
STBY, NMI,
MD1, MD0
Leakage
current in 3state (off
state)
Ports 1 to 7
|ITSI|
–
–
1.0
µA
Vin = 0.5 V to
VCC – 0.5 V
Input pull-up
MOS current
Ports 1 to 7
-Ip
3
–
120
µA
VCC = 3.3 V
Vin = 0 V
238
Table 15-3. DC Characteristics (3V Version for only H8/3257 and H8/3256) (cont.)
Conditions: VCC = 2.7 to 3.6V, VSS = 0V, Ta = –20 to 75°C
Item
Input capacitance
5(6
10,
Symbol min typ
max Unit
Measurement
conditions
Cin
–
–
60
pF
Vin = 0 V
–
–
30
pF
f = 1 MHz
–
–
15
pF
Ta = 25°C
–
4
–
mA
f = 3 MHz
Sleep mode
–
3
–
mA
Normal
operation
–
6
12
mA
Sleep mode
–
4
8
mA
Standby modes
–
0.01 5.0
µA
2.0
–
V
All input pins
except 5(6
and 10,
Current
dissipation*
RAM standby
voltage
Normal
operation
ICC
VRAM
–
f = 5 MHz
Note: Current dissipation values assume that VIH min. = VCC – 0.5V, VIL max. = 0.5V, all output pins are
in the no-load state, and all MOS input pull-ups are off.
239
Table 15-4. Allowable Output Current Sink Values
Conditions: VCC = 5.0V ±10%, VSS = 0V, Ta = –20 to 75°C (regular specifications)
Ta = –40 to 85°C (wide-range specifications)
Item
Allowable output low
current sink (per pin)
Allowable output low
current sink (total)
Ports 1 and 2
Symbol min typ max
–
–
10
IOL
Other output pins
Ports 1 and 2, total
ΣIOL
–
–
–
–
2.0
80
Unit
mA
mA
mA
All output pins
–
–
120
mA
Allowable output high All output pins
–IOH
–
–
2.0
mA
current sink (per pin)
Allowable output high Total of all output
Σ–IOH
–
–
40
mA
current sink (total)
Note: To avoid degrading the reliability of the chip, be careful not to exceed the output current
sink values in table 15-4. In particular, when driving a Darlington pair or LED directly, be
sure to insert a current-limiting resistor in the output path. See figures 17-1 and 17-2.
H8/325
series
2 kΩ
Port
Darlington
pair
Figure 15-1. Example of Circuit for Driving a Darlington Pair
H8/325
series
Vcc
600 Ω
Port 1 or 2
LED
Figure 15-2. Example of Circuit for Driving a LED
240
Table 15-5. Allowable Output Current Sink Values (3V Version for only H8/3257 and
H8/3256)
Conditions: VCC = 2.7 to 3.6V, VSS = 0V, Ta = –20 to 75°C
Item
Allowable output low
current sink (per pin)
Allowable output low
current sink (total)
Symbol
min
typ
max
Unit
IOL
–
–
2
mA
Other output pins
–
–
1.0
mA
Ports 1 and 2, total of 16 pins ΣIOL
–
–
40
mA
Total of all other output pins
–
–
60
mA
Ports 1 and 2
Allowable output high
current sink (per pin)
All output pins
–IOH
–
–
2.0
mA
Allowable output high
current sink (total)
Total of all output pins
Σ–IOH
–
–
30
mA
Note: To avoid degrading the reliability of the chip, be careful not to exceed the output current
sink values in table 15-5.
241
15.2.2 AC Characteristics
The AC characteristics of the H8/325 series are listed in three tables. Bus timing parameters are
given in table 15-6, control signal timing parameters in table 15-7, and timing parameters of the
on-chip supporting modules in table 15-8.
Table 15-6. Bus Timing
Condition A: VCC = 5.0V ±10%, φ = 0.5 to 10MHz, VSS = 0V, Ta = –20 to 75°C
(regular specifications), Ta = –40 to 85°C (wide-range specifications Condition B:
VCC = 2.7 to 3.6V, VSS = 0V, Ta = –20 to 75°C, for only H8/3257 and H8/3256
Condition B
5MHz
6MHz
Item
Clock cycle time
Clock pulse width Low
Clock pulse width
High
Clock rise time
Clock fall time
Address delay time
Address hold time
Address strobe delay
time
Write strobe delay
time
Strobe delay time
Write strobe pulse
width
Address setup time 1
Address setup time 2
Read data setup time
Read data hold time
Write data delay time
Read data access
time
Write data setup time
Write data hold time
Wait setup time
Wait hold time
E clock delay time
E clock rise time
E clock fall time
Read data hold time
(for E clock)
Write data hold time
(for E clock)
242
Condition A
8MHz
10MHz
Symbol
tcyc
tCL
tCH
min
200
65
65
max
2000
–
–
min
166.7
65
65
max
2000
–
–
min
125
45
45
max
2000
–
–
min
100
35
35
max
2000
–
–
Unit
ns
ns
1ns
Measurement
conditions
Fig. 15-4
Fig. 15-4
Fig. 15-4
tCr
tCf
tAD
tAH
tASD
–
–
–
30
–
25
25
90
–
80
–
–
–
30
–
15
15
70
–
70
–
–
–
25
–
15
15
60
–
60
–
–
–
20
–
15
15
55
–
40
ns
ns
ns
ns
ns
Fig. 15-4
Fig. 15-4
Fig. 15-4
Fig. 15-4
Fig. 15-4
tWSD
–
80
–
70
–
60
–
50
ns
Fig. 15-4
tSD
tWSW
–
200
90
–
–
200
70
–
–
150
60
–
–
120
50
–
ns
ns
Fig. 15-4
Fig. 15-4
tAS1
tAS2
tRDS
tRDH
tWDD
tACC
25
105
90
0
–
–
–
–
–
–
125
300
25
105
60
0
–
–
–
–
–
–
85
280
20
80
50
0
–
–
–
–
–
–
75
210
15
65
35
0
–
–
–
–
–
–
75
170
ns
ns
ns
ns
ns
ns
Fig. 15-4
Fig. 15-4
Fig. 15-4
Fig. 15-4
Fig. 15-4
Fig. 15-4
tWDS
tWDH
tWTS
tWTH
tED
tEr
tEf
tRDHE
10
30
60
20
–
–
–
0
–
–
–
–
30
25
25
–
30
30
45
10
–
–
–
0
–
–
–
–
25
15
15
–
15
25
45
10
–
–
–
0
–
–
–
–
25
15
15
–
10
20
45
10
–
–
–
0
–
–
–
–
25
15
15
–
ns
ns
ns
ns
ns
ns
ns
ns
Fig. 15-4
Fig. 15-4
Fig. 15-5
Fig. 15-5
Fig. 15-6
Fig. 15-6
Fig. 15-6
Fig. 15-6
tWDHE
60
–
50
–
40
–
30
–
ns
Fig. 15-6
Table 15-7. Control Signal Timing
Condition A: VCC = 5.0V ±10%, φ = 0.5 to 10MHz, VSS = 0V,
Ta = –20 to 75°C (regular specifications), Ta = –40 to 85°C (wide-range
specifications)
Condition B: VCC = 2.7 to 3.6V, VSS = 0V, Ta = –20 to 75°C, for only H8/3257 and
H8/3256
Item
5(6 setup time
5(6 pulse width
Mode programming setup
time
10, setup time (10,, ,54
to ,54)
10, hold time (10,, ,54 to
,54)
Interrupt pulse width for
recovery from soft- ware
standby mode (10,, ,54 to
,54)
Crystal oscillator settling time
(reset)
Crystal oscillator settling time
(software standby)
Condition B
5MHz
Condition A
6MHz
8MHz
Symbol
tRESS
tRESW
tMDS
min
300
10
4
max
–
–
–
min
200
10
4
max
–
–
–
min
200
10
4
max
–
–
–
min
200
10
4
max
–
–
–
Unit
ns
tcyc
tcyc
Measurement
conditions
Fig. 15-7
Fig. 15-7
Fig. 15-7
tNMIS
300
–
150
–
150
–
150
–
ns
Fig. 15-8
tNMIH
10
–
10
–
10
–
10
–
ns
Fig. 15-8
tNMIW
300
–
200
–
200
–
200
–
ns
Fig. 15-8
tOSC1
20
–
20
–
20
–
20
–
ms
Fig. 15-9
tOSC2
10
–
10
–
10
–
10
–
ms
Fig. 15-10
10MHz
Table 15-8. Timing Conditions of On-Chip Supporting Modules
Condition A: VCC = 5.0V ±10%, φ = 0.5 to 10MHz, VSS = 0V, Ta = –20 to 75°C
(regular specifications), Ta = –40 to 85°C (wide-range specifications) Condition B:
VCC = 2.7 to 3.6V, VSS = 0V, Ta = –20 to 75°C, for only H8/3257 and H8/3256
Condition B
Condition A
5MHz
Item
FRT
Symbol min
6MHz
8MHz
10MHz
max
min
max
min
max
min
max
Measuremen
Unit t conditions
Timer output tFTOD
delay time
–
150
–
100
–
100
–
100
ns
Fig. 15-11
Timer input
setup time
tFTIS
80
–
50
–
50
–
50
–
ns
Fig. 15-11
Timer clock tFTCS
input setup
time
80
–
50
–
50
–
50
–
ns
Fig. 15-12
Timer clock tFTCWH
pulse width
tFTCWL
1.5
–
1.5
–
1.5
–
1.5
–
tcyc
Fig. 15-12
243
Table 15-8. Timing Conditions of On-Chip Supporting Modules (cont.)
Condition A: VCC = 5.0V ±10%, φ = 0.5 to 10MHz, VSS = 0V, Ta = –20 to 75°C
(regular specifications), Ta = –40 to 85°C (wide-range specifications) Condition B:
VCC = 2.7 to 3.6V, VSS = 0V, Ta = –20 to 75°C, for only H8/3257 and H8/3256
Condition B Condition A
5MHz
SCI
Ports
244
8MHz
10MHz
Symbol min max
min max min max
min
Measurement
max Unit conditions
Timer output delay
time
tTMOD
–
150
–
100
–
100
–
100
ns
Fig. 15-13
Timer reset input
setup time
tTMRS
80
–
50
–
50
–
50
–
ns
Fig. 15-15
Timer clock input
setup time
tTMCS
80
–
50
–
50
–
50
–
ns
Fig. 15-14
Timer clock pulse
width (single edge)
tTMCWH
1.5
–
1.5
–
1.5
–
1.5
–
tcyc
Fig. 15-14
Timer clock pulse
width (both edges)
tTMCWL
2.5
–
2.5
–
2.5
–
2.5
–
tcyc
Fig. 15-14
Input
(Async)
tscyc
2
–
2
–
2
–
2
–
tcyc
Fig. 15-16
clock
(Sync) cycle tscyc
4
–
4
–
4
–
4
–
tcyc
Fig. 15-16
100
–
100
ns
Fig. 15-16
Item
TMR
6MHz
Transmit data
delay time (Sync)
tTXD
–
200
–
100
–
Receive data setup
time (Sync)
tRXS
150
–
100
–
100 –
100
–
ns
Fig. 15-16
Receive data hold
time (Sync)
tRXH
150
–
100
–
100 –
100
–
ns
Fig. 15-16
Input clock pulse
width
tSCKW
0.4
0.6
0.4
0.6
0.4
0.6
0.4
0.6
tScyc
Fig. 15-17
Output data delay
time
tPWD
–
150
–
100
–
100
–
100
ns
Fig. 15-18
Input data setup
time
tPRS
80
–
50
–
50
–
50
–
ns
Fig. 15-18
Input data hold time
tPRH
80
–
50
–
50
–
50
–
ns
Fig. 15-18
Table 15-8. Timing Conditions of On-Chip Supporting Modules (cont.)
Condition A: VCC = 5.0V ±10%, φ = 0.5 to 10MHz, VSS = 0V, Ta = –20 to 75°C
(regular specifications), Ta = –40 to 85°C (wide-range specifications)
Condition B: VCC = 2.7 to 3.6V, VSS = 0V, Ta = –20 to 75°C, for only H8/3257 and
H8/3256
Condition B Condition A
5MHz
6MHz
8MHz
10MHz
Item
Symbol min+ max
min
max
min
max
min
max
Unit
Measurement
conditions
Parallel
Handshake
handshake input strobe
interface
pulse width
tHISW
1.5
–
1.5
–
1.5
–
1.5
–
tcyc
Fig. 15-19
Handshake
input data
setup time
tHIS
10
–
10
–
10
–
10
–
ns
Fig. 15-19
Handshake
input data
hold time
tHIH
120
–
120
–
120
–
120
–
ns
Fig. 15-19
Handshake
tHOSD1
–
100
–
80
–
80
–
80
ns
Fig. 15-20
output strobe tHOSD2
delay time
–
100
–
80
–
80
–
80
ns
Fig. 15-20
Busy output
tHBSOD1
–
150
–
150
–
150
–
150
ns
Fig. 15-21
delay time
tHBSOD2
–
150
–
150
–
150
–
150
ns
Fig. 15-21
• Measurement Conditions for AC Characteristics
5V
RL
LSI
output pin
RH
C
C = 90 pF: Ports 1, 2, 3, 46, 6, 7
30 pF: Ports 4 (except 46 ), 5
RL = 2.4 kΩ
RH = 12 kΩ
Input / output timing reference levels
Low: 0.8 V
High: 2.0 V
Figure 15-3. Output Load Circuit
245
15.3 MCU Operational Timing
This section provides the following timing charts:
15.3.1 Bus Timing
Figures 15-4 to 15-6
15.3.2 Control Signal Timing
Figures 15-7 to 15-10
15.3.3 16-Bit Free-Running Timer Timing
Figures 15-11 to 15-12
15.3.4 8-Bit Timer Timing
Figures 15-13 to 15-15
15.3.6 SCI Timing
Figures 15-15 to 15-17
15.3.7 I/O Port Timing
Figure 15-18
15.3.8 Parallel Handshaking Interface Timing
Figures 15-19 to 15-21
15.3.1 Bus Timing
(1) Basic Bus Cycle (without Wait States) in Expanded Modes
T1
T2
T3
t cyc
t CH
t CL
Ø
t Cf
t Cr
t AD
A15 to A0
IOS
tASD
t SD
t AH
t ASI
AS, RD
(Read)
t ACC
D7 to D0
(Read)
t RDS
t WSD
t AS2
t WSW
t RDH
t SD
t AH
WR
t WDD
t WDS
t WDH
D7 to D0
(Write)
Figure 15-4. Basic Bus Cycle (without Wait States) in Expanded Modes
246
(2) Basic Bus Cycle (with 1 Wait State) in Expanded Modes
T1
T2
TW
T3
Ø
A15 to A0
IOS
AS, RD
D7 to D0
(Read)
WR
D7 to D0
(Write)
t WTS
t WTH
t WTS
t WTH
WAIT
Figure 15-5. Basic Bus Cycle (with 1 Wait State) in Expanded Modes
247
(3) E Clock Bus Cycle
Ø
t ED
t ED
E
t Er
t AD
t Ef
A15 to A0, IOS
t SD
t AS1
t AH
AS
t AD
t AD
RD, WR
t RDH
t RDS
t RDHE
D7 to D0
(Read)
t WDHE
D7 to D0
(Write)
Figure 15-6. E Clock Bus Cycle
15.3.2 Control Signal Timing
(1) Reset Input Timing
Ø
t RESS
t RESS
RES
t MDS
t RESW
MD1 and
MD0
Figure 15-7. Reset Input Timing
248
(2) Interrupt Input Timing
Ø
t NMIS
t NMIH
NMI
IRQi (Edge)
t NMIS
IRQi (Level)
t NMIW
NMI
IRQi
Note: i = 0 to 2
Figure 15-8. Interrupt Input Timing
249
(3) Clock Settling Timing
Ø
Vcc
STBY
tOSC1
tOSC1
RES
Figure 15-9. Clock Settling Timing
250
(4) Clock Settling Timing for Recovery from Software Standby Mode
Ø
NMI
IRQi
t OCS2
( i = 0, 1, 2 )
Figure 15-10. Clock Settling Timing for Recovery from Software Standby Mode
15.3.3 16-Bit Free-Running Timer Timing
(1) Free-Running Timer Input/Output Timing
Ø
Free - running
timer counter
Compare - match
t FTOD
FTOA, FTOB
t FTIS
FTI ( without
noise
canceler)
Figure 15-11. Free-Running Timer Input/Output Timing
251
(2) External Clock Input Timing for Free-Running Timer
Ø
t FTCS
FTCI
t FTCWL
t FTCWH
Figure 15-12. External Clock Input Timing for Free-Running Timer
15.3.4 8-Bit Timer Timing
(1) 8-Bit Timer Output Timing
Ø
Timer
counter
Compare - match
t TMOD
TMO1,
TMO0
Figure 15-13. 8-Bit Timer Output Timing
(2) 8-Bit Timer Clock Input Timing
Ø
t TMCS
t TMCS
TMCI0,
TMCI1
t TMCWL
t TMCWH
Figure 15-14. 8-Bit Timer Clock Input Timing
252
(3) 8-Bit Timer Reset Input Timing
Ø
t TMRS
TMRI0,
TMRI1
n
Timer
counter
H'00
Figure 15-15. 8-Bit Timer Reset Input Timing
15.3.5 Serial Communication Interface Timing
(1) SCI Input/Output Timing
t
Serial clock
SCK 0
SCK 1
Scyc
t TXD
Transmit
data
TxD 0
TxD 1
t RXS
t RXH
Receive
data
RxD 0
RxD 1
Figure 15-16. SCI Input/Output Timing (Synchronous Mode)
(2) SCI Input Clock Timing
t
SCK 1
SCK 0
SCKW
t Scyc
Figure 15-17. SCI Input Clock Timing
253
15.3.6 I/O Port Timing
Port read / write cycle
T1
T2
T3
Ø
t PRS
t PRH
Port 1
to
(Input)
Port 7
t PWD
Port 1*
to
(Output)
Port 7
* Except P46
Figure 15-18. I/O Port Input/Output Timing
15.3.7 Parallel Handshake Interface Timing
(1) Input Strobe Input Timing
P3 7 to P3 0
t HIS
t HIH
IS
t HISW
Figure 15-19. Input Strobe Input Timing
254
(2) Output Strobe Output Timing
Ø
t HOSD1
t HOSD2
OS
Figure 15-20. Output Strobe Output Timing
(3) Busy Output Timing
Ø
IS
t HBSOD1
t HBSOD2
BUSY
Figure 15-21. Busy Output Timing
255
256
Appendix A. CPU Instruction Set
A.1 Instruction Set List
Operation Notation
Rd8/16
General register (destination) (8 or 16 bits)
Rs8/16
General register (source) (8 or 16 bits)
Rn8/16
General register (8 or 16 bits)
CCR
Condition code register
N
N (negative) flag in CCR
Z
Z (zero) flag in CCR
V
V (overflow) flag in CCR
C
C (carry) flag in CCR
PC
Program counter
SP
Stack pointer
#xx:3/8/16
Immediate data (3, 8, or 16 bits)
d:8/16
Displacement (8 or 16 bits)
@aa:8/16
Absolute address (8 or 16 bits)
+
Addition
–
Subtraction
×
Multiplication
÷
Division
∧
AND logical
∨
OR logical
⊕
Exclusive OR logical
→
Move
¬
Not
Condition Code Notation
∆
Modified according to the instruction result
*
Undetermined (unpredictable)
0
Always cleared to "0"
—
Not affected by the instruction result
257
Table A-1. Instruction Set
MOV.B #xx:8,Rd
MOV.B Rs,Rd
MOV.B @Rs,Rd
MOV.B @(d:16,Rs),Rd
MOV.B @Rs+,Rd
B
B
B
B
B
MOV.B @aa:8,Rd
MOV.B @aa:16,Rd
MOV.B Rs,@Rd
MOV.B Rs,@(d:16,Rd)
MOV.B Rs,@–Rd
B
B
B
B
B
MOV.B Rs,@aa:8
MOV.B Rs,@aa:16
MOV.W #xx:16,Rd
MOV.W Rs,Rd
MOV.W @Rs,Rd
MOV.W @(d:16,Rs),Rd
MOV.W @Rs+,Rd
B
B
W
W
W
W
W
MOV.W @aa:16,Rd
MOV.W Rs,@Rd
MOV.W Rs,@(d:16,Rd)
MOV.W Rs,@–Rd
W
W
W
W
MOV.W Rs, @aa:16
POP Rd
W
W
PUSH Rs
W
MOVFPE @aa:16,Rd
B
MOVTPE Rs,@aa:16
B
EEPMOV
–
258
#xx:8 → Rd8
Rs8 → Rd8
@Rs16 → Rd8
@(d:16,Rs16) → Rd8
@Rs16 → Rd8
Rs16+1 → Rs16
@aa:8 → Rd8
@aa:16 → Rd8
Rs8 → @Rd16
Rs8 → @(d:16,Rd16)
Rd16–1 → Rd16
Rs8 → @Rd16
Rs8 → @aa:8
Rs8 → @aa:16
#xx:16 → Rd16
Rs16 → Rd16
@Rs16 → Rd16
@(d:16,Rs16) → Rd16
@Rs16 → Rd16
Rs16+2 → Rs16
@aa:16 → Rd16
Rs16 → @Rd16
Rs16 → @(d:16,Rd16)
Rd16–2 → Rd16
Rs16 → @Rd16
Rs16 → @aa:16
@SP → Rd16
SP+2 → SP
SP–2 → SP
Rs16 → @SP
@aa:16 → Rd
(Synchronized with E clock)
Rs → @aa:16
(Synchronized with E clock)
if R4L=0 then
Repeat @R5 → @R6
R5+1 → R5
R6+1 → R6
R4L–1 → R4L
Until R4L=0
else next
No. of States
Operation
#xx:8/16
Rn
@Rn
@(d:16, Rn)
@-Rn/@Rn+
@aa:8/16
@(d:8, PC)
@@aa
Implied
Mnemonic
Operand Size
Addressing mode/ instruction
length
Condition code
I
–
–
–
–
–
H
–
–
–
–
–
N
∆
∆
∆
∆
∆
Z
∆
∆
∆
∆
∆
V
0
0
0
0
0
C
–
–
–
–
–
2
2
4
6
6
2
4
–
–
–
–
–
–
–
–
–
–
∆
∆
∆
∆
∆
∆
∆
∆
∆
∆
0
0
0
0
0
–
–
–
–
–
4
6
4
6
6
2
4
–
–
–
–
–
–
–
–
–
–
–
–
–
–
∆
∆
∆
∆
∆
∆
∆
∆
∆
∆
∆
∆
∆
∆
0
0
0
0
0
0
0
–
–
–
–
–
–
–
4
6
4
2
4
6
6
4
–
–
–
–
–
–
–
–
∆
∆
∆
∆
∆
∆
∆
∆
0
0
0
0
–
–
–
–
6
4
6
6
4
2
–
–
–
–
∆
∆
∆
∆
0
0
–
–
6
6
2
–
–
∆
∆
0
–
6
4
–
–
∆
∆
0
–
4
–
–
∆
∆
0
–
[5
]
[5
]
–
–
–
–
–
[4]
2
2
2
4
2
2
4
2
4
2
2
4
2
2
4
2
4
–
Table A-1. Instruction Set (cont)
No. of States
Operation
#xx:8/16
Rn
@Rn
@(d:16, Rn)
@-Rn/@Rn+
@aa:8/16
@(d:8, PC)
@@aa
Mnemonic
Operand Size
Addressing mode/ instruction
length
Condition code
I
H
N
Z
V
C
∆
∆
∆
∆
∆
2
–
–
∆
∆
∆
∆
∆
2
2
2
–
[1]
∆
∆
∆
∆
2
–
∆
∆
[2] ∆
∆
2
2
–
∆
∆
[2] ∆
∆
2
Rd16+1 → Rd16
2
–
–
–
–
–
–
2
ADD.B #xx:8,Rd
B
Rd8+#xx:8 → Rd8
ADD.B Rs,Rd
B
Rs8+Rd8 → Rd8
ADD.W Rs,Rd
W
Rs16+Rd16 → Rd16
ADDX.B #xx:8,Rd
B
Rd8+#xx:8 +C → Rd8 2
ADDX.B Rs,Rd
B
Rd8+Rs8 +C → Rd8
ADDS.W #1,Rd
W
2
ADDS.W #2,Rd
W
Rd16+2 → Rd16
2
–
–
–
–
–
–
2
INC.B Rd
B
Rd8+1 → Rd8
2
–
–
∆
∆
∆
–
2
DAA.B Rd
B
Rd8 decimal adjust →
Rd8
2
–
*
∆
∆
*
[3] 2
SUB.B Rs,Rd
B
Rd8–Rs8 → Rd8
2
–
∆
∆
∆
∆
∆
SUB.W Rs,Rd
W
Rd16–Rs16 → Rd16
2
–
[1]
∆
∆
∆
∆
2
SUBX.B #xx:8,Rd
B
Rd8–#xx:8 –C → Rd8 2
–
∆
∆
[2] ∆
∆
2
SUBX.B Rs,Rd
B
Rd8–Rs8 –C → Rd8
2
–
∆
∆
[2] ∆
∆
2
SUBS.W #1,Rd
W
Rd16–1 → Rd16
2
–
–
–
–
–
–
2
2
2
SUBS.W #2,Rd
W
Rd16–2 → Rd16
2
–
–
–
–
–
–
DEC.B Rd
B
Rd8–1 → Rd8
2
–
–
∆
∆
∆
–
2
DAS.B Rd
B
Rd8 decimal adjust →
Rd8
2
–
*
∆
∆
*
–
2
NEG.B Rd
B
0–Rd → Rd
CMP.B #xx:8,Rd
B
Rd8–#xx:8
CMP.B Rs,Rd
B
Rd8–Rs8
CMP.W Rs,Rd
W
MULXU.B Rs,Rd
DIVXU.B Rs,Rd
–
∆
∆
∆
∆
∆
2
–
∆
∆
∆
∆
∆
2
2
–
∆
∆
∆
∆
∆
2
Rd16–Rs16
2
–
[1]
∆
∆
∆
∆
2
B
Rd8×Rs8 → Rd16
2
–
–
–
–
–
–
14
B
Rd16÷Rs8 → Rd16
(RdH:remainder,RdL:
quotient)
2
–
–
[6]
[7] –
–
14
–
–
∆
∆
0
–
2
–
–
∆
∆
0
–
2
–
–
∆
∆
0
–
2
–
–
∆
∆
0
–
2
–
–
∆
∆
0
–
2
2
2
AND.B #xx:8,Rd
B
Rd8∧#xx:8 → Rd8
AND.B Rs,Rd
B
Rd8∧Rs8 → Rd8
OR.B #xx:8,Rd
B
Rd8∨#xx:8 → Rd8
OR.B Rs,Rd
B
Rd8∨Rs8 → Rd8
XOR.B #xx:8,Rd
B
Rd8⊕#xx:8 → Rd8
XOR.B Rs,Rd
B
Rd8⊕Rs8 → Rd8
2
–
–
∆
∆
0
–
2
NOT.B Rd
B
Rd → Rd
2
–
–
∆
∆
0
–
2
2
2
2
2
2
259
SHAL.B Rd
B
Operation
SHAR.B Rd
B
SHLL.B Rd
B
SHLR.B Rd
B
ROTXR.B Rd
B
Z
V
C
∆
∆
∆
∆
2
2
–
–
∆
∆
0
∆
2
0
2
–
–
∆
∆
0
∆
2
C
2
–
–
0
∆
0
∆
2
2
–
–
∆
∆
0
∆
2
2
–
–
∆
∆
0
∆
2
2
–
–
∆
∆
0
∆
2
2
–
–
∆
∆
0
∆
2
–
–
–
–
–
–
2
–
–
–
–
–
–
8
–
–
–
–
–
–
8
–
–
–
–
–
–
2
–
–
–
–
–
–
8
–
–
–
–
–
–
8
–
–
–
–
–
–
2
–
–
–
–
–
–
8
b0
C
b0
0
b0
C
b7
b0
C
b7
b0
ROTL.B Rd
B
ROTR.B Rd
B
BSET #xx:3,Rd
B
(#xx:3 of Rd8) ← 1
BSET #xx:3,@Rd
B
(#xx:3 of @Rd16) ← 1
BSET #xx:3,@aa:8
B
(#xx:3 of @aa:8) ← 1
BSET Rn,Rd
B
(Rn8 of Rd8) ← 1
C
b7
b0
C
b7
b0
BSET Rn,@Rd
B
(Rn8 of @Rd16) ← 1
BSET Rn,@aa:8
B
(Rn8 of @aa:8) ← 1
BCLR #xx:3,Rd
B
(#xx:3 of Rd8) ← 0
BCLR #xx:3,@Rd
B
(#xx:3 of @Rd16) ← 0
BCLR #xx:3,@aa:8
B
(#xx:3 of @aa:8) ← 0
BCLR Rn,Rd
B
(Rn8 of Rd8) ← 0
BCLR Rn,@Rd
B
(Rn8 of @Rd16) ← 0
BCLR Rn,@aa:8
B
(Rn8 of @aa:8) ← 0
260
N
–
C
b7
B
H
–
b0
b7
ROTXL.B Rd
I
0
b7
Condition code
2
C
b7
No. of States
#xx:8/16
Rn
@Rn
@(d:16, Rn)
@-Rn/@Rn+
@aa:8/16
@(d:8, PC)
@@aa
Mnemonic
Operand Size
Addressing mode/ instruction
length
2
4
4
2
4
4
2
4
4
2
4
4
–
–
–
–
–
–
8
–
–
–
–
–
–
2
–
–
–
–
–
–
8
–
–
–
–
–
–
8
BNOT #xx:3,Rd
B
(#xx:3 of Rd8) ← ([[RI
5G)
BNOT #xx:3,@Rd
B
(#xx:3 of @Rd16) ← ([[
RI#5G)
BNOT #xx:3,@aa:8
B
(#xx:3 of @aa:8) ← ([[
RI#DD)
2
4
–
4
No. of States
Operation
#xx:8/16
Rn
@Rn
@(d:16, Rn)
@-Rn/@Rn+
@aa:8/16
@(d:8, PC)
@@aa
Mnemonic
Operand Size
Addressing mode/ instruction
length
Condition code
I
H
N
Z
V
C
–
–
–
–
–
–
–
–
–
–
–
8
–
–
–
–
–
–
2
8
261
Table A-1. Instruction Set (cont)
BNOT Rn,Rd
B
(Rn8 of Rd8) ← (5QRI
5G)
BNOT Rn,@Rd
B
(Rn8 of @Rd16) ←
(5QRI#5G)
BNOT Rn,@aa:8
B
2
4
(Rn8 of @aa:8) ← (5Q
)
4
No. of States
Operation
#xx:8/16
Rn
@Rn
@(d:16, Rn)
@-Rn/@Rn+
@aa:8/16
@(d:8, PC)
@@aa
Mnemonic
Operand Size
Addressing mode/ instruction length
Condition code
I
H
N
Z
V
C
–
–
–
–
–
–
2
–
–
–
–
–
–
8
–
–
–
–
–
–
8
RI#DD
BTST #xx:3,Rd
B
([[RI5G) → Z
BTST #xx:3,@Rd
B
([[RI#5G) → Z
BTST #xx:3,@aa:8
B
([[RI#DD) → Z
BTST Rn,Rd
B
(5QRI5G) → Z
BTST Rn,@Rd
B
(5QRI#5G) → Z
BTST Rn,@aa:8
B
(5QRI#DD) → Z
BLD #xx:3,Rd
B
(#xx:3 of Rd8) → C
BLD #xx:3,@Rd
B
(#xx:3 of @Rd16) → C
BLD #xx:3,@aa:8
B
(#xx:3 of @aa:8) → C
BILD #xx:3,Rd
B
([[RI5G) → C
BILD #xx:3,@Rd
B
([[RI#5G) → C
BILD #xx:3,@aa:8
B
([[RI#DD) → C
BST #xx:3,Rd
B
C → (#xx:3 of Rd8)
BST #xx:3,@Rd
B
C → (#xx:3 of @Rd16)
BST #xx:3,@aa:8
B
C → (#xx:3 of @aa:8)
BIST #xx:3,Rd
B
&
→ (#xx:3 of Rd8)
BIST #xx:3,@Rd
B
&
→ (#xx:3 of @Rd16)
BIST #xx:3,@aa:8
B
&
→ (#xx:3 of @aa:8)
BAND #xx:3,Rd
B
C∧(#xx:3 of Rd8) → C
BAND #xx:3,@Rd
B
C∧(#xx:3 of @Rd16) →
C
BAND #xx:3,@aa:8
B
C∧(#xx:3 of @aa:8) →
C
BIAND #xx:3,Rd
B
C∧([[RI5G) → C
BIAND #xx:3,@Rd
B
C∧([[RI#5G) →
C
BIAND #xx:3, @aa:8
B
C∧([[RI#DD) →
C
BOR #xx:3,Rd
B
C∨(#xx:3 of Rd8) → C
BOR #xx:3,@Rd
B
C∨(#xx:3 of @Rd16) →
C
BOR #xx:3,@aa:8
B
C∨(#xx:3 of @aa:8) →
C
BIOR #xx:3,Rd
B
C∨([[RI5G) → C
262
2
4
4
2
4
4
2
4
4
2
4
4
2
4
4
2
4
4
2
4
4
2
4
4
2
4
4
2
–
–
–
∆
–
–
2
–
–
–
∆
–
–
6
–
–
–
∆
–
–
6
–
–
–
∆
–
–
2
–
–
–
∆
–
–
6
–
–
–
∆
–
–
6
–
–
–
–
–
∆
2
–
–
–
–
–
∆
6
–
–
–
–
–
∆
6
–
–
–
–
–
∆
2
–
–
–
–
–
∆
6
–
–
–
–
–
∆
6
–
–
–
–
–
–
2
–
–
–
–
–
–
8
–
–
–
–
–
–
8
–
–
–
–
–
–
2
–
–
–
–
–
–
8
–
–
–
–
–
–
8
–
–
–
–
–
∆
2
–
–
–
–
–
∆
6
–
–
–
–
–
∆
6
–
–
–
–
–
∆
2
–
–
–
–
–
∆
6
–
–
–
–
–
∆
6
–
–
–
–
–
∆
2
–
–
–
–
–
∆
6
–
–
–
–
–
∆
6
–
–
–
–
–
∆
2
Table A-1. Instruction Set (cont)
Branching
Condition
BIOR #xx:3,@Rd
BIOR #xx:3, @aa:8
BXOR #xx:3,Rd
BXOR #xx:3,@Rd
BXOR #xx:3, @aa:8
BIXOR #xx:3,Rd
BIXOR #xx:3,@Rd
BIXOR #xx:3, @aa:8
BRA d:8 (BT d:8)
BRNd:8 (BF d:8)
BHI d:8
B
B
B
B
B
B
B
B
–
–
–
BLS d:8
BCC d:8 (BHS d:8)
BCS d:8 (BLO d:8)
BNE d:8
BEQ d:8
BVC d:8
BVS d:8
BPL d:8
BMI d:8
BGE d:8
BLT d:8
BGT d:8
BLE d:8
JMP @Rn
JMP @aa:16
JMP @@aa:8
BSR d:8
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
C∨([[RI#5G) → C
C∨([[RI#DD) → C
C⊕(#xx:3 of Rd8) → C
2
C⊕(#xx:3 of @Rd16) → C
C⊕(#xx:3 of @aa:8) → C
2
C⊕([[RI5G) → C
C⊕([[RI#5G) → C
C⊕([[RI#DD) → C
PC ← PC+d:8
PC ← PC+2
if
C∨Z = 0
condition
is true
then
PC ←
PC+d:8
else next;
C∨Z = 1
C=0
C=1
Z=0
Z=1
V=0
V=1
N=0
N=1
N⊕V = 0
N⊕V = 1
Z∨(N⊕V) = 0
Z∨(N⊕V) = 1
PC ← Rn16
PC ← aa:16
PC ← @aa:8
SP–2 → SP
PC → @SP
PC ← PC+d:8
4
4
4
4
4
4
2
2
Condition code
I
H
N
Z
V
C
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
∆
∆
∆
∆
∆
∆
∆
–
–
–
6
6
2
6
6
2
6
6
4
4
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
4
6
8
6
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
4
2
2
No. of States
Operation
#xx:8/16
Rn
@Rn
@(d:16, Rn)
@-Rn/@Rn+
@aa:8/16
@(d:8, PC)
@@aa
Mnemonic
Operand Size
Addressing mode/ instruction
length
–
–
–
–
∆
263
Table A-1. Instruction Set (cont)
No. of States
Operation
#xx:8/16
Rn
@Rn
@(d:16, Rn)
@-Rn/@Rn+
@aa:8/16
@(d:8, PC)
@@aa
Implied
Mnemonic
Operand Size
Addressing mode/ instruction length
Condition code
I
H
N
Z
V
C
–
–
–
–
–
–
6
–
–
–
–
–
–
8
–
–
–
–
–
–
8
2
–
–
–
–
–
–
8
CCR ← @SP
SP+2 → SP
PC ← @SP
SP+2 → SP
2
∆
∆
∆
∆
∆
∆
10
Transit to sleep
mode.
2
–
–
–
–
–
–
2
JSR @Rn
–
SP–2 → SP
PC → @SP
PC ← Rn16
JSR @aa:16
–
SP–2 → SP
PC → @SP
PC ← aa:16
JSR @@aa:8
–
SP–2 → SP
PC → @SP
PC ← @aa:8
RTS
–
PC ← @SP
SP+2 → SP
RTE
–
SLEEP
–
LDC #xx:8,CCR
B
#xx:8 → CCR
LDC Rs,CCR
B
Rs8 → CCR
2
4
2
∆
∆
∆
∆
∆
∆
2
2
∆
∆
∆
∆
∆
∆
2
2
2
2
STC CCR,Rd
B
CCR → Rd8
–
–
–
–
–
–
ANDC #xx:8,CCR
B
CCR∧#xx:8 → CCR
2
∆
∆
∆
∆
∆
∆
2
ORC #xx:8,CCR
B
CCR∨#xx:8 → CCR
2
∆
∆
∆
∆
∆
∆
2
XORC #xx:8,CCR
B
CCR⊕#xx:8 → CCR
2
∆
∆
∆
∆
∆
∆
2
NOP
–
PC ← PC+2
–
–
–
–
–
–
2
2
Notes: The number of states is the number of states required for execution when the instruction
and its operands are located in on-chip memory.
[1] Set to 1 when there is a carry or borrow from bit 11; otherwise cleared to 0.
[2] If the result is zero, the previous value of the flag is retained; otherwise the flag is
cleared to 0.
[3] Set to 1 if decimal adjustment produces a carry; otherwise cleared to 0.
[4] The number of states required for execution is 4n+8 (n = value of R4L)
[5] These instructions transfer data in synchronization with the E clock. The number of
states varies depending on the synchronization delay.
[6] Set to 1 if the divisor is negative; otherwise cleared to 0.
[7] Set to 1 if the divisor is zero; otherwise cleared to 0.
264
A.2 Operation Code Map
Table A-2 is a map of the operation codes contained in the first byte of the instruction code (bits
15 to 8 of the first instruction word).
Some pairs of instructions have identical first bytes. These instructions are differentiated by the
first bit of the second byte (bit 7 of the first instruction word).
Instruction when first bit of byte 2 (bit 7 of first instruction word ) is "0".
Instruction when first bit of byte 2 (bit 7 of first instruction word ) is "1".
265
266
0
BOR
BIOR
BXOR
BIXOR
BAND
BIAND
BSR
RTS
BST
BLD
BILD
BIST
BEQ
OR
XOR
AND
MOV
D
E
F
B
C
CMP
SUBX
A
ADDX
BTST
BNE
RTE
BCS* 2
BCC* 2
NEG
9
BCLR
BLS
ROTR
ADD
7
BNOT
BHI
ROTL
8
BSET
MULXU
5
6
DIVXU
SHAR
BRN* 2
SHAL
NOT
LDC
AND
ANDC
XOR
XORC
OR
ORC
LDC
ROTXR
STC
ROTXL
SLEEP
SHLR
NOP
BRA* 2
SHLL
7
6
5
4
3
2
1
0
4
3
2
1
LO
BVC
MOV
8
ADD
SUB
MOV
BVS
9
ADDS
BPL
JMP
EEPMOV
BMI
SUBS
INC
DEC
B
A
* 1 The MOVFPE and MOVTPE instructions are identical to MOV instructions in the first byte and first bit of the second byte (bits 15 to 7 of the instruction word). The PUSH and POP
instructions are identical in machine language to MOV instructions.
* 2 The BT, BF, BHS, and BLO instructions are identical in machine language to BRA, BRN, BCC, and BCS, respectively.
HI
MOV* 1
BGE
C
MOV
BLT
JSR
BGT
SUBX
ADDX
E
Bit manipulation instruction
CMP
D
BLE
DAS
DAA
F
Table A-2. Operation Code Map
A.3 Number of States Required for Execution
The tables below can be used to calculate the number of states required for instruction
execution. Table A-3 indicates the number of states required for each cycle (instruction fetch,
branch address read, stack operation, byte data access, word data access, internal operation).
Table A-4 indicates the number of cycles of each type occurring in each instruction. The total
number of states required for execution of an instruction can be calculated from these two tables
as follows:
Execution states = I × SI + J × SJ + K × SK + L × SL + M × SM + N × SN
Examples: Mode 1 (on-chip ROM disabled), stack located in external memory, 1 wait state
inserted in external memory access.
1. BSET #0, @FFC7
From table A-4: I = L = 2, J = K = M = N= 0
From table A-3: SI = 8, SL = 3
Number of states required for execution: 2 × 8 + 2 × 3 =22
2. JSR @@30
From table A-4: I = 2, J = K = 1, L = M = N = 0
From table A-3: SI = SJ = SK = 8
Number of states required for execution: 2 × 8 + 1 × 8 + 1 × 8 = 32
Table A-3. Number of States Taken by Each Cycle in Instruction Execution
Access location
Execution status
(instruction cycle)
Instruction fetch
On-chip memory On-chip reg. field
External memory
SI
Branch address read SJ
6
6 + 2m
Stack operation
SK
2
Byte data access
SL
3
3 + m (note 2)
Word data access
SM
6
6 + 2m
Internal operation
SN
2
Notes: 1. m: Number of wait states inserted in access to external device.
2. The byte data access cycle to an external device by the MOVFPE and MOVTPE
instructions requires 9 to 16 states since it is synchronized with the E clock. See
section 13, E-Clock Interface for timing details.
267
Table A-4. Number of Cycles in Each Instruction
Instruction
Mnemonic
Instruction Branch
addr. read
fetch
J
I
ADD
ADD.B #xx:8, Rd
1
ADD.B Rs, Rd
1
ADD.W Rs, Rd
1
ADDS
ADDS.W #1/2, Rd
1
ADDX
ADDX.B #xx:8, Rd
1
ADDX.B Rs, Rd
1
AND
AND.B #xx:8, Rd
1
AND.B Rs, Rd
1
Stack
operation
K
Byte data
access
L
ANDC
ANDC #xx:8, CCR
1
BAND
BAND #xx:3, Rd
1
BAND #xx:3, @Rd
2
1
BAND #xx:3, @aa:8 2
1
Bcc
BRA d:8 (BT d:8)
BRN d:8 (BF d:8)
BHI d:8
BLS d:8
BCC d:8 (BHS d:8)
BCS d:8 (BLO d:8)
BNE d:8
BEQ d:8
BVC d:8
BVS d:8
BPL d:8
BMI d:8
BGE d:8
BLT d:8
BLE d:8
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
BCLR
BCLR #xx:3, Rd
BCLR #xx:3, @Rd
BCLR #xx:3, @aa:8
BCLR Rn, Rd
BCLR Rn, @Rd
BCLR Rn, @aa:8
1
2
2
1
2
2
Note: Blank entries are all zero.
268
2
2
2
2
Word data Internal
operation
access
N
M
Table A-4. Number of Cycles in Each Instruction (cont.)
Instruction
BIAND
BILD
BIOR
BIST
BIXOR
BLD
BNOT
BOR
BSET
Mnemonic
Instruction
fetch
I
Branch
addr. read
J
Stack
operation
K
Byte data
access
L
BIAND #xx:3, Rd
1
BIAND #xx:3, @Rd
2
1
BIAND #xx:3, @aa:8
2
1
BILD #xx:3, Rd
1
BILD #xx:3, @Rd
2
1
BILD #xx:3, @aa:8
2
1
BIOR #xx:3 Rd
1
BIOR #xx:3 @Rd
2
1
BIOR #xx:3 @aa:8
2
1
BIST #xx:3, Rd
1
BIST #xx:3, @Rd
2
2
BIST #xx:3, @aa:8
2
2
BIXOR #xx:3, Rd
1
BIXOR #xx:3, @Rd
2
1
BIXOR #xx:3, @aa:8
2
1
BLD #xx:3, Rd
1
BLD #xx:3, @Rd
2
1
BLD #xx:3, @aa:8
2
1
BNOT #xx:3, Rd
1
BNOT #xx:3, @Rd
2
2
BNOT #xx:3, @aa:8
2
2
BNOT Rn, Rd
1
BNOT Rn, @Rd
2
2
BNOT Rn, @aa:8
2
2
BOR #xx:3, Rd
1
BOR #xx:3, @Rd
2
1
BOR #xx:3, @aa:8
2
1
BSET #xx:3, Rd
1
BSET #xx:3, @Rd
2
2
BSET #xx:3, @aa:8
2
2
BSET Rn, Rd
1
BSET Rn, @Rd
2
2
BSET Rn, @aa:8
2
2
Word data
access
M
Internal
operation
N
Note: Blank entries are all zero.
269
Table A-4. Number of Cycles in Each Instruction (cont.)
Instruction
Mnemonic
BSR
BSR d:8
2
BST
BST #xx:3, Rd
1
BST #xx:3, @Rd
2
2
BST #xx:3, @aa:8
2
2
BTST #xx:3, Rd
1
BTST
BXOR
CMP
Instruction
fetch
I
2
1
1
BTST Rn, Rd
1
BTST Rn, @Rd
2
1
BTST Rn, @aa:8
2
1
BXOR #xx:3, Rd
1
BXOR #xx:3, @Rd
2
1
BXOR #xx:3, @aa:8
2
1
CMP.B #xx:8, Rd
1
CMP.B Rs, Rd
1
1
DAS
DAS.B Rd
1
DEC
DEC.B Rd
1
DIVXU
DIVXU.B Rs, Rd
1
EEPMOV
EEPMOV
2
INC
INC.B Rd
1
JMP
JMP @Rn
2
JMP @aa:16
2
MOV
270
Internal
operation
N
6
*1
2n+2
1
JMP @@aa:8
2
JSR @Rn
2
1
JSR @aa:16
2
1
JSR @@aa:8
2
LDC #xx:8, CCR
1
LDC Rs, CCR
1
MOV.B #xx:8, Rd
1
1
1
1
1
1
MOV.B Rs, Rd
1
MOV.B @Rs, Rd
1
1
MOV.B @(d:16,Rs), Rd
2
1
Note: Blank entries are all zero.
Word data
access
M
1
2
1
LDC
Byte data
access
L
BTST #xx:3, @aa:8
DAA.B Rd
JSR
Stack
operation
K
BTST #xx:3, @Rd
CMP.W Rs, Rd
DAA
Branch
addr. read
J
Table A-4. Number of Cycles in Each Instruction (cont.)
Instruction
fetch
I
Branch
addr. read
J
Stack
operation
K
Byte data
access
L
Instruction
Mnemonic
MOV
MOV.B @Rs+, Rd
1
1
MOV.B @aa:8, Rd
1
1
MOV.B @aa:16, Rd
2
1
MOV.B Rs, @Rd
1
1
MOV.B Rs, @(d:16, Rd)
2
1
MOV.B Rs, @–Rd
1
1
MOV.B Rs, @aa:8
1
1
MOV.B Rs, @aa:16
2
1
MOV.W #xx:16, Rd
2
MOV.W Rs, Rd
1
Word data
access
M
1
1
MOV.W @Rs, Rd
1
1
MOV.W @(d:16, Rs), Rd
2
1
MOV.W @Rs+, Rd
1
1
MOV.W @aa:16, Rd
2
1
MOV.W Rs, @Rd
1
1
MOV.W Rs, @(d:16, Rd)
2
1
MOV.W Rs, @–Rd
1
1
MOV.W Rs, @aa:16
2
1
MOVFPE
MOVFPE @aa:16, Rd
2
1
MOVTPE
MOVTPE.Rs, @aa:16
2
1
MULXU
MULXU.Rs, Rd
1
NEG
NEG.B Rd
1
NOP
NOP
1
NOT
NOT.B Rd
1
OR.B #xx:8, Rd
1
OR.B Rs, Rd
1
OR
Internal
operation
N
1
1
*2
*2
6
ORC
ORC #xx:8, CCR
1
ROTL
ROTL.B Rd
1
ROTR
ROTR.B Rd
1
ROTXL
ROTXL.B Rd
1
ROTXR
ROTXR.B Rd
1
RTE
RTE
2
2
1
RTS
RTS
2
1
1
Note: Blank entries are all zero.
271
Table A-4. Number of Cycles in Each Instruction (cont.)
Instruction
Branch
Stack
Byte data
Word data
Internal
fetch
addr. read
operation
access
access
operation
J
K
L
M
N
Instruction
Mnemonic
I
SHAL
SHAL.B Rd
1
SHAR
SHAR.B Rd
1
SHLL
SHLL.B Rd
1
SHLR
SHLR.B Rd
1
SLEEP
SLEEP
1
STC
STC CCR, Rd
1
SUB
SUBS
SUBX
XOR
XORC
SUB.B Rs, Rd
1
SUB.W Rs, Rd
1
SUBS.W #1/2, Rd
1
SUBX.B #xx:8, Rd 1
SUBX.B Rs, Rd
1
XOR.B #xx:8, Rd
1
XOR.B Rs, Rd
1
XORC #xx:8, CCR 1
Notes:
*1 n: Initial value in R4L. Source and destination are accessed n + 1 times each.
*2 Data access requires 9 to 16 states.
Blank entries are all zero.
272
Appendix B. Register Field
B.1 Register Addresses and Bit Names
Bit names
Addr.
(last
byte)
Register
name
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
H'80
H'81
H'82
H'83
H'84
H'85
H'86
H'87
H'88
H'89
H'8A
H'8B
H'8C
H'8D
H'8E
H'8F
Module
External
addresses (in
expanded
modes)
H'90
TCR
ICIE
OCIEB
OCIEA
OVIE
OEB
OEA
CKS1
CKS0
H'91
TCSR
ICF
OCFB
OCFA
OVF
OLVLB
OLVLA
IEDG
CCLRA
H'92
FRC (H)
H'93
FRC (L)
H'94
OCRA (H)
H'95
OCRA (L)
H'96
OCRB (H)
H'97
OCRB (L)
H'98
ICR (H)
H'99
ICR (L)
FRT
H'9A
H'9B
H'9C
H'9D
H'9E
H'9F
Notes: FRT: 16-Bit Free-Running Timer
(Continued on next page)
273
(Continued from previous page)
Bit names
Addr.
(last
Register
byte)
name
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Module
H'A0
External
H'A1
addresses (in
H'A2
expanded
H'A3
modes)
H'A4
H'A5
H'A6
H'A7
H'A8
H'A9
H'AA
H'AB
H'AC
H'AD
H'AE
H'AF
H'B0
P1DDR
P17DDR P16DDR
P15DDR
P14DDR
P13DDR
P12DDR
P11DDR
P10DDR
Port 1
H'B1
P2DDR
P27DDR P26DDR
P25DDR
P24DDR
P23DDR
P22DDR
P21DDR
P20DDR
Port 2
H'B2
P1DR
P17
P16
P15
P14
P13
P12
P11
P10
Port 1
H'B3
P2DR
P27
P26
P25
P24
P23
P22
P21
P20
Port 2
H'B4
P3DDR
P37DDR P36DDR
P35DDR
P34DDR
P33DDR
P32DDR
P31DDR
P30DDR
Port 3
H'B5
P4DDR
P47DDR P46DDR
P45DDR
P44DDR
P43DDR
P42DDR
P41DDR
P40DDR
Port 4
H'B6
P3DR
P37
P36
P35
P34
P33
P32
P31
P30
Port 3
H'B7
P4DR
P47
P46
P45
P44
P43
P42
P41
P40
Port 4
H'B8
P5DDR
—
—
P55DDR
P54DDR
P53DDR
P52DDR
P51DDR
P50DDR
Port 5
H'B9
P6DDR
—
P66DDR
P65DDR
P64DDR
P63DDR
P62DDR
P61DDR
P60DDR
Port 6
H'BA
P5DR
—
—
P55
P54
P53
P52
P51
P50
Port 5
H'BB
P6DR
—
P66
P65
P64
P63
P62
P61
P60
Port 6
H'BC
P7DDR
P77DDR P76DDR
P75DDR
P74DDR
P73DDR
P72DDR
P71DDR
P70DDR
Port 7
H'BD
—
—
—
—
—
—
—
—
—
H'BE
P7DR
P77
P76
P75
P74
P73
P72
P71
P70
H'BF
—
—
—
—
—
—
—
—
—
—
Port 7
—
(Continued on next page)
274
(Continued from preceding page)
Bit names
Addr.
(last
byte)
Register
name
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Module
H'C4
SYSCR
SSBY
STS2
STS1
STS0
—
NMIEG
—
RAME
System
control
H'C5
MDCR
—
—
—
—
—
—
MDS1
MDS0
H'C6
ISCR
—
IRQ2EG
IRQ1EG
IRQ0EG
—
IRQ2SC
IRQ1SC
IRQ0SC
H'C7
IER
—
—
—
—
—
IRQ2E
IRQ1E
IRQ0E
H'C8
TCR
CMIEB
CMIEA
OVIE
CCLR1
CCLR0
CKS2
CKS1
CKS0
H'C9
TCSR
CMFB
CMFA
OVF
—
OS3
OS2
OS1
OS0
H'CA
TCORA
H'C0
H'C1
H'C2
H'C3
H'CB
TCORB
H'CC
TCNT
H'CD
—
—
—
—
—
—
—
—
—
H'CE
—
—
—
—
—
—
—
—
—
H'CF
—
—
—
—
—
—
—
—
—
H'D0
TCR
CMIEB
CMIEA
OVIE
CCLR1
CCLR0
CKS2
CKS1
CKS0
H'D1
TCSR
CMFB
CMFA
OVF
—
OS3
OS2
OS1
OS0
H'D2
TCORA
H'D3
TCORB
H'D4
TCNT
H'D5
—
—
—
—
—
—
—
—
—
H'D6
—
—
—
—
—
—
—
—
—
H'D7
—
—
—
—
—
—
—
—
—
H'D8
SMR
C/$
CHR
PE
O/(
STOP
—
CKS1
CKS0
H'D9
BRR
H'DA
SCR
TIE
RIE
TE
RE
—
—
CKE1
CKE0
H'DB
TDR
H'DC
SSR
TDRE
RDRF
ORER
FER
PER
—
—
—
H'DD
RDR
H'DE
—
—
—
—
—
—
—
—
—
H'DF
—
—
—
—
—
—
—
—
—
TMR0
TMR1
SCI0
(Continued on next page)
Notes: TMR1: 8-Bit Timer channel 0
TMR1: 8-Bit Timer channel 1
SCI0: Serial Communication Interface channel 0
275
(Continued from preceding page)
Bit names
Addr.
(last
byte)
Register
name
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Module
H'E0
SMR
C/$
CHR
PE
O/(
STOP
—
CKS1
CKS0
SCI1
H'E1
BRR
H'E2
SCR
TIE
RIE
TE
RE
—
—
CKE1
CKE0
H'E3
TDR
H'E4
SSR
TDRE
RDRF
ORER
FER
PER
—
—
—
H'E5
RDR
H'E6
—
—
—
—
—
—
—
—
—
H'E7
—
—
—
—
—
—
—
—
—
H'FE
HCSR
ISF
ISIE
OSE
OSS
LTE
BSE
—
—
Handshaking
H'FF
FNCR
—
—
—
—
—
—
NCS1
NCS0
FRT
H'E8
H'E9
H'EA
H'EB
H'EC
H'ED
H'EE
H'EF
H'F0
H'F1
H'F2
H'F3
H'F4
H'F5
H'F6
H'F7
H'F8
H'F9
H'FA
H'FB
H'FC
H'FD
Note: SCI1: Serial Communication Interface channel 1
FRT: 16-bit Free-Running Timer
276
B.2 Register Descriptions
Register name
Abbreviation of
register name
Bit N0.
Initial value
Address onto which register
is mapped
TCR - Timer Control Register
Bit
Initial value
Read/Write
7
ICIE
0
R/W
H'FF90
6
OCIEB
5
OCIEA
4
OVIE
0
R/W
0
R/W
0
R/W
3
OEB
0
R/W
FRT
2
OEA
0
R/W
0
CKS2
0
R/W
0
R/W
Name of on-chip
supporting module
Bit names (abbreviations).
Bits marked "-" are reserved.
Bits 1 and 0 - Clock Select
(CKS1 and CKS0)
0 0 Ø/2 Internal clock source
0 1 Ø/8 Internal clock source
1 0 Ø/32 Internal clock source
1 1 External clock source
( rising edge )
Type of access permitted
R
W
R/W
1
CKS1
Read only
Write only
Read or write
Output Enable A (OEA)
0 Output compare A output is disabled.
1 Output compare A output is enabled.
Output Enable B (OEB)
0 Output compare B output is disabled.
1 Output compare B output is enabled.
Full name of bit
Description of bit function
Timer overflow Interrupt Enable
0 Timer overflow interrupt request is disabled.
1 Timer overflow interrupt request is enabled.
Output Compare Interrupt A Enable
0 Output compare interrupt request A is disabled.
1 Output compare interrupt request A is enabled.
Output Compare Interrupt B Enable
0 Output compare interrupt request B is disabled.
1 Output compare interrupt request B is enabled.
Input Capture Interrupt Enable
0 Input capture interrupt request is disabled.
1 Input capture interrupt request is enabled.
277
TCR—Timer Control Register
Bit
Initial value
Read/Write
7
ICIE
0
R/W
H’FF90
6
OCIEB
5
OCIEA
4
OVIE
0
R/W
0
R/W
0
R/W
3
OEB
0
R/W
FRT
2
OEA
0
R/W
1
CKS1
0
CKS2
0
R/W
0
R/W
Bits 1 and 0 - Clock Select
(CKS1 and CKS0)
0 0 Ø/2 Internal clock source
0 1 Ø/8 Internal clock source
1 0 Ø/32 Internal clock source
1 1 External clock source (rising edge)
Output Enable A (OEA)
0 Output compare A output is disabled.
1 Output compare A output is enabled.
Output Enable B (OEB)
0 Output compare B output is disabled.
1 Output compare B output is enabled.
Timer overflow Interrupt Enable
0 Timer overflow interrupt request is disabled.
1 Timer overflow interrupt request is enabled.
Output Compare Interrupt A Enable
0 Output compare interrupt request A is disabled.
1 Output compare interrupt request A is enabled.
Output Compare Interrupt B Enable
0 Output compare interrupt request B is disabled.
1 Output compare interrupt request B is enabled.
Input Capture Interrupt Enable
0 Input capture interrupt request is disabled.
1 Input capture interrupt request is enabled.
278
TCSR—Timer Control/Status Register
Bit
Initial value
Read/Write
H’FF91
FRT
7
6
5
4
3
2
1
0
ICF
OCFB
OCFA
OVF
OLVLB
OLVLA
IEDG
CCLRA
0
R/(W)*
0
R/(W)*
0
R/W
0
R/W
0
R/W
0
R/W
0
R/(W)*
0
R/(W)*
Counter clear A
0 FRC is not cleared.
1 FRC is cleared at compare-match A.
Input Edge Select
0 Falling edge of FTI is valid.
1 Rising edge of FTI is valid.
Output Level A
0 Compare-match A causes 0 output.
1 Compare-match A causes 1 output.
Output Level B
0 Compare-match B causes 0 output.
1 Compare-match B causes 1 output.
Timer Overflow Flag
0 Cleared by reading OVF = 1, then writing 0.
1 Set when FRC changes from H'FFFF to H'0000.
Out Compare Flag A
0 Cleared by reading OCFA = 1, then writing 0.
1 Set when FRC = OCRA.
Out Compare Flag B
0 Cleared by reading OCFB = 1, then writing 0.
1 Set when FRC = OCRB.
Input Capture Flag
0 Cleared by reading ICF = 1, then writing 0.
1 Set when FTIA input causes FRC to be copied to ICR.
* Software can write a 0 in bits 7 to 4 to clear the flags, but cannot write a 1 in these bits.
279
FRC (H and L)—Free-Running Counter
Bit
7
6
5
H’FF92, H’FF93
4
3
FRT
2
1
0
Initial value
0
0
0
0
0
0
0
0
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
H’FF94, H’FF95
FRT
Count value
OCRA (H and L)—Output Compare Register A
Bit
7
6
5
4
3
2
1
0
Initial value
1
1
1
1
1
1
1
1
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Continually compared with FRC. OCFA is set to 1 when OCRA = FRC.
OCRB (H and L)—Output Compare Register B
H’FF96, H’FF97
FRT
Bit
7
6
5
4
3
2
1
0
Initial value
1
1
1
1
1
1
1
1
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Continually compared with FRC. OCFB is set to 1 when OCRB = FRC.
ICR (H and L)—Input Capture Register
H’FF98, H’FF99
FRT
Bit
7
6
5
4
3
2
1
0
Initial value
0
0
0
0
0
0
0
0
Read/Write
R
R
R
R
R
R
R
R
Contains FRC count captured on FTI input.
280
P1DDR—Port 1 Data Direction Register
7
H’FFB0
Port 1
6
5
4
3
P16DDR
P15DDR
P14DDR
P13DDR
2
P12DDR
1
1
1
1
1
1
1
1
Modes 2 and 3
Initial value
0
0
0
0
0
0
0
0
Read/Write
W
W
W
W
W
W
W
W
Bit
P17DDR
1
0
P11DDR P10DDR
Mode 1
Initial value
Read/Write
Port 1 Input / Output Control
0 Input port
1 Output port
P1DR—Port 1 Data Register
H’FFB2
Port 1
Bit
7
P17
6
P16
5
P15
4
P14
3
P13
2
P12
1
P11
0
P10
Initial value
Read/Write
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
P2DDR—Port 2 Data Direction Register
Bit
H’FFB1
Port 2
6
5
2
P25DDR
4
P24DDR
3
P26DDR
P23DDR
P22DDR
1
1
1
1
1
1
1
1
Modes 2 and 3
Initial value
0
0
0
0
0
0
0
0
Read/Write
W
W
W
W
W
W
W
W
7
P27DDR
1
0
P21DDR P20DDR
Mode 1
Initial value
Read/Write
Port 2 Input / Output Control
0 Input port
1 Output port
281
P2DR—Port 2 Data Register
Bit
H’FFB3
Port 2
7
6
5
4
3
2
1
0
P27
P26
P25
P24
P23
P22
P21
P20
Initial value
0
0
0
0
0
0
0
0
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
P3DDR—Port 3 Data Direction Register
7
Bit
P37DDR
H’FFB4
Port 3
6
5
4
3
P36DDR
P35DDR
P34DDR
P33DDR
2
P32DDR
1
0
P31DDR P30DDR
Initial value
0
0
0
0
0
0
0
0
Read/Write
W
W
W
W
W
W
W
W
Port 3 Input / Output Control
0 Input port
1 Output port
P3DR—Port 3 Data Register
Bit
H’FFB6
Port 3
7
6
5
4
3
2
1
0
P37
P36
P35
P34
P33
P32
P31
P30
Initial value
0
0
0
0
0
0
0
0
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
282
P4DDR—Port 4 Data Direction Register
7
Bit
P47DDR
H’FFB5
Port 4
6
5
4
3
P46DDR
P45DDR
P44DDR
P43DDR
2
P42DDR
1
0
P41DDR P40DDR
Modes 1 and 2
Initial value
1
0
0
0
0
0
0
0
Read/Write
W
W
W
W
W
W
W
W
Mode 3
Initial value
0
0
0
0
0
0
0
0
Read/Write
W
W
W
W
W
W
W
W
Port 4 Input / Output Control
0 Input port
1 Output port
P4DR—Port 4 Data Register
Bit
H’FFB7
Port 4
7
6
5
4
3
2
1
0
P47
P46
P45
P44
P43
P42
P41
P40
Initial value
0
0
0
0
0
0
0
0
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
P5DDR—Port 5 Data Direction Register
Bit
Initial value
Read/Write
7
1
6
1
H’FFB8
5
4
3
P55DDR
P54DDR
P53DDR
Port 5
2
P52DDR
1
0
P51DDR P50DDR
0
0
0
0
0
0
W
W
W
W
W
W
Port 5 Input / Output Control
0 Input port
1 Output port
283
P5DR—Port 5 Data Register
Bit
H’FFBA
Port 5
7
6
5
4
3
2
1
0
—
—
P55
P54
P53
P52
P51
P50
Initial value
1
1
0
0
0
0
0
0
Read/Write
—
—
R/W
R/W
R/W
R/W
R/W
R/W
P6DDR—Port 6 Data Direction Register
7
Bit
Initial value
H’FFB9
Port 6
6
5
4
3
P66DDR
P65DDR
P64DDR
P63DDR
2
P62DDR
0
0
0
0
0
0
0
W
W
W
W
W
W
W
1
Read/Write
1
0
P61DDR P60DDR
Port 6 Input / Output Control
0 Input port
1 Output port
P6DR—Port 6 Data Register
Bit
H’FFBB
Port 6
7
6
5
4
3
2
1
0
—
P66
P65
P64
P63
P62
P61
P60
Initial value
1
0
0
0
0
0
0
0
Read/Write
—
R/W
R/W
R/W
R/W
R/W
R/W
R/W
P7DDR—Port 7 Data Direction Register
H’FFBC
Port 7
7
6
5
4
3
P77DDR
P76DDR
P75DDR
P74DDR
P73DDR
2
P72DDR
Initial value
0
0
0
0
0
0
0
0
Read/Write
W
W
W
W
W
W
W
W
Bit
Port 7 Input / Output Control
0 Input port
1 Output port
284
1
0
P71DDR P70DDR
P7DR—Port 7 Data Register
Bit
H’FFBE
Port 7
7
6
5
4
3
2
1
0
P77
P76
P75
P74
P73
P72
P71
P70
Initial value
0
0
0
0
0
0
0
0
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
SYSCR—System Control Register
Bit
Initial value
Read/Write
H’FFC4
System Control
7
SSBY
6
STS2
5
STS1
4
STS0
3
2
NMIEG
1
0
RAME
0
R/W
0
R/W
0
R/W
0
R/W
1
0
R/W
1
1
R/W
RAM Enable
0 On-chip RAM is disabled.
1 On-chip RAM is enabled.
NMI Edge
0 Falling edge of NMI is detected.
1 Rising edge of NMI is detected.
Standby Timer Select
0
0
0
Clock settling time = 8192 states
0
0
0
1
1
0
Clock settling time = 16384 states
Clock settling time = 32768 states
0
1
1
Clock settling time = 65536 states
1
-
-
Clock settling time = 131072 states
Software Standby
0 SLEEP instructions causes transition to sleep mode.
1 SLEEP instructions causes transition to software standby mode.
285
MDCR—Mode Control Register
H’FFC5
System Control
Bit
7
6
5
4
3
2
Initial value
1
1
1
0
0
1
Read/Write
1
MDS1
*
0
MDS0
*
R
R
Mode Select
Value at mode pins.
* Determined by inputs at pins MD1 and MD0.
286
ISCR—IRQ Sense Control Register
7
6
Initial value
1
IRQ2EG
0
Read/Write
R/W
R/W
Bit
H’FFC6
5
System Control
4
3
IRQ1EG
0
IRQ0EG
0
1
0
R/W
R/W
R/W
R/W
2
IRQ2SC
1
IRQ1SC
0
0
IRQ0SC
0
R/W
R/W
IRQ0 Sense Control, IRQ0 Edge
IRQ0 SC
IRQ0 EG
Description
0
0
Low level of IRQ0 generates an interrupt
0
1
request.
1
0
Falling edge of IRQ0 generates an interrupt
request.
1
1
Rising edge of IRQ0 generates an interrupt
request.
IRQ1 Sense Control, IRQ1 Edge
IRQ1 SC
IRQ1 EG
Description
0
0
Low level of IRQ1 generates an interrupt request.
0
1
1
0
Falling edge of IRQ1 generates an interrupt request.
1
1
Rising edge of IRQ1 generates an interrupt request.
IRQ2 Sense Control, IRQ2 Edge
IRQ2 SC
IRQ2 EG
Description
0
0
Low level of IRQ2 generates an interrupt request.
0
1
1
0
Falling edge of IRQ2 generates an interrupt request.
1
1
Rising edge of IRQ2 generates an interrupt request.
287
IER—IRQ Enable Register
Bit
Initial value
Read/Write
7
1
H’FFC7
6
1
5
1
4
1
System Control
3
1
2
1
0
IRQ2E
IRQ1E
IRQ0E
0
0
0
R/W
R/W
R/W
IRQi Enable (i = 0 to 2)
0 IRQi is disabled.
1 IRQi is enabled.
288
TCR—Timer Control Register
Bit
H’FFC8
TMR0
Initial value
7
CMIEB
0
6
CMIEA
0
5
OVIE
0
4
CCLR1
0
3
CCLR0
0
2
CKS2
0
1
CKS1
0
0
CKS0
0
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Clock Select
0
0
0
0
0
1
No clock source; timer stops.
Internal clock source: ∅/8, counted on falling edge.
0
0
1
1
1
1
1
0
0
1
0
1
0
1
0
Internal clock source: ∅/64, counted on falling edge.
Internal clock source: ∅/1024, counted on falling edge.
No clock source; timer stops.
External clock source, counted on rising edge.
External clock source, counted on falling edge.
1
1
1
External clock source, counted on both rising and falling edges.
Counter Clear
0
0
Counter is not cleared.
0
1
1
1
0
1
Cleared by compare-match A.
Cleared by compare-match B.
Cleared on rising edge of external reset input.
Timer Overflow Interrupt Enable
0 Overflow interrupt request is disabled.
1 Overflow interrupt request is enabled.
Compare - Match Interrupt Enable A
0 Compare - match A interrupt request is disabled.
1 Compare - match A interrupt request is enabled.
Compare - Match Interrupt Enable B
0 Compare - match B interrupt request is disabled.
1 Compare - match B interrupt request is enabled.
289
TCSR—Timer Control/Status
Bit
7
CMFB
Initial value
Read/Write
0
R/(W)* 1
6
CMFA
0
R/(W)* 1
Register H’FFC9
5
4
3
OVF
OS3*
0
R/(W)*1
1
TMR0
2
2
0
R/W
OS2*
1
2
0
R/W
OS1*
0
2
0
R/W
Output Select
0
0
No change on compare-match A.
0
1
Output 0 on compare-match A.
1
1
0
1
Output 1 on compare-match A.
Invert (toggle) output on compare-match A.
Output Select
0
0
No change on compare-match B.
0
1
1
1
0
1
Output 0 on compare-match B.
Output 1 on compare-match B.
Invert (toggle) output on compare-match B.
Timer Overflow Flag
0 Cleared by reading OVF = 1, then writing 0.
1 Set when TCNT changes from H'FF to H'00.
Compare - Match Flag A
0 Cleared by reading CMFA = 1, then writing 0.
1 Set when TCNT = TCORA.
Compare - Match Flag B
0 Cleared by reading CMFB = 1, then writing 0.
1 Set when TCNT = TCORB.
*1 Software can write a 0 in bits 7 to 5 to clear the flags, but cannot write a 1 in these bits.
*2 When all four bits (OS3 to OS0) are cleared to 0, output is disabled.
290
OS0* 2
0
R/W
TCORA—Time Constant Register A
Bit
7
6
H’FFCA
5
4
TMR0
3
2
1
0
Initial value
1
1
1
1
1
1
1
1
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
The CMFA bit is set to 1 when TCORA = TCNT.
TCORB—Time Constant Register B
H’FFCB
TMR0
Bit
7
6
5
4
3
2
1
0
Initial value
1
1
1
1
1
1
1
1
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
The CMFB bit is set to 1 when TCORB = TCNT.
TCNT—Timer Counter
H’FFCC
TMR0
Bit
7
6
5
4
3
2
1
0
Initial value
0
0
0
0
0
0
0
0
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Count value
TCR—Timer Control Register
Bit
H’FFD0
TMR1
7
6
5
4
3
2
1
0
CMIEB
CMIEA
OVIE
CCLR1
CCLR0
CKS2
CKS1
CKS0
Initial value
0
0
0
0
0
0
0
0
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Note: Bit functions are the same as for TMR0.
291
TCSR—Timer Control/Status Register
Bit
Initial value
Read/Write
7
6
5
CMFB
CMFA
OVF
0
0
0
R/(W)
*1
R/(W)
H’FFD1
*1
R/(W)
4
*1
3
TMR1
2
*2
1
*2
0
*2
*2
OS2
OS1
OS0
0
0
0
0
R/W
R/W
R/W
R/W
—
OS3
1
—
Note: Bit functions are the same as for TMR0.
*1 Software can write a 0 in bits 7 to 5 to clear the flags, but cannot write a 1 in these bits.
*2 When all four bits (OS3 to OS0) are cleared to 0, output is disabled.
TCORA—Time Constant Register A
H’FFD2
TMR1
Bit
7
6
5
4
3
2
1
0
Initial value
1
1
1
1
1
1
1
1
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Note: Bit functions are the same as for TMR0.
TCORB—Time Constant Register B
H’FFD3
TMR1
Bit
7
6
5
4
3
2
1
0
Initial value
1
1
1
1
1
1
1
1
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Note: Bit functions are the same as for TMR0.
292
TCNT—Timer Counter
Bit
7
H’FFD4
6
5
4
TMR1
3
2
1
0
Initial value
0
0
0
0
0
0
0
0
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Note: Bit functions are the same as for TMR0.
293
SMR—Serial Mode Register
Bit
H’FFD8
6
CHR
0
5
PE
0
4
O/E
Initial value
7
C/A
0
0
3
STOP
0
Read/Write
R/W
R/W
R/W
R/W
R/W
SCI0
2
1
1
CKS1
0
0
CKS0
0
R/W
R/W
Clock Select
Stop Bit Length
0 One stop bit
1 Two stop bits
Parity mode
0 Even parity
1 Odd parity
Parity Enable
0
Transmit : No parity bit added.
Receive : Parity bit not checked.
1
Transmit : Parity bit added.
Receive : Parity bit checked.
Character Length
0 8-bit data length
1 7-bit data length
Communication mode
0 Asynchronous
1 Synchronous
294
0
0
∅ clock
0
1
∅/4 clock
1
0
∅/16 clock
1
1
∅/64 clock
TDR—Transmit Data Register
Bit
7
6
H’FFDB
5
4
3
SCI0
2
1
0
Initial value
1
1
1
1
1
1
1
1
Read/Write
W
W
W
W
W
W
W
W
Transmit data
BRR—Bit Rate Register
H’FFD9
SCI0
Bit
7
6
5
4
3
2
1
0
Initial value
1
1
1
1
1
1
1
1
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Constant that determines the bit rate
295
SCR—Serial Control Register
Bit
H’FFDA
SCI0
7
6
5
4
3
2
1
1
TIE
RIE
TE
Initial value
0
0
0
RE
0
Read/Write
R/W
R/W
R/W
R/W
1
0
CKE1
CKE0
0
0
R/W
R/W
Clock Enable 0
0 Asynchronous serial clock not
output at SCK pin
1 Asynchronous serial clock
output at SCK pin
Clock Enable 1
0 Internal clock
1 External clock
Receive Enable
0 Receive disabled
1 Receive enabled
Transmit Enable
0 Transmit disabled
1 Transmit enabled
Receive Interrupt Enable
0 Receive interrupt request is disabled.
1 Receive interrupt request is enabled.
Transmit Interrupt Enable
0 Transmit interrupt request is disabled.
1 Transmit interrupt request is enabled.
296
SSR—Serial Status Register
Bit
H’FFDC
6
RDRF
0
5
ORER
0
4
FER
Initial value
7
TDRE
1
Read/Write
R/(W)*
R/(W)*
R/(W)*
R/(W)*
0
3
PER
0
SCI0
2
1
0
1
1
1
R/(W)*
Parity Error
0 Cleared by reading PER = 1, then writing 0.
1 Set when a parity error occurs (parity of receive
data does not match parity selected by O/E bit).
Framing Error
0 Cleared by reading FER = 1, then writing 0.
1 Set when a framing error occurs (stop bit is 0)
Overrun Error
0 Cleared by reading ORER = 1, then writing 0.
1 Set when an overrun error occurs (reception of next data is
completed while RDRF bit is set to 1).
Receive Data Register Full
0 Cleared by reading RDRF = 1, then writing 0.
1 Set when one character is received normally and transfered from RSR
to RDR.
Transmit Data Register Empty
0 Cleared by reading TDRE = 1, then writing 0.
1 Set when :
1. Data is transferred from TDR to TSR.
2. TE is cleared while TDRE = 0.
* Software can write a 0 in bits 7 to 5 to clear the flags, but cannot write a 1 in these bits.
297
RDR—Receive Data Register
Bit
7
6
H’FFDD
5
4
SCI0
3
2
1
0
Initial value
0
0
0
0
0
0
0
0
Read/Write
R
R
R
R
R
R
R
R
Receive data
SMR—Serial Mode Register
Bit
H’FFE0
SCI1
7
6
5
4
3
2
1
0
C/$
CHR
PE
O/(
STOP
—
CKS1
CKS0
Initial value
0
0
0
0
0
1
0
0
Read/Write
R/W
R/W
R/W
R/W
R/W
—
R/W
R/W
Note: Bit functions are the same as for SCI0.
BRR—Bit Rate Register
H’FFE1
SCI1
Bit
7
6
5
4
3
2
1
0
Initial value
1
1
1
1
1
1
1
1
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Note: Bit functions are the same as for SCI0.
SCR—Serial Control Register
Bit
H’FFE2
SCI1
7
6
5
4
3
2
1
0
TIE
RIE
TE
RE
—
—
CKE1
CKE0
Initial value
0
0
0
0
1
1
0
0
Read/Write
R/W
R/W
R/W
R/W
—
—
R/W
R/W
Note: Bit functions are the same as for SCI0.
298
TDR—Transmit Data Register
H’FFE3
SCI1
Bit
7
6
5
4
3
2
1
0
Initial value
1
1
1
1
1
1
1
1
Read/Write
W
W
W
W
W
W
W
W
Note: Bit functions are the same as for SCI0.
SSR—Serial Status Register
Bit
H’FFE4
SCI1
7
6
5
4
3
2
1
0
TDRE
RDRF
ORER
FER
PER
—
—
—
Initial value
1
0
0
0
0
1
1
1
Read/Write
R/(W)*
R/(W)*
R/(W)*
R/(W)*
R/(W)*
—
—
—
Note: Bit functions are the same as for SCI0.
*
Software can write a 0 in bits 7 to 3 to clear the flags, but cannot write a 1 in these bits.
RDR—Receive Data Register
H’FFE5
SCI1
Bit
7
6
5
4
3
2
1
0
Initial value
0
0
0
0
0
0
0
0
Read/Write
R
R
R
R
R
R
R
R
Note: Bit functions are the same as for SCI0.
299
HCSR—Handshake Control/Status Register
Bit
Initial value
Read/Write
H’FFFE
7
ISF
6
ISIE
5
OSE
OSS
4
3
LTE
BSE
2
0
R
0
R/W
0
R/W
0
R/W
0
R/W
0
R/W
Handshaking
1
0
1
1
Busy Enable
0 BUSY output is disabled.
1 BUSY output is enabled.
Latch Enable
0 Input latches are disabled.
1 Input data are latched on falling edge of IS.
Output Strobe Select
0 OS is output when port 3 is read.
1 OS is output when port 3 is written.
Output Strobe Enable
0 OS output is disabled.
1 OS output is enabled.
Input Strobe Interrupt Enable
0 Input strobe interrupt is disabled.
1 Input strobe interrupt is enabled.
Input Strobe Flag
0 Cleared by reading HCSR when ISF = 1, then reading or writing port 3.
1 Set when IS goes low.
300
FNCR—FRT Noise Canceler Control Register
Bit
Initial value
Read/Write
7
1
6
1
5
H’FFFF
4
1
1
3
1
FRT
2
1
1
0
NCS1
NCS0
0
R/W
0
R/W
Noise Canceler Select
NCS1 NCS0 Description
0
0
Noise canceler is disabled.
0
1
Ø/32 sampling clock.
1
0
Ø/64 sampling clock.
1
1
Ø/128 sampling clock.
301
302
Appendix C. Pin States
C.1 Pin States in Each Mode
Table C-1. Pin States
Pin
Name
MCU
Mode Reset
Hardware Software
Standby Standby
Sleep
Mode
Normal
Operation
P17 to P10
A7 to A0
1
Low
3-State
Low
Prev. state
Addr. output
2
3-State
3
1
Low
3-State
Low if DDR =
1, Prev. state if
DDR = 0
Prev. state
Low
(Addr. output pins: Addr. output or
last address
input port
accessed)
I/O port
Prev. state
Addr. output
2
3-State
(Addr. output pins: Addr. output or
last address
input port
accessed)
3
1
3-State 3-State
Low if DDR =
1,
Prev. state
if DDR = 0
Prev. state
3-state
P27 to P20
A15 to A8
P37 to P30
D7 to D0
2
3
P47/E
3-State
I/O port
D7 to D0
Prev. state
Prev. state
I/O port
E clock 3-State
output
Low if
DDR = 1,
3-state if
DDR = 0
E clock if
DDR = 1,
3-state if
DDR = 0
E clock if DDR =
1,
Input port if
DDR = 0
3
3-State
Prev. state
Prev. state
I/O port
1
Clock
3-state
output
3-State
High
Clock
output
Clock
output
High if
DDR = 1,
3-state if
DDR = 0
Prev. state
(note 3)
Clock output
if DDR = 1,
3-state if
DDR = 0
Prev. state
Clock output if
DDR = 1,
input port if
DDR = 0
I/O port
1
2
P46/φ
2
3
P45 to P40,
1
2
3
3-State 3-State
303
Table C-1. Pin States (cont.)
Pin
Name
MCU
Mode
Reset
Hardware
Standby
Software
Standby
Sleep
Mode
Normal
Operation
P55 to P50,
1
2
3
3-State
3-State
Prev. state
(note 3)
Prev. state
I/O port
P66 to P60,
1
2
3
3-State
3-State
Prev. state
(note 3)
Prev. state
I/O port
1
2
3-State
3-State
3-state
3-state
:$,7
Prev. state
Prev. state
I/O port
High
High
$6, :5,
5'
Prev. state
Prev. state
I/O port
Prev. state
Prev. state
I/O port
P77/:$,7
3
P76 to P74,
$6, :5, 5',
P73 to P70,
1
2
High
3
3-State
1
2
3
3-State
3-State
3-State
Notes:
1. 3-state: High-impedance state
2. Prev. state: Previous state. Input ports are in the high-impedance state (with the MOS pull-up
on if DDR = 0 and DR = 1). Output ports hold their previous output level.
3. On-chip supporting modules are initialized, so these pins revert to I/O ports according to the
DDR and DR bits.
4. I/O port: Direction depends on the data direction (DDR) bit. Note that these pins may also be
used by the on-chip supporting modules.
See section 5, I/O Ports for further information.
304
Appendix D. Timing of Transition to and Recovery from
Hardware Standby Mode
Timing of Transition to Hardware Standby Mode
(1) To retain RAM contents, drive the 5(6 signal low 10 system clock cycles before the 67%<
signal goes low, as shown below. 5(6 must remain low until 67%< goes low (minimum
delay from 67%< low to 5(6 high: 0 ns).
STBY
t 1 ≥ 10 tcyc
t 2 ≥ 0 ns
RES
(2) When it is not necessary to retain RAM contents, 5(6 does not have to be driven low as in
(1).
Timing of Recovery From Hardware Standby Mode: Drive the 5(6 signal low
approximately 100 ns before 67%< goes high.
STBY
t = 100 ns
t OSC
RES
305
306
Appendix E. Package Dimensions
Figure E-1 shows the dimensions of the DC-64S package. Figure E-2 shows the dimensions of
the DP-64S package. Figure E-3 shows the dimensions of the FP-64A package. Figure E-4
shows the dimensions of the CP-68 package.
Unit: mm
57.30
33
18.92
64
1
32
0.9
0.48± 0.10
2.54 Min
1.778±0.250
0.51 Min
5.60 Max
19.05
+0.11
0.25 -0.05
Figure E-1. Package Dimensions (DC-64S)
Unit: mm
57.6
58.50 Max
17.0
1
18.2 Max
33
64
32
1.0
1.78 ± 0.25
0.48 ± 0.10
2.54 Min
0.51 Min
5.08 max
19.05
+0.11
0.25 -0.05
0˚ ~ 15˚
Figure E-2. Package Dimensions (DP-64S)
307
Unit: mm
17.2 ± 0.3
14
48
33
32
64
17
17.2 ± 0.3
0.80
49
1
16
0.35 ± 0.10
0.15
1.6
0.17 ± 0.05
0 ~ 5˚
0.1
2.70
3.05 Max
+0.20
-0.16
M
0.8
0.8 ± 0.3
0.1
Figure E-3. Package Dimensions (FP-64A)
Unit: mm
25.15 ± 0.12
24.20
60
44
43
68
1
9
27
10
4.40 ± 0.20
26
0.75 ± 0.09
2.55 ± 0.15
25.15 ± 0.12
61
1.27
0.42 ± 0.10
23.12 ± 0.50
23.12 ± 0.50
0.10
Figure E-4. Package Dimensions (CP-68)
308