Renesas M38048F6KP 8-bit cisc single-chip microcomputer 740 family / 38000 sery Datasheet

REJ09B0212-0100Z
8
3804 Group (Spec. H)
User’s Manual
RENESAS 8-BIT CISC SINGLE-CHIP MICROCOMPUTER
740 FAMILY / 38000 SERIES
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current document available.
Rev. 1.00
Revision date: Jan 14, 2005
www.renesas.com
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REVISION HISTORY
Rev.
3804 Group (Spec. H) User’s Manual
Date
Description
Summary
Page
1.00 Jan 14, 2005
–
First edition issued
(1/1)
BEFORE USING THIS USER’S MANUAL
This user’s manual consists of the following three chapters. Refer to the chapter appropriate to your conditions,
such as hardware design or software development.
1. Organization
● CHAPTER 1 HARDWARE
This chapter describes features of the microcomputer and operation of each peripheral function.
● CHAPTER 2 APPLICATION
This chapter describes usage and application examples of peripheral functions, based mainly on
setting examples of relevant registers.
● CHAPTER 3 APPENDIX
This chapter includes necessary information for systems development using the microcomputer, such
as the electrical characteristics, the notes, and the list of registers.
2. Structure of Register
The figure of each register structure describes its functions, contents at reset, and attributes as follows:
(Note 2)
Bits
Bit attributes
(Note 1)
Contents immediately after reset release
b7 b6 b5 b4 b3 b2 b1 b0
0
CPU mode register (CPUM) [Address : 003B16]
b
0
Name
Processor mode bits
1
Functions
b1
b0
0 0 : Single-chip mode
01:
1 0 : Not available
11:
0 : 0 page
1 : 1 page
At reset
R W
0
0
2
Stack page selection bit
3
Nothing arranged for these bits. These are write disabled
bits. When these bits are read out, the contents are “0.”
0
✕
0
✕
Fix this bit to “0.
” ain clock division ratio selection
M
bits
0
4
5
6
7
: Bit in which nothing is arranged
0
b7 b6
0 0 : φ = XIN/2 (High-speed mode)
0 1 : φ = XIN/8 (Middle-speed mode)
1 0 : φ = XIN/8 (Middle-speed mode)
1 1 : φ = XIN (Double-speed mode)
1
0
: Bit that is not used for control of the corresponding function
Notes 1: Contents immediately after reset release
0 •••••• “0” at reset release
1 •••••• “1” at reset release
Undefined •••••• Undefined or reset release
✻ ••••••Contents determined by option at reset release
2: Bit attributes••••••The attributes of control register bits are classified into 3 bytes : read-only, write-only
and read and write. In the figure, these attributes are represented as follows :
R••••••Read
••••••Read enabled
✕••••••Read disabled
W••••••Write
••••••Write enabled
✕ ••••••Write disabled
3. Supplementary
For details of related development tools and documents, refer to web page “3804 Group” on our website
(http://www.renesas.com/eng/products/mpumcu/8bit/38000/index.html).
Table of contents
3804 Group (Spec.H)
Table of contents
CHAPTER 1 HARDWARE
DESCRIPTION ................................................................................................................................ 1-2
FEATURES ...................................................................................................................................... 1-2
PIN CONFIGURATION .................................................................................................................. 1-3
FUNCTIONAL BLOCK .................................................................................................................. 1-4
PIN DESCRIPTION ........................................................................................................................ 1-5
PART NUMBERING ....................................................................................................................... 1-6
GROUP EXPANSION .................................................................................................................... 1-7
Memory Size ............................................................................................................................. 1-7
Packages ................................................................................................................................... 1-7
FUNCTIONAL DESCRIPTION ...................................................................................................... 1-8
CENTRAL PROCESSING UNIT (CPU) ................................................................................. 1-8
MEMORY ................................................................................................................................. 1-13
I/O PORTS .............................................................................................................................. 1-15
INTERRUPTS .......................................................................................................................... 1-23
TIMERS ................................................................................................................................... 1-27
SERIAL INTERFACE ............................................................................................................. 1-40
PULSE WIDTH MODULATION (PWM) ................................................................................ 1-54
A/D CONVERTER .................................................................................................................. 1-56
D/A CONVERTER .................................................................................................................. 1-58
WATCHDOG TIMER .............................................................................................................. 1-59
MULTI-MASTER I2C-BUS INTERFACE ............................................................................... 1-60
RESET CIRCUIT .................................................................................................................... 1-74
CLOCK GENERATING CIRCUIT ......................................................................................... 1-76
FLASH MEMORY MODE ...................................................................................................... 1-80
NOTES ON PROGRAMMING ..................................................................................................... 1-99
NOTES ON USAGE ................................................................................................................... 1-100
FUNCTIONAL DESCRIPTION SUPPLEMENT ....................................................................... 1-101
Interrupt ................................................................................................................................. 1-101
Timing After Interrupt ........................................................................................................... 1-102
A/D Converter ....................................................................................................................... 1-103
CHAPTER 2 APPLICATION
2.1 I/O port ..................................................................................................................................... 2-2
2.1.1 Memory map ................................................................................................................... 2-2
2.1.2 Relevant registers .......................................................................................................... 2-3
2.1.3 Port Pi pull-up control register ..................................................................................... 2-5
2.1.4 Terminate unused pins .................................................................................................. 2-5
2.1.5 Notes on I/O port ........................................................................................................... 2-6
2.1.6 Termination of unused pins .......................................................................................... 2-7
2.2 Interrupt ................................................................................................................................... 2-8
2.2.1 Memory map ................................................................................................................... 2-8
2.2.2 Relevant registers .......................................................................................................... 2-8
2.2.3 Interrupt source ............................................................................................................ 2-12
2.2.4 Interrupt operation ........................................................................................................ 2-13
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3804 Group (Spec.H)
2.2.5 Interrupt control ............................................................................................................ 2-16
2.2.6 INT interrupt .................................................................................................................. 2-19
2.2.7 Notes on interrupts ...................................................................................................... 2-20
2.3 Timer ....................................................................................................................................... 2-22
2.3.1 Memory map ................................................................................................................. 2-22
2.3.2 Relevant registers ........................................................................................................ 2-23
2.3.3 Timer application examples ........................................................................................ 2-32
2.3.4 Notes on timer .............................................................................................................. 2-45
2.4 Serial interface ..................................................................................................................... 2-47
2.4.1 Memory map ................................................................................................................. 2-47
2.4.2 Relevant registers ........................................................................................................ 2-48
2.4.3 Serial I/O connection examples ................................................................................. 2-56
2.4.4 Setting of serial I/O transfer data format ................................................................. 2-58
2.4.5 Serial I/O1, serial I/O3 operation: stop and initialize .............................................. 2-59
2.4.6 Serial I/O pin function and selection method ........................................................... 2-60
2.4.7 Serial I/O application examples ................................................................................. 2-61
2.4.8 Notes on serial interface ............................................................................................. 2-81
2.5 Multi-master I 2C-BUS interface ......................................................................................... 2-84
2.5.1 Memory map ................................................................................................................. 2-84
2.5.2 Relevant registers ........................................................................................................ 2-85
2.5.3 I 2C-BUS overview ......................................................................................................... 2-94
2.5.4 Communication format ................................................................................................. 2-95
2.5.5 Synchronization and arbitration lost .......................................................................... 2-96
2.5.6 SMBUS communication usage example ................................................................... 2-98
2.5.7 Notes on multi-master I 2C-BUS interface ............................................................... 2-114
2.5.8 Notes on programming for SMBUS interface ......................................................... 2-117
2.6 PWM ...................................................................................................................................... 2-118
2.6.1 Memory map ............................................................................................................... 2-118
2.6.2 Relevant registers ...................................................................................................... 2-118
2.6.3 PWM output circuit application example ................................................................. 2-120
2.6.4 Notes on PWM ........................................................................................................... 2-122
2.7 A/D converter ..................................................................................................................... 2-123
2.7.1 Memory map ............................................................................................................... 2-123
2.7.2 Relevant registers ...................................................................................................... 2-123
2.7.3 A/D converter application examples ........................................................................ 2-127
2.7.4 Notes on A/D converter ............................................................................................ 2-131
2.8 D/A Converter ..................................................................................................................... 2-132
2.8.1 Memory map ............................................................................................................... 2-132
2.8.2 Relevant registers ...................................................................................................... 2-133
2.8.3 D/A converter application example .......................................................................... 2-135
2.8.4 Notes on D/A converter ............................................................................................ 2-138
2.9 Watchdog timer .................................................................................................................. 2-139
2.9.1 Memory map ............................................................................................................... 2-139
2.9.2 Relevant registers ...................................................................................................... 2-139
2.9.3 Watchdog timer application examples ..................................................................... 2-141
2.9.4 Notes on watchdog timer .......................................................................................... 2-142
2.10 Reset .................................................................................................................................. 2-143
2.10.1 Connection____________
example of reset IC ............................................................................ 2-143
2.10.2 Notes on RESET pin ............................................................................................... 2-144
2.11 Clock generating circuit ................................................................................................ 2-145
2.11.1 Relevant registers .................................................................................................... 2-145
2.11.2 Clock generating circuit application example ....................................................... 2-146
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Table of contents
3804 Group (Spec.H)
2.12 Standby function ............................................................................................................. 2-149
2.12.1 Stop mode ................................................................................................................. 2-149
2.12.2 Wait mode ................................................................................................................. 2-153
2.13 Flash memory mode ....................................................................................................... 2-156
2.13.1 Overview .................................................................................................................... 2-156
2.13.2 Memory map ............................................................................................................. 2-156
2.13.3 Relevant registers .................................................................................................... 2-157
2.13.4 Parallel I/O mode ..................................................................................................... 2-159
2.13.5 Standard serial I/O mode ........................................................................................ 2-159
2.13.6 CPU rewrite mode ................................................................................................... 2-160
2.13.7 Flash memory mode application examples .......................................................... 2-162
2.13.8 Notes on CPU rewrite mode .................................................................................. 2-166
CHAPTER 3 APPENDIX
3.1 ELECTRICAL CHARACTERISTICS ...................................................................................... 3-2
3.1.1 Absolute maximum ratings ............................................................................................ 3-2
3.1.2 Recommended operating conditions ............................................................................ 3-3
3.1.3 Electrical characteristics ................................................................................................ 3-6
3.1.4 A/D converter characteristics ........................................................................................ 3-8
3.1.5 D/A converter characteristics ........................................................................................ 3-8
3.1.6 Power source circuit timing characteristics ................................................................ 3-8
3.1.7 Timing requirements and switching characteristics ................................................... 3-9
3.1.8 Multi-master I 2C-BUS bus line characteristics .......................................................... 3-14
3.2 Standard characteristics .................................................................................................... 3-15
3.2.1 Power source current standard characteristics ........................................................ 3-15
3.2.2 Port standard characteristics ...................................................................................... 3-19
3.2.3 A/D conversion standard characteristics ................................................................... 3-22
3.2.4 D/A conversion standard characteristics ................................................................... 3-26
3.3 Notes on use ........................................................................................................................ 3-27
3.3.1 Notes on input and output ports ................................................................................ 3-27
3.3.2 Termination of unused pins ........................................................................................ 3-28
3.3.3 Notes on interrupts ...................................................................................................... 3-29
3.3.4 Notes on 8-bit timer (timer 1, 2, X, Y) ..................................................................... 3-30
3.3.5 Notes on 16-bit timer (timer Z) .................................................................................. 3-30
3.3.6 Notes on serial interface ............................................................................................. 3-32
3.3.7 Notes on multi-master I 2C-BUS interface ................................................................. 3-34
3.3.8 Notes on programming for SMBUS interface ........................................................... 3-36
3.3.9 Notes on PWM ............................................................................................................. 3-37
3.3.10 Notes on A/D converter ............................................................................................ 3-37
3.3.11 Notes on D/A converter ............................................................................................ 3-38
3.3.12 Notes on watchdog
timer .......................................................................................... 3-38
____________
3.3.13 Notes on RESET pin ................................................................................................. 3-38
3.3.14 Notes on low-speed operation mode ...................................................................... 3-38
3.3.15 Quartz-crystal oscillator ............................................................................................. 3-39
3.3.16 Notes on restarting oscillation .................................................................................. 3-39
3.3.17 Notes on using stop mode ....................................................................................... 3-39
3.3.18 Notes on wait mode .................................................................................................. 3-40
3.3.19 Notes on CPU rewrite mode .................................................................................... 3-40
3.3.20 Notes on programming .............................................................................................. 3-40
3.3.21 Notes on flash memory version ............................................................................... 3-42
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Table of contents
3804 Group (Spec.H)
3.3.22 Notes on electric characteristic differences between mask ROM and flash nemory
version MCUs ............................................................................................................. 3-42
3.3.23 Notes on handling of power source pins ............................................................... 3-42
3.3.24 Power Source Voltage ............................................................................................... 3-42
3.4 Countermeasures against noise ...................................................................................... 3-43
3.4.1 Shortest wiring length .................................................................................................. 3-43
3.4.2 Connection of bypass capacitor across V SS line and V CC line ............................... 3-45
3.4.3 Wiring to analog input pins ........................................................................................ 3-46
3.4.4 Oscillator concerns ....................................................................................................... 3-47
3.4.5 Setup for I/O ports ....................................................................................................... 3-48
3.4.6 Providing of watchdog timer function by software .................................................. 3-49
3.5 Control registers .................................................................................................................. 3-50
3.6 Package outline ................................................................................................................... 3-80
3.7 Machine instructions .......................................................................................................... 3-82
3.8 List of instruction code ..................................................................................................... 3-93
3.9 SFR memory map ................................................................................................................ 3-94
3.10 Pin configurations ............................................................................................................. 3-95
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List of figures
3804 Group (Spec.H)
List of figures
CHAPTER 1 HARDWARE
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1 3804 group (Spec. H) pin configuration ........................................................................ 1-3
2 3804 group (Spec. H) pin configuration ........................................................................ 1-3
3 Functional block diagram ................................................................................................. 1-4
4 Part numbering .................................................................................................................. 1-6
5 Memory expansion plan ................................................................................................... 1-7
6 740 Family CPU register structure ................................................................................. 1-8
7 Register push and pop at interrupt generation and subroutine call .......................... 1-9
8 Structure of CPU mode register ................................................................................... 1-11
9 Structure of MISRG ........................................................................................................ 1-12
10 Memory map diagram ................................................................................................... 1-13
11 Memory map of special function register (SFR) ...................................................... 1-14
12 Port block diagram (1) ................................................................................................. 1-16
13 Port block diagram (2) ................................................................................................. 1-17
14 Port block diagram (3) ................................................................................................. 1-18
15 Structure of port pull-up control register (1) ............................................................. 1-19
16 Structure of port pull-up control register (2) ............................................................. 1-20
17 Structure of port pull-up control register (3) ............................................................. 1-21
18 Structure of port pull-up control register (4) ............................................................. 1-22
19 Interrupt control ............................................................................................................. 1-25
20 Structure of interrupt-related registers ....................................................................... 1-26
21 Block diagram of timer X, timer Y, timer 1, and timer 2 ........................................ 1-29
22 Structure of timer XY mode register .......................................................................... 1-30
23 Structure of timer 12, X and timer Y, Z count source selection registers ........... 1-31
24 Block diagram of timer Z ............................................................................................. 1-35
25 Structure of timer Z mode register ............................................................................. 1-36
26 Timing chart of timer/event counter mode ................................................................ 1-37
27 Timing chart of pulse output mode ............................................................................ 1-37
28 Timing chart of pulse period measurement mode (Measuring term between two rising edges) .. 1-38
29 Timing chart of pulse width measurement mode (Measuring “L” term) ................ 1-38
30 Timing chart of programmable waveform generating mode ................................... 1-39
31 Timing chart of programmable one-shot generating mode (“H” one-shot pulse generating) ... 1-39
32 Block diagram of clock synchronous serial I/O1 ...................................................... 1-40
33 Operation of clock synchronous serial I/O1 .............................................................. 1-40
34 Block diagram of UART serial I/O1 ............................................................................ 1-41
35 Operation of UART serial I/O1 ................................................................................... 1-41
36 Structure of serial I/O1 control registers ................................................................... 1-43
37 Structure of serial I/O2 control register ..................................................................... 1-46
38 Block diagram of serial I/O2 ....................................................................................... 1-46
39 Timing of serial I/O2 ..................................................................................................... 1-47
40 Block diagram of clock synchronous serial I/O3 ...................................................... 1-48
41 Operation of clock synchronous serial I/O3 .............................................................. 1-48
42 Block diagram of UART serial I/O3 ............................................................................ 1-49
43 Operation of UART serial I/O3 ................................................................................... 1-49
44 Structure of serial I/O3 control registers ................................................................... 1-51
45 Timing of PWM period ................................................................................................. 1-54
46 Block diagram of PWM function ................................................................................. 1-54
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List of figures
3804 Group (Spec.H)
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96
Structure of PWM control register .............................................................................. 1-55
PWM output timing when PWM register or PWM prescaler is changed .............. 1-55
Structure of AD/DA control register ........................................................................... 1-56
Structure of 10-bit A/D mode reading ........................................................................ 1-56
Block diagram of A/D converter .................................................................................. 1-57
Block diagram of D/A converter .................................................................................. 1-58
Equivalent connection circuit of D/A converter (DA1) ............................................. 1-58
Block diagram of Watchdog timer .............................................................................. 1-59
Structure of Watchdog timer control register ............................................................ 1-59
Block diagram of multi-master I 2C-BUS interface .................................................... 1-60
Structure of I 2C slave address registers 0 to 2 ....................................................... 1-61
Structure of I 2C clock control register ........................................................................ 1-62
Structure of I 2C control register .................................................................................. 1-63
Structure of I2C status register ................................................................................... 1-65
Interrupt request signal generating timing ................................................................. 1-65
START condition generating timing diagram ............................................................ 1-66
STOP condition generating timing diagram ............................................................... 1-66
START/STOP condition detecting timing diagram .................................................... 1-67
STOP condition detecting timing diagram ................................................................. 1-67
Structure of I2C START/STOP condition control register ........................................ 1-68
Structure of I 2C special mode status register ........................................................... 1-69
Structure of I 2C special mode control register ......................................................... 1-70
Address data communication format .......................................................................... 1-71
Reset circuit example ................................................................................................... 1-74
Reset sequence ............................................................................................................ 1-74
Internal status at reset ................................................................................................. 1-75
Ceramic resonator circuit ............................................................................................. 1-77
External clock input circuit .......................................................................................... 1-77
System clock generating circuit block diagram ........................................................ 1-78
State transitions of system clock ................................................................................ 1-79
Block diagram of built-in flash memory ..................................................................... 1-81
Structure of flash memory control register 0 ............................................................ 1-82
Structure of flash memory control register 1 ............................................................ 1-82
Structure of flash memory control register 2 ............................................................ 1-83
CPU rewrite mode set/release flowchart ................................................................... 1-83
Program flowchart ......................................................................................................... 1-85
Erase flowchart .............................................................................................................. 1-86
Full status check flowchart and remedial procedure for errors ............................. 1-88
Structure of ROM code protect control address ...................................................... 1-89
ID code store addresses .............................................................................................. 1-90
Connection for standard serial I/O mode 1 (M38049FFHFP/HP/KP) .................... 1-94
Connection for standard serial I/O mode 2 (M38049FFHFP/HP/KP) .................... 1-95
Connection for standard serial I/O mode 1 (M38049FFHSP) ................................ 1-96
Connection for standard serial I/O mode 2 (M38049FFHSP) ................................ 1-97
Operating waveform for standard serial I/O mode 1 ............................................... 1-98
Operating waveform for standard serial I/O mode 2 ............................................... 1-98
Timing chart after an interrupt occurs ..................................................................... 1-102
Time up to execution of the interrupt processing routine ..................................... 1-102
A/D conversion equivalent circuit ............................................................................. 1-104
A/D conversion timing chart ...................................................................................... 1-105
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List of figures
3804 Group (Spec.H)
CHAPTER 2 APPLICATION
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2.1.1 Memory map of I/O port relevant registers .............................................................. 2-2
2.1.2 Structure of Port Pi (i = 0 to 6) ................................................................................. 2-3
2.1.3 Structure of Port Pi direction register (i = 0 to 6) .................................................. 2-3
2.1.4 Structure of Port Pi pull-up control register (i = 0, 1, 2, 4, 5, 6) ......................... 2-4
2.1.5 Structure of Port P3 pull-up control register ............................................................ 2-4
2.2.1 Memory map of registers relevant to interrupt ........................................................ 2-8
2.2.2 Structure of Interrupt source selection register ....................................................... 2-8
2.2.3 Structure of Interrupt edge selection register .......................................................... 2-9
2.2.4 Structure of Interrupt request register 1 ................................................................... 2-9
2.2.5 Structure of Interrupt request register 2 ................................................................. 2-10
2.2.6 Structure of Interrupt control register 1 .................................................................. 2-10
2.2.7 Structure of Interrupt control register 2 .................................................................. 2-11
2.2.8 Interrupt operation diagram ....................................................................................... 2-13
2.2.9 Changes of stack pointer and program counter upon acceptance of interrupt request .... 2-14
2.2.10 Time up to execution of interrupt processing routine ......................................... 2-15
2.2.11 Timing chart after acceptance of interrupt request ............................................. 2-15
2.2.12 Interrupt control diagram ......................................................................................... 2-16
2.2.13 Example of multiple interrupts ................................................................................ 2-18
2.2.14 Sequence of changing relevant register ............................................................... 2-20
2.2.15 Sequence of check of interrupt request bit .......................................................... 2-21
2.3.1 Memory map of registers relevant to timers .......................................................... 2-22
2.3.2 Structure of Prescaler 12, Prescaler X, Prescaler Y ............................................ 2-23
2.3.3 Structure of Timer 1 .................................................................................................. 2-23
2.3.4 Structure of Timer 2, Timer X, Timer Y ................................................................. 2-24
2.3.5 Structure of Timer Z (low-order, high-order) .......................................................... 2-24
2.3.6 Structure of Timer XY mode register ...................................................................... 2-25
2.3.7 Structure of Timer Z mode register ......................................................................... 2-26
2.3.8 Structure of Timer 12, X count source selection register .................................... 2-28
2.3.9 Structure of Timer Y, Z count source selection register ...................................... 2-28
2.3.10 Structure of Interrupt source selection register ................................................... 2-29
2.3.11 Structure of Interrupt request register 1 ............................................................... 2-30
2.3.12 Structure of Interrupt request register 2 ............................................................... 2-30
2.3.13 Structure of Interrupt control register 1 ................................................................ 2-31
2.3.14 Structure of Interrupt control register 2 ................................................................ 2-31
2.3.15 Timers connection and setting of division ratios ................................................. 2-33
2.3.16 Relevant registers setting ....................................................................................... 2-33
2.3.17 Control procedure ..................................................................................................... 2-34
2.3.18 Peripheral circuit example ....................................................................................... 2-35
2.3.19 Timers connection and setting of division ratios ................................................. 2-35
2.3.20 Relevant registers setting ....................................................................................... 2-36
2.3.21 Control procedure ..................................................................................................... 2-37
2.3.22 Judgment method of valid/invalid of input pulses ............................................... 2-38
2.3.23 Relevant registers setting ....................................................................................... 2-39
2.3.24 Control procedure ..................................................................................................... 2-40
2.3.25 Timers connection and setting of division ratios ................................................. 2-41
2.3.26 Relevant registers setting ....................................................................................... 2-42
2.3.27 Control procedure (1) .............................................................................................. 2-43
2.3.28 Control procedure (2) .............................................................................................. 2-44
2.4.1 Memory map of registers relevant to Serial I/O .................................................... 2-47
2.4.2 Structure of Transmit/Receive buffer register 1 and Transmit/Receive buffer register 3 .. 2-48
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List of figures
3804 Group (Spec.H)
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2.4.3 Structure of Serial I/O1 status register and Serial I/O3 status register ............. 2-48
2.4.4 Structure of Serial I/O1 control register .................................................................. 2-49
2.4.5 Structure of Serial I/O3 control register .................................................................. 2-50
2.4.6 Structure of UART1 control register ........................................................................ 2-51
2.4.7 Structure of UART3 control register ........................................................................ 2-51
2.4.8 Structure of Baud rate generator 1 and Baud rate generator 3 ......................... 2-52
2.4.9 Structure of Serial I/O2 control register .................................................................. 2-52
2.4.10 Structure of Serial I/O2 register ............................................................................. 2-53
2.4.11 Structure of Interrupt source selection register ................................................... 2-53
2.4.12 Structure of Interrupt request register 1 ............................................................... 2-54
2.4.13 Structure of Interrupt request register 2 ............................................................... 2-54
2.4.14 Structure of Interrupt control register 1 ................................................................ 2-55
2.4.15 Structure of Interrupt control register 2 ................................................................ 2-55
2.4.16 Serial I/O connection examples (1) ....................................................................... 2-56
2.4.17 Serial I/O connection examples (2) ....................................................................... 2-57
2.4.18 Serial I/O transfer data format ............................................................................... 2-58
2.4.19 Connection diagram ................................................................................................. 2-61
2.4.20 Timing chart (using clock synchronous serial I/O) .............................................. 2-61
2.4.21 Registers setting relevant to transmitting side ..................................................... 2-62
2.4.22 Registers setting relevant to receiving side ......................................................... 2-63
2.4.23 Control procedure of transmitting side .................................................................. 2-64
2.4.24 Control procedure of receiving side ...................................................................... 2-65
2.4.25 Connection diagrams ............................................................................................... 2-66
2.4.26 Timing chart (serial I/O1) ........................................................................................ 2-66
2.4.27 Registers setting relevant to serial I/O1 ............................................................... 2-67
2.4.28 Setting of serial I/O1 transmission data ............................................................... 2-67
2.4.29 Control procedure of serial I/O1 ............................................................................ 2-68
2.4.30 Registers setting relevant to serial I/O2 ............................................................... 2-69
2.4.31 Setting of serial I/O2 transmission data ............................................................... 2-69
2.4.32 Control procedure of serial I/O2 ............................................................................ 2-70
2.4.33 Connection diagram ................................................................................................. 2-71
2.4.34 Timing chart .............................................................................................................. 2-72
2.4.35 Relevant registers setting ....................................................................................... 2-72
2.4.36 Control procedure of master unit ........................................................................... 2-73
2.4.37 Control procedure of slave unit ............................................................................. 2-74
2.4.38 Connection diagram (Communication using UART) ............................................ 2-75
2.4.39 Timing chart (using UART) ..................................................................................... 2-75
2.4.40 Registers setting relevant to transmitting side ..................................................... 2-77
2.4.41 Registers setting relevant to receiving side ......................................................... 2-78
2.4.42 Control procedure of transmitting side .................................................................. 2-79
2.4.43 Control procedure of receiving side ...................................................................... 2-80
2.4.44 Sequence of setting serial I/Oi (i = 1, 3) control register again ....................... 2-82
2.5.1 Memory map of registers relevant to I2C-BUS interface ...................................... 2-84
2.5.2 Structure of MISRG ................................................................................................... 2-85
2.5.3 Structure of I2C data shift register ........................................................................... 2-85
2.5.4 Structure of I 2C special mode status register ........................................................ 2-86
2.5.5 Structure of I 2C status register ................................................................................. 2-87
2.5.6 Structure of I2C control register ............................................................................... 2-88
2.5.7 Structure of I2C clock control register ..................................................................... 2-89
2.5.8 Structure of I2C START/STOP condition control register ..................................... 2-90
2.5.9 Structure of I 2C special mode control register ....................................................... 2-90
2.5.10 Structure of I2C slave address register i (i = 0 to 2) ......................................... 2-91
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List of figures
3804 Group (Spec.H)
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2.5.11 Structure of Interrupt source selection register ................................................... 2-91
2.5.12 Structure of Interrupt request register 1 ............................................................... 2-92
2.5.13 Structure of Interrupt request register 2 ............................................................... 2-92
2.5.14 Structure of Interrupt control register 1 ................................................................ 2-93
2.5.15 Structure of Interrupt control register 2 ................................................................ 2-93
2.5.16 I2C-BUS connection structure ................................................................................. 2-94
2.5.17 I2C-BUS communication format example .............................................................. 2-95
2.5.18 RESTART condition of master reception .............................................................. 2-96
2.5.19 SCL waveforms when synchronizing clocks ......................................................... 2-97
2.5.20 Initial setting example for SMBUS communication .............................................. 2-99
2.5.21 Read Word protocol communication as SMBUS master device ..................... 2-100
2.5.22 Generating of START condition and transmission process of slave address + write bit ... 2-101
2.5.23 Transmission process of command ..................................................................... 2-102
2.5.24 Transmission process of RESTART condition and slave address + read bit ... 2-103
2.5.25 Reception process of lower data ......................................................................... 2-104
2.5.26 Reception process of upper data ........................................................................ 2-105
2.5.27 Generating of STOP condition ............................................................................. 2-106
2.5.28 Communication example as SMBUS slave device ............................................ 2-107
2.5.29 Reception process of START condition and slave address ............................ 2-108
2.5.30 Reception process of command ........................................................................... 2-109
2.5.31 Reception process of RESTART condition and slave address ....................... 2-110
2.5.32 Transmission process of lower data .................................................................... 2-111
2.5.33 Transmission process of upper data ................................................................... 2-112
2.5.34 Reception of STOP condition ............................................................................... 2-113
2.6.1 Memory map of registers relevant to PWM ......................................................... 2-118
2.6.2 Structure of PWM control register ......................................................................... 2-118
2.6.3 Structure of PWM prescaler ................................................................................... 2-119
2.6.4 Structure of PWM register ...................................................................................... 2-119
2.6.5 Connection diagram ................................................................................................. 2-120
2.6.6 PWM output timing ................................................................................................... 2-120
2.6.7 Setting of relevant registers ................................................................................... 2-121
2.6.8 PWM output .............................................................................................................. 2-121
2.6.9 Control procedure ..................................................................................................... 2-122
2.7.1 Memory map of registers relevant to A/D converter ........................................... 2-123
2.7.2 Structure of AD/DA control register ....................................................................... 2-123
2.7.3 Structure of AD conversion register 1 .................................................................. 2-124
2.7.4 Structure of AD conversion register 2 .................................................................. 2-124
2.7.5 Structure of Interrupt source selection register ................................................... 2-125
2.7.6 Structure of Interrupt request register 2 ............................................................... 2-126
2.7.7 Structure of Interrupt control register 2 ................................................................ 2-126
2.7.8 Connection diagram ................................................................................................. 2-127
2.7.9 Relevant registers setting ....................................................................................... 2-127
2.7.10 Control procedure (10-bit A/D mode) .................................................................. 2-128
2.7.11 Connection diagram ............................................................................................... 2-129
2.7.12 Relevant registers setting ..................................................................................... 2-129
2.7.13 Control procedure (8-bit A/D mode) .................................................................... 2-130
2.8.1 Memory map of registers relevant to D/A converter ........................................... 2-132
2.8.2 Structure of Port P5 direction register .................................................................. 2-133
2.8.3 Structure of AD/DA control register ....................................................................... 2-133
2.8.4 Structure of DAi converter register ........................................................................ 2-134
2.8.5 Peripheral circuit example ....................................................................................... 2-135
2.8.6 Speaker output example ......................................................................................... 2-135
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List of figures
3804 Group (Spec.H)
Fig.
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2.8.7 Relevant registers setting ....................................................................................... 2-136
2.8.8 Control procedure ..................................................................................................... 2-137
2.9.1 Memory map of registers relevant to watchdog timer ........................................ 2-139
2.9.2 Structure of Watchdog timer control register ....................................................... 2-139
2.9.3 Structure of CPU mode register ............................................................................ 2-140
2.9.4 Watchdog timer connection and division ratio setting ........................................ 2-141
2.9.5 Relevant registers setting ....................................................................................... 2-142
2.9.6 Control procedure ..................................................................................................... 2-142
2.10.1 Example of poweron reset circuit ........................................................................ 2-143
2.10.2 RAM backup system .............................................................................................. 2-143
2.11.1 Structure of CPU mode register .......................................................................... 2-145
2.11.2 Connection diagram ............................................................................................... 2-146
2.11.3 Status transition diagram during power failure .................................................. 2-146
2.11.4 Setting of relevant registers ................................................................................. 2-147
2.11.5 Control procedure ................................................................................................... 2-148
2.12.1 Oscillation stabilizing time at restoration by reset input .................................. 2-150
2.12.2 Execution sequence example at restoration by occurrence of INT0 interrupt request ... 2-152
2.12.3 Reset input time ..................................................................................................... 2-154
2.13.1 Memory map of M38049FFHSP/FP/HP/KP ........................................................ 2-156
2.13.2 Memory map of registers relevant to flash memory ......................................... 2-157
2.13.3 Structure of Flash memory control register 0 .................................................... 2-157
2.13.4 Structure of Flash memory control register 1 .................................................... 2-158
2.13.5 Structure of Flash memory control register 2 .................................................... 2-158
2.13.6 Rewrite example of built-in flash memory in standard serial I/O mode ......... 2-162
2.13.7 Connection example in standard serial I/O mode (1) ....................................... 2-163
2.13.8 Connection example in standard serial I/O mode (2) ....................................... 2-163
2.13.9 Connection example in standard serial I/O mode (3) ....................................... 2-164
2.13.10 Example of rewrite system for built-in flash memory in CPU rewrite mode (singlechip mode) ............................................................................................................ 2-165
CHAPTER 3 APPENDIX
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3.1.1
3.1.2
3.1.3
3.1.4
3.2.1
3.2.2
3.2.3
3.2.4
Circuit for measuring output switching characteristics (1) ................................... 3-12
Circuit for measuring output switching characteristics (2) ................................... 3-12
Timing diagram (in single-chip mode) ..................................................................... 3-13
Timing diagram of multi-master I 2C-BUS ................................................................ 3-14
Power source current standard characteristics (in high-speed mode) ............... 3-15
Power source current standard characteristics (in middle-speed mode) ........... 3-15
Power source current standard characteristics (in low-speed mode) ................. 3-16
Power source current standard characteristics (in high-speed mode, f(X IN) = 16.8
MHz, WAIT state) ....................................................................................................... 3-16
3.2.5 Power source current standard characteristics (in middle-speed mode, f(X IN) = 16.8
MHz, WAIT state) ....................................................................................................... 3-17
3.2.6 Power source current standard characteristics (in low-speed mode, WAIT state) ...... 3-17
3.2.7 Power source current standard characteristics (in high-speed mode, f(X IN) = 16.8
MHz, A/D converter operating) ................................................................................. 3-18
3.2.8 Power source current standard characteristics (at oscillation stopping) ............ 3-18
3.2.9 CMOS output port P-channel side characteristics (Ta = 25 °C) ......................... 3-19
3.2.10 CMOS output port N-channel side characteristics (Ta = 25 °C) ...................... 3-19
3.2.11 N-channel open-drain output port N-channel side characteristics (Ta = 25 °C) .... 3-20
3.2.12 CMOS large current output port N-channel side characteristics (Ta = 25 °C) .... 3-20
3.2.13 CMOS input port at pull-up characteristics (Ta = 25 °C) .................................. 3-21
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List of figures
3804 Group (Spec.H)
Fig.
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3.2.14 A/D conversion standard characteristics (f(X IN) = 8 MHz) ................................. 3-23
3.2.15 A/D conversion standard characteristics (f(XIN) = 12 MHz) ............................... 3-24
3.2.16 A/D conversion standard characteristics (f(XIN) = 16 MHz) ............................... 3-25
3.2.17 D/A conversion standard characteristics ............................................................... 3-26
3.3.1 Sequence of changing relevant register ................................................................. 3-29
3.3.2 Sequence of check of interrupt request bit ............................................................ 3-30
3.3.3 Sequence of setting serial I/Oi (i = 1, 3) control register again ......................... 3-33
3.3.4 Ceramic resonator circuit .......................................................................................... 3-38
3.3.5 Initialization of processor status register ................................................................ 3-40
3.3.6 Sequence of PLP instruction execution .................................................................. 3-41
3.3.7 Stack memory contents after PHP instruction execution ..................................... 3-41
3.3.8 Status flag at decimal
calculations .......................................................................... 3-41
_____________
3.4.1 Wiring for the RESET pin ......................................................................................... 3-43
3.4.2 Wiring for clock I/O pins ........................................................................................... 3-44
3.4.3 Wiring for CNV SS pin .................................................................................................. 3-44
3.4.4 Bypass capacitor across the V SS line and the V CC line ........................................ 3-45
3.4.5 Analog signal line and a resistor and a capacitor ................................................ 3-46
3.4.6 Wiring for a large current signal line ...................................................................... 3-47
3.4.7 Wiring of signal lines where potential levels change frequently ......................... 3-47
3.4.8 V SS pattern on the underside of an oscillator ........................................................ 3-48
3.4.9 Setup for I/O ports ..................................................................................................... 3-48
3.4.10 Watchdog timer by software ................................................................................... 3-49
3.5.1 Structure of Port Pi .................................................................................................... 3-50
3.5.2 Structure of Port Pi direction register ..................................................................... 3-50
3.5.3 Structure of Timer 12, X count source selection register .................................... 3-51
3.5.4 Structure of Timer Y, Z count source selection register ...................................... 3-52
3.5.5 Structure of MISRG ................................................................................................... 3-53
3.5.6 Structure of I2C data shift register ........................................................................... 3-53
3.5.7 Structure of I2C special mode status register ........................................................ 3-54
3.5.8 Structure of I2C status register................................................................................. 3-55
3.5.9 Structure of I2C control register ............................................................................... 3-56
3.5.10 Structure of I2C clock control register ................................................................... 3-57
3.5.11 Structure of I2C START/STOP condition control register ................................... 3-58
3.5.12 Structure of I2C special mode control register ..................................................... 3-58
3.5.13 Structure of Transmit/Receive buffer register 1, Transmit/Receive buffer register 3 .... 3-59
3.5.14 Structure of Serial I/O1 status register, Serial I/O3 status register ................. 3-59
3.5.15 Structure of Serial I/O1 control register ................................................................ 3-60
3.5.16 Structure of UART1 control register ...................................................................... 3-61
3.5.17 Structure of Baud rate generator i ........................................................................ 3-61
3.5.18 Structure of Serial I/O2 control register ................................................................ 3-62
3.5.19 Structure of Watchdog timer control register ....................................................... 3-62
3.5.20 Structure of Serial I/O2 register ............................................................................. 3-63
3.5.21 Structure of Prescaler 12, Prescaler X, Prescaler Y .......................................... 3-63
3.5.22 Structure of Timer 1 ................................................................................................ 3-64
3.5.23 Structure of Timer 2, Timer X, Timer Y ............................................................... 3-64
3.5.24 Structure of Timer XY mode register .................................................................... 3-65
3.5.25 Structure of Timer Z low-order, Timer Z high-order ........................................... 3-66
3.5.26 Structure of Timer Z mode register ....................................................................... 3-66
3.5.27 Structure of PWM control register ......................................................................... 3-68
3.5.28 Structure of PWM prescaler ................................................................................... 3-68
3.5.29 Structure of PWM register ...................................................................................... 3-68
3.5.30 Structure of Serial I/O3 control register ................................................................ 3-69
Rev.1.00 Jan 14, 2005
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List of figures
3804 Group (Spec.H)
Fig.
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3.5.31
3.5.32
3.5.33
3.5.34
3.5.35
3.5.36
3.5.37
3.5.38
3.5.39
3.5.40
3.5.41
3.5.42
3.5.43
3.5.44
3.5.45
3.5.46
3.5.47
3.5.48
Rev.1.00 Jan 14, 2005
REJ09B0212-0100Z
Structure
Structure
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Structure
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Structure
of
of
of
of
of
of
of
of
of
of
of
of
of
of
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of
UART3 control register ...................................................................... 3-70
AD/DA control register ....................................................................... 3-70
AD conversion register 1 .................................................................. 3-71
DAi conversion register (i = 1, 2) .................................................... 3-71
AD conversion register 2 .................................................................. 3-71
Interrupt source selection register ................................................... 3-72
Interrupt edge selection register ...................................................... 3-73
CPU mode register ............................................................................ 3-73
Interrupt request register 1 ............................................................... 3-74
Interrupt request register 2 ............................................................... 3-74
Interrupt control register 1 ................................................................ 3-75
Interrupt control register 2 ................................................................ 3-75
Flash memory control register 0 ...................................................... 3-76
Flash memory control register 1 ...................................................... 3-77
Flash memory control register 2 ...................................................... 3-77
Port Pi pull-up control register (i = 0 to 2, 4 to 6) ....................... 3-78
Port P3 pull-up control register ........................................................ 3-78
I2C slave address register i (i = 0 to 2) ......................................... 3-79
xii
List of tables
3804 Group (Spec.H)
List of tables
CHAPTER 1 HARDWARE
Table
Table
Table
Table
Table
Table
Table
Table
Table
Table
Table
Table
Table
Table
Table
Table
Table
Table
Table
Table
Table
Table
Table
1 Support products ............................................................................................................ 1-2
2 Pin description ................................................................................................................ 1-5
3 Push and pop instructions of accumulator or processor status register ............... 1-9
4 Set and clear instructions of each bit of processor status register ..................... 1-10
5 I/O port function ........................................................................................................... 1-15
6 Interrupt vector addresses and priority ..................................................................... 1-24
7 Multi-master I2C-BUS interface functions .................................................................. 1-60
8 Set values of I 2C clock control register and SCL frequency ................................. 1-62
9 START condition generating timing table ................................................................. 1-66
10 STOP condition generating timing table ................................................................. 1-66
11 START condition/STOP condition detecting conditions ........................................ 1-67
12 Recommended set value to START/STOP condition set bits (SSC4–SSC0) for each
oscillation frequency .................................................................................................. 1-68
13 Summary of 3804 group (spec. H) ......................................................................... 1-80
14 State of E/W inhibition function ............................................................................... 1-83
15 List of software commands (CPU rewrite mode) .................................................. 1-85
16 Definition of each bit in status register .................................................................. 1-87
17 Description of pin function (Flash Memory Serial I/O Mode 1) .......................... 1-93
18 Description of pin function (Flash Memory Serial I/O Mode 2) .......................... 1-93
19 Interrupt sources, vector addresses and priority ................................................. 1-101
20 Relative formula for a reference voltage VREF of A/D converter and Vref (at 10-bit A/
D mode) .................................................................................................................... 1-103
21 Relative formula for a reference voltage V REF of A/D converter and V ref (at 8-bit A/
D mode) .................................................................................................................... 1-103
22 Change of AD conversion register during A/D conversion (at 10-bit A/D mode) . 1-103
23 Change of AD conversion register during A/D conversion (at 8-bit A/D mode) ... 1-104
CHAPTER 2 APPLICATION
Table
Table
Table
Table
Table
Table
Table
Table
Table
Table
Table
Table
2.1.1 Termination of unused pins (in single-chip mode) ............................................... 2-5
2.2.1 Interrupt sources, vector addresses and priority .............................................. 2-12
2.2.2 List of interrupt bits according to interrupt source ............................................. 2-17
2.3.1 CNTR 0/CNTR 1 active edge switch bit function .................................................... 2-25
2.3.2 CNTR 2 active edge switch bit function ................................................................ 2-27
2.4.1 Pin function in clock synchronous serial I/O mode ............................................ 2-60
2.4.2 Pin function in UART mode ................................................................................... 2-60
2.4.3 Pin function in clock synchronous serial I/O mode ............................................ 2-60
2.4.4 Setting examples of Baud rate generator (BRG) values and transfer bit rate values ... 2-76
2.12.1 State in stop mode ............................................................................................. 2-149
2.12.2 State in wait mode .............................................................................................. 2-153
2.13.1 Parallel unit when parallel programming (when using EFP-I provided by Suisei
Electronics System Co., Ltd.) ............................................................................ 2-159
Table 2.13.2 Connection example to programmer when serial programming (4 wires) .. 2-159
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List of tables
3804 Group (Spec.H)
CHAPTER 3 APPENDIX
Table
Table
Table
Table
Table
Table
Table
Table
Table
Table
Table
Table
Table
Table
Table
Table
3.1.1 Absolute maximum ratings ....................................................................................... 3-2
3.1.2 Recommended operating conditions (1) ................................................................ 3-3
3.1.3 Recommended operating conditions (2) ................................................................ 3-4
3.1.4 Recommended operating conditions (3) ............................................................... .3-5
3.1.5 Electrical characteristics (1) ..................................................................................... 3-6
3.1.6 Electrical characteristics (2) ..................................................................................... 3-7
3.1.7 A/D converter recommended operating conditions ............................................... 3-8
3.1.8 A/D converter characteristics ................................................................................... 3-8
3.1.9 D/A converter characteristics ................................................................................... 3-8
3.1.10 Power source circuit timing characteristics ......................................................... 3-8
3.1.11 Timing requirements (1) ......................................................................................... 3-9
3.1.12 Timing requirements (2) ....................................................................................... 3-10
3.1.13 Switching characteristics ...................................................................................... 3-11
3.1.14 Multi-master I 2C-BUS bus line characteristics .................................................. 3-14
3.5.1 CNTR 0/CNTR 1 active edge switch bit function .................................................... 3-65
3.5.2 CNTR 2 active edge switch bit function ................................................................ 3-67
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xiv
CHAPTER 1
HARDWARE
DESCRIPTION
FEATURES
PIN CONFIGURATION
FUNCTIONAL BLOCK
PIN DESCRIPTION
PART NUMBERING
GROUP EXPANSION
FUNCTIONAL DESCRIPTION
NOTES ON PROGRAMMING
NOTES ON USAGE
DATA REQUIRED FOR MASK ORDERS
FUNCTIONAL DESCRIPTION SUPPLEMENT
HARDWARE
3804 Group (Spec.H)
DESCRIPTION/FEATURES
DESCRIPTION
The 3804 group (Spec. H) is the 8-bit microcomputer based on the
740 family core technology.
The 3804 group (Spec. H) is designed for household products, office automation equipment, and controlling systems that require
analog signal processing, including the A/D converter and D/A
converters.
FEATURES
● Basic machine-language instructions ...................................... 71
● Minimum instruction execution time ................................ 0.24 µs
(at 16.8 MHz oscillation frequency)
● Memory size
Flash memory .............................................................. 60 K bytes
RAM ............................................................................ 2048 bytes
● Programmable input/output ports ............................................ 56
● Software pull-up resistors ................................................. Built-in
● Interrupts
21 sources, 16 vectors .................................................................
(external 8, internal 12, software 1)
● Timers ........................................................................... 16-bit ✕ 1
8-bit ✕ 4
(with 8-bit prescaler)
● Watchdog timer ............................................................ 16-bit ✕ 1
● Serial interface
Serial I/O1, 3 ............... 8-bit ✕ 2 (UART or Clock-synchronized)
Serial I/O2 ................................... 8-bit ✕ 1 (Clock-synchronized)
● PWM ............................................ 8-bit ✕ 1 (with 8-bit prescaler)
● Multi-master I2C-BUS interface ................................... 1 channel
● A/D converter ............................................. 10-bit ✕ 16 channels
(8-bit reading enabled)
● D/A converter .................................................. 8-bit ✕ 2 channels
● LED direct drive port .................................................................. 8
● Clock generating circuit ..................................... Built-in 2 circuits
(connect to external ceramic resonator or quartz-crystal oscillator)
●Power source voltage
In high-speed mode
At 16.8 MHz oscillation frequency ............................ 4.5 to 5.5 V
At 12.5 MHz oscillation frequency ............................ 4.0 to 5.5 V
At 8.4 MHz oscillation frequency) ............................. 2.7 to 5.5 V
In middle-speed mode
At 16.8 MHz oscillation frequency ............................ 4.5 to 5.5 V
At 12.5 MHz oscillation frequency ............................ 2.7 to 5.5 V
In low-speed mode
At 32 kHz oscillation frequency ................................. 2.7 to 5.5 V
●Power dissipation
In high-speed mode ............................................. 27.5 mW (typ.)
(at 16.8 MHz oscillation frequency, at 5 V power source voltage)
In low-speed mode ............................................... 1200 µW (typ.)
(at 32 kHz oscillation frequency, at 3 V power source voltage)
●Operating temperature range .................................... –20 to 85°C
●Packages
SP .................................................. 64P4B (64-pin 750 mil SDIP)
FP ....................................... 64P6N-A (64-pin 14 ✕ 14 mm QFP)
HP ..................................... 64P6Q-A (64-pin 10 ✕ 10 mm LQFP)
KP ..................................... 64P6U-A (64-pin 14 ✕ 14 mm LQFP)
<Flash memory mode>
●Power source voltage ...................................... Vcc = 2.7 to 5.5 V
●Program/Erase voltage .................................... Vcc = 2.7 to 5.5 V
●Programming method ...................... Programming in unit of byte
●Erasing method ...................................................... Block erasing
●Program/Erase control by software command
●Number of times for programming/erasing ............................ 100
■Notes
Cannot be used for application embedded in the MCU card.
Currently support products are listed below.
Table 1 Support products
Product name
Flash memory size
(bytes)
M38049FFHSP
M38049FFHFP
M38049FFHHP
M38049FFHKP
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61440
RAM size (bytes)
Package
2048
64P4B
64P6N-A
64P6Q-A
64P6U-A
Remarks
Vcc = 2.7 to 5.5 V
1-2
HARDWARE
3804 Group (Spec.H)
PIN CONFIGURATION
P15
P16
P17
34
33
36
35
P13
P14
37
P11/INT01
P12
P06/AN14
42
38
P05/AN13
43
40
P04/AN12
44
39
P03/AN11
45
P07/AN15
P10/INT41
P02/AN10
46
41
P00/AN8
P01/AN9
48
47
PIN CONFIGURATION (TOP VIEW)
P37/SRDY3
49
32
P20(LED0)
P36/SCLK3
50
31
P21(LED1)
P35/TXD3
51
30
P22(LED2)
P34/RXD3
52
29
P23(LED3)
P33/SCL
53
28
P24(LED4)
P32/SDA
54
27
P25(LED5)
P31/DA2
55
26
P26(LED6)
P30/DA1
56
25
P27(LED7)
VCC
57
24
VSS
XOUT
M38049FFHFP/HP/KP
VREF
58
23
AVSS
59
22
XIN
P67/AN7
60
21
P40/INT40/XCOUT
16
P43/INT2
15
14
P45/TXD1
P44/RXD1
12
13
P46/SCLK1
P47/SRDY1/CNTR2
11
P50/SIN2
9
10
8
P53/SRDY2
P52/SCLK2
7
P54/CNTR0
P51/SOUT2
6
P55/CNTR1
P42/INT1
5
17
P56/PWM
64
4
CNVSS
P63/AN3
3
18
P60/AN0
63
P57/INT3
RESET
P64/AN4
1
P41/INT00/XCIN
19
2
20
62
P62/AN2
61
P61/AN1
P66/AN6
P65/AN5
Package type : 64P6N-A/64P6Q-A/64P6U-A
Fig. 1 3804 group (Spec. H) pin configuration
PIN CONFIGURATION (TOP VIEW)
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
M38049FFHSP
VCC
VREF
AVSS
P67/AN7
P66/AN6
P65/AN5
P64/AN4
P63/AN3
P62/AN2
P61/AN1
P60/AN0
P57/INT3
P56/PWM
P55/CNTR1
P54/CNTR0
P53/SRDY2
P52/SCLK2
P51/SOUT2
P50/SIN2
P47/SRDY1/CNTR2
P46/SCLK1
P45/TXD1
P44/RXD1
P43/INT2
P42/INT1
CNVSS
RESET
P41/INT00/XCIN
P40/INT40/XCOUT
XIN
XOUT
VSS
64
63
62
61
60
59
58
57
56
55
54
53
52
51
50
49
48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33
P30/DA1
P31/DA2
P32/SDA
P33/SCL
P34/RXD3
P35/TXD3
P36/SCLK3
P37/SRDY3
P00/AN8
P01/AN9
P02/AN10
P03/AN11
P04/AN12
P05/AN13
P06/AN14
P07/AN15
P10/INT41
P11/INT01
P12
P13
P14
P15
P16
P17
P20(LED0)
P21(LED1)
P22(LED2)
P23(LED3)
P24(LED4)
P25(LED5)
P26(LED6)
P27(LED7)
Package type : 64P4B
Fig. 2 3804 group (Spec. H) pin configuration
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1-3
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28
29
3
VREF AVSS
I/O port P6
4 5 6 7 8 9 10 11
P6(8)
INT3
PWM(8)
RAM
I/O port P5
12 13 14 15 16 17 18 19
P5(8)
SI/O2(8)
ROM
A
P4(8)
X
INT00
INT1
INT2
INT40
P3(8)
I/O port P4
27
I/O port P3
P2(8)
I/O port P2
(LED drive)
2
P1(8)
I/O port P1
I/O port P0
49 50 51 52 53 54 55 56
P0(8)
Timer Y (8)
Timer X (8)
Timer 2 (8)
Timer 1 (8)
INT01
INT41
41 42 43 44 45 46 47 48
IC
Timer Z (16)
Prescaler Y (8)
Prescaler X (8)
Prescaler 12 (8)
CNTR2
CNTR1
26
CNVSS
33 34 35 36 37 38 39 40
CNTR0
SI/O3(8)
57 58 59 60 61 62 63 64
D/A
D/A
converter converter
2 (8)
1 (8)
PS
PC L
S
Y
20 21 22 23 24 25 28 29
SI/O1(8)
PC H
C P U
Data bus
1
32
3804 Group (Spec.H)
2
A/D
converter
(10)
Clock generating circuit
31
RESET
30
Reset input
V CC
X IN X OUT X CIN X COUT
V SS
Clock Clock Sub-clock Sub-clock
input output input
output
FUNCTIONAL BLOCK DIAGRAM (Package: 64P4B)
HARDWARE
FUNCTIONAL BLOCK
FUNCTIONAL BLOCK
Fig. 3 Functional block diagram
1-4
HARDWARE
3804 Group (Spec.H)
PIN DESCRIPTION
PIN DESCRIPTION
Table 2 Pin description
Pin
VCC, VSS
Functions
Name
Function except a port function
•Apply voltage of 2.7 V–5.5 V to Vcc, and 0 V to Vss.
CNVSS
Power source
CNVSS input
VREF
Reference voltage
•Reference voltage input pin for A/D and D/A converters.
AVSS
Analog power source
•Analog power source input pin for A/D and D/A converters.
•This pin controls the operation mode of the chip.
•Normally connected to VSS.
•Connect to VSS.
RESET
XIN
Reset input
Clock input
XOUT
Clock output
•Reset input pin for active “L”.
•Input and output pins for the clock generating circuit.
•Connect a ceramic resonator or quartz-crystal oscillator between the XIN and XOUT pins to set
the oscillation frequency.
•When an external clock is used, connect the clock source to the XIN pin and leave the XOUT
pin open.
P00/AN8–
P07/AN15
I/O port P0
P10/INT41
P11/INT01
I/O port P1
P12–P17
P20–P27
I/O port P2
•8-bit CMOS I/O port.
•A/D converter input pin
•I/O direction register allows each pin to be individually
programmed as either input or output.
•Interrupt input pin
•CMOS compatible input level.
•CMOS 3-state output structure.
•Pull-up control is enabled in a bit unit.
•P20–P27 are enabled to output large current for LED drive.
P30/DA1
P31/DA2
I/O port P3
P32/SDA
P33/SCL
P34/RxD3
P35/TxD3
P36/SCLK3
P37/SRDY3
•8-bit CMOS I/O port.
•D/A converter input pin
•I/O direction register allows each pin to be individually
programmed as either input or output.
•I2C-BUS interface function pins
•CMOS compatible input level.
•P32 to P33 can be switched between CMOS compat- •Serial I/O3 function pin
ible input level or SMBUS input level in the I2C-BUS
interface function.
•P30, P31, P34–P37 are CMOS 3-state output structure.
•P32, P33 are N-channel open-drain output structure.
•Pull-up control of P30, P31, P34–P37 is enabled in a bit
unit.
P40/INT40/
XCOUT
P41/INT00/
XCIN
I/O port P4
P42/INT1
P43/INT2
•Serial I/O1 function pin
•Serial I/O1, timer Z function pin
I/O port P5
•8-bit CMOS I/O port.
•Serial I/O2 function pin
•I/O direction register allows each pin to be individually
programmed as either input or output.
•CMOS compatible input level.
P54/CNTR0
•CMOS 3-state output structure.
P55/CNTR1
•Pull-up control is enabled in a bit unit.
P56/PWM
P57/INT3
P60/AN0–
P67/AN7
•Interrupt input pin
•I/O direction register allows each pin to be individually •Sub-clock generating I/O pin
programmed as either input or output.
(resonator connected)
•CMOS compatible input level.
•Interrupt input pin
•CMOS 3-state output structure.
•Pull-up control is enabled in a bit unit.
P44/RxD1
P45/TxD1
P46/SCLK1
P47/SRDY1
/CNTR2
P50/SIN2
P51/SOUT2
P52/SCLK2
P53/SRDY2
•8-bit CMOS I/O port.
I/O port P6
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REJ09B0212-0100Z
•Timer X function pin
•Timer Y function pin
•PWM output pin
•Interrupt input pin
•A/D converter input pin
1-5
HARDWARE
3804 Group (Spec.H)
PART NUMBERING
PART NUMBERING
Product name
M3804 9
F
F
H
SP
Package type
SP : 64P4B
FP : 64P6N-A
HP : 64P6Q-A
KP : 64P6U-A
: standard
H : Minner spec. change product
ROM/PROM size
9 : 36864 bytes
1 : 4096 bytes
A: 40960 bytes
2 : 8192 bytes
B: 45056 bytes
3 : 12288 bytes
C: 49152 bytes
4 : 16384 bytes
D: 53248 bytes
5 : 20480 bytes
E: 57344 bytes
6 : 24576 bytes
F : 61440 bytes
7 : 28672 bytes
8 : 32768 bytes
Memory type
F : Flash memory version
RAM size
0 : 192 bytes
1 : 256 bytes
2 : 384 bytes
3 : 512 bytes
4 : 640 bytes
5 : 768 bytes
6 : 896 bytes
7 : 1024 bytes
8 : 1536 bytes
9 : 2048 bytes
Fig. 4 Part numbering
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HARDWARE
3804 Group (Spec.H)
GROUP EXPANSION
GROUP EXPANSION
Packages
Renesas plans to expand the 3804 group (Spec. H) as follows.
Memory Size
Flash memory size ......................................................... 60 K bytes
RAM size ....................................................................... 2048 bytes
64P4B ......................................... 64-pin shrink plastic-molded DIP
64P6N-A .................................... 0.8 mm-pitch plastic molded QFP
64P6Q-A .................................. 0.5 mm-pitch plastic molded LQFP
64P6U-A .................................. 0.8 mm-pitch plastic molded LQFP
Memory Expansion Plan
ROM size (bytes)
: Under development
As of Dec. 2004
: Mass production
M38049FFH
60K
M38049FF
48K
32K
28K
24K
20K
16K
12K
8K
384
512
640
768
896
1024
1152
1280
1408
1536
2048
3072
4032
RAM size (bytes)
Fig. 5 Memory expansion plan
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1-7
HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
FUNCTIONAL DESCRIPTION
CENTRAL PROCESSING UNIT (CPU)
[Stack Pointer (S)]
The 3804 group (Spec. H) uses the standard 740 Family instruction set. Refer to the table of 740 Family addressing modes and
machine instructions or the 740 Family Software Manual for details on the instruction set.
Machine-resident 740 Family instructions are as follows:
The FST and SLW instructions cannot be used.
The STP, WIT, MUL, and DIV instructions can be used.
[Accumulator (A)]
The accumulator is an 8-bit register. Data operations such as data
transfer, etc. are executed mainly through the accumulator.
[Index Register X (X)]
The index register X is an 8-bit register. In the index addressing
modes, the value of the OPERAND is added to the contents of
register X and specifies the real address.
[Index Register Y (Y)]
The stack pointer is an 8-bit register used during subroutine calls
and interrupts. This register indicates start address of stored area
(stack) for storing registers during subroutine calls and interrupts.
The low-order 8 bits of the stack address are determined by the
contents of the stack pointer. The high-order 8 bits of the stack address are determined by the stack page selection bit. If the stack
page selection bit is “0” , the high-order 8 bits becomes “0016”. If
the stack page selection bit is “1”, the high-order 8 bits becomes
“0116”.
The operations of pushing register contents onto the stack and
popping them from the stack are shown in Figure 7.
Store registers other than those described in Figure 6 with program when the user needs them during interrupts or subroutine
calls (see Table 3).
[Program Counter (PC)]
The program counter is a 16-bit counter consisting of two 8-bit
registers PCH and PCL. It is used to indicate the address of the
next instruction to be executed.
The index register Y is an 8-bit register. In partial instruction, the
value of the OPERAND is added to the contents of register Y and
specifies the real address.
b0
b7
A
Accumulator
b0
b7
X
Index register X
b0
b7
Y
b7
Index register Y
b0
S
b15
b7
Stack pointer
b0
PCL
PCH
b7
Program counter
b0
N V T B D I Z C
Processor status register (PS)
Carry flag
Zero flag
Interrupt disable flag
Decimal mode flag
Break flag
Index X mode flag
Overflow flag
Negative flag
Fig. 6 740 Family CPU register structure
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1-8
HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
On-going Routine
Interrupt request
(Note)
M (S)
Execute JSR
Push return address
on stack
M (S)
(PCH)
(S)
(S) – 1
M (S)
(PCL)
(S)
(S)– 1
(S)
M (S)
(S)
M (S)
(S)
Subroutine
POP return
address from stack
(S) + 1
(PCL)
M (S)
(S)
(S) + 1
(PCH)
M (S)
(S) – 1
(PCL)
Push return address
on stack
(S) – 1
(PS)
Push contents of processor
status register on stack
(S) – 1
Interrupt
Service Routine
Execute RTS
(S)
(PCH)
I Flag is set from “0” to “1”
Fetch the jump vector
Execute RTI
Note: Condition for acceptance of an interrupt
(S)
(S) + 1
(PS)
M (S)
(S)
(S) + 1
(PCL)
M (S)
(S)
(S) + 1
(PCH)
M (S)
POP contents of
processor status
register from stack
POP return
address
from stack
Interrupt enable flag is “1”
Interrupt disable flag is “0”
Fig. 7 Register push and pop at interrupt generation and subroutine call
Table 3 Push and pop instructions of accumulator or processor status register
Push instruction to stack
Pop instruction from stack
Accumulator
PHA
PLA
Processor status register
PHP
PLP
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1-9
HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
[Processor status register (PS)]
The processor status register is an 8-bit register consisting of 5
flags which indicate the status of the processor after an arithmetic
operation and 3 flags which decide MCU operation. Branch operations can be performed by testing the Carry (C) flag , Zero (Z) flag,
Overflow (V) flag, or the Negative (N) flag. In decimal mode, the Z,
V, N flags are not valid.
•Bit 0: Carry flag (C)
The C flag contains a carry or borrow generated by the arithmetic
logic unit (ALU) immediately after an arithmetic operation. It can
also be changed by a shift or rotate instruction.
•Bit 1: Zero flag (Z)
The Z flag is set if the result of an immediate arithmetic operation
or a data transfer is “0”, and cleared if the result is anything other
than “0”.
•Bit 2: Interrupt disable flag (I)
The I flag disables all interrupts except for the interrupt
generated by the BRK instruction.
Interrupts are disabled when the I flag is “1”.
•Bit 3: Decimal mode flag (D)
The D flag determines whether additions and subtractions are
executed in binary or decimal. Binary arithmetic is executed when
this flag is “0”; decimal arithmetic is executed when it is “1”.
Decimal correction is automatic in decimal mode. Only the ADC
and SBC instructions can execute decimal arithmetic.
•Bit 4: Break flag (B)
The B flag is used to indicate that the current interrupt was
generated by the BRK instruction. The BRK flag in the processor
status register is always “0”. When the BRK instruction is used to
generate an interrupt, the processor status register is pushed
onto the stack with the break flag set to “1”.
•Bit 5: Index X mode flag (T)
When the T flag is “0”, arithmetic operations are performed
between accumulator and memory. When the T flag is “1”, direct
arithmetic operations and direct data transfers are enabled
between memory locations.
•Bit 6: Overflow flag (V)
The V flag is used during the addition or subtraction of one byte
of signed data. It is set if the result exceeds +127 to -128. When
the BIT instruction is executed, bit 6 of the memory location
operated on by the BIT instruction is stored in the overflow flag.
•Bit 7: Negative flag (N)
The N flag is set if the result of an arithmetic operation or data
transfer is negative. When the BIT instruction is executed, bit 7 of
the memory location operated on by the BIT instruction is stored
in the negative flag.
Table 4 Set and clear instructions of each bit of processor status register
C flag
Z flag
I flag
D flag
B flag
T flag
V flag
N flag
Set instruction
SEC
–
SEI
SED
–
SET
–
–
Clear instruction
CLC
–
CLI
CLD
–
CLT
CLV
–
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
[CPU Mode Register (CPUM)] 003B16
The CPU mode register contains the stack page selection bit, etc.
The CPU mode register is allocated at address 003B16.
b7
b0
1
CPU mode register
(CPUM : address 003B16)
Processor mode bits
b1 b0
0 0 : Single-chip mode
0 1 :
1 0 : Not available
1 1 :
Stack page selection bit
0 : 0 page
1 : 1 page
Fix this bit to “1”.
Port XC switch bit
0 : I/O port function (stop oscillating)
1 : XCIN–XCOUT oscillating function
Main clock (XIN–XOUT) stop bit
0 : Oscillating
1 : Stopped
Main clock division ratio selection bits
b7 b6
0 0 : φ = f(XIN)/2 (high-speed mode)
0 1 : φ = f(XIN)/8 (middle-speed mode)
1 0 : φ = f(XCIN)/2 (low-speed mode)
1 1 : Not available
Fig. 8 Structure of CPU mode register
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
MISRG
(1) Bit 0 of address 001016: Oscillation stabilizing time set after STP instruction released bit
When the MCU stops the clock oscillation by the STP instruction
and the STP instruction has been released by an external interrupt
source, usually, the fixed values of Timer 1 and Prescaler 12
(Timer 1 = 0116, Prescaler 12 = FF16) are automatically reloaded
in order for the oscillation to stabilize. The user can inhibit the automatic setting by setting “1” to bit 0 of MISRG (address 001016).
However, by setting this bit to “1”, the previous values, set just before the STP instruction was executed, will remain in Timer 1 and
Prescaler 12. Therefore, you will need to set an appropriate value
to each register, in accordance with the oscillation stabilizing time,
before executing the STP instruction.
Figure 9 shows the structure of MISRG.
(2) Bits 1, 2, 3 of address 0010 16: Middle-speed Mode Automatic Switch Function
In order to switch the clock mode of an MCU which has a subclock, the following procedure is necessary:
set CPU mode register (003B16) --> start main clock oscillation -->
wait for oscillation stabilization --> switch to middle-speed mode
(or high-speed mode).
However, the 3804 group (Spec. H) has the built-in function which
automatically switches from low to middle-speed mode either by
the SCL/SDA interrupt or by program.
b7
●Middle-speed mode automatic switch by SCL/SDA Interrupt
The SCL/SDA interrupt source enables an automatic switch when
the middle-speed mode automatic switch set bit (bit 1) of MISRG
(address 001016) is set to “1”. The conditions for an automatic
switch execution depend on the settings of bits 5 and 6 of the I2C
START/STOP condition control register (address 001616). Bit 5 is
the SCL/SDA interrupt pin polarity selection bit and bit 6 is the
SCL/SDA interrupt pin selection bit. The main clock oscillation stabilizing time can also be selected by middle-speed mode
automatic switch wait time set bit (bit 2) of the MISRG.
●Middle-speed mode automatic switch by program
The middle-speed mode can also be automatically switched by
program while operating in low-speed mode. By setting the
middle-speed automatic switch start bit (bit 3) of MISRG (address
001016) to “1” in the condition that the middle-speed mode automatic switch set bit is “1” while operating in low-speed mode, the
MCU will automatically switch to middle-speed mode. In this case,
the oscillation stabilizing time of the main clock can be selected by
the middle-speed automatic switch wait time set bit (bit 2) of
MISRG (address 001016).
b0
MISRG
(MISRG : address 001016)
Oscillation stabilizing time set after STP instruction
released bit
0: Automatically set “0116” to Timer 1, “FF16” to
Prescaler 12
1: Automatically set disabled
Middle-speed mode automatic switch set bit
0: Not set automatically
1: Automatic switching enabled (Note1, 2)
Middle-speed mode automatic switch wait time set bit
0: 4.5 to 5.5 machine cycles
1: 6.5 to 7.5 machine cycles
Middle-speed mode automatic switch start bit
(Depending on program)
0: Invalid
1: Automatic switch start (Note1)
Not used (return “0” when read)
(Do not write “1” to this bit)
Note 1: During operation in low-speed mode, it is possible automatically to
switch to middle-speed mode owing to SCL/SDA interrupt.
2: When automatic switch to middle-speed mode from low-speed
mode occurs, the values of CPU mode register (003B16) change.
Fig. 9 Structure of MISRG
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
MEMORY
Special Function Register (SFR) Area
Interrupt Vector Area
The interrupt vector area contains reset and interrupt vectors.
The Special Function Register area in the zero page contains control registers such as I/O ports and timers.
Zero Page
RAM
Access to this area with only 2 bytes is possible in the zero page
addressing mode.
The RAM is used for data storage and for stack area of subroutine
calls and interrupts.
Special Page
ROM
Access to this area with only 2 bytes is possible in the special
page addressing mode.
The ROM area can program/erase.
RAM area
RAM size
(bytes)
Address
XXXX16
192
256
384
512
640
768
896
1024
1536
2048
00FF16
013F16
01BF16
023F16
02BF16
033F16
03BF16
043F16
063F16
083F16
000016
SFR area
Zero page
004016
010016
RAM
XXXX16
Not used
0FF016
0FFF16
SFR area
Not used
YYYY16
ROM area
ROM size
(bytes)
Address
YYYY16
4096
8192
12288
16384
20480
24576
28672
32768
36864
40960
45056
49152
53248
57344
61440
F00016
E00016
D00016
C00016
B00016
A00016
900016
800016
700016
600016
500016
400016
300016
200016
100016
ROM
FF0016
FFDC16
Interrupt vector area
Special page
FFFE16
FFFF16
Fig. 10 Memory map diagram
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
000016
Port P0 (P0)
002016
Prescaler 12 (PRE12)
000116
Port P0 direction register (P0D)
002116
Timer 1 (T1)
000216
Port P1 (P1)
002216
Timer 2 (T2)
000316
Port P1 direction register (P1D)
002316
Timer XY mode register (TM)
000416
Port P2 (P2)
002416
Prescaler X (PREX)
000516
Port P2 direction register (P2D)
002516
Timer X (TX)
000616
Port P3 (P3)
002616
Prescaler Y (PREY)
000716
Port P3 direction register (P3D)
002716
Timer Y (TY)
000816
Port P4 (P4)
002816
Timer Z low-order (TZL)
000916
Port P4 direction register (P4D)
002916
Timer Z high-order (TZH)
000A16
Port P5 (P5)
002A16
Timer Z mode register (TZM)
000B16
Port P5 direction register (P5D)
002B16
PWM control register (PWMCON)
000C16
Port P6 (P6)
002C16
PWM prescaler (PREPWM)
000D16
Port P6 direction register (P6D)
002D16
PWM register (PWM)
000E16
Timer 12, X count source selection register (T12XCSS)
002E16
000F16
Timer Y, Z count source selection register (TYZCSS)
002F16
Baud rate generator 3 (BRG3)
001016
MISRG
003016
Transmit/Receive buffer register 3 (TB3/RB3)
001116
I2C data shift register (S0)
003116
Serial I/O3 status register (SIO3STS)
001216
I2C special mode status register (S3)
003216
Serial I/O3 control register (SIO3CON)
001316
I2C status register (S1)
003316
UART3 control register (UART3CON)
001416
I2C control register (S1D)
003416
AD/DA control register (ADCON)
001516
I2C clock control register (S2)
003516
AD conversion register 1 (AD1)
001616
I2C START/STOP condition control register (S2D)
003616
DA1 conversion register (DA1)
001716
I2C special mode control register (S3D)
003716
DA2 conversion register (DA2)
001816
Transmit/Receive buffer register 1 (TB1/RB1)
003816
AD conversion register 2 (AD2)
001916
Serial I/O1 status register (SIO1STS)
003916
Interrupt source selection register (INTSEL)
001A16
Serial I/O1 control register (SIO1CON)
003A16
Interrupt edge selection register (INTEDGE)
001B16
UART1 control register (UART1CON)
003B16
CPU mode register (CPUM)
001C16
Baud rate generator 1 (BRG1)
003C16
Interrupt request register 1 (IREQ1)
001D16
Serial I/O2 control register (SIO2CON)
003D16
Interrupt request register 2 (IREQ2)
001E16
Watchdog timer control register (WDTCON)
003E16
Interrupt control register 1 (ICON1)
001F16
Serial I/O2 register (SIO2)
003F16
Interrupt control register 2 (ICON2)
0FE016
Flash memory control register 0 (FMCR0)
0FF016
Port P0 pull-up control register (PULL0)
0FE116
Flash memory control register 1 (FMCR1)
0FF116
Port P1 pull-up control register (PULL1)
0FE216
Flash memory control register 2 (FMCR2)
0FF216
Port P2 pull-up control register (PULL2)
0FE316
Reserved ✽
0FF316
Port P3 pull-up control register (PULL3)
0FE416
Reserved ✽
0FF416
Port P4 pull-up control register (PULL4)
0FE516
Reserved ✽
0FF516
Port P5 pull-up control register (PULL5)
0FE616
Reserved ✽
0FF616
Port P6 pull-up control register (PULL6)
0FE716
Reserved ✽
0FF716
I2C slave address register 0 (S0D0)
0FE816
Reserved ✽
0FF816
I2C slave address register 1 (S0D1)
0FE916
Reserved ✽
0FF916
I2C slave address register 2 (S0D2)
0FEA16
Reserved ✽
0FEB16
Reserved ✽
0FEC16
Reserved ✽
0FED16
Reserved ✽
0FEE16
Reserved ✽
0FEF16
Reserved ✽
✽ Reserved area: Do not write any data to these addresses,
because these areas are reserved.
Fig. 11 Memory map of special function register (SFR)
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
I/O PORTS
The I/O ports have direction registers which determine the input/
output direction of each individual pin. Each bit in a direction register corresponds to one pin, and each pin can be set to be input
port or output port.
When “0” is written to the bit corresponding to a pin, that pin be-
comes an input pin. When “1” is written to that bit, that pin becomes an output pin.
If data is read from a pin which is set to output, the value of the
port output latch is read, not the value of the pin itself. Pins set to
input are floating. If a pin set to input is written to, only the port
output latch is written to and the pin remains floating.
Table 5 I/O port function
Pin
P00/AN8–P07/AN15
P10/INT41
P11/INT01
P12–P17
P20/LED0–
P27/LED7
P30/DA1
P31/DA2
P32/SDA
P33/SCL
P34/RxD3
P35/TxD3
P36/SCLK3
P37/SRDY3
P40/INT40/XCIN
P41/INT00/XCOUT
Name
Port P0
Port P1
I/O Structure
CMOS compatible input level
CMOS 3-state output
Non-Port Function
A/D converter input
External interrupt input
Related SFRs
Ref.No.
AD/DA control register
Interrupt edge selection
register
(1)
(2)
(3)
Port P2
Port P3
Port P4
CMOS compatible input level
CMOS 3-state output
CMOS compatible input level
N-channel open-drain output
CMOS/SMBUS input level (when
selecting I2C-BUS interface function)
CMOS compatible input level
CMOS 3-state output
CMOS compatible input level
CMOS 3-state output
P42/INT1
P43/INT2
P44/RxD1
P45/TxD1
P46/SCLK1
P47/SRDY1/CNTR2
D/A converter output
AD/DA control register
(4)
I2C-BUS interface function I/O
I2C control register
(5)
Serial I/O3 function I/O
Serial I/O3 control
register
UART3 control register
(6)
(7)
(8)
(9)
External interrupt input
Sub-clock generating
circuit
Interrupt edge selection
register
CPU mode register
Interrupt edge selection
register
(10)
(11)
Serial I/O1 function I/O
Serial I/O1 control
register
UART1 control register
Serial I/O1 function I/O
Timer Z function I/O
Serial I/O1 control
register
Timer Z mode register
Serial I/O2 control
register
(6)
(7)
(8)
(12)
External interrupt input
P50/SIN2
P51/SOUT2
P52/SCLK2
P53/SRDY2
P54/CNTR0
P55/CNTR1
P56/PWM
P57/INT3
Port P5
P60/AN0–P67/AN7
Port P6
CMOS compatible input level
CMOS 3-state output
CMOS compatible input level
CMOS 3-state output
Serial I/O2 function I/O
Timer X, Y function I/O
Timer XY mode register
PWM output
External interrupt input
PWM control register
Interrupt edge selection
register
AD/DA control register
A/D converter input
(2)
(13)
(14)
(15)
(16)
(17)
(18)
(2)
(1)
Notes 1: Refer to the applicable sections how to use double-function ports as function I/O ports.
2: Make sure that the input level at each pin is either 0 V or VCC during execution of the STP instruction.
When an input level is at an intermediate potential, a current will flow from VCC to VSS through the input-stage gate.
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
(1) Ports P0, P6
(2) Ports P10, P11, P42, P43, P57
Pull-up control bit
Pull-up control bit
Direction
register
Data bus
Direction
register
Port latch
Data bus
Port latch
A/D converter input
Analog input pin
selection bit
(3) Ports P12 to P17, P2
Interrupt input
(4) Ports P30, P31
Pull-up control bit
Pull-up control bit
Direction
register
Direction
register
Data bus
Port latch
Data bus
Port latch
D/A converter output
DA1 output enable (P30)
DA2 output enable (P31)
(6) Ports P34, P44
(5) Ports P32, P33
Pull-up control bit
I2C-BUS interface enable bit
Serial I/O enable bit
Receive enable bit
Direction
register
Data bus
Direction
register
Port latch
Data bus
SDA output
SCL output
Port latch
SDA input
SCL input
Serial I/O input
(7) Ports P35, P45
(8) Ports P36, P46
Pull-up control bit
Serial I/O synchronous clock
selection bit
Pull-up control bit
Serial I/O enable bit
Serial I/O enable bit
Transmit enable bit
P-channel output
disable bit
Serial I/O mode selection bit
Serial I/O enable bit
Direction
register
Direction
register
Data bus
Port latch
Serial I/O output
Data bus
Port latch
Serial I/O clock output
Serial I/O external clock input
Fig. 12 Port block diagram (1)
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
(10) Port P40
(9) Port P37
Pull-up control bit
Pull-up control bit
Serial I/O3 mode
selection bit
Serial I/O3 enable bit
SRDY3 output enable bit
Port XC switch bit
Direction
register
Direction
register
Data bus
Port latch
Data bus
Port latch
INT40 interrupt input
Serial I/O3 ready output
Oscillator
Port P41
Port XC switch bit
(11) Port P41
(12) Port P47
Pull-up control bit
Port XC switch bit
Pull-up control bit
Serial I/O1 mode selection bit
Serial I/O1 enable bit
SRDY1 output enable bit
Direction
register
Direction
register
Data bus
Timer Z operating
mode bits
Bit 2
Bit 1
Bit 0
Port latch
Data bus
Port latch
INT00 interrupt input
Sub-clock generating circuit input
Timer output
Serial I/O1 ready output
CNTR2 interrupt input
(14) Port P51
(13) Port P50
Pull-up control bit
Pull-up control bit
Serial I/O2 transmit completion signal
Serial I/O2 port selection bit
Direction
register
Data bus
P-channel output
disable bit
Direction
register
Port latch
Data bus
Port latch
Serial I/O2 input
Serial I/O2 output
Fig. 13 Port block diagram (2)
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
(15) Port P52
(16) Port P53
Pull-up control bit
Pull-up control bit
Serial I/O2 synchronous clock
selection bit
Serial I/O2 port selection bit
SRDY2 enable bit
Direction
register
Direction
register
Port latch
Data bus
Data bus
Port latch
Serial I/O2 ready output
Serial I/O2 clock output
Serial I/O2 external clock input
(17) Ports P54, P55
(18) Port P56
Pull-up control bit
Pull-up control bit
PWM output enable bit
Direction
register
Data bus
Direction
register
Data bus
Port latch
Pulse output mode
Port latch
PWM output
Timer output
CNTR interrupt input
Fig. 14 Port block diagram (3)
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HARDWARE
3804 Group (Spec.H)
b7
FUNCTIONAL DESCRIPTION
b0
Port P0 pull-up control register
(PULL0: address 0FF016)
P00 pull-up control bit
0: No pull-up
1: Pull-up
P01 pull-up control bit
0: No pull-up
1: Pull-up
P02 pull-up control bit
0: No pull-up
1: Pull-up
P03 pull-up control bit
0: No pull-up
1: Pull-up
P04 pull-up control bit
0: No pull-up
1: Pull-up
P05 pull-up control bit
0: No pull-up
1: Pull-up
P06 pull-up control bit
0: No pull-up
1: Pull-up
P07 pull-up control bit
0: No pull-up
1: Pull-up
b7
Note: Pull-up control is valid when the corresponding bit
of the port direction register is “0” (input).
When that bit is “1” (output), pull-up cannot be set
to the port of which pull-up is selected.
b0
Port P1 pull-up control register
(PULL1: address 0FF116)
P10 pull-up control bit
0: No pull-up
1: Pull-up
P11 pull-up control bit
0: No pull-up
1: Pull-up
P12 pull-up control bit
0: No pull-up
1: Pull-up
P13 pull-up control bit
0: No pull-up
1: Pull-up
P14 pull-up control bit
0: No pull-up
1: Pull-up
P15 pull-up control bit
0: No pull-up
1: Pull-up
P16 pull-up control bit
0: No pull-up
1: Pull-up
P17 pull-up control bit
0: No pull-up
1: Pull-up
Note: Pull-up control is valid when the corresponding bit
of the port direction register is “0” (input).
When that bit is “1” (output), pull-up cannot be set
to the port of which pull-up is selected.
Fig. 15 Structure of port pull-up control register (1)
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HARDWARE
3804 Group (Spec.H)
b7
FUNCTIONAL DESCRIPTION
b0
Port P2 pull-up control register
(PULL2: address 0FF216)
P20 pull-up control bit
0: No pull-up
1: Pull-up
P21 pull-up control bit
0: No pull-up
1: Pull-up
P22 pull-up control bit
0: No pull-up
1: Pull-up
P23 pull-up control bit
0: No pull-up
1: Pull-up
P24 pull-up control bit
0: No pull-up
1: Pull-up
P25 pull-up control bit
0: No pull-up
1: Pull-up
P26 pull-up control bit
0: No pull-up
1: Pull-up
P27 pull-up control bit
0: No pull-up
1: Pull-up
b7
Note: Pull-up control is valid when the corresponding bit
of the port direction register is “0” (input).
When that bit is “1” (output), pull-up cannot be set
to the port of which pull-up is selected.
b0
Port P3 pull-up control register
(PULL3: address 0FF316)
P30 pull-up control bit
0: No pull-up
1: Pull-up
P31 pull-up control bit
0: No pull-up
1: Pull-up
Not used
(return “0” when read)
P34 pull-up control bit
0: No pull-up
1: Pull-up
P35 pull-up control bit
0: No pull-up
1: Pull-up
P36 pull-up control bit
0: No pull-up
1: Pull-up
P37 pull-up control bit
0: No pull-up
1: Pull-up
Note: Pull-up control is valid when the corresponding bit
of the port direction register is “0” (input).
When that bit is “1” (output), pull-up cannot be set
to the port of which pull-up is selected.
Fig. 16 Structure of port pull-up control register (2)
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HARDWARE
3804 Group (Spec.H)
b7
FUNCTIONAL DESCRIPTION
b0
Port P4 pull-up control register
(PULL4: address 0FF416)
P40 pull-up control bit
0: No pull-up
1: Pull-up
P41 pull-up control bit
0: No pull-up
1: Pull-up
P42 pull-up control bit
0: No pull-up
1: Pull-up
P43 pull-up control bit
0: No pull-up
1: Pull-up
P44 pull-up control bit
0: No pull-up
1: Pull-up
P45 pull-up control bit
0: No pull-up
1: Pull-up
P46 pull-up control bit
0: No pull-up
1: Pull-up
P47 pull-up control bit
0: No pull-up
1: Pull-up
b7
Note: Pull-up control is valid when the corresponding bit
of the port direction register is “0” (input).
When that bit is “1” (output), pull-up cannot be set
to the port of which pull-up is selected.
b0
Port P5 pull-up control register
(PULL5: address 0FF516)
P50 pull-up control bit
0: No pull-up
1: Pull-up
P51 pull-up control bit
0: No pull-up
1: Pull-up
P52 pull-up control bit
0: No pull-up
1: Pull-up
P53 pull-up control bit
0: No pull-up
1: Pull-up
P54 pull-up control bit
0: No pull-up
1: Pull-up
P55 pull-up control bit
0: No pull-up
1: Pull-up
P56 pull-up control bit
0: No pull-up
1: Pull-up
P57 pull-up control bit
0: No pull-up
1: Pull-up
Note: Pull-up control is valid when the corresponding bit
of the port direction register is “0” (input).
When that bit is “1” (output), pull-up cannot be set
to the port of which pull-up is selected.
Fig. 17 Structure of port pull-up control register (3)
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HARDWARE
3804 Group (Spec.H)
b7
FUNCTIONAL DESCRIPTION
b0
Port P6 pull-up control register
(PULL6: address 0FF616)
P60 pull-up control bit
0: No pull-up
1: Pull-up
P61 pull-up control bit
0: No pull-up
1: Pull-up
P62 pull-up control bit
0: No pull-up
1: Pull-up
P63 pull-up control bit
0: No pull-up
1: Pull-up
P64 pull-up control bit
0: No pull-up
1: Pull-up
P65 pull-up control bit
0: No pull-up
1: Pull-up
P66 pull-up control bit
0: No pull-up
1: Pull-up
P67 pull-up control bit
0: No pull-up
1: Pull-up
Note: Pull-up control is valid when the corresponding bit
of the port direction register is “0” (input).
When that bit is “1” (output), pull-up cannot be set
to the port of which pull-up is selected.
Fig. 18 Structure of port pull-up control register (4)
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
INTERRUPTS
■ Notes
The 3804 group (Spaec. H)’s interrupts are a type of vector and
occur by 16 sources among 23 sources: nine external, thirteen internal, and one software.
When setting the followings, the interrupt request bit may be set to
“1”.
•When setting external interrupt active edge
Related register: Interrupt edge selection register (address 003A16)
Timer XY mode register (address 002316)
Timer Z mode register (address 002A16)
I2C START/STOP condition control register
(address 001616)
•When switching interrupt sources of an interrupt vector address
where two or more interrupt sources are allocated
Related register: Interrupt source selection register
(address 003916)
When not requiring for the interrupt occurrence synchronized with
these setting, take the following sequence.
➀Set the corresponding interrupt enable bit to “0” (disabled).
➁Set the interrupt edge select bit or the interrupt source select bit
to “1”.
➂Set the corresponding interrupt request bit to “0” after 1 or more
instructions have been executed.
④Set the corresponding interrupt enable bit to “1” (enabled).
Interrupt Control
Each interrupt is controlled by an interrupt request bit, an interrupt
enable bit, and the interrupt disable flag except for the software interrupt set by the BRK instruction. An interrupt occurs if the
corresponding interrupt request and enable bits are “1” and the interrupt disable flag is “0”.
Interrupt enable bits can be set or cleared by software.
Interrupt request bits can be cleared by software, but cannot be
set by software.
The reset and the BRK instruction cannot be disabled with any
flag or bit. The I (interrupt disable) flag disables all interrupts except the reset and the BRK instruction interrupt.
When several interrupt requests occur at the same time, the interrupts are received according to priority.
Interrupt Operation
By acceptance of an interrupt, the following operations are automatically performed:
1. The contents of the program counter and the processor status
register are automatically pushed onto the stack.
2. The interrupt disable flag is set and the corresponding interrupt
request bit is cleared.
3. The interrupt jump destination address is read from the vector
table into the program counter.
Interrupt Source Selection
Which of each combination of the following interrupt sources can
be selected by the interrupt source selection register (address
003916).
1. INT0 or Timer Z
2. Serial I/O1 transmission or SCL, SDA
3. CNTR0 or SCL, SDA
4. CNTR1 or Serial I/O3 reception
5. Serial I/O2 or Timer Z
6. INT2 or I2C
7. INT4 or CNTR2
8. A/D converter or serial I/O3 transmission
External Interrupt Pin Selection
The occurrence sources of the external interrupt INT0 and INT4
can be selected from either input from INT00 and INT40 pin, or input from INT01 and INT41 pin by the INT0, INT4 interrupt switch bit
of interrupt edge selection register (bit 6 of address 003A16).
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3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
Table 6 Interrupt vector addresses and priority
Interrupt Source
Priority
Vector Addresses (Note 1)
High
Low
FFFD16
FFFC16
FFFB16
FFFA16
Interrupt Request
Generating Conditions
Remarks
Reset (Note 2)
INT0
1
2
Timer Z
INT1
3
FFF916
FFF816
At detection of either rising or
falling edge of INT1 input
4
FFF716
FFF616
At completion of serial I/O1 data
reception
5
FFF516
FFF416
At completion of serial I/O1
transmission shift or when
transmission buffer is empty
Valid when serial I/O1 is selected
At detection of either rising or
falling edge of SCL or SDA
External interrupt
(active edge selectable)
Serial I/O1
reception
Serial I/O1
transmission
SCL, SDA
Timer X
Timer Y
Timer 1
Timer 2
CNTR0
6
7
8
9
10
FFF316
FFF116
FFEF16
FFED16
FFEB16
FFF216
FFF016
FFEE16
FFEC16
FFEA16
At reset
At detection of either rising or
falling edge of INT0 input
At timer Z underflow
External interrupt
(active edge selectable)
Valid when serial I/O1 is selected
At timer X underflow
At timer Y underflow
At timer 1 underflow
STP release timer underflow
At timer 2 underflow
At detection of either rising or
falling edge of CNTR0 input
At detection of either rising or
falling edge of SCL or SDA
SCL, SDA
Non-maskable
External interrupt
(active edge selectable)
CNTR1
11
FFE916
FFE816
Serial I/O3
reception
Serial I/O2
At detection of either rising or
falling edge of CNTR1 input
At completion of serial I/O3 data
reception
12
FFE716
FFE616
At completion of serial I/O2 data
transmission or reception
Timer Z
INT2
13
FFE516
FFE416
I 2C
INT3
14
FFE316
FFE216
At completion of data transfer
At detection of either rising or
falling edge of INT3 input
INT4
15
FFE116
FFE016
At detection of either rising or
falling edge of INT4 input
External interrupt
(active edge selectable)
External interrupt
(active edge selectable)
External interrupt
(active edge selectable)
Valid when serial I/O3 is selected
Valid when serial I/O2 is selected
At timer Z underflow
At detection of either rising or
falling edge of INT2 input
At detection of either rising or
falling edge of CNTR2 input
CNTR2
A/D converter
Serial I/O3
transmission
16
BRK instruction
17
FFDF16
FFDD16
FFDE16
FFDC16
External interrupt
(active edge selectable)
External interrupt
(active edge selectable)
External interrupt
(active edge selectable)
External interrupt
(active edge selectable)
At completion of A/D conversion
At completion of serial I/O3
transmission shift or when
transmission buffer is empty
Valid when serial I/O3 is selected
At BRK instruction execution
Non-maskable software interrupt
Notes 1: Vector addresses contain interrupt jump destination addresses.
2: Reset function in the same way as an interrupt with the highest priority.
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
Interrupt request bit
Interrupt enable bit
Interrupt disable flag (I)
BRK instruction
Reset
Interrupt request
Fig. 19 Interrupt control
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REJ09B0212-0100Z
1-25
HARDWARE
3804 Group (Spec.H)
b7
b0
FUNCTIONAL DESCRIPTION
Interrupt edge selection register
(INTEDGE : address 003A16)
INT0 active edge selection bit
INT1 active edge selection bit
Not used (returns “0” when read)
INT2 active edge selection bit
INT3 active edge selection bit
INT4 active edge selection bit
INT0, INT4 interrupt switch bit
0 : INT00, INT40 interrupt
1 : INT01, INT41 interrupt
Not used (returns “0” when read)
b7
b0
0 : Falling edge active
1 : Rising edge active
0 : Falling edge active
1 : Rising edge active
Interrupt request register 1
(IREQ1 : address 003C16)
b7
INT0/Timer Z interrupt request bit
INT1 interrupt request bit
Serial I/O1 receive interrupt request bit
Serial I/O1 transmit/SCL, SDA interrupt
request bit
Timer X interrupt request bit
Timer Y interrupt request bit
Timer 1 interrupt request bit
Timer 2 interrupt request bit
b7
b0
Interrupt control register 1
(ICON1 : address 003E16)
INT0/Timer Z interrupt enable bit
INT1 interrupt enable bit
Serial I/O1 receive interrupt enable bit
Serial I/O1 transmit/SCL, SDA interrupt
enable bit
Timer X interrupt enable bit
Timer Y interrupt enable bit
Timer 1 interrupt enable bit
Timer 2 interrupt enable bit
b0
Interrupt request register 2
(IREQ2 : address 003D16)
CNTR0/SCL, SDA interrupt request bit
CNTR1/Serial I/O3 receive interrupt
request bit
Serial I/O2/Timer Z interrupt request bit
INT2/I2C interrupt request bit
INT3 interrupt request bit
INT4/CNTR2 interrupt request bit
AD converter/Serial I/O3 transmit
interrupt request bit
Not used (returns “0” when read)
0 : No interrupt request issued
1 : Interrupt request issued
b7
b0
Interrupt control register 2
(ICON2 : address 003F16)
CNTR0/SCL, SDA interrupt enable bit
CNTR1/Serial I/O3 receive interrupt
enable bit
Serial I/O2/Timer Z interrupt enable bit
INT2/I2C interrupt enable bit
INT3 interrupt enable bit
INT4/CNTR2 interrupt enable bit
AD converter/Serial I/O3 transmit
interrupt enable bit
Not used (returns “0” when read)
0 : Interrupts disabled
1 : Interrupts enabled
b7
b0
Interrupt source selection register
(INTSEL: address 003916)
INT0/Timer Z interrupt source selection bit
0 : INT0 interrupt
1 : Timer Z interrupt
(Do not write “1” to these bits simultaneously.)
Serial I/O2/Timer Z interrupt source selection bit
0 : Serial I/O2 interrupt
1 : Timer Z interrupt
Serial I/O1 transmit/SCL, SDA interrupt source selection bit
0 : Serial I/O1 transmit interrupt
1 : SCL, SDA interrupt
(Do not write “1” to these bits simultaneously.)
CNTR0/SCL, SDA interrupt source selection bit
0 : CNTR0 interrupt
1 : SCL, SDA interrupt
INT4/CNTR2 interrupt source selection bit
0 : INT4 interrupt
1 : CNTR2 interrupt
INT2/I2C interrupt source selection bit
0 : INT2 interrupt
1 : I2C interrupt
CNTR1/Serial I/O3 receive interrupt source selection bit
0 : CNTR1 interrupt
1 : Serial I/O3 receive interrupt
AD converter/Serial I/O3 transmit interrupt source selection bit
0 : A/D converter interrupt
1 : Serial I/O3 transmit interrupt
Fig. 20 Structure of interrupt-related registers
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HARDWARE
3804 Group (Spec.H)
TIMERS
●8-bit Timers
The 3804 group (Spec. H) has four 8-bit timers: timer 1, timer 2,
timer X, and timer Y.
The timer 1 and timer 2 use one prescaler in common, and the
timer X and timer Y use each prescaler. Those are 8-bit
prescalers. Each of the timers and prescalers has a timer latch or
a prescaler latch.
The division ratio of each timer or prescaler is given by 1/(n + 1),
where n is the value in the corresponding timer or prescaler latch.
All timers are down-counters. When the timer reaches “00 16”, an
underflow occurs at the next count pulse and the contents of the
corresponding timer latch are reloaded into the timer and the
count is continued. When the timer underflows, the interrupt request bit corresponding to that timer is set to “1”.
●Timer divider
The divider count source is switched by the main clock division
ratio selection bits of CPU mode register (bits 7 and 6 at address
003B 16). When these bits are “00” (high-speed mode) or “01”
(middle-speed mode), X IN is selected. When these bits are“10”
(low-speed mode), XCIN is selected.
●Prescaler 12
The prescaler 12 counts the output of the timer divider. The count
source is selected by the timer 12, X count source selection
register among 1/2, 1/4, 1/8, 1/16, 1/32, 1/64, 1/128, 1/256, 1/512,
1/1024 of f(XIN) or f(XCIN).
Timer 1 and Timer 2
The timer 1 and timer 2 counts the output of prescaler 12 and periodically set the interrupt request bit.
●Prescaler X and prescaler Y
The prescaler X and prescaler Y count the output of the timer
divider or f(XCIN). The count source is selected by the timer 12, X
count source selection register (address 000E16) and the timer Y,
Z count source selection register (address 000F16 ) among 1/2,
1/4, 1/8, 1/16, 1/32, 1/64, 1/128, 1/256, 1/512, and 1/1024 of f(XIN)
or f(XCIN); and f(XCIN).
Rev.1.00 Jan 14, 2005
REJ09B0212-0100Z
FUNCTIONAL DESCRIPTION
Timer X and Timer Y
The timer X and timer Y can each select one of four operating
modes by setting the timer XY mode register (address 002316).
(1) Timer mode
●Mode selection
This mode can be selected by setting “00” to the timer X operating
mode bits (bits 1 and 0) and the timer Y operating mode bits (bits
5 and 4) of the timer XY mode register (address 002316).
●Explanation of operation
The timer count operation is started by setting “0” to the timer X
count stop bit (bit 3) and the timer Y count stop bit (bit 7) of the
timer XY mode register (address 002316).
When the timer reaches “0016”, an underflow occurs at the next
count pulse and the contents of timer latch are reloaded into the
timer and the count is continued.
(2) Pulse output mode
●Mode selection
This mode can be selected by setting “01” to the timer X operating
mode bits (bits 1 and 0) and the timer Y operating mode bits (bits
5 and 4) of the timer XY mode register (address 002316).
●Explanation of operation
The operation is the same as the timer mode’s. Moreover the
pulse which is inverted each time the timer underflows is output
from CNTR0/CNTR1 pin. Regardless of the timer counting or not
the output of CNTR0/CNTR1 pin is initialized to the level of specified by their active edge switch bits when writing to the timer.
When the CNTR0 active edge switch bit (bit 2) and the CNTR1 active edge switch bit (bit 6) of the timer XY mode register (address
002316) is “0”, the output starts with “H” level. When it is “1”, the
output starts with “L” level.
Switching the CNTR0 or CNTR1 active edge switch bit will reverse
the output level of the corresponding CNTR0 or CNTR1 pin.
■Precautions
Set the double-function port of CNTR0/CNTR1 pin and port P5 4/
P55 to output in this mode.
1-27
HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
(3) Event counter mode
●Mode selection
This mode can be selected by setting “10” to the timer X operating
mode bits (bits 1 and 0) and the timer Y operating mode bits (bits
5 and 4) of the timer XY mode register (address 002316).
●Explanation of operation
The operation is the same as the timer mode’s except that the
timer counts signals input from the CNTR 0 or CNTR 1 pin. The
valid edge for the count operation depends on the CNTR0 active
edge switch bit (bit 2) or the CNTR1 active edge switch bit (bit 6)
of the timer XY mode register (address 002316). When it is “0”, the
rising edge is valid. When it is “1”, the falling edge is valid.
■Precautions
Set the double-function port of CNTR0/CNTR1 pin and port P54/
P55 to input in this mode.
(4) Pulse width measurement mode
●Mode selection
This mode can be selected by setting “11” to the timer X operating
mode bits (bits 1 and 0) and the timer Y operating mode bits (bits
5 and 4) of the timer XY mode register (address 002316).
●Explanation of operation
When the CNTR0 active edge switch bit (bit 2) or the CNTR1 active edge switch bit (bit 6) of the timer XY mode register (address
002316) is “1”, the timer counts during the term of one falling edge
of CNTR0/CNTR1 pin input until the next rising edge of input (“L”
term). When it is “0”, the timer counts during the term of one rising
edge input until the next falling edge input (“H” term).
■Precautions
Set the double-function port of CNTR0/CNTR1 pin and port P54/
P55 to input in this mode.
The count operation can be stopped by setting “1” to the timer X
count stop bit (bit 3) and the timer Y count stop bit (bit 7) of the
timer XY mode register (address 002316). The interrupt request bit
is set to “1” each time the timer underflows.
•Precautions when switching count source
When switching the count source by the timer 12, X and Y count
source selection bits, the value of timer count is altered in inconsiderable amount owing to generating of thin pulses on the count
input signals.
Therefore, select the timer count source before setting the value
to the prescaler and the timer.
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1-28
HARDWARE
3804 Group (Spec.H)
XIN
“00”
“01”
FUNCTIONAL DESCRIPTION
(1/2, 1/4, 1/8, 1/16, 1/32, 1/64, 1/128, 1/256, 1/512, 1/1024)
Divider
Clock for timer 12
Clock for timer Y
XCIN
Main clock
division ratio
selection bits
Count source
selection bit
Clock for timer X
“10”
Data bus
Prescaler X latch (8)
f(XCIN)
Pulse width
measurement
mode
Prescaler X (8)
CNTR0 active edge
switch bit
“0”
P54/CNTR0
Event
counter
mode
Timer X latch (8)
Timer mode
Pulse output mode
Timer X (8)
Timer X count stop bit
To CNTR0 interrupt
request bit
“1 ”
CNTR0 active
edge switch bit “1”
Port P54
direction register
To timer X interrupt
request bit
“0”
Port P54
latch
Q
Toggle flip-flop T
Q
R
Timer X latch write pulse
Pulse output mode
Pulse output mode
Data bus
Count source selection bit
Clock for timer Y
Prescaler Y latch (8)
Pulse width
measurement
mode
f(XCIN)
Prescaler Y (8)
CNTR1 active edge
switch bit
“0”
P55/CNTR1
Event
counter
mode
Timer Y latch (8)
Timer mode
Pulse output mode
Timer Y (8)
To timer Y interrupt
request bit
Timer Y count stop bit
To CNTR1 interrupt
request bit
“1”
CNTR1 active
edge switch bit “1”
Q
Toggle flip-flop T
Q
Port P55
direction register
Port P55
latch
“0”
R
Timer Y latch write pulse
Pulse output mode
Pulse output mode
Data bus
Prescaler 12 latch (8)
Clock for timer 12
Prescaler 12 (8)
Timer 1 latch (8)
Timer 2 latch (8)
Timer 1 (8)
Timer 2 (8)
To timer 2 interrupt
request bit
To timer 1 interrupt
request bit
Fig. 21 Block diagram of timer X, timer Y, timer 1, and timer 2
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REJ09B0212-0100Z
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
b7
b0
Timer XY mode register
(TM : address 002316)
Timer X operating mode bits
b1 b0
0 0 : Timer mode
0 1 : Pulse output mode
1 0 : Event counter mode
1 1 : Pulse width measurement mode
CNTR0 active edge switch bit
0 : Interrupt at falling edge
Count at rising edge in event counter mode
1 : Interrupt at rising edge
Count at falling edge in event counter mode
Timer X count stop bit
0 : Count start
1 : Count stop
Timer Y operating mode bits
b5 b4
0 0 : Timer mode
0 1 : Pulse output mode
1 0 : Event counter mode
1 1 : Pulse width measurement mode
CNTR1 active edge switch bit
0 : Interrupt at falling edge
Count at rising edge in event counter mode
1 : Interrupt at rising edge
Count at falling edge in event counter mode
Timer Y count stop bit
0 : Count start
1 : Count stop
Fig. 22 Structure of timer XY mode register
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REJ09B0212-0100Z
1-30
HARDWARE
3804 Group (Spec.H)
b7
FUNCTIONAL DESCRIPTION
b0
Timer 12, X count source selection register
(T12XCSS : address 000E16)
Timer 12 count source selection bits
b3b2b1b0
1010 :
0 0 0 0 : f(XIN)/2 or f(XCIN)/2
1011 :
0 0 0 1 : f(XIN)/4 or f(XCIN)/4
1100 :
0 0 1 0 : f(XIN)/8 or f(XCIN)/8
1101 :
0 0 1 1 : f(XIN)/16 or f(XCIN)/16
1110 :
0 1 0 0 : f(XIN)/32 or f(XCIN)/32
1111 :
0 1 0 1 : f(XIN)/64 or f(XCIN)/64
0 1 1 0 : f(XIN)/128 or f(XCIN)/128
0 1 1 1 : f(XIN)/256 or f(XCIN)/256
1 0 0 0 : f(XIN)/512 or f(XCIN)/512
1 0 0 1 : f(XIN)/1024 or f(XCIN)/1024
Timer X count source selection bits
b7b6b5b4
0 0 0 0 : f(XIN)/2 or f(XCIN)/2
0 0 0 1 : f(XIN)/4 or f(XCIN)/4
0 0 1 0 : f(XIN)/8 or f(XCIN)/8
0 0 1 1 : f(XIN)/16 or f(XCIN)/16
0 1 0 0 : f(XIN)/32 or f(XCIN)/32
0 1 0 1 : f(XIN)/64 or f(XCIN)/64
0 1 1 0 : f(XIN)/128 or f(XCIN)/128
0 1 1 1 : f(XIN)/256 or f(XCIN)/256
1 0 0 0 : f(XIN)/512 or f(XCIN)/512
1 0 0 1 : f(XIN)/1024 or f(XCIN)/1024
1 0 1 0 : f(XCIN)
b7
1011 :
1100 :
1101 :
1110 :
1111 :
Not used
Not used
b0
Timer Y, Z count source selection register
(TYZCSS : address 000F16)
Timer Y count source selection bits
b3b2b1b0
0 0 0 0 : f(XIN)/2 or f(XCIN)/2
1011 :
0 0 0 1 : f(XIN)/4 or f(XCIN)/4
1100 :
0 0 1 0 : f(XIN)/8 or f(XCIN)/8
1101 :
0 0 1 1 : f(XIN)/16 or f(XCIN)/16
1110 :
0 1 0 0 : f(XIN)/32 or f(XCIN)/32
1111 :
0 1 0 1 : f(XIN)/64 or f(XCIN)/64
0 1 1 0 : f(XIN)/128 or f(XCIN)/128
0 1 1 1 : f(XIN)/256 or f(XCIN)/256
1 0 0 0 : f(XIN)/512 or f(XCIN)/512
1 0 0 1 : f(XIN)/1024 or f(XCIN)/1024
1 0 1 0 : f(XCIN)
Timer Z count source selection bits
b7b6b5b4
0 0 0 0 : f(XIN)/2 or f(XCIN)/2
0 0 0 1 : f(XIN)/4 or f(XCIN)/4
0 0 1 0 : f(XIN)/8 or f(XCIN)/8
0 0 1 1 : f(XIN)/16 or f(XCIN)/16
0 1 0 0 : f(XIN)/32 or f(XCIN)/32
0 1 0 1 : f(XIN)/64 or f(XCIN)/64
0 1 1 0 : f(XIN)/128 or f(XCIN)/128
0 1 1 1 : f(XIN)/256 or f(XCIN)/256
1 0 0 0 : f(XIN)/512 or f(XCIN)/512
1 0 0 1 : f(XIN)/1024 or f(XCIN)/1024
1 0 1 0 : f(XCIN)
1011 :
1100 :
1101 :
1110 :
1111 :
Not used
Not used
Fig. 23 Structure of timer 12, X and timer Y, Z count source selection registers
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REJ09B0212-0100Z
1-31
HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
●16-bit Timer
(2) Event counter mode
The timer Z is a 16-bit timer. When the timer reaches “000016”, an
underflow occurs at the next count pulse and the corresponding
timer latch is reloaded into the timer and the count is continued.
When the timer underflows, the interrupt request bit corresponding
to the timer Z is set to “1”.
When reading/writing to the timer Z, perform reading/writing to
both the high-order byte and the low-order byte. When reading the
timer Z, read from the high-order byte first, followed by the low-order byte. Do not perform the writing to the timer Z between read
operation of the high-order byte and read operation of the low-order byte. When writing to the timer Z, write to the low-order byte
first, followed by the high-order byte. Do not perform the reading
to the timer Z between write operation of the low-order byte and
write operation of the high-order byte.
The timer Z can select the count source by the timer Z count
source selection bits of timer Y, Z count source selection register
(bits 7 to 4 at address 000F16).
Timer Z can select one of seven operating modes by setting the
timer Z mode register (address 002A16).
●Mode selection
This mode can be selected by setting “000” to the timer Z operating mode bits (bits 2 to 0) and setting “1” to the timer/event
counter mode switch bit (bit 7) of the timer Z mode register (address 002A16).
The valid edge for the count operation depends on the CNTR2 active edge switch bit (bit 5) of the timer Z mode register (address
002A16). When it is “0”, the rising edge is valid. When it is “1”, the
falling edge is valid.
●Interrupt
The interrupt at an underflow is the same as the timer mode’s.
●Explanation of operation
The operation is the same as the timer mode’s.
Set the double-function port of CNTR2 pin and port P47 to input in
this mode.
Figure 26 shows the timing chart of the timer/event counter mode.
(1) Timer mode
●Mode selection
This mode can be selected by setting “000” to the timer Z operating mode bits (bits 2 to 0) and setting “0” to the timer/event
counter mode switch bit (b7) of the timer Z mode register (address
002A16).
●Count source selection
In high- or middle-speed mode, 1/2, 1/4, 1/8, 1/16, 1/32, 1/64, 1/
128, 1/256, 1/512 or 1/1024 of f(XIN); or f(XCIN) can be selected as
the count source.
In low-speed mode, 1/2, 1/4, 1/8, 1/16, 1/32, 1/64, 1/128, 1/256, 1/
512 or 1/1024 of f(XCIN); or f(XCIN) can be selected as the count
source.
●Interrupt
When an underflow occurs, the INT0/timer Z interrupt request bit
(bit 0) of the interrupt request register 1 (address 003C16) is set to
“1”.
●Explanation of operation
During timer stop, usually write data to a latch and a timer at the
same time to set the timer value.
The timer count operation is started by setting “0” to the timer Z
count stop bit (bit 6) of the timer Z mode register (address
002A16).
When the timer reaches “000016”, an underflow occurs at the next
count pulse and the contents of timer latch are reloaded into the
timer and the count is continued.
When writing data to the timer during operation, the data is written
only into the latch. Then the new latch value is reloaded into the
timer at the next underflow.
Rev.1.00 Jan 14, 2005
REJ09B0212-0100Z
(3) Pulse output mode
●Mode selection
This mode can be selected by setting “001” to the timer Z operating mode bits (bits 2 to 0) and setting “0” to the timer/event
counter mode switch bit (b7) of the timer Z mode register (address
002A16).
●Count source selection
In high- or middle-speed mode, 1/2, 1/4, 1/8, 1/16, 1/32, 1/64, 1/
128, 1/256, 1/512 or 1/1024 of f(XIN); or f(XCIN) can be selected as
the count source.
In low-speed mode, 1/2, 1/4, 1/8, 1/16, 1/32, 1/64, 1/128, 1/256, 1/
512 or 1/1024 of f(XCIN); or f(XCIN) can be selected as the count
source.
●Interrupt
The interrupt at an underflow is the same as the timer mode’s.
●Explanation of operation
The operation is the same as the timer mode’s. Moreover the
pulse which is inverted each time the timer underflows is output
from CNTR2 pin. When the CNTR2 active edge switch bit (bit 5) of
the timer Z mode register (address 002A16) is “0”, the output starts
with “H” level. When it is “1”, the output starts with “L” level.
■Precautions
The double-function port of CNTR2 pin and port P47 is automatically set to the timer pulse output port in this mode.
The output from CNTR2 pin is initialized to the level depending on
CNTR2 active edge switch bit by writing to the timer.
When the value of the CNTR2 active edge switch bit is changed,
the output level of CNTR2 pin is inverted.
Figure 27 shows the timing chart of the pulse output mode.
1-32
HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
(4) Pulse period measurement mode
(5) Pulse width measurement mode
●Mode selection
This mode can be selected by setting “010” to the timer Z operating mode bits (bits 2 to 0) and setting “0” to the timer/event
counter mode switch bit (b7) of the timer Z mode register (address
002A16).
●Count source selection
In high- or middle-speed mode, 1/2, 1/4, 1/8, 1/16, 1/32, 1/64,
1/128, 1/256, 1/512 or 1/1024 of f(XIN); or f(XCIN) can be selected
as the count source.
In low-speed mode, 1/2, 1/4, 1/8, 1/16, 1/32, 1/64, 1/128, 1/256,
1/512 or 1/1024 of f(XCIN); or f(XCIN) can be selected as the count
source.
●Interrupt
The interrupt at an underflow is the same as the timer mode’s.
When the pulse period measurement is completed, the INT 4 /
CNTR2 interrupt request bit (bit 5) of the interrupt request register
2 (address 003D16) is set to “1”.
●Explanation of operation
The cycle of the pulse which is input from the CNTR2 pin is measured. When the CNTR2 active edge switch bit (bit 5) of the timer
Z mode register (address 002A16) is “0”, the timer counts during
the term from one falling edge of CNTR2 pin input to the next falling edge. When it is “1”, the timer counts during the term from one
rising edge input to the next rising edge input.
When the valid edge of measurement completion/start is detected,
the 1’s complement of the timer value is written to the timer latch
and “FFFF16” is set to the timer.
Furthermore when the timer underflows, the timer Z interrupt request occurs and “FFFF 16” is set to the timer. When reading the
timer Z, the value of the timer latch (measured value) is read. The
measured value is retained until the next measurement completion.
■Precautions
Set the double-function port of CNTR2 pin and port P47 to input in
this mode.
A read-out of timer value is impossible in this mode. The timer can
be written to only during timer stop (no measurement of pulse period).
Since the timer latch in this mode is specialized for the read-out of
measured values, do not perform any write operation during measurement.
“FFFF16” is set to the timer when the timer underflows or when the
valid edge of measurement start/completion is detected. Consequently, the timer value at start of pulse period measurement
depends on the timer value just before measurement start.
Figure 28 shows the timing chart of the pulse period measurement
mode.
●Mode selection
This mode can be selected by setting “011” to the timer Z operating mode bits (bits 2 to 0) and setting “0” to the timer/event
counter mode switch bit (b7) of the timer Z mode register (address
002A16).
●Count source selection
In high- or middle-speed mode, 1/2, 1/4, 1/8, 1/16, 1/32, 1/64,
1/128, 1/256, 1/512 or 1/1024 of f(XIN); or f(XCIN) can be selected
as the count source.
In low-speed mode, 1/2, 1/4, 1/8, 1/16, 1/32, 1/64, 1/128, 1/256,
1/512 or 1/1024 of f(XCIN); or f(XCIN) can be selected as the count
source.
●Interrupt
The interrupt at an underflow is the same as the timer mode’s.
When the pulse widths measurement is completed, the INT 4 /
CNTR2 interrupt request bit (bit 5) of the interrupt request register
2 (address 003D16) is set to “1”.
●Explanation of operation
The pulse width which is input from the CNTR2 pin is measured.
When the CNTR2 active edge switch bit (bit 5) of the timer Z mode
register (address 002A16) is “0”, the timer counts during the term
from one rising edge input to the next falling edge input (“H” term).
When it is “1”, the timer counts during the term from one falling
edge of CNTR2 pin input to the next rising edge of input (“L” term).
When the valid edge of measurement completion is detected, the
1’s complement of the timer value is written to the timer latch.
When the valid edge of measurement completion/start is detected,
“FFFF16” is set to the timer.
When the timer Z underflows, the timer Z interrupt occurs and
“FFFF16” is set to the timer Z. When reading the timer Z, the value
of the timer latch (measured value) is read. The measured value is
retained until the next measurement completion.
■Precautions
Set the double-function port of CNTR2 pin and port P47 to input in
this mode.
A read-out of timer value is impossible in this mode. The timer can
be written to only during timer stop (no measurement of pulse
widths).
Since the timer latch in this mode is specialized for the read-out of
measured values, do not perform any write operation during measurement.
“FFFF16” is set to the timer when the timer underflows or when the
valid edge of measurement start/completion is detected. Consequently, the timer value at start of pulse width measurement
depends on the timer value just before measurement start.
Figure 29 shows the timing chart of the pulse width measurement
mode.
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HARDWARE
3804 Group (Spec.H)
(6) Programmable waveform generating mode
●Mode selection
This mode can be selected by setting “100” to the timer Z operating mode bits (bits 2 to 0) and setting “0” to the timer/event
counter mode switch bit (b7) of the timer Z mode register (address
002A16).
●Count source selection
In high- or middle-speed mode, 1/2, 1/4, 1/8, 1/16, 1/32, 1/64,
1/128, 1/256, 1/512 or 1/1024 of f(XIN); or f(XCIN) can be selected
as the count source.
In low-speed mode, 1/2, 1/4, 1/8, 1/16, 1/32, 1/64, 1/128, 1/256, 1/
512 or 1/1024 of f(XCIN); or f(XCIN) can be selected as the count
source.
●Interrupt
The interrupt at an underflow is the same as the timer mode’s.
●Explanation of operation
The operation is the same as the timer mode’s. Moreover the
timer outputs the data set in the output level latch (bit 4) of the
timer Z mode register (address 002A16) from the CNTR2 pin each
time the timer underflows.
Changing the value of the output level latch and the timer latch after an underflow makes it possible to output an optional waveform
from the CNTR2 pin.
■Precautions
The double-function port of CNTR2 pin and port P47 is automatically set to the programmable waveform generating port in this
mode.
Figure 30 shows the timing chart of the programmable waveform
generating mode.
(7) Programmable one-shot generating mode
●Mode selection
This mode can be selected by setting “101” to the timer Z operating mode bits (bits 2 to 0) and setting “0” to the timer/event
counter mode switch bit (b7) of the timer Z mode register (address
002A16).
●Count source selection
In high- or middle-speed mode, 1/2, 1/4, 1/8, 1/16, 1/32, 1/64, 1/
128, 1/256, 1/512 or 1/1024 of f(XIN); or f(XCIN) can be selected as
the count source.
●Interrupt
The interrupt at an underflow is the same as the timer mode’s.
The trigger to generate one-shot pulse can be selected by the
INT1 active edge selection bit (bit 1) of the interrupt edge selection
register (address 003A16). When it is “0”, the falling edge active is
selected; when it is “1”, the rising edge active is selected.
When the valid edge of the INT1 pin is detected, the INT1 interrupt
request bit (bit 1) of the interrupt request register 1 (address
003C16) is set to “1”.
●Explanation of operation
•“H” one-shot pulse; Bit 5 of timer Z mode register = “0”
The output level of the CNTR2 pin is initialized to “L” at mode selection. When trigger generation (input signal to INT 1 pin) is
detected, “H” is output from the CNTR2 pin. When an underflow
occurs, “L” is output. The “H” one-shot pulse width is set by the
setting value to the timer Z register low-order and high-order.
When trigger generating is detected during timer count stop, although “H” is output from the CNTR 2 pin, “H” output state
continues because an underflow does not occur.
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FUNCTIONAL DESCRIPTION
•“L” one-shot pulse; Bit 5 of timer Z mode register = “1”
The output level of the CNTR2 pin is initialized to “H” at mode selection. When trigger generation (input signal to INT 1 pin) is
detected, “L” is output from the CNTR2 pin. When an underflow
occurs, “H” is output. The “L” one-shot pulse width is set by the
setting value to the timer Z low-order and high-order. When trigger
generating is detected during timer count stop, although “L” is output from the CNTR2 pin, “L” output state continues because an
underflow does not occur.
■Precautions
Set the double-function port of INT1 pin and port P42 to input in
this mode.
Set the double-function port of CNTR2 pin and port P2 2 is automatically set to the programmable one-shot generating port in this
mode.
This mode cannot be used in low-speed mode.
If the value of the CNTR2 active edge switch bit is changed during
one-shot generating enabled or generating one-shot pulse, then
the output level from CNTR2 pin changes.
Figure 31 shows the timing chart of the programmable one-shot
generating mode.
■Notes regarding all modes
●Timer Z write control
Which write control can be selected by the timer Z write control bit
(bit 3) of the timer Z mode register (address 002A16), writing data
to both the latch and the timer at the same time or writing data
only to the latch.
When the operation “writing data only to the latch” is selected, the
value is set to the timer latch by writing data to the address of
timer Z and the timer is updated at next underflow. After reset release, the operation “writing data to both the latch and the timer at
the same time” is selected, and the value is set to both the latch
and the timer at the same time by writing data to the address of
timer Z.
In the case of writing data only to the latch, if writing data to the
latch and an underflow are performed almost at the same time,
the timer value may become undefined.
●Timer Z read control
A read-out of timer value is impossible in pulse period measurement mode and pulse width measurement mode. In the other
modes, a read-out of timer value is possible regardless of count
operating or stopped.
However, a read-out of timer latch value is impossible.
●Switch of interrupt active edge of CNTR2 and INT1
Each interrupt active edge depends on setting of the CNTR2 active edge switch bit and the INT1 active edge selection bit.
●Switch of count source
When switching the count source by the timer Z count source selection bits, the value of timer count is altered in inconsiderable
amount owing to generating of thin pulses on the count input signals.
Therefore, select the timer count source before setting the value
to the prescaler and the timer.
●Usage of CNTR2 pin as normal I/O port
To use the CNTR2 pin as normal I/O port P47, set timer Z operating mode bits (b2, b1, b0) of timer Z mode register (address
002A16) to “000”.
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
P42/INT1
CNTR2 active edge
Data bus
Programmable one-shot
switch bit
“1”
generating mode
Programmable one-shot
generating circuit
Programmable one-shot
generating mode
“0”
To INT1 interrupt
request bit
Programmable waveform
generating mode
Output level latch
D
Q
T
Pulse output mode
CNTR2 active edge switch bit
S
Q
T
Q
“0”
“1”
Pulse output mode
“001”
“100”
“101”
Timer Z operating
mode bits
Timer Z low-order latch
Timer Z high-order latch
Timer Z low-order
Timer Z high-order
Port P47
latch
To timer Z interrupt
request bit
Port P47
direction register
Pulse period measurement mode
Pulse width measurement mode
Edge detection circuit
“1”
“0”
CNTR2 active edge
switch bit
XIN
XCIN
Clock for timer Z
P47/CNTR2
To CNTR2 interrupt
request bit
“1”
f(XCIN)
“0”
Timer/Event
counter mode
switch bit
Timer Z count stop bit
Count source
Divider
selection bit
(1/2, 1/4, 1/8, 1/16, 1/32, 1/64, 1/128, 1/256, 1/512, 1/1024)
Fig. 24 Block diagram of timer Z
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HARDWARE
3804 Group (Spec.H)
b7
FUNCTIONAL DESCRIPTION
b0
Timer Z mode register
(TZM : address 002A16)
Timer Z operating mode bits
b2b1b0
0 0 0 : Timer/Event counter mode
0 0 1 : Pulse output mode
0 1 0 : Pulse period measurement mode
0 1 1 : Pulse width measurement mode
1 0 0 : Programmable waveform generating mode
1 0 1 : Programmable one-shot generating mode
1 1 0 : Not available
1 1 1 : Not available
Timer Z write control bit
0 : Writing data to both latch and timer simultaneously
1 : Writing data only to latch
Output level latch
0 : “L” output
1 : “H” output
CNTR2 active edge switch bit
0 : •Event counter mode: Count at rising edge
•Pulse output mode: Start outputting “H”
•Pulse period measurement mode: Measurement
between two falling edges
•Pulse width measurement mode: Measurement of
“H” term
•Programmable one-shot generating mode: After
start outputting “L”, “H” one-shot pulse generated
•Interrupt at falling edge
1 : •Event counter mode: Count at falling edge
•Pulse output mode: Start outputting “L”
•Pulse period measurement mode: Measurement
between two rising edges
•Pulse width measurement mode: Measurement of
“L” term
•Programmable one-shot generating mode: After
start outputting “H”, “L” one-shot pulse generated
•Interrupt at rising edge
Timer Z count stop bit
0 : Count start
1 : Count stop
Timer/Event counter mode switch bit (Note)
0 : Timer mode
1 : Event counter mode
Note: When selecting the modes except the timer/event
counter mode, set “0” to this bit.
Fig. 25 Structure of timer Z mode register
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
FFFF16
TL
000016
TR
TR
TR
TL : Value set to timer latch
TR : Timer interrupt request
Fig. 26 Timing chart of timer/event counter mode
FFFF16
TL
000016
TR
TR
TR
TR
Waveform output
from CNTR2 pin
CNTR2
CNTR2
TL : Value set to timer latch
TR : Timer interrupt request
CNTR2 : CNTR2 interrupt request
(CNTR2 active edge switch bit = “0”; Falling edge active)
Fig. 27 Timing chart of pulse output mode
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3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
000016
T3
T2
T1
FFFF16
TR
FFFF16 + T1
TR
T2
T3
FFFF16
Signal input from
CNTR2 pin
CNTR2 CNTR2
CNTR2
CNTR2
CNTR2 of rising edge active
TR : Timer interrupt request
CNTR2 : CNTR2 interrupt request
Fig. 28 Timing chart of pulse period measurement mode (Measuring term between two rising edges)
000016
T3
T2
T1
FFFF16
TR
Signal input from
CNTR2 pin
FFFF16 + T2
T3
T1
CNTR2
CNTR2
CNTR2
CNTR2 interrupt of rising edge active; Measurement of “L” width
TR : Timer interrupt request
CNTR2 : CNTR2 interrupt request
Fig. 29 Timing chart of pulse width measurement mode (Measuring “L” term)
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
FFFF16
T3
L
T2
T1
000016
Signal output
from CNTR2 pin
L
T3
T1
T2
TR
TR
TR
TR
CNTR2
CNTR2
L : Timer initial value
TR : Timer interrupt request
CNTR2 : CNTR2 interrupt request
(CNTR2 active edge switch bit = “0”; Falling edge active)
Fig. 30 Timing chart of programmable waveform generating mode
FFFF16
L
TR
Signal input from
INT1 pin
Signal output
from CNTR2 pin
L
TR
L
CNTR2
TR
L
CNTR2
L : One-shot pulse width
TR : Timer interrupt request
CNTR2 : CNTR2 interrupt request
(CNTR2 active edge switch bit = “0”; Falling edge active)
Fig. 31 Timing chart of programmable one-shot generating mode (“H” one-shot pulse generating)
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
SERIAL INTERFACE
Serial I/O1
(1) Clock Synchronous Serial I/O Mode
Clock synchronous serial I/O1 mode can be selected by setting
the serial I/O1 mode selection bit of the serial I/O1 control register
(bit 6 of address 001A16) to “1”.
For clock synchronous serial I/O, the transmitter and the receiver
must use the same clock. If an internal clock is used, transfer is
started by a write signal to the transmit/receive buffer register.
Serial I/O1 can be used as either clock synchronous or asynchronous (UART) serial I/O1. A dedicated timer is also provided for
baud rate generation.
Data bus
Serial I/O1 control register
Address 001816
Receive buffer register 1
P44/RXD1
Address 001A16
Receive buffer full flag (RBF)
Receive interrupt request (RI)
Receive shift register 1
Shift clock
Clock control circuit
P46/SCLK1
Serial I/O1 synchronous
clock selection bit
Frequency division ratio 1/(n+1)
BRG count source selection bit
f(XIN)
(f(XCIN) in low-speed mode)
1/4
P47/SRDY1
F/F
Baud rate generator 1
Address 001C16
1/4
Clock control circuit
Falling-edge detector
Shift clock
P45/TXD1
Transmit shift completion flag (TSC)
Transmit interrupt source selection bit
Transmit interrupt request (TI)
Transmit shift register 1
Transmit buffer register 1
Address 001816
Transmit buffer empty flag (TBE)
Serial I/O1 status register
Address 001916
Data bus
Fig. 32 Block diagram of clock synchronous serial I/O1
Transfer shift clock
(1/2 to 1/2048 of the internal
clock, or an external clock)
Serial output TxD1
D0
D1
D2
D3
D4
D5
D6
D7
Serial input RxD1
D0
D1
D2
D3
D4
D5
D6
D7
Receive enable signal SRDY1
Write pulse to receive/transmit
buffer register (address 001816)
TBE = 0
TBE = 1
TSC = 0
RBF = 1
TSC = 1
Overrun error (OE)
detection
Notes 1: As the transmit interrupt (TI), which can be selected, either when the transmit buffer has emptied (TBE=1) or after the
transmit shift operation has ended (TSC=1), by setting the transmit interrupt source selection bit (TIC) of the serial I/O1
control register.
2: If data is written to the transmit buffer register when TSC=0, the transmit clock is generated continuously and serial data
is output continuously from the TxD pin.
3: The receive interrupt (RI) is set when the receive buffer full flag (RBF) becomes “1” .
Fig. 33 Operation of clock synchronous serial I/O1
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
(2) Asynchronous Serial I/O (UART) Mode
two buffers have the same address in a memory. Since the shift
register cannot be written to or read from directly, transmit data is
written to the transmit buffer register, and receive data is read
from the receive buffer register.
The transmit buffer register can also hold the next data to be
transmitted, and the receive buffer register can hold a character
while the next character is being received.
Clock asynchronous serial I/O mode (UART) can be selected by
clearing the serial I/O1 mode selection bit of the serial I/O1 control
register to “0”.
Eight serial data transfer formats can be selected, and the transfer
formats used by a transmitter and receiver must be identical.
The transmit and receive shift registers each have a buffer, but the
Data bus
Address 001816
P44/RXD1
Serial I/O1 control register Address 001A16
Receive buffer full flag (RBF)
Receive interrupt request (RI)
OE
Receive buffer register 1
Character length selection bit
ST detector
7 bits
Receive shift register 1
1/16
8 bits
PE FE
UART1 control register
Address 001B16
SP detector
Clock control circuit
Serial I/O1 synchronous clock selection bit
P46/SCLK1
BRG count source selection bit Frequency division ratio 1/(n+1)
f(XIN)
Baud rate generator
(f(XCIN) in low-speed mode)
Address 001C16
1/4
ST/SP/PA generator
Transmit shift completion flag (TSC)
1/16
P45/TXD1
Transmit interrupt source selection bit
Transmit interrupt request (TI)
Transmit shift register 1
Character length selection bit
Transmit buffer register 1
Address 001816
Transmit buffer empty flag (TBE)
Serial I/O1 status register Address 001916
Data bus
Fig. 34 Block diagram of UART serial I/O1
Transmit or receive clock
Transmit buffer write
signal
TBE=0
TSC=0
TBE=1
Serial output TXD1
TBE=0
TSC=1✽
TBE=1
ST
D0
D1
SP
ST
D0
Receive buffer read
signal
SP
D1
✽
1 start bit
7 or 8 data bit
1 or 0 parity bit
1 or 2 stop bit (s)
Generated at 2nd bit in 2-stop-bit mode
RBF=0
RBF=1
Serial input RXD1
ST
D0
D1
SP
RBF=1
ST
D0
D1
SP
Notes 1: Error flag detection occurs at the same time that the RBF flag becomes “1” (at 1st stop bit, during reception).
2: As the transmit interrupt (TI), when either the TBE or TSC flag becomes “1,” can be selected to occur depending on the setting of the transmit
interrupt source selection bit (TIC) of the serial I/O1 control register.
3: The receive interrupt (RI) is set when the RBF flag becomes “1.”
4: After data is written to the transmit buffer when TSC=1, 0.5 to 1.5 cycles of the data shift cycle are necessary until changing to TSC=0.
Fig. 35 Operation of UART serial I/O1
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
[Serial I/O1 Control Register (SIO1CON)]
001A16
The serial I/O1 control register consists of eight control bits for the
serial I/O1 function.
[UART1 Control Register (UART1CON)]
001B16
The UART control register consists of four control bits (bits 0 to 3)
which are valid when asynchronous serial I/O is selected and set
the data format of an data transfer, and one bit (bit 4) which is always valid and sets the output structure of the P45/TXD1 pin.
[Serial I/O1 Status Register (SIO1STS)]
001916
The read-only serial I/O1 status register consists of seven flags
(bits 0 to 6) which indicate the operating status of the serial I/O1
function and various errors.
Three of the flags (bits 4 to 6) are valid only in UART mode.
The receive buffer full flag (bit 1) is cleared to “0” when the receive
buffer register is read.
If there is an error, it is detected at the same time that data is
transferred from the receive shift register to the receive buffer register, and the receive buffer full flag is set. A write to the serial I/O1
status register clears all the error flags OE, PE, FE, and SE (bit 3
to bit 6, respectively). Writing “0” to the serial I/O1 enable bit SIOE
(bit 7 of the serial I/O1 control register) also clears all the status
flags, including the error flags.
Bits 0 to 6 of the serial I/O1 status register are initialized to “0” at
reset, but if the transmit enable bit (bit 4) of the serial I/O1 control
register has been set to “1”, the transmit shift completion flag (bit
2) and the transmit buffer empty flag (bit 0) become “1”.
[Transmit Buffer Register 1/Receive Buffer
Register 1 (TB1/RB1)] 001816
The transmit buffer register 1 and the receive buffer register 1 are
located at the same address. The transmit buffer is write-only and
the receive buffer is read-only. If a character bit length is 7 bits, the
MSB of data stored in the receive buffer is “0”.
[Baud Rate Generator 1 (BRG1)] 001C16
The baud rate generator determines the baud rate for serial transfer.
The baud rate generator divides the frequency of the count source
by 1/(n + 1), where n is the value written to the baud rate generator.
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HARDWARE
3804 Group (Spec.H)
b7
b0
Serial I/O1 status register
(SIO1STS : address 001916)
FUNCTIONAL DESCRIPTION
b7
Transmit buffer empty flag (TBE)
0: Buffer full
1: Buffer empty
Receive buffer full flag (RBF)
0: Buffer empty
1: Buffer full
Transmit shift completion flag (TSC)
0: Transmit shift in progress
1: Transmit shift completed
Overrun error flag (OE)
0: No error
1: Overrun error
Parity error flag (PE)
0: No error
1: Parity error
Framing error flag (FE)
0: No error
1: Framing error
Summing error flag (SE)
0: (OE) U (PE) U (FE)=0
1: (OE) U (PE) U (FE)=1
Not used (returns “1” when read)
b0
Serial I/O1 control register
(SIO1CON : address 001A16)
BRG count source selection bit (CSS)
0: f(XIN) (f(XCIN) in low-speed mode)
1: f(XIN)/4 (f(XCIN)/4 in low-speed mode)
Serial I/O1 synchronous clock selection bit (SCS)
0: BRG output divided by 4 when clock synchronous
serial I/O is selected, BRG output divided by 16
when UART is selected.
1: External clock input when clock synchronous serial
I/O is selected, external clock input divided by 16
when UART is selected.
SRDY1 output enable bit (SRDY)
0: P47 pin operates as normal I/O pin
1: P47 pin operates as SRDY1 output pin
Transmit interrupt source selection bit (TIC)
0: Interrupt when transmit buffer has emptied
1: Interrupt when transmit shift operation is completed
Transmit enable bit (TE)
0: Transmit disabled
1: Transmit enabled
Receive enable bit (RE)
0: Receive disabled
1: Receive enabled
Serial I/O1 mode selection bit (SIOM)
0: Clock asynchronous (UART) serial I/O
1: Clock synchronous serial I/O
Serial I/O1 enable bit (SIOE)
0: Serial I/O1 disabled
(pins P44 to P47 operate as normal I/O pins)
1: Serial I/O1 enabled
(pins P44 to P47 operate as serial I/O pins)
b7
b0
UART1 control register
(UART1CON : address 001B16)
Character length selection bit (CHAS)
0: 8 bits
1: 7 bits
Parity enable bit (PARE)
0: Parity checking disabled
1: Parity checking enabled
Parity selection bit (PARS)
0: Even parity
1: Odd parity
Stop bit length selection bit (STPS)
0: 1 stop bit
1: 2 stop bits
P45/TXD1 P-channel output disable bit (POFF)
0: CMOS output (in output mode)
1: N-channel open drain output (in output mode)
Not used (return “1” when read)
Fig. 36 Structure of serial I/O1 control registers
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■ Notes concerning serial I/O1
FUNCTIONAL DESCRIPTION
1. Notes when selecting clock synchronous serial I/O
1.1 Stop of transmission operation
● Note
Clear the serial I/O1 enable bit and the transmit enable bit to “0”
(serial I/O and transmit disabled).
2. Notes when selecting clock asynchronous serial I/O
2.1 Stop of transmission operation
● Note
Clear the transmit enable bit to “0” (transmit disabled). The transmission operation does not stop by clearing the serial I/O1 enable
bit to “0”.
● Reason
Since transmission is not stopped and the transmission circuit is
not initialized even if only the serial I/O1 enable bit is cleared to “0”
(serial I/O disabled), the internal transmission is running (in this
case, since pins TxD1, RxD1, S CLK1, and SRDY1 function as I/O
ports, the transmission data is not output). When data is written to
the transmit buffer register in this state, data starts to be shifted to
the transmit shift register. When the serial I/O1 enable bit is set to
“1” at this time, the data during internally shifting is output to the
TxD1 pin and an operation failure occurs.
● Reason
Since transmission is not stopped and the transmission circuit is
not initialized even if only the serial I/O1 enable bit is cleared to “0”
(serial I/O disabled), the internal transmission is running (in this
case, since pins TxD1, RxD1, SCLK1, and SRDY1 function as I/O
ports, the transmission data is not output). When data is written to
the transmit buffer register in this state, data starts to be shifted to
the transmit shift register. When the serial I/O1 enable bit is set to
“1” at this time, the data during internally shifting is output to the
TxD1 pin and an operation failure occurs.
1.2 Stop of receive operation
● Note
Clear the receive enable bit to “0” (receive disabled), or clear the
serial I/O1 enable bit to “0” (serial I/O disabled).
2.2 Stop of receive operation
● Note
Clear the receive enable bit to “0” (receive disabled).
1.3 Stop of transmit/receive operation
● Note
Clear both the transmit enable bit and receive enable bit to “0”
(transmit and receive disabled).
(when data is transmitted and received in the clock synchronous
serial I/O mode, any one of data transmission and reception cannot be stopped.)
● Reason
In the clock synchronous serial I/O mode, the same clock is used
for transmission and reception. If any one of transmission and reception is disabled, a bit error occurs because transmission and
reception cannot be synchronized.
In this mode, the clock circuit of the transmission circuit also operates for data reception. Accordingly, the transmission circuit does
not stop by clearing only the transmit enable bit to “0” (transmit
disabled). Also, the transmission circuit is not initialized by clearing the serial I/O1 enable bit to “0” (serial I/O disabled) (refer to
1.1).
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2.3 Stop of transmit/receive operation
● Note 1 (only transmission operation is stopped)
Clear the transmit enable bit to “0” (transmit disabled). The transmission operation does not stop by clearing the serial I/O1 enable
bit to “0”.
● Reason
Since transmission is not stopped and the transmission circuit is
not initialized even if only the serial I/O1 enable bit is cleared to “0”
(serial I/O disabled), the internal transmission is running (in this
case, since pins TxD1, RxD1, S CLK1, and SRDY1 function as I/O
ports, the transmission data is not output). When data is written to
the transmit buffer register in this state, data starts to be shifted to
the transmit shift register. When the serial I/O1 enable bit is set to
“1” at this time, the data during internally shifting is output to the
TxD1 pin and an operation failure occurs.
● Note 2 (only receive operation is stopped)
Clear the receive enable bit to “0” (receive disabled).
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
3. SRDY1 output of reception side
● Note
When signals are output from the SRDY1 pin on the reception side
by using an external clock in the clock synchronous serial I/O
mode, set all of the receive enable bit, the S RDY1 output enable
bit, and the transmit enable bit to “1” (transmit enabled).
4. Setting serial I/O1 control register again
● Note
Set the serial I/O1 control register again after the transmission and
the reception circuits are reset by clearing both the transmit enable bit and the receive enable bit to “0.”
Clear both the transmit enable bit
7. Transmit interrupt request when transmit enable bit is set
● Note
When using the transmit interrupt, take the following sequence.
➀ Set the serial I/O1 transmit interrupt enable bit to “0” (disabled).
➁ Set the transmit enable bit to “1”.
➂ Set the serial I/O1 transmit interrupt request bit to “0” after 1 or
more instruction has executed.
➃ Set the serial I/O1 transmit interrupt enable bit to “1” (enabled).
● Reason
When the transmit enable bit is set to “1”, the transmit buffer
empty flag and the transmit shift register shift completion flag are
also set to “1”. Therefore, regardless of selecting which timing for
the generating of transmit interrupts, the interrupt request is generated and the transmit interrupt request bit is set at this point.
(TE) and the receive enable bit
(RE) to “0”
↓
Set the bits 0 to 3 and bit 6 of the
serial I/O control register
↓
Set both the transmit enable bit
Can be set with the
LDM instruction at the
same time
(TE) and the receive enable bit
(RE), or one of them to “1”
5. Data transmission control with referring to transmit shift
register completion flag
● Note
After the transmit data is written to the transmit buffer register, the
transmit shift register completion flag changes from “1” to “0” with
a delay of 0.5 to 1.5 shift clocks. When data transmission is controlled with referring to the flag after writing the data to the transmit
buffer register, note the delay.
6. Transmission control when external clock is selected
● Note
When an external clock is used as the synchronous clock for data
transmission, set the transmit enable bit to “1” at “H” of the SCLK1
input level. Also, write data to the transmit buffer register at “H” of
the SCLK1 input level.
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
Serial I/O2
b7
b0
The serial I/O2 function can be used only for clock synchronous
serial I/O2.
For clock synchronous serial I/O2, the transmitter and the receiver
must use the same clock. If the internal clock is used, transfer is
started by a write signal to the serial I/O2 register.
Serial I/O2 control register
(SIO2CON : address 001D16)
Internal synchronous clock selection bits
b2 b1 b0
0 0 0: f(XIN)/8 (f(XCIN)/8 in low-speed mode)
0 0 1: f(XIN)/16 (f(XCIN)/16 in low-speed mode)
0 1 0: f(XIN)/32 (f(XCIN)/32 in low-speed mode)
0 1 1: f(XIN)/64 (f(XCIN)/64 in low-speed mode)
1 1 0: f(XIN)/128 (f(XCIN)/128 in low-speed mode)
1 1 1: f(XIN)/256 (f(XCIN)/256 in low-speed mode)
[Serial I/O2 Control Register (SIO2CON)]
001D16
Serial I/O2 port selection bit
0: I/O port
1: SOUT2,SCLK2 signal output
The serial I/O2 control register contains eight bits which control
various serial I/O2 functions.
SRDY2 output enable bit
0: I/O port
1: SRDY2 signal output
Transfer direction selection bit
0: LSB first
1: MSB first
Serial I/O2 synchronous clock selection bit
0: External clock
1: Internal clock
P51/SOUT2 P-channel output disable bit
0: CMOS output (in output mode)
1: N-channel open drain output (in output mode)
Fig. 37 Structure of serial I/O2 control register
1/8
Internal synchronous
clock selection bits
Divider
1/16
f(XIN)
(f(XCIN) in low-speed mode)
Data bus
1/32
1/64
1/128
1/256
P53 latch
P53/SRDY2
Serial I/O2 synchronous
clock selection bit “1”
SRDY2
“1”
SRDY2 output enable bit
Synchronization
circuit
SCLK2
“0”
“0”
External clock
P52 latch
“0”
P52/SCLK2
“1”
Serial I/O2 port selection bit
Serial I/O counter 2 (3)
Serial I/O2
interrupt request
P51 latch
“0”
P51/SOUT2
“1”
Serial I/O2 port selection bit
P50/SIN2
Serial I/O2 register (8)
Address 001F16
Fig. 38 Block diagram of serial I/O2
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
Transfer clock (Note 1)
Serial I/O2 register
write signal
(Note 2)
Serial I/O2 output SOUT2
D0
D1
D2
D3
D4
D5
D6
D7
Serial I/O2 input SIN2
Receive enable signal SRDY2
Serial I/O2 interrupt request bit set
Notes 1: When the internal clock is selected as the transfer clock, the divide ratio of f(XIN), or f(XCIN) in low-speed mode, can be
selected by setting bits 0 to 2 of the serial I/O2 control register.
2: When the internal clock is selected as the transfer clock, the SOUT2 pin goes to high impedance after transfer completion.
Fig. 39 Timing of serial I/O2
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
Serial I/O3
(1) Clock Synchronous Serial I/O Mode
Serial I/O3 can be used as either clock synchronous or asynchronous (UART) serial I/O3. A dedicated timer is also provided for
baud rate generation.
Clock synchronous serial I/O3 mode can be selected by setting
the serial I/O3 mode selection bit of the serial I/O3 control register
(bit 6 of address 003216) to “1”.
For clock synchronous serial I/O, the transmitter and the receiver
must use the same clock. If an internal clock is used, transfer is
started by a write signal to the transmit/receive buffer register.
Data bus
Serial I/O3 control register
Address 003016
Receive buffer register 3
P34/RXD3
Address 003216
Receive buffer full flag (RBF)
Receive interrupt request (RI)
Receive shift register 3
Shift clock
Clock control circuit
P36/SCLK3
Serial I/O3 synchronous
clock selection bit
Frequency division ratio 1/(n+1)
BRG count source selection bit
f(XIN)
(f(XCIN) in low-speed mode)
1/4
P37/SRDY3
Baud rate generator 3
Address 002F16
Clock control circuit
Falling-edge detector
F/F
1/4
Shift clock
P35/TXD3
Transmit shift completion flag (TSC)
Transmit interrupt source selection bit
Transmit interrupt request (TI)
Transmit shift register 3
Transmit buffer register 3
Address 003016
Transmit buffer empty flag (TBE)
Serial I/O3 status register
Address 003116
Data bus
Fig. 40 Block diagram of clock synchronous serial I/O3
Transfer shift clock
(1/2 to 1/2048 of the internal
clock, or an external clock)
Serial output TxD3
D0
D1
D2
D3
D4
D5
D6
D7
Serial input RxD3
D0
D1
D2
D3
D4
D5
D6
D7
Receive enable signal SRDY3
Write pulse to receive/transmit
buffer register (address 003016)
TBE = 0
TBE = 1
TSC = 0
RBF = 1
TSC = 1
Overrun error (OE)
detection
Notes 1: As the transmit interrupt (TI), which can be selected, either when the transmit buffer has emptied (TBE=1) or after the
transmit shift operation has ended (TSC=1), by setting the transmit interrupt source selection bit (TIC) of the serial I/O3
control register.
2: If data is written to the transmit buffer register when TSC=0, the transmit clock is generated continuously and serial data
is output continuously from the TxD pin.
3: The receive interrupt (RI) is set when the receive buffer full flag (RBF) becomes “1” .
Fig. 41 Operation of clock synchronous serial I/O3
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
(2) Asynchronous Serial I/O (UART) Mode
two buffers have the same address in a memory. Since the shift
register cannot be written to or read from directly, transmit data is
written to the transmit buffer register, and receive data is read
from the receive buffer register.
The transmit buffer register can also hold the next data to be
transmitted, and the receive buffer register can hold a character
while the next character is being received.
Clock asynchronous serial I/O mode (UART) can be selected by
clearing the serial I/O3 mode selection bit of the serial I/O3 control
register to “0”.
Eight serial data transfer formats can be selected, and the transfer
formats used by a transmitter and receiver must be identical.
The transmit and receive shift registers each have a buffer, but the
Data bus
Serial I/O3 control register Address 003216
Address 003016
P34/RXD3
Receive buffer full flag (RBF)
Receive interrupt request (RI)
Receive buffer register 3
OE
Character length selection bit
ST detector
7 bits
Receive shift register 3
1/16
8 bits
PE FE
UART3 control register
SP detector
Address 003316
Clock control circuit
Serial I/O3 synchronous clock selection bit
P36/SCLK3
BRG count source selection bit Frequency division ratio 1/(n+1)
f(XIN)
Baud rate generator 3
(f(XCIN) in low-speed mode)
Address 002F16
1/4
ST/SP/PA generator
Transmit shift completion flag (TSC)
1/16
P35/TXD3
Transmit interrupt source selection bit
Transmit interrupt request (TI)
Transmit shift register 3
Character length selection bit
Transmit buffer empty flag (TBE)
Serial I/O3 status register Address 003116
Transmit buffer register 3
Address 003016
Data bus
Fig. 42 Block diagram of UART serial I/O3
Transmit or receive clock
Transmit buffer write
signal
TBE=0
TSC=0
TBE=1
Serial output TXD3
TBE=0
TSC=1✽
TBE=1
ST
D0
D1
SP
ST
D0
Receive buffer read
signal
SP
D1
✽
1 start bit
7 or 8 data bit
1 or 0 parity bit
1 or 2 stop bit (s)
Generated at 2nd bit in 2-stop-bit mode
RBF=0
RBF=1
Serial input RXD3
ST
D0
D1
SP
RBF=1
ST
D0
D1
SP
Notes 1: Error flag detection occurs at the same time that the RBF flag becomes “1” (at 1st stop bit, during reception).
2: As the transmit interrupt (TI), when either the TBE or TSC flag becomes “1,” can be selected to occur depending on the setting of the transmit
interrupt source selection bit (TIC) of the serial I/O3 control register.
3: The receive interrupt (RI) is set when the RBF flag becomes “1.”
4: After data is written to the transmit buffer when TSC=1, 0.5 to 1.5 cycles of the data shift cycle are necessary until changing to TSC=0.
Fig. 43 Operation of UART serial I/O3
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3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
[Serial I/O3 Control Register (SIO3CON)]
003216
The serial I/O3 control register consists of eight control bits for the
serial I/O3 function.
[UART3 Control Register (UART3CON)]
003316
The UART control register consists of four control bits (bits 0 to 3)
which are valid when asynchronous serial I/O is selected and set
the data format of an data transfer, and one bit (bit 4) which is always valid and sets the output structure of the P35/TXD3 pin.
[Serial I/O3 Status Register (SIO3STS)] 003116
The read-only serial I/O3 status register consists of seven flags
(bits 0 to 6) which indicate the operating status of the serial I/O3
function and various errors.
Three of the flags (bits 4 to 6) are valid only in UART mode.
The receive buffer full flag (bit 1) is cleared to “0” when the receive
buffer register is read.
If there is an error, it is detected at the same time that data is
transferred from the receive shift register to the receive buffer register, and the receive buffer full flag is set. A write to the serial I/O3
status register clears all the error flags OE, PE, FE, and SE (bit 3
to bit 6, respectively). Writing “0” to the serial I/O3 enable bit SIOE
(bit 7 of the serial I/O3 control register) also clears all the status
flags, including the error flags.
Bits 0 to 6 of the serial I/O3 status register are initialized to “0” at
reset, but if the transmit enable bit (bit 4) of the serial I/O3 control
register has been set to “1”, the transmit shift completion flag (bit
2) and the transmit buffer empty flag (bit 0) become “1”.
[Transmit Buffer Register 3/Receive Buffer
Register 3 (TB3/RB3)] 003016
The transmit buffer register 3 and the receive buffer register 3 are
located at the same address. The transmit buffer is write-only and
the receive buffer is read-only. If a character bit length is 7 bits, the
MSB of data stored in the receive buffer is “0”.
[Baud Rate Generator 3 (BRG3)] 002F16
The baud rate generator determines the baud rate for serial transfer.
The baud rate generator divides the frequency of the count source
by 1/(n + 1), where n is the value written to the baud rate generator.
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HARDWARE
3804 Group (Spec.H)
b7
b0
Serial I/O3 status register
(SIO3STS : address 003116)
FUNCTIONAL DESCRIPTION
b7
Transmit buffer empty flag (TBE)
0: Buffer full
1: Buffer empty
Receive buffer full flag (RBF)
0: Buffer empty
1: Buffer full
Transmit shift completion flag (TSC)
0: Transmit shift in progress
1: Transmit shift completed
Overrun error flag (OE)
0: No error
1: Overrun error
Parity error flag (PE)
0: No error
1: Parity error
Framing error flag (FE)
0: No error
1: Framing error
Summing error flag (SE)
0: (OE) U (PE) U (FE)=0
1: (OE) U (PE) U (FE)=1
Not used (returns “1” when read)
b0
Serial I/O3 control register
(SIO3CON : address 003216)
BRG count source selection bit (CSS)
0: f(XIN) (f(XCIN) in low-speed mode)
1: f(XIN)/4 (f(XCIN)/4 in low-speed mode)
Serial I/O3 synchronous clock selection bit (SCS)
0: BRG output divided by 4 when clock synchronous
serial I/O is selected, BRG output divided by 16
when UART is selected.
1: External clock input when clock synchronous serial
I/O is selected, external clock input divided by 16
when UART is selected.
SRDY3 output enable bit (SRDY)
0: P37 pin operates as normal I/O pin
1: P37 pin operates as SRDY3 output pin
Transmit interrupt source selection bit (TIC)
0: Interrupt when transmit buffer has emptied
1: Interrupt when transmit shift operation is completed
Transmit enable bit (TE)
0: Transmit disabled
1: Transmit enabled
Receive enable bit (RE)
0: Receive disabled
1: Receive enabled
Serial I/O3 mode selection bit (SIOM)
0: Clock asynchronous (UART) serial I/O
1: Clock synchronous serial I/O
Serial I/O3 enable bit (SIOE)
0: Serial I/O disabled
(pins P34 to P37 operate as normal I/O pins)
1: Serial I/O enabled
(pins P34 to P37 operate as serial I/O pins)
b7
b0
UART3 control register
(UART3CON : address 003316)
Character length selection bit (CHAS)
0: 8 bits
1: 7 bits
Parity enable bit (PARE)
0: Parity checking disabled
1: Parity checking enabled
Parity selection bit (PARS)
0: Even parity
1: Odd parity
Stop bit length selection bit (STPS)
0: 1 stop bit
1: 2 stop bits
P35/TXD3 P-channel output disable bit (POFF)
0: CMOS output (in output mode)
1: N-channel open drain output (in output mode)
Not used (return “1” when read)
Fig. 44 Structure of serial I/O3 control registers
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3804 Group (Spec.H)
■ Notes concerning serial I/O3
FUNCTIONAL DESCRIPTION
1. Notes when selecting clock synchronous serial I/O
1.1 Stop of transmission operation
● Note
Clear the serial I/O3 enable bit and the transmit enable bit to “0”
(serial I/O and transmit disabled).
2. Notes when selecting clock asynchronous serial I/O
2.1 Stop of transmission operation
● Note
Clear the transmit enable bit to “0” (transmit disabled). The transmission operation does not stop by clearing the serial I/O3 enable
bit to “0”.
● Reason
Since transmission is not stopped and the transmission circuit is
not initialized even if only the serial I/O3 enable bit is cleared to “0”
(serial I/O disabled), the internal transmission is running (in this
case, since pins TxD 3, RxD3, S CLK3, and SRDY3 function as I/O
ports, the transmission data is not output). When data is written to
the transmit buffer register in this state, data starts to be shifted to
the transmit shift register. When the serial I/O enable bit is set to
“1” at this time, the data during internally shifting is output to the
TxD3 pin and an operation failure occurs.
● Reason
Since transmission is not stopped and the transmission circuit is
not initialized even if only the serial I/O3 enable bit is cleared to “0”
(serial I/O disabled), the internal transmission is running (in this
case, since pins TxD3, RxD3, S CLK3, and SRDY3 function as I/O
ports, the transmission data is not output). When data is written to
the transmit buffer register in this state, data starts to be shifted to
the transmit shift register. When the serial I/O3 enable bit is set to
“1” at this time, the data during internally shifting is output to the
TxD3 pin and an operation failure occurs.
1.2 Stop of receive operation
● Note
Clear the receive enable bit to “0” (receive disabled), or clear the
serial I/O3 enable bit to “0” (serial I/O disabled).
2.2 Stop of receive operation
● Note
Clear the receive enable bit to “0” (receive disabled).
1.3 Stop of transmit/receive operation
● Note
Clear both the transmit enable bit and receive enable bit to “0”
(transmit and receive disabled).
(when data is transmitted and received in the clock synchronous
serial I/O mode, any one of data transmission and reception cannot be stopped.)
● Reason
In the clock synchronous serial I/O mode, the same clock is used
for transmission and reception. If any one of transmission and reception is disabled, a bit error occurs because transmission and
reception cannot be synchronized.
In this mode, the clock circuit of the transmission circuit also operates for data reception. Accordingly, the transmission circuit does
not stop by clearing only the transmit enable bit to “0” (transmit
disabled). Also, the transmission circuit is not initialized by clearing the serial I/O3 enable bit to “0” (serial I/O disabled) (refer to
1.1).
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2.3 Stop of transmit/receive operation
● Note 1 (only transmission operation is stopped)
Clear the transmit enable bit to “0” (transmit disabled). The transmission operation does not stop by clearing the serial I/O3 enable
bit to “0”.
● Reason
Since transmission is not stopped and the transmission circuit is
not initialized even if only the serial I/O3 enable bit is cleared to “0”
(serial I/O disabled), the internal transmission is running (in this
case, since pins TxD3, RxD3, S CLK3, and SRDY3 function as I/O
ports, the transmission data is not output). When data is written to
the transmit buffer register in this state, data starts to be shifted to
the transmit shift register. When the serial I/O3 enable bit is set to
“1” at this time, the data during internally shifting is output to the
TxD3 pin and an operation failure occurs.
● Note 2 (only receive operation is stopped)
Clear the receive enable bit to “0” (receive disabled).
1-52
HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
3. SRDY3 output of reception side
● Note
When signals are output from the SRDY3 pin on the reception side
by using an external clock in the clock synchronous serial I/O
mode, set all of the receive enable bit, the S RDY3 output enable
bit, and the transmit enable bit to “1” (transmit enabled).
4. Setting serial I/O3 control register again
● Note
Set the serial I/O3 control register again after the transmission and
the reception circuits are reset by clearing both the transmit enable bit and the receive enable bit to “0.”
Clear both the transmit enable bit
7. Transmit interrupt request when transmit enable bit is set
● Note
When using the transmit interrupt, take the following sequence.
➀ Set the serial I/O3 transmit interrupt enable bit to “0” (disabled).
➁ Set the transmit enable bit to “1”.
➂ Set the serial I/O3 transmit interrupt request bit to “0” after 1 or
more instruction has executed.
➃ Set the serial I/O3 transmit interrupt enable bit to “1” (enabled).
● Reason
When the transmit enable bit is set to “1”, the transmit buffer
empty flag and the transmit shift register shift completion flag are
also set to “1”. Therefore, regardless of selecting which timing for
the generating of transmit interrupts, the interrupt request is generated and the transmit interrupt request bit is set at this point.
(TE) and the receive enable bit
(RE) to “0”
↓
Set the bits 0 to 3 and bit 6 of the
serial I/O3 control register
↓
Set both the transmit enable bit
Can be set with the
LDM instruction at the
same time
(TE) and the receive enable bit
(RE), or one of them to “1”
5. Data transmission control with referring to transmit shift
register completion flag
● Note
After the transmit data is written to the transmit buffer register, the
transmit shift register completion flag changes from “1” to “0” with
a delay of 0.5 to 1.5 shift clocks. When data transmission is controlled with referring to the flag after writing the data to the transmit
buffer register, note the delay.
6. Transmission control when external clock is selected
● Note
When an external clock is used as the synchronous clock for data
transmission, set the transmit enable bit to “1” at “H” of the SCLK3
input level. Also, write data to the transmit buffer register at “H” of
the SCLK input level.
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3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
PULSE WIDTH MODULATION (PWM)
PWM Operation
The 3804 group (Spec. H) has PWM functions with an 8-bit resolution, based on a signal that is the clock input XIN or that clock
input divided by 2 or the clock input XCIN or that clock input divided by 2 in low-speed mode.
When bit 0 (PWM enable bit) of the PWM control register is set to
“1”, operation starts by initializing the PWM output circuit, and
pulses are output starting at an “H”.
If the PWM register or PWM prescaler is updated during PWM
output, the pulses will change in the cycle after the one in which
the change was made.
Data Setting
The PWM output pin also functions as port P56. Set the PWM period by the PWM prescaler, and set the “H” term of output pulse by
the PWM register.
If the value in the PWM prescaler is n and the value in the PWM
register is m (where n = 0 to 255 and m = 0 to 255) :
PWM period = 255 ✕ (n+1) / f(XIN)
= 31.875 ✕ (n+1) µs (when f(XIN) = 8 MHz)
Output pulse “H” term = PWM period ✕ m / 255
= 0.125 ✕ (n+1) ✕ m µs
(when f(XIN) = 8 MHz)
31.875 ✕ m ✕(n+1)
µs
255
PWM output
T = [31.875 ✕ (n+1)] µs
m: Contents of PWM register
n : Contents of PWM prescaler
T : PWM period (when f(XIN) = 8 MHz
Fig. 45 Timing of PWM period
Data bus
PWM
prescaler pre-latch
PWM
register pre-latch
Transfer control circuit
PWM
prescaler latch
PWM
register latch
PWM prescaler
PWM register
Count source
selection bit
“0”
XIN
Port P56
or
XCIN
1/2
“1”
Port P56 latch
PWM enable bit
Fig. 46 Block diagram of PWM function
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HARDWARE
3804 Group (Spec.H)
b7
FUNCTIONAL DESCRIPTION
b0
PWM control register
(PWMCON : address 002B16)
PWM function enable bit
0: PWM disabled
1: PWM enabled
Count source selection bit
0: f(XIN)
1: f(XIN)/2
Not used (return “0” when read)
Fig. 47 Structure of PWM control register
A
B
B = C
T2
T
C
PWM output
T
PWM register
write signal
PWM prescaler
write signal
T
T2
(Changes “H” term from “A” to “B”.)
(Changes PWM period from “T” to “T2”.)
When the contents of the PWM register or PWM prescaler have changed, the PWM
output will change from the next period after the change.
Fig. 48 PWM output timing when PWM register or PWM prescaler is changed
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3804 Group (Spec.H)
A/D CONVERTER
[AD Conversion Register 1, 2 (AD1, AD2)]
003516, 003816
The AD conversion register is a read-only register that stores the
result of an A/D conversion. When reading this register during an
A/D conversion, the previous conversion result is read.
Bit 7 of the AD conversion register 2 is the conversion mode selection bit. When this bit is set to “0,” the A/D converter becomes
the 10-bit A/D mode. When this bit is set to “1,” that becomes the
8-bit A/D mode. The conversion result of the 8-bit A/D mode is
stored in the AD conversion register 1. As for 10-bit A/D mode, not
only 10-bit reading but also only high-order 8-bit reading of conversion result can be performed by selecting the reading
procedure of the AD conversion registers 1, 2 after A/D conversion
is completed (in Figure 50).
As for 10-bit A/D mode, the 8-bit reading inclined to MSB is performed when reading the AD converter register 1 after A/D
conversion is started; and when the AD converter register 1 is
read after reading the AD converter register 2, the 8-bit reading inclined to LSB is performed.
FUNCTIONAL DESCRIPTION
Channel Selector
The channel selector selects one of ports P67/AN7 to P60/AN0 or
P07/AN15 to P00/AN8, and inputs the voltage to the comparator.
Comparator and Control Circuit
The comparator and control circuit compares an analog input voltage with the comparison voltage, and then stores the result in the
AD conversion registers 1, 2. When an A/D conversion is completed, the control circuit sets the AD conversion completion bit
and the AD interrupt request bit to “1”.
Note that because the comparator consists of a capacitor coupling, set f(XIN) to 500 kHz or more during an A/D conversion.
b7
b0
AD/DA control register
(ADCON : address 003416)
Analog input pin selection bits 1
b2 b1 b0
0
0
0
0
1
1
1
1
[AD/DA Control Register (ADCON)] 003416
The AD/DA control register controls the A/D conversion process.
Bits 0 to 2 and bit 4 select a specific analog input pin. Bit 3 signals
the completion of an A/D conversion. The value of this bit remains
at “0” during an A/D conversion, and changes to “1” when an A/D
conversion ends. Writing “0” to this bit starts the A/D conversion.
0: P60/AN0 or P00/AN8
1: P61/AN1 or P01/AN9
0: P62/AN2 or P02/AN10
1: P63/AN3 or P03/AN11
0: P64/AN4 or P04/AN12
1: P65/AN5 or P05/AN13
0: P66/AN6 or P06/AN14
1: P67/AN7 or P07/AN15
AD conversion completion bit
0: Conversion in progress
1: Conversion completed
Analog input pin selection bit 2
0: AN0 to AN7 side
1: AN8 to AN15 side
Comparison Voltage Generator
The comparison voltage generator divides the voltage between
VREF and AVSS into 1024, and that outputs the comparison voltage
in the 10-bit A/D mode (256 division in 8-bit A/D mode).
The A/D converter successively compares the comparison voltage
Vref in each mode, dividing the VREF voltage (see below), with the
input voltage.
• 10-bit A/D mode (10-bit reading)
Vref = VREF ✕ n (n = 0–1023)
1024
• 10-bit A/D mode (8-bit reading)
Vref = VREF ✕ n (n = 0–255)
256
• 8-bit A/D mode
Vref = VREF ✕ (n–0.5) (n = 1–255)
256
=0
(n = 0)
0
0
1
1
0
0
1
1
Not used (returns “0” when read)
DA1 output enable bit
0: DA1 output disabled
1: DA1 output enabled
DA2 output enable bit
0: DA2 output disabled
1: DA2 output enabled
Fig. 49 Structure of AD/DA control register
10-bit reading
(Read address 003816 before 003516)
b0
b7
AD conversion register 2
0
b9
b8
(AD2: address 003816)
b7
b0
AD conversion register 1
b7 b6 b5 b4 b3 b2 b1 b0
(AD1: address 003516)
Note : Bits 2 to 6 of address 003816 become “0”
at reading.
8-bit reading
(Read only address 003516) b7
b0
AD conversion register 1
b9 b8 b7 b6 b5 b4 b3 b2
(AD1: address 003516)
Fig. 50 Structure of 10-bit A/D mode reading
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
Data bus
AD/DA control register
(Address 003416)
b7
b0
4
AD converter interrupt request
A/D control circuit
Comparator
Channel selector
P60/AN0
P61/AN1
P62/AN2
P63/AN3
P64/AN4
P65/AN5
P66/AN6
P67/AN7
P00/AN8
P01/AN9
P02/AN10
P03/AN11
P04/AN12
P05/AN13
P06/AN14
P07/AN15
AD conversion register 2
AD conversion register 1
(Address 003816)
(Address 003516)
10
Resistor ladder
VREF AVSS
Fig. 51 Block diagram of A/D converter
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
D/A CONVERTER
The 3804 group (Spec. H) has two internal D/A converters (DA1
and DA2) with 8-bit resolution.
The D/A conversion is performed by setting the value in each DA
conversion register. The result of D/A conversion is output from
the DA1 or DA2 pin by setting the DA output enable bit to “1”.
When using the D/A converter, the corresponding port direction
register bit (P30/DA1 or P31/DA2) must be set to “0” (input status).
The output analog voltage V is determined by the value n (decimal
notation) in the DA conversion register as follows:
Data bus
DA1 conversion register (8)
V = VREF ✕ n/256 (n = 0 to 255)
Where VREF is the reference voltage.
R-2R resistor ladder
DA1 output enable bit
P30/DA1
DA2 conversion register (8)
At reset, the DA conversion registers are cleared to “00 16”, and
the DA output enable bits are cleared to “0”, and the P30/DA1 and
P31/DA2 pins become high impedance.
The DA output does not have buffers. Accordingly, connect an external buffer when driving a low-impedance load.
R-2R resistor ladder
DA2 output enable bit
P31/DA2
Fig. 52 Block diagram of D/A converter
“0” DA1 output enable bit
R
R
R
R
R
R
R
2R
P30/DA1
“1”
2R
2R
“0”
2R
2R
2R
2R
2R
LSB
MSB
DA1 conversion register
2R
“1”
AVSS
VREF
Fig. 53 Equivalent connection circuit of D/A converter (DA1)
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
WATCHDOG TIMER
The watchdog timer gives a mean of returning to the reset status
when a program cannot run on a normal loop (for example, because of a software run-away). The watchdog timer consists of an
8-bit watchdog timer L and an 8-bit watchdog timer H.
Watchdog Timer Initial Value
Watchdog timer L is set to “FF16” and watchdog timer H is set to
“FF16” by writing to the watchdog timer control register (address
001E16) or at a reset. Any write instruction that causes a write signal can be used, such as the STA, LDM, CLB, etc. Data can only
be written to bits 6 and 7 of the watchdog timer control register.
Regardless of the value written to bits 0 to 5, the above-mentioned
value will be set to each timer.
Watchdog Timer Operations
The watchdog timer stops at reset and a countdown is started by
the writing to the watchdog timer control register. An internal reset
occurs when watchdog timer H underflows. The reset is released
after its release time. After the release, the program is restarted
from the reset vector address. Usually, write to the watchdog timer
control register by software before an underflow of the watchdog
timer H. The watchdog timer does not function if the watchdog
timer control register is not written to at least once.
XCIN
“10”
Main clock division
ratio selection bits
(Note)
XIN
“FF16” is set when
watchdog timer
control register is
written to.
When bit 6 of the watchdog timer control register is kept at “0”, the
STP instruction is enabled. When that is executed, both the clock
and the watchdog timer stop. Count re-starts at the same time as
the release of stop mode (Note). The watchdog timer does not
stop while a WIT instruction is executed. In addition, the STP instruction is disabled by writing “1” to this bit again. When the STP
instruction is executed at this time, it is processed as an undefined
instruction, and an internal reset occurs. Once a “1” is written to
this bit, it cannot be programmed to “0” again.
The following shows the period between the write execution to the
watchdog timer control register and the underflow of watchdog
timer H.
Bit 7 of the watchdog timer control register is “0”:
when XCIN = 32.768 kHz; 32 s
when XIN = 16 MHz; 65.536 ms
Bit 7 of the watchdog timer control register is “1”:
when XCIN = 32.768 kHz; 125 ms
when XIN = 16 MHz; 256 µs
Note: The watchdog timer continues to count even while waiting for a stop
release. Therefore, make sure that watchdog timer H does not underflow during this period.
Data bus
“FF16” is set when
watchdog timer
control register is
written to.
“0”
Watchdog timer L (8)
1/16
“1”
“00”
“01”
Watchdog timer H (8)
Watchdog timer H count
source selection bit
STP instruction disable bit
STP instruction
Reset
circuit
RESET
Internal reset
Reset release time waiting
Note: Either high-speed, middle-speed or low-speed mode is selected by bits 7 and 6 of the CPU mode register.
Fig. 54 Block diagram of Watchdog timer
b7
b0
Watchdog timer control register
(WDTCON : address 001E16)
Watchdog timer H (for read-out of high-order 6 bit)
STP instruction disable bit
0: STP instruction enabled
1: STP instruction disabled
Watchdog timer H count source selection bit
0: Watchdog timer L underflow
1: f(XIN)/16 or f(XCIN)/16
Fig. 55 Structure of Watchdog timer control register
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
MULTI-MASTER I2C-BUS INTERFACE
Table 7 Multi-master I2C-BUS interface functions
I2C-BUS
The 3804 group (Spec. H) has the multi-master
interface.
The multi-master I2C-BUS interface is a serial communications circuit, conforming to the Philips I2C-BUS data transfer format. This
interface, offering both arbitration lost detection and a synchronous functions, is useful for the multi-master serial
communications.
Figure 56 shows a block diagram of the multi-master I2C-BUS interface and Table 7 lists the multi-master I 2 C-BUS interface
functions.
This multi-master I2C-BUS interface consists of the I2C slave address registers 0 to 2, the I2C data shift register, the I 2C clock
control register, the I2C control register, the I2C status register, the
I2C START/STOP condition control register, the I2C special mode
control register, the I2C special mode status register, and other
control circuits.
When using the multi-master I2 C-BUS interface, set 1 MHz or
more to the internal clock φ.
Interrupt
generating
circuit
Interrupt request signal
(SCL, SDA, IRQ)
Item
Format
Communication mode
SCL clock frequency
Function
In conformity with Philips I2C-BUS
standard:
10-bit addressing format
7-bit addressing format
High-speed clock mode
Standard clock mode
In conformity with Philips I2C-BUS
standard:
Master transmission
Master reception
Slave transmission
Slave reception
16.1 kHz to 400 kHz (at φ= 4 MHz)
System clock φ = f(XIN)/2 (high-speed mode)
φ = f(XIN)/8 (middle-speed mode)
b7 I2C slave address registers 0 to 2 b0
Interrupt
generating
circuit
SAD6 SAD5 SAD4 SAD3 SAD2 SAD1 SAD0 RWB
S0D0–2
Interrupt request signal
(I2CIRQ)
Address comparator
Data
control
circuit
Noise
elimination
circuit
Serial data
(SDA)
b7
b0
I2C data shift register
b7
b0
S0
AL AAS AD0 LRB
MST TRX BB PIN
SIS SIP SSC4 SSC3 SSC2 SSC1 SSC0
AL
circuit
S1
I2C status register
S2D I2C START/STOP condition control
register
Internal data bus
BB
circuit
Serial
clock
(SCL)
Noise
elimination
circuit
Clock
control
circuit
b7
ACK
b0
ACK FAST CCR4 CCR3 CCR2 CCR1 CCR0
BIT MODE
S2
I2C clock control register
Clock division
System clock (φ)
b7
b0
S PCF
PIN2
A AS2 A AS1 A AS0
S3 I2C special mode status register
b7
b7
TISS
b0
TSEL 10BIT AL S
SAD
SPCFL
b0
PIN2
HD
PIN2
IN
HSLAD ACK I
CON
ES0 BC2 BC1 BC0
S3D I2 C special mode control register
S1D I2C control register
Bit counter
Fig. 56 Block diagram of multi-master I2C-BUS interface
✽ : Purchase of MITSUBISHI ELECTRIC CORPORATIONS I2C components conveys a license under the Philips I2C Patent Rights to use these components
an I2C system, provided that the system conforms to the I2C Standard Specification as defined by Philips.
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HARDWARE
3804 Group (Spec.H)
[I2C Data Shift Register (S0)] 001116
The I2C data shift register (S0: address 001116) is an 8-bit shift
register to store receive data and write transmit data.
When transmit data is written into this register, it is transferred to
the outside from bit 7 in synchronization with the SCL, and each
time one-bit data is output, the data of this register are shifted by
one bit to the left. When data is received, it is input to this register
from bit 0 in synchronization with the SCL, and each time one-bit
data is input, the data of this register are shifted by one bit to the
left. The minimum 2 cycles of the internal clock φ are required
from the rising of the SCL until input to this register.
The I2C data shift register is in a write enable status only when the
I2C-BUS interface enable bit (ES0 bit) of the I2C control register
(S1D: address 001416) is “1”. The bit counter is reset by a write instruction to the I2C data shift register. When both the ES0 bit and
the MST bit of the I2C status register (S1: address 001316) are “1,”
the SCL is output by a write instruction to the I2C data shift register. Reading data from the I2C data shift register is always enabled
regardless of the ES0 bit value.
FUNCTIONAL DESCRIPTION
b7
b0
SAD6 SAD5 SAD4 SAD3 SAD2 SAD1 SAD0 RWB
I2C slave address register 0
(S0D0: address 0FF716)
I2C slave address register 1
(S0D1: address 0FF816)
I2C slave address register 2
(S0D2: address 0FF916)
Read/write bit
Slave address
Fig. 57 Structure of I2C slave address registers 0 to 2
[I2C Slave Address Registers 0 to 2 (S0D0 to S0D2)]
0FF716 to 0FF916
The I2C slave address registers 0 to 2 (S0D0 to S0D2: addresses
0FF716 to 0FF916) consists of a 7-bit slave address and a read/
write bit. In the addressing mode, the slave address written in this
register is compared with the address data to be received immediately after the START condition is detected.
•Bit 0: Read/write bit (RWB)
This is not used in the 7-bit addressing mode. In the 10-bit addressing mode, set RWB to “0” because the first address data to
be received is compared with the contents (SAD6 to SAD0 +
RWB) of the I2C slave address registers 0 to 2.
When 2-byte address data match slave address, a 7-bit slave address which is received after restart condition has detected and
R/W data can be matched by setting “1” to RWB with software.
The RWB is cleared to “0” automatically when the stop condition is
detected.
•Bits 1 to 7: Slave address (SAD0–SAD6)
These bits store slave addresses. Regardless of the 7-bit addressing mode or the 10-bit addressing mode, the address data
transmitted from the master is compared with these bits’ contents.
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HARDWARE
3804 Group (Spec.H)
Note: Do not write data into the I2C clock control register during transfer. If
data is written during transfer, the I 2C clock generator is reset, so
that data cannot be transferred normally.
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REJ09B0212-0100Z
b0
ACK
BIT
FAST
MODE CCR4 CCR3 CCR2 CCR1 CCR0
I2C clock control register
(S2 : address 001516)
SCL frequency control bits
Refer to Table 8.
SCL mode specification bit
0 : Standard clock mode
1 : High-speed clock mode
ACK bit
0 : ACK is returned.
1 : ACK is not returned.
ACK clock bit
0 : No ACK clock
1 : ACK clock
Fig. 58 Structure of I2C clock control register
Table 8 Set values of I 2 C clock control register and SCL
frequency
SCL frequency
Setting value of
(at φ = 4 MHz, unit : kHz) (Note 1)
CCR4–CCR0
Standard clock High-speed clock
CCR4 CCR3 CCR2 CCR1 CCR0
mode
mode
0
0
0
0
Setting disabled
Setting disabled
0
0
0
0
1
Setting disabled
Setting disabled
0
0
0
1
0
Setting disabled
Setting disabled
0
0
0
1
1
– (Note 2)
333
0
0
1
0
0
– (Note 2)
250
0
0
1
0
1
100
400 (Note 3)
0
0
1
1
0
83.3
166
…
0
…
•Bit 7: ACK clock bit (ACK)
This bit specifies the mode of acknowledgment which is an acknowledgment response of data transfer. When this bit is set to
“0,” the no ACK clock mode is selected. In this case, no ACK clock
occurs after data transmission. When the bit is set to “1,” the ACK
clock mode is selected and the master generates an ACK clock
each completion of each 1-byte data transfer. The device for
transmitting address data and control data releases the SDA at
the occurrence of an ACK clock (makes SDA “H”) and receives the
ACK bit generated by the data receiving device.
ACK
…
✽ACK clock: Clock for acknowledgment
b7
…
The I2C clock control register (S2: address 001516) is used to set
ACK control, SCL mode and SCL frequency.
•Bits 0 to 4: SCL frequency control bits (CCR0–CCR4)
These bits control the SCL frequency. Refer to Table 8.
•Bit 5: SCL mode specification bit (FAST MODE)
This bit specifies the SCL mode. When this bit is set to “0,” the
standard clock mode is selected. When the bit is set to “1,” the
high-speed clock mode is selected.
When connecting the bus of the high-speed mode I2C bus standard (maximum 400 kbits/s), use 8 MHz or more oscillation
frequency f(XIN) in the high-speed mode (2 division clock).
•Bit 6: ACK bit (ACK BIT)
This bit sets the SDA status when an ACK clock ✽ is generated.
When this bit is set to “0,” the ACK return mode is selected and
SDA goes to “L” at the occurrence of an ACK clock. When the bit
is set to “1,” the ACK non-return mode is selected. The SDA is
held in the “H” status at the occurrence of an ACK clock.
However, when the slave address agree with the address data in
the reception of address data at ACK BIT = “0,” the SDA is automatically made “L” (ACK is returned). If there is a disagreement
between the slave address and the address data, the SDA is automatically made “H” (ACK is not returned).
…
[I2C Clock Control Register (S2)] 001516
FUNCTIONAL DESCRIPTION
500/CCR value
(Note 3)
1
1
1
0
1
17.2
1000/CCR value
(Note 3)
34.5
1
1
1
1
0
16.6
33.3
1
1
1
1
1
16.1
32.3
Notes 1: Duty of SCL output is 50 %. The duty becomes 35 to 45 % only
when the high-speed clock mode is selected and CCR value = 5
(400 kHz, at φ = 4 MHz). “H” duration of the clock fluctuates from
–4 to +2 machine cycles in the standard clock mode, and fluctuates from –2 to +2 machine cycles in the high-speed clock mode.
In the case of negative fluctuation, the frequency does not increase because “L” duration is extended instead of “H” duration
reduction.
These are values when SCL synchronization by the synchronous
function is not performed. CCR value is the decimal notation
value of the SCL frequency control bits CCR4 to CCR0.
2: Each value of SCL frequency exceeds the limit at φ = 4 MHz or
more. When using these setting value, use φ of 4 MHz or less.
3: The data formula of SCL frequency is described below:
φ/(8 ✕ CCR value) Standard clock mode
φ/(4 ✕ CCR value) High-speed clock mode (CCR value ≠ 5)
φ/(2 ✕ CCR value) High-speed clock mode (CCR value = 5)
Do not set 0 to 2 as CCR value regardless of φ frequency.
Set 100 kHz (max.) in the standard clock mode and 400 kHz
(max.) in the high-speed clock mode to the SCL frequency by
setting the SCL frequency control bits CCR4 to CCR0.
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HARDWARE
3804 Group (Spec.H)
[I2C Control Register (S1D)] 001416
The I2C control register (S1D: address 001416) controls data communication format.
•Bits 0 to 2: Bit counter (BC0–BC2)
These bits decide the number of bits for the next 1-byte data to be
transmitted. The I2C interrupt request signal occurs immediately
after the number of count specified with these bits (ACK clock is
added to the number of count when ACK clock is selected by ACK
clock bit (bit 7 of S2, address 001516) have been transferred, and
BC0 to BC2 are returned to “0002”.
Also when a START condition is received, these bits become
“0002” and the address data is always transmitted and received in
8 bits.
•Bit 3: I2C interface enable bit (ES0)
This bit enables to use the multi-master I2C-BUS interface. When
this bit is set to “0,” the use disable status is provided, so that the
SDA and the SCL become high-impedance. When the bit is set to
“1,” use of the interface is enabled.
When ES0 = “0,” the following is performed.
• PIN = “1,” BB = “0” and AL = “0” are set (which are bits of the I2C
status register, S1, at address 001316 ).
• Writing data to the I2C data shift register (S0: address 001116) is
disabled.
•Bit 4: Data format selection bit (ALS)
This bit decides whether or not to recognize slave addresses.
When this bit is set to “0,” the addressing format is selected, so
that address data is recognized. When a match is found between
a slave address and address data as a result of comparison or
when a general call (refer to “I 2 C Status Register,” bit 1) is received, transfer processing can be performed. When this bit is set
to “1,” the free data format is selected, so that slave addresses are
not recognized.
•Bit 5: Addressing format selection bit (10BIT SAD)
This bit selects a slave address specification format. When this bit
is set to “0,” the 7-bit addressing format is selected. In this case,
only the high-order 7 bits (slave address) of the I2C slave address
registers 0 to 2 are compared with address data. When this bit is
set to “1,” the 10-bit addressing format is selected, and all the bits
of the I2C slave address registers 0 to 2 are compared with address data.
•Bit 7: I2C-BUS interface pin input level selection bit (TISS)
This bit selects the input level of the SCL and SDA pins of the
multi-master I2C-BUS interface.
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REJ09B0212-0100Z
FUNCTIONAL DESCRIPTION
b7
TISS
b0
10 B IT
S AD
ALS ES0 BC2 BC1 BC0
I2C control register
(S1D : address 001416)
Bit counter (Number of
transmit/receive bits)
b2 b 1 b0
0 0 0 : 8
0 0 1 : 7
0 1 0 : 6
0 1 1 : 5
1 0 0 : 4
1 0 1 : 3
1 1 0 : 2
1 1 1 : 1
I2C-BUS interface
enable bit
0 : Disabled
1 : Enabled
Data format selection bit
0 : Addressing format
1 : Free data format
Addressing format
selection bit
0 : 7-bit addressing
format
1 : 10-bit addressing
format
Not used
(return “0” when read)
I2C-BUS interface pin input
level selection bit
0 : SMBUS input
1 : CMOS input
Fig. 59 Structure of I2C control register
1-63
HARDWARE
3804 Group (Spec.H)
[I2C Status Register (S1)] 001316
The I2C status register (S1: address 001316) controls the I2C-BUS
interface status. The low-order 4 bits are read-only bits and the
high-order 4 bits can be read out and written to.
Set “00002” to the low-order 4 bits, because these bits become the
reserved bits at writing.
•Bit 0: Last receive bit (LRB)
This bit stores the last bit value of received data and can also be
used for ACK receive confirmation. If ACK is returned when an
ACK clock occurs, the LRB bit is set to “0.” If ACK is not returned,
this bit is set to “1.” Except in the ACK mode, the last bit value of
received data is input. The state of this bit is changed from “1” to
“0” by executing a write instruction to the I2C data shift register
(S0: address 001116).
•Bit 1: General call detecting flag (AD0)
When the ALS bit is “0”, this bit is set to “1” when a general call✽
whose address data is all “0” is received in the slave mode. By a
general call of the master device, every slave device receives control data after the general call. The AD0 bit is set to “0” by
detecting the STOP condition or START condition, or reset.
✽General call: The master transmits the general call address “00 16” to all
slaves.
•Bit 2: Slave address comparison flag (AAS)
This flag indicates a comparison result of address data when the
ALS bit is “0”.
➀ In the slave receive mode, when the 7-bit addressing format is
selected, this bit is set to “1” in one of the following conditions:
• The address data immediately after occurrence of a START
condition agrees with the slave address stored in the high-order 7 bits of the I2C slave address register.
• A general call is received.
➁ In the slave receive mode, when the 10-bit addressing format is
selected, this bit is set to “1” with the following condition:
• When the address data is compared with the I 2C slave address register (8 bits consisting of slave address and RWB
bit), the first bytes agree.
➂ This bit is set to “0” by executing a write instruction to the I2C data
shift register (S0: address 001116) when ES0 is set to “1” or reset.
•Bit 3: Arbitration lost✽ detecting flag (AL)
In the master transmission mode, when the SDA is made “L” by
any other device, arbitration is judged to have been lost, so that
this bit is set to “1.” At the same time, the TRX bit is set to “0,” so
that immediately after transmission of the byte whose arbitration
was lost is completed, the MST bit is set to “0.” The arbitration lost
can be detected only in the master transmission mode. When arbitration is lost during slave address transmission, the TRX bit is
set to “0” and the reception mode is set. Consequently, it becomes
possible to detect the agreement of its own slave address and address data transmitted by another master device.
FUNCTIONAL DESCRIPTION
•Bit 4: SCL pin low hold bit (PIN)
This bit generates an interrupt request signal. Each time 1-byte
data is transmitted, the PIN bit changes from “1” to “0.” At the
same time, an interrupt request signal occurs to the CPU. The PIN
bit is set to “0” in synchronization with a falling of the last clock (including the ACK clock) of an internal clock and an interrupt
request signal occurs in synchronization with a falling of the PIN
bit. When the PIN bit is “0,” the SCL is kept in the “0” state and
clock generation is disabled. Figure 61 shows an interrupt request
signal generating timing chart.
The PIN bit is set to “1” in one of the following conditions:
• Executing a write instruction to the I 2C data shift register (S0:
address 001116). (This is the only condition which the prohibition
of the internal clock is released and data can be communicated
except for the start condition detection.)
• When the ES0 bit is “0”
• At reset
• When writing “1” to the PIN bit by software
The PIN bit is set to “0” in one of the following conditions:
• Immediately after completion of 1-byte data transmission (including when arbitration lost is detected)
• Immediately after completion of 1-byte data reception
• In the slave reception mode, with ALS = “0” and immediately after completion of slave address agreement or general call
address reception
• In the slave reception mode, with ALS = “1” and immediately after completion of address data reception
•Bit 5: Bus busy flag (BB)
This bit indicates the status of use of the bus system. When this
bit is set to “0,” this bus system is not busy and a START condition
can be generated. The BB flag is set/reset by the SCL, SDA pins
input signal regardless of master/slave. This flag is set to “1” by
detecting the START condition, and is set to “0” by detecting the
STOP condition. The condition of these detecting is set by the
START/STOP condition setting bits (SSC4–SSC0) of the I 2 C
START/STOP condition control register (S2D: address 001616).
When the ES0 bit of the I2C control register (bit 3 of S1D, address
001416) is “0” or reset, the BB flag is set to “0.”
For the writing function to the BB flag, refer to the sections
“START Condition Generating Method” and “STOP Condition Generating Method” described later.
The AL bit is set to “0” in one of the following conditions:
•Executing a write instruction to the I2C data shift register (S0: address 001116)
•When the ES0 bit is “0”
•At reset
✽Arbitration lost :The status in which communication as a master is disabled.
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•Bit 6: Communication mode specification bit (transfer direction specification bit: TRX)
This bit decides a direction of transfer for data communication.
When this bit is “0,” the reception mode is selected and the data of
a transmitting device is received. When the bit is “1,” the transmission mode is selected and address data and control data are
output onto the SDA in synchronization with the clock generated
on the SCL.
This bit is set/reset by software and hardware. About set/reset by
hardware is described below. This bit is set to “1” by hardware
when all the following conditions are satisfied:
• When ALS is “0”
• In the slave reception mode or the slave transmission mode
• When the R/W bit reception is “1”
This bit is set to “0” in one of the following conditions:
• When arbitration lost is detected.
• When a STOP condition is detected.
• When writing “1” to this bit by software is invalid by the START
condition duplication preventing function (Note).
• With MST = “0” and when a START condition is detected.
• With MST = “0” and when ACK non-return is detected.
• At reset
•Bit 7: Communication mode specification bit (master/slave
specification bit: MST)
This bit is used for master/slave specification for data communication. When this bit is “0,” the slave is specified, so that a START
condition and a STOP condition generated by the master are received, and data communication is performed in synchronization
with the clock generated by the master. When this bit is “1,” the
master is specified and a START condition and a STOP condition
are generated. Additionally, the clocks required for data communication are generated on the SCL.
This bit is set to “0” in one of the following conditions.
• Immediately after completion of the byte which has lost arbitration when arbitration lost is detected
• When a STOP condition is detected.
• Writing “1” to this bit by software is invalid by the START condition duplication preventing function (Note).
• At reset
Note: START condition duplication preventing function
The MST, TRX, and BB bits is set to “1” at the same time after confirming that the BB flag is “0” in the procedure of a START condition
occurrence. However, when a START condition by another master
device occurs and the BB flag is set to “1” immediately after the contents of the BB flag is confirmed, the START condition duplication
preventing function makes the writing to the MST and TRX bits invalid. The duplication preventing function becomes valid from the
rising of the BB flag to reception completion of slave address.
FUNCTIONAL DESCRIPTION
b7
b0
MST TRX BB PIN AL AAS AD0 LRB
I2C status register
(S1 : address 001316)
Last receive bit (Note)
0 : Last bit = “0”
1 : Last bit = “1”
General call detecting flag
(Note)
0 : No general call detected
1 : General call detected
Slave address comparison flag
(Note)
0 : Address disagreement
1 : Address agreement
Arbitration lost detecting flag
(Note)
0 : Not detected
1 : Detected
SCL pin low hold bit
0 : SCL pin low hold
1 : SCL pin low release
Bus busy flag
0 : Bus free
1 : Bus busy
Communication mode
specification bits
00 : Slave receive mode
01 : Slave transmit mode
10 : Master receive mode
11 : Master transmit mode
Note: These bits and flags can be read out, but cannot be written.
Write “0” to these bits at writing.
Fig. 60 Structure of I2C status register
SCL
PIN
I2CIRQ
Fig. 61 Interrupt request signal generating timing
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FUNCTIONAL DESCRIPTION
START Condition Generating Method
STOP Condition Generating Method
When writing “1” to the MST, TRX, and BB bits of the I2C status
register (S1: address 001316) at the same time after writing the
slave address to the I2C data shift register (S0: address 001116)
with the condition in which the ES0 bit of the I2C control register
(S1D: address 001416) is “1” and the BB flag is “0”, a START condition occurs. After that, the bit counter becomes “0002” and an
SCL for 1 byte is output. The START condition generating timing is
different in the standard clock mode and the high-speed clock
mode. Refer to Figure 62, the START condition generating timing
diagram, and Table 9, the START condition generating timing
table.
When the ES0 bit of the I 2 C control register (S1D: address
001416) is “1,” write “1” to the MST and TRX bits, and write “0” to
the BB bit of the I2C status register (S1: address 001316) simultaneously. Then a STOP condition occurs. The STOP condition
generating timing is different in the standard clock mode and the
high-speed clock mode. Refer to Figure 63, the STOP condition
generating timing diagram, and Table 10, the STOP condition generating timing table.
I2C status register
write signal
SCL
I 2C
status register
write signal
SCL
SDA
SDA
Setup
time
Hold time
Fig. 62 START condition generating timing diagram
Table 9 START condition generating timing table
Standard clock mode High-speed clock mode
Item
2.5 µs (10 cycles)
5.0 µs (20 cycles)
Setup time
2.5 µs (10 cycles)
5.0 µs (20 cycles)
Hold time
Setup
time
Hold time
Fig. 63 STOP condition generating timing diagram
Table 10 STOP condition generating timing table
High-speed clock mode
Standard clock mode
Item
3.0 µs (12 cycles)
5.0 µs (20 cycles)
Setup time
2.5 µs (10 cycles)
4.5 µs (18 cycles)
Hold time
Note: Absolute time at φ = 4 MHz. The value in parentheses denotes the
number of φ cycles.
Note: Absolute time at φ = 4 MHz. The value in parentheses denotes the
number of φ cycles.
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FUNCTIONAL DESCRIPTION
START/STOP Condition Detecting Operation
The START/STOP condition detection operations are shown in
Figures 64, 65, and Table 11. The START/STOP condition is set
by the START/STOP condition set bit.
The START/STOP condition can be detected only when the input
signal of the SCL and SDA pins satisfy three conditions: SCL release time, setup time, and hold time (see Table 11).
The BB flag is set to “1” by detecting the START condition and is
reset to “0” by detecting the STOP condition.
The BB flag set/reset timing is different in the standard clock mode
and the high-speed clock mode. Refer to Table 11, the BB flag set/
reset time.
Note: When a STOP condition is detected in the slave mode (MST = 0), an
interrupt request signal “I2CIRQ” occurs to the CPU.
SCL release time
SCL
SDA
SCL release time
Setup time
Hold time
BB flag set/
reset time
SSC value + 1 cycle (6.25 µs)
Hold time
BB flag
set time
BB flag
Fig. 64 START/STOP condition detecting timing diagram
SCL release time
SCL
SDA
BB flag
Table 11 START condition/STOP condition detecting conditions
Standard clock mode
High-speed clock mode
Setup
time
Setup
time
Hold time
BB flag
reset
time
Fig. 65 STOP condition detecting timing diagram
4 cycles (1.0 µs)
SSC value + 1 cycle < 4.0 µs (3.125 µs)
2 cycles (0.5 µs)
2
SSC value + 1 cycle < 4.0 µs (3.125 µs) 2 cycles (0.5 µs)
2
SSC value –1 + 2 cycles (3.375 µs) 3.5 cycles (0.875 µs)
2
Note: Unit : Cycle number of internal clock φ
SSC value is the decimal notation value of the START/STOP condition set bits SSC4 to SSC0. Do not set “0” or an odd number to SSC
value. The value in parentheses is an example when the I2C START/
STOP condition control register is set to “1816” at φ = 4 MHz.
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FUNCTIONAL DESCRIPTION
[I2C START/STOP Condition Control Register
(S2D)] 001616
The I2C START/STOP condition control register (S2D: address
001616) controls START/STOP condition detection.
•Bits 0 to 4: START/STOP condition set bits (SSC4–SSC0)
SCL release time, setup time, and hold time change the detection
condition by value of the main clock divide ratio selection bit and
the oscillation frequency f(XIN) because these time are measured
by the internal system clock. Accordingly, set the proper value to
the START/STOP condition set bits (SSC4 to SSC0) in considered
of the system clock frequency. Refer to Table 11.
Do not set “000002” or an odd number to the START/STOP condition set bits (SSC4 to SSC0).
Refer to Table 12, the recommended set value to START/STOP
condition set bits (SSC4–SSC0) for each oscillation frequency.
•Bit 5: SCL/SDA interrupt pin polarity selection bit (SIP)
An interrupt can occur when detecting the falling or rising edge of
the SCL or SDA pin. This bit selects the polarity of the SCL or SDA
pin interrupt pin.
b7
•Bit 6: SCL/SDA interrupt pin selection bit (SIS)
This bit selects the pin of which interrupt becomes valid between
the SCL pin and the SDA pin.
Note: When changing the setting of the SCL/SDA interrupt pin polarity selection bit, the SCL/SDA interrupt pin selection bit, or the I2C-BUS
interface enable bit ES0, the SCL/SDA interrupt request bit may be
set. When selecting the SCL/SDA interrupt source, disable the interrupt before the SCL/SDA interrupt pin polarity selection bit, the SCL/
SDA interrupt pin selection bit, or the I2C-BUS interface enable bit
ES0 is set. Reset the request bit to “0” after setting these bits, and
enable the interrupt.
b0
SIS SIP SSC4 SSC3 SSC2 SSC1 SSC0
I2C START/STOP condition
control register
(S2D : address 001616)
START/STOP condition set bits
SCL/SDA interrupt pin polarity
selection bit
0 : Falling edge active
1 : Rising edge active
SCL/SDA interrupt pin selection bit
0 : SDA valid
1 : SCL valid
Not used
(Fix this bit to “0”.)
Fig. 66 Structure of I2C START/STOP condition control register
Table 12 Recommended set value to START/STOP condition set bits (SSC4–SSC0) for each oscillation frequency
Oscillation
frequency
f(XIN) (MHz)
Main clock
divide ratio
Internal
clock φ
(MHz)
8
2
4
8
8
1
4
2
2
2
2
1
START/STOP
condition
control register
SCL release time
(µs)
Setup time
(µs)
Hold time
(µs)
XXX11010
XXX11000
XXX00100
XXX01100
XXX01010
XXX00100
6.75 µs (27 cycles)
6.25 µs (25 cycles)
5.0 µs (5 cycles)
6.5 µs (13 cycles)
5.5 µs (11 cycles)
5.0 µs (5 cycles)
3.5 µs (14 cycles)
3.25 µs (13 cycles)
3.0 µs (3 cycles)
3.5 µs (7 cycles)
3.0 µs (6 cycles)
3.0 µs (3 cycles)
3.25 µs (13 cycles)
3.0 µs (12 cycles)
2.0 µs (2 cycles)
3.0 µs (6 cycles)
2.5 µs (5 cycles)
2.0 µs (2 cycles)
Note: Do not set an odd number to the START/STOP condition set bits (SSC4 to SSC0) and “000002”.
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FUNCTIONAL DESCRIPTION
[I 2 C Special Mode Status Register (S3)]
001216
The I2 C special mode status register (S3: address 001216) consists of the flags indicating I2C operating state in the I2C special
mode, which is set by the I2C special mode control register (S3D:
address 001716).
The stop condition flag is valid in all operating modes.
•Bit 0: Slave address 0 comparison flag (AAS0)
Bit 1: Slave address 1 comparison flag (AAS1)
Bit 2: Slave address 2 comparison flag (AAS2)
These flags indicate a comparison result of address data. These
flags are valid only when the slave address control bit (MSLAD) is
“1”.
In the 7-bit addressing format of the slave reception mode, the respective slave address i (i = 0, 1, 2) comparison flags
corresponding to the I2C slave address registers 0 to 2 are set to
“1” when an address data immediately after an occurrence of a
START condition agrees with the high-order 7-bit slave address
stored in the I2C slave address registers 0 to 2 (addresses 0FF716
to 0FF916).
In the 10-bit addressing format of the slave mode, the respective
slave address i (i = 0, 1, 2) comparison flags corresponding to the
I2C slave address registers are set to “1” when an address data is
compared with the 8 bits consisting of the slave address stored in
the I2C slave address registers 0 to 2 and the RWB bit, and the
first byte agrees.
These flags are initialized to “0” at reset, when the slave address
control bit (MSLAD) is “0”, or when writing data to the I2C data
shift register (S0: address 001116).
b7
SP CF
•Bit 5: SCL pin low hold 2 flag (PIN2)
When the ACK interrupt control bit (ACKICON) and the ACK clock
bit (ACK) are “1”, this flag is set to “0” in synchronization with the
falling of the data’s last SCL clock, just before the ACK clock. The
SCL pin is simultaneously held low, and the I2C interrupt request
occurs.
This flag is initialized to “1” at reset, when the ACK interrupt control bit (ACKICON) is “0”, or when writing “1” to the SCL pin low
hold 2 flag set bit (PIN2IN).
The SCL pin is held low when either the SCL pin low hold bit (PIN)
or the SCL pin low hold 2 flag (PIN2) becomes “0”. The low hold
state of the SCL pin is released when both the SCL pin low hold
bit (PIN) and the SCL pin low hold 2 flag (PIN2) are “1”.
•Bit 7: Stop condition flag (SPCF)
This flag is set to “1” when a STOP condition occurs.
This flag is initialized to “0” at reset, when the I2C-BUS interface
enable bit (ES0) is “0”, or when writing “1” to the STOP condition
flag clear bit (SPFCL).
b0
PIN2
AAS2 AA S1 AAS0
I2C special mode status register
(S3 : address 001216)
Slave address 0 comparison flag
0 : Address disagreement
1 : Address agreement
Slave address 1 comparison flag
0 : Address disagreement
1 : Address agreement
Slave address 2 comparison flag
0 : Address disagreement
1 : Address agreement
Not used
(return “0” when read)
Not used
(return “0” when read)
SCL pin low hold 2 flag
0 : SCL pin low hold
1 : SCL pin low release (Note)
Not used
(return “0” when read)
STOP condition flag
0 : No detection
1 : Detection
Note: In order that the low hold state of the SCL pin may release, it is
necessary that the SCL pin low hold 2 flag and the SCL pin low
hold bit (PIN) are “1” simultaneously.
Fig. 67 Structure of I2C special mode status register
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FUNCTIONAL DESCRIPTION
[I 2 C Special Mode Control Register (S3D)]
001716
The I2C special mode control register (S3D: address 001716) controls special functions such as occurrence timing of reception
interrupt request and extending slave address comparison to 3
bytes.
•Bit 1: ACK interrupt control bit (ACKICON)
This bit controls the timing of I2C interrupt request occurrence at
completion of data receiving due to master reception or slave reception.
When this bit is “0”, the SCL pin low hold bit (PIN) is set to “0” in
synchronization with the falling of the last SCL clock, including the
ACK clock. The SCL pin is simultaneously held low, and the I2C
interrupt request occurs.
When this bit is “1” and the ACK clock bit (ACK) is “1”, the SCL pin
low hold 2 flag (PIN2) is set to “0” in synchronization with the falling of the data’s last SCL clock, just before the ACK clock. The
SCL pin is simultaneously held low, and the I2C interrupt request
occurs again. The ACK bit can be changed after the contents of
data are confirmed by using this function.
b7
SPFCL
•Bit 2: I2C slave address control bit (MSLAD)
This bit controls a slave address. When this bit is “0”, only the I2C
slave address register 0 (address 0FF716 ) becomes valid as a
slave address and a read/write bit.
When this bit is “1”, all of the I2C slave address registers 0 to 2
(addresses 0FF7 16 to 0FF916) become valid as a slave address
and a read/write bit. In this case, when an address data agrees
with any one of the I2C slave address registers 0 to 2, the slave
address comparison flag (AAS) is set to “1” and the I2C slave address comparison flag corresponding to the agreed I 2C slave
address registers 0 to 2 is also set to “1”.
•Bit 5: SCL pin low hold 2 flag set bit (PIN2IN)
Writing “1” to this bit initializes the SCL pin low hold 2 flag (PIN2)
to “1”.
When writing “0”, nothing is generated.
•Bit 6: SCL pin low hold set bit (PIN2HD)
When the SCL pin low hold bit (PIN) becomes “0”, the SCL pin is
held low. However, the SCL pin low hold bit (PIN) cannot be set to
“0” by software. The SCL pin low hold set bit (PIN2HD) is used to ,
hold the SCL pin in the low state by software. When writing “1” to
this bit, the SCL pin low hold 2 flag (PIN2) becomes “0”, and the
SCL pin is held low. When writing “0”, nothing occurs.
•Bit 7: STOP condition flag clear bit (SPFCL)
Writing “1” to this bit initializes the STOP condition flag (SPCF) to
“0”.
When writing “0”, nothing is generated.
b0
PIN2- PIN2IN
HD
MSLAD
ACKI
CON
I2C special mode control register
(S3D : address 001716)
Not used
(Fix this bit to “0”.)
ACK interrupt control bit
0 : At communication completion
1 : At falling of ACK clock and communication
completion
Slave address control bit
0 : One-byte slave address compare mode
1 : Three-byte slave address compare mode
Not used
(return “0” when read)
Not used
(Fix this bit to “0”.)
SCL pin low hold 2 flag set bit (Notes 1, 2)
Writing “1” to this bit initializes the SCL pin low
hold 2 flag to “1”.
SCL pin low hold set bit (Notes 1, 2)
When writing “1” to this bit, the SCL pin low
hold 2 flag becomes “0” and the SCL pin is held
low.
STOP condition flag clear bit (Note 2)
Writing “1” to this bit initializes the STOP
condition flag to “0”.
Notes 1: Do not write “1” to these bits simultaneously.
2: return “0” when read
Fig. 68 Structure of I2C special mode control register
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FUNCTIONAL DESCRIPTION
Address Data Communication
parison, an address comparison between the RWB bit of the
I2C slave address register and the R/W bit which is the last bit
of the address data transmitted from the master is made. In the
10-bit addressing mode, the RWB bit which is the last bit of the
address data not only specifies the direction of communication
for control data, but also is processed as an address data bit.
When the first-byte address data agree with the slave address,
the AAS bit of the I2C status register (S1: address 001316) is
set to “1.” After the second-byte address data is stored into the
I2C data shift register (S0: address 001116 ), perform an address comparison between the second-byte data and the slave
address by software. When the address data of the 2 bytes
agree with the slave address, set the RWB bit of the I2C slave
address register to “1” by software. This processing can make
the 7-bit slave address and R/W data agree, which are received after a RESTART condition is detected, with the value of
the I2C slave address register. For the data transmission format when the 10-bit addressing format is selected, refer to
Figure 69, (3) and (4).
There are two address data communication formats, namely, 7-bit
addressing format and 10-bit addressing format. The respective
address communication formats are described below.
➀ 7-bit addressing format
To adapt the 7-bit addressing format, set the 10BIT SAD bit of
the I2C control register (S1D: address 001416) to “0”. The first 7bit address data transmitted from the master is compared with
the high-order 7-bit slave address stored in the I 2C slave address register. At the time of this comparison, address
comparison of the RWB bit of the I2C slave address register is
not performed. For the data transmission format when the 7-bit
addressing format is selected, refer to Figure 69, (1) and (2).
➁ 10-bit addressing format
To adapt the 10-bit addressing format, set the 10BIT SAD bit of
the I2C control register (S1D: address 0014 16) to “1.” An address comparison is performed between the first-byte address
data transmitted from the master and the 8-bit slave address
stored in the I2C slave address register. At the time of this com-
(1) A master-transmitter transmits data to a slave-receiver
S
Slave address R/W
7 bits
A
“0”
Data
A
1 to 8 bits
Data
A/A
P
A
P
1 to 8 bits
(2) A master-receiver receives data from a slave-transmitter
S
Slave address R/W
7 bits
A
“1”
Data
A
1 to 8 bits
Data
1 to 8 bits
(3) A master-transmitter transmits data to a slave-receiver with a 10-bit address
S
Slave address
R/W
1st 7 bits
7 bits
A
“0”
Slave address
2nd bytes
A
Data
1 to 8 bits
8 bits
Data
A
A/A
P
1 to 8 bits
(4) A master-receiver receives data from a slave-transmitter with a 10-bit address
S
Slave address
R/W
1st 7 bits
7 bits
S : START condition
A : ACK bit
Sr : Restart condition
“0”
A
Slave address
2nd bytes
8 bits
P : STOP condition
R/W : Read/Write bit
A
Sr
Slave address
R/W
1st 7 bits
7 bits
“1”
A
Data
1 to 8 bits
A
Data
A
P
1 to 8 bits
: Master to slave
: Slave to master
Fig. 69 Address data communication format
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FUNCTIONAL DESCRIPTION
Example of Master Transmission
Example of Slave Reception
An example of master transmission in the standard clock mode, at
the SCL frequency of 100 kHz and in the ACK return mode is
shown below.
➀ Set a slave address in the high-order 7 bits of the I2C slave address register and “0” into the RWB bit.
➁ Set the ACK return mode and SCL = 100 kHz by setting “8516”
in the I2C clock control register (S2: address 001516).
➂ Set “0016” in the I 2C status register (S1: address 001316 ) so
that transmission/reception mode can become initializing condition.
➃ Set a communication enable status by setting “0816” in the I2C
control register (S1D: address 001416).
➄ Confirm the bus free condition by the BB flag of the I2C status
register (S1: address 001316).
➅ Set the address data of the destination of transmission in the
high-order 7 bits of the I 2 C data shift register (S0: address
001116) and set “0” in the least significant bit.
➆ Set “F0 16” in the I 2C status register (S1: address 001316 ) to
generate a START condition. At this time, an SCL for 1 byte and
an ACK clock automatically occur.
➇ Set transmit data in the I 2 C data shift register (S0: address
001116). At this time, an SCL and an ACK clock automatically
occur.
➈ When transmitting control data of more than 1 byte, repeat step
➇.
➉ Set “D016” in the I2C status register (S1: address 0013 16) to
generate a STOP condition if ACK is not returned from slave reception side or transmission ends.
An example of slave reception in the high-speed clock mode, at
the SCL frequency of 400 kHz, in the ACK non-return mode and
using the addressing format is shown below.
➀ Set a slave address in the high-order 7 bits of the I2C slave address register and “0” in the RWB bit.
➁ Set the no ACK clock mode and SCL = 400 kHz by setting
“2516” in the I2C clock control register (S2: address 001516).
➂ Set “00 16” in the I2C status register (S1: address 0013 16) so
that transmission/reception mode can become initializing condition.
➃ Set a communication enable status by setting “0816” in the I2C
control register (S1D: address 001416).
➄ When a START condition is received, an address comparison is
performed.
➅ •When all transmitted addresses are “0” (general call):
AD0 of the I2C status register (S1: address 001316) is set to “1”
and an interrupt request signal occurs.
• When the transmitted addresses agree with the address set in
➀:
AAS of the I2C status register (S1: address 001316) is set to
“1” and an interrupt request signal occurs.
• In the cases other than the above AD0 and AAS of the I2C status register (S1: address 001316) are set to “0” and no interrupt
request signal occurs.
➆ Set dummy data in the I 2 C data shift register (S0: address
001116).
➇ When receiving control data of more than 1 byte, repeat step ➆.
➈ When a STOP condition is detected, the communication ends.
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■Precautions when using multi-master I2CBUS interface
(1) Read-modify-write instruction
The precautions when the read-modify-write instruction such as
SEB, CLB etc. is executed for each register of the multi-master
I2C-BUS interface are described below.
• I2C data shift register (S0: address 001116)
When executing the read-modify-write instruction for this register during transfer, data may become a value not intended.
• I2C slave address registers 0 to 2 (S0D0 to S0D2: addresses
0FF716 to0FF916)
When the read-modify-write instruction is executed for this register at detecting the STOP condition, data may become a value
not intended. It is because H/W changes the read/write bit
(RWB) at the above timing.
• I2C status register (S1: address 001316)
Do not execute the read-modify-write instruction for this register
because all bits of this register are changed by H/W.
• I2C control register (S1D: address 001416)
When the read-modify-write instruction is executed for this register at detecting the START condition or at completing the byte
transfer, data may become a value not intended. Because H/W
changes the bit counter (BC0-BC2) at the above timing.
• I2C clock control register (S2: address 001516)
The read-modify-write instruction can be executed for this register.
• I 2 C START/STOP condition control register (S2D: address
001616)
The read-modify-write instruction can be executed for this register.
(2) START condition generating procedure using multi-master
1. Procedure example (The necessary conditions of the generating procedure are described as the following 2 to 5.
::
LDA —
(Taking out of slave address value)
SEI
(Interrupt disabled)
BBS 5, S1, BUSBUSY (BB flag confirming and branch process)
BUSFREE:
STA S0
(Writing of slave address value)
LDM #$F0, S1
(Trigger of START condition generating)
CLI
(Interrupt enabled)
::
BUSBUSY:
CLI
(Interrupt enabled)
::
FUNCTIONAL DESCRIPTION
5. Disable interrupts during the following three process steps:
• BB flag confirming
• Writing of slave address value
• Trigger of START condition generating
When the condition of the BB flag is bus busy, enable interrupts
immediately.
(3) RESTART condition generating procedure
1. Procedure example (The necessary conditions of the generating procedure are described as the following 2 to 4.)
Execute the following procedure when the PIN bit is “0.”
::
LDM #$00, S1
(Select slave receive mode)
LDA —
(Taking out of slave address value)
SEI
(Interrupt disabled)
STA S0
(Writing of slave address value)
LDM #$F0, S1
(Trigger of RESTART condition generating)
CLI
(Interrupt enabled)
::
2. Select the slave receive mode when the PIN bit is “0.” Do not
write “1” to the PIN bit. Neither “0” nor “1” is specified for the
writing to the BB bit.
The TRX bit becomes “0” and the SDA pin is released.
3. The SCL pin is released by writing the slave address value to
the I2C data shift register.
4. Disable interrupts during the following two process steps:
• Writing of slave address value
• Trigger of RESTART condition generating
(4) Writing to I2C status register
Do not execute an instruction to set the PIN bit to “1” from “0” and
an instruction to set the MST and TRX bits to “0” from “1” simultaneously. It is because it may enter the state that the SCL pin is
released and the SDA pin is released after about one machine
cycle. Do not execute an instruction to set the MST and TRX bits
to “0” from “1” simultaneously when the PIN bit is “1.” It is because
it may become the same as above.
(5) Process of after STOP condition generating
Do not write data in the I2C data shift register S0 and the I2C status register S1 until the bus busy flag BB becomes “0” after
generating the STOP condition in the master mode. It is because
the STOP condition waveform might not be normally generated.
Reading to the above registers does not have the problem.
2. Use “Branch on Bit Set” of “BBS 5, S1, –” for the BB flag confirming and branch process.
3. Use “STA $12, STX $12” or “STY $12” of the zero page addressing instruction for writing the slave address value to the
I2C data shift register.
4. Execute the branch instruction of above 2 and the store instruction of above 3 continuously shown the above procedure
example.
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
RESET CIRCUIT
To reset the microcomputer, RESET pin should be held at an “L”
level for 16 cycles or more of XIN. Then the RESET pin is returned
to an “H” level (the power source voltage should be between 2.7 V
to 5.5 V, and the oscillation should be stable), reset is released.
After the reset is completed, the program starts from the address
contained in address FFFD 16 (high-order byte) and address
FFFC16 (low-order byte).
Input to the RESET pin in the following procedure.
●When power source is stabilized
(1) Input “L” level to RESET pin.
(2) Input “L” level for 16 cycles or more to XIN pin.
(3) Input “H” level to RESET pin.
VCC
RESET
VCC
2.7 V
0V
RESET
0.2VCC or less
0V
td(P-R)+XIN 16 cycles or more
5V
RESET
Power source
voltage detection
circuit
VCC
VCC
2.7 V
0V
5V
RESET
0V
●At power-on
(1) Input “L” level to RESET pin.
(2) Increase the power source voltage to 2.7 V.
(3) Wait for td(P-R) until internal power source has stabilized.
(4) Input “L” level for 16 cycles or more to XIN pin.
(5) Input “H” level to RESET pin.
td(P-R)+XIN 16 cycles or more
Example at VCC = 5V
Fig. 70 Reset circuit example
XIN
φ
RESET
Internal
reset
Address
?
?
?
?
FFFC
FFFD
ADH,L
Reset address from the vector table.
?
Data
?
?
?
ADL
ADH
SYNC
XIN: 10.5 to 18.5 clock cycles
Notes 1: The frequency relation of f(XIN) and f(φ) is f(XIN)=8 • f(φ).
2: The question marks (?) indicate an undefined state that depends on the previous state.
Fig. 71 Reset sequence
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
Address Register contents
Address Register contents
(1)
Port P0 (P0)
000016
0016
(41) Timer Z (low-order) (TZL)
002816
FF16
(2)
Port P0 direction register (P0D)
000116
0016
(42) Timer Z (high-order) (TZH)
002916
FF16
(3)
Port P1 (P1)
000216
0016
(43) Timer Z mode register (TZM)
002A16
0016
(4)
Port P1 direction register (P1D)
000316
0016
(44) PWM control register (PWMCON)
002B16
0016
(5)
Port P2 (P2)
000416
0016
(45) PWM prescaler (PREPWM)
002C16 X X X X X X X X
(6)
Port P2 direction register (P2D)
000516
0016
(46) PWM register (PWM)
002D16 X X X X X X X X
(7)
Port P3 (P3)
000616
0016
(47) Baud rate generator 3 (BRG3)
002F16 X X X X X X X X
(8)
Port P3 direction register (P3D)
000716
0016
(48) Transmit/Receive buffer register 3 (TB3/RB3)
003016 X X X X X X X X
(9)
Port P4 (P4)
000816
0016
(49) Serial I/O3 status register (SIO3STS)
003116 1 0 0 0 0 0 0 0
(10) Port P4 direction register (P4D)
000916
0016
(50) Serial I/O3 control register (SIO3CON)
003216
(11) Port P5 (P5)
000A16
0016
(51) UART3 control register (UART3CON)
003316 1 1 1 0 0 0 0 0
(12) Port P5 direction register (P5D)
000B16
0016
(52) AD/DA control register (ADCON)
003416 0 0 0 0 1 0 0 0
(13) Port P6 (P6)
000C16
0016
(53) AD conversion register 1 (AD1)
003516 X X X X X X X X
(14) Port P6 direction register (P6D)
000D16
0016
(54) DA1 conversion register (DA1)
003616
000E16
0 0 1 1 0 0 1 1
(55) DA2 conversion register (DA2)
003716
0016
(56) AD conversion register 2 (AD2)
003816
0 0 0 0 0 0 X X
(57) Interrupt source selection register (INTSEL)
003916
0016
0016
(15)
(16)
Timer 12, X count source selection register (T12XCSS)
0016
0016
000F16
0 0 1 1 0 0 1 1
(17) MISRG
001016
0016
(18) I2C data shift register (S0)
001116 X X X X X X X X
(58) Interrupt edge selection register (INTEDGE)
003A16
(19) I2C special mode status register (S3)
001216 0 0 1 0 0 0 0 0
(59) CPU mode register (CPUM)
003B16 0 1 0 0 1 0 0 0
(20) I2C status register (S1)
001316 0 0 0 1 0 0 0 X
(60) Interrupt request register 1 (IREQ1)
003C16
0016
(21) I2C control register (S1D)
001416
0016
(61) Interrupt request register 2 (IREQ2)
003D16
0016
(22) I2C clock control register (S2)
001516
0016
(62) Interrupt control register 1 (ICON1)
003E16
0016
(23) I2C START/STOP condition control register (S2D)001616 0 0 0 1 1 0 1 0
(63) Interrupt control register 2 (ICON2)
003F16
0016
(24) I2C special mode control register (S3D)
001716
(64) Flash memory control register 0 (FMCR0)
0FE016
0116
(25) Transmit/Receive buffer register 1 (TB1/RB1)
001816 X X X X X X X X
(65) Flash memory control register 1 (FMCR1)
0FE116
4016
(26) Serial I/O1 status register (SIO1STS)
001916 1 0 0 0 0 0 0 0
(66) Flash memory control register 2 (FMCR2)
0FE216
4516
(27) Serial I/O1 control register (SIO1CON)
001A16
(67) Port P0 pull-up control register (PULL0)
0FF016
0016
(28) UART1 control register (UART1CON)
001B16 1 1 1 0 0 0 0 0
(68) Port P1 pull-up control register (PULL1)
0FF116
0016
(29) Baud rate generator 1 (BRG1)
001C16 X X X X X X X X
(69) Port P2 pull-up control register (PULL2)
0FF216
0016
(30) Serial I/O2 control register (SIO2CON)
001D16
(70) Port P3 pull-up control register (PULL3)
0FF316
0016
(31) Watchdog timer control register (WDTCON)
001E16 0 0 1 1 1 1 1 1
(71) Port P4 pull-up control register (PULL4)
0FF416
0016
(32) Serial I/O2 register (SIO2)
001F16 X X X X X X X X
(72) Port P5 pull-up control register (PULL5)
0FF516
0016
(33) Prescaler 12 (PRE12)
002016
FF16
(73) Port P6 pull-up control register (PULL6)
0FF616
0016
0116
(74) I2C
slave address register 0 (S0D0)
0FF716
0016
FF16
(75) I2C
slave address register 1 (S0D1)
0FF816
0016
slave address register 2 (S0D3)
0FF916
0016
Timer Y, Z count source selection register (TYZCSS)
(34) Timer 1 (T1)
(35) Timer 2 (T2)
002116
002216
0016
0016
0016
(36) Timer XY mode register (TM)
002316
0016
(76) I2C
(37) Prescaler X (PREX)
002416
FF16
(77) Processor status register
(PS)
(38) Timer X (TX)
002516
FF16
(78) Program counter
(PCH)
FFFD16 contents
002616
FF16
(PCL)
FFFC16 contents
002716
FF16
(39) Prescaler Y (PREY)
(40) Timer Y (TY)
X X XX X1 X X
Note : X : Not fixed
Since the initial values for other than above mentioned registers and
RAM contents are indefinite at reset, they must be set.
Fig. 72 Internal status at reset
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HARDWARE
3804 Group (Spec.H)
CLOCK GENERATING CIRCUIT
The 3804 group (Spec. H) has two built-in oscillation circuits: main
clock XIN-XOUT oscillation circuit and sub clock XCIN-XCOUT oscillation circuit. An oscillation circuit can be formed by connecting a
resonator between XIN and XOUT (XCIN and XCOUT). Use the circuit constants in accordance with the resonator manufacturer’s
recommended values. No external resistor is needed between XIN
and XOUT since a feed-back resistor exists on-chip.(An external
feed-back resistor may be needed depending on conditions.)
However, an external feed-back resistor is needed between XCIN
and XCOUT.
Immediately after power on, only the XIN oscillation circuit starts
oscillating, and XCIN and XCOUT pins function as I/O ports.
Frequency Control
(1) Middle-speed mode
The internal clock φ is the frequency of XIN divided by 8. After reset is released, this mode is selected.
(2) High-speed mode
The internal clock φ is half the frequency of XIN.
(3) Low-speed mode
The internal clock φ is half the frequency of XCIN.
(4) Low power dissipation mode
The low power consumption operation can be realized by stopping
the main clock XIN in low-speed mode. To stop the main clock, set
bit 5 of the CPU mode register to “1.” When the main clock XIN is
restarted (by setting the main clock stop bit to “0”), set sufficient
time for oscillation to stabilize.
FUNCTIONAL DESCRIPTION
Oscillation Control
(1) Stop mode
If the STP instruction is executed, the internal clock φ stops at an
“H” level, and XIN and X CIN oscillators stop. When the oscillation
stabilizing time set after STP instruction released bit is “0,” the
prescaler 12 is set to “FF16” and timer 1 is set to “0116.” When the
oscillation stabilizing time set after STP instruction released bit is
“1,” set the sufficient time for oscillation of used oscillator to stabilize since nothing is set to the prescaler 12 and timer 1.
After STP instruction is released, the input of the prescaler 12 is
connected to count source which had set at executing the STP instruction, and the output of the prescaler 12 is connected to timer
1. Set the timer 1 interrupt enable bit to disabled (“0”) before executing the STP instruction. Oscillator restarts when an external
interrupt is received, but the internal clock φ is not supplied to the
CPU (remains at “H”) until timer 1 underflows. The internal clock φ
is supplied for the first time, when timer 1 underflows. Therefore
make sure not to set the timer 1 interrupt request bit to “1” before
the STP instruction stops the oscillator. When the oscillator is restarted by reset, apply “L” level to the RESET pin until the
oscillation is stable since a wait time will not be generated.
The internal power supply circuit is changed to low power consumption mode for consumption current reduction at the time of
STP instruction execution.
Although an internal power supply circuit is usually changed to the
normal operation mode at the time of the return from an STP instruction, since a certain time is required to start the power supply
to the flash memory and operation of flash memory to be enabled,
set wait time 100 µs or more by the oscillation stabilization time
set function after release of the STP instruction which used the
timer 1.
(2) Wait mode
If the WIT instruction is executed, the internal clock φ stops at an
“H” level, but the oscillator does not stop. The internal clock φ restarts when an interrupt is received. Since the oscillator does not
stop, normal operation can be started immediately after the clock
is restarted.
■Note
•If you switch the mode between middle/high-speed and lowspeed, stabilize both XIN and XCIN oscillations. The sufficient time
is required for the sub clock to stabilize, especially immediately
after power on and at returning from stop mode. When switching
the mode between middle/high-speed and low-speed, set the frequency on condition that f(XIN) > 3f(XCIN).
•When using the quartz-crystal oscillator of high frequency, such
as 16 MHz etc., it may be necessary to select a specific oscillator
with the specification demanded.
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HARDWARE
3804 Group (Spec.H)
XCIN
XCOUT
FUNCTIONAL DESCRIPTION
XIN
XOUT
Rd (Note)
Rf
Rd
CCIN
CCOUT
CI N
COUT
Notes : Insert a damping resistor if required.
The resistance will vary depending on the oscillator and
the oscillation drive capacity setting.
Use the value recommended by the maker of the
oscillator.
Also, if the oscillator manufacturer's data sheet
specifies that a feedback resistor be added external to
the chip though a feedback resistor exists on-chip,
insert a feedback resistor between XIN and XOUT
following the instruction.
Fig. 73 Ceramic resonator circuit
XCIN
XCOUT
XIN
XOUT
Open
Open
External oscillation
circuit
External oscillation
circuit
VCC
VSS
VCC
VSS
Fig. 74 External clock input circuit
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
XCOUT
XCIN
“0”
“1”
Port XC
switch bit
XOUT
XIN
(Note 4)
Main clock division ratio
selection bits (Note 1)
Low-speed
mode
1/2
Divider
Prescaler 12
1/4
High-speed or
middle-speed
mode
(Note 3)
Timer 1
Reset or
STP instruction
(Note 2)
Main clock division ratio
selection bits (Note 1)
Middle-speed mode
Timing φ (internal clock)
High-speed or
low-speed mode
Main clock stop bit
Q
S
R
S Q
STP instruction
WIT instruction
R
Reset
Q S
R
STP instruction
Reset
Interrupt disable flag l
Interrupt request
Notes 1: Either high-speed, middle-speed or low-speed mode is selected by bits 7 and 6 of the CPU mode register.
When low-speed mode is selected, set port Xc switch bit (b4) to “1”.
2: f(XIN)/16 is supplied as the count source to the prescaler 12 at reset. The count source before executing the STP
instruction is supplied as the count source at executing STP instruction.
3: When bit 0 of MISRG is “0”, timer 1 is set “0116” and prescaler 12 is set “FF16” automatically. When bit 0 of MISRG is
“1”, set the appropriate value to them in accordance with oscillation stablizing time required by the using oscillator
because nothing is automatically set into timer 1 and prescaler 12.
4: Although a feed-back resistor exists on-chip, an external feed-back resistor may be needed depending on conditions.
Fig. 75 System clock generating circuit block diagram
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
Reset
C
“0 M4
CM ”←
“1 6 →“
1”
”←
→
“0
”
”
“0
→
CM ”←
0”
“1 M6 →“
C ”←
“1
4
CM7=0
CM6=0
CM5=0(8 MHz oscillating)
CM4=0(32 kHz stopped)
CM6
“1”←→“0”
C
“0 M7
CM ”←→
“1 6
“1
”←
”
→
“0
”
C M4
“1”←→“0”
C M4
“1”←→“0”
CM7=0
CM6=1
CM5=0(8 MHz oscillating)
CM4=0(32 kHz stopped)
Middle-speed mode
(f(φ)=1 MHz)
CM7=0
CM6=1
CM5=0(8 MHz oscillating)
CM4=1(32 kHz oscillating)
High-speed mode
(f(φ)=4 MHz)
C M6
“1”←→“0”
High-speed mode
(f(φ)=4 MHz)
CM7=0
CM6=0
CM5=0(8 MHz oscillating)
CM4=1(32 kHz oscillating)
C M7
“1”←→“0”
Middle-speed mode
(f(φ)=1 MHz)
Low-speed mode
(f(φ)=16 kHz)
C M5
“1”←→“0”
CM7=1
CM6=0
CM5=0(8 MHz oscillating)
CM4=1(32 kHz oscillating)
Low-speed mode
(f(φ)=16 kHz)
CM7=1
CM6=0
CM5=1(8 MHz stopped)
CM4=1(32 kHz oscillating)
b7
b4
CPU mode register
(CPUM : address 003B16)
CM4 : Port Xc switch bit
0 : I/O port function (stop oscillating)
1 : XCIN-XCOUT oscillating function
CM5 : Main clock (XIN- XOUT) stop bit
0 : Operating
1 : Stopped
CM7, CM6: Main clock division ratio selection bit
b7 b6
0 0 : φ = f(XIN)/2 ( High-speed mode)
0 1 : φ = f(XIN)/8 (Middle-speed mode)
1 0 : φ = f(XCIN)/2 (Low-speed mode)
1 1 : Not available
Notes 1 : Switch the mode by the allows shown between the mode blocks. (Do not switch between the modes directly without an allow.)
2 : The all modes can be switched to the stop mode or the wait mode and return to the source mode when the stop mode or the wait mode is
ended.
3 : Timer operates in the wait mode.
4 : When the stop mode is ended, a delay of approximately 1 ms occurs by connecting prescaler 12 and Timer 1 in middle/high-speed mode.
5 : When the stop mode is ended, a delay of approximately 0.25 s occurs by Timer 1 and Timer 2 in low-speed mode.
6 : Wait until oscillation stabilizes after oscillating the main clock XIN before the switching from the low-speed mode to middle/high-speed
mode.
7 : The example assumes that 8 MHz is being applied to the XIN pin and 32 kHz to the XCIN pin. φ indicates the internal clock.
Fig. 76 State transitions of system clock
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
FLASH MEMORY MODE
The 3804 group (spec. H) has the flash memory that can be rewritten with a single power source.
For this flash memory, three flash memory modes are available in
which to read, program, and erase: the parallel I/O and standard
serial I/O modes in which the flash memory can be manipulated
using a programmer and the CPU rewrite mode in which the flash
memory can be manipulated by the Central Processing Unit
(CPU).
This flash memory has some blocks on it as shown in Figure 77
and each block can be erased.
In addition to the ordinary User ROM area to store the MCU operation control program, the flash memory has a Boot ROM area
that is used to store a program to control rewriting in CPU rewrite
and standard serial I/O modes. This Boot ROM area has had a
standard serial I/O mode control program stored in it when
shipped from the factory. However, the user can write a rewrite
control program in this area that suits the user’s application system. This Boot ROM area can be rewritten in only parallel I/O
mode.
● Summary
Table 13 lists the summary of the 3804 Group (spec. H).
Table 13 Summary of 3804 group (spec. H)
Item
Power source voltage (Vcc)
Program/Erase VPP voltage (VPP)
Flash memory mode
Erase block division
User ROM area/Data ROM area
Boot ROM area (Note)
Program method
Erase method
Program/Erase control method
Number of commands
Number of program/Erase times
ROM code protection
Specifications
VCC = 2.7 to 5.5 V
VCC = 2.7 to 5.5 V
3 modes; Parallel I/O mode, Standard serial I/O mode, CPU rewrite mode
Refer to Fig. 77.
Not divided (4K bytes)
In units of bytes
Block erase
Program/Erase control by software command
5 commands
100
Available in parallel I/O mode and standard serial I/O mode
Note: The Boot ROM area has had a standard serial I/O mode control program stored in it when shipped from the factory.
This Boot ROM area can be erased and written in only parallel I/O mode.
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3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
● Boot Mode
● CPU Rewrite Mode
The control program for CPU rewrite mode must be written into
the User ROM or Boot ROM area in parallel I/O mode beforehand.
(If the control program is written into the Boot ROM area, the standard serial I/O mode becomes unusable.)
See Figure 77 for details about the Boot ROM area.
Normal microcomputer mode is entered when the microcomputer
is reset with pulling CNV SS pin low. In this case, the CPU starts
operating using the control program in the User ROM area.
When the microcomputer is reset and the CNV SS pin high after
pulling the P45/TxD1 pin and CNVss pin high, the CPU starts operating (start address of program is stored into addresses FFFC16
and FFFD16 ) using the control program in the Boot ROM area.
This mode is called the “Boot mode”. Also, User ROM area can be
rewritten using the control program in the Boot ROM area.
In CPU rewrite mode, the internal flash memory can be operated
on (read, program, or erase) under control of the Central Processing Unit (CPU).
In CPU rewrite mode, only the User ROM area shown in Figure 77
can be rewritten; the Boot ROM area cannot be rewritten. Make
sure the program and block erase commands are issued for only
the User ROM area and each block area.
The control program for CPU rewrite mode can be stored in either
User ROM or Boot ROM area. In the CPU rewrite mode, because
the flash memory cannot be read from the CPU, the rewrite control program must be transferred to internal RAM area before it
can be executed.
● Block Address
Block addresses refer to the maximum address of each block.
These addresses are used in the block erase command.
000016
SFR area
004016
180016
Internal RAM area
(2K bytes)
RAM
100016
User ROM area
Data block B:
2K bytes
Data block A:
2K bytes
200016
083F16
Block 3: 24K bytes
800016
0FE016
Block 2: 16K bytes
SFR area
0FFF16
100016
C00016
Notes 1: The boot ROM area can be rewritten in a parallel I/O mode. (Access to except boot ROM
area is disablrd.)
2: To specify a block, use the maximum address
in the block.
Block 1: 8 K bytes
Internal flash memory area
(60K bytes)
F00016
E00016
Boot ROM area
4K bytes
Block 0: 8 K bytes
FFFF16
FFFF16
FFFF16
Fig. 77 Block diagram of built-in flash memory
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HARDWARE
3804 Group (Spec.H)
●Outline Performance
CPU rewrite mode is usable in the single-chip or Boot mode. The
only User ROM area can be rewritten.
In CPU rewrite mode, the CPU erases, programs and reads the internal flash memory as instructed by software commands. This
rewrite control program must be transferred to internal RAM area
before it can be executed.
The MCU enters CPU rewrite mode by setting “1” to the CPU rewrite mode select bit (bit 1 of address 0FE0 16). Then, software
commands can be accepted.
Use software commands to control program and erase operations.
Whether a program or erase operation has terminated normally or
in error can be verified by reading the status register.
Figure 78 shows the flash memory control register 0.
Bit 0 of the flash memory control register 0 is the RY/BY status
flag used exclusively to read the operating status of the flash
memory. During programming and erase operations, it is “0”
(busy). Otherwise, it is “1” (ready).
Bit 1 of the flash memory control register 0 is the CPU rewrite
mode select bit. When this bit is set to “1”, the MCU enters CPU
rewrite mode. And then, software commands can be accepted. In
CPU rewrite mode, the CPU becomes unable to access the internal flash memory directly. Therefore, use the control program in
the internal RAM for write to bit 1. To set this bit 1 to “1”, it is necessary to write “0” and then write “1” in succession to bit 1. The bit
can be set to “0” by only writing “0”.
Bit 2 of the flash memory control register 0 is the 8 KB user block
E/W enable bit. By setting combination of bit 4 of the flash memory
control register 2 and this bit as shown in Table 14, E/W is disabled to user block in the CPU rewriting mode.
Bit 3 of the flash memory control register 0 is the flash memory reset bit used to reset the control circuit of internal flash memory.
This bit is used when flash memory access has failed. When the
CPU rewrite mode select bit is “1”, setting “1” for this bit resets the
control circuit. To release the reset, it is necessary to set this bit to
“0”.
Bit 5 of the flash memory control register 0 is the User ROM area
select bit and is valid only in the boot mode. Setting this bit to “1”
in the boot mode switches an accessible area from the boot ROM
area to the user ROM area. To use the CPU rewrite mode in the
boot mode, set this bit to “1”. To rewrite bit 5, execute the useroriginal reprogramming control software transferred to the internal
RAM in advance.
Bit 6 of the flash memory control register 0 is the program status
flag. This bit is set to “1” when writing to flash memory is failed.
When program error occurs, the block cannot be used.
Bit 7 of the flash memory control register 0 is the erase status flag.
This bit is set to “1” when erasing flash memory is failed. When
erase error occurs, the block cannot be used.
Figure 79 shows the flash memory control register 1.
Bit 0 of the flash memory control register 1 is the Erase suspend
enable bit. By setting this bit to “1”, the erase suspend mode to
suspend erase processing temporaly when block erase command
is executed can be used. In order to set this bit to “1”, writing “0”
and “1” in succession to bit 0. In order to set this bit to “0”, write “0”
only to bit 0.
Bit 1 of the flash memory control register 1 is the erase suspend
request bit. By setting this bit to “1” when erase suspend enable
bit is “1”, the erase processing is suspended.
Bit 6 of the flash memory control register 1 is the erase suspend
flag. This bit is cleared to “0” at the flash erasing.
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FUNCTIONAL DESCRIPTION
b7
b0
Flash memory control register 0
(FMCR0: address : 0FE016: initial value: 0116)
RY/BY status flag
0 : Busy (being written or erased)
1 : Ready
CPU rewrite mode select bit (Note 1)
0 : CPU rewrite mode invalid
1 : CPU rewrite mode valid
8KB user block E/W enable bit (Notes 1, 2)
0 : E/W disabled
1 : E/W enabled
Flash memory reset bit (Notes 3, 4)
0 : Normal operation
1 : reset
Not used (do not write “1” to this bit.)
User ROM area select bit (Note 5)
0 : Boot ROM area is accessed
1 : User ROM area is accessed
Program status flag
0: Pass
1: Error
Erase status flag
0: Pass
1: Error
Notes 1: For this bit to be set to “1”, the user needs to write a “0” and then a
“1” to it in succession. For this bit to be set to “0”, write “0” only to
this bit.
2: This bit can be written only when CPU rewrite mode select bit is “1”.
3: Effective only when the CPU rewrite mode select bit = “1”. Fix this
bit to “0” when the CPU rewrite mode select bit is “0”.
4: When setting this bit to “1” (when the control circuit of flash memory
is reset), the flash memory cannot be accessed for 10 µs.
5: Write to this bit in program on RAM
Fig. 78 Structure of flash memory control register 0
b7
b0
Flash memory control register 1
(FMCR1: address : 0FE116: initial value: 4016)
Erase Suspend enble bit (Notes 1)
0 : Suspend invalid
1 : Suspend valid
Erase Suspend request bit (Notes 2)
0 : Erase restart
1 : Suspend request
Not used (do not write “1” to this bit.)
Erase Suspend flag
0 : Erase active
1 : Erase inactive (Erase Suspend mode)
Not used (do not write “1” to this bit.)
Notes 1: For this bit to be set to “1”, the user needs to write a “0” and then a
“1” to it in succession. For this bit to be set to “0”, write “0” only to
this bit.
2: Effective only when the suspend enable bit = “1”.
Fig. 79 Structure of flash memory control register 1
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HARDWARE
3804 Group (Spec.H)
b7
FUNCTIONAL DESCRIPTION
b0
Flash memory control register 2
(FMCR2: address : 0FE216: initial value: 4516)
Not used
Not used (do not write “1” to this bit.)
Not used
All user block E/W enable bit (Notes 1, 2)
0 : E/W disabled
1 : E/W enabled
Not used
Notes 1: For this bit to be set to “1”, the user needs to write a “0” and then a
“1” to it in succession. For this bit to be set to “0”, write “0” only to
this bit.
2: Effective only when the CPU rewrite mode select bit = “1”.
Fig. 80 Structure of flash memory control register 2
Table 14 State of E/W inhibition function
All user block E/W
enable bit
0
0
1
1
8 KB user block E/W
enable bit
0
1
0
1
8 KB ✕ 2 block
16 KB + 24 KB block
Data block
Addresses C00016 to FFFF16 Addresses 200016 to BFFF16 Addresses 100016 to 1FFF16
E/W disabled
E/W disabled
E/W enabled
E/W disabled
E/W disabled
E/W enabled
E/W disabled
E/W enabled
E/W enabled
E/W enabled
E/W enabled
E/W enabled
Figure 81 shows a flowchart for setting/releasing CPU rewrite
mode.
Start
Single-chip mode or Boot mode
Set CPU mode register (Note 1)
Transfer CPU rewrite mode control program to
internal RAM
Jump to control program transferred to internal
RA M
(Subsequent operations are executed by control
program in this RAM)
Set CPU rewrite mode select bit to “1” (by
writing “0” and then “1” in succession)
Set all user block E/W enable bit to “1”
(by writing “0” and then “1” in succession)
Set 8 KB user block E/W enable bit
(At E/W disabled; writing “0”, at E/W enabled;
writing “0” and then “1” in succession)
Using software command executes erase,
program, or other operation
Execute read array command (Note 2)
Set all user block E/W enable bit to “0”
Set 8 KB user block E/W enable bit to “0”
Write “0” to CPU rewrite mode select bit
End
Notes 1: Set the main clock as follows depending on the clock division ratio selection bits of CPU
mode register (bits 6, 7 of address 003B16).
2: Before exiting the CPU rewrite mode after completing erase or program operation, always
be sure to execute the read array command.
Fig. 81 CPU rewrite mode set/release flowchart
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FUNCTIONAL DESCRIPTION
■ Notes on CPU Rewrite Mode
Take the notes described below when rewriting the flash memory
in CPU rewrite mode.
●Operation speed
During CPU rewrite mode, set the system clock φ to 4.0 MHz or
less using the clock division ratio selection bits (bits 6 and 7 of address 003B16).
●Instructions inhibited against use
The instructions which refer to the internal data of the flash
memory cannot be used during CPU rewrite mode.
●Interrupts
The interrupts cannot be used during CPU rewrite mode because
they refer to the internal data of the flash memory.
●Watchdog timer
If the watchdog timer has been already activated, internal reset
due to an underflow will not occur because the watchdog timer is
surely cleared during program or erase.
●Reset
Reset is always valid. The MCU is activated using the boot mode
at release of reset in the condition of CNVss = “H”, so that the program will begin at the address which is stored in addresses
FFFC16 and FFFD16 of the boot ROM area.
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FUNCTIONAL DESCRIPTION
● Software Commands
Table 15 lists the software commands.
After setting the CPU rewrite mode select bit to “1”, execute a software command to specify an erase or program operation.
Each software command is explained below.
The RY/BY status flag of the flash memory control register is “0”
during write operation and “1” when the write operation is completed as is the status register bit 7.
At program end, program results can be checked by reading the
status register.
• Read Array Command (FF16)
The read array mode is entered by writing the command code
“FF16” in the first bus cycle. When an address to be read is input
in one of the bus cycles that follow, the contents of the specified
address are read out at the data bus (D0 to D7).
The read array mode is retained until another command is written.
Start
Write “4016”
• Read Status Register Command (7016)
When the command code “7016” is written in the first bus cycle,
the contents of the status register are read out at the data bus (D0
to D7) by a read in the second bus cycle.
The status register is explained in the next section.
Write Write address
Write data
Read status register
• Clear Status Register Command (5016)
This command is used to clear the bits SR4 and SR5 of the status
register after they have been set. These bits indicate that operation has ended in an error. To use this command, write the
command code “5016” in the first bus cycle.
• Program Command (4016)
Program operation starts when the command code “4016” is written in the first bus cycle. Then, if the address and data to program
are written in the 2nd bus cycle, program operation (data programming and verification) will start.
Whether the write operation is completed can be confirmed by
_____
read status register or the RY/BY status flag. When the program
starts, the read status register mode is entered automatically and
the contents of the status register is read at the data bus (D0 to
D7). The status register bit 7 (SR7) is set to “0” at the same time
the write operation starts and is returned to “1” upon completion of
the write operation. In this case, the read status register mode remains active until the read array command (FF16) is written.
SR7 = “1”?
or
RY/BY = “1” ?
NO
YES
NO
SR4 = “0”?
Program
error
YES
Program
completed
Fig. 82 Program flowchart
Table 15 List of software commands (CPU rewrite mode)
Command
Cycle number
Mode
First bus cycle
Data
Address
(D0 to D7)
X
Second bus cycle
Mode
Address
Data
(D0 to D7)
Read
X
SRD (Note 1)
F F1 6
Read array
1
Write
Read status register
2
Write
X
7016
Clear status register
1
Write
X
5016
Program
2
Write
X
4016
Write
WA (Note 2)
Block erase
2
Write
X
2016
Write
BA
(Note 4)
(Note 3)
WD (Note 2)
D016
Notes 1: SRD = Status Register Data
2: WA = Write Address, WD = Write Data
3: BA = Block Address to be erased (Input the maximum address of each block.)
4: X denotes a given address in the User ROM area.
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• Block Erase Command (2016/D016)
By writing the command code “2016” in the first bus cycle and the
confirmation command code “D016” and the block address in the
second bus cycle that follows, the block erase (erase and erase
verify) operation starts for the block address of the flash memory
to be specified.
Whether the block erase operation is completed can be confirmed
by read status register or the RY/BY status flag of flash memory
control register. At the same time the block erase operation starts,
the read status register mode is automatically entered, so that the
contents of the status register can be read out. The status register
bit 7 (SR7) is set to “0” at the same time the block erase operation
starts and is returned to “1” upon completion of the block erase
operation. In this case, the read status register mode remains active until the read array command (FF16) is written.
The RY/BY status flag is “0” during block erase operation and “1”
when the block erase operation is completed as is the status register bit 7.
After the block erase ends, erase results can be checked by reading the status register. For details, refer to the section where the
status register is detailed.
FUNCTIONAL DESCRIPTION
Start
Write “2016”
Write
“D016”
Block address
Read status register
SR7 = “1”?
or
RY/BY = “1”?
NO
YES
SR5 = “0” ?
NO
Erase error
YES
Erase completed
(write read command
“FF16”)
Fig. 83 Erase flowchart
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FUNCTIONAL DESCRIPTION
● Status Register
•Erase status (SR5)
The erase status indicates the operating status of erase operation.
If an erase error occurs, it is set to “1”. When the erase status is
cleared, it is reset to “0”.
The status register shows the operating status of the flash
memory and whether erase operations and programs ended successfully or in error. It can be read in the following ways:
(1) By reading an arbitrary address from the User ROM area after
writing the read status register command (7016)
(2) By reading an arbitrary address from the User ROM area in the
period from when the program starts or erase operation starts
to when the read array command (FF16) is input.
Also, the status register can be cleared by writing the clear status
register command (5016).
After reset, the status register is set to “8016”.
Table 16 shows the status register. Each bit in this register is explained below.
•Program status (SR4)
The program status indicates the operating status of write operation. When a write error occurs, it is set to “1”.
The program status is reset to “0” when it is cleared.
If “1” is written for any of the SR5 and SR4 bits, the read array,
program, and block erase commands are not accepted. Before executing these commands, execute the clear status register
command (5016) and clear the status register.
Also, if any commands are not correct, both SR5 and SR4 are set
to “1”.
•Sequencer status (SR7)
The sequencer status indicates the operating status of the flash
memory. This bit is set to “0” (busy) during write or erase operation
and is set to “1” when these operations ends.
After power-on, the sequencer status is set to “1” (ready).
Table 16 Definition of each bit in status register
Each bit of
SRD bits
Status name
Definition
“1”
“0”
Ready
-
Busy
-
Terminated in error
Terminated in error
Terminated normally
Terminated normally
SR7 (bit7)
SR6 (bit6)
Sequencer status
Reserved
SR5 (bit5)
SR4 (bit4)
Erase status
Program status
SR3 (bit3)
SR2 (bit2)
Reserved
Reserved
-
-
SR1 (bit1)
SR0 (bit0)
Reserved
Reserved
-
-
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FUNCTIONAL DESCRIPTION
● Full Status Check
By performing full status check, it is possible to know the execution results of erase and program operations. Figure 84 shows a
full status check flowchart and the action to be taken when each
error occurs.
Read status register
SR4 = “1” and
SR5 = “1” ?
YES
Command
sequence error
NO
SR5 = “0” ?
NO
Erase error
Execute the clear status register command (5016)
to clear the status register. Try performing the
operation one more time after confirming that the
command is entered correctly.
Should an erase error occur, the block in error
cannot be used.
YES
SR4 = “0” ?
NO
Program error
Should a program error occur, the block in error
cannot be used.
YES
End (block erase, program)
Note: When one of SR5 and SR4 is set to “1”, none of the read array, program,
and block erase commands is accepted. Execute the clear status register
command (5016) before executing these commands.
Fig. 84 Full status check flowchart and remedial procedure for errors
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3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
● Functions To Inhibit Rewriting Flash
Memory Version
To prevent the contents of internal flash memory from being read
out or rewritten easily, this MCU incorporates a ROM code protect
function for use in parallel I/O mode and an ID code check function for use in standard serial I/O mode.
(1) ROM Code Protect Function
The ROM code protect function is the function to inhibit reading
out or modifying the contents of internal flash memory by using
the ROM code protect control address (address FFDB16) in parallel I/O mode. Figure 85 shows the ROM code protect control
address (address FFDB16). (This address exists in the User ROM
area.)
b7
If one or both of the pair of ROM code protect bits is set to “0”, the
ROM code protect is turned on, so that the contents of internal
flash memory are protected against readout and modification. The
ROM code protect is implemented in two levels. If level 2 is selected, the flash memory is protected even against readout by a
shipment inspection LSI tester, etc. When an attempt is made to
select both level 1 and level 2, level 2 is selected by default.
If both of the two ROM code protect reset bits are set to “00”, the
ROM code protect is turned off, so that the contents of internal
flash memory can be readout or modified. Once the ROM code
protect is turned on, the contents of the ROM code protect reset
bits cannot be modified in parallel I/O mode. Use the serial I/O or
CPU rewrite mode to rewrite the contents of the ROM code protect
reset bits.
Rewriting of only the ROM code protect control address (address
FFDB16) cannot be performed. When rewriting the ROM code protect reset bit, rewrite the whole user ROM area (block 0)
containing the ROM code protect control address.
b0
ROM code protect control address (address FFDB16)
1 1 ROMCP (FF16 when shipped)
Reserved bits (“1” at read/write)
ROM code protect level 2 set bits (ROMCP2) (Notes 1, 2)
b3b2
0 0: Protect enabled
0 1: Protect enabled
1 0: Protect enabled
1 1: Protect disabled
ROM code protect reset bits (ROMCR) (Note 3)
b5b4
0 0: Protect removed
0 1: Protect set bits effective
1 0: Protect set bits effective
1 1: Protect set bits effective
ROM code protect level 1 set bits (ROMCP1) (Note 1)
b7b6
0 0: Protect enabled
0 1: Protect enabled
1 0: Protect enabled
1 1: Protect disabled
Notes 1: When ROM code protect is turned on, the internal flash memory is protected
against readout or modification in parallel I/O mode.
2: When ROM code protect level 2 is turned on, ROM code readout by a shipment
inspection LSI tester, etc. also is inhibited.
3: The ROM code protect reset bits can be used to turn off ROM code protect level 1
and ROM code protect level 2. However, since these bits cannot be modified in
parallel I/O mode, they need to be rewritten in serial I/O mode or CPU rewrite
mode.
Fig. 85 Structure of ROM code protect control address
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FUNCTIONAL DESCRIPTION
(2) ID Code Check Function
Use this function in standard serial I/O mode. When the contents
of the flash memory are not blank, the ID code sent from the programmer is compared with the ID code written in the flash memory
to see if they match. If the ID codes do not match, the commands
sent from the programmer are not accepted. The ID code consists
of 8-bit data, and its areas are FFD4 16 to FFDA16. Write a program which has had the ID code preset at these addresses to the
flash memory.
Address
FFD416
ID1
FFD516
ID2
FFD616
ID3
FFD716
ID4
FFD816
ID5
FFD916
ID6
FFDA16
ID7
FFDB16
ROM code protect control
Interrupt vector area
Fig. 86 ID code store addresses
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FUNCTIONAL DESCRIPTION
● Parallel I/O Mode
The parallel I/O mode is used to input/output software commands,
address and data in parallel for operation (read, program and
erase) to internal flash memory.
Use the external device (writer) only for 3804 Group (spec. H). For
details, refer to the user’s manual of each writer manufacturer.
• User ROM and Boot ROM Areas
In parallel I/O mode, the User ROM and Boot ROM areas shown
in Figure 77 can be rewritten. Both areas of flash memory can be
operated on in the same way.
The Boot ROM area is 4 Kbytes in size and located at addresses
F00016 through FFFF16. Make sure program and block erase operations are always performed within this address range. (Access
to any location outside this address range is prohibited.)
In the Boot ROM area, an erase block operation is applied to only
one 4 Kbyte block. The boot ROM area has had a standard serial
I/O mode control program stored in it when shipped from the fac-tory.
Therefore, using the MCU in standard serial I/O mode, do not
rewrite to the Boot ROM area.
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FUNCTIONAL DESCRIPTION
● Standard serial I/O Mode
The standard serial I/O mode inputs and outputs the software
commands, addresses and data needed to operate (read, program, erase, etc.) the internal flash memory. This I/O is clock
synchronized serial. This mode requires a purpose-specific peripheral unit.
The standard serial I/O mode is different from the parallel I/O
mode in that the CPU controls flash memory rewrite (uses the
CPU rewrite mode), rewrite data input and so forth. The standard
serial I/O mode is started by connecting “H” to the CNVss pin and
“H” to the P45 (BOOTENT) pin, and releasing the reset operation.
(In the ordinary microcomputer mode, set CNVss pin to “L” level.)
This control program is written in the Boot ROM area when the
product is shipped from Renesas. Accordingly, make note of the
fact that the standard serial I/O mode cannot be used if the Boot
ROM area is rewritten in parallel I/O mode. The standard serial I/
O mode has standard serial I/O mode 1 of the clock synchronous
serial and standard serial I/O mode 2 of the clock asynchronous
serial. Tables 17 and 18 show description of pin function (standard
serial I/O mode). Figures 87 to 90 show the pin connections for
the standard serial I/O mode.
In standard serial I/O mode, only the User ROM area shown in
Figure 77 can be rewritten. The Boot ROM area cannot be written.
In standard serial I/O mode, a 7-byte ID code is used. When there
is data in the flash memory, this function determines whether the
ID code sent from the peripheral unit (programmer) and those written in the flash memory match. The commands sent from the
peripheral unit (programmer) are not accepted unless the ID code
matches.
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FUNCTIONAL DESCRIPTION
Table 17 Description of pin function (Flash Memory Serial I/O Mode 1)
Pin name
VCC,VSS
CNVSS
RESET
Signal name
Power supply
CNVSS
Reset input
I/O
I
I
I
XIN
XOUT
AVSS
Clock input
Clock output
I
O
Analog power supply input
Reference voltage input
I/O port
I
I/O
Function
Apply 2.7 to 5.5 V to the Vcc pin and 0 V to the Vss pin.
After input of port is set, input “H” level.
Reset input pin. To reset the microcomputer, RESET pin should be held at an
“L” level for 16 cycles or more of XIN.
Connect an oscillation circuit between the XIN and XOUT pins.
As for the connection method, refer to the “clock generating circuit”.
Connect AVss to Vss.
Apply reference voltage of A/D to this pin.
Input “L” or “H” level, or keep open.
RxD input
TxD output
SCLK input
BUSY output
I
O
I
O
Serial data input pin.
Serial data output pin.
Serial clock input pin.
BUSY signal output pin.
VREF
P00–P07,P10–P17,
P20–P27,P30–P37,
P40–P43,P50–P57,
P60–P67
P44
P45
P46
P47
Table 18 Description of pin function (Flash Memory Serial I/O Mode 2)
Pin name
VCC,VSS
CNVSS
RESET
Signal name
Power supply
CNVSS
Reset input
I/O
I
I
I
XIN
XOUT
AVss
VREF
P00–P07,P10–P17,
P20–P27,P30–P37,
P40–P43,P50–P57,
P60–P67
P44
P45
P46
P47
Clock input
Clock output
Analog power supply input
Reference voltage input
I/O port
I
O
I
I/O
Function
Apply 2.7 to 5.5 V to the Vcc pin and 0 V to the Vss pin.
After input of port is set, input “H” level.
Reset input pin. To reset the microcomputer, RESET pin should be held at an
“L” level for 16 cycles or more of XIN.
Connect an oscillation circuit between the XIN and XOUT pins.
As for the connection method, refer to the “clock generating circuit”.
Connect AVss to Vss.
Apply reference voltage of A/D to this pin.
Input “L” or “H” level, or keep open.
RxD input
TxD output
SCLK input
BUSY output
I
O
I
O
Serial data input pin.
Serial data output pin.
Input “L” level.
BUSY signal output pin.
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P07/AN15
P10/INT41
P11/INT01
P12
P13
P14
P15
P16
P17
39
38
37
36
35
34
33
P06/AN14
42
40
P05/AN13
43
41
P03/AN11
P04/AN12
44
P02/AN10
46
45
P00/AN8
P01/AN9
48
47
P37/SRDY3
49
32
P36/SCLK3
50
31
P21(LED1)
P35/TXD3
51
30
P22(LED2)
P34/RXD3
52
29
P23(LED3)
P33/SCL
53
28
P24(LED4)
P32/SDA
54
27
P25(LED5)
P26(LED6)
P20(LED0)
P31/DA2
55
26
P30/DA1
56
25
P27(LED7)
VCC
57
24
VREF
58
23
VSS
XOUT
AVSS
59
22
XIN
M38049FFHFP/HP/KP
VSS
✽
P43/INT2
16
15
13
14
P45/TXD1
P44/RXD1
11
P50/SIN2
P46/SCLK1
10
P51/SOUT2
12
9
P52/SCLK2
✽ Connect oscillation circuit.
indicates flash memory pin.
P47/SRDY1/CNTR2
8
P53/SRDY2
P42/INT1
7
17
6
64
P54/CNTR0
CNVss
P63/AN3
P55/CNTR1
RESET
CNVSS
5
RESET
18
P56/PWM
19
63
4
62
P64/AN4
3
P65/AN5
P60/AN0
P41/INT00/XCIN
P57/INT3
P40/INT40/XCOUT
20
2
21
61
1
60
P62/AN2
P67/AN7
P66/AN6
P61/AN1
VCC
FUNCTIONAL DESCRIPTION
RxD
TxD
SCLK
BUSY
Package type: 64P6N-A/64P6Q-A/64P6U-A
Fig. 87 Connection for standard serial I/O mode 1 (M38049FFHFP/HP/KP)
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P11/INT01
P12
P13
P14
P15
P16
P17
39
38
37
36
35
34
33
P07/AN15
P10/INT41
P06/AN14
42
40
P05/AN13
43
41
P03/AN11
P04/AN12
44
P02/AN10
46
45
P00/AN8
P01/AN9
48
47
P37/SRDY3
49
32
P36/SCLK3
50
31
P21(LED1)
P35/TXD3
51
30
P22(LED2)
P34/RXD3
52
29
P23(LED3)
P33/SCL
53
28
P24(LED4)
P32/SDA
54
27
P25(LED5)
P26(LED6)
P20(LED0)
P31/DA2
55
26
P30/DA1
56
25
P27(LED7)
VCC
57
24
VREF
58
23
VSS
XOUT
AVSS
59
22
XIN
M38049FFHFP/HP/KP
VSS
✽
9
10
11
12
13
14
15
16
P51/SOUT2
P50/SIN2
P47/SRDY1/CNTR2
P46/SCLK1
P45/TXD1
P44/RXD1
P43/INT2
P55/CNTR1
✽ Connect oscillation circuit.
indicates flash memory pin.
P52/SCLK2
P42/INT1
8
17
P53/SRDY2
64
7
CNVss
P63/AN3
P54/CNTR0
RESET
CNVSS
5
6
RESET
18
P56/PWM
19
63
4
62
P64/AN4
3
P65/AN5
P60/AN0
P41/INT00/XCIN
P57/INT3
P40/INT40/XCOUT
20
2
21
61
1
60
P62/AN2
P67/AN7
P66/AN6
P61/AN1
VCC
FUNCTIONAL DESCRIPTION
RxD
TxD
“L” input
BUSY
Package type: 64P6N-A/64P6Q-A/64P6U-A
Fig. 88 Connection for standard serial I/O mode 2 (M38049FFHFP/HP/KP)
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
V CC
SCLK
T XD
R XD
CNVSS
RESET
VSS
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
✽ Connect oscillation circuit.
indicates flash memory pin.
M38049FFHSP
BUSY
VCC
VREF
AVSS
P67/AN7
P66/AN6
P65/AN5
P64/AN4
P63/AN3
P62/AN2
P61/AN1
P60/AN0
P57/INT3
P56/PWM
P55/CNTR1
P54/CNTR0
P53/SRDY2
P52/SCLK2
P51/SOUT2
P50/SIN2
P47/SRDY1/CNTR2
P46/SCLK1
P45/TXD1
P44/RXD1
P43/INT2
P42/INT1
CNVSS
RESET
P41/INT00/XCIN
P40/INT40/XCOUT
XIN
✽
XOUT
VSS
64
63
62
61
60
59
58
57
56
55
54
53
52
51
50
49
48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33
P30/DA1
P31/DA2
P32/SDA
P33/SCL
P34/RXD3
P35/TXD3
P36/SCLK3
P37/SRDY3
P00/AN8
P01/AN9
P02/AN10
P03/AN11
P04/AN12
P05/AN13
P06/AN14
P07/AN15
P10/INT41
P11/INT01
P12
P13
P14
P15
P16
P17
P20(LED0)
P21(LED1)
P22(LED2)
P23(LED3)
P24(LED4)
P25(LED5)
P26(LED6)
P27(LED7)
Package type: 64P4B
Fig. 89 Connection for standard serial I/O mode 1 (M38049FFHSP)
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HARDWARE
3804 Group (Spec.H)
V CC
“L” input
T XD
R XD
CNVSS
RESET
VSS
VCC
VREF
AVSS
P67/AN7
P66/AN6
P65/AN5
P64/AN4
P63/AN3
P62/AN2
P61/AN1
P60/AN0
P57/INT3
P56/PWM
P55/CNTR1
P54/CNTR0
P53/SRDY2
P52/SCLK2
P51/SOUT2
P50/SIN2
P47/SRDY1/CNTR2
P46/SCLK1
P45/TXD1
P44/RXD1
P43/INT2
P42/INT1
CNVSS
RESET
P41/INT00/XCIN
P40/INT40/XCOUT
XIN
✽
XOUT
VSS
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
✽ Connect oscillation circuit.
indicates flash memory pin.
M38049FFHSP
BUSY
FUNCTIONAL DESCRIPTION
64
63
62
61
60
59
58
57
56
55
54
53
52
51
50
49
48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33
P30/DA1
P31/DA2
P32/SDA
P33/SCL
P34/RXD3
P35/TXD3
P36/SCLK3
P37/SRDY3
P00/AN8
P01/AN9
P02/AN10
P03/AN11
P04/AN12
P05/AN13
P06/AN14
P07/AN15
P10/INT41
P11/INT01
P12
P13
P14
P15
P16
P17
P20(LED0)
P21(LED1)
P22(LED2)
P23(LED3)
P24(LED4)
P25(LED5)
P26(LED6)
P27(LED7)
Package type: 64P4B
Fig. 90 Connection for standard serial I/O mode 2 (M38049FFHSP)
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION
td(CNVSS-RESET)
td(P45-RESET)
Power source
RESET
CNVSS
P45(TXD)
P46(SCLK)
P47(BUSY)
P44(RXD)
Limits
Unit
Min. Typ. Max.
–
–
ms
0
ms
0
Symbol
td(CNVss-RESET)
td(P45-RESET)
Notes: In the standard serial I/O mode 1, input “H” to the P46 pin.
Be sure to set the CNVss pin to “H” before rising RESET.
Be sure to set the P45 pin to “H” before rising RESET.
Fig. 91 Operating waveform for standard serial I/O mode 1
td(CNVSS-RESET)
td(P45-RESET)
Power source
RESET
CNVSS
P45(TXD)
P46(SCLK)
P47(BUSY)
P44(RXD)
Symbol
td(CNVss-RESET)
td(P45-RESET)
Limits
Unit
Min. Typ. Max.
ms
–
–
0
ms
0
Notes: In the standard serial I/O mode 2, input “H” to the P46 pin.
Be sure to set the CNVss pin to “H” before rising RESET.
Be sure to set the P45 pin to “H” before rising RESET.
Fig. 92 Operating waveform for standard serial I/O mode 2
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HARDWARE
3804 Group (Spec.H)
NOTES ON PROGRAMMING
Processor Status Register
The contents of the processor status register (PS) after a reset are
undefined, except for the interrupt disable flag (I) which is “1.” After a reset, initialize flags which affect program execution. In
particular, it is essential to initialize the index X mode (T) and the
decimal mode (D) flags because of their effect on calculations.
Interrupts
The contents of the interrupt request bits do not change immediately after they have been written. After writing to an interrupt
request register, execute at least one instruction before performing a BBC or BBS instruction.
Decimal Calculations
• To calculate in decimal notation, set the decimal mode flag (D)
to “1”, then execute an ADC or SBC instruction. After executing
an ADC or SBC instruction, execute at least one instruction before executing a SEC, CLC, or CLD instruction.
• In decimal mode, the values of the negative (N), overflow (V),
and zero (Z) flags are invalid.
Timers
If a value n (between 0 and 255) is written to a timer latch, the frequency division ratio is 1/(n+1).
NOTES ON PROGRAMMING
Serial Interface
In clock synchronous serial I/O, if the receive side is using an external clock and it is to output the SRDY signal, set the transmit
enable bit, the receive enable bit, and the SRDY output enable bit
to “1.”
Serial I/O continues to output the final bit from the TXD pin after
transmission is completed. SOUT2 pin for serial I/O2 goes to high
impedance after transfer is completed.
When in serial I/Os 1 and 3 (clock-synchronous mode) or in serial
I/O2, an external clock is used as synchronous clock, write transmission data to the transmit buffer register or serial I/O2 register,
during transfer clock is “H.”
A/D Converter
The comparator uses capacitive coupling amplifier whose charge
will be lost if the clock frequency is too low.
Therefore, make sure that f(XIN) is at least on 500 kHz during an
A/D conversion.
Do not execute the STP instruction during an A/D conversion.
D/A Converter
The accuracy of the D/A converter becomes rapidly poor under
the VCC = 4.0 V or less condition; a supply voltage of VCC ≥ 4.0 V
is recommended. When a D/A converter is not used, set all values
of D/Ai conversion registers (i=1, 2) to “0016.”
Instruction Execution Time
Multiplication and Division Instructions
• The index X mode (T) and the decimal mode (D) flags do not affect the MUL and DIV instruction.
• The execution of these instructions does not change the contents of the processor status register.
Ports
The instruction execution time is obtained by multiplying the period of the internal clock φ by the number of cycles needed to
execute an instruction.
The number of cycles required to execute an instruction is shown
in the list of machine instructions.
The period of the internal clock φ is double of the XIN period in
high-speed mode.
The contents of the port direction registers cannot be read. The
following cannot be used:
• The data transfer instruction (LDA, etc.)
• The operation instruction when the index X mode flag (T) is “1”
• The instruction with the addressing mode which uses the value
of a direction register as an index
• The bit-test instruction (BBC or BBS, etc.) to a direction register
• The read-modify-write instructions (ROR, CLB, or SEB, etc.) to
a direction register.
Use instructions such as LDM and STA, etc., to set the port direction registers.
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HARDWARE
3804 Group (Spec.H)
NOTES ON USAGE
NOTES ON USAGE
Handling of Power Source Pins
In order to avoid a latch-up occurrence, connect a capacitor suitable for high frequencies as bypass capacitor between power
source pin (VCC pin) and GND pin (VSS pin), and between power
source pin (V CC pin) and analog power source input pin (AV SS
pin). Besides, connect the capacitor to as close as possible. For
bypass capacitor which should not be located too far from the pins
to be connected, a ceramic capacitor of 0.01 µF–0.1 µF is recommended.
Power Source Voltage
When the power source voltage value of a microcomputer is less
than the value which is indicated as the recommended operating
conditions, the microcomputer does not operate normally and may
perform unstable operation.
In a system where the power source voltage drops slowly when
the power source voltage drops or the power supply is turned off,
reset a microcomputer when the power source voltage is less than
the recommended operating conditions and design a system not
to cause errors to the system by this unstable operation.
Flash Memory Version
The CNVss pin determines the flash memory mode. To improve
the noise reduction, connect a track between CNVss pin and Vss
pin or Vcc pin with 1 to 10 kΩ resistance. The mask ROM version
track of CNVss pin has no operational interference even if it is
connected to Vss pin or Vcc pin via a resistor.
Electric Characteristic Differences Between
Mask ROM and Flash Memory Version MCUs
There are differences in electric characteristics, operation margin,
noise immunity, and noise radiation between Mask ROM and
Flash Memory version MCUs due to the difference in the manufacturing processes, built-in ROM, and layout pattern etc.When
manufacturing an application system with the Flash Memory version and then switching to use of the Mask ROM version, please
conduct evaluations equivalent to the system evaluations conducted for the flash memory version.
DATA REQUIRED FOR MASK ORDERS
The following are necessary when ordering a mask ROM production:
1.Mask ROM Confirmation Form ✽
2.Mark Specification Form ✽
3.Data to be written to ROM, in EPROM form (three identical copies)
✽ For the mask ROM confirmation and the mark specifications,
refer to the “Renesas Technology Corp.” Homepage
(http://www.renesas.com/en/rom).
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION SUPPLEMENT
FUNCTIONAL DESCRIPTION SUPPLEMENT
Interrupt
The 3804 group (Spec. H) permits interrupts on the basis of 16
sources. It is vector interrupts with a fixed priority system. Accordingly, when two or more interrupt requests occur during the same
sampling, the higher-priority interrupt is accepted first. This priority
is determined by hardware, but variety of priority processing can
be performed by software, using an interrupt enable bit and an interrupt disable flag.
For interrupt sources, vector addresses and interrupt priority, refer
to “Table 19”.
Table 19 Interrupt sources, vector addresses and priority
Interrupt Source
Priority
Reset (Note 2)
INT0
1
2
Timer Z
INT1
Serial I/O1
reception
Serial I/O1
transmission
Vector Addresses (Note 1)
Low
High
FFFC16
FFFD16
Non-maskable
External interrupt
(active edge selectable)
FFFA16
At detection of either rising or
falling edge of INT0 input
At timer Z underflow
3
FFF916
FFF816
At detection of either rising or
falling edge of INT1 input
4
FFF716
FFF616
At completion of serial I/O1 data
reception
5
FFF516
FFF416
At completion of serial I/O1
transmission shift or when
transmission buffer is empty
Valid when serial I/O1 is selected
At detection of either rising or
falling edge of SCL or SDA
At timer X underflow
External interrupt
(active edge selectable)
6
7
8
9
10
FFF316
FFF116
FFEF16
FFED16
FFEB16
FFF216
FFF016
FFEE16
FFEC16
FFEA16
SCL, SDA
CNTR1
At reset
Remarks
FFFB16
SCL, SDA
Timer X
Timer Y
Timer 1
Timer 2
CNTR0
Interrupt Request
Generating Conditions
11
FFE916
FFE816
At timer Y underflow
At timer 1 underflow
12
FFE716
FFE616
Timer Z
INT2
13
FFE516
FFE416
I 2C
INT3
14
FFE316
FFE216
INT4
15
FFE116
FFE016
STP release timer underflow
At timer 2 underflow
At detection of either rising or
falling edge of CNTR0 input
At detection of either rising or
falling edge of SCL or SDA
At detection of either rising or
falling edge of CNTR1 input
At completion of serial I/O3 data
reception
Serial I/O3
reception
Serial I/O2
External interrupt
(active edge selectable)
Valid when serial I/O1 is selected
At completion of serial I/O2 data
transmission or reception
External interrupt
(active edge selectable)
External interrupt
(active edge selectable)
External interrupt
(active edge selectable)
Valid when serial I/O3 is selected
Valid when serial I/O2 is selected
At timer Z underflow
At detection of either rising or
falling edge of INT2 input
At completion of data transfer
At detection of either rising or
falling edge of INT3 input
At detection of either rising or
falling edge of INT4 input
At detection of either rising or
falling edge of CNTR2 input
CNTR2
A/D converter
Serial I/O3
transmission
16
BRK instruction
17
FFDF16
FFDD16
FFDE16
FFDC16
External interrupt
(active edge selectable)
External interrupt
(active edge selectable)
External interrupt
(active edge selectable)
External interrupt
(active edge selectable)
At completion of A/D conversion
At completion of serial I/O3
transmission shift or when
transmission buffer is empty
Valid when serial I/O3 is selected
At BRK instruction execution
Non-maskable software interrupt
Notes 1: Vector addresses contain interrupt jump destination addresses.
2: Reset function in the same way as an interrupt with the highest priority.
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION SUPPLEMENT
Timing After Interrupt
The interrupt processing routine begins with the machine cycle following the completion of the instruction that is currently in
execution.
Figure 93 shows a timing chart after an interrupt occurs, and Figure 94 shows the time up to execution of the interrupt processing
routine.
φ
SYNC
RD
WR
Address bus
Data bus
PC
S, SPS
Not used
S-1, SPS S-2, SPS
PCH
PCL
BH
BL
PS
AL
AL, AH
AH
SYNC : CPU operation code fetch cycle
(This is an internal signal that cannot be observed from the external unit.)
BL, BH : Vector address of each interrupt
AL, AH : Jump destination address of each interrupt
SPS : “0016” or “0116”
Fig. 93 Timing chart after an interrupt occurs
Interrupt request generated
Main routine
0 to 16 cycles
Start of interrupt processing
Waiting time for Stack push and
post-processing Vector fetch
of pipeline
2 cycles
Interrupt processing routine
5 cycles
7 to 23 cycles
(When f(XIN) = 8.4 MHz, 0.83 µs to 2.74 µs)
Fig. 94 Time up to execution of the interrupt processing routine
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION SUPPLEMENT
A/D Converter
By repeating the above operations up to the lowest-order bit of the
AD conversion register, an analog value converts into a digital
value.
In the 10-bit A/D mode, A/D conversion completes at 61 cycles of
2tc(XIN)* (15.25 µs at f(XIN) = 8.0 MHz) after it is started. In the 8bit A/D mode, A/D conversion completes at 50 cycles of 2tc(XIN)
(12.5 µs at f(XIN) = 8.0 MHz) after it is started. And the result of
the conversion is stored into the AD conversion register.
Concurrently with the completion of A/D conversion, the A/D conversion completion bit is set to “1” and an A/D conversion interrupt
request occurs, so that the AD conversion interrupt request bit is
set to “1”.
* tc(XIN) = Main clock input cycle time
A/D conversion is started by setting AD conversion completion bit
to “0”. During A/D conversion, internal operations are performed
as follows.
1. After the start of A/D conversion, AD conversion register
goes to “00 16”.
2. The highest-order bit of AD conversion register is set to
“1”. and the comparison voltage Vref is input to the
comparator. Then, Vref is compared with analog input voltage
VIN.
3. As a result of comparison, when Vref < V IN, the highestorder bit of AD conversion register becomes “1.” When
Vref > VIN, the highest-order bit becomes “0.”
Table 20 Relative formula for a reference voltage VREF of A/D converter and Vref (at 10-bit A/D mode)
When n = 0
Vref = 0
When n = 1 to 1023
Vref =
VREF
1024
✕n
n : Value of A/D converter (decimal numeral)
Table 21 Relative formula for a reference voltage VREF of A/D converter and Vref (at 8-bit A/D mode)
When n = 0
Vref = 0
When n = 1 to 255
Vref =
VREF
256
✕ (n – 0.5)
n : Value of A/D converter (decimal numeral)
Table 22 Change of AD conversion register during A/D conversion (at 10-bit A/D mode)
Change of AD conversion register
Value of comparison voltage (Vref)
0
At start of conversion
0
0
0
0
0
0
0
0
0
0
First comparison
1
0
0
0
0
0
0
0
0
0
VREF
2
Second comparison
✽1
1
0
0
0
0
0
0
0
0
VREF
2
±
V REF
4
1
0
0
0
0
0
0
0
VREF
2
±
V REF
4
Third comparison
✽
1
✽
2
••
•
••
•
After completion of
tenth comparison
••
•
A result of A/D conversion
✽
1
✽
2
✽
3
✽4
✽5
VREF
8
±
✽6
✽7
✽8
✽9
✽10
VREF
2
±
V REF
4
±
•••
±
V REF
1024
✽1–✽10: A result of the first to tenth comparison
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION SUPPLEMENT
Table 23 Change of AD conversion register during A/D conversion (at 8-bit A/D mode)
Change of AD conversion register
Value of comparison voltage (Vref)
0
At start of conversion
0
0
0
0
0
0
0
0
First comparison
1
0
0
0
0
0
0
0
V REF
2
–
VREF
512
Second comparison
✽1
1
0
0
0
0
0
0
VREF
2
±
VREF
4
–
VREF
512
Third comparison
✽
2
1
0
0
0
0
0
VREF
2
±
VREF
4
±
V REF
8
1
✽
••
•
••
•
After completion of
eighth comparison
1
✽
✽
2
3
✽4
✽5
VREF
512
••
•
A result of A/D conversion
✽
–
✽6
✽7
VREF
2
✽8
±
VREF
4
±
•••
±
VREF
256
–
VREF
512
✽1–✽8: A result of the first to eighth comparison
Figure 95 shows A/D conversion equivalent circuit, and Figure 96
shows A/D conversion timing chart.
VCC
VSS
VCC
AVSS
About 2 kΩ
V IN
AN0
Sampling
clock
AN1
C
AN2
Chopper amplifier
AN3
AN4
AD conversion register 1
AN5
AN6
AN7
AD conversion register 2
AN8
AN9
AD conversion interrupt request
AN10
AN11
AN12
AN13
AN14
AN15
b4 b2 b1 b0
AD/DA control register
Vref
VREF
Built-in
D/A converter
Reference
clock
AVSS
Fig. 95 A/D conversion equivalent circuit
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION SUPPLEMENT
XI N
2
Write signal for AD
control register
AD conversion
completion bit
At 10-bit A/D mode : 61 cycles
At 8-bit A/D mode : 50 cycles
Sampling clock
Fig. 96 A/D conversion timing chart
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HARDWARE
3804 Group (Spec.H)
FUNCTIONAL DESCRIPTION SUPPLEMENT
Memo
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CHAPTER 2
APPLICATION
2.1
I/O port
2.2
2.3
Interrupt
Timer
2.4
Serial interface
2.5
2.6
Multi-master I2C-BUS interface
PWM
2.7
A/D converter
2.8
D/A converter
2.9
2.10
Watchdog timer
Reset
2.11
Clock generating circuit
2.12
Standby function
2.13
Flash memory mode
APPLICATION
3804 Group (Spec.H)
2.1 I/O port
2.1 I/O port
This paragraph describes the setting method of I/O port relevant registers, notes etc.
2.1.1 Memory map
Address
000016
Port P0 (P0)
000116
Port P0 direction register (P0D)
000216
Port P1 (P1)
000316
Port P1 direction register (P1D)
000416
Port P2 (P2)
000516
Port P2 direction register (P2D)
000616
Port P3 (P3)
000716
Port P3 direction register (P3D)
000816
Port P4 (P4)
000916
Port P4 direction register (P4D)
000A16
000B16
Port P5 (P5)
Port P5 direction register (P5D)
000C16
Port P6 (P6)
000D16
Port P6 direction register (P6D)
0FF016
Port P0 pull-up control register (PULL0)
0FF116
Port P1 pull-up control register (PULL1)
0FF216
Port P2 pull-up control register (PULL2)
0FF316
0FF416
Port P3 pull-up control register (PULL3)
Port P4 pull-up control register (PULL4)
0FF516
Port P5 pull-up control register (PULL5)
0FF616 Port P6 pull-up control register (PULL6)
Fig. 2.1.1 Memory map of I/O port relevant registers
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APPLICATION
3804 Group (Spec.H)
2.1 I/O port
2.1.2 Relevant registers
Port Pi
b7 b6 b5 b4 b3 b2 b1 b0
Port Pi (i = 0, 1, 2, 3, 4, 5, 6)
(Pi: addresses 000016, 000216, 000416, 000616, 000816, 000A16, 000C16)
b
0
1
2
3
4
5
6
7
Name
Port Pi0
Port Pi1
Port Pi2
Port Pi3
Port Pi4
Port Pi5
Port Pi6
Port Pi7
Functions
●In output mode
Write •••••••• Port latch
Read •••••••• Port latch
●In input mode
Write •••••••• Port latch
Read •••••••• Value of pin
At reset R W
0
0
0
0
0
0
0
0
Fig. 2.1.2 Structure of Port Pi (i = 0 to 6)
Port Pi direction register
b7 b6 b5 b4 b3 b2 b1 b0
Port Pi direction register (i = 0, 1, 2, 3, 4, 5, 6)
(PiD: addresses 000116, 000316, 000516, 000716, 000916, 000B16, 000D16)
b
Name
0 Port Pi direction
register
1
2
3
4
5
6
7
Functions
0 : Port Pi0 input mode
1 : Port Pi0 output mode
0 : Port Pi1 input mode
1 : Port Pi1 output mode
0 : Port Pi2 input mode
1 : Port Pi2 output mode
0 : Port Pi3 input mode
1 : Port Pi3 output mode
0 : Port Pi4 input mode
1 : Port Pi4 output mode
0 : Port Pi5 input mode
1 : Port Pi5 output mode
0 : Port Pi6 input mode
1 : Port Pi6 output mode
0 : Port Pi7 input mode
1 : Port Pi7 output mode
At reset R W
0
0
0
0
0
0
0
0
Fig. 2.1.3 Structure of Port Pi direction register (i = 0 to 6)
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APPLICATION
3804 Group (Spec.H)
2.1 I/O port
Port Pi pull-up control register (i = 0 to 2, 4 to 6)
b7 b6 b5 b4 b3 b2 b1 b0
Port Pi pull-up control register (i = 0 to 2, 4 to 6)
(PULLi: addresses 0FF016, 0FF116, 0FF216, 0FF416, 0FF516, 0FF616)
b
Name
0 Port Pi0 pull-up
control bit
1 Port Pi1 pull-up
control bit
2 Port Pi2 pull-up
control bit
3 Port Pi3 pull-up
control bit
4 Port Pi4 pull-up
control bit
5 Port Pi5 pull-up
control bit
6 Port Pi6 pull-up
control bit
7 Port Pi7 pull-up
control bit
Functions
At reset R W
0
0: No pull-up
1: Pull-up
0: No pull-up
1: Pull-up
0: No pull-up
1: Pull-up
0: No pull-up
1: Pull-up
0: No pull-up
1: Pull-up
0: No pull-up
1: Pull-up
0: No pull-up
1: Pull-up
0: No pull-up
1: Pull-up
0
0
0
0
0
0
0
Fig. 2.1.4 Structure of Port Pi pull-up control register (i = 0, 1, 2, 4, 5, 6)
Port P3 pull-up control register
b7 b6 b5 b4 b3 b2 b1 b0
Port P3 pull-up control register
(PULL3: address 0FF316)
b
Name
Functions
0: No pull-up
0 Port P30 pull-up
control bit
1: Pull-up
Port
P3
1
pull-up
0: No pull-up
1
control bit
1: Pull-up
2 Nothing is arranged for these bits. These are
write disabled bits. When these bits are read
3 out, the contents are “0”.
0: No pull-up
4 Port P34 pull-up
control bit
1: Pull-up
5 Port P35 pull-up
0: No pull-up
control bit
1: Pull-up
0: No pull-up
6 Port P36 pull-up
control bit
1: Pull-up
Port
P3
7
pull-up
7
0: No pull-up
control bit
1: Pull-up
At reset R W
0
0
0
0
0
0
0
0
0
Fig. 2.1.5 Structure of Port P3 pull-up control register
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APPLICATION
3804 Group (Spec.H)
2.1 I/O port
2.1.3 Port Pi pull-up control register
Valid/Invalid of pull-up resistor can be set by the pull-up control register by a bit unit. Pull-up control is valid
only when each direction register is set to the input mode.
Note: Ports P3 2 and P3 3 do not have pull-up control bit because they are N-channel open-drain output.
2.1.4 Terminate unused pins
Table 2.1.1 Termination of unused pins (in single-chip mode)
Pins
Termination
P0, P1, P2, P3, • Set to the input mode and connect each to V CC or V SS through a resistor of 1 kΩ to
P4, P5, P6
10 kΩ.
• Set to the output mode and open at “L” or “H” output state.
VREF
Connect to Vss (GND).
AVSS
Connect to Vss (GND).
XOUT
Open (only when using external clock)
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APPLICATION
3804 Group (Spec.H)
2.1 I/O port
2.1.5 Notes on I/O port
(1) Notes in standby state
In standby state ✽1 for low-power dissipation, do not make input levels of an I/O port “undefined”,
especially for I/O ports of the N-channel open-drain.
Pull-up (connect the port to V CC ) or pull-down (connect the port to V SS ) these ports through a
resistor.
When determining a resistance value, note the following points:
• External circuit
• Variation of output levels during the ordinary operation
When using built-in pull-up resistor, note on varied current values:
• When setting as an input port : Fix its input level
• When setting as an output port : Prevent current from flowing out to external
● Reason
Even when setting as an output port with its direction register, when the content of the port latch
is “1”, the transistor becomes the OFF state, which causes the ports to be the high-impedance
state. Note that the level becomes “undefined” depending on external circuits.
Accordingly, the potential which is input to the input buffer in a microcomputer is unstable in the
state that input levels of an I/O port are “undefined”. This may cause power source current.
✽1 standby state: stop mode by executing STP instruction
wait mode by executing WIT instruction
(2) Modifying output data with bit managing instruction
When the port latch of an I/O port is modified with the bit managing instruction✽2, the value of the
unspecified bit may be changed.
● Reason
The bit managing instructions are read-modify-write form instructions for reading and writing data
by a byte unit. Accordingly, when these instructions are executed on a bit of the port latch of an
I/O port, the following is executed to all bits of the port latch.
•As for bit which is set for input port:
The pin state is read in the CPU, and is written to this bit after bit managing.
•As for bit which is set for output port:
The bit value is read in the CPU, and is written to this bit after bit managing.
Note the following:
•Even when a port which is set as an output port is changed for an input port, its port latch holds
the output data.
•As for a bit of which is set for an input port, its value may be changed even when not specified
with a bit managing instruction in case where the pin state differs from its port latch contents.
✽2 Bit managing instructions: SEB and CLB instructions
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APPLICATION
3804 Group (Spec.H)
2.1 I/O port
2.1.6 Termination of unused pins
(1) Terminate unused pins
➀ I/O ports :
• Set the I/O ports for the input mode and connect them to V CC or V SS through each resistor of
1 kΩ to 10 kΩ.
Ports that permit the selecting of a built-in pull-up resistor can also use this resistor. Set the
I/O ports for the output mode and open them at “L” or “H”.
• When opening them in the output mode, the input mode of the initial status remains until the
mode of the ports is switched over to the output mode by the program after reset. Thus, the
potential at these pins is undefined and the power source current may increase in the input
mode. With regard to an effects on the system, thoroughly perform system evaluation on the user
side.
• Since the direction register setup may be changed because of a program runaway or noise, set
direction registers by program periodically to increase the reliability of program.
➁ The AVss pin when not using the A/D converter :
• When not using the A/D converter, handle a power source pin for the A/D converter, AVss pin
as follows:
AVss: Connect to the Vss pin.
(2) Termination remarks
➀ I/O ports :
Do not open in the input mode.
● Reason
• The power source current may increase depending on the first-stage circuit.
• An effect due to noise may be easily produced as compared with proper termination ➀ and
shown on the above.
➁ I/O ports :
When setting for the input mode, do not connect to V CC or V SS directly.
● Reason
If the direction register setup changes for the output mode because of a program runaway or
noise, a short circuit may occur between a port and V CC (or V SS).
➂ I/O ports :
When setting for the input mode, do not connect multiple ports in a lump to V CC or VSS through
a resistor.
● Reason
If the direction register setup changes for the output mode because of a program runaway or
noise, a short circuit may occur between ports.
• At the termination of unused pins, perform wiring at the shortest possible distance (20 mm or less)
from microcomputer pins.
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APPLICATION
3804 Group (Spec.H)
2.2 Interrupt
2.2 Interrupt
This paragraph explains the registers setting method and the notes relevant to the interrupt.
2.2.1 Memory map
003916
Interrupt source selection register (INTSEL)
003A16
Interrupt edge selection register (INTEDGE)
003C16
Interrupt request register 1 (IREQ1)
003D16
Interrupt request register 2 (IREQ2)
003E16
Interrupt control register 1 (ICON1)
003F16
Interrupt control register 2 (ICON2)
Fig. 2.2.1 Memory map of registers relevant to interrupt
2.2.2 Relevant registers
Interrupt source selection register
b7 b6 b5 b4 b3 b2 b1 b0
Interrupt source selection register
(INTSEL: address 003916)
b
Name
Functions
At reset R W
0 INT0/Timer Z
interrupt source
selection bit (*1)
0: INT0 interrupt
1: Timer Z interrupt
0
1 Serial I/O2/Timer Z
interrupt source
selection bit (*1)
2 Serial I/O1 transmit/
SCL, SDA interrupt
source selection bit
(*2)
0: Serial I/O2 interrupt
1: Timer Z interrupt
0
0: Serial I/O1 transmit
interrupt
1: SCL, SDA interrupt
0
0: CNTR0 interrupt
1: SCL, SDA interrupt
0
0: INT4 interrupt
1: CNTR2 interrupt
0
0: INT2 interrupt
1: I2C interrupt
0: CNTR1 interrupt
1: Serial I/O3 receive
interrupt
0: A/D converter interrupt
1: Serial I/O3 transmit
interrupt
0
3 CNTR0/SCL, SDA
interrupt source
selection bit (*2)
4 INT4/CNTR2
interrupt source
selection bit
5 INT2/I2C interrupt
source selection bit
6 CNTR1/Serial I/O3
receive interrupt
source selection bit
7 AD converter/Serial
I/O3 transmit
interrupt source
selection bit
0
0
*1: Do not write 1 to these bits simultaneously.
*2: Do not write 1 to these bits simultaneously.
Fig. 2.2.2 Structure of Interrupt source selection register
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APPLICATION
3804 Group (Spec.H)
2.2 Interrupt
Interrupt edge selection register
b7 b6 b5 b4 b3 b2 b1 b0
Interrupt edge selection register
(INTEDGE: address 003A16)
b
Name
Functions
At reset R W
0: Falling edge active
0 INT0 active edge
1: Rising edge active
selection bit
0: Falling edge active
1 INT1 active edge
1: Rising edge active
selection bit
2 Nothing is arranged for this bit. This is a write
disabled bit. When this bit is read out, the
contents are “0”.
3 INT2 active edge
0: Falling edge active
selection bit
1: Rising edge active
4 INT3 active edge
0: Falling edge active
selection bit
1: Rising edge active
0: Falling edge active
5 INT4 active edge
selection bit
1: Rising edge active
6 INT0, INT4 interrupt 0: INT00, INT40 interrupt
switch bit
1: INT01, INT41 interrupt
0
7 Nothing is arranged for this bit. This is a write
disabled bit. When this bit is read out, the
contents are “0”.
0
0
0
0
0
0
0
Fig. 2.2.3 Structure of Interrupt edge selection register
Interrupt request register 1
b7 b6 b5 b4 b3 b2 b1 b0
Interrupt request register 1
(IREQ1 : address 003C16)
b
Name
Functions
At reset R W
0 INT0/Timer Z
0 : No interrupt request issued
interrupt request bit 1 : Interrupt request issued
0
✽
1 INT1 interrupt
request bit
0
✽
2 Serial I/O1 receive 0 : No interrupt request issued
interrupt request bit 1 : Interrupt request issued
0
✽
0 : No interrupt request issued
3 Serial I/O1
transmit/SCL, SDA 1 : Interrupt request issued
interrupt request bit
0
✽
4 Timer X interrupt
request bit
0 : No interrupt request issued
0
✽
5 Timer Y interrupt
request bit
0 : No interrupt request issued
0
✽
6 Timer 1 interrupt
request bit
0 : No interrupt request issued
0
✽
0
✽
0 : No interrupt request issued
1 : Interrupt request issued
1 : Interrupt request issued
1 : Interrupt request issued
1 : Interrupt request issued
7 Timer 2 interrupt
0 : No interrupt request issued
request bit
1 : Interrupt request issued
✽: 0 can be set by software, but 1 cannot be set.
Fig. 2.2.4 Structure of Interrupt request register 1
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APPLICATION
3804 Group (Spec.H)
2.2 Interrupt
Interrupt request register 2
b7 b6 b5 b4 b3 b2 b1 b0
Interrupt request register 2
(IREQ2 : address 003D16)
b
Name
Functions
At reset R W
0 CNTR0/SCL, SDA
interrupt request bit
1 CNTR1/Serial I/O3
receive interrupt
request bit
0 : No interrupt request issued
1 : Interrupt request issued
0 : No interrupt request issued
1 : Interrupt request issued
0
✽
0
✽
2 Serial I/O2/Timer Z
interrupt request bit
3 INT2/I2C interrupt
request bit
4 INT3 interrupt
request bit
5 INT4/CNTR2
interrupt request bit
6 AD converter/Serial
I/O3 transmit
interrupt request bit
0 : No interrupt request issued
1 : Interrupt request issued
0 : No interrupt request issued
1 : Interrupt request issued
0 : No interrupt request issued
1 : Interrupt request issued
0 : No interrupt request issued
1 : Interrupt request issued
0 : No interrupt request issued
1 : Interrupt request issued
0
✽
0
✽
0
✽
0
✽
0
✽
0
7 Nothing is arranged for this bit. This is a write
disabled bit. When this bit is read out, the
contents are 0 .
✽: 0 can be set by software, but 1 cannot be set.
Fig. 2.2.5 Structure of Interrupt request register 2
Interrupt control register 1
b7 b6 b5 b4 b3 b2 b1 b0
Interrupt control register 1
(ICON1 : address 003E16)
b
Name
Functions
At reset R W
0 INT0/Timer Z
interrupt enable bit
1 INT1 interrupt
enable bit
2 Serial I/O1 receive
interrupt enable bit
3 Serial I/O1
transmit/SCL, SDA
interrupt enable bit
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0
4 Timer X interrupt
enable bit
5 Timer Y interrupt
enable bit
6 Timer 1 interrupt
enable bit
7 Timer 2 interrupt
enable bit
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0
0
0
0
0
0
0
Fig. 2.2.6 Structure of Interrupt control register 1
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APPLICATION
3804 Group (Spec.H)
2.2 Interrupt
Interrupt control register 2
b7 b6 b5 b4 b3 b2 b1 b0
0
Interrupt control register 2
(ICON2 : address 003F16)
b
Name
Functions
At reset R W
0 CNTR0/SCL, SDA
interrupt enable bit
1 CNTR1/ Serial I/O3
receive interrupt
enable bit
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0
2 Serial I/O2/ Timer Z
interrupt enable bit
3 INT2/I2C interrupt
enable bit
4 INT3 interrupt
enable bit
5 INT4/CNTR2
interrupt enable bit
6 AD converter/Serial
I/O3 transmit
interrupt enable bit
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
0
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0
7 Fix this bit to “0”.
0
0
0
0
0
Fig. 2.2.7 Structure of Interrupt control register 2
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APPLICATION
3804 Group (Spec.H)
2.2 Interrupt
2.2.3 Interrupt source
The 3804 group (Spec. H) ’s interrupts are a type of vector and occur by 16 sources among 23 sources:
nine external, thirteen internal, and one software. These are vector interrupts with a fixed priority system.
Accordingly, when two or more interrupt requests occur during the same sampling, the higher-priority
interrupt is accepted first. This priority is determined by hardware, but a variety of priority processing can
be performed by software, using an interrupt enable bit and an interrupt disable flag.
For interrupt sources, vector addresses and interrupt priority, refer to Tables 2.2.1.
Table 2.2.1 Interrupt sources, vector addresses and priority
Interrupt Source
Priority
Reset (Note 2)
INT0
1
2
Timer Z
INT1
Serial I/O1
reception
Serial I/O1
transmission
Vector Addresses (Note 1)
Low
High
FFFC16
FFFD16
Non-maskable
External interrupt
(active edge selectable)
FFFA16
3
FFF916
FFF816
4
FFF716
FFF616
At completion of serial I/O1 data
reception
5
FFF516
FFF416
At completion of serial I/O1
transmission shift or when
transmission buffer is empty
Valid when serial I/O1 is selected
At detection of either rising or
falling edge of SCL or SDA
External interrupt
(active edge selectable)
6
7
8
9
10
FFF316
FFF116
FFEF16
FFED16
FFEB16
FFF216
FFF016
FFEE16
FFEC16
FFEA16
At detection of either rising or
falling edge of INT0 input
At timer Z underflow
At detection of either rising or
falling edge of INT1 input
11
FFE916
FFE816
External interrupt
(active edge selectable)
Valid when serial I/O1 is selected
At timer X underflow
At timer Y underflow
At timer 1 underflow
STP release timer underflow
At timer 2 underflow
At detection of either rising or
falling edge of CNTR0 input
At detection of either rising or
falling edge of SCL or SDA
SCL, SDA
CNTR1
At reset
Remarks
FFFB16
SCL, SDA
Timer X
Timer Y
Timer 1
Timer 2
CNTR0
Interrupt Request
Generating Conditions
At detection of either rising or
falling edge of CNTR1 input
Serial I/O3
reception
Serial I/O2
At completion of serial I/O3 data
reception
At completion of serial I/O2 data
transmission or reception
12
FFE716
FFE616
Timer Z
INT2
13
FFE516
FFE416
I 2C
INT3
14
FFE316
FFE216
At detection of either rising or
falling edge of INT3 input
INT4
15
FFE116
FFE016
At detection of either rising or
falling edge of INT4 input
At detection of either rising or
falling edge of CNTR2 input
A/D converter
Serial I/O3
transmission
16
FFDF16
FFDE16
At completion of A/D conversion
BRK instruction
17
External interrupt
(active edge selectable)
External interrupt
(active edge selectable)
External interrupt
(active edge selectable)
Valid when serial I/O3 is selected
Valid when serial I/O2 is selected
At timer Z underflow
At detection of either rising or
falling edge of INT2 input
External interrupt
(active edge selectable)
At completion of data transfer
CNTR2
FFDD16
FFDC16
External interrupt
(active edge selectable)
External interrupt
(active edge selectable)
External interrupt
(active edge selectable)
At completion of serial I/O3
transmission shift or when
transmission buffer is empty
Valid when serial I/O3 is selected
At BRK instruction execution
Non-maskable software interrupt
Notes 1: Vector addresses contain interrupt jump destination addresses.
2: Reset function in the same way as an interrupt with the highest priority.
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APPLICATION
3804 Group (Spec.H)
2.2 Interrupt
2.2.4 Interrupt operation
When an interrupt request is accepted, the contents of the following registers just before acceptance of the
interrupt requests are automatically pushed onto the stack area in the order of ➀, ➁ and ➂.
➀High-order contents of program counter (PC H)
➁Low-order contents of program counter (PC L)
➂Contents of processor status register (PS)
After the contents of the above registers are pushed onto the stack area, the accepted interrupt vector
address enters the program counter and consequently the interrupt processing routine is executed.
When the RTI instruction is executed at the end of the interrupt processing routine, the contents of the
above registers pushed onto the stack area are restored to the respective registers in the order of ➂, ➁
and ➀; and the microcomputer resumes the processing executed just before acceptance of the interrupts.
Figure 2.2.8 shows an interrupt operation diagram.
Executing routine
·······
Interrupt occurs
(Accepting interrupt request)
Suspended
operation
Resume processing
Contents of program counter (high-order) are pushed onto stack
Contents of program counter (low-order) are pushed onto stack
Contents of processor status register are pushed onto stack
·······
Interrupt
processing
routine
RTI instruction
Contents of processor status register are popped from stack
Contents of program counter (low-order) are popped from stack
Contents of program counter (high-order) are popped from stack
: Operation commanded by software
: Internal operation performed automatically
Fig. 2.2.8 Interrupt operation diagram
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APPLICATION
3804 Group (Spec.H)
2.2 Interrupt
(1) Processing upon acceptance of interrupt request
Upon acceptance of an interrupt request, the following operations are automatically performed.
➀The processing being executed is stopped.
➁The contents of the program counter and the processor status register are pushed onto the stack
area. Figure 2.2.9 shows the changes of the stack pointer and the program counter upon acceptance
of an interrupt request.
➂Concurrently with the push operation, the jump destination address (the beginning address of the
interrupt processing routine) of the occurring interrupt stored in the vector address is set in the
program counter, then the interrupt processing routine is executed.
➃After the interrupt processing routine is started, the corresponding interrupt request bit is automatically
cleared to “0”. The interrupt disable flag is set to “1” so that multiple interrupts are disabled.
Accordingly, for executing the interrupt processing routine, it is necessary to set the jump destination
address in the vector area corresponding to each interrupt.
Stack area
Program counter
PCL Program counter (low-order)
PCH Program counter (high-order)
Interrupt disable flag = “0”
Stack pointer
S
(S)
(S)
Interrupt
request is
accepted
Program counter
PCL
Vector address
PCH
(from Interrupt vector area)
Stack pointer
S
(S) – 3
Stack area
Interrupt disable flag = “1”
(s) – 3
Processor status register
Program counter (low-order)
(S) Program counter (high-order)
Fig. 2.2.9 Changes of stack pointer and program counter upon acceptance of interrupt request
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APPLICATION
3804 Group (Spec.H)
2.2 Interrupt
(2) Timing after acceptance of interrupt request
The interrupt processing routine begins with the machine cycle following the completion of the
instruction that is currently being executed.
Figure 2.2.10 shows the time up to execution of interrupt processing routine and Figure 2.2.11 shows
the timing chart after acceptance of interrupt request.
Interrupt request generated
Main routine
Start of interrupt processing
Waiting time for Stack push and
post-processing Vector fetch
of pipeline
Interrupt processing routine
✽
0 to 16 cycles
2 cycles
5 cycles
7 to 23 cycles
(When f(XIN) = 8 MHz, 1.75 µs to 5.75 µs)
✽ When executing DIV instruction
Fig. 2.2.10 Time up to execution of interrupt processing routine
Waiting time for pipeline
post-processing
Push onto stack
Vector fetch
Interrupt operation starts
φ
SYNC
RD
WR
Address bus
Data bus
PC
Not used
S, SPS
S-1, SPS S-2, SPS
PCH
P CL
PS
BL
BH
AL
AL, AH
AH
SYNC : CPU operation code fetch cycle
(This is an internal signal that cannot be observed from the external unit.)
BL, BH : Vector address of each interrupt
AL, AH : Jump destination address of each interrupt
SPS : “0016” or “0116”
Fig. 2.2.11 Timing chart after acceptance of interrupt request
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APPLICATION
3804 Group (Spec.H)
2.2 Interrupt
2.2.5 Interrupt control
The acceptance of all interrupts, excluding the BRK instruction interrupt, can be controlled by the interrupt
request bit, interrupt enable bit, and an interrupt disable flag, as described in detail below. Figure 2.2.12
shows an interrupt control diagram.
Interrupt request bit
Interrupt enable bit
Interrupt request
Interrupt disable flag
BRK instruction
Reset
Fig. 2.2.12 Interrupt control diagram
The interrupt request bit, interrupt enable bit and interrupt disable flag function independently and do not
affect each other. An interrupt is accepted when all the following conditions are satisfied.
●Interrupt request bit .......... “1”
●Interrupt enable bit ........... “1”
●Interrupt disable flag ........ “0”
Though the interrupt priority is determined by hardware, a variety of priority processing can be performed
by software using the above bits and flag. Tables 2.2.2 shows list of interrupt control bits according to the
interrupt source.
(1) Interrupt request bits
The interrupt request bits are allocated to the interrupt request register 1 (address 003C 16) and
interrupt request register 2 (address 003D 16).
The occurrence of an interrupt request causes the corresponding interrupt request bit to be set to
“1”. The interrupt request bit is held in the “1” state until the interrupt is accepted. When the interrupt
is accepted, this bit is automatically cleared to “0”.
Each interrupt request bit can be set to “0”, but cannot be set to “1”, by software.
(2) Interrupt enable bits
The interrupt enable bits are allocated to the interrupt control register 1 (address 003E 16) and the
interrupt control register 2 (address 003F 16).
The interrupt enable bits control the acceptance of the corresponding interrupt request.
When an interrupt enable bit is “0”, the corresponding interrupt request is disabled. If an interrupt
request occurs when this bit is “0”, the corresponding interrupt request bit is set to “1” but the
interrupt is not accepted. In this case, unless the interrupt request bit is set to “0” by software, the
interrupt request bit remains in the “1” state.
When an interrupt enable bit is “1”, the corresponding interrupt is enabled. If an interrupt request
occurs when this bit is “1”, the interrupt is accepted (when interrupt disable flag = “0”).
Each interrupt enable bit can be set to “0” or “1” by software.
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3804 Group (Spec.H)
2.2 Interrupt
(3) Interrupt disable flag
The interrupt disable flag is allocated to bit 2 of the processor status register. The interrupt disable
flag controls the acceptance of interrupt request except BRK instruction.
When this flag is “1”, the acceptance of interrupt requests is disabled. When the flag is “0”, the
acceptance of interrupt requests is enabled. This flag is set to “1” with the SEI instruction and is set
to “0” with the CLI instruction.
When a main routine branches to an interrupt processing routine, this flag is automatically set to “1”,
so that multiple interrupts are disabled. To use multiple interrupts, set this flag to “0” with the CLI
instruction within the interrupt processing routine. Figure 2.2.13 shows an example of multiple interrupts.
Table 2.2.2 List of interrupt bits according to interrupt source
Interrupt source
INT 0/Timer Z
INT1
Serial I/O1 reception
Serial I/O1 transmission/SCL, SDA
Timer X
Timer Y
Timer 1
Timer 2
CNTR 0/SCL, SDA
CNTR 1/Serial I/O3 reception
Serial I/O2/Timer Z
INT 2/I2C
INT3
INT 4/CNTR2
A/D converter/Serial I/O3 transmission
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REJ09B0212-0100Z
Interrupt enable bit
Address
003E16
003E16
003E16
003E16
003E16
003E16
003E16
003E16
003F16
003F16
003F16
003F16
003F16
003F16
003F16
Bit
b0
b1
b2
b3
b4
b5
b6
b7
b0
b1
b2
b3
b4
b5
b6
Interrupt request bit
Address
003C16
003C16
003C16
003C16
003C16
003C16
003C16
003C16
003D16
003D16
003D16
003D16
003D16
003D16
003D16
Bit
b0
b1
b2
b3
b4
b5
b6
b7
b0
b1
b2
b3
b4
b5
b6
2-17
APPLICATION
3804 Group (Spec.H)
2.2 Interrupt
Interrupt request
Nesting
Reset
Time
Main routine
I=1
C1 = 0, C2 = 0
Interrupt
request 1
C1 = 1
I=0
Interrupt 1
Interrupt
request 2
I=1
Multiple interrupt
C2 = 1
I=0
Interrupt 2
I=1
RTI
I=0
RTI
I=0
I : Interrupt disable flag
C1 : Interrupt enable bit of interrupt 1
C2 : Interrupt enable bit of interrupt 2
: Set automatically.
: Set by software.
Fig. 2.2.13 Example of multiple interrupts
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APPLICATION
3804 Group (Spec.H)
2.2 Interrupt
2.2.6 INT interrupt
The INT interrupt requests is generated when the microcomputer detects a level change of each INT pin
(INT 0–INT 4).
(1) Active edge selection
INT 0–INT4 can be selected from either a falling edge or rising edge detection as an active edge by
the interrupt edge selection register. In the “0” state, the falling edge of the corresponding pin is
detected. In the “1” state, the rising edge of the corresponding pin is detected.
(2) INT0, INT 2, INT 4 interrupt source selection
When using the following interrupt source, select which of the interrupt source by the interrupt source
selection register (address 0039 16). (Set these bits to “0” when using INT.)
•INT 0 or timer Z (bit 0)
•INT 4 or CNTR 2 (bit 4)
•INT 2 or I 2C (bit 5)
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APPLICATION
3804 Group (Spec.H)
2.2 Interrupt
2.2.7 Notes on interrupts
(1) Change of relevant register settings
When the setting of the following registers or bits is changed, the interrupt request bit may be set
to “1”. When not requiring the interrupt occurrence synchronized with these setting, take the following
sequence.
•Interrupt edge selection register (address 003A 16)
•Timer XY mode register (address 0023 16)
•Timer Z mode register (address 002A 16)
•I2C START/STOP condition control register (address 001616)
Set the above listed registers or bits as the following sequence.
Set the corresponding interrupt enable bit to “0”
(disabled) .
↓
Set the interrupt edge select bit (active edge switch
bit) or the interrupt (source) select bit to “1”.
↓
NOP (One or more instructions)
↓
Set the corresponding interrupt request bit to “0”
(no interrupt request issued).
↓
Set the corresponding interrupt enable bit to “1”
(enabled).
Fig. 2.2.14 Sequence of changing relevant register
■ Reason
When setting the followings, the interrupt request bit may be set to “1”.
•When setting external interrupt active edge
Concerned register: Interrupt edge selection register (address 003A 16)
Timer XY mode register (address 0023 16)
Timer Z mode register (address 002A 16)
I 2C START/STOP condition control register (address 0016 16)
•When switching interrupt sources of an interrupt vector address where two or more interrupt
sources are allocated.
Concerned register: Interrupt source selection register (address 0039 16)
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APPLICATION
3804 Group (Spec.H)
2.2 Interrupt
(2) Check of interrupt request bit
● When executing the BBC or BBS instruction to an interrupt request bit of an interrupt request
register immediately after this bit is set to “0”, execute one or more instructions before executing
the BBC or BBS instruction.
Clear the interrupt request bit to “0” (no interrupt issued)
↓
NOP (one or more instructions)
↓
Execute the BBC or BBS instruction
Fig. 2.2.15 Sequence of check of interrupt request bit
■ Reason
If the BBC or BBS instruction is executed immediately after an interrupt request bit of an interrupt
request register is cleared to “0”, the value of the interrupt request bit before being cleared to “0”
is read.
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3804 Group (Spec.H)
2.3 Timer
2.3 Timer
This paragraph explains the registers setting method and the notes relevant to the timers.
2.3.1 Memory map
Address
000E16
Timer 12, X count source selection register (T12XCSS)
000F16
Timer Y, Z count source selection register (TYZCSS)
002016
Prescaler 12 (PRE12)
002116
Timer 1 (T1)
002216
Timer 2 (T2)
002316
Timer XY mode register (TM)
002416
Prescaler X (PREX)
002516
Timer X (TX)
002616
Prescaler Y (PREY)
002716
Timer Y (TY)
002816
002916
Timer Z low-order (TZL)
Timer Z high-order (TZH)
002A16
Timer Z mode register (TZM)
003916
Interrupt source selection register (INTSEL)
003C16
Interrupt request register 1 (IREQ1)
003D16
Interrupt request register 2 (IREQ2)
003E16
Interrupt control register 1 (ICON1)
Interrupt control register 2 (ICON2)
003F16
Fig. 2.3.1 Memory map of registers relevant to timers
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APPLICATION
3804 Group (Spec.H)
2.3 Timer
2.3.2 Relevant registers
Prescaler 12, Prescaler X, Prescaler Y
b7 b6 b5 b4 b3 b2 b1 b0
Prescaler 12 (PRE12), Prescaler X (PREX), Prescaler Y (PREY)
(addresses 002016, 002416, 002616)
b
Functions
0 • Set a count value of each prescaler.
1 • The value set in this register is written to both
2 each prescaler and the corresponding
3 prescaler latch at the same time.
• When this register is read out, the count value
4
of the corresponding prescaler is read out.
5
6
7
At reset R W
1
1
1
1
1
1
1
1
Fig. 2.3.2 Structure of Prescaler 12, Prescaler X, Prescaler Y
Timer 1
b7 b6 b5 b4 b3 b2 b1 b0
Timer 1
(T1: address 002116)
b
Functions
0 • Set timer 1 count value.
1 • The value set in this register is written to both
2 the timer 1 and the timer 1 latch at the same
3 time.
• When the timer 1 is read out, the count value
4
of the timer 1 is read out.
5
6
7
At reset R W
1
0
0
0
0
0
0
0
Fig. 2.3.3 Structure of Timer 1
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APPLICATION
3804 Group (Spec.H)
2.3 Timer
Timer 2, Timer X, Timer Y
b7 b6 b5 b4 b3 b2 b1 b0
Timer 2 (T2), Timer X (TX), Timer Y (TY)
(addresses 002216, 002516, 002716)
b
Functions
0 • Set each timer count value.
1 • The value set in this register is written to both
2 each timer and the corresponding timer latch
3 at the same time.
• When each timer is read out, the count value
4
of the corresponding timer is read out.
5
6
7
At reset R W
1
1
1
1
1
1
1
1
Fig. 2.3.4 Structure of Timer 2, Timer X, Timer Y
Timer Z low-order, Timer Z high-order
b7 b6 b5 b4 b3 b2 b1 b0
Timer Z low-order (TZL), Timer Z high-order (TZH)
(addresses 002816, 002916)
b
Functions
0
• Set each timer count value.
[At write]
• Depending on the write control bit (bit 3 of
TZM), the value set to this register is written to
each timer and the corresponding timer latch
at the same time, or is written only to the latch.
[At read]
• The corresponding timer count value is read
out by reading this register.
• Read both registers in order of TZH and TZL
following.
• Write both registers in order of TZL and TZH
following.
1
2
3
4
5
6
7
At reset R W
1
1
1
1
1
1
1
1
Fig. 2.3.5 Structure of Timer Z (low-order, high-order)
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3804 Group (Spec.H)
2.3 Timer
Timer XY mode register
b7 b6 b5 b4 b3 b2 b1 b0
Timer XY mode register
(TM: address 002316)
b
Name
Functions
0 Timer X operating
mode bits
1
2
3
4
5
6
7
At reset R W
b1 b0
0 0: Timer mode
0 1: Pulse output mode
1 0: Event counter mode
1 1: Pulse width
measurement mode
CNTR0 active edge Refer to Table 2.3.1
switch bit
Timer X count stop 0: Count start
1: Count stop
bit
Timer Y operating b5 b4
0 0: Timer mode
mode bits
0 1: Pulse output mode
1 0: Event counter mode
1 1: Pulse width
measurement mode
CNTR1 active edge Refer to Table 2.3.1
switch bit
Timer Y count stop 0: Count start
1: Count stop
bit
0
0
0
0
0
0
0
0
Fig. 2.3.6 Structure of Timer XY mode register
Table 2.3.1 CNTR 0 /CNTR 1 active edge switch bit function
Timer X /Timer Y operation
modes
Timer mode
CNTR 0 / CNTR 1 active edge switch bit
(bits 2, 6 of address 0023 16) contents
“0” CNTR 0 / CNTR 1 interrupt request occurrence: Falling edge
; No influence to timer count
“1” CNTR 0 / CNTR 1 interrupt request occurrence: Rising edge
Pulse output mode
; No influence to timer count
“0” Pulse output start: Beginning at “H” level
CNTR 0 / CNTR 1 interrupt request occurrence: Falling edge
“1” Pulse output start: Beginning at “L” level
CNTR 0 / CNTR 1 interrupt request occurrence: Rising edge
Event counter mode
“0” Timer X / Timer Y: Rising edge count
CNTR 0 / CNTR 1 interrupt request occurrence: Falling edge
“1” Timer X / Timer Y: Falling edge count
CNTR 0 / CNTR 1 interrupt request occurrence: Rising edge
Pulse width measurement mode
“0” Timer X / Timer Y: “H” level width measurement
CNTR 0 / CNTR 1 interrupt request occurrence: Falling edge
“1” Timer X / Timer Y: “L” level width measurement
CNTR 0 / CNTR 1 interrupt request occurrence: Rising edge
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APPLICATION
3804 Group (Spec.H)
2.3 Timer
Timer Z mode register
b7 b6 b5 b4 b3 b2 b1 b0
Timer Z mode register
(TZM: address 002A16)
b
Name
0 Timer Z operating
mode bits
1
2
Functions
b2b1b0
0 0 0: Timer/Event counter mode
0 0 1: Pulse output mode
0 1 0: Pulse period
measurement mode
0 1 1: Pulse width
measurement mode
1 0 0: Programmable waveform
generating mode
1 0 1: Programmable one-shot
generating mode
1 1 0: Not available
1 1 1: Not available
3 Timer Z write control 0: Writing data to both latch
and timer simultaneousuly
bit
1: Writing data only to latch
0: “L” output
4 Output level latch
1: “H” output
CNTR
2
active
edge
5
Refer to Table 2.3.2.
switch bit
6 Timer Z count stop 0: Count start
1: Count stop
bit
7 Timer/Event counter 0: Timer mode
mode switch bit (Note) 1: Event counter mode
At reset R W
0
0
0
0
0
0
0
0
Note: When selecting the modes except the timer/event counter mode, set “0” to this bit.
Fig. 2.3.7 Structure of Timer Z mode register
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APPLICATION
3804 Group (Spec.H)
2.3 Timer
Table 2.3.2 CNTR 2 active edge switch bit function
Timer Z
CNTR2 active edge switch bit
operation modes
(bit 5 of address 002A 16) contents
Timer mode
“0” CNTR 2 interrupt request occurrence: Falling edge
; No influence to timer count
“1” CNTR 2 interrupt request occurrence: Rising edge
; No influence to timer count
Event counter mode
“0” Timer Z: Rising edge count
CNTR 2 interrupt request occurrence: Falling edge
“1” Timer Z: Falling edge count
CNTR 2 interrupt request occurrence: Rising edge
Pulse output mode
“0” Pulse output start: Beginning at “H” level
CNTR 2 interrupt request occurrence: Falling edge
“1” Pulse output start: Beginning at “L” level
CNTR 2 interrupt request occurrence: Rising edge
Pulse period measurement mode
“0” Timer Z : Term from one falling edge to next falling edge measurement
CNTR 2 interrupt request occurrence: Falling edge
“1” Timer Z : Term from one rising edge to next rising edge measurement
CNTR 2 interrupt request occurrence: Rising edge
Pulse width measurement mode
“0” Timer Z: “H” level width measurement
CNTR 2 interrupt request occurrence: Falling edge
“1” Timer Z: “L” level width measurement
CNTR 2 interrupt request occurrence: Rising edge
Programmable one-shot generating “0” Timer Z : Pulse output start from “L” level, and “H” level one-shot
mode
pulse is output.
CNTR 2 interrupt request occurrence: Falling edge
“1” Timer Z : Pulse output start from “H” level, and “L” level one-shot
pulse is output.
CNTR 2 interrupt request occurrence: Rising edge
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APPLICATION
3804 Group (Spec.H)
2.3 Timer
Timer 12, X count source selection register
b7 b6 b5 b4 b3 b2 b1 b0
Timer 12, X count source selection register
(T12XCSS: address 000E16)
b
Name
0 Timer 12 count
source selection
bits
1
2
3
4 Timer X count
source selection
bits
5
6
7
Functions
b3b2b1b0
0 0 0 0: f(XIN)/2 or f(XCIN)/2
0 0 0 1: f(XIN)/4 or f(XCIN)/4
0 0 1 0: f(XIN)/8 or f(XCIN)/8
0 0 1 1: f(XIN)/16 or f(XCIN)/16
0 1 0 0: f(XIN)/32 or f(XCIN)/32
0 1 0 1: f(XIN)/64 or f(XCIN)/64
0 1 1 0: f(XIN)/128 or f(XCIN)/128
0 1 1 1: f(XIN)/256 or f(XCIN)/256
1 0 0 0: f(XIN)/512 or f(XCIN)/512
1 0 0 1: f(XIN)/1024 or f(XCIN)/1024
1010 to 1111: Not available
b7b6b5b4
0 0 0 0: f(XIN)/2 or f(XCIN)/2
0 0 0 1: f(XIN)/4 or f(XCIN)/4
0 0 1 0: f(XIN)/8 or f(XCIN)/8
0 0 1 1: f(XIN)/16 or f(XCIN)/16
0 1 0 0: f(XIN)/32 or f(XCIN)/32
0 1 0 1: f(XIN)/64 or f(XCIN)/64
0 1 1 0: f(XIN)/128 or f(XCIN)/128
0 1 1 1: f(XIN)/256 or f(XCIN)/256
1 0 0 0: f(XIN)/512 or f(XCIN)/512
1 0 0 1: f(XIN)/1024 or f(XCIN)/1024
1 0 1 0: f(XCIN)
1011 to 1111: Not available
At reset R W
1
1
0
0
1
1
0
0
Fig. 2.3.8 Structure of Timer 12, X count source selection register
Timer Y, Z count source selection register
b7 b6 b5 b4 b3 b2 b1 b0
Timer Y, Z count source selection register
(TYZCSS: address 000F16)
b
Name
0 Timer Y count
source selection
bits
1
2
3
4 Timer Z count
source selection
bits
5
6
7
Functions
b3b2b1b0
0 0 0 0: f(XIN)/2 or f(XCIN)/2
0 0 0 1: f(XIN)/4 or f(XCIN)/4
0 0 1 0: f(XIN)/8 or f(XCIN)/8
0 0 1 1: f(XIN)/16 or f(XCIN)/16
0 1 0 0: f(XIN)/32 or f(XCIN)/32
0 1 0 1: f(XIN)/64 or f(XCIN)/64
0 1 1 0: f(XIN)/128 or f(XCIN)/128
0 1 1 1: f(XIN)/256 or f(XCIN)/256
1 0 0 0: f(XIN)/512 or f(XCIN)/512
1 0 0 1: f(XIN)/1024 or f(XCIN)/1024
1 0 1 0: f(XCIN)
1011 to 1111: Not available
b7b6b5b4
0 0 0 0: f(XIN)/2 or f(XCIN)/2
0 0 0 1: f(XIN)/4 or f(XCIN)/4
0 0 1 0: f(XIN)/8 or f(XCIN)/8
0 0 1 1: f(XIN)/16 or f(XCIN)/16
0 1 0 0: f(XIN)/32 or f(XCIN)/32
0 1 0 1: f(XIN)/64 or f(XCIN)/64
0 1 1 0: f(XIN)/128 or f(XCIN)/128
0 1 1 1: f(XIN)/256 or f(XCIN)/256
1 0 0 0: f(XIN)/512 or f(XCIN)/512
1 0 0 1: f(XIN)/1024 or f(XCIN)/1024
1 0 1 0: f(XCIN)
1011 to 1111: Not available
At reset R W
1
1
0
0
1
1
0
0
Fig. 2.3.9 Structure of Timer Y, Z count source selection register
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APPLICATION
3804 Group (Spec.H)
2.3 Timer
Interrupt source selection register
b7 b6 b5 b4 b3 b2 b1 b0
Interrupt source selection register
(INTSEL: address 003916)
b
Name
Functions
At reset R W
0 INT0/Timer Z
interrupt source
selection bit (*1)
0: INT0 interrupt
1: Timer Z interrupt
0
1 Serial I/O2/Timer Z
interrupt source
selection bit (*1)
2 Serial I/O1 transmit/
SCL, SDA interrupt
source selection bit
(*2)
0: Serial I/O2 interrupt
1: Timer Z interrupt
0
0: Serial I/O1 transmit
interrupt
1: SCL, SDA interrupt
0
0: CNTR0 interrupt
1: SCL, SDA interrupt
0
0: INT4 interrupt
1: CNTR2 interrupt
0
0: INT2 interrupt
1: I2C interrupt
0: CNTR1 interrupt
1: Serial I/O3 receive
interrupt
0: A/D converter interrupt
1: Serial I/O3 transmit
interrupt
0
3 CNTR0/SCL, SDA
interrupt source
selection bit (*2)
4 INT4/CNTR2
interrupt source
selection bit
5 INT2/I2C interrupt
source selection bit
6 CNTR1/Serial I/O3
receive interrupt
source selection bit
7 AD converter/Serial
I/O3 transmit
interrupt source
selection bit
0
0
*1: Do not write 1 to these bits simultaneously.
*2: Do not write 1 to these bits simultaneously.
Fig. 2.3.10 Structure of Interrupt source selection register
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APPLICATION
3804 Group (Spec.H)
2.3 Timer
Interrupt request register 1
b7 b6 b5 b4 b3 b2 b1 b0
Interrupt request register 1
(IREQ1 : address 003C16)
b
Name
Functions
At reset R W
0 INT0/Timer Z
0 : No interrupt request issued
interrupt request bit 1 : Interrupt request issued
0
✽
1 INT1 interrupt
request bit
0
✽
2 Serial I/O1 receive 0 : No interrupt request issued
interrupt request bit 1 : Interrupt request issued
0
✽
0 : No interrupt request issued
3 Serial I/O1
transmit/SCL, SDA 1 : Interrupt request issued
interrupt request bit
0
✽
4 Timer X interrupt
request bit
0 : No interrupt request issued
0
✽
5 Timer Y interrupt
request bit
0 : No interrupt request issued
0
✽
6 Timer 1 interrupt
request bit
0 : No interrupt request issued
0
✽
0
✽
0 : No interrupt request issued
1 : Interrupt request issued
1 : Interrupt request issued
1 : Interrupt request issued
1 : Interrupt request issued
7 Timer 2 interrupt
0 : No interrupt request issued
request bit
1 : Interrupt request issued
✽: 0 can be set by software, but 1 cannot be set.
Fig. 2.3.11 Structure of Interrupt request register 1
Interrupt request register 2
b7 b6 b5 b4 b3 b2 b1 b0
Interrupt request register 2
(IREQ2 : address 003D16)
b
Name
Functions
At reset R W
0 CNTR0/SCL, SDA
interrupt request bit
1 CNTR1/Serial I/O3
receive interrupt
request bit
0 : No interrupt request issued
1 : Interrupt request issued
0 : No interrupt request issued
1 : Interrupt request issued
0
✽
0
✽
2 Serial I/O2/Timer Z
interrupt request bit
3 INT2/I2C interrupt
request bit
4 INT3 interrupt
request bit
5 INT4/CNTR2
interrupt request bit
6 AD converter/Serial
I/O3 transmit
interrupt request bit
0 : No interrupt request issued
1 : Interrupt request issued
0 : No interrupt request issued
1 : Interrupt request issued
0 : No interrupt request issued
1 : Interrupt request issued
0 : No interrupt request issued
1 : Interrupt request issued
0 : No interrupt request issued
1 : Interrupt request issued
0
✽
0
✽
0
✽
0
✽
0
✽
7 Nothing is arranged for this bit. This is a write
disabled bit. When this bit is read out, the
contents are 0 .
0
✽: 0 can be set by software, but 1 cannot be set.
Fig. 2.3.12 Structure of Interrupt request register 2
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APPLICATION
3804 Group (Spec.H)
2.3 Timer
Interrupt control register 1
b7 b6 b5 b4 b3 b2 b1 b0
Interrupt control register 1
(ICON1 : address 003E16)
b
Name
Functions
At reset R W
0 INT0/Timer Z
interrupt enable bit
1 INT1 interrupt
enable bit
2 Serial I/O1 receive
interrupt enable bit
3 Serial I/O1
transmit/SCL, SDA
interrupt enable bit
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0
4 Timer X interrupt
enable bit
5 Timer Y interrupt
enable bit
6 Timer 1 interrupt
enable bit
Timer
2 interrupt
7
enable bit
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0
0
0
0
0
0
0
Fig. 2.3.13 Structure of Interrupt control register 1
Interrupt control register 2
b7 b6 b5 b4 b3 b2 b1 b0
0
Interrupt control register 2
(ICON2 : address 003F16)
b
Name
Functions
At reset R W
0 CNTR0/SCL, SDA
interrupt enable bit
1 CNTR1/ Serial I/O3
receive interrupt
enable bit
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0
2 Serial I/O2/ Timer Z
interrupt enable bit
3 INT2/I2C interrupt
enable bit
4 INT3 interrupt
enable bit
5 INT4/CNTR2
interrupt enable bit
6 AD converter/Serial
I/O3 transmit
interrupt enable bit
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
0
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0
7 Fix this bit to “0”.
0
0
0
0
0
Fig. 2.3.14 Structure of Interrupt control register 2
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APPLICATION
3804 Group (Spec.H)
2.3 Timer
2.3.3 Timer application examples
(1) Basic functions and uses
[Function 1] Control of Event interval (Timer X, Timer Y, Timer Z, Timer 1, Timer 2)
When a certain time, by setting a count value to each timer, has passed, the timer interrupt request
occurs.
<Use>
•Generation of an output signal timing
•Generation of a wait time
[Function 2] Control of Cyclic operation (Timer X, Timer Y, Timer Z, Timer 1, Timer 2)
The value of the timer latch is automatically written to the corresponding timer each time the timer
underflows, and each timer interrupt request occurs in cycles.
<Use>
•Generation of cyclic interrupts
•Clock function (measurement of 250 ms); see Application example 1
•Control of a main routine cycle
[Function 3] Output of Rectangular waveform (Timer X, Timer Y, Timer Z)
The output level of the CNTR pin is inverted each time the timer underflows (in the pulse output
mode).
<Use>
•Piezoelectric buzzer output; see Application example 2
•Generation of the remote control carrier waveforms
[Function 4] Count of External pulses (Timer X, Timer Y, Timer Z)
External pulses input to the CNTR pin are counted as the timer count source (in the event counter
mode).
<Use>
•Frequency measurement; see Application example 3
•Division of external pulses
•Generation of interrupts due to a cycle using external pulses as the count source; count of a
reel pulse
[Function 5] Measurement of External pulse width (Timer X, Timer Y, Timer Z)
The “H” or “L” level width of external pulses input to CNTR pin is measured (in the pulse width
measurement mode).
<Use>
•Measurement of external pulse frequency (measurement of pulse width of FG pulse ✽ for a
motor); see Application example 4
•Measurement of external pulse duty (when the frequency is fixed)
FG pulse ✽: Pulse used for detecting the motor speed to control the motor speed.
[Function 6] Output of Arbitrary waveform (Timer Z)
The value which is set to the output level latch is output from the CNTR pin each time the timer
underflows. (programmable waveform generating mode)
[Function 7] One-shot pulse output by external trigger (Timer Z)
The value of timer latch is set to timer by trigger signal which is input from the INT pin, and timer
is counted down. When trigger signal is input, “H” or “L” is output from the CNTR pin at the same
time, and “L” or “H” is output by underflow of timer. (programmable one-shot generating mode)
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APPLICATION
3804 Group (Spec.H)
2.3 Timer
(2) Timer application example 1: Clock function (measurement of 250 ms)
Outline: The input clock is divided by the timer so that the clock can count up at 250 ms intervals.
Specifications: •The clock f(X IN) = 4.19 MHz (2 22 Hz) is divided by the timer.
•The clock is counted up in the process routine of the timer X interrupt which occurs
at 250 ms intervals.
Figure 2.3.15 shows the timers connection and setting of division ratios; Figure 2.3.16 shows the
relevant registers setting; Figure 2.3.17 shows the control procedure.
f(XIN) = 4.19 MHz
Timer X count source
selection bit
Prescaler X
Timer X
Timer X interrupt
request bit
1/16
1/256
1/256
0 or 1
Dividing by 4 with software
1/4
250 ms
1 second
0 : No interrupt request issued
1 : Interrupt request issued
Fig. 2.3.15 Timers connection and setting of division ratios
Timer 12, X count source selection register (address 000E16)
b7
T12XCSS
b0
0 0 1 1
Timer X count source : f(XIN)/16
Timer XY mode register (address 002316)
b7
b0
1
TM
0 0
Timer X operating mode: Timer mode
Timer X count: Stop
Clear to “0” when starting count.
Prescaler X (address 002416)
b7
PREX
b0
256 – 1
Timer X (address 002516)
b7
Set “division ratio – 1”
b0
256 – 1
TX
Interrupt control register 1 (address 003E16)
b7
ICON1
b0
1
Timer X interrupt: Enabled
Interrupt request register 1 (address 003C16)
b7
IREQ1
b0
0
Timer X interrupt request
(becomes “1” at 250 ms intervals)
Fig. 2.3.16 Relevant registers setting
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APPLICATION
3804 Group (Spec.H)
2.3 Timer
RESET
● x: This bit is not used here. Set it to “0” or “1” arbitrarily.
Initialization
•All interrupts disabled
SEI
.....
TM
XXXX1X002
(address 002316)
IREQ1 (address 003C16), bit4
0
ICON1 (address 003E16), bit4
1
•Timer X : Timer mode
•Clear Timer X interrupt request bit
•Timer X interrupt enabled
.....
T12XCSS (address 000E16)
(address 002416)
PREX
(address 002516)
TX
•Timer X count source : f(XIN)/16
•Set “division ratio – 1” to Prescaler X and Timer X
0011XXXX2
256 – 1
256 – 1
.....
(address 002316),
bit3
TM
0
•Timer X count start
.....
•Interrupts enabled
CLI
Main processing
.....
<Procedure for completion of clock set>
(Note 1)
PREX (address 002416)
256 – 1
TX
(address 002516)
256 – 1
IREQ1 (address 003C16), bit4
0
•Reset Timer to restart count from 0 second after completion
of clock set
Note 1: Perform procedure for completion of clock set only
when completing clock set.
Timer X interrupt process routine
CLT (Note 2)
CLD (Note 3)
Push registers to stack
Clock stop ?
Note 2: When using Index X mode flag (T)
Note 3: When using Decimal mode flag (D)
•Push registers used in interrupt process routine
Y
•Judge whether clock stops
N
Clock count up (1/4 second to year)
Pop registers
•Clock count up
•Pop registers pushed to stack
RTI
Fig. 2.3.17 Control procedure
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APPLICATION
3804 Group (Spec.H)
2.3 Timer
(3) Timer application example 2: Piezoelectric buzzer output
Outline: The rectangular waveform output function of the timer is applied for a piezoelectric buzzer
output.
Specifications: •The rectangular waveform, dividing the clock f(XIN) = 8 MHz into about 2 kHz (2049
Hz), is output from the P4 7/CNTR 2 pin.
•The level of the P47/CNTR 2 pin is fixed to “H” while a piezoelectric buzzer output
stops.
Figure 2.3.18 shows a peripheral circuit example, and Figure 2.3.19 shows the timers connection and
setting of division ratios. Figure 2.3.20 shows the relevant registers setting, and Figure 2.3.21 shows
the control procedure.
The “H” level is output while a piezoelectric buzzer output stops.
CNTR2 output
P47/CNTR2
PiPiPi.....
244 µs 244 µs
Set a division ratio so that the
underflow output period of the timer Z 3804 Group (Spec. H)
can be 244 µs.
Fig. 2.3.18 Peripheral circuit example
Timer Z count source
selection bit
Timer Z
f(XIN) = 8 MHz
1/16
1/122
CNTR2
Fig. 2.3.19 Timers connection and setting of division ratios
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APPLICATION
3804 Group (Spec.H)
2.3 Timer
Timer Y, Z count source selection register (address 000F16)
b7
TYZCSS
b0
0 0 1 1
Timer Z count source: f(XIN)/16
Timer Z mode register (address 002A16)
b7
b0
1 0
TM
0 0 0 1
Timer Z operating mode : Pulse output mode
Write value in latch and timer at the same time
CNTR2 active edge switch : Output starting at “H” level
Timer Z count : Stop
Clear to “0” when starting count
Timer Z high-order (address 002916)
b7
TZH
b0
0
Timer Z low-order (address 002816)
b7
Set “division ratio – 1”
b0
122–1
TZL
Port P4 direction register (address 000916)
b7
P4D
b0
1
P47/CNTR2 : Output mode
Port P4 (address 000816)
b7
P4
b0
1
“H” output at stopping buzzer output
Fig. 2.3.20 Relevant registers setting
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APPLICATION
3804 Group (Spec.H)
2.3 Timer
● X: This bit is not used here. Set it to “0” or “1” arbitrarily.
RESET
Initialization
.....
P4 (address 000816), bit7
P4D (address 000916)
1
1XXXXXXX2
.....
•Timer Z interrupt disabled
•Timer Z count stopped; Buzzer output stopped
•Timer Z: Pulse output mode
•Timer Z count source: f(XIN)/16
•Set (division ratio – 1) to timer Z
ICON1 (address 003E16), bit0
0
X10X00012
(address 002A16)
TZM
TYZCSS (address 000F16)
(address 002816)
TZL
(address 002916)
TZH
0011XXXX2
122–1
0
.....
Main processing
.....
•Processing buzzer request, generated during main
processing, in output unit
Output unit
Yes
Buzzer request ?
No
TZM
(address 002A16), bit6
Stop of piezoelectric buzzer
output
1
TZM
(address 002A16), bit6
0
Start of piezoelectric buzzer output
Fig. 2.3.21 Control procedure
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APPLICATION
3804 Group (Spec.H)
2.3 Timer
(4) Timer application example 3: Frequency measurement
Outline: The following two values are compared to judge whether the frequency is within a valid
range.
•A value by counting pulses input to P5 5/CNTR 1 pin with the timer.
•A reference value
Specifications: •The pulse is input to the P5 5/CNTR 1 pin and counted by the timer Y.
•The clock f(XIN) = 8 MHz is dividing by the timer 1, and the interrupt request occurs
at about 2 ms intervals.
•A count value is read out at about 2 ms intervals, the timer 1 interrupt interval.
When the count value is 28 to 40, it is judged that the input pulse is valid.
•Because the timer is a down-counter, the count value is compared with 227 to 215
(Note).
Note: 227 to 215 = {255 (initial value of counter) – 28} to {255 – 40}; 28 to 40 means the number
of valid count value.
Figure 2.3.22 shows the judgment method of valid/invalid of input pulses; Figure 2.3.23 shows the
relevant registers setting; Figure 2.3.24 shows the control procedure.
Input pulse
•••••
71.4 µs or more
(less than 14 kHz)
•••••
71.4 µs
(14 kHz)
Invalid
•••••
50 µs
(20 kHz)
Valid
2 ms = 28 counts
71.4 µs
50 µs or less
(20 kHz or more)
Invalid
2 ms
50 µs
= 40 counts
Fig. 2.3.22 Judgment method of valid/invalid of input pulses
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APPLICATION
3804 Group (Spec.H)
2.3 Timer
Timer XY mode register (address 002316)
b7
TM
1
b0
1 1 0
Timer Y operating mode: Event counter mode
CNTR1 active edge switch: Falling edge count
Timer Y count: Stop
Clear to “0” when starting count
Timer 12, X count source selection register (address 000E16)
b7
b0
T12XCSS
0 1 0 0
f(XIN)/32: select
Prescaler 12 (address 002016)
b7
b0
PRE12
64 – 1
Timer 1 (address 002116)
b7
b0
T1
8–1
Set “division ratio – 1”
Prescaler Y (address 002616)
b7
b0
PREY
1–1
Timer Y (address 002716)
b7
b0
TY
Set 255 just before counting pulses
(After a certain time has passed, the number of input
pulses is decreased from this value.)
255
Interrupt control register 1 (address 003E16)
b7
ICON1
b0
1 0
Timer Y interrupt: Disabled
Timer 1 interrupt: Enabled
Interrupt request register 1 (address 003C16)
b7
IREQ1
b0
0
Judgment of Timer Y interrupt request bit
( “1” of this bit when reading the count value indicates the 256 or more
pulses input in the condition of Timer Y = 255)
Fig. 2.3.23 Relevant registers setting
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APPLICATION
3804 Group (Spec.H)
2.3 Timer
RESET
● x: This bit is not used here. Set it to “0” or “1” arbitrary.
Initialization
SEI
•All interrupts disabled
... ..
1110XXXX2
(address 002316)
TM
T12XCSS(address 000E16)
XXXX01002
PRE12 (address 002016)
64 – 1
(address 002116)
T1
8–1
(address 002616)
PREY
1–1
(address 002716)
TY
255
IREQ1 (address 003C16)
X00XXXXX2
1
ICON1 (address 003E16), bit6
•Timer Y operating mode : Event counter mode
(Count a falling edge of pulses input from CNTR1 pin.)
•Set division ratio so that Timer 1 interrupt will occur at
2 ms intervals.
•Timer 1, Y interrupt request bit cleared
•Timer 1 interrupt: Enabled
... ..
0
(address 002316), bit7
TM
•Timer Y count start
... ..
•Interrupts enabled
CLI
Timer 1 interrupt process routine
CLT (Note 1)
CLD (Note 2)
Push registers to stack
Note 1: When using Index X mode flag (T)
Note 2: When using Decimal mode flag (D)
•Push registers used in interrupt process routine
1
IREQ1(address 003C16), bit5 ?
•Process as out of range when the count value is 256 or more
0
(A)
TY (address 002716)
•Read the count value
•Store the count value into Accumulator (A)
In range
•Compare the read value with
reference value
•Store the comparison result to
flag Fpulse
214 < (A) < 228
Out of range
Fpulse
0
TY
(address 002716)
IREQ1 (address 003C16), bit5
Fpulse
256 – 1
0
1
•Initialize the counter value
•Clear Timer Y interrupt request bit
Process judgment result
Pop registers
•Pop registers pushed to stack
RTI
Fig. 2.3.24 Control procedure
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APPLICATION
3804 Group (Spec.H)
2.3 Timer
(5) Timer application example 4: Measurement of FG pulse width for motor
Outline: The timer Z counts the “H” level width of the pulses input to the P47/CNTR2 pin. An underflow
is detected by the timer Z interrupt and an end of the input pulse “H” level is detected by
the P4 7/CNTR2 interrupt.
Specifications: •The timer Z counts the “H” level width of the FG pulse input to the P4 7/CNTR 2 pin.
<Example>
When the clock frequency is 8 MHz, the count source is 2 µs, which is obtained by dividing the
clock frequency by 16. Measurement can be made up to 131.072 ms in the range of FFFF 16 to
0000 16.
Figure 2.3.25 shows the timers connection and setting of division ratio; Figure 2.3.26 shows the
relevant registers setting; Figure 2.3.27 and Figure 2.3.28 show the control procedure.
Timer Z count source
selection bit
f(XIN) = 8 MHz
1/16
Timer Z
Timer Z interrupt
request bit
1/65536
0 or 1
131.072 ms
0 : No interrupt request issued
1 : Interrupt request issued
Fig. 2.3.25 Timers connection and setting of division ratios
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APPLICATION
3804 Group (Spec.H)
2.3 Timer
Port P4 direction register (address 000916)
b7
P4D
b0
0
P47/CNTR2: Input mode
Timer Z mode register (address 002A16)
b7
TZM
b0
1 0
0 0 1 1
Timer Z operating mode: Pulse width measurement mode
Write in latch and timer at the same time
CNTR2 active edge switch: “H” level width measurement
Timer Z count: Stop
Clear to “0” when starting count
Timer Y, Z count source selection register (address 000F16)
b7
TYZCSS
b0
0 0 1 1
Timer Z count source: f(XIN)/16
Timer Z high-order (address 002916)
b7
b0
TZH
FF16
Timer Z low-order (address 002816)
b7
b0
TZL
Set initial value “FFFF16” before starting pulse
width measurement. (When not setting the
initial value, count is started from the timer
value before measurement start.)
FF16
Interrupt source selection register (address 003916)
b7
b0
INTSEL
1
1
INT0/timer Z interrupt source: Timer Z interrupt
INT4/CNTR2 interrupt source: CNTR2 interrupt
Interrupt request register 1 (address 003C16)
b7
b0
IREQ1
0
Timer Z interrupt request
(Set to “1” automatically when Timer Z underflows)
Interrupt control register 1 (address 003E16)
b7
b0
1
ICON1
Timer Z interrupt: Enabled
Interrupt request register 2 (address 003D16)
b7
IREQ2
b0
0
CNTR2 interrupt request
(Set to “1” automatically when “H” level input came to the end)
Interrupt control register 2 (address 003F16)
b7
ICON2
b0
1
CNTR2 interrupt: Enabled
Fig. 2.3.26 Relevant registers setting
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APPLICATION
3804 Group (Spec.H)
2.3 Timer
RESET
● x: This bit is not used here. Set it to “0” or “1” arbitrarily.
Initialization
SEI
•All interrupts disabled
.....
....
0XXXXXXX2
(address 000916)
P4D
X10X00112
(address 002A16)
TZM
0011XXXX2
TYZCSS (address 000F16)
FF16
(address 002816)
TZL
FF16
(address 002916)
TZH
XXX1XXX12
INTSEL (address 003916)
IREQ1 (address 003C16), bit0
0
ICON1 (address 003E16), bit0
1
IREQ2 (address 003D16), bit5
0
ICON2 (address 003F16), bit5
1
....
TZM
(address 002A16), bit6
0
•Set P47/CNTR2 pin to input mode
•Timer Z: Pulse width measurement mode
(Measure “H” level of pulses input from CNTR2 pin.)
•Set timer Z initial value
•Timer Z interrupt enabled
•CNTR2 interrupt enabled
•Timer Z count start
•Interrupts enabled
CLI
Timer Z interrupt process routine
CLT (Note 1)
CLD (Note 2)
Push registers to stack
Note 1: When using Index X mode flag (T)
Note 2: When using Decimal mode flag (D)
•Push registers used in interrupt process routine
Error processing
Pop registers
•Pop registers pushed to stack
RTI
Note: Timer Z interrupt also occurs owing to factors other than measurement level.
(CNTR2 input =“L” in this application)
Process it by software as error processing is performed for measurement level as necessary.
(CNTR2 input level can be checked by reading the contents of sharing port P47 register.)
Fig. 2.3.27 Control procedure (1)
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APPLICATION
3804 Group (Spec.H)
2.3 Timer
CNTR2 interrupt process routine (Note 1)
Notes 2: When using Index X mode flag (T)
3: When using Decimal mode flag (D)
•Pushing registers used in interrupt process routine
CLT (Note 2)
CLD (Note 3)
Push registers to stack
(A)
Measurement result (high-order 8 bits)
(A)
Measurement result (low-order 8 bits)
TZH
(A)
TZL
(A)
Pop registers
•Count value read and storing it to RAM
•Popping registers pushed to stack
RTI
Note 1: The first value becomes invalid depending on start timing of Timer Z count shown
by the following figure.
Process it by software as necessary.
[ Example 1] • Start Timer Z count when CNTR2 input level is “L”.
(CNTR2 input level can be checked by reading the contents of sharing port P47 register.)
FFFF16
T1
T2
000016
T1 value: Valid
T2 value: Valid
CNTR2
Count start of
Timer Z
CNTR2 interrupt
CNTR2 interrupt
[ Example 2] • Start Timer Z count when CNTR2 input level is “H”.
Invalidate the first CNTR2 interrupt after start of Timer Z count.
FFFF16
T1
T2
000016
T1 value: Invalid
T2 value: Valid
CNTR2
Count start of
CNTR2 interrupt
Timer z
CNTR2 interrupt
Fig. 2.3.28 Control procedure (2)
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APPLICATION
3804 Group (Spec.H)
2.3 Timer
2.3.4 Notes on timer
Notes on 8-bit timer (timer 1, 2, X, Y)
● If a value n (between 0 and 255) is written to a timer latch, the frequency division ratio is 1/(n+1).
● When switching the count source by the timer 12, X and Y count source selection bits, the value
of timer count is altered in unconsiderable amount owing to generating of thin pulses in the count
input signals.
Therefore, select the timer count source before set the value to the prescaler and the timer.
● Set the double-function port of the CNTR0/CNTR1 pin and port P54/P55 to output in the pulse output
mode.
● Set the double-function port of CNTR 0/CNTR 1 pin and port P54/P5 5 to input in the event counter
mode and the pulse width measurement mode.
Notes on 16-bit timer (timer Z)
(1) Pulse output mode
● Set the double-function port of the CNTR 2 pin and port P4 7 to output.
(2) Pulse period measurement mode
● Set the double-function port of the CNTR 2 pin and port P4 7 to input.
● A read-out of timer value is impossible in this mode. The timer can be written to only during timer
stop (no measurement of pulse period).
● Since the timer latch in this mode is specialized for the read-out of measured values, do not
perform any write operation during measurement.
● “FFFF 16 ” is set to the timer when the timer underflows or when the valid edge of measurement
start/completion is detected. Consequently, the timer value at start of pulse period measurement
depends on the timer value just before measurement start.
(3) Pulse width measurement mode
● Set the double-function port of the CNTR 2 pin and port P4 7 to input.
● A read-out of timer value is impossible in this mode. The timer can be written to only during timer
stop (no measurement of pulse period).
● Since the timer latch in this mode is specialized for the read-out of measured values, do not
perform any write operation during measurement.
● “FFFF 16 ” is set to the timer when the timer underflows or when the valid edge of measurement
start/completion is detected. Consequently, the timer value at start of pulse width measurement
depends on the timer value just before measurement start.
(4) Programmable waveform generating mode
● Set the double-function port of the CNTR 2 pin and port P4 7 to output.
(5) Programmable one-shot generating mode
● Set the double-function port of CNTR 2 pin and port P4 7 to output, and of INT1 pin and port P42 to
input in this mode.
● This mode cannot be used in low-speed mode.
● If the value of the CNTR2 active edge switch bit is changed during one-shot generating enabled
or generating one-shot pulse, then the output level from CNTR2 pin changes.
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APPLICATION
3804 Group (Spec.H)
2.3 Timer
(6) All modes
●Timer Z write control
Which write control can be selected by the timer Z write control bit (bit 3) of the timer Z mode
register (address 002A 16), writing data to both the latch and the timer at the same time or writing
data only to the latch.
When the operation “writing data only to the latch” is selected, the value is set to the timer latch
by writing data to the address of timer Z and the timer is updated at next underflow. After reset
release, the operation “writing data to both the latch and the timer at the same time” is selected,
and the value is set to both the latch and the timer at the same time by writing data to the address
of timer Z.
In the case of writing data only to the latch, if writing data to the latch and an underflow are
performed almost at the same time, the timer value may become undefined.
●Timer Z read control
A read-out of timer value is impossible in pulse period measurement mode and pulse width measurement
mode. In the other modes, a read-out of timer value is possible regardless of count operating or
stopped.
However, a read-out of timer latch value is impossible.
●Switch of interrupt active edge of CNTR 2 and INT 1
Each interrupt active edge depends on setting of the CNTR 2 active edge switch bit and the INT1
active edge selection bit.
●Switch of count source
When switching the count source by the timer Z count source selection bits, the value of timer
count is altered in inconsiderable amount owing to generating of thin pulses on the count input
signals.
Therefore, select the timer count source before setting the value to the prescaler and the timer.
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APPLICATION
3804 Group (Spec.H)
2.4 Serial interface
2.4 Serial interface
This paragraph explains the registers setting method and the notes relevant to Serial I/O.
2.4.1 Memory map
Address
001816
Transmit/Receive buffer register 1 (TB1/RB1)
001916
Serial I/O1 status register (SIO1STS)
001A16
Serial I/O1 control register (SIO1CON)
001B16
UART1 control register (UART1CON)
001C16
Baud rate generator 1 (BRG1)
001D16
Serial I/O2 control register (SIO2CON)
001F16
Serial I/O2 register (SIO2)
002F16
Baud rate generator 3 (BRG3)
003016
Transmit/Receive buffer register 3 (TB3/RB3)
003116
003216
Serial I/O3 status register (SIO3STS)
Serial I/O3 control register (SIO3CON)
003316
UART3 control register (UART3CON)
003916
Interrupt source selection register (INTSEL)
003C16
Interrupt request register 1 (IREQ1)
003D16
Interrupt request register 2 (IREQ2)
003E16
Interrupt control register 1 (ICON1)
Interrupt control register 2 (ICON2)
003F16
Fig. 2.4.1 Memory map of registers relevant to Serial I/O
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APPLICATION
3804 Group (Spec.H)
2.4 Serial interface
2.4.2 Relevant registers
Transmit/Receive buffer register 1, Transmit/Receive buffer register 3
b7 b6 b5 b4 b3 b2 b1 b0
Transmit/Receive buffer register 1 (TB1/RB1: address 001816)
Transmit/Receive buffer register 3 (TB3/RB3: address 003016)
b
Functions
0
1
2
3
4
5
6
7
The transmission data is written to or the
receive data is read out from this buffer register.
• At write: A data is written to the transmit buffer
register.
• At read: The contents of the receive buffer
register are read out.
At reset R W
Undefined
Undefined
Undefined
Undefined
Undefined
Undefined
Undefined
Undefined
Note: The contents of transmit buffer register cannot be read out.
The data cannot be written to the receive buffer register.
Fig. 2.4.2 Structure of Transmit/Receive buffer register 1 and Transmit/Receive buffer register 3
Serial I/O1 status register, Serial I/O3 status register
b7 b6 b5 b4 b3 b2 b1 b0
Serial I/O1 status register (SIO1STS: address 001916)
Serial I/O3 status register (SIO3STS: address 003116)
b
Name
0 Transmit buffer
empty flag (TBE)
1 Receive buffer full
flag (RBF)
2 Transmit shift register
shift completion flag
(TSC)
Functions
0: Buffer full
1: Buffer empty
0: Buffer empty
1: Buffer full
0: Transmit shift in progress
1: Transmit shift completed
3 Overrun error flag 0: No error
(OE)
1: Overrun error
4 Parity error flag
0: No error
(PE)
1: Parity error
5 Framing error flag 0: No error
(FE)
1: Framing error
6 Summing error flag 0: (OE) U (PE) U (FE) = 0
(SE)
1: (OE) U (PE) U (FE) = 1
7 Nothing is arranged for this bit. This bit is a
write disabled bit. When this bit is read out, the
contents are “1”.
At reset R W
✕
0
0
✕
0
✕
0
✕
0
✕
0
✕
0
✕
1
✕
Fig. 2.4.3 Structure of Serial I/O1 status register and Serial I/O3 status register
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2.4 Serial interface
Serial I/O1 control register
b7 b6 b5 b4 b3 b2 b1 b0
Serial I/O1 control register
(SIO1CON: address 001A16)
b
Name
Functions
0 BRG count source 0: f(XIN)
selection bit (CSS) 1: f(XIN)/4
When clock synchronous
1 Serial I/O1
synchronous clock serial I/O is selected,
selection bit (SCS) 0: BRG output divided by 4
1: External clock input
When UART is selected,
0: BRG output divided by 16
1: External clock input
divided by16
At reset R W
0
0
2 SRDY1 output
enable bit (SRDY)
0: I/O port (P47)
1: SRDY1 output pin
0
3 Transmit interrupt
source selection
bit (TIC)
0: Transmit buffer empty
1: Transmit shift operation
completion
0
4 Transmit enable bit
(TE)
5 Receive enable bit
(RE)
6 Serial I/O1 mode
selection bit (SIOM)
0: Transmit disabled
1: Transmit enabled
0: Receive disabled
1: Receive enabled
0: UART
1: Clock synchronous
serial I/O
0: Serial I/O1 disabled
(P44 to P47: normal I/O pins)
1: Serial I/O1 enabled
(P44 to P47: Serial I/O pins)
0
7 Serial I/O1 enable
bit (SIOE)
0
0
0
Fig. 2.4.4 Structure of Serial I/O1 control register
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2.4 Serial interface
Serial I/O3 control register
b7 b6 b5 b4 b3 b2 b1 b0
Serial I/O3 control register
(SIO3CON: address 003216)
b
Name
Functions
0 BRG count source 0: f(XIN)
selection bit (CSS) 1: f(XIN)/4
When clock synchronous
1 Serial I/O3
synchronous clock serial I/O is selected,
selection bit (SCS) 0: BRG output divided by 4
1: External clock input
When UART is selected,
0: BRG output divided by 16
1: External clock input
divided by16
At reset R W
0
0
2 SRDY3 output
enable bit (SRDY)
0: I/O port (P37)
1: SRDY3 output pin
0
3 Transmit interrupt
source selection
bit (TIC)
0: Transmit buffer empty
1: Transmit shift operation
completion
0
4 Transmit enable bit
(TE)
5 Receive enable bit
(RE)
6 Serial I/O3 mode
selection bit (SIOM)
0: Transmit disabled
1: Transmit enabled
0: Receive disabled
1: Receive enabled
0: UART
1: Clock synchronous
serial I/O
0: Serial I/O3 disabled
(P34 to P37: normal I/O pins)
1: Serial I/O3 enabled
(P34 to P37: Serial I/O pins)
0
7 Serial I/O3 enable
bit (SIOE)
0
0
0
Fig. 2.4.5 Structure of Serial I/O3 control register
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2.4 Serial interface
UART1 control register
b7 b6 b5 b4 b3 b2 b1 b0
UART1 control register
(UART1CON: address 001B16)
b
Name
Functions
At reset R W
0 Character length
0: 8 bits
selection bit (CHAS) 1: 7 bits
0
1 Parity enable bit
(PARE)
0: Parity checking disabled
1: Parity checking enabled
0
2 Parity selection bit
(PARS)
0: Even parity
1: Odd parity
0
3 Stop bit length
0: 1 stop bit
selection bit (STPS) 1: 2 stop bits
0
4 P45/TxD1 P-channel 0: CMOS output
output disable bit
(in output mode)
(POFF)
1: N-channel open-drain
output (in output mode)
5 Nothing is arranged for these bits. These are
6 write disabled bits. When these bits are read
out, the contents are “1”.
7
0
1
1
1
✕
✕
✕
Fig. 2.4.6 Structure of UART1 control register
UART3 control register
b7 b6 b5 b4 b3 b2 b1 b0
UART3 control register
(UART3CON: address 003316)
b
Name
Functions
At reset R W
0 Character length
0: 8 bits
selection bit (CHAS) 1: 7 bits
0
1 Parity enable bit
(PARE)
0: Parity checking disabled
1: Parity checking enabled
0
2 Parity selection bit
(PARS)
0: Even parity
1: Odd parity
0
3 Stop bit length
0: 1 stop bit
selection bit (STPS) 1: 2 stop bits
0
4 P35/TxD3 P-channel 0: CMOS output
output disable bit
(in output mode)
(POFF)
1: N-channel open-drain
output (in output mode)
5 Nothing is arranged for these bits. These are
6 write disabled bits. When these bits are read
out, the contents are “1”.
7
0
1
1
1
✕
✕
✕
Fig. 2.4.7 Structure of UART3 control register
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2.4 Serial interface
Baud rate generator i (i = 1, 3)
b7 b6 b5 b4 b3 b2 b1 b0
Baud rate generator i
(BRGi (i=1, 3): address 001C16, 002F16)
b
Functions
At reset R W
0 Set a count value of baud rate generator.
Undefined
1
Undefined
2
Undefined
3
Undefined
4
Undefined
5
Undefined
6
Undefined
7
Undefined
Note: Write to this register while transmit/receive operation is stopped.
Fig. 2.4.8 Structure of Baud rate generator 1 and Baud rate generator 3
Serial I/O2 control register
b7 b6 b5 b4 b3 b2 b1 b0
Serial I/O2 control register
(SIO2CON: address 001D16)
b
Name
0 Internal
synchronous clock
1 selection bits
2
3 Serial I/O2 port
selection bit
4 SRDY2 output
enable bit
5 Transfer direction
selection bit
6 Serial I/O2
synchronous
clock selection bit
7 P51/SOUT2
P-channel output
disable bit
Functions
b2b1b0
0 0 0: f(XIN)/8
0 0 1: f(XIN)/16
0 1 0: f(XIN)/32
0 1 1: f(XIN)/64
1 1 0: f(XIN)/128
1 1 1: f(XIN)/256
0: I/O port (P51, P52)
1: SOUT2, SCLK2 signal output
0: I/O port (P53)
1: SRDY2 signal output
0: LSB first
1: MSB first
0: External clock
1: Internal clock
0: CMOS output
(in output mode)
1: N-channel open-drain
output (in output mode)
At reset R W
0
0
0
0
0
0
0
0
Fig. 2.4.9 Structure of Serial I/O2 control register
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2.4 Serial interface
Serial I/O2 register
b7 b6 b5 b4 b3 b2 b1 b0
Serial I/O2 register
(SIO2: address 001F16)
b
0
1
2
3
4
5
6
7
Name
Functions
This register becomes shift register.
At transmit: Set transmit data to this register.
At receive: Received data is stored to this
register.
At reset R W
Undefined
Undefined
Undefined
Undefined
Undefined
Undefined
Undefined
Undefined
Fig. 2.4.10 Structure of Serial I/O2 register
Interrupt source selection register
b7 b6 b5 b4 b3 b2 b1 b0
Interrupt source selection register
(INTSEL: address 003916)
b
Name
Functions
At reset R W
0 INT0/Timer Z
interrupt source
selection bit (*1)
0: INT0 interrupt
1: Timer Z interrupt
0
1 Serial I/O2/Timer Z
interrupt source
selection bit (*1)
2 Serial I/O1 transmit/
SCL, SDA interrupt
source selection bit
(*2)
0: Serial I/O2 interrupt
1: Timer Z interrupt
0
0: Serial I/O1 transmit
interrupt
1: SCL, SDA interrupt
0
0: CNTR0 interrupt
1: SCL, SDA interrupt
0
0: INT4 interrupt
1: CNTR2 interrupt
0
0: INT2 interrupt
1: I2C interrupt
0: CNTR1 interrupt
1: Serial I/O3 receive
interrupt
0: A/D converter interrupt
1: Serial I/O3 transmit
interrupt
0
3 CNTR0/SCL, SDA
interrupt source
selection bit (*2)
4 INT4/CNTR2
interrupt source
selection bit
5 INT2/I2C interrupt
source selection bit
6 CNTR1/Serial I/O3
receive interrupt
source selection bit
7 AD converter/Serial
I/O3 transmit
interrupt source
selection bit
0
0
*1: Do not write 1 to these bits simultaneously.
*2: Do not write 1 to these bits simultaneously.
Fig. 2.4.11 Structure of Interrupt source selection register
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2.4 Serial interface
Interrupt request register 1
b7 b6 b5 b4 b3 b2 b1 b0
Interrupt request register 1
(IREQ1 : address 003C16)
b
Name
Functions
At reset R W
0 INT0/Timer Z
0 : No interrupt request issued
interrupt request bit 1 : Interrupt request issued
0
✽
1 INT1 interrupt
request bit
0
✽
2 Serial I/O1 receive 0 : No interrupt request issued
interrupt request bit 1 : Interrupt request issued
0
✽
0 : No interrupt request issued
3 Serial I/O1
transmit/SCL, SDA 1 : Interrupt request issued
interrupt request bit
0
✽
4 Timer X interrupt
request bit
0 : No interrupt request issued
0
✽
5 Timer Y interrupt
request bit
0 : No interrupt request issued
0
✽
6 Timer 1 interrupt
request bit
0 : No interrupt request issued
0
✽
0
✽
0 : No interrupt request issued
1 : Interrupt request issued
1 : Interrupt request issued
1 : Interrupt request issued
1 : Interrupt request issued
7 Timer 2 interrupt
0 : No interrupt request issued
request bit
1 : Interrupt request issued
✽: 0 can be set by software, but 1 cannot be set.
Fig. 2.4.12 Structure of Interrupt request register 1
Interrupt request register 2
b7 b6 b5 b4 b3 b2 b1 b0
Interrupt request register 2
(IREQ2 : address 003D16)
b
Name
Functions
At reset R W
0 CNTR0/SCL, SDA
interrupt request bit
1 CNTR1/Serial I/O3
receive interrupt
request bit
0 : No interrupt request issued
1 : Interrupt request issued
0 : No interrupt request issued
1 : Interrupt request issued
0
✽
0
✽
2 Serial I/O2/Timer Z
interrupt request bit
3 INT2/I2C interrupt
request bit
4 INT3 interrupt
request bit
5 INT4/CNTR2
interrupt request bit
6 AD converter/Serial
I/O3 transmit
interrupt request bit
0 : No interrupt request issued
1 : Interrupt request issued
0 : No interrupt request issued
1 : Interrupt request issued
0 : No interrupt request issued
1 : Interrupt request issued
0 : No interrupt request issued
1 : Interrupt request issued
0 : No interrupt request issued
1 : Interrupt request issued
0
✽
0
✽
0
✽
0
✽
0
✽
7 Nothing is arranged for this bit. This is a write
disabled bit. When this bit is read out, the
contents are 0 .
0
✽: 0 can be set by software, but 1 cannot be set.
Fig. 2.4.13 Structure of Interrupt request register 2
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2.4 Serial interface
Interrupt control register 1
b7 b6 b5 b4 b3 b2 b1 b0
Interrupt control register 1
(ICON1 : address 003E16)
b
Name
Functions
At reset R W
0 INT0/Timer Z
interrupt enable bit
1 INT1 interrupt
enable bit
2 Serial I/O1 receive
interrupt enable bit
3 Serial I/O1
transmit/SCL, SDA
interrupt enable bit
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0
4 Timer X interrupt
enable bit
5 Timer Y interrupt
enable bit
6 Timer 1 interrupt
enable bit
7 Timer 2 interrupt
enable bit
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0
0
0
0
0
0
0
Fig. 2.4.14 Structure of Interrupt control register 1
Interrupt control register 2
b7 b6 b5 b4 b3 b2 b1 b0
0
Interrupt control register 2
(ICON2 : address 003F16)
b
Name
Functions
At reset R W
0 CNTR0/SCL, SDA
interrupt enable bit
1 CNTR1/ Serial I/O3
receive interrupt
enable bit
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0
2 Serial I/O2/ Timer Z
interrupt enable bit
3 INT2/I2C interrupt
enable bit
4 INT3 interrupt
enable bit
5 INT4/CNTR2
interrupt enable bit
6 AD converter/Serial
I/O3 transmit
interrupt enable bit
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
0
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0
7 Fix this bit to “0”.
0
0
0
0
0
Fig. 2.4.15 Structure of Interrupt control register 2
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2.4 Serial interface
2.4.3 Serial I/O connection examples
(1) Control of peripheral IC equipped with CS pin
Figure 2.4.16 shows connection examples of a peripheral IC equipped with the CS pin.
There are connection examples using a clock synchronous serial I/O mode.
(1) Only transmission
(Using the RXDi pin as an I/O port)
Port
(2) Transmission and reception
CS
SCLKi
CLK
TXDi
DATA
3804 group
Peripheral IC
(Spec. H) (OSD controller etc.)
(3) Transmission and reception
(When connecting RXDi with TXDi)
(When connecting IN with OUT in
peripheral IC)
Port
CS
SCLKi
CLK
TXDi
RXDi
IN
3804 group
(Spec. H)
OUT
Peripheral IC
2
(E PROM etc.)
(4) Connection of plural IC
Port
CS
SCLKi
CLK
CS
TXDi
IN
SCLKi
CLK
R XD i
TXDi
RXDi
IN
Port
OUT
3804 group ✽1 Peripheral IC ✽2
2
(Spec. H)
(E PROM etc.)
Port
3804 group
(Spec. H)
OUT
Peripheral IC 1
CS
CLK
✽1:
Select an N-channel open-drain output for TXDi pin output control.
✽2: Use the OUT pin of peripheral IC which is an N-channel opendrain output and becomes high impedance during receiving data.
IN
OUT
Peripheral IC 2
Notes 1: “Port” means an output port controlled by software.
2: Use SOUT2 and SIN2 instead of TxDi and RxDi for the
serial I/O2. (i = 1, 3)
Fig. 2.4.16 Serial I/O connection examples (1)
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2.4 Serial interface
(2) Connection with microcomputer
Figure 2.4.17 shows connection examples with another microcomputer.
(1) Selecting internal clock
SCLKi
CLK
TXDi
RXDi
3804 group
(Spec. H)
SCLKi
CLK
IN
TXDi
IN
OUT
R XD i
OUT
Microcomputer
(3) Using SRDYi signal output function
(Selecting an external clock)
SRDYi
RDY
SCLKi
CLK
TXDi
IN
RXDi
3804 group
(Spec. H)
(2) Selecting external clock
OUT
Microcomputer
3804 group
(Spec. H)
Microcomputer
(4) In UART ✽
TXDi
R XD
R XD i
TXD
3804 group
(Spec. H)
Microcomputer
✽ UART cannot be used for serial I/O2.
Note: Use SOUT2 and SIN2 instead of TxDi and RxDi for the serial I/O2. (i = 1, 3)
Fig. 2.4.17 Serial I/O connection examples (2)
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2.4 Serial interface
2.4.4 Setting of serial I/O transfer data format
A clock synchronous or clock asynchronous (UART) can be selected as a data format of serial I/O1 and
serial I/O3.
Serial I/O2 operates in a clock synchronous.
Figure 2.4.18 shows the serial I/O transfer data format.
1ST-8DATA-1SP
ST
LSB
MSB
SP
1ST-7DATA-1SP
ST
LSB
MSB
SP
1ST-8DATA-1PAR-1SP
ST
LSB
MSB
PAR
PAR
SP
MSB
2SP
SP
1ST-7DATA-1PAR-1SP
ST
UART
LSB
MSB
1ST-8DATA-2SP
ST
LSB
1ST-7DATA-2SP
ST
Serial I/O1
Serial I/O3
LSB
MSB
2SP
1ST-8DATA-1PAR-2SP
ST
LSB
MSB
PAR
PAR
2SP
2SP
1ST-7DATA-1PAR-2SP
ST
Clock synchronous
Serial I/O
Serial I/O2
Clock synchronous
Serial I/O
LSB
MSB
LSB first
LSB first
MSB first
ST : Start bit
SP : Stop bit
PAR : Parity bit
Fig. 2.4.18 Serial I/O transfer data format
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2.4 Serial interface
2.4.5 Serial I/O1, serial I/O3 operation: stop and initialize
Serial I/O1 and serial I/O3 perform the same operation. In the following explanations when names of serial
I/O1 and serial I/O3 are different, serial I/O1s' are showed first and then serial I/O3s' in the marked ( ).
(1) Clock synchronous serial I/O mode
■Stop/initialize transmit operation when only transmitting
When using an internal clock, set the transmit enable bit and serial I/O1 enable bit (serial I/O3
enable bit) to “0”.
When using an external clock, set the transmit enable bit to “0”.
By setting the transmit enable bit to “0”, the transmit operations listed below will be stopped or
initialized. However, when using an internal clock, the clock is output in 8 pulses, even if the
transmit enable bit is set to “0” during transmit operations.
•Stop supply of shift clock to transmit shift register
•Initialize clock control circuit for transmit
•Transmit buffer empty flag = “0”
•Transmit shift register shift complete flag = “0”
•P4 5/TxD 1 pin: input/output port P4 5 (P35/TxD3 pin: input/output port P35)
By setting the serial I/O1 enable bit (serial I/O3 enable bit) to “0”, pins P4 4/RxD1, P4 5/TxD1, P46/
S CLK1, and P4 7/S RDY1 (P3 4/RxD 3, P3 5/TxD 3, P3 6/S CLK3 , P3 7/S RDY3 pins) all become I/O ports. As a
result, the internal clock cannot be output externally.
■Stop/initialize receive operation when only receiving
When using an internal clock, set the receive enable bit and serial I/O1 enable bit (serial I/O3
enable bit) to “0”.
When using an external clock, set the receive enable bit or serial I/O1 enable bit (serial I/O3
enable bit) to “0”.
By setting the receive enable bit to “0”, the receive operations listed below will be stopped or
initialized. However, when using an internal clock, the clock is output in 8 pulses, even if the
receive enable bit is set to “0” during receive operations.
•Stop supply of shift clock to receive shift register
•Initialize clock control circuit for receive
•Error flags (over-run, parity, framing, and summing error flags) = “0”
•Receive buffer full flag = “0”
•P4 4/RxD 1 pin: input/output port P4 4 (P3 4/RxD 3 pin: input/output port P34)
By setting the serial I/O1 enable bit (serial I/O3 enable bit) to “0”, the receive operations listed
below will be stopped or initialized. As a result, the internal clock cannot be output externally.
•Stop supply of shift clock to receive shift register
•Initialize clock control circuit for receive
•Error flags (over-run, parity, framing, and summing error flags) = “0”
•Receive buffer full flag = “0”
•P44/RxD1, P4 5/TxD 1, P4 6/S CLK1, P4 7/S RDY1 pins: I/O ports P44, P4 5, P4 6, P4 7
(P34/RxD 3, P3 5/TxD3, P3 6/S CLK3, P3 7/SRDY3 pins: I/O ports P3 4, P3 5, P36, P3 7)
■Stop/initialize receive/transmit operation when both receiving and transmitting
Set the transmit enable bit and receive enable bit to “0” simultaneously.
When using an internal clock, also set the serial I/O1 enable bit (serial I/O3 enable bit) to “0”.
(2) UART Mode
■Stop/initialize transmit operation
Set the transmit enable bit to “0”.
■Stop/initialize receive operation
Set the receive enable bit to “0”.
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2.4 Serial interface
2.4.6 Serial I/O pin function and selection method
(1) Serial I/O1, serial I/O3
Table 2.4.1 shows the pin function in the clock synchronous serial I/O mode, Table 2.4.2 shows the
pin function in the UART mode.
Table 2.4.1 Pin function in clock synchronous serial I/O mode
Serial I/O1 control register (address 001A16)
Serial I/O3 control register (address 003216)
Pin name
(Serial I/O1)
Pin name
(Serial I/O3)
b7
Function
(No te 1)
b6
SIOE SIOM
P44/RxD1
P34/RxD3
P45/TxD1
P35/TxD3
P46/SCLK1
P36/SCLK3
(Note 2)
P47/SRDY1
/CNTR2
P37/SRDY3
b5
b4
b3
b2
b1
RE
TE
T IC
SRDY
SCS
Corresponding
direction
CSS register
b0
RxD1, RxD3
1
1
1
1
✕
✕
✕
✕
✕
P44, P34
1
1
0
✕
✕
✕
✕
✕
0/1
TxD1, TxD3
1
1
✕
1
✕
✕
✕
✕
✕
P45, P35
1
1
✕
0
✕
✕
✕
✕
0/1
SCLK1 (External clock input)
1
1
✕
1
✕
✕
1
✕
✕
SCLK1 (Internal clock output)
1
1
✕
1
✕
✕
0
✕
✕
SRDY1, SRDY3
1
1
1
1
✕
1
✕
✕
✕
P47, P37
1
1
✕
✕
✕
0
✕
✕
0/1
Note 1: When SIOE is set to “0”, all pins become I/O ports regardless of set value of b6–b0.
Note 2: In the pulse output mode, the programmable waveform generating mode, or the programmable one-shot generating mode of
the timer Z, this pin functions as the timer Z function output pin regardless of b7-b0 setting.
✕: This is not used for the pin’s function setting.
Table 2.4.2 Pin function in UART mode
Serial I/O1 control register (address 001A16)
Pin name
(Serial I/O1)
Pin name
(Serial I/O3)
P44/RxD1
P34/RxD3
P45/TxD1
P35/TxD3
P46/SCLK1
P36/SCLK3
(Note 2)
P47/SRDY1
/CNTR2
Function
b7
(No te 1)
b6
b5
b4
b3
b2
b1
Corresponding
direction
CSS register
b0
SIOE
SIOM
RE
TE
TIC
SRDY
SCS
RxD
1
0
1
✕
✕
✕
✕
✕
✕
P44
1
0
0
✕
✕
✕
✕
✕
0/1
TxD
1
0
✕
1
✕
✕
✕
✕
✕
P45
1
0
✕
0
✕
✕
✕
✕
0/1
SCLK1 (External clock input)
1
0
✕
✕
✕
✕
1
✕
✕
P46
1
0
✕
✕
✕
✕
0
✕
0/1
P47
1
0
✕
✕
✕
✕
✕
✕
0/1
P37/SRDY3
Note 1: When SIOE is set to “0”, all pins become I/O ports regardless of set value of b6–b0.
Note 2: In the pulse output mode, the programmable waveform generating mode, or the programmable one-shot generating mode of
the timer Z, this pin functions as the timer Z function output pin regardless of b7-b0 setting.
✕: This is not used for the pin’s function setting.
(2) Serial I/O2
Table 2.4.3 shows the pin function in the clock synchronous serial I/O mode.
Table 2.4.3 Pin function in clock synchronous serial I/O mode
Serial I/O2 control register (address 001D16)
Function
Pin name
P50/SIN2
P51/SOUT2
b7
b6
b5
b4
b3
b2
b1
b0
✕
✕
✕
✕
1
✕
✕
✕
0
✕
✕
✕
✕
✕
✕
✕
✕
0/1
CMOS output
0
✕
✕
✕
1
✕
✕
✕
✕
N-channel open-drain output
1
✕
✕
✕
1
✕
✕
✕
✕
(No te 3)
✕
✕
✕
0
✕
✕
✕
0/1
✕
0
✕
✕
1
✕
✕
✕
✕
SIN2
(Note 1)
P50
SOUT2
P51
SCLK2 (External clock input)
P52/SCLK2
P53/SRDY2
C orrespo nding d irection
register
(Note 2)
SCLK2 (Internal clock output)
✕
1
✕
✕
1
✕
✕
✕
✕
P52
✕
✕
✕
✕
0
✕
✕
✕
0/1
SRDY2
✕
✕
✕
1
✕
✕
✕
✕
✕
P53
✕
✕
✕
0
✕
✕
✕
✕
0/1
Notes 1: Although this pin functions as SIN2 when b3 is set to “0”, set “1” to b3.
Notes 2: Although this pin functions as SCLK2 when b3 and the corresponding direction register are set to “0”, set “1” to b3.
Notes 3: When the corresponding direction register bit is "1", the b7 setting is valid.
✕: This is not used for the pin’s function setting.
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3804 Group (Spec.H)
2.4 Serial interface
2.4.7 Serial I/O application examples
(1) Communication using clock synchronous serial I/O (transmit/receive)
Outline : 2-byte data is transmitted and received, using the clock synchronous serial I/O.
The SRDY1 signal is used for communication control.
Figure 2.4.19 shows a connection diagram, and Figure 2.4.20 shows a timing chart.
Figure 2.4.21 shows a registers setting relevant to the transmitting side, and Figure 2.4.22 shows
registers setting relevant to the receiving side.
Transmitting side
Receiving side
P42/INT1
SRDY1
SCLK1
SCLK1
TXD1
R XD 1
3804 group
(Spec. H)
3804 group
(Spec. H)
Note: Use SOUT2 and SIN2 instead of TxDi and RxDi for the serial I/O2. (i = 1, 3)
Fig. 2.4.19 Connection diagram
Specifications : •
•
•
•
Serial I/O is used (clock synchronous serial I/O is selected.)
Synchronous clock frequency : 125 kHz (f(XIN) = 4 MHz is divided by 32)
SRDY1 (receivable signal) is used.
The receiving side outputs SRDY1 signal at intervals of 2 ms (generated by timer),
and 2-byte data is transferred from the transmitting side to the receiving side.
SRDY1
....
SCLK1
....
TXD
D0 D1 D2 D3 D4 D5 D6 D7
D0 D1 D2 D3 D4 D5 D6 D7
D0 D1
....
2 ms
Fig. 2.4.20 Timing chart (using clock synchronous serial I/O)
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3804 Group (Spec.H)
2.4 Serial interface
Transmitting side
AA AA
AA
Port P4 direction register (Address : 000916)
b7
P4D
b0
0
Port P42/INT1: Input mode
AA AA
AA
Serial I/O1 status register (Address : 001916)
b7
SIO1STS
AA AA
AA
b0
Transmit buffer empty flag
• Confirm that the data has been transferred from Transmit buffer
register to Transmit shift register.
• When this flag is “1”, it is possible to write the next transmission
data in to Transmit buffer register.
Transmit shift register shift completion flag
Confirm completion of transmitting 1-byte data with this flag.
“1” : Transmit shift completed
Serial I/O1 control register (Address : 001A16)
b7
SIO1CON
1 1 0 1
b0
0 0
BRG count source : f(XIN)
Serial I/O1 synchronous clock : BRG/4
Transmit enabled
Receive disabled
Clock synchronous serial I/O
Serial I/O1 enabled
Baud rate generator 1 (Address : 001C16)
b7
BRG1
b0
Set “division ratio – 1”
8–1
A AA
Interrupt edge selection register (Address : 003A16)
b7
INTEDGE
b0
0
INT1 falling edge active
Fig. 2.4.21 Registers setting relevant to transmitting side
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APPLICATION
3804 Group (Spec.H)
2.4 Serial interface
Receiving side
AA AA
AA
Serial I/O1 status register (Address : 001916)
b7
SIO1STS
b0
Receive buffer full flag
Confirm completion of receiving 1-byte data with this flag.
“1” : at completing reception
“0” : at reading out contents of Receive buffer register
Overrun error flag
“1” : When data is ready in Receive shift register while Receive buffer
register contains the data.
Parity error flag
“1” : When a parity error occurs in enabled parity.
Framing error flag
“1” : When stop bits cannot be detected at the specified timing
Summing error flag
“1” : when any one of the following errors occurs.
• Overrun error
• Parity error
• Framing error
AA
A
AA A
Serial I/O1 control register (Address : 001A16)
b7
SIO1CON
1 1 1 1
b0
1 1
Serial I/O1 synchronous clock : External clock
SRDY1 output enabled
Transmit enabled
Set this bit to “1”, using SRDY1 output.
Receive enabled
Clock synchronous serial I/O
Serial I/O1 enabled
Fig. 2.4.22 Registers setting relevant to receiving side
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2.4 Serial interface
Figure 2.4.23 shows a control procedure of the transmitting side, and Figure 2.4.24 shows a control
procedure of the receiving side.
RESET
● x: This bit is not used here. Set it to “0” or “1” arbitrarily.
Initialization
... ..
SIO1CON (Address : 001A16)
1101xx002
(Address : 001C16)
8–1
BRG1
0
INTEDGE (Address : 003A16), bit1
0
IREQ1 (Address: 003C16), bit1?
• Detection of INT1 falling edge
1
IREQ1 (Address : 003C16), bit1
0
The first byte of a
transmission data
TB1/RB1
(Address : 001816)
SIO1STS (Address : 001916), bit0?
• Transmission data write
Transmit buffer empty flag is set to “0”
by this writing.
0
1
TB1/RB1
(Address : 001816)
The second byte of a
transmission data
SIO1STS (Address : 001916), bit0?
0
1
SIO1STS (Address : 001916), bit2?
0
• Judgment of transferring from Transmit
buffer register to Transmit shift register
(Transmit buffer empty flag)
• Transmission data write
Transmit buffer empty flag is set to “0”
by this writing.
• Judgment of transferring from Transmit
buffer register to Transmit shift register
(Transmit buffer empty flag)
• Judgment of shift completion of Transmit shift register
(Transmit shift register shift completion flag)
1
Fig. 2.4.23 Control procedure of transmitting side
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3804 Group (Spec.H)
2.4 Serial interface
RESET
● x: This bit is not used here. Set it to “0” or “1” arbitrarily.
Initialization
... ..
SIO1CON (Address : 001A16)
1111x11x2
N
Pass 2 ms?
• An interval of 2 ms generated by Timer.
Y
TB1/RB1 (Address : 001816)
Dummy data
• SRDY1 output
SRDY1 signal is outpu t by writing data to
the TB1/RB1.
Using the SRDY1, set Transmit enable bit
(bit 4) of the SIO1CON to “1”.
0
SIO1STS (Address : 001916), bit1?
• Judgment of completion of receiving
(Receive buffer full flag)
1
• Reception of the first byte data.
Receive buffer full flag is set to “0” by reading data.
Read out reception data from
TB1/RB1 (Address : 001816)
0
SIO1STS (Address : 001916), bit1?
• Judegment of completion of receiving
(Receive buffer full flag)
1
Read out reception data from
TB1/RB1 (Address : 001816)
• Reception of the second byte data.
Receive buffer full flag is set to “0” by reading data.
Fig. 2.4.24 Control procedure of receiving side
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3804 Group (Spec.H)
2.4 Serial interface
(2) Output of serial data (control of peripheral IC)
Outline : 4-byte data is transmitted and received, using the clock synchronous serial I/O.
The CS signal is output to a peripheral IC through port P6 3.
Figure 2.4.25 shows connection diagrams of example for using serial I/O1 and example for using
serial I/O2 with the same specification, and Figure 2.4.26 shows a timing chart.
P63
CS
SCLK1
CLK
TXD1
DATA
3804 group
(Spec. H)
CS
P63
CS
CLK
SCLK2
CLK
DATA
SOUT2
DATA
3804 group
(Spec. H)
Peripheral IC
(1) Example for using Serial I/O1
CS
CLK
DATA
Peripheral IC
(2) Example for using Serial I/O2
Fig. 2.4.25 Connection diagrams
Specifications : • Serial I/O is used (clock synchronous serial I/O is selected.)
• Synchronous clock frequency : 125 kHz (f(XIN) = 4 MHz is divided by 32)
• Transfer direction : LSB first
• The Serial I/O interrupt is not used.
• Port P63 is connected to the CS pin (“L” active) of the peripheral IC for transmission
control; the output level of port P63 is controlled by software.
CS
CLK
DATA
DO0
DO1
DO2
DO3
Note: When using serial I/O2, the SOUT2 pin becomes the high-impedance state
after transfer is completed.
Fig. 2.4.26 Timing chart (serial I/O1)
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2.4 Serial interface
Figure 2.4.27 shows registers setting relevant to serial I/O1, and Figure 2.4.28 shows a setting of
serial I/O1 transmission data.
Serial I/O1 control register (Address : 001A16)
b7
SIO1CON
b0
1 1 0 1 1 0 0 0
BRG count source : f(XIN)
Serial I/O1 synchronous clock : BRG/4
SRDY1 output disabled
Transmit interrupt source : Transmit shift operating completion
Transmit enabled
Receive disabled
Clock synchronous serial I/O
Serial I/O1 enabled
UART1 control register (Address : 001B16)
b7
b0
UART1CON
0
P45/TXD1 pin : CMOS output
Baud rate generator 1 (Address : 001C16)
b7
b0
BRG1
Set “division ratio – 1”
8 –1
Interrupt control register 1 (Address : 003E16)
b7
b0
ICON1
0
Serial I/O1 transmit interrupt : Disabled
Interrupt request register 1 (Address : 003C16)
b7
b0
IREQ1
0
Serial I/O1 transmit interrupt request
Confirm completion of transmitting
1-byte data by one unit.
“1” : Transmit shift completion
Port P6 (Address : 000C16)
b7
b0
P6
1
Port P63: CS signal to peripheral ICs
"L" active
Port P6 direction register (Address : 000D16)
b7
b0
P6D
1
Port P63: Output mode
Fig. 2.4.27 Registers setting relevant to serial I/O1
Transmit/Receive buffer register 1 (Address : 001816)
b7
TB1/RB1
b0
Set a transmission data.
Confirm that transmission of the previous data is
completed (bit 3 of the Interrupt request register 1
is “1”) before writing data.
Fig. 2.4.28 Setting of serial I/O1 transmission data
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3804 Group (Spec.H)
2.4 Serial interface
When the registers are set as shown in Fig. 2.4.27, serial I/O1 can transmit 1-byte data by writing
data to the transmit buffer register.
Thus, after setting the CS signal to “L”, write the transmission data to the transmit buffer register by
each 1 byte, and return the CS signal to “H” when the target number of bytes has been transmitted.
Figure 2.4.29 shows a control procedure of serial I/O1.
RESET
● X: This bit is not used here. Set it to “0” or “1” arbitrarily.
Initialization
....
SIO1CON (Address : 001A16) 110110002
0
UART1CON(Address : 001B16), bit4
8–1
BRG1
(Address : 001C16)
0
ICON1
(Address : 003E16), bit3
1
P6
(Address : 000C16), bit3
P6D
(Address : 000D16) XXXX1XXX2
....
P6 (Address : 000C16), bit3
0
IREQ1 (Address : 003C16), bit3
TB1/RB1 (Address : 001816)
• Serial I/O1 setting
• Serial I/O1 transmit interrupt : Disabled
• CS signal output port setting
(“H” level output)
• CS signal output level to “L” setting
• Serial I/O1 transmit interrupt request bit to
“0” setting
0
a transmission
data
IREQ1 (Address : 003C16), bit3?
• Transmission data write
(Start of transmit 1-byte data)
0
• Judgment of completion of transmitting 1-byte
data
1
N
• Use any of RAM area as a counter for counting
the number of transmitted bytes
• Judgment of completion of transmitting the
target number of bytes
Complete to transmit data?
Y
P6 (Address : 000C16), bit3
1
• Returning CS signal output level to “H”
when transmission of the target number
of bytes is completed
Fig. 2.4.29 Control procedure of serial I/O1
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2.4 Serial interface
Figure 2.4.30 shows registers setting relevant to serial I/O2, and Figure 2.4.31 shows a setting of
serial I/O2 transmission data.
Serial I/O2 control register (Address : 001D16)
b7
SIO2CON
b0
1 0 0 1 0 1 0
Synchronous clock : f(XIN)/32
Serial I/O2 used
SRDY2 output disabled
LSB first
Internal clock
Interrupt source selection register (Address : 003916)
b7
b0
INTSEL
0
Serial I/O2/timer Z interrupt source selection : Serial I/O2 interrupt
Interrupt control register 2 (Address : 003F16)
b7
b0
ICON2
0
Serial I/O2 interrupt : Interrupt disabled
Interrupt request register 2 (Address : 003D16)
b7
b0
IREQ2
0
Port P6 (Address : 000C16)
b7
Serial I/O2 interrupt request
Confirm completion of transmitting
1-byte data by one unit.
“1” : Transmit shift completion
b0
P6
1
Port P63: CS signal to peripheral ICs
"L" active
Port P6 direction register (Address : 000D16)
b7
b0
P6D
1
Port P63: Output mode
Fig. 2.4.30 Registers setting relevant to serial I/O2
Serial I/O2 register (Address : 001F16)
b7
b0
SIO2
Set a transmission data.
Confirm that transmission of the previous data is
completed (bit 2 of the Interrupt request register 2
is “1”) before writing data.
Fig. 2.4.31 Setting of serial I/O2 transmission data
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3804 Group (Spec.H)
2.4 Serial interface
When the registers are set as shown in Fig. 2.4.30, serial I/O2 can transmit 1-byte data by writing
data to the serial I/O2 register.
Thus, after setting the CS signal to “L”, write the transmission data to the serial I/O2 register by each
1 byte, and return the CS signal to “H” when the target number of bytes has been transmitted.
Figure 2.4.32 shows a control procedure of serial I/O2.
RESET
● X: This bit is not used here. Set it to “0” or “1” arbitrarily.
Initialization
....
SIO2CON (Address : 001D16) 010010102
INTSEL (Address : 003916)
XXXXXX0X2
ICON2
(Address : 003F16), bit2
0
P6
(Address : 000C16), bit3
1
P6D
(Address : 000D16) XXXX1XXX2
• Serial I/O2 control register setting
• Serial I/O2 interrupt : Disabled
• CS signal output port setting
(“H” level output)
....
P6 (Address : 000C16), bit3
0
IREQ2 (Address : 003D16), bit2
SIO2 (Address : 001F16)
• CS signal output level to “L” setting
• Serial I/O2 interrupt request bit to “0” setting
0
a transmission
data
IREQ2 (Address : 003D16), bit2?
• Transmission data write
(Start of transmit 1-byte data)
0
• Judgment of completion of transmitting 1-byte
data
1
N
• Use any of RAM area as a counter for counting
the number of transmitted bytes.
• Judgment of completion of transmitting the
target number of bytes
Complete to transmit data?
Y
P6 (Address : 000C16), bit3
1
• Returning CS signal output level to “H”
when transmission of the target number
of bytes is completed
Fig. 2.4.32 Control procedure of serial I/O2
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3804 Group (Spec.H)
2.4 Serial interface
(3) Cyclic transmission or reception of block data (data of specified number of bytes) between
two microcomputers
Outline : When the clock synchronous serial I/O is used for communication, synchronization of the
clock and the data between the transmitting and receiving sides may be lost because of
noise included in the synchronous clock. It is necessary to correct that constantly, using
“heading adjustment”.
This “heading adjustment” is carried out by using the interval between blocks in this
example. This example is described for serial I/O1, but this example also can apply serial
I/O3.
Figure 2.4.33 shows connection diagram.
SCLK1
SCLK1
RXD1
TXD1
TXD1
RXD1
Master unit
Slave unit
Note: Use SOUT2 and SIN2 instead of TxD1 and RxD1 for serial I/O2.
Fig. 2.4.33 Connection diagram
Specifications :
•
•
•
•
•
•
•
•
Serial I/O is used (clock synchronous serial I/O is selected).
Synchronous clock frequency : 131 kHz (f(X IN) = 4.19 MHz is divided by 32)
Byte cycle: 488 µs
Number of bytes for transmission or reception : 8 byte/block
Block transfer cycle : 16 ms
Block transfer term : 3.5 ms
Interval between blocks : 12.5 ms
Heading adjustment time : 8 ms
Limitations of the specifications :
• Reading of the reception data and setting of the next transmission data must be
completed within the time obtained from “byte cycle – time for transferring 1-byte
data” (in this example, the time taken from generating of the serial I/O1 receive
interrupt request to input of the next synchronous clock is 431 µs).
• “Heading adjustment time < interval between blocks” must be satisfied.
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2.4 Serial interface
The communication is performed according to the timing shown in Figure 2.4.34. In the slave unit,
when a synchronous clock is not input within a certain time (heading adjustment time), the next clock
input is processed as the beginning (heading) of a block.
When a clock is input again after one block (8 byte) is received, the clock is ignored.
Figure 2.4.35 shows relevant registers setting.
D0
D1
D2
D7
D0
Byte cycle
Block transfer term
Interval between blocks
Block transfer cycle
Heading adjustment time
Processing for heading adjustment
Fig. 2.4.34 Timing chart
Master unit
Slave unit
Serial I/O1 control register (Address : 001A16)
b7
b0
Serial I/O1 control register (Address : 001A16)
b7
b0
SIO1CON 1 1 1 1
SIO1CON 1 1 1 1 1 0 0 0
BRG count source : f(XIN)
Synchronous clock : BRG/4
SRDY1 output disabled
Transmit interrupt source :
Transmit shift operating completion
Transmit enabled
Receive enabled
Clock synchronous serial I/O
Serial I/O1 enabled
0 1
Not be affected by external clock
Synchronous clock : External clock
SRDY1 output disabled
Not use the serial I/O1 transmit interrupt
Transmit enabled
Receive enabled
Clock synchronous serial I/O
Serial I/O1 enabled
Both of units
UART1 control register (Address : 001B16)
b7
b0
UART1CON
0
P45/TXD1 pin : CMOS output
Baud rate generator 1 (Address : 001C16)
b7
b0
BRG1
8–1
Set “division ratio – 1”
Fig. 2.4.35 Relevant registers setting
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2.4 Serial interface
Control procedure :
● Control in the master unit
After setting the relevant registers shown in Figure 2.4.35, the master unit starts transmission or
reception of 1-byte data by writing transmission data to the transmit buffer register.
To perform the communication in the timing shown in Figure 2.4.34, take the timing into account
and write transmission data. Additionally, read out the reception data when the serial I/O1 transmit
interrupt request bit is set to “1,” or before the next transmission data is written to the transmit
buffer register.
Figure 2.4.36 shows a control procedure of the master unit using timer interrupts.
Interrupt processing routine
executed every 488µs
CLT (Note 1)
CLD (Note 2)
Push register to stack
Within a block transfer
period?
●
Note 1: When using the Index X mode flag (T).
Note 2: When using the Decimal mode flag (D).
Push the register used in the interrupt
processing routine into the stack.
N
●
Y
Y
Start a block transfer?
N
Check the block interval counter and
determine to start a block transfer.
N
Y
Write the first transmission data
(first byte) in a block
Write a transmission data
Pop registers
●
Count a block interval counter
Read a reception data
Complete to transfer a
block?
Generate a certain block interval by
using a timer or other functions.
●
Pop registers which is pushed to stack.
RTI
Fig. 2.4.36 Control procedure of master unit
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2.4 Serial interface
● Control in the slave unit
After setting the relevant registers as shown in Figure 2.4.35, the slave unit becomes the state
where a synchronous clock can be received at any time, and the serial I/O1 receive interrupt
occurs each time an 8-bit synchronous clock is received.
In the serial I/O1 receive interrupt processing routine, the data to be transmitted next is written to
the transmit buffer register after the received data is read out.
However, if no serial I/O1 receive interrupt occurs for a certain time (heading adjustment time or
more), the following processing will be performed.
1. The first 1-byte data of the transmission data in the block is written into the transmit buffer register.
2. The data to be received next is processed as the first 1 byte of the received data in the block.
Figure 2.4.37 shows a control procedure of the slave unit using the serial I/O1 receive interrupt
and any timer interrupt (for heading adjustment).
Timer interrupt processing
routine
Serial I/O1 receive interrupt
processing routine
CLT (Note 1)
CLD (Note 2)
Push register to stack
Within a block transfer
term?
• Push the register used in
the interrupt processing
routine into the stack.
• Confirm the received
byte counter to judge
N the block transfer term.
CLT (Note 1)
CLD (Note 2)
Push register to stack
• Push the register used in
the interrupt processing
routine into the stack.
Heading adjustment
counter – 1
Y
N
Heading adjustment
counter = 0?
Read a reception data
Y
Write the first transmission
data (first byte) in a block
A received byte counter +1
A received byte
counter ≥ 8?
A received byte counter
Y
0
N
Pop registers
Write a transmission data
Write dummy data (FF16)
• Pop registers which is pushed
to stack.
RTI
Initial
value
(Note 3)
Heading
adjustment
counter
Pop registers
RTI
• Pop registers which is pushed
to stack.
Notes 1: When using the Index X mode flag (T).
2: When using the Decimal mode flag (D).
3: In this example, set the value which is equal to the
heading adjustment time divided by the timer interrupt
cycle as the initial value of the heading adjustment
counter.
For example: When the heading adjustment time is 8 ms
and the timer interrupt cycle is 1 ms, set
8 as the initial value.
Fig. 2.4.37 Control procedure of slave unit
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3804 Group (Spec.H)
2.4 Serial interface
(4) Communication (transmit/receive) using asynchronous serial I/O (UART)
Outline : 2-byte data is transmitted and received, using the asynchronous serial I/O.
Port P4 0 is used for communication control.
Figure 2.4.38 shows a connection diagram, and Figure 2.4.39 shows a timing chart.
Transmitting side
Receiving side
P40
P40
TXD
RXD
3804 group
(Spec. H)
3804 group
(Spec. H)
Fig. 2.4.38 Connection diagram (Communication using UART)
Specifications : • Serial I/O1 is used (UART is selected).
• Transfer bit rate : 9600 bps (f(X IN) = 4.9152 MHz is divided by 512)
• Communication control using port P40
(The output level of port P40 is controlled by software.)
• 2-byte data is transferred from the transmitting side to the receiving side at intervals
of 10 ms generated by the timer.
P40
••••
TXD1
ST D0 D1 D2 D3 D4 D5 D6 D7 SP(2) ST D0 D1 D2 D3 D4 D5 D6 D7 SP(2)
ST D0
••••
10 ms
Fig. 2.4.39 Timing chart (using UART)
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3804 Group (Spec.H)
2.4 Serial interface
Table 2.4.4 shows setting examples of the baud rate generator (BRG) values and transfer bit rate
values; Figure 2.4.40 shows registers setting relevant to the transmitting side; Figure 2.4.41 shows
registers setting relevant to the receiving side.
Table 2.4.4 Setting examples of Baud rate generator (BRG) values and transfer bit rate values
BRG count source
(Note 1)
BRG setting value
Transfer bit rate (bps) (Note 2)
at f(X IN) = 4.9152 MH Z
at f(X IN ) = 16 MH Z
f(X IN)/4
255(FF16)
300
f(X IN)/4
127(7F 16)
600
1953.125
f(X IN)/4
63(3F16)
1200
3906.25
f(X IN)/4
31(1F16)
2400
7812.5
f(X IN)/4
15(0F16)
4800
15625
f(X IN)/4
7(0716)
9600
31250
f(X IN)/4
3(0316)
19200
62500
f(X IN)/4
1(0116)
38400
125000
f(X IN)
3(0316)
76800
250000
f(X IN)
1(0116)
153600
500000
f(X IN)
0(0016)
307200
1000000
976.5625
Notes 1: Select the BRG count source with bit 0 of the serial I/O1 control register (Address : 001A 16).
2: Equation of transfer bit rate:
Transfer bit rate (bps) =
f(XIN)
(BRG setting value + 1) ✕ 16 ✕ m ✽
✽m: When bit 0 of the serial I/O1 control register (Address : 001A 16) is set to “0,” a value of
m is 1.
When bit 0 of the serial I/O1 control register (Address : 001A 16) is set to “1,” a value of
m is 4.
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3804 Group (Spec.H)
2.4 Serial interface
Transmitting side
AA
A
AA A
Serial I/O1 status register (Address : 001916)
b7
b0
SIO1STS
Transmit buffer empty flag
• Confirm that the data has been transferred from Transmit buffer
register to Transmit shift register.
• When this flag is “1”, it is possible to write the next transmission
data in to Transmit buffer register.
Transmit shift register shift completion flag
Confirm completion of transmitting 1-byte data with this flag.
“1” : Transmit shift completed
AA A
Serial I/O1 control register (Address : 001A16)
b7
SIO1CON 1 0 0 1
b0
0 0 1
BRG count source : f(XIN)/4
Synchronous clock : BRG/16
SRDY1 output disabled
Transmit enabled
Receive disabled
AA
A
AA A
Asynchronous serial I/O(UART)
Serial I/O1 enabled
UART1 control register (Address : 001B16)
b7
UART1CON
0 1
b0
0 0
Character length : 8 bits
Parity checking disabled
Stop bit length : 2 stop bits
P45/TXD1 pin : CMOS output
Baud rate generator 1 (Address : 001C16)
b7
b0
8–1
BRG1
Set
f(XIN)
Transfer bit rate ✕ 16 ✕ m
✽
–1
✽ When bit 0 of Serial I/O1 control register (Address : 001A16) is set to “0,”
a value of m is 1.
When bit 0 of Serial I/O1 control register (Address : 001A16) is set to “1,”
a value of m is 4.
Port P4 (Address : 000816)
b7
P4
b0
0
Port P40: Communication control: “H” active
Port P4 direction register (Address : 000916)
b7
P4D
b0
1
Port P40: Communication control: Output mode
Fig. 2.4.40 Registers setting relevant to transmitting side
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2.4 Serial interface
Receiving side
AA
A
AA A
Serial I/O1 status register (Address : 001916)
b7
b0
SIO1STS
Receive buffer full flag
Confirm completion of receiving 1-byte data with this flag.
“1” : at completing reception
“0” : at reading out contents of Receive buffer register
Overrun error flag
“1” : When data is ready in Receive shift register while Receive buffer
register contains the data.
Parity error flag
“1” : When a parity error occurs in enabled parity.
Framing error flag
“1” : When stop bits cannot be detected at the specified timing
Summing error flag
“1” : when any one of the following errors occurs.
• Overrun error
• Parity error
• Framing error
AA
A
AA A
Serial I/O1 control register (Address : 001A16)
b7
SIO1CON
1 0 1 0
b0
0 0 1
BRG count source : f(XIN)/4
Synchronous clock : BRG/16
SRDY1 output disabled
Transmit disabled
Receive enabled
Asynchronous serial I/O(UART)
Serial I/O1 enabled
AA
A
AA A
UART1 control register (Address : 001B16)
b7
1
UART1CON
b0
0
0
Character length : 8 bits
Parity checking disabled
Stop bit length : 2 stop bits
Baud rate generator 1 (Address : 001C16)
b7
b0
Set
8–1
BRG1
f(XIN)
Transfer bit rate ✕ 16 ✕ m
✽
–1
✽ When bit 0 of Serial I/O1 control register (Address : 001A16) is set to “0,”
a value of m is 1.
When bit 0 of Serial I/O1 control register (Address : 001A16) is set to “1,”
a value of m is 4.
Port P4 direction register (Address : 000916)
b7
P4D
b0
0
Port P40: Communication control: Input mode
Fig. 2.4.41 Registers setting relevant to receiving side
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2.4 Serial interface
Figure 2.4.42 shows a control procedure of the transmitting side, and Figure 2.4.43 shows a control
procedure of the receiving side.
● X: This bit is not used here. Set it to “0” or “1” arbitrarily.
RESET
Initialization
... ..
SIO1CON (Address : 001A16)
1001X0012
UART1CON (Address : 001B16)
000010002
BRG1
(Address : 001C16)
8–1
0
P4
(Address : 000816), bit0
P4D
(Address : 000916) XXXXXXX12
N
Pass 10 ms?
• Port P40 set for communication control
• An interval of 10 ms generated by Timer
Y
P4 (Address : 000816), bit0
TB1/RB1
(Address : 001816)
• Communication start
1
• Transmission data write
Transmit buffer empty flag is set to “0”
by this writing.
The first byte of a
transmission data
0
SIO1STS (Address : 001916), bit0?
• Judgment of transferring data from Transmit
buffer register to Transmit shift register
(Transmit buffer empty flag)
1
TB1/RB1
(Address : 001816)
The second byte of
a transmission data
SIO1STS (Address : 001916), bit0?
• Transmission data write
Transmit buffer empty flag is set to “0”
by this writing.
0
• Judgment of transferring data from Transmit
buffer register to Transmit shift register
(Transmit buffer empty flag)
0
• Judgment of shift completion of Transmit shift register
(Transmit shift register shift completion flag)
1
SIO1STS (Address : 001916), bit2?
1
P4 (Address : 000816), bit0
0
• Communication completion
Fig. 2.4.42 Control procedure of transmitting side
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2.4 Serial interface
● X: This bit is not used here. Set it to “0” or “1” arbitrarily.
RESET
Initialization
... ..
SIO1CON (Address : 001A16)
UART1CON (Address : 001B16)
BRG1
(Address : 001C16)
P4D
(Address : 000916)
1010X0012
000010002
8–1
XXXXXXX02
SIO1STS (Address : 001916), bit1?
0
• Judgment of completion of receiving
(Receive buffer full flag)
1
• Reception of the first byte data
Receive buffer full flag is set
to “0” by reading data.
Read out a reception data
from RB1 (Address : 001816)
SIO1STS (Address : 001916), bit6?
1
• Judgment of an error flag
0
• Judgment of completion of
receiving
(Receive buffer full flag)
0
SIO1STS (Address : 001916), bit1?
1
• Reception of the second byte data
Receive buffer full flag is set
to “0” by reading data.
Read out a reception data
from RB1 (Address : 001816)
SIO1STS (Address : 001916), bit6?
1
Processing for error
0
1
• Judgment of an error flag
P4 (Address : 000816), bit0?
0
SIO1CON (Address : 001A16)
SIO1CON (Address : 001A16)
0000X0012
1010X0012
• Countermeasure for a bit slippage
Fig. 2.4.43 Control procedure of receiving side
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3804 Group (Spec.H)
2.4 Serial interface
2.4.8 Notes on serial interface
(1) Notes when selecting clock synchronous serial I/O
➀ Stop of transmission operation
As for serial I/Oi (i = 1, 3) that can be used as either a clock synchronous or an asynchronous
(UART) serial I/O, clear the serial I/Oi enable bit and the transmit enable bit to “0” (serial I/Oi and
transmit disabled).
● Reason
Since transmission is not stopped and the transmission circuit is not initialized even if only the
serial I/Oi enable bit is cleared to “0” (serial I/Oi disabled), the internal transmission is running (in
this case, since pins TxDi, RxDi, S CLKi, and S RDYi function as I/O ports, the transmission data is
not output). When data is written to the transmit buffer register in this state, data starts to be
shifted to the transmit shift register. When the serial I/Oi enable bit is set to “1” at this time, the
data during internally shifting is output to the TxDi pin and an operation failure occurs.
➁ Stop of receive operation
As for serial I/Oi (i = 1, 3) that can be used as either a clock synchronous or an asynchronous
(UART) serial I/O, clear the receive enable bit to “0” (receive disabled), or clear the serial I/Oi
enable bit to “0” (serial I/Oi disabled).
➂ Stop of transmit/receive operation
As for serial I/Oi (i = 1, 3) that can be used as either a clock synchronous or an asynchronous
(UART) serial I/O, clear both the transmit enable bit and receive enable bit to “0” simultaneously
(transmit and receive disabled) in the clock synchronous serial I/O mode.
(When data is transmitted and received in the clock synchronous serial I/O mode, any one of data
transmission and reception cannot be stopped.)
● Reason
In the clock synchronous serial I/O mode, the same clock is used for transmission and reception.
If any one of transmission and reception is disabled, a bit error occurs because transmission and
reception cannot be synchronized.
In this mode, the clock circuit of the transmission circuit also operates for data reception. Accordingly,
the transmission circuit does not stop by clearing only the transmit enable bit to “0” (transmit
disabled). Also, the transmission circuit is not initialized by clearing the serial I/Oi enable bit to “0”
(serial I/Oi disabled) (refer to ➀ in (1) ).
(2) Notes when selecting clock asynchronous serial I/O
➀ Stop of transmission operation
Clear the transmit enable bit to “0” (transmit disabled). Transmission operation does not stop by
setting the serial I/Oi enable bit (i = 1, 3) to “0”.
● Reason
This is the same as ➀ in (1).
➁ Stop of receive operation
Clear the receive enable bit to “0” (receive disabled).
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2.4 Serial interface
➂ Stop of transmit/receive operation
Only transmission operation is stopped.
Clear the transmit enable bit to “0” (transmit disabled). Transmission operation does not stop by
setting the serial I/Oi enable bit (i = 1, 3) to “0”.
● Reason
This is the same as ➀ in (1).
Only receive operation is stopped.
Clear the receive enable bit to “0” (receive disabled).
(3) S RDYi (i = 1, 3) output of reception side
When signals are output from the SRDYi pin on the reception side by using an external clock in the
clock synchronous serial I/O mode, set all of the receive enable bit, the SRDYi output enable bit, and
the transmit enable bit to “1” (transmit enabled).
(4) Setting serial I/Oi (i = 1, 3) control register again
Set the serial I/Oi control register again after the transmission and the reception circuits are reset
by clearing both the transmit enable bit and the receive enable bit to “0.”
Clear both the transmit enable
bit (TE) and the receive enable
bit (RE) to “0”
↓
Set the bits 0 to 3 and bit 6 of the
serial I/Oi control register
↓
Set both the transmit enable bit
(TE) and the receive enable bit
(RE), or one of them to “1”
Can be set with the
LDM instruction at
the same time
Fig. 2.4.44 Sequence of setting serial I/Oi (i = 1, 3) control register again
(5) Data transmission control with referring to transmit shift register completion flag
After the transmit data is written to the transmit buffer register, the transmit shift register completion
flag changes from “1” to “0” with a delay of 0.5 to 1.5 shift clocks. When data transmission is
controlled with referring to the flag after writing the data to the transmit buffer register, note the
delay.
(6) Transmission control when external clock is selected
When an external clock is used as the synchronous clock for data transmission, set the transmit
enable bit to “1” at “H” of the SCLKi (i = 1, 3) input level. Also, write the transmit data to the transmit
buffer register at “H” of the S CLKi input level.
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2.4 Serial interface
(7) Transmit interrupt request when transmit enable bit is set
When the transmit interrupt is used, take the following sequence.
➀ Set the serial I/Oi transmit interrupt enable bit (i = 1, 3) to “0” (disabled).
➁ Set the tranasmit enable bit to “1”.
➂ Set the serial I/Oi transmit interrupt request bit (i = 1, 3) to “0” after 1 or more instruction has
executed.
➃ Set the serial I/Oi transmit interrupt enable bit (i = 1, 3) to “1” (enabled).
● Reason
When the transmission enable bit is set to “1”, the transmit buffer empty flag and transmit shift
register shift completion flag are also set to “1”.
Therefore, regardless of selecting which timing for the generating of transmit interrupts, the interrupt
request is generated and the transmit interrupt request bit is set at this point.
(8) Writing to baud rate generator i (BRGi) (i = 1, 3)
Write data to the baud rate generator i (BRGi) (i = 1, 3) while the transmission/reception operation
is stopped.
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2.5 Multi-master I2C-BUS interface
3804 Group (Spec.H)
2.5 Multi-master I2C-BUS interface
The only 3804 group has functions of the multi-master I 2C-BUS interface.
The multi-master I2C-BUS interface is a serial communication circuit, conforming to the Philips I2C-BUS data
transfer format. This paragraph explains the I 2C-BUS overview and communication examples.
2.5.1 Memory map
001016 MISRG
001116 I2C data shift register (S0)
001216 I2C special mode status register (S3)
001316 I2C status register (S1)
001416 I2C control register (S1D)
001516 I2C clock control register (S2)
001616 I2C START/STOP condition control register (S2D)
001716 I2C special mode control register (S3D)
003916 Interrupt source selection register (INTSEL)
003C16 Interrupt request register 1 (IREQ1)
003D16 Interrupt request register 2 (IREQ2)
003E16 Interrupt control register 1 (ICON1)
003F16 Interrupt control register 2 (ICON2)
0FF716
0FF816
I2C slave address register 0 (S0D0)
I2C slave address register 1 (S0D1)
0FF916 I2C slave address register 2 (S0D2)
Fig. 2.5.1 Memory map of registers relevant to I 2C-BUS interface
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2.5 Multi-master I2C-BUS interface
3804 Group (Spec.H)
2.5.2 Relevant registers
MISRG
b7 b6 b5 b4 b3 b2 b1 b0
MISRG
(MISRG: address 001016)
b
Name
Functions
At reset R W
0 Oscillation stabilizing 0: Automatically set (Note 1)
time set after STP
1: Autimatically set disabled
instruction released bit
1 Middle-speed mode 0: Not set automatically
automatic switch set 1: Automatic switching
enabled (Notes 2, 3)
bit
2 Middle-speed mode 0: 4.5 to 5.5 machine cycles
1: 6.5 to 7.5 machine cycles
automatic switch
wait time set bit
3 Middle-speed mode 0: Invalid
1: Automatic switch start
automatic switch
(Note 3)
start bit
(Depending on
program)
4 Nothing is arranged for these bits. These are
write disabled bits. When these bits are read
5
out, the contents are 0 .
6
0
7
0
0
0
0
0
0
0
✕
✕
✕
✕
Notes 1: 0116 is set to Timer 1, FF16 is set to Prescaler 12.
2: During operation in low-speed mode, it is possible automatically to switch to
middle-speed mode owing to the rising of SCL/SDA.
3: When automatic switch to middle-speed mode from low-speed mode occurs,
the values of CPU mode register (003B16) change.
Fig. 2.5.2 Structure of MISRG
I2C data shift register
b7 b6 b5 b4 b3 b2 b1 b0
I2C data shift register
(S0: address 001116)
b
Functions
At reset R W
0 • 8-bit shift register to store receive data and
1 write transmit data.
2
3
4
5
6
7
Undefined
Undefined
Undefined
Undefined
Undefined
Undefined
Undefined
Undefined
Note: When data is written to I2C data shift register after the MST
bit is set to “0” (slave mode), keep the interval for 8 machine
cycles or more.
Also, when the read-modify-write instructions (SEB, CLB) are
used during data transfer, the values may be undefined.
Fig. 2.5.3 Structure of I 2C data shift register
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2.5 Multi-master I2C-BUS interface
3804 Group (Spec.H)
I2C special mode status register
b7 b6 b5 b4 b3 b2 b1 b0
I2C special mode status register
(S3: address 001216)
b
Name
Functions
At reset R W
✕
0
0 Slave address 0
comparison flag
(AAS0)
0: Address disagreement
1: Address agreement
(Notes 1, 2)
1 Slave address 1
comparison flag
(AAS1)
0: Address disagreement
1: Address agreement
(Notes 1, 2)
0
✕
2 Slave address 2
comparison flag
(AAS2)
0: Address disagreement
1: Address agreement
(Notes 1, 2)
0
✕
3 Nothing is arranged for this bit. This is a write
disabled bit. When this bit is read out, the
contents are 0 .
4 Nothing is arranged for this bit. This is a write
disabled bit. When this bit is read out, the
contents are undefined.
0
✕
0
✕
5 SCL pin low hold 2 0: SCL pin low hold
1: SCL pin low release
flag (PIN2)
(Notes 1, 3)
6 Nothing is arranged for this bit. This is a write
disabled bit. When this bit is read out, the
contents are 0 .
1
✕
0
✕
7 STOP condition
flag (SPCF)
0
✕
0: No detection
1: Detection (Notes 1, 4)
Notes 1: These bits and flags can be read out, but cannot be written.
2: These bits can be detected only when the data format selection bit
(ALS) of I2C control register is set to 0 .
3: This bit is initialized to 1 at reset, when the ACK interrupt control bit
is 0 , or when writing 1 to the SCL pin low hold 2 flag set bit.
4: This bit is initialized to 0 at reset, when the I2C-BUS interface
enable bit (ES0) is 0 , or when writing 1 to the STOP condition
flag clear bit.
Fig. 2.5.4 Structure of I 2C special mode status register
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2.5 Multi-master I2C-BUS interface
3804 Group (Spec.H)
I2C status register
b7 b6 b5 b4 b3 b2 b1 b0
I2C status register
(S1: address 001316)
b
Name
0 Last receive bit
(LRB)
1 General call
detection flag
(AD0)
2 Slave address
comparison flag
(AAS)
Functions
At reset R W
Undefined
0: Last bit = 0
1: Last bit = 1 (Note 1)
0
0: No general call detected
1: General call detected
(Notes 1, 2)
0
0: Address disagreement
1: Address agreement
(Notes 1, 2)
3 Arbitration lost
detection flag (AL)
4 SCL pin low hold
bit (PIN)
5 Bus busy flag (BB)
0: Not detected
1: Detected (Note 1)
0: SCL pin low hold (Note 3)
1: SCL pin low release
0: Bus free
1: Bus busy
0
6 Communication
mode specification
bits (TRX, MST)
7
b7 b6
0
0
0
1
1
0:
1:
0:
1:
Slave receive mode
Slave transmit mode
Master receive mode
Master transmit mode
1
0
0
Notes 1: These flags and bits are exclusive to input. When writing to
these bits, write 0 to these bits.
2: These bits can be detected only when the data format
selection bit (ALS) of I2C control register is set to 0 .
3: This bit can be set to 1 by program, but cannot be cleared
to 0 .
4: All bits are changed by hardware. Do not use the readmodify-write instructions (SEB, CLB).
Fig. 2.5.5 Structure of I 2C status register
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3804 Group (Spec.H)
I2C control register
b7 b6 b5 b4 b3 b2 b1 b0
I2C control register
(S1D: address 001416)
b
Name
0 Bit counter
(Number of
transmit/receive
1 bits)
(BC0, BC1, BC2)
2
Functions
b2b1b0
0 0 0: 8
0 0 1: 7
0 1 0: 6
0 1 1: 5
1 0 0: 4
1 0 1: 3
1 1 0: 2
1 1 1: 1
0: Disabled
3 I2C-BUS interface
1: Enabled
enable bit (ES0)
0: Addressing format
4 Data format
selection bit (ALS) 1: Free data format
5 Addressing format 0: 7-bit addressing format
selection bit
1: 10-bit addressing format
(10BIT SAD)
6 Nothing is arranged for this bit. This is a write
disabled bit. When this bit is read out, the
contents are 0 .
7 I2C-BUS interface pin 0: SMBUS input
input level selection 1: CMOS input
bit (TISS)
At reset R W
0
0
0
0
0
0
0
✕
0
Note: Do not use the read-modify-write instruction because some bits
change by hardware when the start condition is detected and
the byte-transfer is completed.
Fig. 2.5.6 Structure of I 2C control register
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2.5 Multi-master I2C-BUS interface
3804 Group (Spec.H)
I2C clock control register
b7 b6 b5 b4 b3 b2 b1 b0
I2C clock control register
(S2: address 001516)
b
Name
0 SCL frequency
control bits
(CCR0, CCR1,
1 CCR2, CCR3,
CCR4)
2
3
4
5 SCL mode
specification bit
(FAST MODE)
6 ACK bit
(ACK BIT)
7 ACK clock bit
(ACK)
Functions
Setting value
b4b3b2b1b0
00 to 02
03
04
05
06
Standard High-speed
clock mode clock mode
Disabled Disabled
Disabled 333
(Note 2) 250
100
400 (Note 3)
83.3
166
500/CCR value 1000/CCR value
(Note 3) (Note 3)
17.2
34.5
1D
1E
16.6
33.3
1F
16.1
32.3
(φ = 4 MHz, Unit: kHz) (Note 1)
At reset R W
0
0
0
0
0
0: Standard clock mode
1: High-speed clock mode
0
0: ACK is returned.
1: ACK is not returned.
0: No ACK clock
1: ACK clock
0
0
Notes 1: Duty of SCL clock output is 50 %. The duty becomes 35 to 45 % only when the highspeed clock mode is selected and CCR value = 5 (400 kHz, at φ = 4 MHz). H
duration of the clock fluctuates from —4 to +2 machine cycles in the standard clock
mode, and fluctuates from —2 to +2 machine cycles in the high-speed clock mode. In
the case of negative fluctuation, the frequency does not increase because L
duration is extended instead of H duration reduction.
These are values when SCL clock synchronization by the synchronous function is not
performed. CCR value is the decimal notation value of the SCL frequency control bits
CCR4 to CCR0.
2: Each value of SCL frequency exceeds the limit at φ = 4 MHz or more. When using
these setting value, use φ of 4 MHz or less.
3: The data formula of SCL frequency is described below:
φ/(8 ✕ CCR value) Standard clock mode
φ/(4 ✕ CCR value) High-speed clock mode (CCR value ≠ 5)
φ/(2 ✕ CCR value) High-speed clock mode (CCR value = 5)
Do not set 0 to 2 as CCR value regardless of φ frequency.
Set 100 kHz (max.) in the standard clock mode and 400 kHz (max.) in the high-speed
clock mode to the SCL frequency by setting the SCL frequency control bits CCR4 to
CCR0.
Fig. 2.5.7 Structure of I 2C clock control register
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3804 Group (Spec.H)
I2C START/STOP condition control register
b7 b6 b5 b4 b3 b2 b1 b0
I2C START/STOP condition control register
(S2D: address 001616)
0
b
Name
0 START/STOP
condition set bits
1 (SSC0, SSC1,
2 SSC2, SSC3,
SSC4)
3
Functions
SCL release time
= φ (µs) ✕ (SSC+1)
Setup time
= φ (µs) ✕ (SSC+1)/2
Hold time
= φ (µs) ✕ (SSC+1)/2
4
At reset R W
0
1
0
1
1
5 SCL/SDA interrupt
pin polarity selection
bit (SIP)
6 SCL/SDA interrupt
pin selection bit
(SIS)
0: Falling edge active
1: Rising edge active
0
0: SDA valid
1: SCL valid
0
0
7 Fix this bit to 0 .
Note: Fix SSC0 to 0 . Also, do not set SSC4 to SSC0 to odd values or 000002 .
Fig. 2.5.8 Structure of I 2C START/STOP condition control register
I2C special mode control register
b7 b6 b5 b4 b3 b2 b1 b0
0
0
I2C special mode control register
(S3D: address 001716)
b
Name
Functions
At reset R W
0 Fix this bit to 0 .
1 ACK interrupt control 0: At communication
completion
bit (ACKICON)
1: At falling of ACK clock and
communication completion
0
0
2 Slave address
0: One-byte slave address
control bit (MSLAD)
compare mode
1: Three-byte slave address
compare mode
3 Nothing is arranged for this bit. This is a write
disabled bit. When this bit is read out, the
contents are 0 .
0
4 Fix this bit to 0 .
5 SCL pin low hold 2 Writing 1 to this bit initializes
flag set bit (PIN2IN) the SCL pin low hold 2 flag
to 1 . (Notes 1, 2)
Writing 1 to this bit clears
6 SCL pin low hold
set bit (PIN2HD)
the SCL pin low hold 2 flag to
0 and holds the SCL pin low.
(Notes 1, 2)
0
0
7 STOP condition flag Writing 1 to this bit initializes
clear bit (SPFCL)
the STOP condition flag to
0 . (Note 1)
0
0
✕
0
Notes 1: When 0 is written to these bits, nothing is happened.
2: Do not write 1 to these bits at the same time.
Fig. 2.5.9 Structure of I2C special mode control register
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I2C slave address register i (i = 0 to 2)
b7 b6 b5 b4 b3 b2 b1 b0
I2C slave address register i (i = 0 to 2)
(S0D0, S0D1, S0D2: addresses 0FF716, 0FF816, 0FF916)
b
Name
0 Read/Write bit
(RWB)
Functions
0: Write bit
1: Read bit
At reset R W
0
1 Slave address
0
The contents of these bits
2 (SAD0, SAD1, SAD2, are compared with the
0
3 SAD3, SAD4, SAD5, address data transmitted
0
from master.
4 SAD6)
0
5
0
6
0
7
0
Note: When the read-modify-write instructions (SEB, CLB) are used at
detection of stop condition, the values may be undefined.
Fig. 2.5.10 Structure of I 2C slave address register i (i = 0 to 2)
Interrupt source selection register
b7 b6 b5 b4 b3 b2 b1 b0
Interrupt source selection register
(INTSEL: address 003916)
b
Name
Functions
At reset R W
0 INT0/Timer Z
interrupt source
selection bit (*1)
0: INT0 interrupt
1: Timer Z interrupt
0
1 Serial I/O2/Timer Z
interrupt source
selection bit (*1)
2 Serial I/O1 transmit/
SCL, SDA interrupt
source selection bit
(*2)
0: Serial I/O2 interrupt
1: Timer Z interrupt
0
0: Serial I/O1 transmit
interrupt
1: SCL, SDA interrupt
0
0: CNTR0 interrupt
1: SCL, SDA interrupt
0
0: INT4 interrupt
1: CNTR2 interrupt
0
0: INT2 interrupt
1: I2C interrupt
0: CNTR1 interrupt
1: Serial I/O3 receive
interrupt
0: A/D converter interrupt
1: Serial I/O3 transmit
interrupt
0
3 CNTR0/SCL, SDA
interrupt source
selection bit (*2)
4 INT4/CNTR2
interrupt source
selection bit
5 INT2/I2C interrupt
source selection bit
6 CNTR1/Serial I/O3
receive interrupt
source selection bit
7 AD converter/Serial
I/O3 transmit
interrupt source
selection bit
0
0
*1: Do not write 1 to these bits simultaneously.
*2: Do not write 1 to these bits simultaneously.
Fig. 2.5.11 Structure of Interrupt source selection register
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Interrupt request register 1
b7 b6 b5 b4 b3 b2 b1 b0
Interrupt request register 1
(IREQ1 : address 003C16)
b
Name
Functions
At reset R W
0 INT0/Timer Z
0 : No interrupt request issued
interrupt request bit 1 : Interrupt request issued
0
✽
1 INT1 interrupt
request bit
0
✽
2 Serial I/O1 receive 0 : No interrupt request issued
interrupt request bit 1 : Interrupt request issued
0
✽
0 : No interrupt request issued
3 Serial I/O1
transmit/SCL, SDA 1 : Interrupt request issued
interrupt request bit
0
✽
4 Timer X interrupt
request bit
0 : No interrupt request issued
0
✽
5 Timer Y interrupt
request bit
0 : No interrupt request issued
0
✽
6 Timer 1 interrupt
request bit
0 : No interrupt request issued
0
✽
0
✽
0 : No interrupt request issued
1 : Interrupt request issued
1 : Interrupt request issued
1 : Interrupt request issued
1 : Interrupt request issued
7 Timer 2 interrupt
0 : No interrupt request issued
request bit
1 : Interrupt request issued
✽: 0 can be set by software, but 1 cannot be set.
Fig. 2.5.12 Structure of Interrupt request register 1
Interrupt request register 2
b7 b6 b5 b4 b3 b2 b1 b0
Interrupt request register 2
(IREQ2 : address 003D16)
b
Name
Functions
At reset R W
0 CNTR0/SCL, SDA 0 : No interrupt request issued
interrupt request bit 1 : Interrupt request issued
1 CNTR1/Serial I/O3 0 : No interrupt request issued
1 : Interrupt request issued
receive interrupt
request bit
0
✽
0
✽
0 : No interrupt request issued
1 : Interrupt request issued
0 : No interrupt request issued
1 : Interrupt request issued
0 : No interrupt request issued
1 : Interrupt request issued
0 : No interrupt request issued
1 : Interrupt request issued
0 : No interrupt request issued
1 : Interrupt request issued
0
✽
0
✽
0
✽
0
✽
0
✽
2 Serial I/O2/Timer Z
interrupt request bit
3 INT2/I2C interrupt
request bit
4 INT3 interrupt
request bit
5 INT4/CNTR2
interrupt request bit
6 AD converter/Serial
I/O3 transmit
interrupt request bit
7 Nothing is arranged for this bit. This is a write
disabled bit. When this bit is read out, the
contents are 0 .
0
✽: 0 can be set by software, but 1 cannot be set.
Fig. 2.5.13 Structure of Interrupt request register 2
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Interrupt control register 1
b7 b6 b5 b4 b3 b2 b1 b0
Interrupt control register 1
(ICON1 : address 003E16)
b
Name
Functions
At reset R W
0 INT0/Timer Z
interrupt enable bit
1 INT1 interrupt
enable bit
2 Serial I/O1 receive
interrupt enable bit
3 Serial I/O1
transmit/SCL, SDA
interrupt enable bit
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0
4 Timer X interrupt
enable bit
5 Timer Y interrupt
enable bit
6 Timer 1 interrupt
enable bit
7 Timer 2 interrupt
enable bit
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0
0
0
0
0
0
0
Fig. 2.5.14 Structure of Interrupt control register 1
Interrupt control register 2
b7 b6 b5 b4 b3 b2 b1 b0
0
Interrupt control register 2
(ICON2 : address 003F16)
b
Name
0 CNTR0/SCL, SDA
interrupt enable bit
1 CNTR1/ Serial I/O3
receive interrupt
enable bit
2 Serial I/O2/ Timer Z
interrupt enable bit
3 INT2/I2C interrupt
enable bit
4 INT3 interrupt
enable bit
5 INT4/CNTR2
interrupt enable bit
6 AD converter/Serial
I/O3 transmit
interrupt enable bit
7 Fix this bit to 0 .
Functions
At reset R W
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
0
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0
0
0
0
0
0
Fig. 2.5.15 Structure of Interrupt control register 2
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2.5 Multi-master I2C-BUS interface
2.5.3 I 2C-BUS overview
The I 2C-BUS is a both directions serial bus connected with two signal lines; the SCL which transmits a
clock and the SDA which transmits data.
Each port of the 3804 group has an N-channel open-drain structure for output and a CMOS structure for
input. The devices connected with the I 2 C-BUS interface use an open drain, so that external pull-up
resistors are required. Accordingly, while any one of devices always outputs “L”, other devices cannot
output “H”.
Figure 2.5.16 shows the I 2C-BUS connection structure.
SCL output
SCL output
SCL input
SCL input
SDA output
SDA output
SDA input
SDA input
SCL output
SCL input
SDA output
SDA input
Fig. 2.5.16 I 2C-BUS connection structure
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2.5.4 Communication format
Figure 2.5.17 shows an I2C-BUS communication format example.
The I 2C-BUS consists of the following:
•START condition to indicate communication start
•Slave address and data to specify each device
•ACK to indicate acknowledgment of address and data
•STOP condition to indicate communication completion.
Bus busy term
S
Slave address
7 bits
R/W A
Data
8 bits
A
Data
8 bits
A P
SCL
SDA
Start Addresses 0 to 6 W ACK
Data 0 to 7 ACK
Data 0 to 7
ACK
Stop
Fig. 2.5.17 I2C-BUS communication format example
(1) START condition
When communication starts, the master device outputs the START condition to the slave device. The
I2C-BUS defines that data can be changed when a clock line is “L”. Accordingly, data change when
a clock line is “H” is treated as STOP or START condition.
The data line change from “H” to “L” when a clock line is “H” is START condition.
(2) STOP condition
Just as in START condition, the data line change from “L” to “H” when a clock line is “H” is STOP
condition.
The term from START condition to STOP condition is called “Bus busy”. The master device is
inhibited from starting data transfer during that term.
The Bus busy status can be judged by using the BB flag of I2C status register (bit 5 of address 001316).
(3) Slave address
The slave address is transmitted after START condition. This address consists of 7 bits and the 7th bit functions as the read/write (R/W) bit which indicates a data transmission method. The slave
devices connected with the same I2C-BUS must have their addresses, individually. It is because that
address is defined for the master to specify the transmitted/received slave device.
The read/write (R/W) bit indicates a data transmission direction; “L” means write from the master to
the slave, and “H” means read in.
(4) Data
The data has an 8-bit length. There are two cases depending on the read/write (R/W) bit of a slave
address; one is from the master to the slave and the other is from the slave to the master.
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(5) ACK bit
The ACK bit clock is generated by the master. This is used for indication of acknowledgment on the
SDA line, the slave’s busy and the data end.
For example, the slave device makes the SDA line “L” for acknowledgment when confirming the slave
address following the START condition. The built-in I2C-BUS interface has the slave address automatic
judgment function and the ACK acknowledgment function. “L” is automatically output when the ACK
bit of I2C clock control register (bit 6 of address 001516) is “0” and an address data is received. When
the slave address and the address data do not correspond, “H” (NACK) is automatically output.
In case the slave device cannot receive owing to an interrupt process, performing operation or
others, the master can output STOP condition and complete data transfer by making the ACK data
of the slave address “H” for acknowledgment. Even in case the slave device cannot receive data
during data transferring, the communication can be interrupted by performing NACK acknowledgment
to the following data.
When the master is receiving the data from the slave, the master can notify the slave of completion
of data reception by performing NACK acknowledgment to the last data received from the slave.
(6) RESTART condition
The master can receive or transmit data without transmission of STOP condition while the master is
transmitting or receiving a data.
For example, after the master transmitted a data to the slave, transmitting a slave address + R
(Read) following RESTART condition can make the following data treat as a reception data.
Additionally, transmitting a slave address + W (Write) following RESTART condition can make the
following data treat as a transmission data.
START condition
S
RESTART condition
Slave address R/W A
7 bits
“0”
Write
Data
A Sr
8 bits
Master reception
1st-byte
Slave address R/W A
7 bits
Lower data
“1”
Read
8 bits
A
Master reception
2nd-byte
Upper data
A P
8 bits
NACK expression end of
master reception data
S: START condition
P: STOP condition
A: ACK bit
R/W: Read/Write bit
Sr: RESTART condition
Master to slave
Slave to master
Fig. 2.5.18 RESTART condition of master reception
2.5.5 Synchronization and arbitration lost
(1) Synchronization
When a plural master exists on the I2C-BUS and the masters, which have different speed, are going
to simultaneously communicate; there is a rule to unify clocks so that a clock of each bit can be
output correctly.
Figure 2.5.19 shows a synchronized SCL line example. The SCL (A) and the SCL (B) are the master
devices having a different speed. The SCL is synchronized waveforms.
As shown by Figure 2.5.19, the SCL lines can be synchronized by the following method; the device
which first finishes “H” term makes the SCL line “L” and the device which last remains “L” makes the
SCL line “H”.
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➀
SCL(A)
➁
➅
➂
SCL(B)
➄
➃
➆
SCL
Fig. 2.5.19 SCL waveforms when synchronizing clocks
➀ After START condition, the masters, which have different speed, simultaneously start clock transmission.
➁ The SCL outputs “L” because (A) finished counting “H” output; then (B)’s “H” output counting is
interrupted and (B) starts counting “L” output.
➂ The (A) outputs “H” because (A) finished counting “L” term; the SCL level does not become “H”
because (B) outputs “L”, and counting “H” term does not start but stop.
➃ (B) outputs “L” term.
➄ The SCL outputs “H” because (B) finished counting “L” term; then (B)’s “H” output counting is
started at the same time as (A).
➅ The SCL outputs “L” because (A) first finished counting “H” output; then (B)’s “H” output counting
is interrupted and (B) starts counting “L” output.
➆ The above are repeatedly performed.
(2) Clock synchronization during communication
In the I 2C-BUS, the slave device is permitted to retain the SCL line “L” and become waiting status
for transmission from the master. By byte unit, for the reception preparation of the slave device, the
master can become waiting status by making the SCL line “L”, which is after completion of byte
reception or the ACK.
By bit unit, it is possible to slow down a clock speed by retaining the clock line “L” for slave devices
having limited hardware.
The 3804 group can transmit data correctly without reduction of data bits toward waiting status
request from the slave device. It is because the synchronization circuit is included for the case when
retaining the SCL line “L” as an internal hardware.
After the last bit, including the ACK bit, of a transmission/reception data byte, the SCL line automatically
remains “L” and waiting status is generated until completion of an interrupt process or reception
preparation.
(3) Arbitration lost
A plural master exists on the same bus in the I2C-BUS and there are possibility to start communication
simultaneously. Even when the master devices having the same transmission frequency start
communication simultaneously, which device must transmit data correctly. Accordingly, there is the
definition to detect a communication confliction on the SDA line in the I 2C-BUS.
The SDA line is output at the timing synchronized by the SCL, however, the synchronization among
the SDA signals is not performed.
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2.5 Multi-master I2C-BUS interface
2.5.6 SMBUS communication usage example
This clause explains a SMBUS communication control example using the I2C-BUS. This is a control example
as the master device and the slave device in the Read Word protocol of SMBUS protocol.
The following is a communication example of the “Voltage () command” of the Smart battery data.
Communication specifications:
•Communication frequency = 100 kHz
•Slave address of itself, battery, = “0001011X 2” (X means the read/write bit)
•Slave address of communication destination, host, = “0001000X 2” (X means the read/write bit)
•Voltage () command = “09 16”
•Voltage value of acknowledgment = “2EE016” (12000 mV)
•The communication process is performed in the interrupt process. However, the main process performs
an occurrence of the first START condition and a slave address set.
•A communication buffer is established. Data transfer between the main process and the interrupt process
is performed through the communication buffer.
(1) Initial setting
Figure 2.5.20 shows an initial setting example using SMBUS communication.
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I2C special mode control register (address 001716)
b7
S3D
b0
0 0 0 0 0 0 0 0
Fix to “0”
ACK interrupt control : At communication completion
One-byte slave address compare mode
This setting can be omitted.
Fix to “0”
Fix to “0”
SCL pin low hold 2 flag set bit : Not used
SCL pin low hold set bit : Not set
STOP condition flag clear bit : Not used
I2C slave address register 0 (address 0FF716)
b7
S0D0
b0
0 0 0 1 0 1 1 0
Set slave address value 001616.
I2C clock control register (address 001516)
b0
b7
S2
1 0 0 0 0 1 0 1
Set clock 100 kHz (XIN = 8MHz)
Standard clock mode
ACK is returned
ACK clock
I2C status register (address 001316)
b0
b7
S1
0 0
1
SCL pin low hold bit: Fix to “1”
Slave receive mode
I2C START/STOP condition control register (address 001616)
b7
S2D
b0
0 0 0 1 1 0 1 0
Set setup time, hold time to 27 cycles (6.75 µs: XIN = 8 MHz).
SCL/SDA interrupt: Falling edge active
SCL/SDA interrupt: SDA valid
Fix to “0”
I2C control register (address 001416)
b7
S1D
b0
0 0 0 0 1 0 0 0
Set number of transmit/receive bits to “8”.
I2C-BUS interface: Enabled
Addressing format
7-bit addressing format
Fix to “0”
Set SMBUS input level.
Fig. 2.5.20 Initial setting example for SMBUS communication
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(2) Communication example in master device
The master device follows the procedures ➀ to ➅ shown by Figure 2.5.21.
Additionally, the shaded area in the figure is a transmission data from the master device and the
white area is a transmission data from the slave device.
➀
➁
➂
➃
➄
➅
Generating of START condition; Transmission of slave address + write bit
Transmission of command
Generating of RESTART condition; Transmission of slave address + read bit
Reception of lower data
Reception of upper data
Generating of STOP condition
Figures 2.5.22 to 2.5.27 show the procedures ➀ to ➅.
➀
S
➁
➂
Slave address R/W A Command A Sr Slave address R/W A
7 bits
“0”
Write
8 bits
Interrupt request
7 bits
Interrupt request
S: START condition
P: STOP condition
A: ACK bit
R/W: Read/Write bit
Sr: RESTART condition
➄
➃
Lower data
“1”
Read
A
8 bits
➅
Upper data
A P
8 bits
Interrupt request Interrupt request
Interrupt request
Master to slave
Slave to master
Fig. 2.5.21 Read Word protocol communication as SMBUS master device
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➀ Generating of START condition; Transmission of slave address + write bit
After confirming that other master devices do not use the bus, generate the START condition,
because the SMBUS is a multi-master.
Write “slave address + write bit” to the I2C data shift register (address 0011 16) before performing
to make the START condition generate. It is because the SCL of 1-byte unit is output, following
occurrence of the START condition.
If other master devices start communication until an occurrence of the START condition after
confirming the bus use, it cannot communicate correctly. However in this case, that situation does
not affect other master devices owing to detection of an arbitration lost or the START condition
duplication preventing function.
1
(A)←000100002
SEI (Note 1)
• Interrupts disabled
1 (used)
BB (address 001316), bit5 ? (Note 2)
• Bus use confirmation
0 (not used)
S0 (address 001116) ← (A)
S1 (address 001316) ←111100002
CLI (Note 1)
• Slave address value write
• START condition occurrence
• Interrupt enabled
End
Notes 1: In this example, the SEI instruction to disable interrupts need not be executed
because this processing is going to be performed in the interrupt processing.
When the START condition is generated out of the interrupt processing, execute
the SEI instruction to disable interrupts.
2: Use the branch bit instruction to confirm bus busy.
Fig. 2.5.22 Generating of START condition and transmission process of slave address + write bit
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➁ Transmission of command
Confirm correct completion of communication at ➀ before command transmission. When receiving
the STOP condition, a process not to transmit a command is required, because the internal I2CBUS generates an interrupt request also owing to the STOP condition transmitted to other devices.
After confirming correct completion of communication, write a command to the I 2 C data shift
register (address 001116).
In case the AL bit (bit 3 of address 001316) is “1”, check the slave address comparison flag (AAS
bit; bit 2 of address 001316) to judge whether the device given a right of master transmission owing
to an arbitration specifies itself as a slave address. When it is “1”, perform the slave reception;
when “0”, wait for a STOP condition occurrence caused by other devices and the communication
completion.
In case the AL bit is “0”, check the last received bit (LRB bit; bit 0 of address 0013 16). When it is
“1”, make the STOP condition generate and release the bus use, because the specified slave
device does not exist on the SMBUS.
2
1(error)
PIN (address 001316), bit 4 ?
• Judgment of bus hold
0 (slave address transmitted)
1(detected)
AL (address 001316), bit 3 ?
• Judgment of arbitration lost detection
0 (not detected)
1(NACK)
LRB (address 001316), bit 0 ?
• ACK confirmation
0 (ACK)
S0 (address 001116) ← 000010012
• Command data write to I2C data shift register
End
STOP condition output
0 (address not corresponded)
AAS (address 001316), bit 2 ?
• Judgment of slave address comparison
1 (address corresponded)
Re-transmission preparation
Slave reception
Fig. 2.5.23 Transmission process of command
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APPLICATION
2.5 Multi-master I2C-BUS interface
3804 Group (Spec.H)
➂ Generating of RESTART condition; Transmission of slave address + read bit
Confirm correct completion of communication at ➁ before generating the RESTART condition.
After confirming correct completion, generate the RESTART condition and perform the transmission
process of “slave address + read bit”. Note that procedure because that is different from ➀’s
process.
As the same reason as ➀, write “slave address + read bit” to the I2C data shift register (address
0011 16) before performing to make the START condition generate. However, when writing a slave
address to the I 2C data shift register in this condition, a slave address is output at that time.
Consequently, the RESTART condition cannot be generated. Therefore, follow the slave reception
procedure before those processes.
In case the arbitration lost detecting flag (AL bit, bit 3 of address 0013 16) is “1”, return to the
process ➀, because other master devices will have priority to communicate.
When the last received bit (LRB bit; bit 0 of address 001316) is “1”, generate the STOP condition
and make the bus release, because acknowledgment cannot be done owing to BUSY status of the
slave device specified on the SMBUS or other reasons.
3
1 (STOP condition)
PIN (address 001316), bit 4 ?
• Bus judgment during hold
0 (command transmission)
1 (detected)
AL (address 001316), bit 3 ?
• Judgment of arbitration lost detection
0 (not detected)
1 (NACK)
LRB (address 001316), bit 0 ?
• ACK confirmation
0 (ACK)
S1 (address 001316) ← 000000002 (Note 1)
• Slave receive mode set
(A) ← 000100012
• Slave address read out
SEI (Note 2)
S0 (address 001116) ← (A)
S1 (address 001316) ← 111100002
CLI (Note 2)
• Interrupt disabled
• Slave address value write
• RESTART condition occurrence
• Interrupt enabled
End
Re-transmission preparation
STOP condition output
Notes 1: Set to the receive mode while the PIN bit is “0”. Do not write “1” to the PIN bit.
2: In this example, the SEI instruction to disable interrupts need not be executed because this
processing is going to be performed in the interrupt processing.
When the START condition is generated out of the interrupt processing, execute the SEI
instruction to disable interrupts.
Fig. 2.5.24 Transmission process of RESTART condition and slave address + read bit
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APPLICATION
2.5 Multi-master I2C-BUS interface
3804 Group (Spec.H)
➃ Reception of lower data
Confirm correct completion of communication at ➂ before receiving the lower data. After confirming
correct completion, clear the ACK bit (bit 6 of address 0015 16) to “0”, in which ACK is returned,
and set to the master receive mode. After that, write dummy data to the I 2C data shift register
(address 001116).
When the MST bit (bit 7 of address 001316) is “0”, perform the error process explained as follows
and return to the process ➀.
When the last receive bit (LRB bit; bit 0 of address 0013 16) is “1”, generate the STOP condition
and make the bus release, because the slave device specified on the SMBUS does not exist.
4
1 (STOP condition)
PIN (address 001316), bit 4 ?
• Judgment of bus hold
0 (transmission of RESTART
condition)
0 (slave)
MST (address 001316), bit 7 ?
• Judgment of slave mode detection
1 (master)
1 (NACK)
LRB (address 001316), bit 0 ?
• ACK confirmation
0 (ACK)
S2 (address 001516) ← 100001012
• “ACK clock is used” select and
“ACK is returned” set
S1 (address 001316) ←101000002
• Master receive mode set
S0 (address 001116) ← 111111112
• Dummy data to I2C data shift register write
End
STOP condition output
1 (detected)
AL (address 001316), bit 3 ?
• Judgment of arbitration lost detection
0 (not detected)
Re-transmission preparation
Error processing
Fig. 2.5.25 Reception process of lower data
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APPLICATION
2.5 Multi-master I2C-BUS interface
3804 Group (Spec.H)
➄ Transmission of upper data
Confirm correct completion of communication at ➃ before receiving the upper data. After confirming
correct completion, store the received data (lower data).
Set the ACK bit (bit 6 of address 0015 16) to “1”, in which ACK is not returned and write dummy
data to the I 2C data shift register (address 0011 16).
When the MST bit (bit 7 of address 001316) is “0”, return to the process ➀, because other devices
have priority to communicate.
5
1 (STOP condition)
PIN (address 001316), bit 4 ?
• Judgment of bus hold
0 (lower data transmitted)
0 (slave)
MST (address 001316), bit 7 ?
• Judgment of slave mode detection
1 (Master)
Receive data buffer ← S0 (address 001116)
• Receive data read and save
S2 (address 001516) ←110001012
• “NACK is returned” set
S0 (address 001116) ← 111111112
• Dummy data to I2C data shift register write
End
1(detected)
AL (address 001316), bit 3 ?
• Judgment of arbitration lost detection
0 (not detected)
Re-transmission preparation
Error processing
Fig. 2.5.26 Reception process of upper data
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APPLICATION
2.5 Multi-master I2C-BUS interface
3804 Group (Spec.H)
➅ Generating of STOP condition
Confirm correct completion of communication at ➄ before generating the STOP condition. After
confirming correct completion, store the received data (upper data).
Clear the ACK bit (bit 6 of address 0015 16) to “0”, in which ACK is returned, and generate the
STOP condition. The communication mode is set to the slave receive mode by the occurrence of
STOP condition.
When the MST bit (bit 7 of address 001316) is “0”, return to the process ➀, because other devices
have priority to communicate.
6
1 (STOP condition)
PIN (address 001316), bit 4 ?
• Judgment of bus hold
0 (upper data transmitted)
1 (detected)
AL (address 001316), bit 3 ?
• Judgment of arbitration lost detection
0 (not detected)
Receive data buffer ← S0 (address 001116)
• Receive data read and save
S2 (address 001516) ← 100001012
• Set “ACK is returned”
S1 (address 001316) ← 110100002
• STOP condition occurrence
BB (address 001316), bit5 ? (Note)
• Judgment of bus busy
1 (bus busy)
0 (bus free)
Re-transmission preparation
End
Note: Use the branch bit instruction to check bus busy.
Also, execute the time out processing separately, if neccessary.
Fig. 2.5.27 Generating of STOP condition
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APPLICATION
2.5 Multi-master I2C-BUS interface
3804 Group (Spec.H)
(3) Communication example in slave device
The slave device follows the procedures ➀ to ➅ shown by Figure 2.5.28.
The only difference from the master device’s communication is an occurrence of interrupt request
after detection of STOP condition.
➀
➁
➂
➃
➄
➅
Reception of START condition; Transmission of ACK bit due to slave address correspondence
Reception of command
Reception of RESTART condition; Reception of slave address + read bit
Transmission of lower data
Transmission of upper data
Reception of STOP condition
Figures 2.5.29 to 2.5.34 show the procedures ➀ to ➅.
➀
S
➁
➂
Slave address R/W A Command A Sr Slave address R/W A
7 bits
“0”
Write
8 bits
Interrupt request
7 bits
Interrupt request
S: START condition
P: STOP condition
A: ACK bit
R/W: Read/Write bit
Sr: RESTART condition
➃
Lower data
“1”
Read
8 bits
Interrupt request
A
➄➅
Upper data
A P
8 bits
Interrupt request
Interrupt Interrupt request
request
Master to slave
Slave to master
Fig. 2.5.28 Communication example as SMBUS slave device
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APPLICATION
2.5 Multi-master I2C-BUS interface
3804 Group (Spec.H)
➀ Reception of START condition; Transmission of ACK bit due to slave address correspondence
In the case of operation as the slave, all processes are performed in the interrupt after setting of
the slave reception in the main process, because an interrupt request does not occur until
correspondence of a slave address.
In the first interrupt, after confirming correspondence of the slave address, write dummy data to
receive a command into the I 2C data shift register.
1
1 (STOP condition)
PIN (address 001316), bit 4 ?
• Judgment of bus hold
0 (slave address received)
0 (not corresponded)
AAS (address 001316), bit 2 ?
• Judgment of slave address correspondence
1 (corresponded)
S0 (address 001116) ← 111111112
• Dummy data write to I2C data shift register
End
S1 (address 001316) ← 000100002
• Slave receive mode set
Error processing
Fig. 2.5.29 Reception process of START condition and slave address
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APPLICATION
2.5 Multi-master I2C-BUS interface
3804 Group (Spec.H)
➁ Reception of command
Confirm correct completion of the command reception in the interrupt after receiving the command.
After confirming correct command from the host, write dummy data to the I 2C data shift register
to wait for reception of the next slave address.
2
1 (STOP condition)
PIN (address 001316), bit 4 ?
• Judgment of bus hold
0 (command received)
Receive data buffer ← S0 (address 001116)
• Receive data read and save
Judgment of receive command
S2 (address 001516) ← 100001012
• “ACK clock is used” select and “ACK is returned” set
S0 (address 001116) ← 111111112
• Dummy data write to I2C data shift register
End
S1 (address 001316) ← 000100002
• Slave receive mode set
Error end
Fig. 2.5.30 Reception process of command
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APPLICATION
2.5 Multi-master I2C-BUS interface
3804 Group (Spec.H)
➂ Reception of RESTART condition and slave address
After receiving a slave address, prepare transmission data.
Judgment whether receiving data or transmitting is required, because the mode is automatically
switched between the receive mode and the transmit mode depending on the R/W bit of the
received slave address. Accordingly, judge whether read or write referring the slave address
comparison flag (AAS bit; bit 2 of address 0013 16).
3
1 (STOP condition)
• Judgment of bus hold
PIN (address 001316), bit 4 ?
0 (lower data received)
0 (not corresponded)
AAS (address 001316), bit 2 ?
1 (corresponded)
0 (received)
TRX (address 001316), bit 6 ?
• Judgment of transmit/receive mode
1 (transmitted)
S0 (address 001116) ← lower data
• Output lower data write to I2C data shift register
End
Slave receive processing, etc.
End
S1 (address 001316) ← 000100002
• Slave receive mode set
Error end
Fig. 2.5.31 Reception process of RESTART condition and slave address
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APPLICATION
2.5 Multi-master I2C-BUS interface
3804 Group (Spec.H)
➃ Transmission of lower data
Before transmitting the upper data, restart to transmit the data at ➃ and confirm correct completion
of transmission of the lower data set in the slave address reception interrupt.
After that, transmit the upper data.
4
1 (STOP condition)
PIN (address 001316), bit 4 ?
• Judgment of bus hold
0 (lower data transmission completed)
1(NACK)
LRB (address 001316), bit 0 ?
• ACK confirmation
0 (ACK)
S0 (address 001116) ←Upper data
• Output upper data write to I2C data shift register
End
S1 (address 001316) ← 000100002
• Slave receive mode set
Error end
Fig. 2.5.32 Transmission process of lower data
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APPLICATION
2.5 Multi-master I2C-BUS interface
3804 Group (Spec.H)
➄ Transmission of upper data
Confirm correct completion of the upper data transmission. The master returns the NACK toward
the transmitted second-byte data, the upper data. Accordingly, confirm that the last receive bit
(LRB bit; bit 0 of address 0013 16) is “1”.
After that, write dummy data to the I 2C data shift register and wait for the interrupt of STOP
condition.
5
1 (STOP condition)
PIN (address 001316), bit 4 ?
• Judgment of bus hold
0 (upper data transmission completed)
0 (ACK)
LRB (address 001316), bit 0 ?
• ACK confirmation
1 (NACK)
S0 (address 001116) ← 111111112
• Dummy data write to I2C data shift register
End
S1 (address 001316) ← 000100002
• Slave receive mode set
Error end
Note: Use the branch bit instruction to check bus busy.
Fig. 2.5.33 Transmission process of upper data
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APPLICATION
2.5 Multi-master I2C-BUS interface
3804 Group (Spec.H)
➅ Reception of STOP condition
Confirm that the STOP condition is correctly output and the bus is released.
6
0 (address or data received)
PIN (address 001316), bit 4 ?
• Judgment of bus hold
1 (STOP condition)
End processing
S1 (address 001316) ← 000100002
• Slave receive mode set
End
S1(address 001316) ← 000100002
• Slave receive mode set
Error end
Fig. 2.5.34 Reception of STOP condition
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APPLICATION
3804 Group (Spec.H)
2.5 Multi-master I2C-BUS interface
2.5.7 Notes on multi-master I 2C-BUS interface
(1) Read-modify-write instruction
Each register of the multi-master I2C-BUS interface has bits to change by hardware. The precautions
when the read-modify-write instruction such as SEB, CLB etc. is executed for each register of the
multi-master I 2C-BUS interface are described below.
➀ I2C data shift register (S0: address 0011 16)
When executing the read-modify-write instruction for this register during transfer, data may become
a value not intended.
➁ I 2C slave address registers 0 to 2 (S0D0 to S0D2: addresses 0FF7 16 to 0FF916)
When the read-modify-write instruction is executed for this register at detecting the STOP condition,
data may become a value not intended.
● Reason
It is because hardware changes the read/write bit (RWB) at detecting the STOP condition.
➂ I2C status register (S1: address 0013 16)
Do not execute the read-modify-write instruction for this register because all bits of this register
are changed by hardware.
➃ I2C control register (S1D: address 0014 16)
When the read-modify-write instruction is executed for this register at detecting the START condition
or at completing the byte transfer, data may become a value not intended.
● Reason
Because hardware changes the bit counter (BC0 to BC2).
➄ I2C clock control register (S2: address 001516)
The read-modify-write instruction can be executed for this register.
➅ I2C START/STOP condition control register (S2D: address 001616)
The read-modify-write instruction can be executed for this register.
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APPLICATION
3804 Group (Spec.H)
2.5 Multi-master I2C-BUS interface
(2) START condition generating procedure using multi-master
➀ Procedure example (The necessary conditions of the generating procedure are described as the
following ➁ to ➄).
LDA #SLADR
(Taking out of slave address value)
SEI
(Interrupt disabled)
BBS 5, S1, BUSBUSY (BB flag confirming and branch process)
BUSFREE:
STA S0
(Writing of slave address value)
LDM #$F0, S1
(Trigger of START condition generating)
CLI
(Interrupt enabled)
:
:
BUSBUSY:
CLI
(Interrupt enabled)
:
:
➁ Use “Branch on Bit Set” of “BBS 5, S1, –” for the BB flag confirming and branch process.
➂ Use “STA, STX” or “STY” of the zero page addressing instruction for writing the slave address
value to the I 2C data shift register (S0: address 0011 16).
➃ Execute the branch instruction of above ➁ and the store instruction of above ➂ continuously shown
by the above procedure example.
➄ Disable interrupts during the following three process steps:
• BB flag confirming
• Writing of slave address value
• Trigger of START condition generating
(3) RESTART condition generating procedure in master
➀ Procedure example (The necessary conditions of the generating procedure are described as the
following ➁ to ➃). Execute the following procedure when the PIN bit is “0”.
LDM #$00, S1
(Select slave receive mode)
LDA #SLADR
(Taking out of slave address value)
SEI
(Interrupt disabled)
STA S0
(Writing of slave address value)
LDM #$F0, S1
(Trigger of RESTART condition generating)
CLI
(Interrupt enabled)
:
:
➁ Select the slave receive mode when the PIN bit is “0”. Do not write “1” to the PIN bit. The TRX bit
becomes “0” and the SDA pin is released.
➂ The SCL pin is released by writing the slave address value to the I 2C data shift register.
➃ Disable interrupts during the following two process steps:
• Writing of slave address value
• Trigger of RESTART condition generating
(4) Writing to I 2C status register (S1: address 0013 16)
Do not execute an instruction to set the PIN bit to “1” from “0” and an instruction to set the MST and
TRX bits to “0” from “1” simultaneously. It is because it may enter the state that the SCL pin is
released and the SDA pin is released after about one machine cycle. Do not execute an instruction
to set the MST and TRX bits to “0” from “1” simultaneously when the PIN bit is “1”. It is because it
may become the same as above.
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3804 Group (Spec.H)
2.5 Multi-master I2C-BUS interface
(5) Writing to I 2C clock control register (S2: address 001516)
Do not write data into the I2C clock control register during transfer. If data is written during transfer,
the I 2C clock generator is reset, so that data cannot be transferred normally.
(6) Switching of SCL/SDA interrupt pin polarity selection bit, SCL/SDA interrupt pin selection bit,
I 2C-BUS interface enable bit
When changing the setting of the SCL/SDA interrupt pin polarity selection bit, the SCL/SDA interrupt
pin selection bit, or the I 2C-BUS interface enable bit ES0, the SCL/SDA interrupt request bit may be
set. When selecting the SCL/SDA interrupt source, disable the interrupt before the SCL/SDA interrupt
pin polarity selection bit, the SCL/SDA interrupt pin selection bit, or the I2C-BUS interface enable bit
ES0 is set. Reset the request bit to “0” after setting these bits, and enable the interrupt.
(7) Process of after STOP condition generating in master mode
Do not write data in the I2C data shift register (S0) and the I2C status register (S1) until the bus busy
flag BB becomes “0” after generating the STOP condition in the master mode. It is because the
STOP condition waveform might not be normally generated. Reading to the above registers does not
have the problem.
(8) ES0 bit switch
In standard clock mode when SSC = “00010 2” or in high-speed clock mode, flag BB may switch to
“1” if ES0 bit is set to “1” when SDA is “L”.
Countermeasure:
Set ES0 to “1” when SDA is “H”.
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APPLICATION
3804 Group (Spec.H)
2.5 Multi-master I2C-BUS interface
2.5.8 Notes on programming for SMBUS interface
(1) Time out process
For a smart battery system, the time out process with a program is required so that the communication
can be completed even when communication is interrupted. It is because there is possibility of
extracting a battery from a PC.
The specifications are defined so that communication has been able to be completed within 25 ms
from START condition to STOP condition and within 10 ms from the ACK pulse to the ACK pulse of
each byte. Accordingly, the following two should be considered as count start conditions.
➀ SDA falling edge caused by SCL/SDA interrupt
This is the countermeasure for a communication interrupt in the middle of from START condition
to a slave address. However, the detection condition must be considered because a interrupt is
also generated by communication from other masters to other slaves.
➁ SMBUS interrupt after receiving slave address
This is the countermeasure for when communication is interrupted from receiving a slave address
until receiving a command.
(2) Low hold of communication line
The I2C-BUS interface conforms to the I2C-BUS Standard Specifications. However, because the use
condition of SMBUS differs from the I 2C-BUS’s, there is possibility of occurrence of the following
problem.
➀ Low hold of SDA line caused by ACK pulse at voltage drop of communication line
When the SMBUS voltage slowly drops, that is caused by extracting a battery from equipment or
turning off a PC’s power or etc., it might be incorrectly treated as the SCL pulse near the threshold
level voltage.
When the SDA is judged “L” in that condition, it becomes the general call and the ACK is transmitted.
However, when the SCL remains “L” at the ACK pulse, the SDA continuously remains “L” until
input of the next SCL pulse.
Countermeasure:
As explained before, start the time out count at the falling of SDA line of START condition and
reset ES0 bit of the S1D register when the time out is satisfied (Note).
Note: Do not use the read-modify-write instruction at this time. Furthermore, when the ES0 bit is
set to “0”, it becomes a general-purpose port ; so that the port must be set to input mode
or “H”.
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APPLICATION
3804 Group (Spec.H)
2.6 PWM
2.6 PWM
This paragraph explains the registers setting method and the notes relevant to the PWM.
2.6.1 Memory map
Address
002B16
PWM control register (PWMCON)
002C16
PWM prescaler (PREPWM)
PWM register (PWM)
002D16
Fig. 2.6.1 Memory map of registers relevant to PWM
2.6.2 Relevant registers
PWM control register
b7 b6 b5 b4 b3 b2 b1 b0
PWM control register (PWMCON: address 002B16)
b
Name
Functions
0 PWM function
0 : PWM disabled
enable bit
1 : PWM enabled
1 Count source
0 : f(XIN)
selection bit
1 : f(XIN)/2
2 Nothing is arranged for these bits. These are
3 write disabled bits. When these bits are read
4 out, the contents are “0”.
5
6
7
At reset R W
0
0
0
0
0
0
0
0
✕
✕
✕
✕
✕
✕
Fig. 2.6.2 Structure of PWM control register
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APPLICATION
3804 Group (Spec.H)
2.6 PWM
PWM prescaler
b7 b6 b5 b4 b3 b2 b1 b0
PWM prescaler
(PREPWM: address 002C16)
b
Functions
At reset R W
0 •Set the PWM period.
1 •The value set in this register is written to both
PWM prescaler pre-latch and PWM prescaler
2 latch at the same time.
3 • When data is written to this register during
PWM output, the pulse corresponding to
4 changed value is output at the next period.
5 • When this register is read out, the count value
of the PWM prescaler latch is read out.
6
Undefined
7
Undefined
Undefined
Undefined
Undefined
Undefined
Undefined
Undefined
Fig. 2.6.3 Structure of PWM prescaler
PWM register
b7 b6 b5 b4 b3 b2 b1 b0
PWM register
(PWM: address 002D16)
b
Functions
At reset R W
0 • Set the PWM “H” level output interval.
1 • The value set in this register is written to both
PWM register pre-latch and PWM register
2 latch at the same time.
3 • When data is written to this register during
PWM output, the pulse corresponding to
4 changed value is output at the next period.
5 • When this register is read out, the contents of
the PWM register latch is read out.
6
Undefined
7
Undefined
Undefined
Undefined
Undefined
Undefined
Undefined
Undefined
Fig. 2.6.4 Structure of PWM register
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APPLICATION
3804 Group (Spec.H)
2.6 PWM
2.6.3 PWM output circuit application example
<Motor control>
Outline : The rotation speed of the motor is controlled by using PWM (pulse width modulation) output.
Figure 2.6.5 shows a connection diagram ; Figures 2.6.6 shows PWM output timing, and Figure 2.6.7
shows a setting of the related registers.
M
P56/PWM
D/A converter
Motor driver
3804 group
(Spec. H)
Fig. 2.6.5 Connection diagram
Specifications : • Motor is controlled by using the PWM output function of 8-bit resolution.
• Clock f(XIN) = 5 MHz
• “T”, PWM cycle : 102 µs
• “t”, “H” level width of output pulse : 40 µs (Fixed speed)
✽ A motor speed can be changed by modifying the “H” level width of output pulse.
t = 40 µs
PWM output
T = 102 µs
Fig. 2.6.6 PWM output timing
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APPLICATION
3804 Group (Spec.H)
2.6 PWM
PWM control register (Address : 002B16)
b7
b0
0 1
PWMCON
PWM output: Enabled (Note)
Count source: f(XIN)
PWM prescaler (Address : 002C16)
b7
PREPWM
b0
n
Set “T”, PWM cycle
n=1
[Equation]
255 ✕ (n + 1)
T=
f(XIN)
Set “t”, “H” level width of PWM
m = 100
[Equation]
t= T✕m
255
PWM register (Address : 002D16)
b7
PWM
b0
m
Note: The PWM output function has priority even when bit 6 (corresponding bit to P56 pin)
of Port P5 direction register is set to “0” (input mode).
Fig. 2.6.7 Setting of relevant registers
<About PWM output>
1. Set the PWM function enable bit to “1” : The P56/PWM pin is used as the PWM pin.
The pulse beginning with “H” level pulse is output.
2. Set the PWM function enable bit to “0” : The P56/PWM pin is used as the port P56.
Thus, when fixing the output level, take the following procedure:
(1) Write an output value to bit 6 of the port P5 register.
(2) Write “010000002” to the port P5 direction register.
3. After data is set to the PWM prescaler and the PWM register, the PWM waveforms corresponding to updated
data will be output from the next repetitive cycle.
PWM output
Change PWM
output data
From the next repetitive cycle,
output modified data
Fig. 2.6.8 PWM output
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3804 Group (Spec.H)
2.6 PWM
By setting the related registers as shown by Figure 2.6.7, PWM waveforms are output to the externals.
This PWM output is integrated through the low pass filter, and that converted into DC signals is used
for control of the motor. Figure 2.6.9 shows control procedure.
• X : This bit is not used here.
Set it to “0” or “1” arbitrarily.
~
~
P5 (Address : 000A16), bit6
P5D (Address : 000B16)
0
X1XXXXXX2
PREPWM (Address : 002C16)
PWM
(Address : 002D16)
PWMCON (Address : 002B16)
1
100
XXXXXX012
• “L” level output from P56/PWM pin
• PWM period setting
• “H” level width of PWM setting
• PWM count source selected, PWM output enabled
~
~
Fig. 2.6.9 Control procedure
2.6.4 Notes on PWM
The PWM starts after the PWM enable bit is set to enable and “L” level is output from the PWM pin.
The length of this “L“ level output is as follows:
n + 1
2 • f(XIN)
(s)
(Count source selection bit = 0, where n is the value set in the prescaler)
n + 1
f(XIN)
(s)
(Count source selection bit = 1, where n is the value set in the prescaler)
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2.7 A/D converter
2.7 A/D converter
This paragraph explains the registers setting method and the notes relevant to the A/D converter.
2.7.1 Memory map
Address
003416
AD/DA control register (ADCON)
003516
AD conversion register 1 (AD1)
003816
AD conversion register 2 (AD2)
003916
Interrupt source selection register (INTSEL)
003D16
Interrupt request register 2 (IREQ2)
003F16
Interrupt control register 2 (ICON2)
Fig. 2.7.1 Memory map of registers relevant to A/D converter
2.7.2 Relevant registers
AD/DA control register
b7 b6 b5 b4 b3 b2 b1 b0
AD/DA control register
(ADCON: address 003416)
b
Name
0 Analog input pin
selection bits 1
1
2
Functions
b2 b1 b0
0 0 0: P60/AN0 or P00/AN8
0 0 1: P61/AN1 or P01/AN9
0 1 0: P62/AN2 or P02/AN10
0 1 1: P63/AN3 or P03/AN11
1 0 0: P64/AN4 or P04/AN12
1 0 1: P65/AN5 or P05/AN13
1 1 0: P66/AN6 or P06/AN14
1 1 1: P67/AN7 or P07/AN15
0: Conversion in progress
3 AD conversion
1: Conversion completed
completion bit
4 Analog input pin
0: AN0 to AN7 side
1: AN8 to AN15 side
selection bit 2
5 Nothing is arranged for this bit. This is a write
disabled bit. When this bit is read out, the
contents are “0”.
6 DA1 output enable 0: DA1 output disabled
1: DA1 output enabled
bit
7 DA2 output enable 0: DA2 output disabled
1: DA2 output enabled
bit
At reset R W
0
0
0
1
0
0
0
0
Fig. 2.7.2 Structure of AD/DA control register
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2.7 A/D converter
AD conversion register 1
b7 b6 b5 b4 b3 b2 b1 b0
AD conversion register 1
(AD1: address 003516)
b
Functions
0 This is A/D conversion result stored bits. This is
1 read exclusive register.
2
8-bit read
b7
b0
3
b9 b8 b7 b6 b5 b4 b3 b2
4
5
10-bit read
b7
b0
6
b7 b6 b5 b4 b3 b2 b1 b0
7
At reset R W
Undefined
Undefined
0
Undefined
0
Undefined
0
Undefined
0
Undefined
0
Undefined
0
Undefined
0
Fig. 2.7.3 Structure of AD conversion register 1
AD conversion register 2
b7 b6 b5 b4 b3 b2 b1 b0
AD conversion register 2
(AD2: address 003816)
b
Functions
At reset R W
0 This is A/D conversion result stored bits. This is Undefined
read exclusive register.
10-bit read b0
b7
Undefined
1
0
b9 b8
2
3
4
5
6
7
Nothing is arranged for these bits. These are
write disabled bits. When these bits are read out,
the contents are “0”.
Conversion mode
selection bit
0: 10-bit A/D mode
1: 8-bit A/D mode
0
0
0
0
0
0
Fig. 2.7.4 Structure of AD conversion register 2
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2.7 A/D converter
Interrupt source selection register
b7 b6 b5 b4 b3 b2 b1 b0
Interrupt source selection register
(INTSEL: address 003916)
b
Name
Functions
At reset R W
0 INT0/Timer Z
interrupt source
selection bit (*1)
0: INT0 interrupt
1: Timer Z interrupt
0
1 Serial I/O2/Timer Z
interrupt source
selection bit (*1)
2 Serial I/O1 transmit/
SCL, SDA interrupt
source selection bit
(*2)
0: Serial I/O2 interrupt
1: Timer Z interrupt
0
0: Serial I/O1 transmit
interrupt
1: SCL, SDA interrupt
0
0: CNTR0 interrupt
1: SCL, SDA interrupt
0
0: INT4 interrupt
1: CNTR2 interrupt
0
0: INT2 interrupt
1: I2C interrupt
0: CNTR1 interrupt
1: Serial I/O3 receive
interrupt
0: A/D converter interrupt
1: Serial I/O3 transmit
interrupt
0
3 CNTR0/SCL, SDA
interrupt source
selection bit (*2)
4 INT4/CNTR2
interrupt source
selection bit
5 INT2/I2C interrupt
source selection bit
6 CNTR1/Serial I/O3
receive interrupt
source selection bit
7 AD converter/Serial
I/O3 transmit
interrupt source
selection bit
0
0
*1: Do not write 1 to these bits simultaneously.
*2: Do not write 1 to these bits simultaneously.
Fig. 2.7.5 Structure of Interrupt source selection register
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2.7 A/D converter
Interrupt request register 2
b7 b6 b5 b4 b3 b2 b1 b0
Interrupt request register 2
(IREQ2 : address 003D16)
b
Name
Functions
At reset R W
0 CNTR0/SCL, SDA
interrupt request bit
1 CNTR1/Serial I/O3
receive interrupt
request bit
0 : No interrupt request issued
1 : Interrupt request issued
0 : No interrupt request issued
1 : Interrupt request issued
0
✽
0
✽
2 Serial I/O2/Timer Z
interrupt request bit
3 INT2/I2C interrupt
request bit
4 INT3 interrupt
request bit
5 INT4/CNTR2
interrupt request bit
6 AD converter/Serial
I/O3 transmit
interrupt request bit
0 : No interrupt request issued
1 : Interrupt request issued
0 : No interrupt request issued
1 : Interrupt request issued
0 : No interrupt request issued
1 : Interrupt request issued
0 : No interrupt request issued
1 : Interrupt request issued
0 : No interrupt request issued
1 : Interrupt request issued
0
✽
0
✽
0
✽
0
✽
0
✽
0
7 Nothing is arranged for this bit. This is a write
disabled bit. When this bit is read out, the
contents are 0 .
✽: 0 can be set by software, but 1 cannot be set.
Fig. 2.7.6 Structure of Interrupt request register 2
Interrupt control register 2
b7 b6 b5 b4 b3 b2 b1 b0
0
Interrupt control register 2
(ICON2 : address 003F16)
b
Name
Functions
At reset R W
0 CNTR0/SCL, SDA
interrupt enable bit
CNTR
1/ Serial I/O3
1
receive interrupt
enable bit
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0
2 Serial I/O2/ Timer Z
interrupt enable bit
3 INT2/I2C interrupt
enable bit
4 INT3 interrupt
enable bit
5 INT4/CNTR2
interrupt enable bit
6 AD converter/Serial
I/O3 transmit
interrupt enable bit
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
0
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0
7 Fix this bit to “0”.
0
0
0
0
0
Fig. 2.7.7 Structure of Interrupt control register 2
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2.7 A/D converter
2.7.3 A/D converter application examples
(1) Conversion of analog input voltage 1
Outline : The analog input voltage input from a sensor is converted to digital values.
Figure 2.7.8 shows a connection diagram, and Figure 2.7.9 shows the relevant registers setting.
P60/AN0
Sensor
3804 Group
(Spec. H)
Fig. 2.7.8 Connection diagram
Specifications : •The analog input voltage input from a sensor is converted to digital values.
•P6 0/AN 0 pin is used as an analog input pin.
•10-bit A/D mode
AA
AA
A
A
AAAAAA
AD/DA control register (address 003416)
b7
ADCON
b0
0 0 0 0 0
Analog input pin : P60/AN0 selected
A/D conversion start
Analog input pin : AN0–AN7 selected
AA
A
AA A
AD conversion register 2 (address 003816)
b7
AD2
b0
0
A result of A/D conversion is stored (read-only) (Note).
10-bit A/D mode
AD conversion register 1 (address 003516)
b7
b0
(Read-only)
AD1
A result of A/D conversion is stored (Note).
Note: After bit 3 of AD/DA control register (ADCON) is set to “1”, read out that contents.
When reading 10-bit data, read address 003816 before address 003516.
When reading 10-bit data, bits 2 to 6 of address 003816 become “0”.
Fig. 2.7.9 Relevant registers setting
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2.7 A/D converter
An analog input signal from a sensor is converted to the digital value according to the relevant
registers setting shown by Figure 2.7.9. Figure 2.7.10 shows the control procedure for 10-bit A/D
mode.
● X: This bit is not used here. Set it to “0” or “1” arbitrarily.
AD2 (address 003816)
•10-bit A/D mode selected
0XXXXXXX2
ADCON (address 003416)
•P60/AN0 pin selected as analog input pin
•A/D conversion start
XX0000002
ADCON (address 003416), bit3 ?
0
•Judgment of A/D conversion completion
1
Read out AD2 (address 003816)
•Read out of high-order digit (b9, b8) of conversion result
Read out AD1 (address 003516)
•Read out of low-order digit (b7 – b0) of conversion result
Fig. 2.7.10 Control procedure (10-bit A/D mode)
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2.7 A/D converter
(2) Conversion of analog input voltage 2
Outline : The analog input voltage input from a sensor is converted to digital values.
Figure 2.7.11 shows a connection diagram, and Figure 2.7.12 shows the relevant registers setting.
P60/AN0
Sensor
3804 Group
(Spec. H)
Fig. 2.7.11 Connection diagram
Specifications : •The analog input voltage input from a sensor is converted to digital values.
•P6 0/AN 0 pin is used as an analog input pin.
•8-bit A/D mode
AA
AA
A
A
AAAAAA
AD/DA control register (address 003416)
b7
ADCON
b0
0 0 0 0 0
Analog input pin : P60/AN0 selected
A/D conversion start
Analog input pin : AN0–AN7 selected
AA A
AA A
AD conversion register 2 (address 003816)
b7
AD2
b0
1
8-bit A/D mode
AD conversion register 1 (address 003516)
b7
b0
(Read-only)
AD1
A result of A/D conversion is stored (Note).
Note: After bit 3 of AD/DA control register (ADCON) is set to “1”, read out that contents.
When reading 8-bit data, read address 003516 only.
Fig. 2.7.12 Relevant registers setting
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2.7 A/D converter
An analog input signal from a sensor is converted to the digital value according to the relevant
registers setting shown by Figure 2.7.12. Figure 2.7.13 shows the control procedure for 8-bit A/D
mode.
● x: This bit is not used here. Set it to “0” or “1” arbitrarily.
AD2 (address 003816)
ADCON (address 003416)
1XXXXXXX2
•8-bit A/D mode selected
XX0000002
•P60/AN0 pin selected as analog input pin
•A/D conversion start
ADCON (address 003416), bit3 ?
0
•Judgment of A/D conversion completion
1
Read out AD1 (address 003516)
•Read out of conversion result
Fig. 2.7.13 Control procedure (8-bit A/D mode)
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2.7 A/D converter
2.7.4 Notes on A/D converter
(1) Analog input pin
Make the signal source impedance for analog input low, or equip an analog input pin with an external
capacitor of 0.01 µF to 1 µF. Further, be sure to verify the operation of application products on the
user side.
● Reason
An analog input pin includes the capacitor for analog voltage comparison. Accordingly, when
signals from signal source with high impedance are input to an analog input pin, charge and
discharge noise generates. This may cause the A/D conversion precision to be worse.
(2) A/D converter power source pin
The AVSS pin is A/D converter power source pins. Regardless of using the A/D conversion function
or not, connect it as following :
• AV SS : Connect to the V SS line
● Reason
If the AV SS pin is opened, the microcomputer may have a failure because of noise or others.
(3) Clock frequency during A/D conversion
The comparator consists of a capacity coupling, and a charge of the capacity will be lost if the clock
frequency is too low. Thus, make sure the following during an A/D conversion.
• f(X IN) is 500 kHz or more
• Do not execute the STP instruction
(4) Difference between at 8-bit reading in 10-bit A/D mode and at 8-bit A/D mode
At 8-bit reading in the 10-bit A/D mode, “–1/2 LSB” correction is not performed to the A/D conversion
result.
In the 8-bit A/D mode, the A/D conversion characteristics is the same as 3802 group’s characteristics
because “–1/2 LSB” correction is performed.
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2.8 D/A converter
2.8 D/A Converter
This paragraph explains the registers setting method and the notes relevant to the D/A converter.
2.8.1 Memory map
000716
Port P3 direction register (P3D)
003416
AD/DA control register (ADCON)
003616
DA1 conversion register (DA1)
003716
DA2 conversion register (DA2)
Fig. 2.8.1 Memory map of registers relevant to D/A converter
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2.8 D/A converter
2.8.2 Relevant registers
Port P3 direction register
b7 b6 b5 b4 b3 b2 b1 b0
Port P3 direction register
(P3D: address 000716)
b
Name
0 Port P3 direction
register
1
2
3
4
5
6
7
Functions
0 : Port P30 input mode
1 : Port P30 output mode
0 : Port P31 input mode
1 : Port P31 output mode
0 : Port P32 input mode
1 : Port P32 output mode
0 : Port P33 input mode
1 : Port P33 output mode
0 : Port P34 input mode
1 : Port P34 output mode
0 : Port P35 input mode
1 : Port P35 output mode
0 : Port P36 input mode
1 : Port P36 output mode
0 : Port P37 input mode
1 : Port P37 output mode
At reset R W
0
0
0
0
0
0
0
0
Fig. 2.8.2 Structure of Port P5 direction register
AD/DA control register
b7 b6 b5 b4 b3 b2 b1 b0
AD/DA control register
(ADCON: address 003416)
b
Name
0 Analog input pin
selection bits 1
1
2
Functions
b2 b1 b0
0 0 0: P60/AN0 or P00/AN8
0 0 1: P61/AN1 or P01/AN9
0 1 0: P62/AN2 or P02/AN10
0 1 1: P63/AN3 or P03/AN11
1 0 0: P64/AN4 or P04/AN12
1 0 1: P65/AN5 or P05/AN13
1 1 0: P66/AN6 or P06/AN14
1 1 1: P67/AN7 or P07/AN15
0: Conversion in progress
3 AD conversion
1: Conversion completed
completion bit
4 Analog input pin
0: AN0 to AN7 side
1: AN8 to AN15 side
selection bit 2
5 Nothing is arranged for this bit. This is a write
disabled bit. When this bit is read out, the
contents are “0”.
6 DA1 output enable 0: DA1 output disabled
1: DA1 output enabled
bit
7 DA2 output enable 0: DA2 output disabled
1: DA2 output enabled
bit
At reset R W
0
0
0
1
0
0
0
0
Fig. 2.8.3 Structure of AD/DA control register
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2.8 D/A converter
DAi conversion register
b7 b6 b5 b4 b3 b2 b1 b0
DAi conversion register (i = 1, 2)
(DAi: addresses 003616, 003716)
b
Functions
0 This is D/A output value stored bits. This is write
1 exclusive register.
2
3
4
5
6
7
At reset R W
0
0
0
0
0
0
0
0
Fig. 2.8.4 Structure of DAi converter register
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2.8 D/A converter
2.8.3 D/A converter application example
(1) Speaker output volume modulation
Outline: The volume of a speaker output is modulated by using D/A converter.
Specifications: •Timer X modulates the period of sound for the pitch interval, so that a fixed pitch
(“la”: approx. 440 Hz) can be output. Modulating the amplitude with the D/A output
value controls the volume.
•Use f(XIN) = 6 MHz.
•Use DA1 (P3 0/DA 1 pin) as D/A converter.
Figure 2.8.5 shows a peripheral circuit example and Figure 2.8.6 shows a speaker output example.
Figure 2.8.7 shows the relevant registers setting.
3804 Group (Spec. H)
P30/DA1
Amplification
circuit
Power
amplifier
+
Fig. 2.8.5 Peripheral circuit example
Modulation of volume
VREF
(amplitude is set
by D/A1 output)
VSS
Timer X
interrupt
Timer X
interrupt
Timer X
interrupt
Timer X
interrupt
Timer X
interrupt
Timer X
interrupt
Modulation of pitch interval: 440 Hz
(Cycle is set by timer X)
Fig. 2.8.6 Speaker output example
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b7
2.8 D/A converter
b0
0
Port P3 direction register (P3D) (address 000716)
P30/DA1: Input mode
b7
b0
1
AD/DA control register (ADCON) (address 003416)
DA1 output enabled
b7
b0
Timer XY mode register (TM) (address 002316)
0 0 1
Timer X count: Stop
Timer mode
b7
b0
Timer 12, X count source serection register (T12XCSS) (address 000E16)
0 0 1 1
Timer X count source: f(XIN)/16
b7
b0
Prescaler X (PREX) (address 002416)
2–1
Set “division ratio –1”
b7
b0
Timer X (TX) (address 002516)
D616 – 1
Set “division ratio –1”
b7
b0
Interrupt request register 1 (IREQ1) (address 003C16)
0
Timer X interrupt request
b7
b0
Interrupt control register 1 (ICON1) (address 003E16)
1
Timer X interrupt: Enabled
b7
b0
DA1 conversion register (DA1) (address 003616)
Set conversion value (n)
Analog voltage V =
b7
VREF × n
256
(n=0 to 255)
b0
0 0 0
Timer XY mode register (TM) (address 002316 )
Timer X count: Start
Fig. 2.8.7 Relevant registers setting
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2.8 D/A converter
When the registers are set as shown in Figure 2.8.7, the speaker output volume is modulated by the
D/A output value. Figure 2.8.8 shows the control procedure.
RESET
● x: This bit is not used here. Set it to “0” or “1” arbitrarily.
Initialization
SEI
CLT (Note 1)
CLD (Note 2)
•All interrupts disabled
.....
(address 003E16), bit4
0
ICON1
(address 000716), bit0
0
P3D
X1XXXXXX2
(address 003416)
ADCON
XX001XXX2
(address 002316)
TM
0011XXXX2
T12XCSS (address 000E16)
2–1
(address 002416)
PREX
D616 – 1
(address 002516)
TX
1
WORK flag (Note 3)
(address 003C16), bit4
0
IREQ1
(address 003E16), bit4
1
ICON1
(address 003616)
Set output value (volume)
DA1
CLI
(address 002316)
XX000XXX2
TM
•Timer X interrupt disabled
•Set port P30 to input mode
•DA1 output enabled
•Timer Y: Timer mode, Timer X count: Stop
•Timer X count source: f(XIN)/16
•Set “division ratio – 1” to Prescaler X
•Set “division ratio – 1” to Timer X
•Timer X interrupt request bit cleared
•Timer X interrupt: Enabled
•D/A converter start
•All interrupts enabled
•Timer X count start
.....
Notes 1: When using Index X mode flag
2: When using Decimal mode flag
3: The WORK flag is a user flag for work. When this flag is “1
”, a value other than Vss is output from the DA output pin.
When this flag is “0”, Vss is output from the DA output pin.
Main processing
Timer X interrupt process routine
Push registers to stack
Value of WORK flag ?
•Push registers used in interrupt process routine
“0”
“1”
Set value except Vss to DA1 conversion
register.
Set “0” to WORK flag.
Pop registers
Set value of Vss to DA1 conversion register.
Set “1” to WORK flag.
•Pop registers pushed to stack
RTI
✻ Decide an D/A value from several times of D/A conversion results.
Fig. 2.8.8 Control procedure
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2.8 D/A converter
2.8.4 Notes on D/A converter
(1) Vcc when using D/A converter
The D/A converter accuracy when Vcc is 4.0 V or less differs from that of when Vcc is 4.0 V or more.
When using the D/A converter, we recommend using a Vcc of 4.0 V or more.
(2) DAi conversion register when not using D/A converter
When a D/A converter is not used, set all values of the DAi conversion registers (i = 1, 2) to “00 16”.
The initial value after reset is “00 16”.
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2.9 Watchdog timer
2.9 Watchdog timer
This paragraph explains the registers setting method and the notes relevant to the watchdog timer.
2.9.1 Memory map
Address
001E16
Watchdog timer control register (WDTCON)
003B16
CPU mode register (CPUM)
Fig. 2.9.1 Memory map of registers relevant to watchdog timer
2.9.2 Relevant registers
Watchdog timer control register
b7 b6 b5 b4 b3 b2 b1 b0
Watchdog timer control register
(WDTCON: address 001E16)
b
Name
Functions
0 Watchdog timer H
1 (for read-out of high-order 6 bit)
2
3
4
5
6 STP instruction
0: STP instruction enabled
1: STP instruction disabled
disable bit
7 Watchdog timer H 0: Watchdog timer L
underflow
count source selection
1: f(XIN)/16 or f(XCIN)/16
bit
At reset R W
1
✕
✕
1
1
✕
✕
1
1
✕
✕
1
0
0
Fig. 2.9.2 Structure of Watchdog timer control register
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2.9 Watchdog timer
CPU mode register
b7 b6 b5 b4 b3 b2 b1 b0
1
CPU mode register
(CPUM: address 003B16)
b
Name
0 Processor mode
bits
1
2 Stack page
selection bit
3 Fix this bit to “1”.
Functions
b1 b0
00 : Single-chip mode
01 :
10 :
Not available
11 :
0 : 0 page
1 : 1 page
At reset R W
0
0
0
1
4 Port Xc switch bit
0: I/O port function
(stop oscillating)
1: XCIN-XCOUT oscillation
function
0
5 Main clock (XINXOUT) stop bit
6 Main clock division
ratio selection bits
0: Oscillating
1: Stopped
0
b7 b6
1
7
0 0: φ=f(XIN)/2
(high-speed mode)
0 1: φ=f(XIN)/8
(middle-speed mode)
1 0: φ=f(XCIN)/2
(low-speed mode)
1 1: Not available
0
Fig. 2.9.3 Structure of CPU mode register
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2.9 Watchdog timer
2.9.3 Watchdog timer application examples
(1) Detection of program runaway
Outline: If program runaway occurs, let the microcomputer reset, using the internal timer for detection
of program runaway.
Specifications: •High-speed mode is used as a main clock division ratio.
•An underflow signal of the watchdog timer L is supplied as the count source of
watchdog timer H.
•1 cycle of main routine is 65.536 ms or less.
•Before the watchdog timer H underflows, “0” is set into bit 7 of the watchdog timer
control register at every cycle in a main routine.
•An underflow of watchdog timer H is judged to be program runaway, and the
microcomputer is returned to the reset status.
Figure 2.9.4 shows a watchdog timer connection and division ratio setting; Figure 2.9.5 shows the
relevant registers setting; Figure 2.9.6 shows the control procedure.
Fixed
f(XIN) = 16 MHz
1/16
Watchdog timer L Watchdog timer H
1/256
1/256
Reset
circuit
Internal reset
RESET
STP instruction disable bit
STP instruction
Fig. 2.9.4 Watchdog timer connection and division ratio setting
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2.9 Watchdog timer
CPU mode register (address 003B16)
b7
CPUM
0 0 0
b0
1
0 0
Processor mode: Single-chip mode
Fix to “1”
Main clock (XIN-XOUT): Operating
Main clock division ratio: f(XIN)/2 (high-speed mode)
Watchdog timer control register (address 001E16)
b7
WDTCON
b0
0 0
Watchdog timer H (for read-out of high-order 6 bits)
Enable STP instruction
Watchdog timer H count source: Watchdog timer L underflow
Fig. 2.9.5 Relevant registers setting
RESET
Initialization
SEI
CLT
CLD
CPUM (address 003B16)
:
:
CLI
WDTCON (address 001E16)
•All interrupts disabled
000X1X002
•Processor mode: Single-chip mode
•Main clock f(XIN): Operating
•High-speed mode selected as main clock division ratio
•Interrupts enabled
000XXXXX2
•Watchdog timer L underflow selected as Watchdog
timer H count source
•STP instruction enabled
Main processing
:
:
Fig. 2.9.6 Control procedure
2.9.4 Notes on watchdog timer
●Make sure that the watchdog timer H does not underflow while waiting Stop release, because the
watchdog timer keeps counting during that term.
●When the STP instruction disable bit has been set to “1”, it is impossible to switch it to “0” by a program.
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2.10 Reset
2.10 Reset
2.10.1 Connection example of reset IC
VCC
1
Power source
M62022L
5
Output
RESET
Delay capacity
4
GND
0.1 µF
3
VSS
3804 Group (Spec. H)
Fig. 2.10.1 Example of poweron reset circuit
Figure 2.10.2 shows the system example which switches to the RAM backup mode by detecting a drop of
the system power source voltage with the INT interrupt.
System power
source voltage
+5 V
VCC
+
7
VCC1
RESET 5
2
VCC2
INT
3
RESET
INT
VSS
1
V1
GND
4
Cd
6
3804 Group
(Spec. H)
M62009L,M62009P,M62009FP
Fig. 2.10.2 RAM backup system
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2.10 Reset
2.10.2 Notes on RESET pin
Connecting capacitor
In case where the RESET signal rise time is long, connect a ceramic capacitor or others across the
RESET pin and the V SS pin. Use a 1000 pF or more capacitor for high frequency use. When
connecting the capacitor, note the following :
• Make the length of the wiring which is connected to a capacitor as short as possible.
• Be sure to verify the operation of application products on the user side.
● Reason
If the several nanosecond or several ten nanosecond impulse noise enters the RESET pin, it may
cause a microcomputer failure.
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2.11
Clock generating circuit
2.11 Clock generating circuit
This paragraph explains how to set the registers relevant to the clock generating circuit and describes an
application example.
2.11.1 Relevant registers
CPU mode register
b7 b6 b5 b4 b3 b2 b1 b0
1
CPU mode register
(CPUM: address 003B16)
b
Name
0 Processor mode
bits
1
2 Stack page
selection bit
3 Fix this bit to “1”.
Functions
b1 b0
00 : Single-chip mode
01 : Not available
10 : Not available
11 : Not available
0 : 0 page
1 : 1 page
At reset R W
0
0
0
1
4 Port Xc switch bit
0: I/O port function
(oscillation stopped)
1: XCIN-XCOUT oscillation
function
0
5 Main clock (XINXOUT) stop bit
Main
clock division
6
ratio selection bits
0: Oscillating
1: Stopped
0
b7 b6
1
7
0 0: φ=f(XIN)/2
(high-speed mode)
0 1: φ=f(XIN)/8
(middle-speed mode)
1 0: φ=f(XCIN)/2
(low-speed mode)
1 1: Not available
0
Fig. 2.11.1 Structure of CPU mode register
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2.11
Clock generating circuit
2.11.2 Clock generating circuit application example
(1) Status transition during power failure
Outline: The clock counts up every second by using the timer interrupt during a power failure.
Input port
(Note)
Power failure detection signal
3804 Group (Spec. H)
Note: A signal is detected when input to input port, interrupt
input pin, or analog input pin.
Fig. 2.11.2 Connection diagram
Specifications: •Reducing power dissipation as low as possible while maintaining clock function
•Clock: f(X IN) = 8 MHz, f(X CIN) = 32.768 kHz
•Port processing
Input port: Fixed to “H” or “L” level externally.
Output port: Fixed to output level that does not cause current flow to the external.
(Example) Fix to “H” for an LED circuit that turns on at “L” output
level.
I/O port: Input port → Fixed to “H” or “L” level externally.
Output port → Output of data that does not consume current
V REF pin: Terminate A/D conversion operation
Stop VREF current dissipation by setting value of DAi conversion register
to “00 16”.
Figure 2.11.3 shows the status transition diagram during power failure and Figure 2.11.4 shows the
setting of relevant registers.
Reset released
Power failure detected
XIN
XCIN
Internal system clock
Middle-speed
mode
Low-speed mode
High-speed mode
Change internal system
clock to high-speed mode
After detection, change internal system clock to
low-speed mode and stop oscillating XIN-XOUT
XCIN-XCOUT oscillation function selected
Fig. 2.11.3 Status transition diagram during power failure
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2.11
b7
Clock generating circuit
b0
CPUM 0 0 0 0 1
0 0
CPU mode register (CPUM) (address 003B16)
Main clock: High-speed mode (f(XIN)/2) (Note 1)
b7
b0
CPUM 0 0 0 1 1
0 0
CPU mode register (CPUM) (address 003B16)
(Note 2)
Port XC: XCIN–XCOUT oscillation function
b7
b0
CPUM 1 0 0 1 1
0 0
CPU mode register (CPUM) (address 003B16)
Internal system clock: Low-speed mode (f(XCIN)/2)
b7
b0
CPUM 1 0 1 1 1
0 0
CPU mode register (CPUM) (address 003B16)
Main clock f(XIN): Stopped
Notes 1: This setting is necessary only when selecting the high-speed mode.
2: When selecting the middle-speed mode, bit 6 is “1”.
Fig. 2.11.4 Setting of relevant registers
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2.11
Clock generating circuit
Control procedure: To prepare for a power failure, set the relevant registers in the order shown
below.
●X: This bit is not used here. Set it to “0” or “1” arbitrarily.
RESET
Initialization
••••
CPUM (address 003B16), bit7, bit 6
CPUM (address 003B16), bit 4
0, 0
1
When selecting main clock f(XIN)/2 (high-speed mode)
Port XC: XCIN-XCOUT oscillation function
••••
N
Detect power failure ?
Y
CPUM (address 003B16), bit7, bit 6
CPUM (address 003B16), bit5
1, 0 (Note)
1 (Note)
Set timer interrupt to occurs every second.
Execute WIT instruction.
N
Internal system clock: f(XCIN)/2 (low-speed mode)
Main clock f(XIN) oscillation stopped
At power failure, clock count is performed during
timer interrupt processing (every second).
Return condition from power failure
completed ?
Y
Return processing from power failure
Note: Do not switch simultaneously.
Fig. 2.11.5 Control procedure
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2.12 Standby function
3804 Group (Spec.H)
2.12 Standby function
The 3804 group (Spec. H) is provided with standby functions to stop the CPU by software and put the CPU
into the low-power operation.
The following two types of standby functions are available.
•Stop mode using STP instruction
•Wait mode using WIT instruction
2.12.1 Stop mode
The stop mode is set by executing the STP instruction. In the stop mode, the oscillation of both clocks (XIN–
XOUT, X CIN–X COUT) stop and the internal clock φ stops at the “H” level. The CPU stops and peripheral units
stop operating. As a result, power dissipation is reduced.
(1) State in stop mode
Table 2.12.1 shows the state in the stop mode.
Table 2.12.1 State in stop mode
State in stop mode
Item
Oscillation
Stopped.
CPU
Stopped.
Internal clock φ
Stopped at “H” level.
I/O ports P0–P6
Timer
Retains the state at the STP instruction execution.
PWM
Watchdog timer
Serial I/O1, Serial I/O2, Serial I/O3
Stopped. (Timers 1, 2, X, Y, Z)
However, Timers X, Y, Z can be operated in the event counter
mode.
Stopped.
Stopped.
Stopped.
However, these can be operated only when an external clock
is selected.
A/D converter
Stopped.
Stopped.
D/A converter
Retains output voltage.
I 2C-BUS interface
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2.12 Standby function
3804 Group (Spec.H)
(2) Release of stop mode
The stop mode is released by a reset input or by the occurrence of an interrupt request. Note the
differences in the restoration process according to reset input or interrupt request, as described
below.
■Restoration by reset input
The stop mode is released by holding the RESET pin to the “L” input level during the stop mode.
Oscillation is started when all ports are in the input state and the stop mode of the main clock (XINXOUT) is released.
Oscillation is unstable when restarted. For this reason, time for stabilizing of oscillation (oscillation
stabilizing time) is required. The input of the RESET pin should be held at the “L” level until oscillation
stabilizes.
When the RESET pin is held at the “L” level for 16 cycles or more of X IN after the oscillation has
stabilized, the microcomputer will go to the reset state. After the input level of the RESET pin is
returned to “H”, the reset state is released in approximately 10.5 to 18.5 cycles of the XIN input.
Figure 2.12.1 shows the oscillation stabilizing time at restoration by reset input.
At release of the stop mode by reset input, the internal RAM retains its contents previous to the
reset. However, the previous contents of the CPU register and SFR are not retained.
For more details concerning reset, refer to “2.10 Reset”.
Stop mode
Oscillation
16 cycles or
stabilizing time more of XIN
Operating mode
Vcc
Time to hold internal reset state =
approximately 10.5 to 18.5 cycles of XIN input
RESET
XIN
(Note)
Execute Stop instruction
Note: Some cases may occur in which no waveform is input to XIN (in low-speed mode).
Fig. 2.12.1 Oscillation stabilizing time at restoration by reset input
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2.12 Standby function
■Restoration by interrupt request
The occurrence of an interrupt request in the stop mode releases the stop mode. As a result,
oscillation is resumed. The interrupts available for restoration are:
•INT 0–INT 4
•CNTR 0, CNTR1, CNTR2
•Serial I/O (1, 2, 3) using an external clock
•Timer X, Y, Z using an external event count
•SCL/SDA
However, when using any of these interrupt requests for restoration from the stop mode, in order to
enable the selected interrupt, you must execute the STP instruction after setting the following conditions.
[Necessary register setting]
➀ Interrupt disable flag I = “0” (interrupt enabled)
➁ Timer 1 interrupt enable bit = “0” (interrupt disabled)
➂ Interrupt request bit of interrupt source to be used for restoration = “0” (no interrupt request
issued)
➃ Interrupt enable bit of interrupt source to be used for restoration = “1” (interrupts enabled)
For more details concerning interrupts, refer to “2.2 Interrupts”.
Oscillation is unstable when restarted. For this reason, time for stabilizing of oscillation (oscillation
stabilizing time) is required. For restoration by an interrupt request, waiting time prior to supplying
internal clock φ to the CPU is automatically generated✽2 by Prescaler 12 and Timer 1✽1. This waiting
time is reserved as the oscillation stabilizing time on the system clock side. The supply of internal
clock φ to the CPU is started at the Timer 1 underflow.
Figure 2.12.2 shows an execution sequence example at restoration by the occurrence of an INT 0
interrupt request.
✽1: If the STP instruction is executed when the oscillation stabilizing time set after STP instruction
released bit is “0”, “FF 16” and “01 16” are automatically set in the Prescaler 12 counter/latch and
Timer 1 counter/latch, respectively. When the oscillation stabilizing time set after STP instruction
released bit is “1”, nothing is automatically set to either Prescaler 12 or Timer 1. For this reason,
any suitable value can be set to Prescaler 12 and Timer 1 for the oscillation stabilizing time.
✽2: Immediately after the oscillation is started, the count source is supplied to the prescaler 12 so
that a count operation is started.
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2.12 Standby function
3804 Group (Spec.H)
●When restoring microcomputer from stop mode by INT0 interrupt
(oscillation stabilizing time set after STP instruction released bit = “0”, rising edge selected)
Stop mode
XIN or XCIN
(System clock)
Oscillation stabilizing time
XIN; “H”
XCIN; in high-impedance state
INT0 pin
512 counts
“FF16”
Prescaler 12 counter
“0116”
Timer 1 counter
INT0 interrupt request bit
Peripheral device
Operating
CPU
Operating
Operating
Stopped
Execute STP
instruction
Stopped
INT0 interrupt signal
input (INT0 interrupt
request occurs)
Oscillation start
Prescaler 12 count start
Operating
512 counts down by
prescaler 12
Start supplying internal
clock φ to CPU
Accept INT0 interrupt
request
Note: The count source set at STP instruction execution is connected as the prescaler 12 count source.
Fig. 2.12.2 Execution sequence example at restoration by occurrence of INT 0 interrupt request
(3) Notes on using stop mode
■Register setting
Since values of the prescaler 12 and Timer 1 are automatically reloaded when returning from the
stop mode, set them again, respectively. (When the oscillation stabilizing time set after STP
instruction released bit is “0”)
■Clock restoration
After restoration from the stop mode to the normal mode by an interrupt request, the contents of
the CPU mode register previous to the STP instruction execution are retained. Accordingly, if both
main clock and sub clock were oscillating before execution of the STP instruction, the oscillation
of both clocks is resumed at restoration.
In the above case, when the main clock side is set as a system clock, the oscillation stabilizing
time until the timer 1 underflow is reserved at restoration from the stop mode.
When the oscillation stabilizing time set after STP instruction released bit is “0”, the time for 512
counts of the count source become the oscillation stabilizing time. When the oscillation stabilizing
time set after STP instruction released bit is “1”, an arbitrarily count value set to the prescaler 12
and the timer 1 become the oscillation stabilizing time.
At this time, note that the oscillation on the sub clock side may not be stabilized even after the
lapse of the oscillation stabilizing time of the main clock side.
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2.12 Standby function
3804 Group (Spec.H)
2.12.2 Wait mode
The wait mode is set by execution of the WIT instruction. In the wait mode, oscillation continues, but the
internal clock φ stops at the “H” level.
The CPU stops, but most of the peripheral units continue operating.
(1) State in wait mode
The continuation of oscillation permits clock supply to the peripheral units. Table 2.12.2 shows the
state in the wait mode.
Table 2.12.2 State in wait mode
State in wait mode
Item
Oscillation
Operating.
CPU
Stopped.
Internal clock φ
Stopped at “H” level.
I/O ports P0–P6
Timer
Retains the state at the WIT instruction execution.
PWM
Watchdog timer
Operating.
Operating.
Serial I/O1, Serial I/O2, Serial I/O3
Operating.
2
Operating.
I C-BUS interface
Stopped.
A/D converter
D/A converter
Operating.
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3804 Group (Spec.H)
(2) Release of wait mode
The wait mode is released by reset input or by the occurrence of an interrupt request. Note the
differences in the restoration process according to reset input or interrupt request, as described
below.
In the wait mode, oscillation is continued, so an instruction can be executed immediately after the
wait mode is released.
■Restoration by reset input
The wait mode is released by holding the input level of the RESET pin at “L” in the wait mode.
Upon release of the wait mode, all ports are in the input state, and supply of the internal clock
φ to the CPU is started. To reset the microcomputer, the RESET pin should be held at an “L” level
for 16 cycles or more of XIN. The reset state is released in approximately 10.5 cycles to 18.5 cycles
of the XIN input after the input of the RESET pin is returned to the “H” level.
At release of wait mode, the internal RAM retains its contents previous to the reset. However, the
previous contents of the CPU register and SFR are not retained.
Figure 2.12.3 shows the reset input time.
For more details concerning reset, refer to “2.10 Reset”.
Operating mode
Wait mode
Vcc
16 cycles of XIN
Time to hold internal reset state =
approximately 10.5 to 18.5 cycles of XIN input
RESET
XIN
(Note)
Execute WIT instruction
Note: Some cases may occur in which no waveform is input to XIN (in low-speed mode).
Fig. 2.12.3 Reset input time
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2.12 Standby function
■Restoration by interrupt request
In the wait mode, the occurrence of an interrupt request releases the wait mode and supply of the
internal clock φ to the CPU is started. At the same time, the interrupt request used for restoration
is accepted, so the interrupt processing routine is executed.
However, when using an interrupt request for restoration from the wait mode, in order to enable the
selected interrupt, you must execute the STP instruction after setting the following conditions.
[Necessary register setting]
➀ Interrupt disable flag I = “0” (interrupt enabled)
➁ Interrupt request bit of interrupt source to be used for restoration = “0” (no interrupt request issued)
➂ Interrupt enable bit of interrupt source to be used for restoration = “1” (interrupts enabled)
For more details concerning interrupts, refer to “2.2 Interrupts”.
(3) Notes on wait mode
■Clock restoration
If the wait mode is released by a reset when X CIN is set as the system clock and X IN oscillation is
stopped during execution of the WIT instruction, X CIN oscillation stops, XIN oscillations starts, and
X IN is set as the system clock.
In the above case, the RESET pin should be held at “L” until the oscillation is stabilized.
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2.13 Flash memory mode
3804 Group (Spec.H)
2.13 Flash memory mode
This paragraph explains the registers setting method and the notes relevant to the flash memory mode of
M38049FFHSP/FP/HP/KP.
2.13.1 Overview
The functions of the flash memory version are similar to those of the mask ROM version except that the
flash memory is built-in and some of the SFR area differ from that of the mask ROM version (refer to
“2.13.2 Memory map”).
In the flash memory version, the built-in flash memory can be programmed or erased by using the following
three modes.
• CPU rewrite mode
• Parallel I/O mode
• Standard serial I/O mode
2.13.2 Memory map
M38049FFHSP/FP/HP/KP have 60 Kbytes of built-in flash memory.
Figure 2.13.1 shows the memory map of the flash memory version.
000016
SFR area
004016
180016
Internal RAM area
(2 Kbytes)
RAM
100016
User ROM area
Data block B:
2 Kbytes
Data block A:
2 Kbytes
200016
083F16
Block 3: 24 Kbytes
800016
0FE016
0FFF16
100016
Block 2: 16 Kbytes
SFR area
C00016
Notes 1: The boot ROM area can be rewritten in a parallel I/O mode. (Access to except boot ROM
area is disabled.)
2: To specify a block, use the maximum address
in the block.
Block 1: 8 Kbytes
Internal flash memory area
(60 Kbytes)
F00016
E00016
Boot ROM area
4 Kbytes
Block 0: 8 Kbytes
FFFF16
FFFF16
FFFF16
Fig. 2.13.1 Memory map of M38049FFHSP/FP/HP/KP
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2.13 Flash memory mode
3804 Group (Spec.H)
2.13.3 Relevant registers
Address
0FE016 Flash memory control register 0 (FMCR0)
0FE116 Flash memory control register 1 (FMCR1)
0FE216 Flash memory control register 2 (FMCR2)
Fig. 2.13.2 Memory map of registers relevant to flash memory
Flash memory control register 0
b7 b6 b5 b4 b3 b2 b1 b0
Flash memory control register 0
(FMCR0 : address 0FE016)
b
Name
Functions
At reset R W
0 : Busy (being automatic written
or automatic erased)
1 : Ready
1
1 CPU rewrite mode
select bit (Note 1)
0
2
0 : CPU rewrite mode invalid
(software commandes invalid)
1 : CPU rewrite mode valid
(Software commands
acceptable)
8 KB user block E/W 0: E/W disabled
enable bit (Notes 1, 1: E/W enabled
2)
Flash memory reset 0: Normal operation
bit (Notes 3, 4)
1: Reset
Not used (Do not write “1” to this bit.)
User ROM area
0: User ROM area is accessed
select bit (Note 5)
1: Boot ROM area is accessed
Program status flag 0: Pass
1: Error
Erase status flag
0: Pass
1: Error
0
0 RY/BY status flag
3
4
5
6
7
0
0
0
0
0
Notes 1: For this bit to be set to “1”, the user needs to write a “0” and then a
“1” to it in succession. For this bit to be set to “0”, write “0” only to
this bit.
2: This bit can be written only when the CPU rewrite mode select bit
is “1”.
3: Effective only when the CPU rewrite mode select bit = “1”. Fix this
bit to “0” when the CPU rewrite mode select bit is “0”.
4: When setting this bit to “1” (when the control circuit of flash memory
is reset), the flash memory cannot be accessed for 10 µs.
5: Write to this bit from program on RAM.
Fig. 2.13.3 Structure of Flash memory control register 0
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2.13 Flash memory mode
3804 Group (Spec.H)
Flash memory control register 1
b7 b6 b5 b4 b3 b2 b1 b0
Flash memory control register 1
(FMCR1 : address 0FE116)
b
Name
Functions
At reset R W
0 : Suspend invalid
0 Erase suspend
enable bit (Note 1) 1 : Suspend valid
1 Erase suspend
0 : Erase restart (no
request issued)
request bit (Note 2)
1 : Suspend request
(request issued)
2 Nothing is arranged for these bits. If writing to
3 these bits, write “0”. The contents are undefined
4 at reading.
5
0 : Erase active
6 Erase suspend flag
1 : Erase inactive (Erase
suspend mode)
0
7 Nothing is arranged for these bits. If writing to
these bits, write “0”. The contents are undefined
at reading.
0
0
0
0
0
0
1
Notes 1: For this bit to be set to “1”, the user needs to write a “0” and then
a “1” to it in succession.
2: Only when the erase suspend bit is “1”, this bit is valid.
Fig. 2.13.4 Structure of Flash memory control register 1
Flash memory control register 2
b7 b6 b5 b4 b3 b2 b1 b0
Flash memory control register 2
(FMCR2 : address 0FE216)
b
0
1
2
3
4
Name
Functions
Nothing is arranged for these bits. If writing to
these bits, write “0”. The contents are undefined
at reading.
At reset R W
1
0
1
0
0
All user block E/W
0 : E/W disabled
enable bit (Notes 1, 2) 1 : E/W enabled
0
5 Nothing is arranged for these bits. If writing to
6 these bits, write “0”. The contents are undefined
1
7 at reading.
0
Notes 1: For this bit to be set to “1”, the user needs to write a “0” and then
a “1” to it in succession.
2: Effective only when the CPU rewrite mode select bit = “1”.
Fig. 2.13.5 Structure of Flash memory control register 2
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2.13 Flash memory mode
3804 Group (Spec.H)
2.13.4 Parallel I/O mode
In the parallel I/O mode, program/erase to the built-in flash memory can be performed by a flash memory
programmer (EFP-I etc.).
The memory area of program/erase is from 0F000 16 to 0FFFF 16 (boot ROM area) or from 01000 16 to
0FFFF16 (user ROM area). Be especially careful when erasing; if the memory area is not set correctly, the
products will be damaged eternally.
Table 2.13.1 shows the parallel unit when programming by EFP-I in the parallel I/O mode.
•EFP-I provided by Suisei Electronics System Co., Ltd. (http://www.suisei.co.jp/index_e.htm)
(product available in Asia and Oceania only)
Table 2.13.1 Parallel unit when parallel programming (when using EFP-I provided by Suisei Electronics
System Co., Ltd.)
Products
M38049FFHSP
Parallel unit
EF3803F-64S
M38049FFHFP
EF3803F-64F
M38049FFHHP
M38049FFHKP
EF3803F-64H
Boot ROM area
User ROM area
0F000 16 to 0FFFF16
01000 16 to 0FFFF16
EF3803F-64U
2.13.5 Standard serial I/O mode
Table 2.13.2 shows a pin connection example (4 wires) between the programmer (EFP-I; Serial unit
EF1SRP-01U is required additionally) and the microcomputer when programming in the standard serial
I/O mode 1.
•EFP-I provided by Suisei Electronics System Co., Ltd. (http://www.suisei.co.jp/index_e.htm)
(product available in Asia and Oceania only)
Table 2.13.2 Connection example to programmer when serial programming (4 wires)
Function
Transfer clock input
Serial data input
Serial data output
Transmit/Receive
EFP-I (EF1SRP-01U)
EF1RP-01U side
Signal name
connector Line number
Flash memory version
Pin name
M38049FFHSP M38049FFHSP
pin number
pin number
13
21
T_SCLK
T_TXD
9
P4 6/S CLK1
10
P4 4/RxD 1
23
15
T_RXD
11
22
14
T_BUSY
12
P4 5/TxD1
P4 7/S RDY1/CNTR2
20
12
enable output
T_VPP
3
CNVSS
26
18
T_RESET
14
RESET (Note 1)
27
19
Target board power
T_VDD (Note 2)
4
VCC (Note 2)
1
57
source monitor input
GND
GND (Note 3)
1, 2, 15, 16
32, 3
24, 59
“H” input
Reset input
VSS, AVSS (Note 3)
Notes 1: Since reset release after write verification is not performed, when operating MCU after writing,
separate a target connection cable.
2: Supply Vcc of EFP-I side from user side so that the power supply voltage of the output buffer used
by the EFP-I side becomes the same as user side power supply voltage (Vcc).
3: Four pins (No. 1, 2, 15, and 16) of the EF1SRP-01U side connector are prepared for GND signal.
When connecting with a target board, although connection of only one pin does not have a
problem, we recommend connecting with two or more pins.
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APPLICATION
3804 Group (Spec.H)
2.13 Flash memory mode
2.13.6 CPU rewrite mode
In the CPU rewrite mode, issuing software commands through the Central Processing Unit (CPU) can
rewrite the built-in flash memory. Accordingly, the contents of the built-in flash memory can be rewritten
with the microcomputer itself mounted on board, without using the programmer.
Store the rewrite control program to the built-in flash memory in advance. The built-in flash memory cannot
be read in the CPU rewrite mode. Accordingly, after transferring the rewrite control program to RAM,
execute it on the RAM.
The following commands can be used in the CPU rewrite mode: read array, read status register, clear
status register, program, and block erase. For details concerning each command, refer to “CHAPTER 1
Flash memory mode (CPU rewrite mode)”.
(1) CPU rewrite mode beginning/release procedures
Operation procedure in the CPU rewrite mode for the built-in flash memory is described below.
[Beginning procedure]
➀ Apply “H” to the CNVSS pin and P4 5/TxD 1 pin (at selecting boot ROM area).
➁ Release reset.
➂ Set bits 6 and 7 (main clock division ratio selection bits) of the CPU mode register. (Make sure
that system clock φ is less than 4.0 MHz.)
➃ After CPU rewrite mode control program is transferred to internal RAM, jump to this control
program on RAM. (The following operations are controlled by this control program).
➄ Set “1” to the CPU rewrite mode select bit (bit 1 of address 0FFE 16 ).
For this bit to be set to “1”, the user needs to write “0” and then “1” to it in succession.
➅ Set “1” to the all user block E/W enable bit (bit 4 of address 0FE216). Set the 8 KB user block
E/W enable bit. (Set to “0” when E/W is disabled, and set to “1” when E/W is enabled.)✽
✽
For these bits to be set to “1”, the user needs to write “0” and then “1” to those in succession.
➆ Flash memory operations are executed by using software commands.
Note 1: The following procedures are also necessary.
• Control for data which is input from the external (serial I/O etc.) and to be programmed
to the flash memory.
• Initial setting for ports, etc.
• Writing to the watchdog timer
[Release procedure]
➀ Execute the read array command.
➁ In order to disable E/W to the user ROM area (except for data block), set “0” to the all user block E/
W enable bit (bit 4 of 0FE216) and the 8 KB user block E/W enable bit (bit 2 of 0FE016) (Note 2).
➂ Set the CPU rewrite mode select bit (bit 1 of address 0FFE 16) to “0”.
➃ Jump from the CPU rewriting control program on RAM to the user program on the flash memory.
Note 2: Although E/W inhibition is not indispensable, the safety of system improves by disabling
E/W except the time of E/W execution.
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2.13 Flash memory mode
Also, execute the following processing before the CPU reprogramming mode is selected so that
interrupts will not occur during the CPU reprogramming mode.
• Set the interrupt disable flag (I) to “1”
When the watchdog timer has already started, write to the watchdog timer control register (address
001E16) periodically during the CPU reprogramming mode in order not to generate the reset by the
underflow of the watchdog timer H.
During the program or erase execution, watchdog timer is automatically cleared. Accordingly, the
inernal reset by underflow does not occur.
When the interrupt request or reset occurs in the CPU reprogramming mode, the microcomputer
enters the following state;
• Interrupt occurs
This may cause a program runaway because the read from the flash memory which has the interrupt
vector area cannot be performed.
• Underflow of watchdog timer H, reset
This may cause a microcomputer reset; the built-in flash memory control circuit and the flash memory
control register are reset. When reset state is released with CNVss = “H” and P4 5/TxD1 = “H”, CPU
starts in the boot mode.
Also, when the above interrupt and reset occur during program/erase, error data may still exist after
reset release because the reprogramming of the flash memory is not completed, so that reprogramming
of the flash memory in the parallel I/O mode or serial I/O mode is required.
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APPLICATION
2.13 Flash memory mode
3804 Group (Spec.H)
2.13.7 Flash memory mode application examples
The control pin processing example on the system board in the standard serial I/O mode and the control
example in the CPU rewrite mode are described below.
(1) Control pin connection example on system board in standard serial I/O mode
As shown in Figure 2.13.6, in the standard serial I/O mode, the built-in flash memory can be rewritten
with the microcomputer mounted on board. Connection examples of control pins (P4 4/RxD, P45/TxD,
P4 6/S CLK1, P4 7/S RDY1/CNTR 2, CNVSS, and RESET pin) in the standard serial I/O mode are described
below.
RS-232C Serial programmer
M3
80
49
FF
HS
P/
FP
/H
P/
KP
Fig. 2.13.6 Rewrite example of built-in flash memory in standard serial I/O mode
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APPLICATION
2.13 Flash memory mode
3804 Group (Spec.H)
➀ When control signals are not affected to user system circuit
When the control signals in the standard serial I/O mode are not used or not affected to the user
system circuit, they can be connected as shown in Figure 2.13.7.
Target board
✽1
Not used or to user system circuit
M38049FFHSP/FP/HP/KP
TXD(P45)
SCLK1(P46)
RXD(P44)
BUSY(P47)
CNVSS
✽2
VCC
AVSS
VSS
RESET
XIN
XOUT
User reset signal (Low active)
✽1: When not used, set to input mode and pull up or pull down, or set to output mode and open.
✽2: It is necessary to apply Vcc to SCLK1 (P46) pin only when reset is released in the serial I/O mode 1.
It is necessary to apply Vss to SCLK1 (P46) pin only when reset is released in the serial I/O mode 2.
Fig. 2.13.7 Connection example in standard serial I/O mode (1)
➁ When control signals are affected to user system circuit-1
Figure 2.13.8 shows an example that the jumper switch cut-off the control signals not to supply
to the user system circuit in the standard serial I/O mode.
Target board
To user system circuit
M38049FFHSP/FP/HP/KP
TXD(P45)
✽
SCLK1(P46)
RXD(P44)
BUSY(P47)
VCC
AVSS
VSS
CNVSS
RESET
XIN XOUT
User reset signal (Low active)
✽: It is necessary to apply Vcc to SCLK1 (P46) pin only when reset is released in the serial I/O mode 1.
It is necessary to apply Vss to SCLK1 (P46) pin only when reset is released in the serial I/O mode 2.
Fig. 2.13.8 Connection example in standard serial I/O mode (2)
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APPLICATION
2.13 Flash memory mode
3804 Group (Spec.H)
➂ When control signals are affected to user system circuit-2
Figure 2.13.9 shows an example that the analog switch (74HC4066) cut-off the control signals not
to supply to the user system circuit in the standard serial I/O mode.
Target board
74HC4066
To user system circuit
M38049FFHSP/FP/HP/KP
✽
TXD(P45)
SCLK1(P46)
RXD(P44)
BUSY(P47)
VCC
AVSS
VSS
CNVss
RESET
XIN XOUT
User reset signal (Low active)
✽: It is necessary to apply Vcc to SCLK1 (P46) pin only when reset is released in the serial I/O mode 1.
It is necessary to apply Vss to SCLK1 (P46) pin only when reset is released in the serial I/O mode 2.
Fig. 2.13.9 Connection example in standard serial I/O mode (3)
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APPLICATION
2.13 Flash memory mode
3804 Group (Spec.H)
(2) Control pin termination example in CPU rewrite mode
In this example, data is received by using serial I/O, and the data is programmed to the built-in flash
memory in the CPU rewrite mode.
Figure 2.13.10 shows an example of the reprogramming system for the built-in flash memory in the
CPU rewrite mode. For the CPU rewrite mode beginning/release method, refer to “2.13.6 CPU rewrite
mode.”
M38049FFHSP/FP/HP/KP
Clock input
BUSY output
Data input
Data output
VCC
SCLK1
SRDY1(BUSY)
AVSS
VSS
RXD
TXD
RESET
CNVSS
User reset signal
XIN XOUT
Fig. 2.13.10 Example of rewrite system for built-in flash memory in CPU rewrite mode (single-chip mode)
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APPLICATION
3804 Group (Spec.H)
2.13 Flash memory mode
2.13.8 Notes on CPU rewrite mode
(1) Operation speed
During CPU rewrite mode, set the system clock φ 4.0 MHz or less using the main clock division ratio
selection bits (bits 6 and 7 of address 003B 16).
(2) Instructions inhibited against use
The instructions which refer to the internal data of the flash memory cannot be used during the CPU
rewrite mode.
(3) Interrupts inhibited against use
The interrupts cannot be used during the CPU rewrite mode because they refer to the internal data
of the flash memory.
(4) Watchdog timer
In case of the watchdog timer has been running already, the internal reset generated by watchdog
timer underflow does not happen, because of watchdog timer is always clearing during program or
erase operation.
(5) Reset
Reset is always valid. In case of CNV SS = “H” when reset is released, boot mode is active. So the
program starts from the address contained in address FFFC 16 and FFFD 16 in boot ROM area.
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CHAPTER 3
APPENDIX
3.1
Electrical characteristics
3.2
3.3
Standard characteristics
Notes on use
3.4
Countermeasures against noise
3.5
List of registers
3.6
Package outline
3.7
Machine instructions
3.8
3.9
List of instruction code
SFR memory map
3.10
Pin configurations
APPENDIX
3804 Group (Spec.H)
3.1 Electrical characteristics
3.1 ELECTRICAL CHARACTERISTICS
3.1.1 Absolute maximum ratings
Table 3.1.1 Absolute maximum ratings
Symbol
Parameter
VCC
Power source voltages
Input voltage P00–P07, P10–P17, P20–P27,
VI
P30, P31, P34–P37, P40–P47,
P50–P57, P60–P67, VREF
VI
Input voltage P32, P33
____________
VI
Input voltage RESET, XIN
VI
Input voltage CNVSS
VO
Output voltage P00–P07, P10–P17, P20–P27,
P30, P31, P34–P37, P40–P47,
P50–P57, P60–P67, XOUT
VO
Output voltage P32, P33
Pd
Power dissipation
Topr
Operating temperature
Storage temperature
Tstg
Conditions
All voltages are based on Vss.
Output transistors are cut off.
Ta = 25°C
Ratings
–0.3 to 6.5
–0.3 to VCC +0.3
Unit
V
V
–0.3 to 5.8
–0.3 to VCC +0.3
–0.3 to VCC +0.3
–0.3 to VCC +0.3
V
V
V
V
–0.3 to 5.8
1000 (Note)
–20 to 85
–65 to 125
V
mW
°C
°C
Note: This value is 300 mW except SP package.
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APPENDIX
3804 Group (Spec.H)
3.1 Electrical characteristics
3.1.2 Recommended operating conditions
Table 3.1.2 Recommended operating conditions (1)
(VCC = 2.7 to 5.5 V, VSS = 0V, Ta = –20 to 85 °C, unless otherwise noted)
Symbol
Parameter
VCC
Power source voltage
(Note 1)
VSS
Power source voltage
“H” input voltage
P00–P07, P10–P17, P20–P27,
P30, P31, P34–P37, P40–P47,
P50–P57, P60–P67
“H” input voltage
P32, P33
“H” input voltage
(when I2C-BUS input level is selected)
SDA, SCL
“H” input voltage
(when SMBUS input level is selected)
SDA, SCL
“H” input voltage
____________
RESET, XIN, CNVSS
“H” input voltage
XCIN
“L” input voltage
P00–P07, P10–P17, P20–P27,
P30–P37,P40–P47,
P50–P57, P60–P67
“L” input voltage
(when I2C-BUS input level is selected)
SDA, SCL
“L” input voltage
(when SMBUS input level is selected)
SDA, SCL
VIH
VIH
VIH
VIH
VIH
VIH
VIL
VIL
VIL
VIL
VIL
VIL
“L” input voltage
RESET, CNVSS
____________
“L” input voltage
XIN
“L” input voltage
XCIN
Conditions
When start oscillating (Note 2)
High-speed mode
f(XIN) ≤ 8.4 MHz
f(φ) = f(XIN)/2
f(XIN) ≤ 12.5 MHz
f(XIN) ≤ 16.8 MHz
f(XIN) ≤ 12.5 MHz
Middle-speed mode
f(XIN) ≤ 16.8 MHz
f(φ) = f(XIN)/8
Min.
2.7
2.7
4.0
4.5
2.7
4.5
Limits
Typ.
5.0
5.0
5.0
5.0
5.0
5.0
0
Max.
5.5
5.5
5.5
5.5
5.5
5.5
Unit
0.8VCC
VCC
V
V
V
V
V
V
V
V
0.8VCC
5.5
V
0.7VCC
5.5
V
1.4
5.5
V
0.8VCC
VCC
V
2
VCC
V
0
0.2VCC
V
0
0.3Vcc
V
0
0.6
V
0
0.2VCC
V
0.16VCC
V
0.4
V
Notes 1: When using A/D converter, see A/D converter recommended operating conditions.
2: The start voltage and the start time for oscillation depend on the using oscillator, oscillation circuit constant value and operating
temperature range, etc.. Particularly a high-frequency oscillator might require some notes in the low voltage operation.
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APPENDIX
3804 Group (Spec.H)
3.1 Electrical characteristics
Table 3.1.3 Recommended operating conditions (2)
(VCC = 2.7 to 5.5 V, VSS = 0V, Ta = –20 to 85 °C, unless otherwise noted)
Symbol
f(XIN)
Parameter
Main clock input oscillation
frequency (Note 1)
Conditions
High-speed mode
f(φ) = f(XIN)/2
Limits
Min.
Typ.
2.7 ≤ VCC < 4.0 V
4.0 ≤ VCC < 4.5 V
Middle-speed mode
f(φ) = f(XIN)/8
4.5 ≤ VCC ≤ 5.5 V
2.7 ≤ VCC < 4.5 V
4.5 ≤ VCC ≤ 5.5 V
f(XCIN)
Sub-clock input oscillation
frequency (Notes 1, 2)
32.768
Max.
(9✕VCC-0.3)✕1.05
3
(24✕VCC-60)✕1.05
3
16.8
(15✕VCC+39)✕1.1
7
16.8
50
Unit
MHz
MHz
MHz
MHz
MHz
kHz
Notes 1: When the oscillation frequency has a duty cycle of 50%.
2: When using the microcomputer in low-speed mode, set the sub-clock input oscillation frequency on condition that
f(XCIN) < f(XIN)/3.
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APPENDIX
3804 Group (Spec.H)
3.1 Electrical characteristics
Table 3.1.4 Recommended operating conditions (3)
(VCC = 2.7 to 5.5 V, VSS = 0V, Ta = –20 to 85 °C, unless otherwise noted)
Symbol
Parameter
ΣIOH(peak)
ΣIOH(peak)
ΣIOL(peak)
ΣIOL(peak)
ΣIOL(peak)
ΣIOH(avg)
ΣIOH(avg)
ΣIOL(avg)
ΣIOL(avg)
ΣIOL(avg)
IOH(peak)
“H” total peak output current
“H” total peak output current
“L” total peak output current
“L” total peak output current
“L” total peak output current
“H” total average output current
“H” total average output current
“L” total average output current
“L” total average output current
“L” total average output current
“H” peak output current
IOL(peak)
“L” peak output current
IOL(peak)
IOH(avg)
“L” peak output current
“H” average output current
IOL(avg)
“L” average output current
IOL(avg)
“L” average output current
P00–P07, P10–P17, P20–P27, P30, P31, P34–P37 (Note 1)
P40–P47, P50–P57, P60–P67 (Note 1)
P00–P07, P10–P17, P30–P37 (Note 1)
P20–P27 (Note 1)
P40–P47,P50–P57, P60–P67 (Note 1)
P00–P07, P10–P17, P20–P27, P30, P31, P34–P37 (Note 1)
P40–P47,P50–P57, P60–P67 (Note 1)
P00–P07, P10–P17, P30–P37 (Note 1)
P20–P27 (Note 1)
P40–P47,P50–P57, P60–P67 (Note 1)
P00–P07, P10–P17, P20–P27, P30, P31, P34–P37,
P40–P47, P50–P57, P60–P67 (Note 2)
P00–P07, P10–P17, P30–P37, P40–P47, P50–P57,
P60–P67 (Note 2)
P20–P27 (Note 2)
P00–P07, P10–P17, P20–P27, P30, P31, P34–P37,
P40–P47, P50–P57, P60–P67 (Note 3)
P00–P07, P10–P17, P30–P37, P40–P47, P50–P57,
P60–P67 (Note 3)
P20–P27 (Note 3)
Min.
Limits
Typ.
Max.
–80
–80
80
80
80
–40
–40
40
40
40
–10
Unit
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
10
mA
20
–5
mA
mA
5
mA
10
mA
Notes 1: The total output current is the sum of all the currents flowing through all the applicable ports. The total average current is an average value measured over 100 ms. The total peak current is the peak value of all the currents.
2: The peak output current is the peak current flowing in each port.
3: The average output current IOL(avg), IOH(avg) are average value measured over 100 ms.
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APPENDIX
3804 Group (Spec.H)
3.1 Electrical characteristics
3.1.3 Electrical characteristics
Table 3.1.5 Electrical characteristics (1)
(VCC = 2.7 to 5.5 V, VSS = 0V, Ta = –20 to 85 °C, unless otherwise noted)
Symbol
VOH
VOL
VOL
VT+–VT–
VT+–VT–
VT+–VT–
IIH
IIH
IIH
IIL
IIL
IIL
IIL
VRAM
Parameter
“H” output voltage
P00–P07, P10–P17, P20–P27,
P30, P31, P34–P37, P40–P47,
P50–P57, P60–P67 (Note 1)
“L” output voltage
P00–P07, P10–P17, P20–P27,
P30–P37, P40–P47, P50–P57,
P60–P67
“L” output voltage
P20–P27
Hysteresis
CNTR0, CNTR1, CNTR2,
INT0–INT4
Hysteresis
RxD1, SCLK1, SIN2, SCLK2, RxD3,
SCLK3
____________
Hysteresis RESET
“H” input current
P00–P07, P10–P17, P20–P27,
P30–P37, P40–P47, P50–P57,
P60–P67
____________
“H” input current RESET, CNVSS
“H” input current XIN
“L” input current
P00–P07, P10–P17, P20–P27,
P30–P37, P40–P47, P50–P57,
P60–P67
____________
“L” input current RESET,CNVSS
“L” input current XIN
“L” input current (at Pull-up)
P00–P07, P10–P17, P20–P27,
P30, P31, P34–P37, P40–P47,
P50–P57, P60–P67
RAM hold voltage
Test conditions
IOH = –10 mA
VCC = 4.0 to 5.5 V
IOH = –1.0 mA
VCC = 1.8 to 5.5 V
IOL = 10 mA
VCC = 4.0 to 5.5 V
IOL = 1.6 mA
VCC = 1.8 to 5.5 V
IOL = 20 mA
VCC = 4.0 to 5.5 V
IOL = 1.6 mA
VCC = 1.8 to 5.5 V
Limits
Min.
Typ.
Max.
VCC–2.0
V
VCC–1.0
V
2.0
V
1.0
V
2.0
V
0.4
V
0.4
V
0.5
V
0.5
VI = VCC
(Pin floating. Pull-up
transistors “off”)
5.0
VI = VCC
VI = VCC
VI = VSS
(Pin floating. Pull-up
transistors “off”)
VI = VSS
VI = VSS
VI = VSS
VCC = 5.0 V
VI = VSS
VCC = 3.0 V
When clock stopped
Unit
5.0
4.0
–5.0
V
µA
µA
µA
µA
–80
–4.0
–210
–420
µA
µA
µA
–30
–70
–140
µA
VCC
V
–5.0
1.8
Note 1: P35 is measured when the P35/TxD3 P-channel output disable bit of the UART3 control register (bit 4 of address 003316) is “0”.
P45 is measured when the P45/TxD1 P-channel output disable bit of the UART1 control register (bit 4 of address 001B16) is “0”.
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APPENDIX
3804 Group (Spec.H)
3.1 Electrical characteristics
Table 3.1.6 Electrical characteristics (2)
(VCC = 2.7 to 5.5 V, Ta = –20 to 85 °C, f(XCIN)=32.768kHZ (Stoped in middle-speed mode), Output transistors “off”,
AD converter not operated)
Limits
Symbol
ICC
Parameter
Power source
current
Test conditions
High-speed
mode
VCC = 5V
VCC = 3V
Middle-speed
mode
VCC = 5V
VCC = 3V
Low-speed
mode
VCC = 5V
VCC = 3V
In STP state
(All oscillation stopped)
Increment when A/D conversion
is executed
Rev.1.00 Jan 14, 2005
REJ09B0212-0100Z
f(XIN) = 16.8 MHz
f(XIN) = 12.5 MHz
f(XIN) = 8.4 MHz
f(XIN) = 4.2 MHz
f(XIN) = 16.8 MHz (in WIT state)
f(XIN) = 8.4 MHz
f(XIN) = 4.2 MHz
f(XIN) = 2.1 MHz
f(XIN) = 16.8 MHz
f(XIN) = 12.5 MHz
f(XIN) = 8.4 MHz
f(XIN) = 16.8 MHz (in WIT state)
f(XIN) = 12.5 MHz
f(XIN) = 8.4 MHz
f(XIN) = 6.3 MHz
f(XIN) = stopped
In WIT state
f(XIN) = stopped
In WIT state
Ta = 25 °C
Ta = 85 °C
f(XIN) = 16.8 MHz, VCC = 5V
In Middle-, high-speed mode
Min.
Unit
Typ.
Max.
5.5
4.5
8,3
6.8
mA
mA
3.5
2.2
2.2
2.7
1.8
1.1
3.0
2.4
2.0
2.1
1.7
1.5
1.3
410
4.5
400
3.7
0.55
0.75
1000
5.3
3.3
3.3
4.1
2.7
1.7
4.5
3.6
3.0
3.2
2.6
2.3
2.0
630
6.8
600
5.6
3.0
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
µA
µA
µA
µA
µA
µA
µA
3-7
APPENDIX
3804 Group (Spec.H)
3.1 Electrical characteristics
3.1.4 A/D converter characteristics
Table 3.1.7 A/D converter recommended operating conditions
(VCC = 2.7 to 5.5 V, VSS = AVSS = 0 V,Ta = –20 to 85 °C, unless otherwise noted)
Symbol
Power source voltage
(When A/D converter is used)
Analog reference voltage
Analog power source voltage
Analog input voltage
Main clock oscillation frequency
(When A/D converter is used)
VCC
VREF
AVSS
VIA
f(XIN)
Limits
Conditions
Parameter
Min.
8-bit A/D mode (Note 1)
10-bit A/D mode (Note 2)
Typ.
5.0
5.0
2.7
2.7
2.0
Max.
Unit
5.5
5.5
VCC
V
0
2.7 ≤ VCC < 4.0 V
0
0.5
4.0 ≤ VCC < 4.5 V
0.5
4.5 ≤ VCC ≤ 5.5 V
0.5
VCC
(9✕VCC-0.3)✕1.05
3
(24✕VCC-60)✕1.05
3
16.8
V
V
V
MHZ
Note 1: 8-bit A/D mode: When the conversion mode selection bit (bit 7 of address 003816) is “1”.
2: 10-bit A/D mode: When the conversion mode selection bit (bit 7 of address 003816) is “0”.
Table 3.1.8 A/D converter characteristics
(VCC = 2.7 to 5.5 V, VSS = AVSS = 0 V, Ta = –20 to 85 °C, unless otherwise noted)
Symbol
Parameter
–
Resolution
–
Absolute accuracy
(excluding quantization error)
Conversion time
tCONV
Test conditions
8-bit A/D mode (Note 1)
10-bit A/D mode (Note 2)
8-bit A/D mode (Note 1)
10-bit A/D mode (Note 2)
8-bit A/D mode (Note 1)
10-bit A/D mode (Note 2)
Min.
Limits
Typ.
2.7 ≤ VREF ≤ 5.5 V
2.7 ≤ VREF ≤ 5.5 V
RLADDER Ladder resistor
IVREF
Reference power
at A/D converter operated VREF = 5.0 V
source input current at A/D converter stopped VREF = 5.0 V
II(AD)
A/D port inout current
12
50
35
150
Max.
8
10
±2
±4
50
61
100
200
5
5
Unit
bit
LSB
2tc(XIN)
kΩ
µA
µA
µA
Note 1: 8-bit A/D mode: When the conversion mode selection bit (bit 7 of address 003816) is “1”.
2: 10-bit A/D mode: When the conversion mode selection bit (bit 7 of address 003816) is “0”.
3.1.5 D/A converter characteristics
Table 3.1.9 D/A converter characteristics
(VCC = 2.7 to 5.5 V, VREF = 2.7 V to VCC, VSS = AVSS = 0 V, Ta = –20 to 85 °C, unless otherwise noted)
Symbol
–
–
tsu
RO
IVREF
Parameter
Resolution
Absolute accuracy
Test conditions
Limits
Min.
Typ.
4.0 ≤ VREF ≤ 5.5 V
2.7 ≤ VREF < 4.0 V
Setting time
Output resistor
Reference power source input current (Note 1)
2
3.5
Max.
8
1.0
2.5
3
5
3.2
Unit
bit
%
%
µs
kΩ
mA
Note 1: Using one D/A converter, with the value in the DA conversion register of the other D/A converter being “0016”.
3.1.6 Power source circuit timing characteristics
Table 3.1.10 Power source circuit timing characteristics
(VCC = 2.7 to 5.5 V, VREF = 2.7 V to VCC, VSS = AVSS = 0 V, Ta = –20 to 85 °C, unless otherwise noted)
Symbol
td(P–R)
Parameter
Internal power source stable time at power-on
Rev.1.00 Jan 14, 2005
REJ09B0212-0100Z
Test conditions
2.7 ≤ Vcc < 5.5 V
Limits
Min.
Typ.
Max.
2
Unit
ms
3-8
APPENDIX
3804 Group (Spec.H)
3.1 Electrical characteristics
3.1.7 Timing requirements and switching characteristics
Table 3.1.11 Timing requirements (1)
(VCC = 2.7 to 5.5 V, VSS = 0V, Ta = –20 to 85 °C, unless otherwise noted)
Symbol
Limits
Parameter
tW(RESET)
tC(XIN)
Reset input “L” pulse width
Main clock XIN
input cycle time
tWH(XIN)
Main clock XIN
input “H” pulse width
tWL(XIN)
Main clock XIN
input “L” pulse width
tC(XCIN)
tWH(XCIN)
tWL(XCIN)
tC(CNTR)
Sub-clock XCIN input cycle time
Sub-clock XCIN input “H” pulse width
Sub-clock XCIN input “L” pulse width
CNTR0–CNTR2
input cycle time
tWH(CNTR)
CNTR0–CNTR2
input “H” pulse width
tWL(CNTR)
CNTR0–CNTR2
input “L” pulse width
tWH(INT)
INT00, INT01, INT1, INT2, INT3, INT40, INT41
input “H” pulse width
tWL(INT)
INT00, INT01, INT1, INT2, INT3, INT40, INT41
input “L” pulse width
Rev.1.00 Jan 14, 2005
REJ09B0212-0100Z
Min.
4.5≤VCC≤5.5 V
4.0≤VCC<4.5 V
2.7≤VCC<4.0 V
4.5≤VCC≤5.5 V
4.0≤VCC<4.5 V
2.7≤VCC<4.0 V
4.5≤VCC≤5.5 V
4.0≤VCC<4.5 V
2.7≤VCC<4.0 V
4.5≤VCC≤5.5 V
4.0≤VCC<4.5 V
2.7≤VCC<4.0 V
4.5≤VCC≤5.5 V
4.0≤VCC<4.5 V
2.7≤VCC<4.0 V
4.5≤VCC≤5.5 V
4.0≤VCC<4.5 V
2.7≤VCC<4.0 V
4.5≤VCC≤5.5 V
4.0≤VCC<4.5 V
2.7≤VCC<4.0 V
4.5≤VCC≤5.5 V
4.0≤VCC<4.5 V
2.7≤VCC<4.0 V
td(P-R) ms + 16
59.5
10000/(86VCC-219)
26✕103/(82VCC-3)
25
4000/(86VCC-219)
10000/(82VCC-3)
25
4000/(86VCC-219)
10000/(82VCC-3)
20
5
5
120
160
250
48
64
115
48
64
115
48
64
115
48
64
115
Typ. Max.
Unit
XIN cycle
ns
ns
ns
µs
µs
µs
ns
ns
ns
ns
ns
3-9
APPENDIX
3804 Group (Spec.H)
3.1 Electrical characteristics
Table 3.1.12 Timing requirements (2)
(VCC = 2.7 to 5.5 V, VSS = 0V, Ta = –20 to 85 °C, unless otherwise noted)
Symbol
Parameter
tC(SCLK1), tC(SCLK3)
Serial I/O1, serial I/O3
clock input cycle time (Note)
tWH(SCLK1), tWH(SCLK3)
Serial I/O1, serial I/O3
clock input “H” pulse width (Note)
tWL(SCLK1), tWL(SCLK3)
Serial I/O1, serial I/O3
clock input “L” pulse width (Note)
tsu(RxD1-SCLK1),
tsu(RxD3-SCLK3)
Serial I/O1, serial I/O3
clock input setup time
th(SCLK1-RxD1),
th(SCLK3-RxD3)
Serial I/O1, serial I/O3
clock input hold time
tC(SCLK2)
Serial I/O2
clock input cycle time
tWH(SCLK2)
Serial I/O2
clock input “H” pulse width
tWL(SCLK2)
Serial I/O2
clock input “L” pulse width
tsu(SIN2-SCLK2)
Serial I/O2
clock input setup time
th(SCLK2-SIN2)
Serial I/O2
clock input hold time
4.5≤VCC≤5.5 V
4.0≤VCC<4.5 V
2.7≤VCC<4.0 V
4.5≤VCC≤5.5 V
4.0≤VCC<4.5 V
2.7≤VCC<4.0 V
4.5≤VCC≤5.5 V
4.0≤VCC<4.5 V
2.7≤VCC<4.0 V
4.5≤VCC≤5.5 V
4.0≤VCC<4.5 V
2.7≤VCC<4.0 V
4.5≤VCC≤5.5 V
4.0≤VCC<4.5 V
2.7≤VCC<4.0 V
4.5≤VCC≤5.5 V
4.0≤VCC<4.5 V
2.7≤VCC<4.0 V
4.5≤VCC≤5.5 V
4.0≤VCC<4.5 V
2.7≤VCC<4.0 V
4.5≤VCC≤5.5 V
4.0≤VCC<4.5 V
2.7≤VCC<4.0 V
4.5≤VCC≤5.5 V
4.0≤VCC<4.5 V
2.7≤VCC<4.0 V
4.5≤VCC≤5.5 V
4.0≤VCC<4.5 V
2.7≤VCC<4.0 V
Min.
250
320
500
120
150
240
120
150
240
70
90
100
32
40
50
500
650
1000
200
260
400
200
260
400
100
130
200
100
130
150
Limits
Typ. Max.
Unit
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
Note : When bit 6 of address 001A16 and bit 6 of address 003216 are “1” (clock synchronous).
Divide this value by four when bit 6 of address 001A 16 and bit 6 of address 003216 are “0” (UART).
Rev.1.00 Jan 14, 2005
REJ09B0212-0100Z
3-10
APPENDIX
3804 Group (Spec.H)
3.1 Electrical characteristics
Table 3.1.13 Switching characteristics
(VCC = 2.7 to 5.5 V, VSS = 0V, Ta = –20 to 85 °C, unless otherwise noted)
Symbol
Test
conditions
Parameter
tWH(SCLK1)
tWH(SCLK3)
Serial I/O1, serial I/O3
clock output “H” pulse width
tWL(SCLK1)
tWL(SCLK3)
Serial I/O1, serial I/O3
clock output “L” pulse width
td(SCLK1-TxD1)
td(SCLK3-TxD3)
Serial I/O1, serial I/O3
output delay time (Note)
tV(SCLK1-TxD1)
tV(SCLK3-TxD3)
Serial I/O1, serial I/O3
output valid time (Note)
tr(SCLK1)
tr(SCLK3)
Serial I/O1, serial I/O3
rise time of clock output
tf(SCLK1)
tf(SCLK3)
Serial I/O1, serial I/O3
fall time of clock output
tWH(SCLK2)
Serial I/O2
clock output “H” pulse width
tWL(SCLK2)
Serial I/O2
clock output “L” pulse width
td(SCLK2-SOUT2)
Serial I/O2
output delay time
tV(SCLK2-SOUT2)
Serial I/O2
output valid time
tf(SCLK2)
Serial I/O2
fall time of clock output
tr(CMOS)
CMOS
rise time of output (Note)
tf(CMOS)
CMOS
fall time of output (Note)
4.5≤VCC≤5.5 V
4.0≤VCC<4.5 V
2.7≤VCC<4.0 V
4.5≤VCC≤5.5 V
4.0≤VCC<4.5 V
2.7≤VCC<4.0 V
4.5≤VCC≤5.5 V
4.0≤VCC<4.5 V
2.7≤VCC<4.0 V
4.5≤VCC≤5.5 V
4.0≤VCC<4.5 V
2.7≤VCC<4.0 V
4.5≤VCC≤5.5 V
4.0≤VCC<4.5 V
2.7≤VCC<4.0 V
4.5≤VCC≤5.5 V
4.0≤VCC<4.5 V
2.7≤VCC<4.0 V
4.5≤VCC≤5.5 V
4.0≤VCC<4.5 V
2.7≤VCC<4.0 V
4.5≤VCC≤5.5 V
4.0≤VCC<4.5 V
2.7≤VCC<4.0 V
4.5≤VCC≤5.5 V
4.0≤VCC<4.5 V
2.7≤VCC<4.0 V
4.5≤VCC≤5.5 V
4.0≤VCC<4.5 V
2.7≤VCC<4.0 V
4.5≤VCC≤5.5 V
4.0≤VCC<4.5 V
2.7≤VCC<4.0 V
4.5≤VCC≤5.5 V
4.0≤VCC<4.5 V
2.7≤VCC<4.0 V
4.5≤VCC≤5.5 V
4.0≤VCC<4.5 V
2.7≤VCC<4.0 V
Limits
Min.
tC(SCLK1)2-30, tC(SCLK3)/2-30
tC(SCLK1)2-35, tC(SCLK3)/2-35
tC(SCLK1)2-40, tC(SCLK3)/2-40
tC(SCLK1)2-30, tC(SCLK3)/2-30
tC(SCLK1)2-35, tC(SCLK3)/2-35
tC(SCLK1)2-40, tC(SCLK3)/2-40
Typ. Max.
ns
ns
140
200
350
ns
ns
-30
-30
-30
Fig. 3.1.1
Unit
30
35
40
30
35
40
ns
ns
ns
tC(SCLK2)/2-160
tC(SCLK2)/2-200
tC(SCLK2)/2-240
tC(SCLK2)/2-160
tC(SCLK2)/2-200
tC(SCLK2)/2-240
ns
200
250
300
ns
0
0
0
10
12
15
10
12
15
ns
30
35
40
30
35
40
30
35
40
ns
ns
ns
Note: When the P45/TxD1 P-channel output disable bit of the UART1 control register (bit 4 of address 001B16) is “0”.
Rev.1.00 Jan 14, 2005
REJ09B0212-0100Z
3-11
APPENDIX
3804 Group (Spec.H)
3.1 Electrical characteristics
Measurement output pin
1kΩ
100pF
Measurement output pin
100pF
CMOS output
N-channel open-drain output
Fig. 3.1.1 Circuit for measuring output switching characteristics (1)
Rev.1.00 Jan 14, 2005
REJ09B0212-0100Z
Fig. 3.1.2 Circuit for measuring output switching characteristics (2)
3-12
APPENDIX
3804 Group (Spec.H)
3.1 Electrical characteristics
Single-chip mode timing diagram
tC(CNTR)
tWL(CNTR)
tWH(CNTR)
0.8VCC
CNTR0, CNTR1, CNTR2
0.2VCC
tWL(INT)
tWH(INT)
INT1,INT2,INT3
INT00,INT40
INT01,INT41
0.8VCC
0.2VCC
tW(RESET)
RESET
0.8VCC
0.2VCC
tC(XIN)
tWL(XIN)
tWH(XIN)
0.8VCC
XIN
0.2VCC
tC(XCIN)
tWL(XCIN)
tWH(XCIN)
0.8VCC
XCIN
0.2VCC
tC(SCLK1), tC(SCLK2),tC(SCLK3),
SCLK1
SCLK2
SCLK3
tf
tWL(SC LK1), tW L(SC LK2), tWL(SC LK3)
TXD1
TXD3
SOUT2
tWH (SC LK1), tWH (SC LK2), tWH (SC LK3)
0.8VCC
0.2VCC
tsu(RxD1-SCLK1),
tsu(SIN2-SCLK2),
tsu(RxD3-SCLK3)
RXD1
RXD3
SIN2
tr
th(SCLK1-RxD1),
th(SCLK2-SIN2),
th(SCLK3-RxD3)
0.8VCC
0.2VCC
td(SC LK1-TxD1), td(SC LK2-SOUT2), td(SC LK3-TxD3)
tv(SC LK1-TxD1),
tv(SC LK2-SOUT2),
tv(SC LK3-TxD3)
Fig. 3.1.3 Timing diagram (in single-chip mode)
Rev.1.00 Jan 14, 2005
REJ09B0212-0100Z
3-13
APPENDIX
3804 Group (Spec.H)
3.1 Electrical characteristics
3.1.8 Multi-master I2C-BUS bus line characteristics
Table 3.1.14 Multi-master I 2C-BUS bus line characteristics
Standard clock mode High-speed clock mode
Symbol
Parameter
Min.
Max.
tBUF
Bus free time
4.7
Min.
1.3
tHD;STA
Hold time for START condition
4.0
0.6
tLOW
Hold time for SCL clock = “0”
4.7
tR
Rising time of both SCL and SDA signals
tHD;DAT
Data hold time
tHIGH
Hold time for SCL clock = “1”
tF
Falling time of both SCL and SDA signals
tSU;DAT
Data setup time
tSU;STA
Setup time for repeated START condition
tSU;STO
Unit
µs
µs
µs
1.3
20+0.1C b
300
ns
0
0
0.9
µs
4.0
0.6
1000
300
Setup time for STOP condition
Max.
µs
20+0.1C b
300
ns
250
100
ns
4.7
0.6
µs
4.0
0.6
µs
Note: Cb = total capacitance of 1 bus line
S DA
tHD:STA
tBUF
tLOW
SCL
P
tR
tF
S
tHD:STA
Sr
tHD:DAT
tsu:STO
tHIGH
tsu:DAT
P
tsu:STA
S : START condition
Sr: RESTART condition
P : STOP condition
Fig. 3.1.4 Timing diagram of multi-master I2C-BUS
Rev.1.00 Jan 14, 2005
REJ09B0212-0100Z
3-14
APPENDIX
3804 Group (Spec.H)
3.2 Standard characteristics
3.2 Standard characteristics
Standard characteristics described below are just examples of the 3804 Group (spec. H)’s characteristics
and are not guaranteed. For rated values, refer to “3.1 Electrical characteristics”.
3.2.1 Power source current standard characteristics
High-speed mode (TYP, 25 °C)
[φ = X IN/2, X CIN = 32.768 kHz]
8.0
Icc (mA)
6.0
4.0
2.0
0.0
2.5
3.0
3.5
16.8 MHz
4.0
4.5
Vcc (V)
12.5 MHz
5.0
8.4 MHz
5.5
4.2 MHz
6.0
2.1 MHz
Fig. 3.2.1 Power source current standard characteristics (in high-speed mode)
Middle-speed mode (TYP, 25 °C)
[φ = X IN /8, XCIN = stopped]
4.0
Icc (mA)
3.0
2.0
1.0
0.0
2.5
3.0
16.8 MHz
3.5
4.0
4.5
Vcc (V)
12.5 MHz
8.4 MHz
5.0
5.5
6.0
6.3 MHz
Fig. 3.2.2 Power source current standard characteristics (in middle-speed mode)
Rev.1.00 Jan 14, 2005
REJ09B0212-0100Z
3-15
APPENDIX
3804 Group (Spec.H)
3.2 Standard characteristics
Low-speed mode (TYP, 25 °C)
[φ = X CIN/2, XIN = stopped]
800.0
Icc (µ
µ A)
600.0
400.0
200.0
0.0
2.5
3.0
3.5
4.0
4.5
Vcc (V)
5.0
5.5
6.0
32.768 kHz
Fig. 3.2.3 Power source current standard characteristics (in low-speed mode)
High-speed mode, WAIT state (TYP, 25 °C)
[φ = X IN/2, X CIN = 32.768 kHz]
8.0
Icc (mA)
6.0
4.0
2.0
0.0
2.5
3.0
3.5
4.0
4.5
Vcc (V)
5.0
5.5
6.0
16.8 MHz
Fig. 3.2.4 Power source current standard characteristics (in high-speed mode, f(XIN) = 16.8 MHz, WAIT state)
Rev.1.00 Jan 14, 2005
REJ09B0212-0100Z
3-16
APPENDIX
3804 Group (Spec.H)
3.2 Standard characteristics
Middle-speed mode, WAIT state (TYP, 25 °C)
[φ = X IN/8, XCIN = stopped]
4.0
Icc (mA)
3.0
2.0
1.0
0.0
2.5
3.0
3.5
4.0
4.5
Vcc (V)
5.0
5.5
6.0
16.8 MHz
Fig. 3.2.5 Power source current standard characteristics (in middle-speed mode, f(XIN) = 16.8 MHz, WAIT state)
Low-speed mode, WAIT state (TYP, 25 °C)
[φ = X CIN/2, X IN = stopped, X CIN = 32.768 kHz]
8.0
Icc (µ
µ A)
6.0
4.0
2.0
0.0
2.5
3.0
3.5
4.0
4.5
Vcc (V)
5.0
5.5
6.0
32.768 kHz
Fig. 3.2.6 Power source current standard characteristics (in low-speed mode, WAIT state)
Rev.1.00 Jan 14, 2005
REJ09B0212-0100Z
3-17
APPENDIX
3804 Group (Spec.H)
3.2 Standard characteristics
High-speed mode, A/D converter operating (TYP, 25 °C)
[φ = X IN/2, X CIN = 32.768 kHz]
8.0
Icc (mA)
(
)
6.0
4.0
2.0
0.0
2.5
3.0
3.5
4.0
4.5
VCC(V)
5.0
5.5
6.0
16.8 MHz
Fig. 3.2.7 Power source current standard characteristics (in high-speed mode, f(XIN) = 16.8 MHz, A/D converter operating)
Oscillation stop mode (TYP, 25 °C)
[STP instruction executing, X IN = stopped, XCIN = stopped]
1.0
0.8
Icc (µ
µ A)
0.6
0.4
0.2
0.0
2.5
3.0
3.5
4.0
4.5
Vcc (V)
5.0
5.5
6.0
Stopped
Fig. 3.2.8 Power source current standard characteristics (at oscillation stopping)
Rev.1.00 Jan 14, 2005
REJ09B0212-0100Z
3-18
APPENDIX
3804 Group (Spec.H)
3.2 Standard characteristics
3.2.2 Port standard characteristics
Port P60 IOH–VOH characteristics (P-channel drive) [Ta = 25 °C]
(Same characteristics pins: P0, P1, P2, P30, P31, P34–P37, P4, P5, P6)
–50
–45
–40
–35
Vcc = 5.0 V
IOH –30
[mA] –25
Vcc = 4.0V
–20
–15
Vcc = 2.7V
–10
–5
0
0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
4.5
5.0
5.5
VOH [V]
Fig. 3.2.9 CMOS output port P-channel side characteristics (Ta = 25 °C)
Port P60 IOL–VOL characteristics (N-channel drive) [Ta = 25 °C]
(Same characteristics pins: P0, P1, P3, P4, P5, P6)
50
Vcc = 5.0 V
45
40
35
IOL
[mA]
30
Vcc = 4.0 V
25
20
15
Vcc = 2.7 V
10
5
0
0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
4.5
5.0
5.5
VOL[V]
Fig. 3.2.10 CMOS output port N-channel side characteristics (Ta = 25 °C)
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APPENDIX
3804 Group (Spec.H)
3.2 Standard characteristics
Port P32 IOL–VOL characteristics (N-channel drive) [Ta = 25 °C]
(Same characteristics pins: P32, P33)
50
45
40
Vcc = 5.0 V
35
IOL
[mA]
30
Vcc = 4.0 V
25
20
15
Vcc = 2.7 V
10
5
0
0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
4.5
5.0
5.5
VOL[V]
Fig. 3.2.11 N-channel open-drain output port N-channel side characteristics (Ta = 25 °C)
Port P20 IOL–VOL characteristics (N-channel drive) [Ta = 25 °C]
(Same characteristics pins: P2)
100
90
Vcc = 5.0 V
80
70
IOL
[mA]
60
Vcc = 4.0 V
50
40
Vcc = 2.7 V
30
20
10
0
0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
4.5
5.0
5.5
VOL[V]
Fig. 3.2.12 CMOS large current output port N-channel side characteristics (Ta = 25 °C)
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APPENDIX
3804 Group (Spec.H)
3.2 Standard characteristics
Port P60 IIL–VIL characteristics (at pull-up) [Ta = 25 °C]
(Same characteristics pins: P0, P1, P2, P30, P31, P34–P37, P4, P5, P6)
–400
–360
–320
Vcc = 6.0 V
–280
IIL –240
[mA] –200
Vcc = 5.0 V
–160
–120
Vcc = 3.0 V
–80
–40
0
0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
4.5
5.0
5.5
6.0
VIL[V]
Fig. 3.2.13 CMOS input port at pull-up characteristics (Ta = 25 °C)
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APPENDIX
3804 Group (Spec.H)
3.2 Standard characteristics
3.2.3 A/D conversion standard characteristics
Figure3.2.14, Figure 3.2.15, and Figure 3.2.16 show the A/D conversion standard characteristics.
The thick lines of the graph indicate the absolute precision errors, These are expressed as the deviation
from the ideal value when the output code changes. For example, the change in output code from 512 to
513 should occur at 2560 mV, but the measured value is –10 mV. Accordingly, the measured point of
change is 2560 – 10 = 2550 mV.
The thin lines of the graph indicate the input voltage width for which the output code is constant. For
example, the measured input voltage width for which the output code is 512 is 5.0 mV, so that the
differential non-linear error is 5.0 – 5.0 = 0.0 mV (0 LSB).
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APPENDIX
3804 Group (Spec.H)
3.2 Standard characteristics
M38049FFHSP A/D CONV. ERROR & STEP WIDTH
V DD = 5.12 [V], VREF = 5.12 [V]
X IN = 8 [MHz], Ta = 25 [deg.]
Error
1 LSB Width
Fig. 3.2.14 A/D conversion standard characteristics (f(X IN) = 8 MHz)
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APPENDIX
3804 Group (Spec.H)
3.2 Standard characteristics
M38049FFHSP A/D CONV. ERROR & STEP WIDTH
V DD = 5.12 [V], VREF = 5.12 [V]
X IN = 12 [MHz], Ta = 25 [deg.]
Error
1 LSB Width
Fig. 3.2.15 A/D conversion standard characteristics (f(X IN) = 12 MHz)
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APPENDIX
3804 Group (Spec.H)
3.2 Standard characteristics
M38049FFHSP A/D CONV. ERROR & STEP WIDTH
V DD = 5.12 [V], VREF = 5.12 [V]
X IN = 16 [MHz], Ta = 25 [deg.]
Error
1 LSB Width
Fig. 3.2.16 A/D conversion standard characteristics (f(X IN) = 16 MHz)
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APPENDIX
3804 Group (Spec.H)
3.2 Standard characteristics
3.2.4 D/A conversion standard characteristics
Figure 3.2.17 shows the D/A conversion standard characteristics.
M38049FFHSP D/A CONV. STEP WIDTH MEASUREMENT
V CC = 5.12 [V], VREF = 5.12 [V]
X IN = 16 [MHz], Ta = 25 [deg.]
Error
1 LSB Width
Fig. 3.2.17 D/A conversion standard characteristics
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APPENDIX
3804 Group (Spec.H)
3.3 Notes on use
3.3 Notes on use
3.3.1 Notes on input and output ports
(1) Notes in standby state
In standby state ✽1 for low-power dissipation, do not make input levels of an I/O port “undefined”.
Even when an I/O port of N-channel open-drain is set as output mode, if output data is “1”, the
aforementioned notes are necessary.
Pull-up (connect the port to V CC ) or pull-down (connect the port to V SS ) these ports through a
resistor.
When determining a resistance value, note the following points:
• External circuit
• Variation of output levels during the ordinary operation
When using built-in pull-up resistor, note on varied current values:
• When setting as an input port : Fix its input level
• When setting as an output port : Prevent current from flowing out to external
● Reason
Exclusive input ports are always in a high-impedance state. An output transistor becomes an OFF
state when an I/O port is set as input mode by the direction register, so that the port enter a highimpedance state. At this time, the potential which is input to the input buffer in a microcomputer is
unstable in the state that input levels are “undefined”. This may cause power source current. Even
when an I/O port of N-channel open-drain is set as output mode by the direction register, if the
contents of the port latch is “1”, the same phenomenon as that of an input port will occur.
✽1 standby state: Stop mode by executing STP instruction
Wait mode by executing WIT instruction
(2) Modifying output data with bit managing instruction
When the port latch of an I/O port is modified with the bit managing instruction ✽2, the value of the
unspecified bit may be changed.
● Reason
The bit managing instructions are read-modify-write form instructions for reading and writing data
by a byte unit. Accordingly, when these instructions are executed on a bit of the port latch of an
I/O port, the following is executed to all bits of the port latch.
•As for bit which is set for input port:
The pin state is read in the CPU, and is written to this bit after bit managing.
•As for bit which is set for output port:
The bit value is read in the CPU, and is written to this bit after bit managing.
Note the following:
•Even when a port which is set as an output port is changed for an input port, its port latch holds
the output data.
•As for a bit of which is set for an input port, its value may be changed even when not specified
with a bit managing instruction in case where the pin state differs from its port latch contents.
✽2 Bit managing instructions: SEB and CLB instructions
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APPENDIX
3804 Group (Spec.H)
3.3 Notes on use
3.3.2 Termination of unused pins
(1) Terminate unused pins
➀ I/O ports :
• Set the I/O ports for the input mode and connect them to V CC or V SS through each resistor of
1 kΩ to 10 kΩ.
Ports that permit the selecting of a built-in pull-up resistor can also use this resistor. Set the
I/O ports for the output mode and open them at “L” or “H”.
• When opening them in the output mode, the input mode of the initial status remains until the
mode of the ports is switched over to the output mode by the program after reset. Thus, the
potential at these pins is undefined and the power source current may increase in the input
mode. With regard to an effects on the system, thoroughly perform system evaluation on the user
side.
• Since the direction register setup may be changed because of a program runaway or noise, set
direction registers by program periodically to increase the reliability of program.
➁ The AVss pin when not using the A/D converter :
• When not using the A/D converter, handle a power source pin for the A/D converter, AVss pin
as follows:
AVss: Connect to the Vss pin.
(2) Termination remarks
➀ I/O ports :
Do not open in the input mode.
● Reason
• The power source current may increase depending on the first-stage circuit.
• An effect due to noise may be easily produced as compared with proper termination ➀ and
shown on the above.
➁ I/O ports :
When setting for the input mode, do not connect to V CC or V SS directly.
● Reason
If the direction register setup changes for the output mode because of a program runaway or
noise, a short circuit may occur between a port and V CC (or V SS ).
➂ I/O ports :
When setting for the input mode, do not connect multiple ports in a lump to V CC or VSS through
a resistor.
● Reason
If the direction register setup changes for the output mode because of a program runaway or
noise, a short circuit may occur between ports.
• At the termination of unused pins, perform wiring at the shortest possible distance (20 mm or less)
from microcomputer pins.
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APPENDIX
3804 Group (Spec.H)
3.3 Notes on use
3.3.3 Notes on interrupts
(1) Change of relevant register settings
When the setting of the following registers or bits is changed, the interrupt request bit may be set
to “1”. When not requiring the interrupt occurrence synchronized with these setting, take the following
sequence.
•Interrupt edge selection register (address 003A 16)
•Timer XY mode register (address 0023 16)
•Timer Z mode register (address 002A 16)
•I 2C START/STOP condition control register (address 0016 16)
Set the above listed registers or bits as the following sequence.
Set the corresponding interrupt enable bit to “0”
(disabled) .
↓
Set the interrupt edge select bit (active edge switch
bit) or the interrupt (source) select bit to “1”.
↓
NOP (One or more instructions)
↓
Set the corresponding interrupt request bit to “0”
(no interrupt request issued).
↓
Set the corresponding interrupt enable bit to “1”
(enabled).
Fig. 3.3.1 Sequence of changing relevant register
■ Reason
When setting the followings, the interrupt request bit may be set to “1”.
•When setting external interrupt active edge
Concerned register: Interrupt edge selection register (address 003A 16)
Timer XY mode register (address 0023 16)
Timer Z mode register (address 002A 16)
I 2C START/STOP condition control register (address 0016 16)
•When switching interrupt sources of an interrupt vector address where two or more interrupt
sources are allocated.
Concerned register: Interrupt source selection register (address 0039 16)
(2) Check of interrupt request bit
● When executing the BBC or BBS instruction to an interrupt request bit of an interrupt request
register immediately after this bit is set to “0”, execute one or more instructions before executing
the BBC or BBS instruction.
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APPENDIX
3804 Group (Spec.H)
3.3 Notes on use
■ Reason
If the BBC or BBS instruction is executed immediately after an interrupt request bit of an interrupt
request register is cleared to “0”, the value of the interrupt request bit before being cleared to “0”
is read.
Clear the interrupt request bit to “0” (no interrupt issued)
↓
NOP (one or more instructions)
↓
Execute the BBC or BBS instruction
Fig. 3.3.2 Sequence of check of interrupt request bit
3.3.4 Notes on 8-bit timer (timer 1, 2, X, Y)
● If a value n (between 0 and 255) is written to a timer latch, the frequency division ratio is 1/(n+1).
● When switching the count source by the timer 12, X and Y count source selection bits, the value
of timer count is altered in unconsiderable amount owing to generating of thin pulses in the count
input signals.
Therefore, select the timer count source before set the value to the prescaler and the timer.
● Set the double-function port of the CNTR0/CNTR1 pin and port P54/P55 to output in the pulse output
mode.
● Set the double-function port of CNTR 0/CNTR 1 pin and port P5 4/P5 5 to input in the event counter
mode and the pulse width measurement mode.
3.3.5 Notes on 16-bit timer (timer Z)
(1) Pulse output mode
● Set the double-function port of the CNTR 2 pin and port P4 7 to output.
(2) Pulse period measurement mode
● Set the double-function port of the CNTR 2 pin and port P47 to input.
● A read-out of timer value is impossible in this mode. The timer can be written to only during timer
stop (no measurement of pulse period).
● Since the timer latch in this mode is specialized for the read-out of measured values, do not
perform any write operation during measurement.
● “FFFF 16” is set to the timer when the timer underflows or when the valid edge of measurement
start/completion is detected. Consequently, the timer value at start of pulse period measurement
depends on the timer value just before measurement start.
(3) Pulse width measurement mode
● Set the double-function port of the CNTR 2 pin and port P47 to input.
● A read-out of timer value is impossible in this mode. The timer can be written to only during timer
stop (no measurement of pulse period).
● Since the timer latch in this mode is specialized for the read-out of measured values, do not
perform any write operation during measurement.
● “FFFF 16” is set to the timer when the timer underflows or when the valid edge of measurement
start/completion is detected. Consequently, the timer value at start of pulse width measurement
depends on the timer value just before measurement start.
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APPENDIX
3804 Group (Spec.H)
3.3 Notes on use
(4) Programmable waveform generating mode
● Set the double-function port of the CNTR 2 pin and port P4 7 to output.
(5) Programmable one-shot generating mode
● Set the double-function port of CNTR2 pin and port P47 to output, and of INT1 pin and port P42 to
input in this mode.
● This mode cannot be used in low-speed mode.
● If the value of the CNTR 2 active edge switch bit is changed during one-shot generating enabled
or generating one-shot pulse, then the output level from CNTR 2 pin changes.
(6) All modes
●Timer Z write control
Which write control can be selected by the timer Z write control bit (bit 3) of the timer Z mode
register (address 002A 16), writing data to both the latch and the timer at the same time or writing
data only to the latch.
When the operation “writing data only to the latch” is selected, the value is set to the timer latch
by writing data to the address of timer Z and the timer is updated at next underflow. After reset
release, the operation “writing data to both the latch and the timer at the same time” is selected,
and the value is set to both the latch and the timer at the same time by writing data to the address
of timer Z.
In the case of writing data only to the latch, if writing data to the latch and an underflow are
performed almost at the same time, the timer value may become undefined.
●Timer Z read control
A read-out of timer value is impossible in pulse period measurement mode and pulse width measurement
mode. In the other modes, a read-out of timer value is possible regardless of count operating or
stopped.
However, a read-out of timer latch value is impossible.
●Switch of interrupt active edge of CNTR2 and INT 1
Each interrupt active edge depends on setting of the CNTR 2 active edge switch bit and the INT1
active edge selection bit.
●Switch of count source
When switching the count source by the timer Z count source selection bits, the value of timer
count is altered in inconsiderable amount owing to generating of thin pulses on the count input
signals.
Therefore, select the timer count source before setting the value to the prescaler and the timer.
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APPENDIX
3804 Group (Spec.H)
3.3 Notes on use
3.3.6 Notes on serial interface
(1) Notes when selecting clock synchronous serial I/O
➀ Stop of transmission operation
As for serial I/Oi (i = 1, 3) that can be used as either a clock synchronous or an asynchronous
(UART) serial I/O, clear the serial I/Oi enable bit and the transmit enable bit to “0” (serial I/Oi and
transmit disabled).
● Reason
Since transmission is not stopped and the transmission circuit is not initialized even if only the
serial I/Oi enable bit is cleared to “0” (serial I/Oi disabled), the internal transmission is running (in
this case, since pins TxDi, RxDi, SCLKi, and S RDYi function as I/O ports, the transmission data is
not output). When data is written to the transmit buffer register in this state, data starts to be
shifted to the transmit shift register. When the serial I/Oi enable bit is set to “1” at this time, the
data during internally shifting is output to the TxDi pin and an operation failure occurs.
➁ Stop of receive operation
As for serial I/Oi (i = 1, 3) that can be used as either a clock synchronous or an asynchronous
(UART) serial I/O, clear the receive enable bit to “0” (receive disabled), or clear the serial I/Oi
enable bit to “0” (serial I/Oi disabled).
➂ Stop of transmit/receive operation
As for serial I/Oi (i = 1, 3) that can be used as either a clock synchronous or an asynchronous
(UART) serial I/O, clear both the transmit enable bit and receive enable bit to “0” (transmit and
receive disabled).
(when data is transmitted and received in the clock synchronous serial I/O mode, any one of data
transmission and reception cannot be stopped.)
● Reason
In the clock synchronous serial I/O mode, the same clock is used for transmission and reception.
If any one of transmission and reception is disabled, a bit error occurs because transmission and
reception cannot be synchronized.
In this mode, the clock circuit of the transmission circuit also operates for data reception. Accordingly,
the transmission circuit does not stop by clearing only the transmit enable bit to “0” (transmit
disabled). Also, the transmission circuit is not initialized by clearing the serial I/Oi enable bit to “0”
(serial I/Oi disabled) (refer to ➀ in (1) ).
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APPENDIX
3804 Group (Spec.H)
3.3 Notes on use
(2) Notes when selecting clock asynchronous serial I/O
➀ Stop of transmission operation
Clear the transmit enable bit to “0” (transmit disabled). The transmission operation does not stop
by clearing the serial I/Oi enable bit (i = 1, 3) to “0”.
● Reason
This is the same as ➀ in (1).
➁ Stop of receive operation
Clear the receive enable bit to “0” (receive disabled).
➂ Stop of transmit/receive operation
Only transmission operation is stopped.
Clear the transmit enable bit to “0” (transmit disabled). The transmission operation does not stop
by clearing the serial I/Oi enable bit (i = 1, 3) to “0”.
● Reason
This is the same as ➀ in (1).
Only receive operation is stopped.
Clear the receive enable bit to “0” (receive disabled).
(3) S RDYi (i = 1, 3) output of reception side
When signals are output from the S RDYi pin on the reception side by using an external clock in the
clock synchronous serial I/O mode, set all of the receive enable bit, the SRDYi output enable bit, and
the transmit enable bit to “1” (transmit enabled).
(4) Setting serial I/Oi (i = 1, 3) control register again
Set the serial I/Oi control register again after the transmission and the reception circuits are reset
by clearing both the transmit enable bit and the receive enable bit to “0.”
Clear both the transmit enable
bit (TE) and the receive enable
bit (RE) to “0”
↓
Set the bits 0 to 3 and bit 6 of the
serial I/Oi control register
↓
Set both the transmit enable bit
(TE) and the receive enable bit
(RE), or one of them to “1”
Can be set with the
LDM instruction at
the same time
Fig. 3.3.3 Sequence of setting serial I/Oi (i = 1, 3) control register again
(5) Data transmission control with referring to transmit shift register completion flag
After the transmit data is written to the transmit buffer register, the transmit shift register completion flag
changes from “1” to “0” with a delay of 0.5 to 1.5 shift clocks. When data transmission is controlled with
referring to the flag after writing the data to the transmit buffer register, note the delay.
(6) Transmission control when external clock is selected
When an external clock is used as the synchronous clock for data transmission, set the transmit
enable bit to “1” at “H” of the S CLKi (i = 1, 3) input level. Also, write the transmit data to the transmit
buffer register at “H” of the S CLKi input level.
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APPENDIX
3804 Group (Spec.H)
3.3 Notes on use
(7) Transmit interrupt request when transmit enable bit is set
When using the transmit interrupt, take the following sequence.
➀ Set the serial I/Oi transmit interrupt enable bit (i = 1, 3) to “0” (disabled).
➁ Set the tranasmit enable bit to “1”.
➂ Set the serial I/Oi transmit interrupt request bit (i = 1, 3) to “0” after 1 or more instruction has
executed.
➃ Set the serial I/Oi transmit interrupt enable bit (i = 1, 3) to “1” (enabled).
● Reason
When the transmission enable bit is set to “1”, the transmit buffer empty flag and transmit shift
register shift completion flag are also set to “1”.
Therefore, regardless of selecting which timing for the generating of transmit interrupts, the interrupt
request is generated and the transmit interrupt request bit is set at this point.
(8) Writing to baud rate generator i (BRGi) (i = 1, 3)
Write data to the baud rate generator i (BRGi) (i = 1, 3) while the transmission/reception operation
is stopped.
3.3.7 Notes on multi-master I 2C-BUS interface
(1) Read-modify-write instruction
Each register of the multi-master I2C-BUS interface has bits to change by hardware. The precautions
when the read-modify-write instruction such as SEB, CLB etc. is executed for each register of the
multi-master I2C-BUS interface are described below.
➀ I 2C data shift register (S0: address 0011 16)
When executing the read-modify-write instruction for this register during transfer, data may become
a value not intended.
➁ I2C slave address registers 0 to 2 (S0D0 to S0D2: addresses 0FF716 to 0FF916)
When the read-modify-write instruction is executed for this register at detecting the STOP condition,
data may become a value not intended.
● Reason
________
It is because hardware changes the read/write bit (RWB) at detecting the STOP condition.
➂ I 2C status register (S1: address 001316)
Do not execute the read-modify-write instruction for this register because all bits of this register
are changed by hardware.
➃ I 2C control register (S1D: address 0014 16)
When the read-modify-write instruction is executed for this register at detecting the START condition
or at completing the byte transfer, data may become a value not intended.
● Reason
Because hardware changes the bit counter (BC0 to BC2).
➄ I 2C clock control register (S2: address 001516)
The read-modify-write instruction can be executed for this register.
➅ I 2C START/STOP condition control register (S2D: address 0016 16)
The read-modify-write instruction can be executed for this register.
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APPENDIX
3804 Group (Spec.H)
3.3 Notes on use
(2) START condition generating procedure using multi-master
➀ Procedure example (The necessary conditions of the generating procedure are described as the
following ➁ to ➄).
LDA #SLADR
(Taking out of slave address value)
SEI
(Interrupt disabled)
BBS 5, S1, BUSBUSY (BB flag confirming and branch process)
BUSFREE:
STA S0
(Writing of slave address value)
LDM #$F0, S1
(Trigger of START condition generating)
CLI
(Interrupt enabled)
:
:
BUSBUSY:
CLI
(Interrupt enabled)
:
:
➁ Use “Branch on Bit Set” of “BBS 5, S1, –” for the BB flag confirming and branch process.
➂ Use “STA, STX” or “STY” of the zero page addressing instruction for writing the slave address
value to the I 2C data shift register (S0: address 0011 16).
➃ Execute the branch instruction of above ➁ and the store instruction of above ➂ continuously shown
by the above procedure example.
➄ Disable interrupts during the following three process steps:
• BB flag confirming
• Writing of slave address value
• Trigger of START condition generating
(3) RESTART condition generating procedure in master
➀ Procedure example (The necessary conditions of the generating procedure are described as the
following ➁ to ➃). Execute the following procedure when the PIN bit is “0”.
LDM #$00, S1
(Select slave receive mode)
LDA #SLADR
(Taking out of slave address value)
SEI
(Interrupt disabled)
STA S0
(Writing of slave address value)
LDM #$F0, S1
(Trigger of RESTART condition generating)
CLI
(Interrupt enabled)
:
:
➁ Select the slave receive mode when the PIN bit is “0”. Do not write “1” to the PIN bit. The TRX bit
becomes “0” and the SDA pin is released.
➂ The SCL pin is released by writing the slave address value to the I 2C data shift register.
➃ Disable interrupts during the following two process steps:
• Writing of slave address value
(4) Writing to I 2C status register (S1: address 0013 16)
Do not execute an instruction to set the PIN bit to “1” from “0” and an instruction to set the MST and
TRX bits to “0” from “1” simultaneously. It is because it may enter the state that the SCL pin is
released and the SDA pin is released after about one machine cycle. Do not execute an instruction
to set the MST and TRX bits to “0” from “1” simultaneously when the PIN bit is “1”. It is because it
may become the same as above.
(5) Writing to I 2C clock control register (S2: address 0015 16)
Do not write data into the I 2C clock control register during transfer. If data is written during transfer,
the I2C clock generator is reset, so that data cannot be transferred normally.
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APPENDIX
3804 Group (Spec.H)
3.3 Notes on use
(6) Switching of SCL/SDA interrupt pin polarity selection bit, SCL/SDA interrupt pin selection bit,
I 2C-BUS interface enable bit
When changing the setting of the SCL/SDA interrupt pin polarity selection bit, the SCL/SDA interrupt
pin selection bit, or the I 2C-BUS interface enable bit ES0, the SCL/SDA interrupt request bit may be
set. When selecting the SCL/SDA interrupt source, disable the interrupt before the SCL/SDA interrupt
pin polarity selection bit, the SCL/SDA interrupt pin selection bit, or the I2C-BUS interface enable bit
ES0 is set. Reset the request bit to “0” after setting these bits, and enable the interrupt.
(7) Process of after STOP condition generating in master mode
Do not write data in the I2C data shift register (S0) and the I2C status register (S1) until the bus busy
flag BB becomes “0” after generating the STOP condition in the master mode. It is because the
STOP condition waveform might not be normally generated. Reading to the above registers does not
have the problem.
(8) ES0 bit switch
In standard clock mode when SSC = “00010 2” or in high-speed clock mode, flag BB may switch to
“1” if ES0 bit is set to “1” when SDA is “L”.
Countermeasure:
Set ES0 to “1” when SDA is “H”.
• Trigger of RESTART condition generating
3.3.8 Notes on programming for SMBUS interface
(1) Time out process
For a smart battery system, the time out process with a program is required so that the communication
can be completed even when communication is interrupted. It is because there is possibility of
extracting a battery from a PC.
The specifications are defined so that communication has been able to be completed within 25 ms
from START condition to STOP condition and within 10 ms from the ACK pulse to the ACK pulse of
each byte. Accordingly, the following two should be considered as count start conditions.
➀ SDA falling edge caused by SCL/SDA interrupt
This is the countermeasure for a communication interrupt in the middle of from START condition
to a slave address. However, the detection condition must be considered because a interrupt is
also generated by communication from other masters to other slaves.
➁ SMBUS interrupt after receiving slave address
This is the countermeasure for when communication is interrupted from receiving a slave address
until receiving a command.
(2) Low hold of communication line
The I2C-BUS interface conforms to the I 2C-BUS Standard Specifications. However, because the use
condition of SMBUS differs from the I 2C-BUS’s, there is possibility of occurrence of the following
problem.
➀ Low hold of SDA line caused by ACK pulse at voltage drop of communication line
When the SMBUS voltage slowly drops, that is caused by extracting a battery from equipment or
turning off a PC’s power or etc., it might be incorrectly treated as the SCL pulse near the threshold
level voltage.
When the SDA is judged “L” in that condition, it becomes the general call and the ACK is transmitted.
However, when the SCL remains “L” at the ACK pulse, the SDA continuously remains “L” until
input of the next SCL pulse.
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3804 Group (Spec.H)
3.3 Notes on use
Countermeasure:
As explained before, start the time out count at the falling of SDA line of START condition and
reset ES0 bit of the S1D register when the time out is satisfied (Note).
Note: Do not use the read-modify-write instruction at this time. Furthermore, when the ES0 bit is
set to “0”, it becomes a general-purpose port ; so that the port must be set to input mode
or “H”.
3.3.9 Notes on PWM
The PWM starts from “H” level after the PWM enable bit is set to enable and “L” level is temporarily output
from the PWM pin.
The length of this “L“ level output is as follows:
n + 1
2 • f(X IN)
(s)
(Count source selection bit = “0”, where n is the value set in the prescaler)
n + 1
f(X IN)
(s)
(Count source selection bit = “1”, where n is the value set in the prescaler)
3.3.10 Notes on A/D converter
(1) Analog input pin
Make the signal source impedance for analog input low, or equip an analog input pin with an external
capacitor of 0.01 µF to 1 µF. Further, be sure to verify the operation of application products on the
user side.
● Reason
An analog input pin includes the capacitor for analog voltage comparison. Accordingly, when
signals from signal source with high impedance are input to an analog input pin, charge and
discharge noise generates. This may cause the A/D conversion precision to be worse.
(2) A/D converter power source pin
The AVSS pin is A/D converter power source pins. Regardless of using the A/D conversion function
or not, connect it as following :
• AV SS : Connect to the V SS line
● Reason
If the AV SS pin is opened, the microcomputer may have a failure because of noise or others.
(3) Clock frequency during A/D conversion
The comparator consists of a capacity coupling, and a charge of the capacity will be lost if the clock
frequency is too low. Thus, make sure the following during an A/D conversion.
• f(X IN) is 500 kHz or more
• Do not execute the STP instruction
(4) Difference between at 8-bit reading in 10-bit A/D mode and at 8-bit A/D mode
At 8-bit reading in the 10-bit A/D mode, “–1/2 LSB” correction is not performed to the A/D conversion
result.
In the 8-bit A/D mode, the A/D conversion characteristics is the same as 3802 group’s characteristics
because “–1/2 LSB” correction is performed.
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APPENDIX
3804 Group (Spec.H)
3.3 Notes on use
3.3.11 Notes on D/A converter
(1) Vcc when using D/A converter
The D/A converter accuracy when Vcc is 4.0 V or less differs from that of when Vcc is 4.0 V or more.
When using the D/A converter, we recommend using a Vcc of 4.0 V or more.
(2) DAi conversion register when not using D/A converter
When a D/A converter is not used, set all values of the DAi conversion registers (i = 1, 2) to “0016”.
The initial value after reset is “00 16”.
3.3.12 Notes on watchdog timer
●Make sure that the watchdog timer H does not underflow while waiting Stop release, because the
watchdog timer keeps counting during that term.
●When the STP instruction disable bit has been set to “1”, it is impossible to switch it to “0” by a program.
3.3.13 Notes on RESET pin
Connecting capacitor
In case where the RESET signal rise time is long, connect a ceramic capacitor or others across the
RESET pin and the V SS pin. Use a 1000 pF or more capacitor for high frequency use. When
connecting the capacitor, note the following :
• Make the length of the wiring which is connected to a capacitor as short as possible.
• Be sure to verify the operation of application products on the user side.
● Reason
____________
If the several nanosecond or several ten nanosecond impulse noise enters the RESET pin, it may
cause a microcomputer failure.
3.3.14 Notes on low-speed operation mode
(1) Using sub-clock
To use a sub-clock, fix bit 3 of the CPU mode
register to “1” or control the Rd (refer to Figure
3.3.4) resistance value to a certain level to
stabilize an oscillation. For resistance value
of Rd, consult the oscillator manufacturer.
● Reason
When bit 3 of the CPU mode register is set
to “0”, the sub-clock oscillation may stop.
XCIN
XCOUT
Rf
CCIN
Rd
CCOUT
Fig. 3.3.4 Ceramic resonator circuit
(2) Switch between middle/high-speed mode and low-speed mode
If you switch the mode between middle/high-speed and low-speed, stabilize both XIN and XCIN oscillations.
The sufficient time is required for the sub clock to stabilize, especially immediately after power on
and at returning from stop mode. When switching the mode between middle/high-speed and lowspeed, set the frequency on condition that f(X IN) > 3f(X CIN).
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APPENDIX
3804 Group (Spec.H)
3.3 Notes on use
3.3.15 Quartz-crystal oscillator
When using the quartz-crystal oscillator of high frequency, such as 16 MHz etc., it may be necessary to
select a specific oscillator with the specification demanded.
3.3.16 Notes on restarting oscillation
(1) Restarting oscillation
Usually, when the MCU stops the clock oscillation by STP instruction and the STP instruction has
been released by an external interrupt source, the fixed values of Timer 1 and Prescaler 12 (Timer
1 = “0116”, Prescaler 12 = “FF16”) are automatically reloaded in order for the oscillation to stabilize.
The user can inhibit the automatic setting by writing “1” to bit 0 of MISRG (address 0010 16).
However, by setting this bit to “1”, the previous values, set just before the STP instruction was
executed, will remain in Timer 1 and Prescaler 12. Therefore, you will need to set an appropriate
value to each register, in accordance with the oscillation stabilizing time, before executing the STP
instruction.
● Reason
Oscillation will restart when an external interrupt is received. However, internal clock φ is supplied
to the CPU only when Timer 1 starts to underflow. This ensures time for the clock oscillation using
the ceramic resonators to be stabilized.
3.3.17 Notes on using stop mode
■Register setting
Since values of the prescaler 12 and Timer 1 are automatically reloaded when returning from the
stop mode, set them again, respectively. (When the oscillation stabilizing time set after STP
instruction released bit is “0”)
■Clock restoration
After restoration from the stop mode to the normal mode by an interrupt request, the contents of
the CPU mode register previous to the STP instruction execution are retained. Accordingly, if both
main clock and sub clock were oscillating before execution of the STP instruction, the oscillation
of both clocks is resumed at restoration.
In the above case, when the main clock side is set as a system clock, the oscillation stabilizing
time until the timer 1 underflow is reserved at restoration from the stop mode.
When the oscillation stabilizing time set after STP instruction released bit is “0”, the time for 512
counts of the count source become the oscillation stabilizing time. When the oscillation stabilizing
time set after STP instruction released bit is “1”, an arbitrarily count value set to the prescaler 12
and the timer 1 become the oscillation stabilizing time.
At this time, note that the oscillation on the sub clock side may not be stabilized even after the
lapse of the oscillation stabilizing time of the main clock side.
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APPENDIX
3804 Group (Spec.H)
3.3 Notes on use
3.3.18 Notes on wait mode
■Clock restoration
If the wait mode is released by a reset when X CIN is set as the system clock and XIN oscillation is
stopped during execution of the WIT instruction, X CIN oscillation stops, X IN oscillations starts, and
X IN is set as the system clock.
In the above case, the RESET pin should be held at “L” until the oscillation is stabilized.
3.3.19 Notes on CPU rewrite mode
(1) Operation speed
During CPU rewrite mode, set the system clock φ 4.0 MHz or less using the main clock division ratio
selection bits (bits 6 and 7 of address 003B 16).
(2) Instructions inhibited against use
The instructions which refer to the internal data of the flash memory cannot be used during the CPU
rewrite mode.
(3) Interrupts inhibited against use
The interrupts cannot be used during the CPU rewrite mode because they refer to the internal data
of the flash memory.
(4) Watchdog timer
In case of the watchdog timer has been running already, the internal reset generated by watchdog
timer underflow does not happen, because of watchdog timer is always clearing during program or
erase operation.
(5) Reset
Reset is always valid. In case of CNV SS = “H” when reset is released, boot mode is active. So the
program starts from the address contained in address FFFC 16 and FFFD 16 in boot ROM area.
3.3.20 Notes on programming
(1) Processor status register
➀ Initializing of processor status register
Flags which affect program execution must be initialized after a reset.
In particular, it is essential to initialize the T and D flags because they have an important effect
on calculations.
● Reason
After a reset, the contents of the processor status register (PS) are undefined except for the I
flag which is “1”.
Reset
↓
Initializing of flags
↓
Main program
Fig. 3.3.5 Initialization of processor status register
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APPENDIX
3804 Group (Spec.H)
3.3 Notes on use
➁ How to reference the processor status register
To reference the contents of the processor status register (PS), execute the PHP instruction once
then read the contents of (S+1). If necessary, execute the PLP instruction to return the PS to its
original status.
A NOP instruction should be executed after every PLP instruction.
PLP instruction execution
↓
NOP
(S)
(S)+1
Fig. 3.3.6 Sequence of PLP instruction execution
Stored PS
Fig. 3.3.7 Stack memory contents after PHP
instruction execution
(2) BRK instruction
➀ Interrupt priority level
When the BRK instruction is executed with the following conditions satisfied, the interrupt execution
is started from the address of interrupt vector which has the highest priority.
• Interrupt request bit and interrupt enable bit are set to “1”.
• Interrupt disable flag (I) is set to “1” to disable interrupt.
(3) Decimal calculations
➀ Execution of decimal calculations
The ADC and SBC are the only instructions which will yield proper decimal notation, set the
decimal mode flag (D) to “1” with the SED instruction. After executing the ADC or SBC instruction,
execute another instruction before executing the SEC, CLC, or CLD instruction.
➁ Notes on status flag in decimal mode
When decimal mode is selected, the values of three of the flags in the status register (the N, V,
and Z flags) are invalid after a ADC or SBC instruction is executed.
The carry flag (C) is set to “1” if a carry is generated as a result of the calculation, or is cleared
to “0” if a borrow is generated. To determine whether a calculation has generated a carry, the C
flag must be initialized to “0” before each calculation. To check for a borrow, the C flag must be
initialized to “1” before each calculation.
Set D flag to “1”
↓
ADC or SBC instruction
↓
NOP instruction
↓
SEC, CLC, or CLD instruction
Fig. 3.3.8 Status flag at decimal calculations
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APPENDIX
3804 Group (Spec.H)
3.3 Notes on use
(4) JMP instruction
When using the JMP instruction in indirect addressing mode, do not specify the last address on a
page as an indirect address.
(5) Multiplication and Division Instructions
• The index X mode (T) and the decimal mode (D) flags do not affect the MUL and DIV instruction.
• The execution of these instructions does not change the contents of the processor status register.
(6) Ports
The contents of the port direction registers cannot be read. The following cannot be used:
• The data transfer instruction (LDA, etc.)
• The operation instruction when the index X mode flag (T) is “1”
• The instruction with the addressing mode which uses the value of a direction register as an index
• The bit-test instruction (BBC or BBS, etc.) to a direction register
• The read-modify-write instructions (ROR, CLB, or SEB, etc.) to a direction register.
Use instructions such as LDM and STA, etc., to set the port direction registers.
3.3.21 Notes on flash memory version
The CNVss pin determines the flash memory mode. To improve the noise reduction, connect a track
between CNVss pin and Vss pin or Vcc pin with 1 to 10km resistance. The mask ROM version track of
CNVss pin has no operational interference even if it is connected to Vss pin or Vcc pin via a resistor.
3.3.22 Notes on electric characteristic differences between mask ROM and flash nemory version MCUs
There are differences in electric characteristics, operation margin, noise immunity, and noise radiation
between Mask ROM and Flash Memory version MCUs due to the difference in the manufacturing processes,
built-in ROM, and layout pattern etc. When manufacturing an application system with the Flash Memory
version and then switching to use of the Mask ROM version, please conduct evaluations equivalent to the
system evaluations conducted for the flash memory version.
3.3.23 Notes on handling of power source pins
In order to avoid a latch-up occurrence, connect a capacitor suitable for high frequencies as bypass
capacitor between power source pin (Vcc pin) and GND pin (Vss pin), and between power source pin (Vcc
pin) and analog power source input pin (AVss pin). Besides, connect the capacitor to as close as possible.
For bypass capacitor which should not be located too far from the pins to be connected, a ceramic
capacitor of 0.01 µF–0.1 µ F is recommended.
3.3.24 Power Source Voltage
When the power source voltage value of a microcomputer is less than the value which is indicated as the
recommended operating conditions, the microcomputer does not operate normally and may perform unstable
operation.
In a system where the power source voltage drops slowly when the power source voltage drops or the
power supply is turned off, reset a microcomputer when the power source voltage is less than the recommended
operating conditions and design a system not to cause errors to the system by this unstable operation.
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APPENDIX
3804 Group (Spec.H)
3.4 Countermeasures against noise
3.4 Countermeasures against noise
Countermeasures against noise are described below. The following countermeasures are effective against
noise in theory, however, it is necessary not only to take measures as follows but to evaluate before actual use.
3.4.1 Shortest wiring length
The wiring on a printed circuit board can function as an antenna which feeds noise into the microcomputer.
The shorter the total wiring length (by mm unit), the less the possibility of noise insertion into a microcomputer.
(1) Wiring for RESET pin
Make the length of wiring which is connected to the RESET pin as short as possible. Especially,
connect a capacitor across the RESET pin and the VSS pin with the shortest possible wiring (within
20 mm).
● Reason
The width of a pulse input into the RESET pin is determined by the timing necessary conditions.
If noise having a shorter pulse width than the standard is input to the RESET pin, the reset is
released before the internal state of the microcomputer is completely initialized. This may cause
a program runaway.
Noise
Reset
circuit
RESET
VSS
VSS
Reset
circuit
VSS
RESET
VSS
N.G.
O.K.
Fig. 3.4.1 Wiring for the RESET pin
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APPENDIX
3804 Group (Spec.H)
3.4 Countermeasures against noise
(2) Wiring for clock input/output pins
• Make the length of wiring which is connected to clock I/O pins as short as possible.
• Make the length of wiring (within 20 mm) across the grounding lead of a capacitor which is
connected to an oscillator and the V SS pin of a microcomputer as short as possible.
• Separate the VSS pattern only for oscillation from other VSS patterns.
● Reason
If noise enters clock I/O pins, clock waveforms may be deformed. This may cause a program
failure or program runaway. Also, if a potential difference is caused by the noise between the V SS
level of a microcomputer and the V SS level of an oscillator, the correct clock will not be input in
the microcomputer.
Noise
XIN
XOUT
VSS
XIN
XOUT
VSS
O.K.
N.G.
Fig. 3.4.2 Wiring for clock I/O pins
(3) Wiring to CNVss pin
Connect the CNVss pin to the Vss pin with the shortest possible wiring.
● Reason
The processor mode of a microcomputer is influenced by a potential at the CNVss pin. If a
potential difference is caused by the noise between pins CNVss and Vss, the processor mode may
become unstable. This may cause a microcomputer malfunction or a program runaway.
Noise
CNVSS
CNVSS
VSS
VSS
N.G.
O.K.
Fig. 3.4.3 Wiring for CNVss pin
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APPENDIX
3804 Group (Spec.H)
3.4 Countermeasures against noise
3.4.2 Connection of bypass capacitor across V SS line and V CC line
Connect an approximately 0.1 µ F bypass capacitor across the V SS line and the V CC line as follows:
• Connect a bypass capacitor across the V SS pin and the VCC pin at equal length.
• Connect a bypass capacitor across the V SS pin and the V CC pin with the shortest possible wiring.
• Use lines with a larger diameter than other signal lines for V SS line and V CC line.
• Connect the power source wiring via a bypass capacitor to the V SS pin and the V CC pin.
VCC
VCC
VSS
VSS
N.G.
O.K.
Fig. 3.4.4 Bypass capacitor across the V SS line and the V CC line
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APPENDIX
3804 Group (Spec.H)
3.4 Countermeasures against noise
3.4.3 Wiring to analog input pins
• Connect an approximately 100 Ω to 1 kΩ resistor to an analog signal line which is connected to an analog
input pin in series. Besides, connect the resistor to the microcomputer as close as possible.
• Connect an approximately 1000 pF capacitor across the V SS pin and the analog input pin. Besides,
connect the capacitor to the VSS pin as close as possible. Also, connect the capacitor across the analog
input pin and the V SS pin at equal length.
● Reason
Signals which is input in an analog input pin (such as an A/D converter/comparator input pin) are
usually output signals from sensor. The sensor which detects a change of event is installed far
from the printed circuit board with a microcomputer, the wiring to an analog input pin is longer
necessarily. This long wiring functions as an antenna which feeds noise into the microcomputer,
which causes noise to an analog input pin.
If a capacitor between an analog input pin and the VSS pin is grounded at a position far away from
the V SS pin, noise on the GND line may enter a microcomputer through the capacitor.
Noise
(Note)
Microcomputer
Analog
input pin
Thermistor
N.G.
O.K.
VSS
Note : The resistor is used for dividing
resistance with a thermistor.
Fig. 3.4.5 Analog signal line and a resistor and a capacitor
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APPENDIX
3804 Group (Spec.H)
3.4 Countermeasures against noise
3.4.4 Oscillator concerns
Take care to prevent an oscillator that generates clocks for a microcomputer operation from being affected
by other signals.
(1) Keeping oscillator away from large current signal lines
Install a microcomputer (and especially an oscillator) as far as possible from signal lines where a
current larger than the tolerance of current value flows.
● Reason
In the system using a microcomputer, there are signal lines for controlling motors, LEDs, and
thermal heads or others. When a large current flows through those signal lines, strong noise
occurs because of mutual inductance.
Microcomputer
Mutual inductance
M
XIN
XOUT
VSS
Large
current
GND
Fig. 3.4.6 Wiring for a large current signal line
(2) Installing oscillator away from signal lines where potential levels change frequently
Install an oscillator and a connecting pattern of an oscillator away from signal lines where potential
levels change frequently. Also, do not cross such signal lines over the clock lines or the signal lines
which are sensitive to noise.
● Reason
Signal lines where potential levels change frequently (such as the CNTR pin signal line) may affect
other lines at signal rising edge or falling edge. If such lines cross over a clock line, clock waveforms
may be deformed, which causes a microcomputer failure or a program runaway.
N.G.
Do not cross
CNTR
XIN
XOUT
VSS
Fig. 3.4.7 Wiring of signal lines where potential levels change frequently
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APPENDIX
3804 Group (Spec.H)
3.4 Countermeasures against noise
(3) Oscillator protection using VSS pattern
As for a two-sided printed circuit board, print a VSS pattern on the underside (soldering side) of the
position (on the component side) where an oscillator is mounted.
Connect the V SS pattern to the microcomputer V SS pin with the shortest possible wiring. Besides,
separate this V SS pattern from other V SS patterns.
An example of VSS patterns on the
underside of a printed circuit board
Oscillator wiring
pattern example
XIN
XOUT
VSS
Separate the VSS line for oscillation from other VSS lines
Fig. 3.4.8 V SS pattern on the underside of an oscillator
3.4.5 Setup for I/O ports
Setup I/O ports using hardware and software as follows:
<Hardware>
• Connect a resistor of 100 Ω or more to an I/O port in series.
<Software>
• As for an input port, read data several times by a program for checking whether input levels are
equal or not.
• As for an output port, since the output data may reverse because of noise, rewrite data to its port
latch at fixed periods.
• Rewrite data to direction registers and pull-up control registers at fixed periods.
Noise
O.K.
Data bus
Noise
Direction register
N.G.
Port latch
I/O port
pins
Fig. 3.4.9 Setup for I/O ports
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APPENDIX
3804 Group (Spec.H)
3.4 Countermeasures against noise
3.4.6 Providing of watchdog timer function by software
If a microcomputer runs away because of noise or others, it can be detected by a software watchdog timer
and the microcomputer can be reset to normal operation. This is equal to or more effective than program
runaway detection by a hardware watchdog timer. The following shows an example of a watchdog timer
provided by software.
In the following example, to reset a microcomputer to normal operation, the main routine detects errors of
the interrupt processing routine and the interrupt processing routine detects errors of the main routine.
This example assumes that interrupt processing is repeated multiple times in a single main routine processing.
<The main routine>
• Assigns a single byte of RAM to a software watchdog timer (SWDT) and writes the initial value
N in the SWDT once at each execution of the main routine. The initial value N should satisfy the
following condition:
N+1 ≥ ( Counts of interrupt processing executed in each main routine)
As the main routine execution cycle may change because of an interrupt processing or others,
the initial value N should have a margin.
• Watches the operation of the interrupt processing routine by comparing the SWDT contents with
counts of interrupt processing after the initial value N has been set.
• Detects that the interrupt processing routine has failed and determines to branch to the program
initialization routine for recovery processing in the following case:
If the SWDT contents do not change after interrupt processing.
<The interrupt processing routine>
• Decrements the SWDT contents by 1 at each interrupt processing.
• Determines that the main routine operates normally when the SWDT contents are reset to the
initial value N at almost fixed cycles (at the fixed interrupt processing count).
• Detects that the main routine has failed and determines to branch to the program initialization
routine for recovery processing in the following case:
If the SWDT contents are not initialized to the initial value N but continued to decrement and if
they reach 0 or less.
≠N
Main routine
Interrupt processing routine
(SWDT)← N
(SWDT) ← (SWDT)—1
CLI
Interrupt processing
Main processing
(SWDT)
≤0?
(SWDT)
=N?
N
Interrupt processing
routine errors
≤0
>0
RTI
Return
Main routine
errors
Fig. 3.4.10 Watchdog timer by software
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APPENDIX
3804 Group (Spec.H)
3.5 Control registers
3.5 Control registers
Port Pi
b7 b6 b5 b4 b3 b2 b1 b0
Port Pi (i = 0, 1, 2, 3, 4, 5, 6)
(Pi: addresses 000016, 000216, 000416, 000616, 000816, 000A16, 000C16)
b
0
1
2
3
4
5
6
7
Name
Port Pi0
Port Pi1
Port Pi2
Port Pi3
Port Pi4
Port Pi5
Port Pi6
Port Pi7
Functions
●In output mode
Write •••••••• Port latch
Read •••••••• Port latch
●In input mode
Write •••••••• Port latch
Read •••••••• Value of pin
At reset R W
0
0
0
0
0
0
0
0
Fig. 3.5.1 Structure of Port Pi
Port Pi direction register
b7 b6 b5 b4 b3 b2 b1 b0
Port Pi direction register (i = 0, 1, 2, 3, 4, 5, 6)
(PiD: addresses 000116, 000316, 000516, 000716, 000916, 000B16, 000D16)
b
Name
0 Port Pi direction
register
1
2
3
4
5
6
7
Functions
0 : Port Pi0 input mode
1 : Port Pi0 output mode
0 : Port Pi1 input mode
1 : Port Pi1 output mode
0 : Port Pi2 input mode
1 : Port Pi2 output mode
0 : Port Pi3 input mode
1 : Port Pi3 output mode
0 : Port Pi4 input mode
1 : Port Pi4 output mode
0 : Port Pi5 input mode
1 : Port Pi5 output mode
0 : Port Pi6 input mode
1 : Port Pi6 output mode
0 : Port Pi7 input mode
1 : Port Pi7 output mode
At reset R W
0
0
0
0
0
0
0
0
Fig. 3.5.2 Structure of Port Pi direction register
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APPENDIX
3804 Group (Spec.H)
3.5 Control registers
Timer 12, X count source selection register
b7 b6 b5 b4 b3 b2 b1 b0
Timer 12, X count source selection register
(T12XCSS: address 000E16)
b
Name
0 Timer 12 count
source selection
bits
1
2
3
4 Timer X count
source selection
bits
5
6
7
Functions
b3b2b1b0
0 0 0 0: f(XIN)/2 or f(XCIN)/2
0 0 0 1: f(XIN)/4 or f(XCIN)/4
0 0 1 0: f(XIN)/8 or f(XCIN)/8
0 0 1 1: f(XIN)/16 or f(XCIN)/16
0 1 0 0: f(XIN)/32 or f(XCIN)/32
0 1 0 1: f(XIN)/64 or f(XCIN)/64
0 1 1 0: f(XIN)/128 or f(XCIN)/128
0 1 1 1: f(XIN)/256 or f(XCIN)/256
1 0 0 0: f(XIN)/512 or f(XCIN)/512
1 0 0 1: f(XIN)/1024 or f(XCIN)/1024
1010 to 1111: Not available
b7b6b5b4
0 0 0 0: f(XIN)/2 or f(XCIN)/2
0 0 0 1: f(XIN)/4 or f(XCIN)/4
0 0 1 0: f(XIN)/8 or f(XCIN)/8
0 0 1 1: f(XIN)/16 or f(XCIN)/16
0 1 0 0: f(XIN)/32 or f(XCIN)/32
0 1 0 1: f(XIN)/64 or f(XCIN)/64
0 1 1 0: f(XIN)/128 or f(XCIN)/128
0 1 1 1: f(XIN)/256 or f(XCIN)/256
1 0 0 0: f(XIN)/512 or f(XCIN)/512
1 0 0 1: f(XIN)/1024 or f(XCIN)/1024
1 0 1 0: f(XCIN)
1011 to 1111: Not available
At reset R W
1
1
0
0
1
1
0
0
Fig. 3.5.3 Structure of Timer 12, X count source selection register
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APPENDIX
3804 Group (Spec.H)
3.5 Control registers
Timer Y, Z count source selection register
b7 b6 b5 b4 b3 b2 b1 b0
Timer Y, Z count source selection register
(TYZCSS: address 000F16)
b
Name
0 Timer Y count
source selection
bits
1
2
3
4 Timer Z count
source selection
bits
5
6
7
Functions
b3b2b1b0
0 0 0 0: f(XIN)/2 or f(XCIN)/2
0 0 0 1: f(XIN)/4 or f(XCIN)/4
0 0 1 0: f(XIN)/8 or f(XCIN)/8
0 0 1 1: f(XIN)/16 or f(XCIN)/16
0 1 0 0: f(XIN)/32 or f(XCIN)/32
0 1 0 1: f(XIN)/64 or f(XCIN)/64
0 1 1 0: f(XIN)/128 or f(XCIN)/128
0 1 1 1: f(XIN)/256 or f(XCIN)/256
1 0 0 0: f(XIN)/512 or f(XCIN)/512
1 0 0 1: f(XIN)/1024 or f(XCIN)/1024
1 0 1 0: f(XCIN)
1011 to 1111: Not available
b7b6b5b4
0 0 0 0: f(XIN)/2 or f(XCIN)/2
0 0 0 1: f(XIN)/4 or f(XCIN)/4
0 0 1 0: f(XIN)/8 or f(XCIN)/8
0 0 1 1: f(XIN)/16 or f(XCIN)/16
0 1 0 0: f(XIN)/32 or f(XCIN)/32
0 1 0 1: f(XIN)/64 or f(XCIN)/64
0 1 1 0: f(XIN)/128 or f(XCIN)/128
0 1 1 1: f(XIN)/256 or f(XCIN)/256
1 0 0 0: f(XIN)/512 or f(XCIN)/512
1 0 0 1: f(XIN)/1024 or f(XCIN)/1024
1 0 1 0: f(XCIN)
1011 to 1111: Not available
At reset R W
1
1
0
0
1
1
0
0
Fig. 3.5.4 Structure of Timer Y, Z count source selection register
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APPENDIX
3804 Group (Spec.H)
3.5 Control registers
MISRG
b7 b6 b5 b4 b3 b2 b1 b0
MISRG
(MISRG: address 001016)
b
Name
Functions
At reset R W
0 Oscillatin stabilizing 0: Automatically set (Note 1)
time set after STP
1: Autimatically set disabled
instrution released bit
1 Middle-speed mode 0: Not set automatically
automatic switch set 1: Automatic switching
enabled (Notes 2, 3)
bit
2 Middle-speed mode 0: 4.5 to 5.5 machine cycles
1: 6.5 to 7.5 machine cycles
automatic switch
wait time set bit
3 Middle-speed mode 0: Invalid
1: Automatic switch start
automatic switch
(Note 3)
start bit
(Depending on
program)
4 Nothing is arranged for these bits. These are
write disabled bits. When these bits are read
5
out, the contents are “0”.
6
0
0
0
0
0
0
0
✕
✕
✕
✕
0
7
Notes 1: “0116” is set to Timer 1, “FF16” is set to Prescaler 12.
2: During operation in low-speed mode, it is possible automatically to switch to
middle-speed mode owing to the rising of SCL/SDA.
3: When automatic switch to middle-speed mode from low-speed mode occurs,
the values of CPU mode register (003B16) change.
Fig. 3.5.5 Structure of MISRG
I2C data shift register
b7 b6 b5 b4 b3 b2 b1 b0
I2C data shift register
(S0: address 001116)
b
Functions
At reset R W
0 • 8-bit shift register to store receive data and
1 write transmit data.
2
3
4
5
6
7
Undefined
Undefined
Undefined
Undefined
Undefined
Undefined
Undefined
Undefined
Note: When data is written to I2C data shift register after the MST
bit is set to “0” (slave mode), keep the interval for 8 machine
cycles or more.
Also, when the read-modify-write instructions (SEB, CLB) are
used during data transfer, the values may be undefined.
Fig. 3.5.6 Structure of I 2C data shift register
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APPENDIX
3804 Group (Spec.H)
3.5 Control registers
I2C special mode status register
b7 b6 b5 b4 b3 b2 b1 b0
I2C special mode status register
(S3: address 001216)
b
Name
Functions
At reset R W
✕
0
0 Slave address 0
comparison flag
(AAS0)
0: Address disagreement
1: Address agreement
(Notes 1, 2)
1 Slave address 1
comparison flag
(AAS1)
0: Address disagreement
1: Address agreement
(Notes 1, 2)
0
✕
2 Slave address 2
comparison flag
(AAS2)
0: Address disagreement
1: Address agreement
(Notes 1, 2)
0
✕
3 Nothing is arranged for this bit. This is a write
disabled bit. When this bit is read out, the
contents are “0”.
4 Nothing is arranged for this bit. This is a write
disabled bit. When this bit is read out, the
contents are undefined.
0
✕
0
✕
5 SCL pin low hold 2 0: SCL pin low hold
1: SCL pin low release
flag (PIN2)
(Notes 1, 3)
Nothing
is
arranged
for
this bit. This is a write
6
disabled bit. When this bit is read out, the
contents are “0”.
1
✕
0
✕
7 STOP condition
flag (SPCF)
0
✕
0: No detection
1: Detection (Notes 1, 4)
Notes 1: These bits and flags can be read out, but cannot be written.
2: These bits can be detected only when the data format selection bit
(ALS) of I2C control register is set to “0”.
3: This bit is initialized to “1” at reset, when the ACK interrupt control bit
is “0”, or when writing “1” to the SCL pin low hold 2 flag set bit.
4: This bit is initialized to “0” at reset, when the I2C-BUS interface
enable bit (ES0) is “0”, or when writing “1” to the STOP condition
flag clear bit.
Fig. 3.5.7 Structure of I2C special mode status register
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APPENDIX
3804 Group (Spec.H)
3.5 Control registers
I2C status register
b7 b6 b5 b4 b3 b2 b1 b0
I2C status register
(S1: address 001316)
b
Name
0 Last receive bit
(LRB)
1 General call
detection flag
(AD0)
2 Slave address
comparison flag
(AAS)
Functions
At reset R W
Undefined
0: Last bit = “0”
1: Last bit = “1” (Note 1)
0
0: No general call detected
1: General call detected
(Notes 1, 2)
0
0: Address disagreement
1: Address agreement
(Notes 1, 2)
3 Arbitration lost
detection flag (AL)
4 SCL pin low hold
bit (PIN)
5 Bus busy flag (BB)
0: Not detected
1: Detected (Note 1)
0: SCL pin low hold (Note 3)
1: SCL pin low release
0: Bus free
1: Bus busy
0
6 Communication
mode specification
bits (TRX, MST)
7
b7 b6
0
0
0
1
1
0:
1:
0:
1:
Slave receive mode
Slave transmit mode
Master receive mode
Master transmit mode
1
0
0
Notes 1: These flags and bits are exclusive to input. When writing to
these bits, write “0” to these bits.
2: These bits can be detected only when the data format
selection bit (ALS) of I2C control register is set to “0”.
3: This bit can be set to “1” by program, but cannot be cleared
to “0”.
4: All bits are changed by hardware. Do not use the readmodify-write instructions (SEB, CLB).
Fig. 3.5.8 Structure of I 2C status register
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APPENDIX
3804 Group (Spec.H)
3.5 Control registers
I2C control register
b7 b6 b5 b4 b3 b2 b1 b0
I2C control register
(S1D: address 001416)
b
Name
0 Bit counter
(Number of
transmit/receive
1 bits)
(BC0, BC1, BC2)
2
Functions
b2b1b0
0 0 0: 8
0 0 1: 7
0 1 0: 6
0 1 1: 5
1 0 0: 4
1 0 1: 3
1 1 0: 2
1 1 1: 1
At reset R W
0
0
0
0: Disabled
3 I2C-BUS interface
1: Enabled
enable bit (ES0)
0: Addressing format
4 Data format
selection bit (ALS) 1: Free data format
5 Addressing format 0: 7-bit addressing format
selection bit
1: 10-bit addressing format
(10BIT SAD)
6 Nothing is arranged for this bit. This is a write
disabled bit. When this bit is read out, the
contents are “0”.
0
7 I2C-BUS interface pin 0: SMBUS input
input level selection 1: CMOS input
bit (TISS)
0
0
0
0
✕
Note: Do not use the read-modify-write instruction because some bits
change by hardware when the start condition is detected and
the byte-transfer is completed.
Fig. 3.5.9 Structure of I 2C control register
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APPENDIX
3804 Group (Spec.H)
3.5 Control registers
I2C clock control register
b7 b6 b5 b4 b3 b2 b1 b0
I2C clock control register
(S2: address 001516)
b
Name
0 SCL frequency
control bits
(CCR0, CCR1,
1 CCR2, CCR3,
CCR4)
2
3
4
5 SCL mode
specification bit
(FAST MODE)
6 ACK bit
(ACK BIT)
7 ACK clock bit
(ACK)
Functions
Setting value
b4b3b2b1b0
00 to 02
03
04
05
06
Standard High-speed
clock mode clock mode
Disabled Disabled
Disabled 333
(Note 2) 250
100
400 (Note 3)
83.3
166
500/CCR value 1000/CCR value
(Note 3) (Note 3)
17.2
34.5
1D
1E
16.6
33.3
1F
16.1
32.3
(φ = 4 MHz, Unit: kHz) (Note 1)
At reset R W
0
0
0
0
0
0: Standard clock mode
1: High-speed clock mode
0
0: ACK is returned.
1: ACK is not returned.
0: No ACK clock
1: ACK clock
0
0
Notes 1: Duty of SCL clock output is 50 %. The duty becomes 35 to 45 % only when the highspeed clock mode is selected and CCR value = 5 (400 kHz, at φ = 4 MHz). H
duration of the clock fluctuates from —4 to +2 machine cycles in the standard clock
mode, and fluctuates from —2 to +2 machine cycles in the high-speed clock mode. In
the case of negative fluctuation, the frequency does not increase because L
duration is extended instead of H duration reduction.
These are values when SCL clock synchronization by the synchronous function is not
performed. CCR value is the decimal notation value of the SCL frequency control bits
CCR4 to CCR0.
2: Each value of SCL frequency exceeds the limit at φ = 4 MHz or more. When using
these setting value, use φ of 4 MHz or less.
3: The data formula of SCL frequency is described below:
φ/(8 ✕ CCR value) Standard clock mode
φ/(4 ✕ CCR value) High-speed clock mode (CCR value ≠ 5)
φ/(2 ✕ CCR value) High-speed clock mode (CCR value = 5)
Do not set 0 to 2 as CCR value regardless of φ frequency.
Set 100 kHz (max.) in the standard clock mode and 400 kHz (max.) in the high-speed
clock mode to the SCL frequency by setting the SCL frequency control bits CCR4 to
CCR0.
Fig. 3.5.10 Structure of I 2C clock control register
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APPENDIX
3804 Group (Spec.H)
3.5 Control registers
I2C START/STOP condition control register
b7 b6 b5 b4 b3 b2 b1 b0
I2C START/STOP condition control register
(S2D: address 001616)
0
b
Name
0 START/STOP
condition set bits
1 (SSC0, SSC1,
2 SSC2, SSC3,
SSC4)
3
Functions
SCL release time
= φ (µs) ✕ (SSC+1)
Setup time
= φ (µs) ✕ (SSC+1)/2
Hold time
= φ (µs) ✕ (SSC+1)/2
4
At reset R W
0
1
0
1
1
5 SCL/SDA interrupt
pin polarity selection
bit (SIP)
6 SCL/SDA interrupt
pin selection bit
(SIS)
0: Falling edge active
1: Rising edge active
0
0: SDA valid
1: SCL valid
0
0
7 Fix this bit to 0 .
Note: Fix SSC0 to 0 . Also, do not set SSC4 to SSC0 to odd values or 000002 .
Fig. 3.5.11 Structure of I 2C START/STOP condition control register
I2C special mode control register
b7 b6 b5 b4 b3 b2 b1 b0
0
0
I2C special mode control register
(S3D: address 001716)
b
Name
Functions
At reset R W
0 Fix this bit to 0 .
1 ACK interrupt control 0: At communication
completion
bit (ACKICON)
1: At falling of ACK clock and
communication completion
0
0
2 Slave address
0: One-byte slave address
control bit (MSLAD)
compare mode
1: Three-byte slave address
compare mode
3 Nothing is arranged for this bit. This is a write
disabled bit. When this bit is read out, the
contents are 0 .
0
4 Fix this bit to 0 .
5 SCL pin low hold 2 Writing 1 to this bit initializes
flag set bit (PIN2IN) the SCL pin low hold 2 flag
to 1 . (Notes 1, 2)
Writing 1 to this bit clears
6 SCL pin low hold
set bit (PIN2HD)
the SCL pin low hold 2 flag to
0 and holds the SCL pin low.
(Notes 1, 2)
0
0
7 STOP condition flag Writing 1 to this bit initializes
clear bit (SPFCL)
the STOP condition flag to
0 . (Note 1)
0
0
✕
0
Notes 1: When 0 is written to these bits, nothing is happened.
2: Do not write 1 to these bits at the same time.
Fig. 3.5.12 Structure of I 2C special mode control register
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APPENDIX
3804 Group (Spec.H)
3.5 Control registers
Transmit/Receive buffer register 1, Transmit/Receive buffer register 3
b7 b6 b5 b4 b3 b2 b1 b0
Transmit/Receive buffer register 1 (TB1/RB1: address 001816)
Transmit/Receive buffer register 3 (TB3/RB3: address 003016)
b
Functions
At reset R W
0
1
2
3
4
5
6
7
The transmission data is written to or the
receive data is read out from this buffer register.
• At write: A data is written to the transmit buffer
register.
• At read: The contents of the receive buffer
register are read out.
Undefined
Undefined
Undefined
Undefined
Undefined
Undefined
Undefined
Undefined
Note: The contents of transmit buffer register cannot be read out.
The data cannot be written to the receive buffer register.
Fig. 3.5.13 Structure of Transmit/Receive buffer register 1, Transmit/Receive buffer register 3
Serial I/O1 status register, Serial I/O3 status register
b7 b6 b5 b4 b3 b2 b1 b0
Serial I/O1 status register (SIO1STS: address 001916)
Serial I/O3 status register (SIO3STS: address 003116)
b
Name
0 Transmit buffer
empty flag (TBE)
1 Receive buffer full
flag (RBF)
2 Transmit shift
register shift
completion flag
(TSC)
Functions
0: Buffer full
1: Buffer empty
0: Buffer empty
1: Buffer full
0: Transmit shift in progress
1: Transmit shift completed
3 Overrun error flag 0: No error
(OE)
1: Overrun error
4 Parity error flag
0: No error
(PE)
1: Parity error
5 Framing error flag 0: No error
(FE)
1: Framing error
Summing
error
flag
6
0: (OE) U (PE) U (FE) = 0
(SE)
1: (OE) U (PE) U (FE) = 1
7 Nothing is arranged for this bit. This bit is a
write disabled bit. When this bit is read out, the
contents are “1”.
At reset R W
✕
0
0
✕
0
✕
0
✕
0
✕
0
✕
0
✕
1
✕
Fig. 3.5.14 Structure of Serial I/O1 status register, Serial I/O3 status register
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APPENDIX
3804 Group (Spec.H)
3.5 Control registers
Serial I/O1 control register
b7 b6 b5 b4 b3 b2 b1 b0
Serial I/O1 control register
(SIO1CON: address 001A16)
b
Name
Functions
0 BRG count source 0: f(XIN)
selection bit (CSS) 1: f(XIN)/4
Serial
I/O1
When clock synchronous
1
synchronous clock serial I/O is selected,
selection bit (SCS) 0: BRG output divided by 4
1: External clock input
When UART is selected,
0: BRG output divided by 16
1: External clock input
divided by16
At reset R W
0
0
2 SRDY1 output
enable bit (SRDY)
0: I/O port (P47)
1: SRDY1 output pin
0
3 Transmit interrupt
source selection
bit (TIC)
0: Transmit buffer empty
1: Transmit shift operation
completion
0
4 Transmit enable bit
(TE)
5 Receive enable bit
(RE)
6 Serial I/O1 mode
selection bit (SIOM)
0: Transmit disabled
1: Transmit enabled
0: Receive disabled
1: Receive enabled
0: UART
1: Clock synchronous
serial I/O
0: Serial I/O1 disabled
(P44 to P47: normal I/O pins)
1: Serial I/O1 enabled
(P44 to P47: Serial I/O pins)
0
7 Serial I/O1 enable
bit (SIOE)
0
0
0
Fig. 3.5.15 Structure of Serial I/O1 control register
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APPENDIX
3804 Group (Spec.H)
3.5 Control registers
UART1 control register
b7 b6 b5 b4 b3 b2 b1 b0
UART1 control register
(UART1CON: address 001B16)
b
Name
Functions
At reset R W
0 Character length
0: 8 bits
selection bit (CHAS) 1: 7 bits
0
1 Parity enable bit
(PARE)
0: Parity checking disabled
1: Parity checking enabled
0
2 Parity selection bit
(PARS)
0: Even parity
1: Odd parity
0
3 Stop bit length
0: 1 stop bit
selection bit (STPS) 1: 2 stop bits
0
4 P45/TxD1 P-channel 0: CMOS output
output disable bit
(in output mode)
(POFF)
1: N-channel open-drain
output (in output mode)
5 Nothing is arranged for these bits. These are
6 write disabled bits. When these bits are read
out, the contents are “1”.
7
0
1
1
1
✕
✕
✕
Fig. 3.5.16 Structure of UART1 control register
Baud rate generator i (i = 1, 3)
b7 b6 b5 b4 b3 b2 b1 b0
Baud rate generator i
(BRGi (i=1, 3): address 001C16, 002F16)
b
Functions
At reset R W
0 Set a count value of baud rate generator.
Undefined
1
Undefined
2
Undefined
3
Undefined
4
Undefined
5
Undefined
6
Undefined
7
Undefined
Note: Write to this register while transmit/receive operation is stopped.
Fig. 3.5.17 Structure of Baud rate generator i
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APPENDIX
3804 Group (Spec.H)
3.5 Control registers
Serial I/O2 control register
b7 b6 b5 b4 b3 b2 b1 b0
Serial I/O2 control register
(SIO2CON: address 001D16)
b
Name
0 Internal
synchronous clock
1 selection bits
2
3 Serial I/O2 port
selection bit
4 SRDY2 output
enable bit
5 Transfer direction
selection bit
6 Serial I/O2
synchronous
clock selection bit
7 P51/SOUT2
P-channel output
disable bit
Functions
b2b1b0
0 0 0: f(XIN)/8
0 0 1: f(XIN)/16
0 1 0: f(XIN)/32
0 1 1: f(XIN)/64
1 1 0: f(XIN)/128
1 1 1: f(XIN)/256
0: I/O port (P51, P52)
1: SOUT2, SCLK2 signal output
0: I/O port (P53)
1: SRDY2 signal output
0: LSB first
1: MSB first
0: External clock
1: Internal clock
0: CMOS output
(in output mode)
1: N-channel open-drain
output (in output mode)
At reset R W
0
0
0
0
0
0
0
0
Fig. 3.5.18 Structure of Serial I/O2 control register
Watchdog timer control register
b7 b6 b5 b4 b3 b2 b1 b0
Watchdog timer control register
(WDTCON: address 001E16)
b
Name
Functions
0 Watchdog timer H
1 (for read-out of high-order 6 bit)
2
3
4
5
6 STP instruction
0: STP instruction enabled
1: STP instruction disabled
disable bit
7 Watchdog timer H 0: Watchdog timer L
underflow
count source selection
1: f(XIN)/16 or f(XCIN)/16
bit
At reset R W
1
✕
✕
1
1
✕
✕
1
1
✕
✕
1
0
0
Fig. 3.5.19 Structure of Watchdog timer control register
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APPENDIX
3804 Group (Spec.H)
3.5 Control registers
Serial I/O2 register
b7 b6 b5 b4 b3 b2 b1 b0
Serial I/O2 register
(SIO2: address 001F16)
b
0
1
2
3
4
5
6
7
Name
Functions
This register becomes shift register.
At transmit: Set transmit data to this register.
At receive: Received data is stored to this
register.
At reset R W
Undefined
Undefined
Undefined
Undefined
Undefined
Undefined
Undefined
Undefined
Fig. 3.5.20 Structure of Serial I/O2 register
Prescaler 12, Prescaler X, Prescaler Y
b7 b6 b5 b4 b3 b2 b1 b0
Prescaler 12 (PRE12), Prescaler X (PREX), Prescaler Y (PREY)
(addresses 002016, 002416, 002616)
b
Functions
0 • Set a count value of each prescaler.
1 • The value set in this register is written to both
2 each prescaler and the corresponding
3 prescaler latch at the same time.
• When this register is read out, the count value
4
of the corresponding prescaler is read out.
5
6
7
At reset R W
1
1
1
1
1
1
1
1
Fig. 3.5.21 Structure of Prescaler 12, Prescaler X, Prescaler Y
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APPENDIX
3804 Group (Spec.H)
3.5 Control registers
Timer 1
b7 b6 b5 b4 b3 b2 b1 b0
Timer 1
(T1: address 002116)
b
Functions
0 • Set timer 1 count value.
1 • The value set in this register is written to both
2 the timer 1 and the timer 1 latch at the same
3 time.
• When the timer 1 is read out, the count value
4
of the timer 1 is read out.
5
6
7
At reset R W
1
0
0
0
0
0
0
0
Fig. 3.5.22 Structure of Timer 1
Timer 2, Timer X, Timer Y
b7 b6 b5 b4 b3 b2 b1 b0
Timer 2 (T2), Timer X (TX), Timer Y (TY)
(addresses 002216, 002516, 002716)
b
Functions
0 • Set each timer count value.
1 • The value set in this register is written to both
2 each timer and the corresponding timer latch
3 at the same time.
• When each timer is read out, the count value
4
of the corresponding timer is read out.
5
6
7
At reset R W
1
1
1
1
1
1
1
1
Fig. 3.5.23 Structure of Timer 2, Timer X, Timer Y
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APPENDIX
3804 Group (Spec.H)
3.5 Control registers
Timer XY mode register
b7 b6 b5 b4 b3 b2 b1 b0
Timer XY mode register
(TM: address 002316)
b
Name
0 Timer X operating
mode bits
1
2
3
4
5
6
7
Functions
At reset R W
b1 b0
0
0 0: Timer mode
0 1: Pulse output mode
1 0: Event counter mode
1 1: Pulse width
measurement mode
CNTR0 active edge Refer to Table 3.5.1
switch bit
Timer X count stop 0: Count start
1: Count stop
bit
Timer Y operating b5 b4
0 0: Timer mode
mode bits
0 1: Pulse output mode
1 0: Event counter mode
1 1: Pulse width
measurement mode
CNTR1 active edge Refer to Table 3.5.1
switch bit
Timer Y count stop 0: Count start
1: Count stop
bit
0
0
0
0
0
0
0
Fig. 3.5.24 Structure of Timer XY mode register
Table 3.5.1 CNTR0/CNTR1 active edge switch bit function
Timer X/Timer Y operation modes CNTR0/CNTR1 active edge switch bit (bits 2 and 6 of address 002316) contents
Timer mode
“0” CNTR 0/CNTR1 interrupt request occurrence: Falling edge
; No influence to timer count
“1” CNTR 0/CNTR 1 interrupt request occurrence: Rising edge
Pulse output mode
; No influence to timer count
“0” Pulse output start: Beginning at “H” level
CNTR 0/CNTR1 interrupt request occurrence: Falling edge
“1” Pulse output start: Beginning at “L” level
CNTR 0/CNTR 1 interrupt request occurrence: Rising edge
Event counter mode
“0” Timer X/Timer Y: Rising edge count
CNTR 0/CNTR1 interrupt request occurrence: Falling edge
“1” Timer X/Timer Y: Falling edge count
CNTR 0/CNTR 1 interrupt request occurrence: Rising edge
Pulse width measurement mode
“0” Timer X/Timer Y: “H” level width measurement
CNTR 0/CNTR1 interrupt request occurrence: Falling edge
“1” Timer X/Timer Y: “L” level width measurement
CNTR 0/CNTR 1 interrupt request occurrence: Rising edge
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APPENDIX
3804 Group (Spec.H)
3.5 Control registers
Timer Z low-order, Timer Z high-order
b7 b6 b5 b4 b3 b2 b1 b0
Timer Z low-order (TZL), Timer Z high-order (TZH)
(addresses 002816, 002916)
b
Functions
At reset R W
0 • Set each timer count value.
[At write]
1 • Depending on the write control bit (bit 3 of
TZM), the value set to this register is written to
2
each timer and the corresponding timer latch
at the same time, or is written only to the latch.
3
[At read]
4 • The corresponding timer count value is read
out by reading this register.
5
• Read both registers in order of TZH and TZL
following.
6
• Write both registers in order of TZL and TZH
7
following.
1
1
1
1
1
1
1
1
Fig. 3.5.25 Structure of Timer Z low-order, Timer Z high-order
Timer Z mode register
b7 b6 b5 b4 b3 b2 b1 b0
Timer Z mode register
(TZM: address 002A16)
b
Name
0 Timer Z operating
mode bits
1
2
Functions
b2b1b0
0 0 0: Timer/Event counter mode
0 0 1: Pulse output mode
0 1 0: Pulse period
measurement mode
0 1 1: Pulse width
measurement mode
1 0 0: Programmable waveform
generating mode
1 0 1: Programmable one-shot
generating mode
1 1 0: Not available
1 1 1: Not available
3 Timer Z write control 0: Writing data to both latch
and timer simultaneousuly
bit
1: Writing data only to latch
0: “L” output
4 Output level latch
1: “H” output
5 CNTR2 active edge Refer to Table 3.5.2.
switch bit
6 Timer Z count stop 0: Count start
1: Count stop
bit
7 Timer/Event counter 0: Timer mode
mode switch bit (Note) 1: Event counter mode
At reset R W
0
0
0
0
0
0
0
0
Note: When selecting the modes except the timer/event counter mode, set “0” to this bit.
Fig. 3.5.26 Structure of Timer Z mode register
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APPENDIX
3804 Group (Spec.H)
3.5 Control registers
Table 3.5.2 CNTR 2 active edge switch bit function
Timer Z operation modes
Timer mode
CNTR2 active edge switch bit (bit 5 of address 002A16) contents
“0” CNTR 2 interrupt request occurrence: Falling edge
; No influence to timer count
“1” CNTR 2 interrupt request occurrence: Rising edge
; No influence to timer count
Event counter mode
“0” Timer Z: Rising edge count
CNTR 2 interrupt request occurrence: Falling edge
“1” Timer Z: Falling edge count
CNTR 2 interrupt request occurrence: Rising edge
Pulse output mode
“0” Pulse output start: Beginning at “H” level
CNTR 2 interrupt request occurrence: Falling edge
“1” Pulse output start: Beginning at “L” level
CNTR 2 interrupt request occurrence: Rising edge
Pulse period measurement mode
“0” Timer Z: Period from falling edge to the next falling edge measurement
CNTR 2 interrupt request occurrence: Falling edge
“1” Timer Z: Period from rising edge to the next rising edge measurement
Pulse width measurement mode
CNTR 2 interrupt request occurrence: Rising edge
“0” Timer Z: “H” level width measurement
CNTR 2 interrupt request occurrence: Falling edge
“1” Timer Z: “L” level width measurement
CNTR 2 interrupt request occurrence: Rising edge
Programmable one-shot generating “0” Timer Z: after start outputting “L”, “H” one-shot pulse generated
mode
CNTR 2 interrupt request occurrence: Falling edge
“1” Timer Z: after start outputting “H”, “L” one-shot pulse generated
CNTR 2 interrupt request occurrence: Rising edge
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APPENDIX
3804 Group (Spec.H)
3.5 Control registers
PWM control register
b7 b6 b5 b4 b3 b2 b1 b0
PWM control register (PWMCON: address 002B16)
b
0
1
2
3
4
5
6
7
Name
Functions
PWM function
0 : PWM disabled
enable bit
1 : PWM enabled
Count source
0 : f(XIN)
selection bit
1 : f(XIN)/2
Nothing is arranged for these bits. These are
write disabled bits. When these bits are read
out, the contents are “0”.
At reset R W
0
0
0
0
0
0
0
0
✕
✕
✕
✕
✕
✕
Fig. 3.5.27 Structure of PWM control register
PWM prescaler
b7 b6 b5 b4 b3 b2 b1 b0
PWM prescaler
(PREPWM: address 002C16)
b
Functions
At reset R W
0 •Set the PWM period.
1 •The value set in this register is written to both
PWM prescaler pre-latch and PWM prescaler
2 latch at the same time.
3 • When data is written to this register during
PWM output, the pulse corresponding to
4 changed value is output at the next period.
5 • When this register is read out, the count value
of the PWM prescaler latch is read out.
6
Undefined
7
Undefined
Undefined
Undefined
Undefined
Undefined
Undefined
Undefined
Fig. 3.5.28 Structure of PWM prescaler
PWM register
b7 b6 b5 b4 b3 b2 b1 b0
PWM register
(PWM: address 002D16)
b
Functions
At reset R W
0 • Set the PWM “H” level output interval.
1 • The value set in this register is written to both
PWM register pre-latch and PWM register
2 latch at the same time.
3 • When data is written to this register during
PWM output, the pulse corresponding to
4 changed value is output at the next period.
5 • When this register is read out, the contents of
the PWM register latch is read out.
6
Undefined
7
Undefined
Undefined
Undefined
Undefined
Undefined
Undefined
Undefined
Fig. 3.5.29 Structure of PWM register
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APPENDIX
3804 Group (Spec.H)
3.5 Control registers
Serial I/O3 control register
b7 b6 b5 b4 b3 b2 b1 b0
Serial I/O3 control register
(SIO3CON: address 003216)
b
Name
Functions
0 BRG count source 0: f(XIN)
selection bit (CSS) 1: f(XIN)/4
When clock synchronous
1 Serial I/O3
synchronous clock serial I/O is selected,
selection bit (SCS) 0: BRG output divided by 4
1: External clock input
When UART is selected,
0: BRG output divided by 16
1: External clock input
divided by16
At reset R W
0
0
2 SRDY3 output
enable bit (SRDY)
0: I/O port (P37)
1: SRDY3 output pin
0
3 Transmit interrupt
source selection
bit (TIC)
0: Transmit buffer empty
1: Transmit shift operation
completion
0
4 Transmit enable bit
(TE)
5 Receive enable bit
(RE)
6 Serial I/O3 mode
selection bit (SIOM)
0: Transmit disabled
1: Transmit enabled
0: Receive disabled
1: Receive enabled
0: UART
1: Clock synchronous
serial I/O
0: Serial I/O3 disabled
(P34 to P37: normal I/O pins)
1: Serial I/O3 disabled
(P34 to P37: Serial I/O pins)
0
7 Serial I/O3 enable
bit (SIOE)
0
0
0
Fig. 3.5.30 Structure of Serial I/O3 control register
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APPENDIX
3804 Group (Spec.H)
3.5 Control registers
UART3 control register
b7 b6 b5 b4 b3 b2 b1 b0
UART3 control register
(UART3CON: address 003316)
b
Name
Functions
At reset R W
0 Character length
0: 8 bits
selection bit (CHAS) 1: 7 bits
0
1 Parity enable bit
(PARE)
0: Parity checking disabled
1: Parity checking enabled
0
2 Parity selection bit
(PARS)
0: Even parity
1: Odd parity
0
3 Stop bit length
0: 1 stop bit
selection bit (STPS) 1: 2 stop bits
0
4 P35/TxD3 P-channel 0: CMOS output
output disable bit
(in output mode)
(POFF)
1: N-channel open-drain
output (in output mode)
5 Nothing is arranged for these bits. These are
6 write disabled bits. When these bits are read
out, the contents are “1”.
7
0
1
1
1
✕
✕
✕
Fig. 3.5.31 Structure of UART3 control register
AD/DA control register
b7 b6 b5 b4 b3 b2 b1 b0
AD/DA control register
(ADCON: address 003416)
b
Name
0 Analog input pin
selection bits 1
1
2
Functions
b2 b1 b0
0 0 0: P60/AN0 or P00/AN8
0 0 1: P61/AN1 or P01/AN9
0 1 0: P62/AN2 or P02/AN10
0 1 1: P63/AN3 or P03/AN11
1 0 0: P64/AN4 or P04/AN12
1 0 1: P65/AN5 or P05/AN13
1 1 0: P66/AN6 or P06/AN14
1 1 1: P67/AN7 or P07/AN15
0: Conversion in progress
3 AD conversion
1: Conversion completed
completion bit
4 Analog input pin
0: AN0 to AN7 side
1: AN8 to AN15 side
selection bit 2
5 Nothing is arranged for this bit. This is a write
disabled bit. When this bit is read out, the
contents are “0”.
6 DA1 output enable 0: DA1 output disabled
1: DA1 output enabled
bit
7 DA2 output enable 0: DA2 output disabled
1: DA2 output enabled
bit
At reset R W
0
0
0
1
0
0
0
0
Fig. 3.5.32 Structure of AD/DA control register
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APPENDIX
3804 Group (Spec.H)
3.5 Control registers
AD conversion register 1
b7 b6 b5 b4 b3 b2 b1 b0
AD conversion register 1
(AD1: address 003516)
b
0
1
2
3
4
5
6
7
Functions
At reset R W
This is A/D conversion result stored bits. This is Undefined
Undefined
read exclusive register.
0
Undefined
0
8-bit
read
b7
b0
Undefined
0
b9 b8 b7 b6 b5 b4 b3 b2
Undefined
0
Undefined
0
10-bit
read
b7
b0
Undefined
0
b7 b6 b5 b4 b3 b2 b1 b0
Undefined
Fig. 3.5.33 Structure of AD conversion register 1
DAi conversion register
b7 b6 b5 b4 b3 b2 b1 b0
DAi conversion register (i = 1, 2)
(DAi: addresses 003616, 003716)
b
Functions
0 This is D/A output value stored bits. This is write
1 exclusive register.
2
3
4
5
6
7
At reset R W
0
0
0
0
0
0
0
0
Fig. 3.5.34 Structure of DAi conversion register (i = 1, 2)
AD conversion register 2
b7 b6 b5 b4 b3 b2 b1 b0
AD conversion register 2
(AD2: address 003816)
b
Functions
At reset R W
0 This is A/D conversion result stored bits. This is Undefined
read exclusive register.
10-bit read b0
b7
Undefined
1
0
b9 b8
2
3
4
5
6
7
Nothing is arranged for these bits. These are
write disabled bits. When these bits are read out,
the contents are “0”.
Conversion mode
selection bit
0: 10-bit A/D mode
1: 8-bit A/D mode
0
0
0
0
0
0
Fig. 3.5.35 Structure of AD conversion register 2
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APPENDIX
3804 Group (Spec.H)
3.5 Control registers
Interrupt source selection register
b7 b6 b5 b4 b3 b2 b1 b0
Interrupt source selection register
(INTSEL: address 003916)
b
Name
Functions
At reset R W
0 INT0/Timer Z
interrupt source
selection bit (*1)
0: INT0 interrupt
1: Timer Z interrupt
0
1 Serial I/O2/Timer Z
interrupt source
selection bit (*1)
2 Serial I/O1 transmit/
SCL, SDA interrupt
source selection bit
(*2)
0: Serial I/O2 interrupt
1: Timer Z interrupt
0
0: Serial I/O1 transmit
interrupt
1: SCL, SDA interrupt
0
0: CNTR0 interrupt
1: SCL, SDA interrupt
0
0: INT4 interrupt
1: CNTR2 interrupt
0
0: INT2 interrupt
1: I2C interrupt
0: CNTR1 interrupt
1: Serial I/O3 receive
interrupt
0: A/D converter interrupt
1: Serial I/O3 transmit
interrupt
0
3 CNTR0/SCL, SDA
interrupt source
selection bit (*2)
4 INT4/CNTR2
interrupt source
selection bit
5 INT2/I2C interrupt
source selection bit
6 CNTR1/Serial I/O3
receive interrupt
source selection bit
7 AD converter/Serial
I/O3 transmit
interrupt source
selection bit
0
0
*1: Do not write 1 to these bits simultaneously.
*2: Do not write 1 to these bits simultaneously.
Fig. 3.5.36 Structure of Interrupt source selection register
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APPENDIX
3804 Group (Spec.H)
3.5 Control registers
Interrupt edge selection register
b7 b6 b5 b4 b3 b2 b1 b0
Interrupt edge selection register
(INTEDGE: address 003A16)
b
Name
Functions
At reset R W
0: Falling edge active
0 INT0 active edge
1: Rising edge active
selection bit
0: Falling edge active
1 INT1 active edge
1: Rising edge active
selection bit
2 Nothing is arranged for this bit. This is a write
disabled bit. When this bit is read out, the
contents are “0”.
3 INT2 active edge
0: Falling edge active
selection bit
1: Rising edge active
4 INT3 active edge
0: Falling edge active
selection bit
1: Rising edge active
0: Falling edge active
5 INT4 active edge
selection bit
1: Rising edge active
6 INT0, INT4 interrupt 0: INT00, INT40 interrupt
switch bit
1: INT01, INT41 interrupt
0
7 Nothing is arranged for this bit. This is a write
disabled bit. When this bit is read out, the
contents are “0”.
0
0
0
0
0
0
0
Fig. 3.5.37 Structure of Interrupt edge selection register
CPU mode register
b7 b6 b5 b4 b3 b2 b1 b0
1
CPU mode register
(CPUM: address 003B16)
b
Name
0 Processor mode
bits
1
2 Stack page
selection bit
3 Fix this bit to “1”.
Functions
b1 b0
00 : Single-chip mode
01 :
10 :
Not available
11 :
0 : 0 page
1 : 1 page
At reset R W
0
0
0
1
4 Port Xc switch bit
0: I/O port function
(stop oscillating)
1: XCIN-XCOUT oscillation
function
0
5 Main clock (XINXOUT) stop bit
6 Main clock division
ratio selection bits
0: Oscillating
1: Stopped
0
b7 b6
1
7
0 0: φ=f(XIN)/2
(high-speed mode)
0 1: φ=f(XIN)/8
(middle-speed mode)
1 0: φ=f(XCIN)/2
(low-speed mode)
1 1: not available
0
Fig. 3.5.38 Structure of CPU mode register
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APPENDIX
3804 Group (Spec.H)
3.5 Control registers
Interrupt request register 1
b7 b6 b5 b4 b3 b2 b1 b0
Interrupt request register 1
(IREQ1 : address 003C16)
b
Name
Functions
At reset R W
0 INT0/Timer Z
0 : No interrupt request issued
interrupt request bit 1 : Interrupt request issued
0
✽
1 INT1 interrupt
request bit
0
✽
2 Serial I/O1 receive 0 : No interrupt request issued
interrupt request bit 1 : Interrupt request issued
0
✽
0 : No interrupt request issued
3 Serial I/O1
transmit/SCL, SDA 1 : Interrupt request issued
interrupt request bit
0
✽
4 Timer X interrupt
request bit
0 : No interrupt request issued
0
✽
5 Timer Y interrupt
request bit
0 : No interrupt request issued
0
✽
6 Timer 1 interrupt
request bit
0 : No interrupt request issued
0
✽
0
✽
0 : No interrupt request issued
1 : Interrupt request issued
1 : Interrupt request issued
1 : Interrupt request issued
1 : Interrupt request issued
7 Timer 2 interrupt
0 : No interrupt request issued
request bit
1 : Interrupt request issued
✽: 0 can be set by software, but 1 cannot be set.
Fig. 3.5.39 Structure of Interrupt request register 1
Interrupt request register 2
b7 b6 b5 b4 b3 b2 b1 b0
Interrupt request register 2
(IREQ2 : address 003D16)
b
Name
Functions
At reset R W
0 CNTR0/SCL, SDA
interrupt request bit
1 CNTR1/Serial I/O3
receive interrupt
request bit
0 : No interrupt request issued
1 : Interrupt request issued
0 : No interrupt request issued
1 : Interrupt request issued
0
✽
0
✽
2 Serial I/O2/Timer Z
interrupt request bit
3 INT2/I2C interrupt
request bit
4 INT3 interrupt
request bit
5 INT4/CNTR2
interrupt request bit
6 AD converter/Serial
I/O3 transmit
interrupt request bit
0 : No interrupt request issued
1 : Interrupt request issued
0 : No interrupt request issued
1 : Interrupt request issued
0 : No interrupt request issued
1 : Interrupt request issued
0 : No interrupt request issued
1 : Interrupt request issued
0 : No interrupt request issued
1 : Interrupt request issued
0
✽
0
✽
0
✽
0
✽
0
✽
7 Nothing is arranged for this bit. This is a write
disabled bit. When this bit is read out, the
contents are 0 .
0
✽: 0 can be set by software, but 1 cannot be set.
Fig. 3.5.40 Structure of Interrupt request register 2
Rev.1.00 Jan 14, 2005
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APPENDIX
3804 Group (Spec.H)
3.5 Control registers
Interrupt control register 1
b7 b6 b5 b4 b3 b2 b1 b0
Interrupt control register 1
(ICON1 : address 003E16)
b
Name
Functions
At reset R W
0 INT0/Timer Z
interrupt enable bit
1 INT1 interrupt
enable bit
2 Serial I/O1 receive
interrupt enable bit
3 Serial I/O1
transmit/SCL, SDA
interrupt enable bit
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0
4 Timer X interrupt
enable bit
5 Timer Y interrupt
enable bit
6 Timer 1 interrupt
enable bit
Timer
2 interrupt
7
enable bit
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0
0
0
0
0
0
0
Fig. 3.5.41 Structure of Interrupt control register 1
Interrupt control register 2
b7 b6 b5 b4 b3 b2 b1 b0
0
Interrupt control register 2
(ICON2 : address 003F16)
b
Name
Functions
At reset R W
0 CNTR0 interrupt
enable bit
CNTR
1/ Serial I/O3
1
receive interrupt
enable bit
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0
2 Serial I/O2/ Timer Z
interrupt enable bit
3 INT2 interrupt
enable bit
4 INT3 interrupt
enable bit
5 INT4/CNTR2
interrupt enable bit
AD
converter/Serial
6
I/O3 transmit
interrupt enable bit
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
0
0 : Interrupt disabled
1 : Interrupt enabled
0 : Interrupt disabled
1 : Interrupt enabled
0
7 Fix this bit to “0”.
0
0
0
0
0
Fig. 3.5.42 Structure of Interrupt control register 2
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APPENDIX
3804 Group (Spec.H)
3.5 Control registers
Flash memory control register 0
b7 b6 b5 b4 b3 b2 b1 b0
Flash memory control register 0
(FMCR0 : address 0FE016)
b
Name
Functions
At reset R W
0 : Busy (being automatic written
or automatic erased)
1 : Ready
1
1 CPU rewrite mode
select bit (Note 1)
0
2
0 : CPU rewrite mode invalid
(software commandes invalid)
1 : CPU rewrite mode valid
(Software commands
acceptable)
8 KB user block E/W 0: E/W disabled
enable bit (Notes 1, 1: E/W enabled
2)
Flash memory reset 0: Normal operation
bit (Note 3)
1: Reset
Not used (Do not write “1” to this bit.)
User ROM area
0: User ROM area is accessed
select bit
1: Boot ROM area is accessed
Program status flag 0: Pass
1: Error
Erase status flag
0: Pass
1: Error
0
0 RY/BY status flag
3
4
5
6
7
0
0
0
0
0
Notes 1: For this bit to be set to “1”, the user needs to write a “0” and then a
“1” to it in succession. For this bit to be set to “0”, write “0” only to
this bit.
2: This bit can be written only when the CPU rewrite mode select bit
is “1”.
3: Effective only when the CPU rewrite mode select bit = “1”. Fix this
bit to “0” when the CPU rewrite mode select bit is “0”.
4: When setting this bit to “1” (when the control circuit of flash memory
is reset), the flash memory cannot be accessed for 10 µs.
5: Write to this bit from program on RAM.
Fig. 3.5.43 Structure of Flash memory control register 0
Rev.1.00 Jan 14, 2005
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APPENDIX
3804 Group (Spec.H)
3.5 Control registers
Flash memory control register 1
b7 b6 b5 b4 b3 b2 b1 b0
Flash memory control register 1
(FMCR1 : address 0FE116)
b
Name
Functions
At reset R W
0 : Suspend invalid
0 Erase suspend
enable bit (Note 1) 1 : Suspend valid
1 Erase suspend
0 : Erase restart (no
request issued)
request bit (Note 2)
1 : Suspend request
(request issued)
2 Nothing is arranged for these bits. If writing to
3 these bits, write “0”. The contents are undefined
4 at reading.
5
0 : Erase active
6 Erase suspend flag
1 : Erase inactive (Erase
suspend mode)
0
7 Nothing is arranged for these bits. If writing to
these bits, write “0”. The contents are undefined
at reading.
0
0
0
0
0
0
1
Notes 1: For this bit to be set to “1”, the user needs to write a “0” and then
a “1” to it in succession.
2: Only when the erase suspend bit is “1”, this bit is valid.
Fig. 3.5.44 Structure of Flash memory control register 1
Flash memory control register 2
b7 b6 b5 b4 b3 b2 b1 b0
Flash memory control register 2
(FMCR2 : address 0FE216)
b
0
1
2
3
4
Name
Functions
Nothing is arranged for these bits. If writing to
these bits, write “0”. The contents are undefined
at reading.
At reset R W
1
0
1
0
0
All user block E/W
0 : E/W disabled
enable bit (Notes 1, 2) 1 : E/W enabled
0
5 Nothing is arranged for these bits. If writing to
6 these bits, write “0”. The contents are undefined
1
7 at reading.
0
Notes 1: For this bit to be set to “1”, the user needs to write a “0” and then
a “1” to it in succession.
2: Effective only when the CPU rewrite mode select bit = “1”.
Fig. 3.5.45 Structure of Flash memory control register 2
Rev.1.00 Jan 14, 2005
REJ09B0212-0100Z
3-77
APPENDIX
3804 Group (Spec.H)
3.5 Control registers
Port Pi pull-up control register (i = 0 to 2, 4 to 6)
b7 b6 b5 b4 b3 b2 b1 b0
Port Pi pull-up control register (i = 0 to 2, 4 to 6)
(PULLi: addresses 0FF016, 0FF116, 0FF216, 0FF416, 0FF516, 0FF616)
b
Name
0 Port Pi0 pull-up
control bit
1 Port Pi1 pull-up
control bit
2 Port Pi2 pull-up
control bit
3 Port Pi3 pull-up
control bit
4 Port Pi4 pull-up
control bit
5 Port Pi5 pull-up
control bit
6 Port Pi6 pull-up
control bit
7 Port Pi7 pull-up
control bit
Functions
0: No pull-up
1: Pull-up
0: No pull-up
1: Pull-up
0: No pull-up
1: Pull-up
0: No pull-up
1: Pull-up
0: No pull-up
1: Pull-up
0: No pull-up
1: Pull-up
0: No pull-up
1: Pull-up
0: No pull-up
1: Pull-up
At reset R W
0
0
0
0
0
0
0
0
Fig. 3.5.46 Structure of Port Pi pull-up control register (i = 0 to 2, 4 to 6)
Port P3 pull-up control register
b7 b6 b5 b4 b3 b2 b1 b0
Port P3 pull-up control register
(PULL3: address 0FF316)
b
Name
Functions
0: No pull-up
0 Port P30 pull-up
control bit
1: Pull-up
0: No pull-up
1 Port P31 pull-up
control bit
1: Pull-up
2 Nothing is arranged for these bits. These are
write disabled bits. When these bits are read
3 out, the contents are “0”.
0: No pull-up
4 Port P34 pull-up
control bit
1: Pull-up
5 Port P35 pull-up
0: No pull-up
control bit
1: Pull-up
0: No pull-up
6 Port P36 pull-up
control bit
1: Pull-up
7 Port P37 pull-up
0: No pull-up
control bit
1: Pull-up
At reset R W
0
0
0
0
0
0
0
0
0
Fig. 3.5.47 Structure of Port P3 pull-up control register
Rev.1.00 Jan 14, 2005
REJ09B0212-0100Z
3-78
APPENDIX
3804 Group (Spec.H)
3.5 Control registers
I2C slave address register i (i = 0 to 2)
b7 b6 b5 b4 b3 b2 b1 b0
I2C slave address register i (i = 0 to 2)
(S0D0, S0D1, S0D2: addresses 0FF716, 0FF816, 0FF916)
b
Name
0 Read/Write bit
(RWB)
Functions
0: Write bit
1: Read bit
At reset R W
0
1 Slave address
0
The contents of these bits
2 (SAD0, SAD1, SAD2, are compared with the
0
3 SAD3, SAD4, SAD5, address data transmitted
0
from master.
4 SAD6)
0
5
0
6
0
7
0
Note: When the read-modify-write instructions (SEB, CLB) are used at
detection of stop condition, the values may be undefined.
Fig. 3.5.48 Structure of I 2C slave address register i (i = 0 to 2)
Rev.1.00 Jan 14, 2005
REJ09B0212-0100Z
3-79
APPENDIX
3804 Group (Spec.H)
3.6 Package outline
3.6 Package outline
64P6N-A
Plastic 64pin 14✕14mm body QFP
EIAJ Package Code
QFP64-P-1414-0.80
Weight(g)
1.11
Lead Material
Alloy 42
MD
e
JEDEC Code
–
HD
49
b2
64
ME
D
1
48
I2
HE
E
Recommended Mount Pad
Symbol
A
A1
A2
b
c
D
E
e
HD
HE
L
L1
y
33
16
A
32
L1
c
A2
17
F
e
A1
b
y
b2
I2
MD
ME
L
Detail F
64P4B
Dimension in Millimeters
Min
Nom
Max
–
–
3.05
0.1
0.2
0
–
–
2.8
0.3
0.35
0.45
0.13
0.15
0.2
13.8
14.0
14.2
13.8
14.0
14.2
–
0.8
–
16.5
16.8
17.1
16.5
16.8
17.1
0.4
0.6
0.8
1.4
–
–
0.1
–
–
0°
10°
–
–
–
0.5
1.3
–
–
–
–
14.6
–
–
14.6
Plastic 64pin 750mil SDIP
JEDEC Code
–
Weight(g)
7.9
Lead Material
Alloy 42/Cu Alloy
33
1
32
E
64
e1
c
EIAJ Package Code
SDIP64-P-750-1.78
Symbol
A1
L
A
A2
D
e
SEATING PLANE
Rev.1.00 Jan 14, 2005
REJ09B0212-0100Z
b1
b
b2
A
A1
A2
b
b1
b2
c
D
E
e
e1
L
Dimension in Millimeters
Min
Nom
Max
–
–
5.08
0.38
–
–
–
3.8
–
0.4
0.5
0.59
0.9
1.0
1.3
0.65
0.75
1.05
0.2
0.25
0.32
56.2
56.4
56.6
16.85
17.0
17.15
–
1.778
–
–
19.05
–
2.8
–
–
0°
–
15°
3-80
APPENDIX
3804 Group (Spec.H)
3.6 Package outline
64P6Q-A
Plastic 64pin 10✕10mm body LQFP
Weight(g)
Lead Material
Cu Alloy
MD
ME
JEDEC Code
—
e
EIAJ Package Code
LQFP64-P-1010-0.5
b2
HD
D
48
33
49
I2
Recommended Mount Pad
32
A
A1
A2
b
c
D
E
e
HD
HE
L
L1
Lp
HE
E
Symbol
17
64
1
16
A
F
e
x
L
M
Detail F
x
y
c
A1
y
b
A3
A3
A2
L1
b2
I2
MD
ME
Lp
64P6U-A
Dimension in Millimeters
Min
Nom
Max
—
—
1.7
0.1
0.2
0
—
—
1.4
0.13
0.18
0.28
0.105
0.125
0.175
9.9
10.0
10.1
9.9
10.0
10.1
—
0.5
—
11.8
12.0
12.2
11.8
12.0
12.2
0.3
0.5
0.7
1.0
—
—
0.75
0.6
0.45
—
0.25
—
0.08
—
—
0.1
—
—
0¡
10¡
—
0.225
—
—
—
—
1.0
—
—
10.4
—
—
10.4
Plastic 64pin 14✕14mm body LQFP
EIAJ Package Code
LQFP64-P-1414-0.8
Weight(g)
Lead Material
Cu Alloy
MD
e
JEDEC Code
—
D
48
ME
b2
HD
33
l2
49
32
Recommended Mount Pad
64
A
A1
A2
b
c
D
E
e
HD
HE
L
L1
Lp
HE
E
Symbol
17
1
A
16
L1
F
A3
A2
e
A3
x
M
c
b
A1
y
L
x
y
Lp
Detail F
Rev.1.00 Jan 14, 2005
REJ09B0212-0100Z
b2
I2
MD
ME
Dimension in Millimeters
Min
Nom
Max
—
—
1.7
0.1
0.2
0
1.4
—
—
0.32
0.37
0.45
0.105
0.125
0.175
13.9
14.1
14.0
13.9
14.1
14.0
0.8
—
—
16.0
15.8
16.2
15.8
16.2
16.0
0.3
0.5
0.7
1.0
—
—
0.75
0.6
0.45
—
0.25
—
—
—
0.2
0.1
—
—
0¡
8¡
—
0.5
—
—
—
—
0.95
—
14.4
—
—
—
14.4
3-81
APPENDIX
3804 Group (Spec.H)
3.7 Machine instructions
3.7 Machine instructions
Addressing mode
Symbol
Function
Details
IMP
OP n
ADC
(Note 1)
(Note 5)
When T = 0
A←A+M+C
When T = 1
M(X) ← M(X) + M + C
AND
(Note 1)
When TV= 0
A←A M
When T = 1 V
M(X) ← M(X) M
7
ASL
C←
0
←0
IMM
# OP n
A
# OP n
BIT,A,AR
BIT,
# OP n
ZP
# OP n
BIT,ZP,
ZPR
BIT,
# OP n
When T = 0, this instruction adds the contents
M, C, and A; and stores the results in A and C.
When T = 1, this instruction adds the contents
of M(X), M and C; and stores the results in
M(X) and C. When T=1, the contents of A remain unchanged, but the contents of status
flags are changed.
M(X) represents the contents of memory
where is indicated by X.
69 2
2
65 3
2
When T = 0, this instruction transfers the contents of A and M to the ALU which performs a
bit-wise AND operation and stores the result
back in A.
When T = 1, this instruction transfers the contents M(X) and M to the ALU which performs a
bit-wise AND operation and stores the results
back in M(X). When T = 1, the contents of A
remain unchanged, but status flags are
changed.
M(X) represents the contents of memory
where is indicated by X.
29 2
2
25 3
2
06 5
2
This instruction shifts the content of A or M by
one bit to the left, with bit 0 always being set to
0 and bit 7 of A or M always being contained in
C.
0A 2
1
#
BBC
(Note 4)
Ai or Mi = 0?
This instruction tests the designated bit i of M
or A and takes a branch if the bit is 0. The
branch address is specified by a relative address. If the bit is 1, next instruction is
executed.
13 4
+
20i
2
17 5
+
20i
3
BBS
(Note 4)
Ai or Mi = 1?
This instruction tests the designated bit i of the
M or A and takes a branch if the bit is 1. The
branch address is specified by a relative address. If the bit is 0, next instruction is
executed.
03 4
+
20i
2
07 5
+
20i
3
BCC
(Note 4)
C = 0?
This instruction takes a branch to the appointed address if C is 0. The branch address
is specified by a relative address. If C is 1, the
next instruction is executed.
BCS
(Note 4)
C = 1?
This instruction takes a branch to the appointed address if C is 1. The branch address
is specified by a relative address. If C is 0, the
next instruction is executed.
BEQ
(Note 4)
Z = 1?
This instruction takes a branch to the appointed address when Z is 1. The branch
address is specified by a relative address.
If Z is 0, the next instruction is executed.
BIT
A
BMI
(Note 4)
N = 1?
This instruction takes a branch to the appointed address when N is 1. The branch
address is specified by a relative address.
If N is 0, the next instruction is executed.
BNE
(Note 4)
Z = 0?
This instruction takes a branch to the appointed address if Z is 0. The branch address
is specified by a relative address. If Z is 1, the
next instruction is executed.
V
M
Rev.1.00 Jan 14, 2005
REJ09B0212-0100Z
This instruction takes a bit-wise logical AND of
A and M contents; however, the contents of A
and M are not modified.
The contents of N, V, Z are changed, but the
contents of A, M remain unchanged.
24 3
2
3-82
APPENDIX
3804 Group (Spec.H)
3.7 Machine instructions
Addressing mode
ZP, X
ZP, Y
OP n
# OP n
75 4
ABS
ABS, X
ABS, Y
IND
# OP n
# OP n
# OP n
# OP n
2
6D 4
3 7D 5
3 79 5
35 4
2
2D 4
3 3D 5
3 39 5
16 6
2
0E 6
3 1E 7
3
2C 4
Rev.1.00 Jan 14, 2005
REJ09B0212-0100Z
Processor status register
ZP, IND
# OP n
IND, X
IND, Y
REL
SP
# OP n
#
7
6
5
4
3
2
1
0
N
V
T
B
D
I
Z
C
# OP n
# OP n
# OP n
3
61 6
2 71 6
2
N
V
•
•
•
•
Z
C
3
21 6
2 31 6
2
N
•
•
•
•
•
Z
•
N
•
•
•
•
•
Z
C
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
90 2
2
•
•
•
•
•
•
•
•
B0 2
2
•
•
•
•
•
•
•
•
F0 2
2
•
•
•
•
•
•
•
•
M7 M6 •
•
•
•
Z
•
3
30 2
2
•
•
•
•
•
•
•
•
D0 2
2
•
•
•
•
•
•
•
•
3-83
APPENDIX
3804 Group (Spec.H)
3.7 Machine instructions
Addressing mode
Symbol
Function
Details
IMP
IMM
OP n
# OP n
00 7
1
BPL
(Note 4)
N = 0?
This instruction takes a branch to the appointed address if N is 0. The branch address
is specified by a relative address. If N is 1, the
next instruction is executed.
BRA
PC ← PC ± offset
This instruction branches to the appointed address. The branch address is specified by a
relative address.
BRK
B←1
(PC) ← (PC) + 2
M(S) ← PCH
S←S–1
M(S) ← PCL
S←S–1
M(S) ← PS
S←S–1
I← 1
PCL ← ADL
PCH ← ADH
When the BRK instruction is executed, the
CPU pushes the current PC contents onto the
stack. The BADRS designated in the interrupt
vector table is stored into the PC.
BVC
(Note 4)
V = 0?
This instruction takes a branch to the appointed address if V is 0. The branch address
is specified by a relative address. If V is 1, the
next instruction is executed.
BVS
(Note 4)
V = 1?
This instruction takes a branch to the appointed address when V is 1. The branch
address is specified by a relative address.
When V is 0, the next instruction is executed.
CLB
Ai or Mi ← 0
This instruction clears the designated bit i of A
or M.
CLC
C←0
This instruction clears C.
18 2
1
CLD
D←0
This instruction clears D.
D8 2
1
CLI
I←0
This instruction clears I.
58 2
1
CLT
T←0
This instruction clears T.
12 2
1
CLV
V←0
This instruction clears V.
B8 2
1
CMP
(Note 3)
When T = 0
A–M
When T = 1
M(X) – M
When T = 0, this instruction subtracts the contents of M from the contents of A. The result is
not stored and the contents of A or M are not
modified.
When T = 1, the CMP subtracts the contents
of M from the contents of M(X). The result is
not stored and the contents of X, M, and A are
not modified.
M(X) represents the contents of memory
where is indicated by X.
COM
M←M
This instruction takes the one’s complement of
the contents of M and stores the result in M.
CPX
X–M
This instruction subtracts the contents of M
from the contents of X. The result is not stored
and the contents of X and M are not modified.
E0 2
CPY
Y–M
This instruction subtracts the contents of M
from the contents of Y. The result is not stored
and the contents of Y and M are not modified.
C0 2
DEC
A ← A – 1 or
M←M–1
This instruction subtracts 1 from the contents
of A or M.
__
Rev.1.00 Jan 14, 2005
REJ09B0212-0100Z
A
# OP n
BIT, A
# OP n
1B 2
+
20i
C9 2
ZP
# OP n
BIT, ZP
# OP n
#
1F 5
+
20i
2
1
C5 3
2
44 5
2
2
E4 3
2
2
C4 3
2
C6 5
2
2
1A 2
1
3-84
APPENDIX
3804 Group (Spec.H)
3.7 Machine instructions
Addressing mode
ZP, X
OP n
D5 4
D6 6
ZP, Y
# OP n
2
2
ABS
# OP n
CD 4
ABS, X
# OP n
3 DD 5
ABS, Y
# OP n
3 D9 5
IND
# OP n
3
Processor status register
ZP, IND
# OP n
IND, X
# OP n
C1 6
IND, Y
# OP n
2 D1 6
REL
# OP n
2
SP
# OP n
#
7
6
5
4
3
2
1
0
N
V
T
B
D
I
Z
C
10 2
2
•
•
•
•
•
•
•
•
80 4
2
•
•
•
•
•
•
•
•
•
•
•
1
•
1
•
•
50 2
2
•
•
•
•
•
•
•
•
70 2
2
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
0
•
•
•
•
0
•
•
•
•
•
•
•
•
0
•
•
•
•
0
•
•
•
•
•
•
0
•
•
•
•
•
•
N
•
•
•
•
•
Z
C
N
•
•
•
•
•
Z
•
EC 4
3
N
•
•
•
•
•
Z
C
CC 4
3
N
•
•
•
•
•
Z
C
CE 6
3 DE 7
N
•
•
•
•
•
Z
•
Rev.1.00 Jan 14, 2005
REJ09B0212-0100Z
3
3-85
APPENDIX
3804 Group (Spec.H)
3.7 Machine instructions
Addressing mode
Symbol
Function
Details
IMP
OP n
IMM
# OP n
DEX
X←X–1
This instruction subtracts one from the current CA 2
contents of X.
1
DEY
Y←Y–1
This instruction subtracts one from the current
contents of Y.
88 2
1
DIV
A ← (M(zz + X + 1),
M(zz + X )) / A
M(S) ← one's complement of Remainder
S←S–1
This instruction divides the 16-bit data in
M(zz+(X)) (low-order byte) and M(zz+(X)+1)
(high-order byte) by the contents of A. The
quotient is stored in A and the one's complement of the remainder is pushed onto the stack.
EOR
(Note 1)
When T = 0
–M
A←AV
When T = 0, this instruction transfers the contents of the M and A to the ALU which
performs a bit-wise Exclusive OR, and stores
the result in A.
When T = 1, the contents of M(X) and M are
transferred to the ALU, which performs a bitwise Exclusive OR and stores the results in
M(X). The contents of A remain unchanged,
but status flags are changed.
M(X) represents the contents of memory
where is indicated by X.
When T = 1
–M
M(X) ← M(X) V
49 2
A
# OP n
BIT, A
# OP n
2
ZP
# OP n
BIT, ZP
# OP n
45 3
2
E6 5
2
A5 3
2
3C 4
3
INC
A ← A + 1 or
M←M+1
This instruction adds one to the contents of A
or M.
INX
X←X+1
This instruction adds one to the contents of X.
E8 2
1
INY
Y←Y+1
This instruction adds one to the contents of Y.
C8 2
1
JMP
If addressing mode is ABS
PCL ← ADL
PCH ← ADH
If addressing mode is IND
PCL ← M (ADH, ADL)
PCH ← M (ADH, ADL + 1)
If addressing mode is ZP, IND
PCL ← M(00, ADL)
PCH ← M(00, ADL + 1)
This instruction jumps to the address designated by the following three addressing
modes:
Absolute
Indirect Absolute
Zero Page Indirect Absolute
JSR
M(S) ← PCH
S←S–1
M(S) ← PCL
S←S–1
After executing the above,
if addressing mode is ABS,
PCL ← ADL
PCH ← ADH
if addressing mode is SP,
PCL ← ADL
PCH ← FF
If addressing mode is ZP, IND,
PCL ← M(00, ADL)
PCH ← M(00, ADL + 1)
This instruction stores the contents of the PC
in the stack, then jumps to the address designated by the following addressing modes:
Absolute
Special Page
Zero Page Indirect Absolute
LDA
(Note 2)
When T = 0
A←M
When T = 1
M(X) ← M
When T = 0, this instruction transfers the contents of M to A.
When T = 1, this instruction transfers the contents of M to (M(X)). The contents of A remain
unchanged, but status flags are changed.
M(X) represents the contents of memory
where is indicated by X.
LDM
M ← nn
This instruction loads the immediate value in
M.
LDX
X←M
This instruction loads the contents of M in X.
A2 2
2
A6 3
2
LDY
Y←M
This instruction loads the contents of M in Y.
A0 2
2
A4 3
2
Rev.1.00 Jan 14, 2005
REJ09B0212-0100Z
3A 2
A9 2
2
1
#
3-86
APPENDIX
3804 Group (Spec.H)
3.7 Machine instructions
Addressing mode
ZP, X
OP n
ZP, Y
# OP n
ABS
# OP n
ABS, X
# OP n
ABS, Y
# OP n
IND
# OP n
Processor status register
ZP, IND
# OP n
IND, X
# OP n
IND, Y
# OP n
REL
# OP n
SP
# OP n
#
E2 16 2
55 4
2
4D 4
3 5D 5
3 59 5
F6 6
2
EE 6
3 FE 7
3
B5 4
2
B6 4
B4 4
2
4C 3
3
20 6
3
AD 4
3 BD 5
2 AE 4
AC 4
Rev.1.00 Jan 14, 2005
REJ09B0212-0100Z
41 6
6C 5
3 B9 5
3
3 BC 5
3
BE 5
3
3
3
3 B2 4
2
02 7
2
2 51 6
2
22 5
A1 6
2 B1 6
2
2
7
6
5
4
3
2
1
0
N
V
T
B
D
I
Z
C
N
•
•
•
•
•
Z
•
N
•
•
•
•
•
Z
•
•
•
•
•
•
•
•
•
N
•
•
•
•
•
Z
•
N
•
•
•
•
•
Z
•
N
•
•
•
•
•
Z
•
N
•
•
•
•
•
Z
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
N
•
•
•
•
•
Z
•
•
•
•
•
•
•
•
•
N
•
•
•
•
•
Z
•
N
•
•
•
•
•
Z
•
3-87
APPENDIX
3804 Group (Spec.H)
3.7 Machine instructions
Addressing mode
Symbol
Function
Details
IMP
OP n
LSR
7
0→
0
→C
This instruction multiply Accumulator with the
memory specified by the Zero Page X address
mode and stores the high-order byte of the result on the Stack and the low-order byte in A.
NOP
PC ← PC + 1
This instruction adds one to the PC but does EA 2
no other operation.
ORA
(Note 1)
When T = 0
A←AVM
When T = 0, this instruction transfers the contents of A and M to the ALU which performs a
bit-wise “OR”, and stores the result in A.
When T = 1, this instruction transfers the contents of M(X) and the M to the ALU which
performs a bit-wise OR, and stores the result
in M(X). The contents of A remain unchanged,
but status flags are changed.
M(X) represents the contents of memory
where is indicated by X.
PHP
PLA
PLP
ROL
# OP n
1
ZP
# OP n
BIT, ZP
# OP n
46 5
2
05 3
2
09 2
2
48 3
1
M(S) ← PS
S←S–1
This instruction pushes the contents of PS to
the memory location designated by S and decrements the contents of S by one.
08 3
1
S←S+1
A ← M(S)
This instruction increments S by one and
stores the contents of the memory designated
by S in A.
68 4
1
S←S+1
PS ← M(S)
This instruction increments S by one and
stores the contents of the memory location
designated by S in PS.
28 4
1
7
←
This instruction shifts either A or M one bit left
through C. C is stored in bit 0 and bit 7 is
stored in C.
2A 2
1
26 5
2
This instruction shifts either A or M one bit
right through C. C is stored in bit 7 and bit 0 is
stored in C.
6A 2
1
66 5
2
82 8
2
0
←C ←
RRF
7
→
0
→
0
→
This instruction rotates 4 bits of the M content
to the right.
S←S+1
PS ← M(S)
S←S+1
PCL ← M(S)
S←S+1
PCH ← M(S)
This instruction increments S by one, and
stores the contents of the memory location
designated by S in PS. S is again incremented
by one and stores the contents of the memory
location designated by S in PC L . S is again
incremented by one and stores the contents of
memory location designated by S in PCH.
S←S+1
PCL ← M(S)
S←S+1
PCH ← M(S)
(PC) ← (PC) + 1
This instruction increments S by one and
stores the contents of the memory location
d e s i g n a t e d b y S i n P C L. S i s a g a i n
incremented by one and the contents of the
memory location is stored in PC H . PC is
incremented by 1.
Rev.1.00 Jan 14, 2005
REJ09B0212-0100Z
#
1
This instruction pushes the contents of A to
the memory location designated by S, and
decrements the contents of S by one.
7
C→
RTS
BIT, A
M(S) ← A
S←S–1
ROR
RTI
# OP n
4A 2
M(S) • A ← A ✽ M(zz + X)
S←S–1
PHA
# OP n
A
This instruction shifts either A or M one bit to
the right such that bit 7 of the result always is
set to 0, and the bit 0 is stored in C.
MUL
When T = 1
M(X) ← M(X) V M
IMM
40 6
1
60 6
1
3-88
APPENDIX
3804 Group (Spec.H)
3.7 Machine instructions
Addressing mode
ZP, X
ZP, Y
OP n
# OP n
56 6
2
ABS
ABS, X
ABS, Y
# OP n
# OP n
# OP n
4E 6
3 5E 7
3
IND
# OP n
Processor status register
ZP, IND
# OP n
IND, X
# OP n
IND, Y
# OP n
# OP n
62 15 2
15 4
2
0D 4
3 1D 5
3 19 5
3
01 6
2 11 6
REL
2
SP
# OP n
#
7
6
5
4
3
2
1
0
N
V
T
B
D
I
Z
C
0
•
•
•
•
•
Z
C
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
N
•
•
•
•
•
Z
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
N
•
•
•
•
•
Z
•
(Value saved in stack)
36 6
2
2E 6
3 3E 7
3
N
•
•
•
•
•
Z
C
76 6
2
6E 6
3 7E 7
3
N
•
•
•
•
•
Z
C
•
•
•
•
•
•
•
•
(Value saved in stack)
•
Rev.1.00 Jan 14, 2005
REJ09B0212-0100Z
•
•
•
•
•
•
•
3-89
APPENDIX
3804 Group (Spec.H)
3.7 Machine instructions
Addressing mode
Symbol
Function
Details
IMP
OP n
SBC
(Note 1)
(Note 5)
When T = 0 _
A←A–M–C
When T = 1
_
M(X) ← M(X) – M – C
IMM
# OP n
E9 2
When T = 0, this instruction subtracts the
value of M and the complement of C from A,
and stores the results in A and C.
When T = 1, the instruction subtracts the contents of M and the complement of C from the
contents of M(X), and stores the results in
M(X) and C.
A remain unchanged, but status flag are
changed.
M(X) represents the contents of memory
where is indicated by X.
SEB
Ai or Mi ← 1
This instruction sets the designated bit i of A
or M.
SEC
C←1
This instruction sets C.
38 2
1
SED
D←1
This instruction set D.
F8 2
1
SEI
I←1
This instruction set I.
78 2
1
SET
T←1
This instruction set T.
32 2
1
STA
M←A
This instruction stores the contents of A in M.
The contents of A does not change.
This instruction resets the oscillation control F/
F and the oscillation stops. Reset or interrupt
input is needed to wake up from this mode.
STP
A
# OP n
BIT, A
# OP n
# OP n
E5 3
2
0B 2
+
20i
42 2
ZP
BIT, ZP
# OP n
2
1
0F 5
+
20i
85 4
2
M←X
This instruction stores the contents of X in M.
The contents of X does not change.
86 4
2
STY
M←Y
This instruction stores the contents of Y in M.
The contents of Y does not change.
84 4
2
TAX
X←A
This instruction stores the contents of A in X.
The contents of A does not change.
AA 2
1
TAY
Y←A
This instruction stores the contents of A in Y.
The contents of A does not change.
A8 2
1
TST
M = 0?
This instruction tests whether the contents of
M are “0” or not and modifies the N and Z.
64 3
2
TSX
X←S
This instruction transfers the contents of S in BA 2
X.
1
TXA
A←X
This instruction stores the contents of X in A.
8A 2
1
TXS
S←X
This instruction stores the contents of X in S.
9A 2
1
TYA
A←Y
This instruction stores the contents of Y in A.
98 2
1
The WIT instruction stops the internal clock
but not the oscillation of the oscillation circuit
is not stopped.
CPU starts its function after the Timer X over
flows (comes to the terminal count). All registers or internal memory contents except Timer
X will not change during this mode. (Of course
needs VDD).
C2 2
1
Notes 1
2
3
4
5
:
:
:
:
:
2
1
STX
WIT
#
The number of cycles “n” is increased by 3 when T is 1.
The number of cycles “n” is increased by 2 when T is 1.
The number of cycles “n” is increased by 1 when T is 1.
The number of cycles “n” is increased by 2 when branching has occurred.
N, V, and Z flags are invalid in decimal operation mode.
Rev.1.00 Jan 14, 2005
REJ09B0212-0100Z
3-90
APPENDIX
3804 Group (Spec.H)
3.7 Machine instructions
Addressing mode
ZP, X
ZP, Y
OP n
# OP n
F5 4
2
95 5
2
ABS, X
ABS, Y
IND
# OP n
# OP n
# OP n
# OP n
ED 4
3 FD 5
3 F9 5
3
8D 5
2
96 5
94 5
ABS
3 9D 6
3 99 6
3
Processor status register
ZP, IND
# OP n
IND, X
IND, Y
REL
# OP n
# OP n
# OP n
E1 6
2 F1 6
2
81 7
2 91 7
2
SP
# OP n
#
7
6
5
4
3
2
1
0
N
V
T
B
D
I
Z
C
N
V
•
•
•
•
Z
C
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
1
•
•
•
•
1
•
•
•
•
•
•
•
•
1
•
•
•
•
1
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
2 8E 5
3
•
•
•
•
•
•
•
•
8C 5
3
•
•
•
•
•
•
•
•
N
•
•
•
•
•
Z
•
N
•
•
•
•
•
Z
•
N
•
•
•
•
•
Z
•
N
•
•
•
•
•
Z
•
N
•
•
•
•
•
Z
•
•
•
•
•
•
•
•
•
N
•
•
•
•
•
Z
•
•
•
•
•
•
•
•
•
Rev.1.00 Jan 14, 2005
REJ09B0212-0100Z
3-91
APPENDIX
3804 Group (Spec.H)
Symbol
3.7 Machine instructions
Contents
IMP
IMM
A
BIT, A
BIT, A, R
ZP
BIT, ZP
BIT, ZP, R
ZP, X
ZP, Y
ABS
ABS, X
ABS, Y
IND
Implied addressing mode
Immediate addressing mode
Accumulator or Accumulator addressing mode
Accumulator bit addressing mode
Accumulator bit relative addressing mode
Zero page addressing mode
Zero page bit addressing mode
Zero page bit relative addressing mode
Zero page X addressing mode
Zero page Y addressing mode
Absolute addressing mode
Absolute X addressing mode
Absolute Y addressing mode
Indirect absolute addressing mode
ZP, IND
Zero page indirect absolute addressing mode
IND, X
IND, Y
REL
SP
C
Z
I
D
B
T
V
N
Indirect X addressing mode
Indirect Y addressing mode
Relative addressing mode
Special page addressing mode
Carry flag
Zero flag
Interrupt disable flag
Decimal mode flag
Break flag
X-modified arithmetic mode flag
Overflow flag
Negative flag
Symbol
+
–
✽
/
V
V
–
V
–
←
X
Y
S
PC
PS
PCH
PCL
ADH
ADL
FF
nn
zz
M
M(X)
M(S)
M(ADH, ADL)
M(00, ADL)
Ai
Mi
OP
n
#
Rev.1.00 Jan 14, 2005
REJ09B0212-0100Z
Contents
Addition
Subtraction
Multiplication
Division
Logical OR
Logical AND
Logical exclusive OR
Negation
Shows direction of data flow
Index register X
Index register Y
Stack pointer
Program counter
Processor status register
8 high-order bits of program counter
8 low-order bits of program counter
8 high-order bits of address
8 low-order bits of address
FF in Hexadecimal notation
Immediate value
Zero page address
Memory specified by address designation of any addressing mode
Memory of address indicated by contents of index
register X
Memory of address indicated by contents of stack
pointer
Contents of memory at address indicated by ADH and
ADL, in ADH is 8 high-order bits and ADL is 8 low-order bits.
Contents of address indicated by zero page ADL
Bit i (i = 0 to 7) of accumulator
Bit i (i = 0 to 7) of memory
Opcode
Number of cycles
Number of bytes
3-92
APPENDIX
3804 Group (Spec.H)
3.8 List of instruction code
3.8 List of instruction code
D7 – D4
D3 – D0
0000
0001
0010
0011
0100
0101
0110
0111
1000
1001
1010
1011
1100
1101
1110
1111
Hexadecimal
notation
0
1
2
3
4
5
6
7
8
9
A
B
C
D
E
F
ORA
ABS
ASL
ABS
SEB
0, ZP
0000
0
BRK
BBS
ORA
JSR
IND, X ZP, IND 0, A
—
ORA
ZP
ASL
ZP
BBS
0, ZP
PHP
ORA
IMM
ASL
A
SEB
0, A
—
0001
1
BPL
ORA
IND, Y
CLT
BBC
0, A
—
ORA
ZP, X
ASL
ZP, X
BBC
0, ZP
CLC
ORA
ABS, Y
DEC
A
CLB
0, A
—
0010
2
JSR
ABS
AND
IND, X
JSR
SP
BBS
1, A
BIT
ZP
AND
ZP
ROL
ZP
BBS
1, ZP
PLP
AND
IMM
ROL
A
SEB
1, A
BIT
ABS
0011
3
BMI
AND
IND, Y
SET
BBC
1, A
—
AND
ZP, X
ROL
ZP, X
BBC
1, ZP
SEC
AND
ABS, Y
INC
A
CLB
1, A
ROL
CLB
AND
LDM
ZP ABS, X ABS, X 1, ZP
0100
4
RTI
EOR
IND, X
STP
BBS
2, A
COM
ZP
EOR
ZP
LSR
ZP
BBS
2, ZP
PHA
EOR
IMM
LSR
A
SEB
2, A
JMP
ABS
0101
5
BVC
EOR
IND, Y
—
BBC
2, A
—
EOR
ZP, X
LSR
ZP, X
BBC
2, ZP
CLI
EOR
ABS, Y
—
CLB
2, A
—
0110
6
RTS
MUL
ADC
IND, X ZP, X
BBS
3, A
TST
ZP
ADC
ZP
ROR
ZP
BBS
3, ZP
PLA
ADC
IMM
ROR
A
SEB
3, A
JMP
IND
0111
7
BVS
ADC
IND, Y
—
BBC
3, A
—
ADC
ZP, X
ROR
ZP, X
BBC
3, ZP
SEI
ADC
ABS, Y
—
CLB
3, A
—
1000
8
BRA
STA
IND, X
RRF
ZP
BBS
4, A
STY
ZP
STA
ZP
STX
ZP
BBS
4, ZP
DEY
—
TXA
SEB
4, A
STY
ABS
STA
ABS
STX
ABS
SEB
4, ZP
1001
9
BCC
STA
IND, Y
—
BBC
4, A
STY
ZP, X
STA
ZP, X
STX
ZP, Y
BBC
4, ZP
TYA
STA
ABS, Y
TXS
CLB
4, A
—
STA
ABS, X
—
CLB
4, ZP
1010
A
LDY
IMM
LDA
IND, X
LDX
IMM
BBS
5, A
LDY
ZP
LDA
ZP
LDX
ZP
BBS
5, ZP
TAY
LDA
IMM
TAX
SEB
5, A
LDY
ABS
LDA
ABS
LDX
ABS
SEB
5, ZP
1011
B
BCS
JMP
BBC
LDA
IND, Y ZP, IND 5, A
LDY
ZP, X
LDA
ZP, X
LDX
ZP, Y
BBC
5, ZP
CLV
LDA
ABS, Y
TSX
CLB
5, A
1100
C
CPY
IMM
CMP
IND, X
WIT
BBS
6, A
CPY
ZP
CMP
ZP
DEC
ZP
BBS
6, ZP
INY
CMP
IMM
DEX
SEB
6, A
CPY
ABS
1101
D
BNE
CMP
IND, Y
—
BBC
6, A
—
CMP
ZP, X
DEC
ZP, X
BBC
6, ZP
CLD
CMP
ABS, Y
—
CLB
6, A
—
1110
E
CPX
IMM
DIV
SBC
IND, X ZP, X
BBS
7, A
CPX
ZP
SBC
ZP
INC
ZP
BBS
7, ZP
INX
SBC
IMM
NOP
SEB
7, A
CPX
ABS
1111
F
BEQ
SBC
IND, Y
BBC
7, A
—
SBC
ZP, X
INC
ZP, X
BBC
7, ZP
SED
SBC
ABS, Y
—
CLB
7, A
—
—
ASL
CLB
ORA
ABS, X ABS, X 0, ZP
AND
ABS
EOR
ABS
ROL
ABS
LSR
ABS
SEB
1, ZP
SEB
2, ZP
LSR
CLB
EOR
ABS, X ABS, X 2, ZP
ADC
ABS
ROR
ABS
SEB
3, ZP
ROR
CLB
ADC
ABS, X ABS, X 3, ZP
LDX
CLB
LDY
LDA
ABS, X ABS, X ABS, Y 5, ZP
CMP
ABS
DEC
ABS
SEB
6, ZP
DEC
CLB
CMP
ABS, X ABS, X 6, ZP
SBC
ABS
INC
ABS
SEB
7, ZP
INC
CLB
SBC
ABS, X ABS, X 7, ZP
: 3-byte instruction
: 2-byte instruction
: 1-byte instruction
Rev.1.00 Jan 14, 2005
REJ09B0212-0100Z
3-93
APPENDIX
3804 Group (Spec.H)
3.9 SFR memory map
3.9 SFR memory map
000016
Port P0 (P0)
002016
Prescaler 12 (PRE12)
000116
Port P0 direction register (P0D)
002116
Timer 1 (T1)
000216
Port P1 (P1)
002216
Timer 2 (T2)
000316
Port P1 direction register (P1D)
002316
Timer XY mode register (TM)
000416
Port P2 (P2)
002416
Prescaler X (PREX)
000516
Port P2 direction register (P2D)
002516
Timer X (TX)
000616
Port P3 (P3)
002616
Prescaler Y (PREY)
000716
Port P3 direction register (P3D)
002716
Timer Y (TY)
000816
Port P4 (P4)
002816
Timer Z low-order (TZL)
000916
Port P4 direction register (P4D)
002916
Timer Z high-order (TZH)
000A16
Port P5 (P5)
002A16
Timer Z mode register (TZM)
000B16
Port P5 direction register (P5D)
002B16
PWM control register (PWMCON)
000C16
Port P6 (P6)
002C16
PWM prescaler (PREPWM)
000D16
Port P6 direction register (P6D)
002D16
PWM register (PWM)
000E16
Timer 12, X count source selection register (T12XCSS)
002E16
000F16
Timer Y, Z count source selection register (TYZCSS)
002F16
Baud rate generator 3 (BRG3)
001016
MISRG
003016
Transmit/Receive buffer register 3 (TB3/RB3)
001116
I2C data shift register (S0)
003116
Serial I/O3 status register (SIO3STS)
001216
I2C special mode status register (S3)
003216
Serial I/O3 control register (SIO3CON)
001316
I2C status register (S1)
003316
UART3 control register (UART3CON)
001416
I2C
control register (S1D)
003416
AD/DA control register (ADCON)
001516
I2C clock control register (S2)
003516
AD conversion register 1 (AD1)
001616
I2C START/STOP condition control register (S2D)
003616
DA1 conversion register (DA1)
001716
I2C special mode control register (S3D)
003716
DA2 conversion register (DA2)
001816
Transmit/Receive buffer register 1 (TB1/RB1)
003816
AD conversion register 2 (AD2)
001916
Serial I/O1 status register (SIO1STS)
003916
Interrupt source selection register (INTSEL)
001A16
Serial I/O1 control register (SIO1CON)
003A16
Interrupt edge selection register (INTEDGE)
001B16
UART1 control register (UART1CON)
003B16
CPU mode register (CPUM)
001C16
Baud rate generator 1 (BRG1)
003C16
Interrupt request register 1 (IREQ1)
001D16
Serial I/O2 control register (SIO2CON)
003D16
Interrupt request register 2 (IREQ2)
001E16
Watchdog timer control register (WDTCON)
003E16
Interrupt control register 1 (ICON1)
001F16
Serial I/O2 register (SIO2)
003F16
Interrupt control register 2 (ICON2)
0FE016
Flash memory control register 0 (FMCR0)
0FF016
Port P0 pull-up control register (PULL0)
0FE116
Flash memory control register 1 (FMCR1)
0FF116
Port P1 pull-up control register (PULL1)
0FE216
Flash memory control register 2 (FMCR2)
0FF216
Port P2 pull-up control register (PULL2)
0FE316
Reserved ✽
0FF316
Port P3 pull-up control register (PULL3)
0FE416
Reserved ✽
0FF416
Port P4 pull-up control register (PULL4)
0FE516
Reserved ✽
0FF516
Port P5 pull-up control register (PULL5)
0FE616
Reserved ✽
0FF616
Port P6 pull-up control register (PULL6)
0FE716
Reserved ✽
0FF716
I2C slave address register 0 (S0D0)
0FE816
Reserved ✽
0FF816
I2C slave address register 1 (S0D1)
0FE916
Reserved ✽
0FF916
I2C slave address register 2 (S0D2)
0FEA16
Reserved ✽
0FEB16
Reserved ✽
0FEC16
Reserved ✽
0FED16
Reserved ✽
0FEE16
Reserved ✽
0FEF16
Reserved ✽
Rev.1.00 Jan 14, 2005
REJ09B0212-0100Z
✽ Reserved area: Do not write any data to these addresses,
because these areas are reserved.
3-94
APPENDIX
3804 Group (Spec.H)
3.10 Pin configurations
3.10 Pin configurations
P15
P16
P17
34
33
36
35
P13
P14
37
P11/INT01
P12
P06/AN14
42
38
P05/AN13
43
40
P04/AN12
44
39
P03/AN11
45
P07/AN15
P10/INT41
P02/AN10
46
41
P00/AN8
P01/AN9
48
47
(TOP VIEW)
P37/SRDY3
49
32
P20(LED0)
P36/SCLK3
50
31
P21(LED1)
P35/TXD3
51
30
P22(LED2)
P34/RXD3
52
29
P23(LED3)
P33/SCL
53
28
P24(LED4)
P32/SDA
54
27
P25(LED5)
P31/DA2
55
26
P26(LED6)
P30/DA1
56
25
P27(LED7)
VCC
57
24
VSS
XOUT
M38049FFHFP/HP/KP
VREF
58
23
AVSS
59
22
XIN
P67/AN7
60
21
P40/INT40/XCOUT
16
P43/INT2
15
14
P45/TXD1
13
P46/SCLK1
P44/RXD1
12
P47/SRDY1/CNTR2
11
P50/SIN2
9
10
8
P53/SRDY2
P52/SCLK2
7
P54/CNTR0
P51/SOUT2
6
P55/CNTR1
P42/INT1
5
17
P56/PWM
64
4
CNVSS
P63/AN3
3
18
P60/AN0
63
P57/INT3
RESET
P64/AN4
1
P41/INT00/XCIN
19
2
20
62
P62/AN2
61
P61/AN1
P66/AN6
P65/AN5
Package type : 64P6N-A/64P6Q-A/64P6U-A
(TOP VIEW)
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
M38049FFHSP
VCC
VREF
AVSS
P67/AN7
P66/AN6
P65/AN5
P64/AN4
P63/AN3
P62/AN2
P61/AN1
P60/AN0
P57/INT3
P56/PWM
P55/CNTR1
P54/CNTR0
P53/SRDY2
P52/SCLK2
P51/SOUT2
P50/SIN2
P47/SRDY1/CNTR2
P46/SCLK1
P45/TXD1
P44/RXD1
P43/INT2
P42/INT1
CNVSS
RESET
P41/INT00/XCIN
P40/INT40/XCOUT
XIN
XOUT
VSS
64
63
62
61
60
59
58
57
56
55
54
53
52
51
50
49
48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33
P30/DA1
P31/DA2
P32/SDA
P33/SCL
P34/RXD3
P35/TXD3
P36/SCLK3
P37/SRDY3
P00/AN8
P01/AN9
P02/AN10
P03/AN11
P04/AN12
P05/AN13
P06/AN14
P07/AN15
P10/INT41
P11/INT01
P12
P13
P14
P15
P16
P17
P20(LED0)
P21(LED1)
P22(LED2)
P23(LED3)
P24(LED4)
P25(LED5)
P26(LED6)
P27(LED7)
Package type : 64P4B
Rev.1.00 Jan 14, 2005
REJ09B0212-0100Z
3-95
3804 Group (Spec. H) User’s Manual
Publication Data :
Rev.1.00 Jan 14, 2005
Published by :
Sales Strategic Planning Div.
Renesas Technology Corp.
© 2005. Renesas Technology Corp., All rights reserved. Printed in Japan.
3804 Group (Spec. H)
User’s Manual
2-6-2, Ote-machi, Chiyoda-ku, Tokyo, 100-0004, Japan
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