RENESAS M306V5EESP

To all our customers
Regarding the change of names mentioned in the document, such as Mitsubishi
Electric and Mitsubishi XX, to Renesas Technology Corp.
The semiconductor operations of Hitachi and Mitsubishi Electric were transferred to Renesas
Technology Corporation on April 1st 2003. These operations include microcomputer, logic, analog
and discrete devices, and memory chips other than DRAMs (flash memory, SRAMs etc.)
Accordingly, although Mitsubishi Electric, Mitsubishi Electric Corporation, Mitsubishi
Semiconductors, and other Mitsubishi brand names are mentioned in the document, these names
have in fact all been changed to Renesas Technology Corp. Thank you for your understanding.
Except for our corporate trademark, logo and corporate statement, no changes whatsoever have been
made to the contents of the document, and these changes do not constitute any alteration to the
contents of the document itself.
Note : Mitsubishi Electric will continue the business operations of high frequency & optical devices
and power devices.
Renesas Technology Corp.
Customer Support Dept.
April 1, 2003
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
1. DESCRIPTION
The M306V5ME-XXXSP and M306V5EESP are single-chip microcomputers using the high-performance
silicon gate CMOS process using a M16C/60 Series CPU core and are packaged in a 64-pin plastic molded
SDIP. These single-chip microcomputers operate using sophisticated instructions featuring a high level of
instruction efficiency. With 1M bytes of address space, they are capable of executing instructions at high
speed. They also feature a built-in OSD display function and data slicer, making them ideal for controlling
TV with a closed caption decoder.
The features of the M306V5EESP are similar to those of the M306V5ME-XXXSP except that this chip has
a built-in PROM which can be written electrically.
1.1 Features
• Memory size ........................................<ROM>192K bytes
<RAM> 5K bytes
<OSD ROM> 61K bytes
<OSD RAM> 2.2K bytes
• Shortest instruction execution time ...... 100 ns (f(XIN)=10 MHz)
• Power sourse voltage .......................... 4.5 V to 5.5V
• Power consumption ............................. 250 mW
• Interrupts .............................................. 21 internal and 3 external interrupt sources, 4 software
interrupt sources; 7 levels
• Multifunction 16-bit timer ...................... 2 output timers + 1 input timer + 5 timers
• Serial I/O .............................................. 4 units
UART/clock synchronous: 2
Multi-master I2C-BUS interface 0 (2 systems): 1
Multi-master I2C-BUS interface 1 (1 systems): 1
• DMAC .................................................. 2 channels (trigger: 23 sources)
• A-D converter ....................................... 8 bits ✕ 6 channels
• D-A converter ....................................... 8 bits ✕ 2 channels
• Data slicer ............................................ 1 circuit
• HSYNC counter ..................................... 1 circuit (2 systems)
• OSD function ....................................... 1 circuit
• Watchdog timer .................................... 1 circuit
• Programmable I/O ............................... 46 lines
• Clock generating circuit ....................... 2 built-in clock generation circuits
1.2 Applications
TV with a closed caption decoder
Rev. 1.1
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
------Table of Contents-----1. DESCRIPTION .............................................. 1
2.16.18 Scan Mode ................................ 219
1.1 Features ................................................... 1
1.2 Applications ............................................. 1
2.16.19 R, G, B Signal Output Control ... 219
2.16.20 OSD Reserved Register ........... 220
1.3 Pin Configuration ..................................... 3
2.17 Programmable I/O Ports .................... 221
1.4 Block Diagram ......................................... 4
1.5 Performance Outline ................................ 5
3. USAGE PRECAUTION .............................. 239
3.1 Timer A (timer mode) ........................... 239
2. OPERATION OF FUNCTIONAL BLOKS ..... 10
3.2 Timer A (event counter mode) ............. 239
2.1 Memory .................................................. 10
3.3 Timer A (one-shot timer mode) ............ 239
2.2 Central Processing Unit (CPU) .............. 16
2.3 Reset ..................................................... 19
3.4 Timer A (pulse width modulation mode)239
3.5 Timer B (timer mode, event counter mode)240
2.4 Single-chip Mode ................................... 23
3.6 Timer B (pulse period, pulse width
2.5 Clock Generating Circuit ........................ 27
measurement mode) ................................ 240
2.6 Protection ............................................... 35
3.7 A-D Converter ...................................... 240
2.7 Interrupts ................................................ 36
3.8 Stop Mode and Wait Mode .................. 240
2.8 Watchdog Timer .................................... 56
3.9 Interrupts .............................................. 241
2.9 DMAC .................................................... 58
3.10 Built-in PROM Version ....................... 242
2.10 Timer .................................................... 68
2.11 Serial I/O .............................................. 88
4. ITEMS TO BE SUBMITTED WHEN ORDERING
2.12 A-D Converter .................................... 138
MASKED ROM VERSION ......................... 243
2.13 D-A Converter .................................... 153
5. ELECTRICAL CHARACTERISTICS .......... 244
2.14 Data Slicer ......................................... 155
5.1. Absolute Maximum Ratings ................ 244
2.15 HSYNC Counter ................................ 165
5.2 Recommended Operating Conditions .. 245
2.16 OSD Functions .................................. 166
5.3 Electrical Characteristics ..................... 246
2.16.1 Triple Layer OSD ........................ 172
5.4 A-D Conversion Characteristics ........... 247
2.16.2 Display Position .......................... 174
2.16.3 Dot Size ...................................... 178
5.5 D-A Conversion Characteristics ........... 247
5.6 Analog R, G, B Output Characteristics 247
2.16.4 Clock for OSD ............................. 179
5.7 Timing Requirements ........................... 248
2.16.5 Field Determination Display ........ 180
5.8 Timing Diagram ................................... 250
2.16.6 Memory for OSD ......................... 182
2.16.7 Character Color .......................... 195
6. MASK CONFIRMATION FORM ................ 251
2.16.8 Character Background Color ...... 195
2.16.9 OUT1, OUT2 Signals .................. 200
7. MARK SPECIFICATION FORM ................ 255
2.16.10 Attribute .................................... 201
2.16.11 Automatic Solid Space Function .... 206
8. ONE TIME PROM VERSION M306V5EESP
2.16.12 Particular OSD Mode Block ...... 207
MARKING .................................................. 256
2.16.13 Multiline Display ........................ 209
2.16.14 SPRITE OSD Function ............. 210
9. PACKAGE OUTLINE ................................. 257
2.16.15 Window Function ...................... 213
2.16.16 Blank Function .......................... 214
2.16.17 Raster Coloring Function .......... 217
Rev. 1.0
2
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
1.3 Pin Configuration
Figure 1.3.1 shows the pin configuration (top view).
PIN CONFIGURATION (top view)
P101/VSYNC
1
64
P00
P100/HSYNC
TVSETB
2
63
3
62
AVCC
CVIN
VHOLD
4
61
5
60
P01
P02
P03
P04
6
59
P05
HLF
P94/DA1/SCL3
P93/DA0/SDA3
P90/TB0IN
CNVSS
7
58
8
57
P06
P07
56
P20
55
11
54
RESET
XOUT
12
53
VSS
14
P21
P22
P23
P24
P25
P26
P27
13
XIN
15
VCC
OSC1
16
OSC2
18
P82/INT0
19
OUT1
20
OUT2
P76/TA3OUT
P74/TA2OUT
P72/CLK2/SCL2
P71/RxD2/SCL1
P70/TxD2/SDA1
M306V5ME-XXXSP
M306V5EESP
9
10
52
51
50
49
47
P30
P31
46
P32
45
P33/INT1
21
44
22
43
23
42
24
41
P34/HC0
P35/HC1
P36/AN0
P37/AN1
25
40
26
39
P67/SDA2
27
38
R
G
B
P63/TxD0
P62/RxD0
28
37
29
36
30
35
31
34
P42/AN4
P43/AN5
P50
P52
P53
32
33
P55/CLK0
17
48
P40/AN2
P41/AN3
Package: 64P4B
Figure 1.3.1 Pin configuration (top view)
Rev. 1.0
3
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
1.4 Block Diagram
Figure 1.4.1 is a block diagram.
8
I/O ports
Port P0
8
Port P2
4
Port P3
Port P4
UART/clock synchronous SI/O
Data slicer
Multi-master I2C-bus
interface 0
HSYNC counter
Registers
Multi-master I2C-bus
interface 1
RA M
5K
INTB
Stack pointer
ISP
USP
FLG
Multiplier
2
SB
Vector table
ROM
192 K
Port P10
D-A converter
(8 bits X 2 channels)
PC
3
DMAC
(2 channels)
Program counter
Memory
Port P9
(15 bits)
R0H
R0L
R0H
R0L
R1H
R1L
R1H
R1L
R2
R2
R3
R3
A0
A0
A1
A1
FB
FB
1
UART /clock synchronous SI/O
Port P6
Port P8
OSD
3
5
XIN–XOUT
M16C/60 series16-bit CPU core
Watchdog timer
Port P5
System clock generator
A-D converter
Timer
Timer TA0 (16 bits)
Timer TA1 (16 bits)
Timer TA2 (16 bits)
Timer TA3 (16 bits)
Timer TA4 (16 bits)
Timer TB0 (16 bits)
Timer TB1 (16 bits)
Timer TB2 (16 bits)
4
Port P7
Internal peripheral functions
8
Figure 1.4.1 Block diagram
Rev. 1.0
4
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
1.5 Performance Outline
Table 1.5.1 is a performance outline.
Table 1.5.1 Performance outline
Item
Performance
Number of basic instructions
91 instructions
Shortest instruction execution time
Memory
ROM
100 ns(f(XIN)=10 MHz)
192K bytes
size
RAM
5K bytes
OSD ROM
61K bytes
I/O port
OSD RAM
P0, P2 to P10
2.2K bytes
8 bits ✕ 3, 5 bits ✕ 1, 4 bits ✕ 2, 3 bits ✕ 2, 2 bits ✕ 1,
1 bit ✕ 1
Multifunction
TA0, TA1, TA2, TA3, TA4
16 bits ✕ 5
timer
TB0, TB1, TB2
16 bits ✕ 3
Serial I/O
UART0
1 unit: UART or clock synchronous
UART2
1 unit: UART or clock synchronous
2
Multi-master I C-BUS interface 0 1 unit (2 channels)
Multi-master I2C-BUS interface 1 1 unit (1 channels)
A-D converter
8 bits ✕ 6 channels
D-A converter
8 bits ✕ 2 channels
DMAC
2 channels (trigger: 23 sources)
OSD function
Data slicer
HSYNC counter
Watchdog timer
Triple layer, 890 kinds of fonts, 42 character ✕ 16 lines
32-bit buffer
8 bits ✕ 2 channels
15 bits ✕ 1 (with prescaler)
Interrupt
21 internal and 3 external sources, 4 software sources, 7 levels
Clock generating circuit
2 built-in clock generation circuits
Power source voltage
4.5 V to 5.5V (f(XIN ) = 10 MHz)
Power consumption
250 mW
I/O
I/O withstand voltage
characteristics Output current
5V
5 mA
Operating ambient temperature
–10 o C to 70 o C
Device configuration
CMOS high performance silicon gate
Package
64-pin plastic molded SDIP
Rev. 1.0
5
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
Currently supported products are listed below.
Table 1.5.2 List of supported products
Type No
ROM capacity
RAM capacity
Package type
Remarks
M306V5ME-XXXSP
192K bytes
5K bytes
64P4B
Mask ROM version
M306V5EESP
192K bytes
5K bytes
64P4B
One Time PROM version
M306V5EESS
192K bytes
5K bytes
64S1B
EPROM version
Note: Since EPROM version is for development support tool (for evaluation), do not use for mass production.
Type No.
M306V5M E – XXX SP
Package type:
SP : Package
SS : Package
64P4B
64S1B
ROM No.
Omitted for One Time PROM version
and EPROM version
ROM capacity:
E : 192K bytes
Memory type:
M : Mask ROM version
E : One Time PROM version or EPROM
version
Shows RAM capacity, pin count, etc
(The value itself has no specific meaning)
M16C/6V Group
M16C Family
Figure 1.5.1 Type No., memory size, and package
Rev. 1.0
6
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
1.5.1 As For M16C/6V (64-Pin Version) Group
M16C/6V (64-pin version) group is packaged in a 64-pin plastic molded SDIP. Note that the number of
pins is reduced when it is compared with a 100-pin package product.
(1) M16C/6V (64-pin version) group supports only the shingle-chip mode. It does not support the memory
expansion and the microprocessor modes.
(2) Be sure to initialize in the sequence below immediately after reset release.
➀ Set OSD reserved register i (i = 1 to 4) to the specified values.
➁ Set each reserved bit of the port Pi direction register, the port Pi register, and pull-up control register i
to the specified values.
➂ Set port reserved register i (i = 1 to 3) to the specified values.
➃ Set other reserved registers and each reserved bit of other registers to the specified values.
Rev. 1.0
7
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
Table 1.5.3 Pin description (1)
Pin name
Signal name
I/O type
Function
VCC, VSS
Power supply
input
CNVSS
CNVSS
Input
Connect this pin to the VSS pin.
RESET
Reset input
Input
A “L” on this input resets the microcomputer.
X IN
Clock input
Input
XOUT
Clock output
Output
These pins are provided for the main clock generating circuit.Connect
a ceramic resonator or crystal between the XIN and the XOUT pins. To
use an externally derived clock, input it to the XIN pin and leave the
XOUT pin open.
AVCC
Analog power
supply input
P00 to P07
I/O port P0
Input/output
This is an 8-bit CMOS I/O port. It has an input/output port direction
register that allows the user to set each pin for input or output
individually. When set for input, the user can specify in units of four bits
via software whether or not they are tied to a pull-up resistor.
P20 to P27
I/O port P2
Input/output
This is an 8-bit I/O port equivalent to P0.
P30 to P37
I/O port P3
Input/output
This is an 8-bit I/O port equivalent to P0. Pins in this port function as
external interrupt pin, HSYNC counter I/O pins, and A-D converter input
pins as selected by software.
P40 to P43
I/O port P4
Input/output
This is an 8-bit I/O port equivalent to P0. Pins in this port function as A-D
converter input pins as selected by software.
P50, P52,
P53, P55
I/O port P5
Input/output
This is a 4-bit I/O port equivalent to P0. P57 in this port functions as
UART0 I/O pin as selected by software.
P62, P63,
P67
I/O port P6
Input/output
This is a 3-bit I/O port equivalent to P0. Pins in this port also function as
UART0 and multi-master I2C-BUS interface 0 I/O pins as selected by
software.
P70 to P72,
P74, P76
I/O port P7
Input/output
This is a 5-bit I/O port equivalent to P0 (P70 and P71 are N-channel
open-drain output). Pins in this port also function as timers A2 and A3,
UART2, multi-master I2C-BUS interface 0 I/O pins as selected by
software.
P82
I/O port P8
Input/output
P82 is I/O port with the same functions as P0.
P82 can be made to function as the I/O pin for the input pins for external
interrupts as selected by software.
P90, P93, P94 I/O port P9
Input/output
This is an 3-bit I/O port equivalent to P0. Pins in this port also function
as Timer B0 input pin, D-A converter output pins, and multi-master I2CBUS interface 1 I/O pins as selected by software.
Supply 4.5 V to 5.5 V to the VCC pin. Supply 0 V to the VSS pin.
This pin is a power supply input for the A-D converter. Connect this
pin to VCC.
Rev. 1.0
8
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
Table 1.5.4 Pin description (continued) (2)
Pin name
Signal name
I/O type
Function
P100, P101
I/O port P10
Input/output
This is a 2-bit I/O port equivalent to P0. Pins in this port also function
as a input pins for OSD function as selected bysoftware.
R, G, B
OSD output
Output
These are OSD output pins (analog output).
OUT1, OUT2
OSD output
Output
These are OSD output pins (digital output).
OSC1
Clock input
for OSD
Input
This is an OSD clock input pin.
OSC2
Clock output
for OSD
Output
This is an OSD clock output pin.
CVIN
I/O for data
slicer
Input
Input composite video signal through a capacitor.
Input
Connect a capacitor between VHOLD and Vss.
Input/output
Connect a filter using of a capacitor and a resistor
between HLF and Vss.
Input
This is a test input pin. Fix it to “L.”
VHOLD
HLF
TVSETB
Test input
Rev. 1.0
9
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
2. OPERATION OF FUNCTIONAL BLOKS
This microcomputer accommodates certain units in a single chip. These units include ROM and RAM to
store instructions and data and the central processing unit (CPU) to execute arithmetic/logic operations.
Also included are peripheral units such as timers, serial I/O, D-A converter, DMAC, OSD circuit, data slicer,
A-D converter, and I/O ports.
The following explains each unit.
2.1 Memory
Figure 2.1.1 is a memory map. The address space extends the 1M bytes from address 0000016 to
FFFFF16. From FFFFF16 down is ROM. There is 192K bytes of internal ROM from D000016 to FFFFF16.
The vector table for fixed interrupts such as the reset mapped to FFFDC16 to FFFFF16. The starting address of the interrupt routine is stored here. The address of the vector table for timer interrupts, etc., can be
set as desired using the internal register (INTB). See the section on interrupts for details.
5K bytes of internal RAM is mapped to the space from 02C0016 to 03FFF16. In addition to storing data, the
RAM also stores the stack used when calling subroutines and when interrupts are generated.
The SFR area is mapped to 0000016 to 003FF16. This area accommodates the control registers for peripheral devices such as I/O ports, A-D converter, serial I/O, and timers, etc. Figures 2.1.2 to 2.1.5 are location
of peripheral unit control registers. Any part of the SFR area that is not occupied is reserved and cannot be
used for other purposes.
The special page vector table is mapped to FFE0016 to FFFDB16. If the starting addresses of subroutines
or the destination addresses of jumps are stored here, subroutine call instructions and jump instructions
can be used as 2-byte instructions, reducing the number of program steps.
Rev. 1.0
10
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
00000 16
SFR area
003FF 16 (Refer to Figures 2.1.2 to 2.1.5)
00400 16
OSD RAM area
013FF 16
01400 16
Internal reserved
area
02BFF 16
02C00 16
Internal RAM area
FFE00 16
03FFF 16
04000 16
Internal reserved
area
Special page
vector table
8FFFF 16
90000 16
OSD ROM area
FFFDC 16
Undefined instruction
Overflow
AFFFF 16
B0000 16
Internal reserved
area
CFFFF 16
D0000 16
Internal ROM area
FFFFF 16
FFFFF 16
BRK instruction
Address match
Single step
Watchdog timer
DBC
Reset
Figure 2.1.1 Memory map
Rev. 1.0
11
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
000016
004016
000116
004116
000216
004216
004316
000316
000416
000516
000616
000716
Processor mode register 0 (PM0)
Processor mode register 1 (PM1)
System clock control register 0 (CM0)
System clock control register 1 (CM1)
004416
004516
004616
004716
004816
000816
OSD1 interrupt control register (OSD1IC)
Interrupt control reserved register 0 (RE0IC)
Interrupt control reserved register 1 (RE1IC)
Interrupt control reserved register 2 (RE2IC)
OSD2 interrupt control register (OSD2IC)
004916
Multi-master I2C-BUS interface 1 interrupt control register (IIC1IC)
004A16
Bus collision detection interrupt control register (BCNIC)
000B16
004B16
000C16
004C16
DMA0 interrupt control register (DM0IC)
DMA1 interrupt control register (DM1IC)
000916
000A16
Address match interrupt enable register (AIER)
Protect register (PRCR)
000D16
000E16
000F16
Watchdog timer start register (WDTS)
Watchdog timer control register (WDC)
Multi-master I2C-BUS interface 0 interrupt control register (IIC0IC)
004E16
A-D conversion interrupt control register (ADIC)
004F16
UART2 transmit interrupt control register (S2TIC)
UART2 receive interrupt control register (S2RIC)
UART0 transmit interrupt control register (S0TIC)
UART0 receive interrupt control register (S0RIC)
Data slicer interrupt control register (DSIC)
VSYNC interrupt control register (VSYNCIC)
005016
001016
001116
004D16
Address match interrupt register 0 (RMAD0)
005116
001216
005216
001316
005316
005416
001416
001516
Address match interrupt register 1 (RMAD1)
005516
001616
005616
001716
005716
001816
005816
001916
005916
001A16
005A16
001B16
005B16
001C16
005C16
001D16
005D16
001E16
005E16
001F16
005F16
006016
002016
002116
Timer A0 interrupt control register (TA0IC)
Timer A1 interrupt control register (TA1IC)
Timer A2 interrupt control register (TA2IC)
Timer A3 interrupt control register (TA3IC)
Timer A4 interrupt control register (TA4IC)
Timer B0 interrupt control register (TB0IC)
Timer B1 interrupt control register (TB1IC)
Timer B2 interrupt control register (TB2IC)
INT0 interrupt control register (INT0IC)
INT1 interrupt control register (INT1IC)
Interrupt control reserved register 3 (RE3IC)
DMA0 source pointer (SAR0)
002216
002316
002416
002516
DMA0 destination pointer (DAR0)
002616
002716
002816
002916
DMA0 transfer counter (TCR0)
002A16
002B16
002C16
DMA0 control register (DM0CON)
002D16
002E16
002F16
003016
003116
DMA1 source pointer (SAR1)
003216
003316
003416
003516
DMA1 destination pointer (DAR1)
003616
003716
003816
003916
DMA1 transfer counter (TCR1)
003A16
003B16
003C16
DMA1 control register (DM1CON)
003D16
003E16
003F16
01FF16
Figure 2.1.2 Location of peripheral unit control registers (1)
Rev. 1.0
12
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
020016
020116
020216
020316
020416
020516
020616
020716
020816
020916
024016
SPRITE OSD control register (SC)
OSD control register 1 (OC1)
OSD control register 2 (OC2)
Horizontal position register (HP)
Clock control register (CS)
I/O polarity control register (PC)
OSD control register 3 (OC3)
Raster color register (RSC)
024116
024216
024316
024416
024516
024616
024716
024816
024916
020A16
024A16
020B16
024B16
020C16
024C16
020D16
Top border control register (TBR)
020E16
020F16
021016
021116
021216
021316
021416
021516
021616
021716
021816
021916
021A16
021B16
021C16
021D16
021E16
021F16
022016
022116
022216
022316
022416
022516
022616
022716
024E16
Bottom border control register (BBR)
Block control register 1 (BC1)
Block control register 2 (BC2)
Block control register 3 (BC3)
Block control register 4 (BC4)
Block control register 5 (BC5)
Block control register 6 (BC6)
Block control register 7 (BC7)
Block control register 8 (BC8)
Block control register 9 (BC9)
Block control register 10 (BC10)
Block control register 11(BC11)
Block control register 12 (BC12)
Block control register 13 (BC13)
Block control register 14 (BC14)
Block control register 15 (BC15)
Block control register 16 (BC16)
Vertical position register 1 (VP1)
Vertical position register 2 (VP2)
Vertical position register 3 (VP3)
Vertical position register 4 (VP4)
022816
022916
022C16
022D16
022E16
022F16
023016
023116
023216
023316
023416
023516
023616
023716
023816
023916
023A16
023B16
023C16
023D16
023E16
023F16
024F16
025016
025116
025216
025316
025416
025516
025616
025716
025816
025916
025A16
025B16
025D16
025F16
026016
026116
026216
026316
026416
026516
026616
026716
026916
026A16
026B16
Vertical position register 7 (VP7)
026F16
Vertical position register 9 (VP9)
Vertical position register 10 (VP10)
Vertical position register 11 (VP11)
Vertical position register 12 (VP12)
Vertical position register 13 (VP13)
Vertical position register 14 (VP14)
Vertical position register 15 (VP15)
Vertical position register 16 (VP16)
Color palette register 3 (CR3)
Color palette register 4 (CR4)
Color palette register 5 (CR5)
Color palette register 6 (CR6)
Color palette register 7 (CR7)
Color palette register 9 (CR9)
Color palette register 10 (CR10)
Color palette register 11 (CR11)
Color palette register 12 (CR12)
Color palette register 13 (CR13)
Color palette register 14 (CR14)
Color palette register 15 (CR15)
OSD reserved register 1 (OR1)
025E16
Vertical position register 6 (VP6)
Vertical position register 8 (VP8)
Color palette register 2 (CR2)
025C16
026816
Vertical position register 5 (VP5)
022A16
022B16
024D16
Color palette register 1 (CR1)
027016
027116
027216
027316
027416
027516
027616
027716
027816
027916
027A16
027B16
027C16
027D16
027E16
027F16
OSD control register 4 (OC4)
Data slicer control register 1 (DSC1)
Data slicer control register 2 (DSC2)
Caption data register 1 (CD1)
Caption data register 2 (CD2)
Caption position register (CPS)
Data slicer reserved register 2 (DR2)
Data slicer reserved register 1 (DR1)
Clock run-in detect register (CRD)
Data clock position register (DPS)
Left border control register (LBR)
Right border control register (RBR)
SPRITE vertical position register 1 (VS1)
SPRITE vertical position register 2 (VS2)
SPRITE horizontal position register (HS)
OSD reserved register 4 (OR4)
OSD reserved register 3 (OR3)
OSD reserved register 2 (OR2)
Peripheral mode register (PM)
HSYNC counter register (HC)
HSYNC counter latch
028016
02DF16
Figure 2.1.3 Location of peripheral unit control registers (2)
Rev. 1.0
13
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
02E016
02E116
02E216
02E316
02E416
02E516
02E616
I2C0 data shift register (IIC0S0)
I2C0 address register (IIC0S0D)
I2C0 status register (IIC0S1)
I2C0 control register (IIC0S1D)
I2C0 clock control register (IIC0S2)
I2C0 port selection register (IIC0S2D)
I2C0 transmit buffer register (IIC0S0S)
02E916
02EA16
02EB16
02EC16
02ED16
02EE16
038116
038216
038316
038416
I2C1
data shift register (IIC1S0)
I2C1 address register (IIC1S0D)
I2C1 status register (IIC1S1)
I2C1 control register (IIC1S1D)
I2C1 clock control register (IIC1S2)
I2C1 port selection register (IIC1S2D)
I2C1 transmit buffer register (IIC1S0S)
038616
Timer A0 register (TA0)
038816
038916
Timer A1 register (TA1)
038A16
038B16
Timer A2 register (TA2)
038C16
038D16
Timer A3 register (TA3)
038E16
038F16
02EF16
Count start flag (TABSR)
Reserved register 6 (INVC6)
One-shot start flag (ONSF)
Trigger select register (TRGSR)
Up-down flag (UDF)
038516
038716
02E716
02E816
038016
Timer A4 register (TA4)
039016
039116
039216
033916
034016
Reserved register 1 (INVC1)
039316
034116
039416
034216
039516
034316
039616
034416
039716
034516
039816
034616
039916
039A16
034716
034816
Reserved register 0 (INVC0)
039B16
039C16
034916
039D16
Timer B0 register (TB0)
Timer B1 register (TB1)
Timer B2 register (TB2)
Timer A0 mode register (TA0MR)
Timer A1 mode register (TA1MR)
Timer A2 mode register (TA2MR)
Timer A3 mode register (TA3MR)
Timer A4 mode register (TA4MR)
Timer B0 mode register (TB0MR)
Timer B1 mode register (TB1MR)
Timer B2 mode register (TB2MR)
039E16
035E16
Interrupt request cause select register (IFSR)
036016
039F16
03A016
UART0 transmit/receive mode register (U0MR)
036116
03A116
UART0 bit rate generator (U0BRG)
035F16
036216
Reserved register 3 (INVC3)
03A216
036316
03A316
036416
03A416
036516
03A516
036616
Reserved register 4 (INVC4)
UART0 transmit buffer register (U0TB)
UART0 transmit/receive control register 0 (U0C0)
UART0 transmit/receive control register 1 (U0C1)
03A616
036716
03A716
UART0 receive buffer register (U0RB)
036816
03A816
Reserved register 2 (INVC2)
036916
03A916
036A16
03AA16
036B16
03AB16
036C16
03AC16
036D16
03AD16
036E16
03AE16
036F16
03AF16
037016
03B016
037116
03B116
037216
03B216
037316
03B316
037416
03B416
03B516
037516
037616
037716
037816
037916
037A16
037B16
037C16
037D16
037E16
037F16
UART transmit/receive control register 2 (UCON)
Reserved register 5 (INVC5)
UART2 special mode register (U2SMR)
03B616
UART2 transmit/receive mode register (U2MR)
UART2 bit rate generator (U2BRG)
03B816
03B716
03BA16
UART2 transmit buffer register (U2TB)
UART2 transmit/receive control register 0 (U2C0)
UART2 transmit/receive control register 1 (U2C1)
DMA0 request cause select register (DM0SL)
03B916
DMA1 request cause select register (DM1SL)
03BB16
03BC16
03BD16
03BE16
UART2 receive buffer register (U2RB)
03BF16
Figure 2.1.4 Location of peripheral unit control registers (3)
Rev. 1.0
14
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
03C016
03C116
03C216
03C316
03C416
A-D register 0 (AD0)
03C516
03C616
A-D register 1 (AD1)
03C716
03C816
A-D register 2 (AD2)
03C916
03CA16
A-D register 3 (AD3)
03CB16
03CC16
A-D register 4 (AD4)
03CD16
03CE16
A-D register 5 (AD5)
03CF16
03D016
03D116
03D216
03D316
03D416
A-D control register 2 (ADCON2)
03D516
03D616
03D716
03D816
A-D control register 0 (ADCON0)
A-D control register 1 (ADCON1)
D-A register 0 (DA0)
03D916
03DA16
D-A register 1 (DA1)
03DB16
03DC16
D-A control register (DACON)
03DD16
03DE16
03DF16
03E016
03E116
03E216
03E316
03E416
03E516
03E616
03E716
03E816
03E916
03EA16
03EB16
03EC16
03ED16
03EE16
03EF16
03F016
03F116
03F216
03F316
03F416
Port P0 register (P0)
Port reserved register 1 (PR1)
Port P0 direction register (PD0)
Port reserved register 2 (PR2)
Port P2 register (P2)
Port P3 register (P3)
Port P2 direction register (PD2)
Port P3 direction register (PD3)
Port P4 register (P4)
Port P5 register (P5)
Port P4 direction register (PD4)
Port P5 direction register (PD5)
Port P6 register (P6)
Port P7 register (P7)
Port P6 direction register (PD6)
Port P7 direction register (PD7)
Port P8 register (P8)
Port P9 register (P9)
Port P8 direction register (PD8)
Port P9 direction register (PD9)
Port P10 register (P10)
03F516
03F616
Port P10 direction register (PD10)
03F716
03F816
03F916
03FA16
03FB16
03FC16
03FD16
03FE16
03FF16
Pull-up control register 0 (PUR0)
Pull-up control register 1 (PUR1)
Pull-up control register 2 (PUR2)
Port reserved register 3 (PR3)
Figure 2.1.5 Location of peripheral unit control registers (4)
Rev. 1.0
15
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
2.2 Central Processing Unit (CPU)
The CPU has a total of 13 registers shown in Figure 2.2.1. Seven of these registers (R0, R1, R2, R3, A0,
A1, and FB) come in two sets; therefore, these have two register banks.
b15
R0(Note)
b8 b7
b15
R1(Note)
b0
L
H
b8 b7
H
b19
b0
L
b0
Program counter
PC
Data
registers
b15
b0
b19
R2(Note)
INTB
b15
Interrupt table
register
L
b15
b0
b0
User stack pointer
USP
R3(Note)
b15
b15
b0
b0
Interrupt stack
pointer
ISP
A0(Note)
b15
b0
Address
registers
b15
b0
Static base
register
SB
A1(Note)
b15
FB(Note)
b0
H
b15
b0
Frame base
registers
IPL
b0
FLG
Flag register
U I
O B S Z D C
Note: These registers consist of two register banks.
Figure 2.2.1 Central processing unit register
Rev. 1.0
16
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
2.2.1 Data Registers (R0, R0H, R0L, R1, R1H, R1L, R2, and R3)
Data registers (R0, R1, R2, and R3) are configured with 16 bits, and are used primarily for transfer and
arithmetic/logic operations.
Registers R0 and R1 each can be used as separate 8-bit data registers, high-order bits as (R0H/R1H),
and low-order bits as (R0L/R1L). In some instructions, registers R2 and R0, as well as R3 and R1 can
use as 32-bit data registers (R2R0/R3R1).
2.2.2 Address Registers (A0 and A1)
Address registers (A0 and A1) are configured with 16 bits, and have functions equivalent to those of data
registers. These registers can also be used for address register indirect addressing and address register
relative addressing.
In some instructions, registers A1 and A0 can be combined for use as a 32-bit address register (A1A0).
2.2.3 Frame Base Register (FB)
Frame base register (FB) is configured with 16 bits, and is used for FB relative addressing.
2.2.4 Program Counter (PC)
Program counter (PC) is configured with 20 bits, indicating the address of an instruction to be executed.
2.2.5 Interrupt Table Register (INTB)
Interrupt table register (INTB) is configured with 20 bits, indicating the start address of an interrupt vector
table.
2.2.6 Stack Pointer (USP/ISP)
Stack pointer comes in two types: user stack pointer (USP) and interrupt stack pointer (ISP), each configured with 16 bits.
Your desired type of stack pointer (USP or ISP) can be selected by a stack pointer select flag (U flag).
This flag is located at the position of bit 7 in the flag register (FLG).
2.2.7 Static Base Register (SB)
Static base register (SB) is configured with 16 bits, and is used for SB relative addressing.
2.2.8 Flag Register (FLG)
Flag register (FLG) is configured with 11 bits, each bit is used as a flag. Figure 2.2.2 shows the flag
register (FLG). The following explains the function of each flag:
• Bit 0: Carry flag (C flag)
This flag retains a carry, borrow, or shift-out bit that has occurred in the arithmetic/logic unit.
• Bit 1: Debug flag (D flag)
This flag enables a single-step interrupt.
When this flag is “1”, a single-step interrupt is generated after instruction execution. This flag is
cleared to “0” when the interrupt is acknowledged.
• Bit 2: Zero flag (Z flag)
This flag is set to “1” when an arithmetic operation resulted in 0; otherwise, cleared to “0”.
• Bit 3: Sign flag (S flag)
This flag is set to “1” when an arithmetic operation resulted in a negative value; otherwise, cleared to “0”.
• Bit 4: Register bank select flag (B flag)
This flag chooses a register bank. Register bank 0 is selected when this flag is “0” ; register bank 1 is
selected when this flag is “1”.
Rev. 1.0
17
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
• Bit 5: Overflow flag (O flag)
This flag is set to “1” when an arithmetic operation resulted in overflow; otherwise, cleared to “0”.
• Bit 6: Interrupt enable flag (I flag)
This flag enables a maskable interrupt.
An interrupt is disabled when this flag is “0”, and is enabled when this flag is “1”. This flag is cleared to
“0” when the interrupt is acknowledged.
• Bit 7: Stack pointer select flag (U flag)
Interrupt stack pointer (ISP) is selected when this flag is “0” ; user stack pointer (USP) is selected
when this flag is “1”.
This flag is cleared to “0” when a hardware interrupt is acknowledged or an INT instruction of software
interrupt Nos. 0 to 31 is executed.
• Bits 8 to 11: Reserved area
• Bits 12 to 14: Processor interrupt priority level (IPL)
Processor interrupt priority level (IPL) is configured with three bits, for specification of up to eight
processor interrupt priority levels from level 0 to level 7.
If a requested interrupt has priority greater than the processor interrupt priority level (IPL), the interrupt
is enabled.
• Bit 15: Reserved area
The C, Z, S, and O flags are changed when instructions are executed. See the software manual for
details.
b15
b0
IPL
U
I O B S Z D C
Flag register (FLG)
Carry flag
Debug flag
Zero flag
Sign flag
Register bank select flag
Overflow flag
Interrupt enable flag
Stack pointer select flag
Reserved area
Processor interrupt prior
Reserved area
Figure 2.2.2 Flag register (FLG)
Rev. 1.0
18
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
2.3 Reset
There are two kinds of resets; hardware and software. In both cases, operation is the same after the reset.
(See “Software Reset” for details of software resets.) This section explains on hardware resets.
When the supply voltage is in the range where operation is guaranteed, a reset is effected by holding the
reset pin level “L” (0.2VCC max.) for at least 20 cycles. When the reset pin level is then returned to the “H”
level while main clock is stable, the reset status is cancelled and program execution resumes from the
address in the reset vector table.
Figure 2.3.1 shows the example reset circuit. Figure 2.3.2 shows the reset sequence.
5V
4.5V
VCC
VCC
RESET
0V
5V
RESET
0.9V
0V
Example when f(XIN) = 10 MHz and VCC = 5V.
Figure 2.3.1 Example reset circuit
2.3.1 Software Reset
Writing “1” to bit 3 of the processor mode register 0 (address 000416) applies a (software) reset to the
microcomputer. A software reset has almost the same effect as a hardware reset. The contents of internal
RAM are preserved.
XIN
More than 20 cycles are needed
Single-chip
mode
RESET
BCLK
24cycles
BCLK
Content of reset vector
FFFFC 16
Address
Content of reset vector
FFFFE16
Figure 2.3.2 Reset sequence
Rev. 1.0
19
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
____________
2.3.2 Pin Status When RESET Pin Level is “L”
____________
Table 2.3.1 shows the statuses of the other pins while the RESET pin level is “L”. Figures 2.3.3 and 2.3.4
show the internal status of the microcomputer immediately after the reset is cancelled.
____________
Table 2.3.1 Pin status when RESET pin level is “L”
Status
Pin name
CNV SS = VSS
P0, P2 , P3,
P40 to P4 3,
P50, P52, P53, P5 5,
P62, P63, P67,
P70 to P7 2, P74, P76,
P82,
P90, P93, P94,
P100, P10 1
Input port (floating)
R, G, B, OUT1,OUT2
Output port
CVIN, VHOLD ,
HLF
Input/output port
OSC1
Input port
OSC2
Output port
Rev. 1.0
20
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
Timer B0 interrupt control register
(005A16)···
? 0 0 0
Timer B1 interrupt control register
(005B16)···
? 0 0 0
4816
Timer B2 interrupt control register
(005C16)···
? 0 0 0
2016
INT0 interrupt control register
(005D16)···
0 0 ? 0 0 0
Processor mode register 0 (Note)
(000416)···
Processor mode register 1
(000516)··· 0 0 0 0 0
System clock control register 0
(000616)···
System clock control register 1
(000716)···
0016
0 0
Address match interrupt
enable register
(000916)···
0 0
INT1 interrupt control register
(005E16)···
0 0 ? 0 0 0
Protect register
(000A16)···
0 0 0
SPRITE OSD control register
(020116)···
0 0 0 0 0
Watchdog timer control register
(000F16)··· 0 0 0 ? ? ? ? ?
OSD control register 1
(020216)···
0016
Address match interrupt register 0
(001016)···
0016
OSD control register 2
(020316)···
0016
(001116)···
0016
Horizontal position register
(020416)···
0016
0016
Clock control register
(020516)···
(001416)···
0016
I/O polarity control register
(020616)··· 1 0 0 0 0 0 0 0
(001516)···
0016
OSD control register 3
(020716)···
0016
Raster color register
(020816)···
0016
(001216)···
Address match interrupt register 1
(001616)···
0 0 0 0
0 0 0 0
DMA0 control register
(002C16)··· 0 0 0 0 0 ? 0 0
(020916)···
0016
DMA1 control register
(003C16)··· 0 0 0 0 0 ? 0 0
OSD reserved register 1
(025D16)···
0016
OSD1 interrupt control register
(004416)···
? 0 0 0
OSD control register 4
(025F16)···
(004816)···
? 0 0 0
Data slicer control register 1
(026016)···
(004916)···
0 0 ? 0 0 0
Data slicer control register 2
(026116)··· ? 0 ? 0 ? ? 0 ?
(004A16)···
? 0 0 0
Caption position register
(026616)··· 0 0 ? 0 0 0 0 0
DMA0 interrupt control register
(004B16)···
? 0 0 0
Data slicer reserved register 2
(026716)···
0016
DMA1 interrupt control register
Multi-master I2C-BUS interface 0
interrupt control register
A-D conversion interrupt
control register
UART2 transmit interrupt
control register
UART2 receive interrupt
control register
UART0 transmit interrupt
control register
UART0 receive interrupt
control register
(004C16)···
? 0 0 0
Data slicer reserved register 1
(026816)···
0016
(004D16)···
? 0 0 0
Clock run-in detect register
(026916)···
0016
(004E16)···
? 0 0 0
Data clock position register
(026A16)···
0 0 0 0 1
(004F16)···
? 0 0 0
Left border control register
(027016)···
0116
(005016)···
? 0 0 0
(005116)···
? 0 0 0
(005216)···
? 0 0 0
OSD2 interrupt control register
Multi-master I2C-BUS interface 1
interrupt control register
Bus collision detection interrupt
control register
0 0
0016
0 0 0
(027116)···
Right border control register
(027216)···
0016
0 0 0
(027316)···
Data slicer interrupt control register
(005316)···
? 0 0 0
SPRITE horizontal position register
(high-order)
(027916)···
0 0 0
VSYNC interrupt control register
(005416)···
? 0 0 0
OSD reserved register 4
(027A16)···
0 0 0 0 0 0 0
Timer A0 interrupt control register
(005516)···
? 0 0 0
OSD reserved register 3
(027B16)···
0016
Timer A1 interrupt control register
(005616)···
? 0 0 0
OSD reserved register 2
(027C16)···
0016
Timer A2 interrupt control register
(005716)···
? 0 0 0
Peripheral mode register
(027D16)··· 0
0 0 0 0 0
Timer A3 interrupt control register
(005816)···
? 0 0 0
HSYNC counter register
(027E16)···
0 0
Timer A4 interrupt control register
(005916)···
? 0 0 0
0 0
X : Nothing is mapped to this bit
? : Undefined
The content of other registers and RAM is undefined when the microcomputer is reset. The initial values
must therefore be set.
Figure 2.3.3 Device’s internal status after a reset is cleared (1)
Rev. 1.0
21
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
I2C0 address register
(02E116)···
I2C0 status register
I2C0
0016
0 0 0 0 0 0 0
UART transmit/receive control register 2
(03B016)···
(02E216)··· 0 0 0 1 0 0 0 ?
DMA0 request cause select register
(03B816)···
0016
0016
control register
(02E316)···
0016
DMA1 request cause select register
(03BA16)···
I2C0 clock control register
(02E416)···
0016
A-D control register 2
(03D416)··· 0 0 0 0 ? ? ? 0
I2C0 port selection register
(02E516)··· 0 0 ? ? 0 0 0 0
A-D control register 0
(03D616)··· 0 0 0 0 0 ? ? ?
I2C1 address register
(02E916)···
A-D control register 1
(03D716)···
0016
I2C1
(02EA16)··· 0 0 0 1 0 0 0 ?
D-A control register
(03DC16)···
0016
I2C1 control register
(02EB16)···
0016
Port P0 direction register
(03E216)···
0016
I2C1
(02EC16)···
0016
status register
clock control register
0016
Port reserved register 2
(03E316)···
0016
I2C1 port selection register
(02ED16)··· 0 0 ? ? 0 0 0 0
Port P2 direction register
(03E616)···
0016
Reserved register 1
(034016)··· 0 0 0 ? ? ? ? ?
Port P3 direction register
(03E716)···
0016
Reserved register 0
(034816)···
0016
Port P4 direction register
(03EA16)···
0016
Interrupt request cause select register
(035F16)···
0016
Port P5 direction register
(03EB16)···
0016
Reserved register 3
(036216)···
4016
Port P6 direction register
(03EE16)···
0016
Reserved register 4
(036616)···
4016
Port P7 direction register
(03EF16)···
0016
Reserved register 5
(037616)···
0016
Port P8 direction register
(03F216)··· 0 0
0 0 0 0 0
UART2 special mode register
(037716)···
0016
Port P9 direction register
(03F316)···
0016
UART2 transmit/receive mode register
(037816)···
0016
Port P10 direction register
(03F616)···
0016
UART2 transmit/receive control register 0
(037C16)···
0816
Pull-up control register 0
(03FC16)···
0016
Pull-up control register 1(Note)
(03FD16)···
0016
Pull-up control register 2
(03FE16)···
0016
Port reserved register 3
(03FF16)···
UART2 transmit/receive control register 1
(037D16)···
0216
Count start flag
(038016)···
0016
Reserved register 6
(038116)··· 0
One-shot start flag
(038216)··· 0 0
0 0 0 0 0
Data registers (R0/R1/R2/R3)
000016
Trigger select register
(038316)···
0016
Address registers (A0/A1)
000016
Up-down flag
(038416)···
0016
Frame base register (FB)
000016
Timer A0 mode register
(039616)···
0016
Interrupt table register (INTB)
0000016
Timer A1 mode register
(039716)···
0016
User stack pointer (USP)
000016
Timer A2 mode register
(039816)···
0016
Interrupt stack pointer (ISP)
000016
Timer A3 mode register
(039916)···
0016
Static base register (SB)
000016
Timer A4 mode register
(039A16)···
0016
Flag register (FLG)
000016
Timer B0 mode register
(039B16)··· 0 0 ?
0 0 0 0
Timer B1 mode register
(039C16)··· 0 0 ?
0 0 0 0
Timer B2 mode register
(039D16)··· 0 0 ?
UART0 transmit/receive mode register
(03A016)···
0016
UART0 transmit/receive control register 0
(03A416)···
0816
UART0 transmit/receive control register 1
(03A516)···
0216
Reserved register 2
(03A816)···
0016
0016
0 0 0 0
x : Nothing is mapped to this bit
? : Undefined
The content of other registers and RAM is undefined when the microcomputer is reset. The initial values
must therefore be set.
Figure 2.3.4 Device’s internal status after a reset is cleared (2)
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2.4 Single-chip Mode
This microcomputer supports single-chip mode only.
In single-chip mode, only internal memory space (SFR, OSD RAM, internal RAM, and internal ROM) can
be accessed. Ports P0, P2 to P10 can be used as programmable I/O ports or as I/O ports for the internal
peripheral functions.
Figure 2.4.1 shows the processor mode register 0 and Figure 2.4.2 shows the processor mode register 1.
Figure 2.4.3 shows the memory map.
Processor mode register 0 (Note)
b7
b6
b5
b4
b3
b2
0 0 0 0
b1
Symbol
PM0
b0
Address
000416
When reset
0016
0 0 0
Bit symbol
PM00
Bit name
Processor mode bit
PM01
Reserved bit
PM03
Function
R W
b1 b0
0 0: Single-chip mode
0 1: Inhibited
1 0: Inhibited
1 1: Inhibited
Must always be set to “0”
Software reset bit
Reserved bits
The device is reset when this bit is set
to “1”. The value of this bit is “0” when
read.
Must always be set to “0”
Note : Set bit 1 of the protect register (address 000A16) to “1” when writing new
values to this register.
Figure 2.4.1 Processor mode register 0
Processor mode register 1 (Note 1)
b7
b6
b5
b4
0 0 0
b3
0
b2
b1
b0
1 0
Symbol
PM1
Address
000516
Bit symbol
Bit name
When reset
00000X002
Function
Reserved bit
Must always be set to “0”
Reserved bit (Note 2)
Must always be set to “1”
R W
Nothing is assigned.
In an attempt to write to this bit, write “0.” The value, if read, turns out to be
indeterminate.
Reserved bits
PM17
Must always be set to “0”
Wait bit
0 : No wait state
1 : Wait state inserted
Notes 1: Set bit 1 of the protect register (address 000A16) to “1” when writing new
values to this register.
2: As this bit becomes “0” at reset, must always be set to “1” after reset
release.
Figure 2.4.2 Processor mode register 1
Rev. 1.0
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0000016
SFR area
003FF16
0040016
OSD RAM
013FF16
0140016
Internal
reserved area
02BFF16
02C0016
Internal
RAM area
03FFF16
0400016
Internal
reserved area
8FFFF 16
9000016
OSD ROM
AFFFF16
B000016
Internal
reserved area
CFFFF16
D000016
Internal
ROM area
FFFFF16
Figure 2.4.3 Memory map in single-chip mode
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2.4.1 Software Wait
A software wait can be inserted by setting the wait bit (bit 7) of processor mode register 1 (address
000516).
A software wait is inserted in the internal ROM/RAM area by setting the wait bit of the processor mode
register 1. When set to “0”, each bus cycle is executed in one BCLK cycle. When set to “1”, each bus cycle
is executed in two BCLK cycles. After the microcomputer has been reset, this bit defaults to “0”.
The SFR area and the OSD RAM area is always accessed in two BCLK cycles regardless of the setting
of these control bits.
Table 2.4.1 shows the software wait and bus cycles. Figure 2.4.4 shows example bus timing when using
software waits.
Table 2.4.1 Software waits and bus cycles
Bus cycle
Area
Wait bit
SFR/
OSD RAM
Invalid
2 BCLK cycles
0
1 BCLK cycle
1
2 BCLK cycles
Internal
ROM/RAM
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< No wait >
Bus cycle
BCLK
Write signal
Read signal
Output
Data bus
Address bus
Address
Input
Address
Chip select
< With wait >
Bus cycle
BCLK
Write signal
Read signal
Data bus
Address bus
Input
Output
Address
Address
Chip select
Figure 2.4.4 Typical bus timings using software wait
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2.5 Clock Generating Circuit
The clock generating circuit contains each oscillator circuit that supplies the operating clock sources to the
CPU and internal peripheral units and that supplies the operating clock source to OSD.
Table 2.5.1. Clock oscillation circuits
Main clock oscillation circuit
Use of clock
OSD oscillation circuit
• CPU’s operating clock source
• OSD’s operating clock source
• Internal peripheral units’
operating clock source
Usable oscillator
• Ceramic resonator
• Ceramic resonator
(or quartz-crystal oscillator)
Pins to connect oscillator
(or quartz-crystal oscillator)
• LC oscillator
XIN, XOUT
OSC1, OSC2
Oscillation stop/restart function
Available
Oscillator status immediately after reset
Oscillating
Other
Externally derived clock can be input
2.5.1 Example of Oscillator Circuit
Figure 2.5.1 shows some examples of the main clock circuit, one using an oscillator connected to the
circuit, and the other one using an externally derived clock for input. Circuit constants in Figure 2.5.1 vary
with each oscillator used. Use the values recommended by the manufacturer of your oscillator.
Microcomputer
Microcomputer
(Built-in feedback resistor)
(Built-in feedback resistor)
XIN
XIN
XOUT
XOUT
Open
(Note)
Rd
Externally derived clock
C IN
COUT
Vcc
Vss
Note: 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.
When the oscillation drive capacity is set to low, check that oscillation is stable. When being specified to connect a
feedback resistor externally by the manufacture, connect a feedback resistor between pins XIN and XOUT.
Figure 2.5.1 Examples of main clock
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2.5.2 OSD Oscillation Circuit
The OSD clock oscillation circuit can obtain simply a clock for OSD by connecting an LC oscillator or a
ceramic resonator (or a quartz-crystal oscillator) across the pins OSC1 and OSC2. Which of LC oscillator
or a ceramic resonator (or a quartz-crystal oscillator) is selected by setting bits 1 and 2 of the clock control
register (address 020516).
Microcomputer
OSC1
OSC2
L
C1
C2
Figure 2.5.2 OSD clock connection example
2.5.3 Clock Control
Figure 2.5.3 shows the block diagram of the main clock generating circuit.
f1
f1SIO2
fAD
f8
Sub clock
f8SIO2
f32SIO2
CM10 “1”
Write signal
f32
S Q
XIN
XOUT
b
R
a
RESET
Software reset
c
d
Divider
BCLK
Main clock
CM02
Interrupt request
level judgment
output
S Q
WAIT instruction
R
c
b
a
1/2
1/2
1/2
1/2
1/2
CM06=0
CM17,CM16=11
CM06=1
CM06=0
CM17,CM16=10
d
CM06=0
CM17,CM16=01
CM06=0
CM17,CM16=00
CM0i : Bit i at address 000616
CM1i : Bit i at address 000716
WDCi : Bit i at address 000F16
Details of divider
Figure 2.5.3 Clock generating circuit
Rev. 1.0
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The following paragraphs describes the clocks generated by the clock generating circuit.
(1) Main clock
The main clock is generated by the main clock oscillation circuit. After a reset, the clock is divided by
8 to the BCLK. The clock can be stopped using the main clock stop bit (bit 5 at address 000616).
After the oscillation of the main clock oscillation circuit has stabilized, the drive capacity of the main
clock oscillation circuit can be reduced using the XIN-XOUT drive capacity select bit (bit 5 at address
000716). Reducing the drive capacity of the main clock oscillation circuit reduces the power dissipation. This bit changes to “1” when shifting from high-speed/medium-speed mode to stop mode and at
a reset.
(2) BCLK
The internal clock φ is the clock that drives the CPU, and is the clock derived by dividing the main
clock by 1, 2, 4, 8, or 16. The BCLK is derived by dividing the main clock by 8 after a reset.
The main clock division select bit 0 (bit 6 at address 000616) changes to “1” when shifting from highspeed/medium-speed to stop mode and at reset.
(3) Peripheral function clock (f1, f8, f32, f1SIO2, f8SIO2, f32SIO2, fAD)
The clock for the peripheral devices is derived by dividing the main clock by 1, 8 or 32. The peripheral
function clock is stopped by stopping the main clock or by setting the WAIT peripheral function clock
stop bit (bit 2 at 000616) to “1” and then executing a WAIT instruction.
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Figures 2.5.4 and 2.5.5 shows the system clock control registers 0 and 1.
System clock control register 0 (Note 1)
b7
b6
0
b5
b4
b3
b2
0 0 1
b1
b0
Symbol
CM0
0 0
Address
000616
Bit symbol
When reset
4816
Bit name
Must always be set to “0”
Reserved bits
CM02
WAIT peripheral function
clock stop bit
0 : Do not stop peripheral function clock in wait mode
1 : Stop peripheral function clock in wait mode
Reserved bit
Must always be set to “1”
Reserved bits
Must always be set to “0”
CM06
RW
Function
Main clock division select
bit 0 (Note 2)
0 : CM16 and CM17 valid
1 : Division by 8 mode
Must always be set to “0”
Reserved bit
Notes 1: Set bit 0 of the protect register (address 000A16) to “1” before writing to this register.
2: This bit changes to “1” when shifting from high-speed/medium-speed mode to stop mode and at a reset.
Figures 2.5.4 System clock control register 0
System clock control register 1 (Note 1)
b7
b6
b5
b4
b3
b2
b1
0 0 0 0
b0
Symbol
CM1
Address
000716
Bit symbol
CM10
When reset
2016
Bit name
All clock stop control bit
(Note 4)
Reserved bits
Function
RW
0 : Clock on
1 : All clocks off (stop mode)
Must always be set to “0”
CM15
XIN-XOUT drive capacity
select bit (Note 2)
0 : LOW
1 : HIGH
CM16
Main clock division
select bit 1 (Note 3)
0 0 : No division mode
0 1 : Division by 2 mode
1 0 : Division by 4 mode
1 1 : Division by 16 mode
b7 b6
CM17
Notes 1: Set bit 0 of the protect register (address 000A16) to “1” before writing to this register.
2: This bit changes to “1” when shifting from high-speed/medium-speed mode to stop mode and at a
reset.
3: Can be selected when bit 6 of the system clock control register 0 (address 000616) is “0.”
If “1”, division mode is fixed at 8.
4: If this bit is set to “1,” XOUT turns “H,” and the built-in feedback resistor is cut off.
Figure 2.5.5 System clock control register 1
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2.5.4 Stop Mode
Writing “1” to the all-clock stop control bit (bit 0 at address 000716) stops all oscillation and the microcomputer enters stop mode. In stop mode, the content of the internal RAM is retained provided that VCC
remains above 4.5V.
Because the oscillation, BCLK, f1 to f32, f1SIO2 to f32SIO2, and fAD stops in stop mode, peripheral functions
such as the A-D converter and watchdog timer do not function. However, timer B operates provided that
the event counter mode is set to an external pulse, and UARTi (i = 0, 2) functions provided an external
clock is selected. Table 2.5.2 shows the status of the ports in stop mode.
Stop mode is cancelled by a hardware reset or an interrupt. If an interrupt is to be used to cancel stop
mode, that interrupt must first have been enabled. If returning by an interrupt, that interrupt routine is
executed.
When shifting from high-speed/medium-speed mode to stop mode and at a reset, the main clock division
select bit 0 (bit 6 at address 000616) is set to “1.” When shifting from low-speed/low power dissipation
mode to stop mode, the value before stop mode is retained.
Table 2.5.2 Port status during stop mode
Pin
State
Port
Retains status before stop mode
2.5.5 Wait Mode
When a WAIT instruction is executed, the BCLK stops and the microcomputer enters the wait mode. In
this mode, oscillation continues but the BCLK and watchdog timer stop. Writing “1” to the WAIT peripheral
function clock stop bit and executing a WAIT instruction stops the clock being supplied to the internal
peripheral functions, allowing power dissipation to be reduced. Table 2.5.3 shows the status of the ports
in wait mode.
Wait mode is cancelled by a hardware reset or an interrupt. If an interrupt is used to cancel wait mode, the
microcomputer restarts from the interrupt routine using as BCLK, the clock that had been selected when
the WAIT instruction was executed.
Table 2.5.3 Port status during wait mode
Pin
State
Port
Retains status before wait mode
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2.5.6 Status Transition of BCLK
Power dissipation can be reduced and low-voltage operation achieved by changing the count source for
BCLK. Table 2.5.4 shows the operating modes corresponding to the settings of system clock control
registers 0 and 1.
After a reset, operation defaults to division by 8 mode. When shifting to stop mode, the main clock division
select bit 0 (bit 6 at address 000616) is set to “1”. The following shows the operational modes of internal
clock φ.
(1) Division by 2 mode
The main clock is divided by 2 to obtain the BCLK.
(2) Division by 4 mode
The main clock is divided by 4 to obtain the BCLK.
(3) Division by 8 mode
The main clock is divided by 8 to obtain the BCLK. Note that oscillation of the main clock must have
stabilized before transferring from this mode to another mode.
(4) Division by 16 mode
The main clock is divided by 16 to obtain the BCLK.
(5) No-division mode
The main clock is used as the BCLK.
Table 2.5.4 Operating modes dictated by settings of system clock control registers 0 and 1
CM17
CM16
CM06
CM04
Operating mode of BCLK
0
1
0
Invalid
Division by 2 mode
1
0
0
Invalid
Division by 4 mode
Invalid
Invalid
1
Invalid
Division by 8 mode
1
1
0
Invalid
Division by 16 mode
0
0
0
Invalid
No-division mode
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2.5.7 Power Control
The following is a description of the three available power control modes:
Modes
Power control is available in three modes.
(1) Normal operation mode
■ High-speed mode
Divide-by-1 frequency of the main clock becomes the BCLK. The CPU operates with the internal
clock selected. Each peripheral function operates according to its assigned clock.
■ Medium-speed mode
Divide-by-2, divide-by-4, divide-by-8, or divide-by-16 frequency of the main clock becomes the
BCLK. The CPU operates according to the internal clock selected. Each peripheral function operates
according to its assigned clock.
(2) Wait mode
The CPU operation is stopped. The oscillators do not stop.
(3) Stop mode
All oscillators stop. The CPU and all built-in peripheral functions stop. This mode, among the three
modes listed here, is the most effective in decreasing power consumption.
Figure 2.5.6 is the state transition diagram of the above modes.
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Transition of stop mode, wait mode
Reset
WAIT
instruction
CM10 = “1”
Medium-speed mode
(Divided-by-8 mode)
Stop mode
All oscillators stopped
Interrupt
Interrupt
CPU operation stopped
Interrupt
WAIT
instruction
High-speed/
medium-speed
mode
CM10 = “1”
Stop mode
Wait mode
Wait mode
Interrupt
All oscillators stopped
CPU operation stopped
(See the figure below as for transition of normal mode)
Transition of normal mode
Main clock is oscillating
Medium-speed mode (divided-by-8 mode)
BCLK : f(XIN)/8
CM06 = “1”
CM06 = “0”
CM06 = “1”
Main clock is oscillating
High-speed mode
BCLK : f(XIN)
CM06 = “0”
CM17 = “0” CM16 = “0”
Medium-speed mode (divided-by-4)
BCLK: f(XIN)/4
CM06 = “0”
CM17 = “1” CM16 = “0”
Medium-speed mode (divided-by-2)
BCLK : f(XIN)/2
CM06 = “0”
CM17 = “0” CM16 = “1”
Medium-speed mode (divided-by-16)
BCLK : f(XIN)/16
CM06 = “0”
CM17 = “1” CM16 = “1”
Notes 1: Switch clocks after oscillation of main clock is
sufficiently stable.
2:Change CM06 after changing CM17 and
CM16.
3: Transit in accordance with arrows.
Figure 2.5.6 State transition diagram of Power control mode
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2.6 Protection
The protection function is provided so that the values in important registers cannot be changed in the event
that the program runs out of control. Figure 2.6.1 shows the protect register. The values in the processor
mode register 0 (address 000416), processor mode register 1 (address 000516), system clock control register 0 (address 000616), system clock control register 1 (address 000716) and port P9 direction register
(address 03F316) can only be changed when the respective bit in the protect register is set to “1”. Therefore, important outputs can be allocated to port P9.
If, after “1” (write-enabled) has been written to the port P9 direction register write-enable bit (bit 2 at address
000A16), a value is written to any address, the bit automatically reverts to “0” (write-inhibited). However, the
system clock control registers 0 and 1 write-enable bit (bit 0 at 000A16) and processor mode register 0 and
1 write-enable bit (bit 1 at 000A16) do not automatically return to “0” after a value has been written to an
address. The program must therefore be written to return these bits to “0”.
Protect register
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
PRCR
Address
000A 16
When reset
XXXXX000 2
Bit symbol
Bit name
PRC0
Enables writing to system clock
control registers 0 and 1 (addresses
000616 and 0007 16)
PRC1
Enables writing to processor mode
0 : Write-inhibited
registers 0 and 1 (addresses 0004 16
1 : Write-enabled
and 0005 16)
PRC2
Enables writing to port P9 direction
register (address 03F3 16)
(Note)
Function
R W
0 : Write-inhibited
1 : Write-enabled
0 : Write-inhibited
1 : Write-enabled
Nothing is assigned.
In an attempt to write to these bits, write “0.” The value, if read, turns out to be
indeterminate.
Note: Writing a value to an address after “1” is written to this bit returns the bit
to “0.” Other bits do not automatically return to “0” and they must therefore
be reset by the program.
Figure 2.6.1 Protect register
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2.7 Interrupts
2.7.1 Type of Interrupts
Figure 2.7.1 lists the types of interrupts.










Hardware
Special
Peripheral I/O (Note)
















Interrupt
Software
Undefined instruction (UND instruction)
Overflow (INTO instruction)
BRK instruction
INT instruction
Reset
DBC
________
Watchdog timer
Single step
Address matched
Note: Peripheral I/O interrupts are generated by the peripheral functions built into the microcomputer system.
Figure 2.7.1 Classification of interrupts
• Maskable interrupt :
An interrupt which can be enabled (disabled) by the interrupt enable flag
(I flag) or whose interrupt priority can be changed by priority level.
• Non-maskable interrupt : An interrupt which cannot be enabled (disabled) by the interrupt enable flag
(I flag) or whose interrupt priority cannot be changed by priority level.
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2.7.2 Software Interrupts
A software interrupt occurs when executing certain instructions. Software interrupts are non-maskable
interrupts.
• Undefined instruction interrupt
An undefined instruction interrupt occurs when executing the UND instruction.
• Overflow interrupt
An overflow interrupt occurs when executing the INTO instruction with the overflow flag (O flag) set to
“1”. The following are instructions whose O flag changes by arithmetic:
ABS, ADC, ADCF, ADD, CMP, DIV, DIVU, DIVX, NEG, RMPA, SBB, SHA, SUB
• BRK interrupt
A BRK interrupt occurs when executing the BRK instruction.
• INT interrupt
An INT interrupt occurs when assiging one of software interrupt numbers 0 through 63 and executing
the INT instruction. Software interrupt numbers 0 through 31 are assigned to peripheral I/O interrupts,
so executing the INT instruction allows executing the same interrupt routine that a peripheral I/O
interrupt does.
The stack pointer (SP) used for the INT interrupt is dependent on which software interrupt number is
involved.
So far as software interrupt numbers 0 through 31 are concerned, the microcomputer saves the stack
pointer assignment flag (U flag) when it accepts an interrupt request. If change the U flag to “0” and
select the interrupt stack pointer (ISP), and then execute an interrupt sequence. When returning from
the interrupt routine, the U flag is returned to the state it was before the acceptance of interrupt request. So far as software numbers 32 through 63 are concerned, the stack pointer does not make a
shift.
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2.7.3 Hardware Interrupts
Hardware interrupts are classified into two types — special interrupts and peripheral I/O interrupts.
(1) Special interrupts
Special interrupts are non-maskable interrupts.
• Reset
____________
Reset occurs if an “L” is input to the RESET pin.
________
• DBC interrupt
This interrupt is exclusively for the debugger, do not use it in other circumstances.
• Watchdog timer interrupt
Generated by the watchdog timer.
• Single-step interrupt
This interrupt is exclusively for the debugger, do not use it in other circumstances. With the debug
flag (D flag) set to “1,” a single-step interrupt occurs after one instruction is executed.
• Address match interrupt
An address match interrupt occurs immediately before the instruction held in the address indicated
by the address match interrupt register is executed with the address match interrupt enable bit set to
“1.” If an address other than the first address of the instruction in the address match interrupt register
is set, no address match interrupt occurs. For address match interrupt, see 2.11 Address match
Interrupt.
(2) Peripheral I/O interrupts
A peripheral I/O interrupt is generated by one of built-in peripheral functions. Built-in peripheral functions are dependent on classes of products, so the interrupt factors too are dependent on classes of
products. The interrupt vector table is the same as the one for software interrupt numbers 0 through
31 the INI instruction uses. Peripheral I/O interrupts are maskable interrupts.
• Bus collision detection interrupt
This is an interrupt that the serial I/O bus collision detection generates.
• DMA0 interrupt, DMA1 interrupt
These are interrupts DMA generates.
• VSYNC interrupt
VSYNC interrupt occurs if a VSYNC edge is input.
• A-D conversion interrupt
This is an interrupt that the A-D converter generates.
• UART0 transmission, UART2 transmission interrupts
These are interrupts that the serial I/O transmission generates.
• UART0 reception, UART2 reception interrupts
These are interrupts that the serial I/O reception generates.
• Multi-master I2C-BUS interface 0 and multi-master I2C-BUS interface 1 interrupts
This is an interrupt that the serial I/O transmission/reception is completed, or a STOP condition is
detected.
• Timer A0 interrupt through timer A4 interrupt
These are interrupts that timer A generates
• Timer B0 interrupt through timer B2 interrupt
These are interrupts that timer B generates.
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________
________
• INT0 interrupt and INT1 interrupt
______
______
An INT interrupt occurs if either a rising edge or a falling edge or a both edge is input to the INT pin.
• OSD1 interrupt and OSD2 interrupt
These are interrupts that OSD display is completed.
• Data slicer interrupt
This is an interrupt that data slicer circuit requests.
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2.7.4 Interrupts and Interrupt Vector Tables
If an interrupt request is accepted, a program branches to the interrupt routine set in the interrupt vector
table. Set the first address of the interrupt routine in each vector table. Figure 2.7.2 shows the format for
specifying the address.
Two types of interrupt vector tables are available — fixed vector table in which addresses are fixed and
variable vector table in which addresses can be varied by the setting.
AAAAAAAA
AAAAAAAA
AAAAAAAA
AAAAAAAA
AAAAAAAA
MSB
Vector address + 0
Vector address + 1
Vector address + 2
Vector address + 3
LSB
Low address
Mid address
0000
High address
0000
0000
Figure 2.7.2 Format for specifying interrupt vector addresses
(1) Fixed vector tables
The fixed vector table is a table in which addresses are fixed. The vector tables are located in an area
extending from FFFDC16 to FFFFF16. One vector table comprises four bytes. Set the first address of
interrupt routine in each vector table. Table 2.7.1 shows the interrupts assigned to the fixed vector
tables and addresses of vector tables.
Table 2.7.1 Interrupts assigned to the fixed vector tables and addresses of vector tables
Interrupt source
Vector table addresses
Remarks
Address (L) to address (H)
Undefined instruction
Overflow
FFFDC16 to FFFDF16
FFFE016 to FFFE316
Interrupt on UND instruction
Interrupt on INTO instruction
BRK instruction
FFFE416 to FFFE716
If the vector is filled with FF16, program execution starts from
Address match
FFFE816 to FFFEB16
There is an address-matching interrupt enable bit
Single step (Note)
FFFEC16 to FFFEF16
Do not use
Watchdog timer
FFFF016 to FFFF316
the address shown by the vector in the variable vector table
________
DBC (Note)
FFFF416 to FFFF716
Do not use
Reserved source
FFFE816 to FFFEB16
Do not use
Reset
FFFFC16 to FFFFF16
Note: Interrupts used for debugging purposes only.
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(2) Variable vector tables
The fixed vector table is a table in which addresses are fixed. The vector tables are located in an area
extending from FFFDC16 to FFFFF16. One vector table comprises four bytes. Set the first address of
interrupt routine in each vector table. Table 2.7.2 shows the interrupts assigned to the fixed vector
tables and addresses of vector tables.
Table 2.7.2 Interrupts assigned to the variable vector tables and addresses of vector tables
Software interrupt number
Vector table address
Interrupt source
Address (L) to address (H)
Software interrupt number 0
+0 to +3 (Note)
BRK instruction
Software interrupt number 4
+16 to +19 (Note)
OSD1
Software interrupt number 5
+20 to +23 (Note)
Reserved source
Software interrupt number 6
+24 to +27 (Note)
Reserved source
Software interrupt number 7
+28 to +31 (Note)
Reserved source
Software interrupt number 8
+32 to +35 (Note)
OSD2
Software interrupt number 9
+36 to +39 (Note)
Multi-master I2C-BUS interface 1
Software interrupt number 10
+40 to +43 (Note)
Bus collision detection
Software interrupt number 11
+44 to +47 (Note)
DMA0
Software interrupt number 12
+48 to +51 (Note)
DMA1
Software interrupt number 13
+52 to +55 (Note)
Multi-master I2C-BUS interface 0
Software interrupt number 14
+56 to +59 (Note)
A-D conversion
Software interrupt number 15
+60 to +63 (Note)
UART2 transmit
Software interrupt number 16
+64 to +67 (Note)
UART2 receive
Software interrupt number 17
+68 to +71 (Note)
UART0 transmit
Software interrupt number 18
+72 to +75 (Note)
UART0 receive
Software interrupt number 19
+76 to +79 (Note)
Data slicer
Software interrupt number 20
+80 to +83 (Note)
VSYNC
Software interrupt number 21
+84 to +87 (Note)
Timer A0
Software interrupt number 22
+88 to +91 (Note)
Timer A1
Software interrupt number 23
+92 to +95 (Note)
Timer A2
Software interrupt number 24
+96 to +99 (Note)
Timer A3
Software interrupt number 25
+100 to +103 (Note)
Timer A4
Software interrupt number 26
+104 to +107 (Note)
Timer B0
Software interrupt number 27
+108 to +111 (Note)
Timer B1
Software interrupt number 28
+112 to +115 (Note)
Timer B2
Software interrupt number 29
+116 to +119 (Note)
INT0
Software interrupt number 30
+120 to +123 (Note)
INT1
Software interrupt number 31
+124 to +127 (Note)
Reserved source
Software interrupt number 32
+128 to +131 (Note)
to
Software interrupt number 63
to
+252 to +255 (Note)
Software interrupt
Remarks
Cannot be masked I flag
Cannot be masked I flag
Note: Address relative to address in interrupt table register (INTB).
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2.7.5 Interrupt Control
Descriptions are given here regarding how to enable or disable maskable interrupts and how to set the
priority to be accepted. What is described here does not apply to non-maskable interrupts.
Enable or disable a non-maskable interrupt using the interrupt enable flag (I flag), interrupt priority level
selection bit, or processor interrupt priority level (IPL). Whether an interrupt request is present or absent
is indicated by the interrupt request bit. The interrupt request bit and the interrupt priority level selection
bit are located in the interrupt control register of each interrupt. Also, the interrupt enable flag (I flag) and
the IPL are located in the flag register (FLG).
Figure 2.7.3 shows the interrupt control registers.
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Symbol
OSDiIC(i = 1, 2)
BCNIC
DMiIC(i = 0, 1)
IIC0IC
ADIC
SiTIC(i = 0 , 2)
SiRIC(i = 0 , 2)
DSIC
VSYNCIC
TAiIC(i = 0 to 4)
TBiIC(i = 0 to 2)
Interrupt control register
b7
b6
b5
b4
b3
b2
b1
b0
Bit symbol
ILVL0
Address
004416, 0048 16
004A 16
004B 16, 004C 16
004D 16
004E 16
0051 16, 004F16
0052 16, 0050 16
0053 16
0054 16
0055 16 to 0059 16
005A16 to 005C 16
Bit name
Interrupt priority level
select bit
ILVL1
ILVL2
IR
Interrupt request bit
When reset
XXXX?000 2
XXXX?000 2
XXXX?000 2
XXXX?000 2
XXXX?000 2
XXXX?000 2
XXXX?000 2
XXXX?000 2
XXXX?000 2
XXXX?000 2
XXXX?000 2
Function
R
W
b2 b1 b0
000:
001:
010:
011:
100:
101:
110:
111:
Level 0 (interrupt disabled)
Level 1
Level 2
Level 3
Level 4
Level 5
Level 6
Level 7
0 : Interrupt not requested
1 : Interrupt requested
(Note)
Nothing is assigned.
In an attempt to write to these bits, write “0.” The value, if read, turns out to
be indeterminate.
Notes 1: This bit can only be accessed for reset (= 0), but cannot be accessed for set (= 1).
2: To rewrite the interrupt control register, do so at a point that does not generate the
interrupt register for that register. For details, see the precautions for interrupts.
b7
b6
b5
0
b4
b3
b2
b1
b0
Symbol
INTiIC(i = 0, 1)
IIC1IC
Bit symbol
ILVL0
Address
005D 16, 005E16
0049 16
Bit name
Interrupt priority level
select bit
ILVL1
ILVL2
IR
POL
When reset
XX00?000 2
XX00?000 2
Interrupt request bit
Polarity select bit
(Note 2)
Reserved bit
Function
R
W
b2 b1 b0
0 0 0 : Level 0 (interrupt disabled)
0 0 1 : Level 1
0 1 0 : Level 2
0 1 1 : Level 3
1 0 0 : Level 4
1 0 1 : Level 5
1 1 0 : Level 6
1 1 1 : Level 7
0: Interrupt not requested
1: Interrupt requested
(Note 1)
0 : Selects falling edge
1 : Selects rising edge
Must always be set to “0”
Nothing is assigned.
In an attempt to write to these bits, write “0.” The value, if read, turns out to
be indeterminate.
Notes 1: This bit can only be accessed for reset (= 0), but cannot be accessed for set (= 1).
2: Bit 4 at address 0049 16 is invalid. Must always be set to “0.”
3: To rewrite the interrupt control register, do so at a point that does not generate the
interrupt register for that register. For details, see the precautions for interrupts.
Figure 2.7.3 Interrupt control registers
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2.7.6 Interrupt Enable Flag (I flag)
The interrupt enable flag (I flag) controls the enabling and disabling of maskable interrupts. Setting this
flag to “1” enables all maskable interrupts; setting it to “0” disables all maskable interrupts. This flag is set
to “0” after reset.
2.7.7 Interrupt Request Bit
The interrupt request bit is set to "1" by hardware when an interrupt is requested. After the interrupt is
accepted and jumps to the corresponding interrupt vector, the request bit is set to "0" by hardware. The
interrupt request bit can also be set to "0" by software. (Do not set this bit to "1").
2.7.8 Interrupt Priority Level Select Bit and Processor Interrupt Priority Level (IPL)
Set the interrupt priority level using the interrupt priority level select bit, which is one of the component bits
of the interrupt control register. When an interrupt request occurs, the interrupt priority level is compared
with the IPL. The interrupt is enabled only when the priority level of the interrupt is higher than the IPL.
Therefore, setting the interrupt priority level to “0” disables the interrupt.
Table 2.7.3 shows the settings of interrupt priority levels and Table 2.7.4 shows the interrupt levels enabled, according to the consist of the IPL.
The following are conditions under which an interrupt is accepted:
· interrupt enable flag (I flag) = 1
· interrupt request bit = 1
· interrupt priority level > IPL
The interrupt enable flag (I flag), the interrupt request bit, the interrupt priority select bit, and the IPL are
independent, and they are not affected by one another.
Table 2.7.3 Settings of interrupt priority levels
Table 2.7.4 Interrupt levels enabled according
to the contents of the IPL
Interrupt priority
level select bit
Interrupt priority
level
Priority
order
b2 b1 b0
IPL
Enabled interrupt priority levels
IPL2 IPL1 IPL0
0
0
0
Level 0 (interrupt disabled)
0
0
0
Interrupt levels 1 and above are enabled
0
0
1
Level 1
0
0
1
Interrupt levels 2 and above are enabled
0
1
0
Level 2
0
1
0
Interrupt levels 3 and above are enabled
0
1
1
Level 3
0
1
1
Interrupt levels 4 and above are enabled
1
0
0
Level 4
1
0
0
Interrupt levels 5 and above are enabled
1
0
1
Level 5
1
0
1
Interrupt levels 6 and above are enabled
1
1
0
Level 6
1
1
0
Interrupt levels 7 and above are enabled
1
1
1
Level 7
1
1
1
All maskable interrupts are disabled
Low
High
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2.7.9 Rewrite Interrupt Control Register
To rewrite the interrupt control register, do so at a point that does not generate the interrupt request for
that register. If there is possibility of the interrupt request occur, rewrite the interrupt control register after
the interrupt is disabled. The program examples are described as follow:
Example 1:
INT_SWITCH1:
FCLR
I
AND.B #00h, 0055h
NOP
NOP
FSET
I
; Disable interrupts.
; Clear TA0IC int. priority level and int. request bit.
; Enable interrupts.
Example 2:
INT_SWITCH2:
FCLR
I
AND.B #00h, 0055h
MOV.W MEM, R0
FSET
I
; Disable interrupts.
; Clear TA0IC int. priority level and int. request bit.
; Dummy read.
; Enable interrupts.
Example 3:
INT_SWITCH3:
PUSHC FLG
FCLR
I
AND.B #00h, 0055h
POPC FLG
; Push Flag register onto stack
; Disable interrupts.
; Clear TA0IC int. priority level and int. request bit.
; Enable interrupts.
The reason why two NOP instructions or dummy read are inserted before FSET I in Examples 1 and 2 is
to prevent the interrupt enable flag I from being set before the interrupt control register is rewritten due to
effects of the instruction queue.
When a instruction to rewrite the interrupt control register is executed but the interrupt is disabled, the
interrupt request bit is not set sometimes even if the interrupt request for that register has been generated. This will depend on the instruction. If this creates problems, use the below instructions to change
the register.
Instructions : AND, OR, BCLR, BSET
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2.7.10 Interrupt Sequence
An interrupt sequence — what are performed over a period from the instant an interrupt is accepted to the
instant the interrupt routine is executed — is described here.
If an interrupt occurs during execution of an instruction, the processor determines its priority when the
execution of the instruction is completed, and transfers control to the interrupt sequence from the next
cycle. If an interrupt occurs during execution of either the SMOVB, SMOVF, SSTR or RMPA instruction,
the processor temporarily suspends the instruction being executed, and transfers control to the interrupt
sequence.
In the interrupt sequence, the processor carries out the following in sequence given:
(1) CPU gets the interrupt information (the interrupt number and interrupt request level) by reading address 0000016.
(2) Saves the content of the flag register (FLG) as it was immediately before the start of interrupt sequence in the temporary register (Note) within the CPU.
(3) Sets the interrupt enable flag (I flag), the debug flag (D flag), and the stack pointer select flag (U flag)
to “0” (the U flag, however does not change if the INT instruction, in software interrupt numbers 32
through 63, is executed)
(4) Saves the content of the temporary register (Note 1) within the CPU in the stack area.
(5) Saves the content of the program counter (PC) in the stack area.
(6) Sets the interrupt priority level of the accepted instruction in the IPL.
After the interrupt sequence is completed, the processor resumes executing instructions from the first
address of the interrupt routine.
Note: This register cannot be utilized by the user.
2.7.11 Interrupt Response Time
'Interrupt response time' is the period between the instant an interrupt occurs and the instant the first
instruction within the interrupt routine has been executed. This time comprises the period from the
occurrence of an interrupt to the completion of the instruction under execution at that moment (a) and the
time required for executing the interrupt sequence (b). Figure 2.7.4 shows the interrupt response time.
Interrupt request generated
Interrupt request acknowledged
Time
Instruction
(a)
Interrupt sequence
Instruction in
interrupt routine
(b)
Interrupt response time
Figure 2.7.4 Interrupt response time
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Time (a) is dependent on the instruction under execution. Thirty cycles is the maximum required for the
DIVX instruction (without wait).
Time (b) is as shown in Table 2.7.5.
Table 2.7.5 Time required for executing the interrupt sequence
Interrupt vector address
Stack pointer (SP) value
16-Bit bus, without wait
8-Bit bus, without wait
Even
Even
18 cycles (Note 1)
20 cycles (Note 1)
Even
Odd
19 cycles (Note 1)
20 cycles (Note 1)
Odd (Note 2)
Even
19 cycles (Note 1)
20 cycles (Note 1)
Odd (Note 2)
Odd
20 cycles (Note 1)
20 cycles (Note 1)
________
Notes 1: Add 2 cycles in the case of a DBC interrupt; add 1 cycle in the case either of an address coincidence interrupt or of a single-step interrupt.
2: Locate an interrupt vector address in an even address, if possible.
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
BCLK
Address bus
Data bus
Address
0000
Interrupt
information
R
Indeterminate
Indeterminate
SP-2
SP-4
SP-2
contents
SP-4
contents
vec
vec+2
vec
contents
PC
vec+2
contents
Indeterminate
W
The indeterminate segment is dependent on the queue buffer.
If the queue buffer is ready to take an instruction, a read cycle occurs.
Figure 2.7.5 Time required for executing the interrupt sequence
2.7.12 Variation of IPL when Interrupt Request is Accepted
If an interrupt request is accepted, the interrupt priority level of the accepted interrupt is set in the IPL.
If an interrupt request, that does not have an interrupt priority level, is accepted, one of the values shown
in Table 2.7.6 is set in the IPL.
Table 2.7.6 Relationship between interrupts without interrupt priority levels and IPL
Interrupt sources without priority levels
Value set in the IPL
Watchdog timer
7
Reset
0
Other
Not changed
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2.7.13 Saving Registers
In the interrupt sequence, only the contents of the flag register (FLG) and that of the program counter
(PC) are saved in the stack area.
First, the processor saves the four higher-order bits of the program counter, and 4 upper-order bits and 8
lower-order bits of the FLG register, 16 bits in total, in the stack area, then saves 16 lower-order bits of the
program counter. Figure 2.7.6 shows the state of the stack as it was before the acceptance of the interrupt request, and the state the stack after the acceptance of the interrupt request.
Save other necessary registers at the beginning of the interrupt routine using software. Using the
PUSHM instruction alone can save all the registers except the stack pointer (SP).
Address
MSB
Stack area
Address
MSB
LSB
Stack area
LSB
m–4
m–4
Program counter (PCL)
m–3
m–3
Program counter (PCM)
m–2
m–2
Flag register (FLGL)
m–1
m–1
m
Content of previous stack
m+1
Content of previous stack
Stack status before interrupt request
is acknowledged
[SP]
Stack pointer
value before
interrupt occurs
Flag register
(FLGH)
[SP]
New stack
pointer value
Program
counter (PCH)
m
Content of previous stack
m+1
Content of previous stack
Stack status after interrupt request
is acknowledged
Figure 2.7.6 State of stack before and after acceptance of interrupt request
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The operation of saving registers carried out in the interrupt sequence is dependent on whether the
content of the stack pointer, at the time of acceptance of an interrupt request, is even or odd. If the
content of the stack pointer (Note) is even, the content of the flag register (FLG) and the content of the
program counter (PC) are saved, 16 bits at a time. If odd, their contents are saved in two steps, 8 bits at
a time. Figure 2.7.7 shows the operation of the saving registers.
Note: Stack pointer indicated by U flag.
(1) Stack pointer (SP) contains even number
Address
Stack area
Sequence in which order
registers are saved
[SP] – 5 (Odd)
[SP] – 4 (Even)
Program counter (PCL)
[SP] – 3(Odd)
Program counter (PCM)
[SP] – 2 (Even)
Flag register (FLGL)
[SP] – 1(Odd)
[SP]
Flag register
(FLGH)
Program
counter (PCH)
(2) Saved simultaneously,
all 16 bits
(1) Saved simultaneously,
all 16 bits
(Even)
Finished saving registers
in two operations.
(2) Stack pointer (SP) contains odd number
Address
Stack area
Sequence in which order
registers are saved
[SP] – 5 (Even)
[SP] – 4(Odd)
Program counter (PCL)
(3)
[SP] – 3 (Even)
Program counter (PCM)
(4)
[SP] – 2(Odd)
Flag register (FLGL)
[SP] – 1 (Even)
[SP]
Flag register
(FLGH)
Program
counter (PCH)
Saved simultaneously,
all 8 bits
(1)
(2)
(Odd)
Finished saving registers
in four operations.
Note: [SP] denotes the initial value of the stack pointer (SP) when interrupt request is acknowledged.
After registers are saved, the SP content is [SP] minus 4.
Figure 2.7.7 Operation of saving registers
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2.7.14 Returning from an Interrupt Routine
Executing the REIT instruction at the end of an interrupt routine returns the contents of the flag register
(FLG) as it was immediately before the start of interrupt sequence and the contents of the program
counter (PC), both of which have been saved in the stack area. Then control returns to the program that
was being executed before the acceptance of the interrupt request, so that the suspended process resumes.
Return the other registers saved by software within the interrupt routine using the POPM or similar instruction before executing the REIT instruction.
2.7.15 Interrupt Priority
If there are two or more interrupt requests occurring at a point in time within a single sampling (checking
whether interrupt requests are made), the interrupt assigned a higher priority is accepted.
Assign an arbitrary priority to maskable interrupts (peripheral I/O interrupts) using the interrupt priority
level select bit. If the same interrupt priority level is assigned, however, the interrupt assigned a higher
hardware priority is accepted.
Priorities of the special interrupts, such as Reset (dealt with as an interrupt assigned the highest priority),
watchdog timer interrupt, etc. are regulated by hardware.
Figure 2.7.8 shows the priorities of hardware interrupts.
Software interrupts are not affected by the interrupt priority. If an instruction is executed, control branches
invariably to the interrupt routine.
2.7.16 Interrupt priority level resolution circuit
When two or more interrupts are generated simultaneously, this circuit selects the interrupt with the highest
priority level.
Figure 2.7.9 shows the circuit that judges the interrupt priority level.
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________
Reset > DBC > Watchdog timer > Peripheral I/O > Single step > Address match
Figure 2.7.8 Hardware interrupts priorities
Priority level of each interrupt
INT1
Level 0 (initial value)
High
Timer B2
Timer B0
Timer A3
Timer A1
OSD1
INT0
Timer B1
Timer A4
Timer A2
VSYNC
UART0 reception
UART2 reception
A-D conversion
DMA1
Priority of peripheral I/O interrupts
(if priority levels are same)
Bus collision detection
OSD2
Timer A0
Data slicer
UART0 transmission
UART2 transmission
Multi-master I2C-BUS interface 0
DMA0
Multi-master I2C-BUS interface 1
Low
Processor interrupt priority level (IPL)
Interrupt enable flag (I flag)
Interrupt request accepted
Address match
Watchdog timer
DBC
Reset
Figure 2.7.9 Maskable interrupts priorities (peripheral I/O interrupts)
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______
2.7.17 INT Interrupt
________
________
INT0 and INT1 are triggered by the edges of external inputs. The edge polarity is selected using the
polarity select bit.
As for external interrupt input, an interrupt can be generated both at the rising edge and at the falling edge
by setting “1” in the INTi interrupt polarity switching bit of the interrupt request cause select register
(035F16). To select both edges, set the polarity switching bit of the corresponding interrupt control register to ‘falling edge’ (“0”).
Figure 2.7.10 shows the Interrupt control reserved register, Figure 2.7.11 shows the Interrupt request
cause select register.
Interrupt control reserved register i
b7
b6
0
0 0 0
b5
b4
b3
b2
b1
b0
0 0
0
0
Symbol
REiIC (i = 0 to 3)
Address
004516, 004616, 004716, 005F16
Bit name
Bit symbol
When reset
Indeterminate
Function
R W
Must always be set to “0”
Reserved bits
Figure 2.7.10 Interrupt control reserved register i (i = 0 to 3)
Interrupt request cause select register
b7
b6
b5
b4
b3
b2
0
0
0 0
0
0
b1
b0
Symbol
IFSR
Address
035F16
Bit name
Bit symbol
When reset
0016
Function
IFSR0
INT0 interrupt polarity
switching bit
0 : One edge
1 : Two edges
IFSR1
INT1 interrupt polarity
switching bit
0 : One edge
1 : Two edges
Reserved bits
R W
Must always be set to “0”
Figure 2.7.11 Interrupt request cause select register
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2.7.18 Address Match Interrupt
An address match interrupt is generated when the address match interrupt address register contents
match the program counter value. Two address match interrupts can be set, each of which can be
enabled and disabled by an address match interrupt enable bit. Address match interrupts are not affected by the interrupt enable flag (I flag) and processor interrupt priority level (IPL). The value of the
program counter (PC) for an address match interrupt varies depending on the instruction being executed.
Figures 2.7.12 and 2.7.13 show the address match interrupt-related registers.
Address match interrupt enable register
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
AIER
Bit symbol
Address
0009 16
When reset
XXXXXX00 2
Bit name
Function
AIER0
Address match interrupt 0
enable bit
0 : Interrupt disabled
1 : Interrupt enabled
AIER1
Address match interrupt 1
enable bit
0 : Interrupt disabled
1 : Interrupt enabled
RW
Nothing is assigned.
In an attempt to write to these bits, write “0”. The value, if read, turns out to
be indeterminated.
Figure 2.7.12 Address match interrupt enable register
Address match interrupt register i (i = 0, 1)
(b23)
b7
(b19)
b3
(b16)(b15)
b0 b7
(b8)
b0 b7
b0
Symbol
RMAD0
RMAD1
Address
001216 to 0010 16
001616 to 0014 16
Function
Address setting register for address match interrupt
When reset
X00000 16
X00000 16
Values that can be set R W
00000 16 to FFFFF 16
Nothing is assigned.
In an attempt to write to these bits, write “0”. The value, if read, turns out to
be indeterminated.
Figure 2.7.13 Address match interrupt register i (i = 0, 1)
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2.7.19 Precautions for Interrupts
(1) Reading address 0000016
• When maskable interrupt is occurred, CPU read the interrupt information (the interrupt number and
interrupt request level) in the interrupt sequence.
The interrupt request bit of the certain interrupt written in address 0000016 will then be set to “0”.
Reading address 0000016 by software sets enabled highest priority interrupt source request bit to “0”.
Though the interrupt is generated, the interrupt routine may not be executed.
Do not read address 0000016 by software.
(2) Setting the stack pointer
• The value of the stack pointer immediately after reset is initialized to 000016. Accepting an interrupt
before setting a value in the stack pointer may become a factor of runaway. Be sure to set a value in
the stack pointer before accepting an interrupt.
(3) External interrupt
________
• Either an “L” level or an “H” level of at least 250 ns width is necessary for the signal input to pins INT0
_______
and INT1 regardless of the CPU operation clock.
_______
_______
•When the polarity of the INT0 and INT1 pins is changed, the interrupt request bit is sometimes set to
“1”. After changing the polarity, set the interrupt request bit to “0”. Figure 2.7.14 shows the procedure
______
for changing the INT interrupt generate factor.
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Clear the interrupt enable flag to “0”
(Disable interrupt)
Set the interrupt priority level to level 0
(Disable INTi interrupt)
Set the polarity select bit
Clear the interrupt request bit to “0”
Set the interrupt priority level to level 1 to 7
(Enable the accepting of INTi interrupt request)
Set the interrupt enable flag to “1”
(Enable interrupt)
______
Figure 2.7.14 Switching condition of INT interrupt request
(4) Rewrite interrupt control register
• To rewrite the interrupt control register, do so at a point that does not generate the interrupt request
for that register. If there is possibility of the interrupt request occur, rewrite the interrupt control register after the interrupt is disabled. The program examples are described as follow:
Example 1:
INT_SWITCH1:
FCLR
I
AND.B #00h, 0055h
NOP
NOP
FSET
I
; Disable interrupts.
; Clear TA0IC int. priority level and int. request bit.
; Enable interrupts.
Example 2:
INT_SWITCH2:
FCLR
I
AND.B #00h, 0055h
MOV.W MEM, R0
FSET
I
; Disable interrupts.
; Clear TA0IC int. priority level and int. request bit.
; Dummy read.
; Enable interrupts.
Example 3:
INT_SWITCH3:
PUSHC FLG
FCLR
I
AND.B #00h, 0055h
POPC FLG
; Push Flag register onto stack
; Disable interrupts.
; Clear TA0IC int. priority level and int. request bit.
; Enable interrupts.
The reason why two NOP instructions or dummy read are inserted before FSET I in Examples 1 and 2 is
to prevent the interrupt enable flag I from being set before the interrupt control register is rewritten due to
effects of the instruction queue.
• When a instruction to rewrite the interrupt control register is executed but the interrupt is disabled, the
interrupt request bit is not set sometimes even if the interrupt request for that register has been
generated. This will depend on the instruction. If this creates problems, use the below instructions to
change the register.
Instructions : AND, OR, BCLR, BSET
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2.8 Watchdog Timer
The watchdog timer has the function of detecting when the program is out of control. The watchdog timer is
a 15-bit counter which down-counts the clock derived by dividing the BCLK using the prescaler. A watchdog
timer interrupt is generated when an underflow occurs in the watchdog timer. Bit 7 of the watchdog timer
control register (address 000F16) selects the prescaler division ratio (by 16 or by 128). Thus the watchdog
timer’s period can be calculated as given below. The watchdog timer’s period is, however, subject to an
error due to the pre-scaler.
Watchdog timer period =
pre-scaler dividing ratio (16 or 128) ✕ watchdog timer count (32768)
BCLK
For example suppose that BCLK runs at 10 MHz and that 16 has been chosen for the dividing ratio of the
pre-scaler, then the watchdog timer’s period becomes approximately 52.4 ms.
The watchdog timer is initialized by writing to the watchdog timer start register (address 000E16) and when
a watchdog timer interrupt request is generated. The prescaler is initialized only when the microcomputer is
reset. After a reset is cancelled, the watchdog timer and prescaler are both stopped. The count is started by
writing to the watchdog timer start register (address 000E16).
Figure 2.8.1 shows the block diagram of the watchdog timer. Figure 2.8.2 shows the watchdog timer control
register and Figure 2.8.3 shows the watchdog timer start register.
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Prescaler
“WDC7 = 0”
1/16
BCLK
Watchdog timer
HOLD
Watchdog timer
interrupt request
“WDC7 = 1”
1/128
Write to the watchdog timer
start register
(address 000E 16)
Set to
“7FFF 16 ”
RESET
Figure 2.8.1 Block diagram of watchdog timer
Watchdog timer control register
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
WDC
0 0
Address
000F 16
When reset
000????? 2
Bit name
Bit symbol
Function
R W
High-order bit of watchdog timer
Reserved bits
Must always be set to “0”
WDC7
0 : Divided by 16
1 : Divided by 128
Prescaler select bit
Figure 2.8.2 Watchdog timer control register
Watchdog timer start register
b7
b0
Symbol
WDTS
Address
000E 16
When reset
Indeterminate
Function
R W
The watchdog timer is initialized and starts counting after a write instruction to
this register. The watchdog timer value is always initialized to “7FFF 16”
regardless of whatever value is written.
Figure 2.8.3 Watchdog timer start register
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2.9 DMAC
This microcomputer has two DMAC (direct memory access controller) channels that allow data to be sent to
memory without using the CPU. DMAC shares the same data bus with the CPU. The DMAC is given a
higher right of using the bus than the CPU, which leads to working the cycle stealing method. On this
account, the operation from the occurrence of DMA transfer request signal to the completion of 1-word (16bit) or 1-byte (8-bit) data transfer can be performed at high speed. Figure 2.9.1 shows the block diagram of
the DMAC. Table 2.9.1 shows the DMAC specifications. Figures 2.9.2 to 2.9.7 show the registers used by
the DMAC.
Address bus
DMA0 source pointer SAR0(20)
(addresses 0022 16 to 0020 16)
DMA0 destination pointer DAR0 (20)
(addresses 0026 16 to 0024 16)
DMA0 forward address pointer (20) (Note)
DMA0 transfer counter reload register TCR0 (16)
(addresses 0029 16, 0028 16)
DMA1 source pointer SAR1 (20)
(addresses 0032 16 to 0030 16)
DMA0 transfer counter TCR0 (16)
DMA1 destination pointer DAR1 (20)
DMA1 transfer counter reload register TCR1 (16)
DMA1 forward address pointer (20) (Note)
(addresses 0036 16 to 0034 16)
(addresses 0039 16, 0038 16)
DMA1 transfer counter TCR1 (16)
DMA latch high-order bits
DMA latch low-order bits
Data bus low-order bits
Data bus high-order bits
Note: Pointer is incremented by a DMA request.
Figure 2.9.1 Block diagram of DMAC
Either a write signal to the software DMA request bit or an interrupt request signal is used as a DMA transfer
request signal. But the DMA transfer is affected neither by the interrupt enable flag (I flag) nor by the
interrupt priority level. The DMA transfer doesn't affect any interrupts either.
If the DMAC is active (the DMA enable bit is set to 1), data transfer starts every time a DMA transfer request
signal occurs. If the cycle of the occurrences of DMA transfer request signals is higher than the DMA
transfer cycle, there can be instances in which the number of transfer requests doesn't agree with the
number of transfers. For details, see the description of the DMA request bit.
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Table 2.9.1 DMAC specifications
Item
Specification
No. of channels
2 (cycle steal method)
Transfer memory space
• From any address in the 1M bytes space to a fixed address
• From a fixed address to any address in the 1M bytes space
• From a fixed address to a fixed address
(Note that DMA-related registers [002016 to 003F16] cannot be accessed)
Maximum No. of bytes transferred
128K bytes (with 16-bit transfers) or 64K bytes (with 8-bit transfers)
DMA request factors (Note)
Falling edge or both edge of pin INT0
________
_______
Falling edge of pin INT1
Timer A0 to timer A4 interrupt requests
Timer B0 to timer B2 interrupt requests
UART0 transmission and reception interrupt requests
UART2 transmission and reception interrupt requests
Multi-master I2C-BUS interface 0 interrupt request
Multi-master I2C-BUS interface 1 interrupt request
A-D conversion interrupt request
OSD1 and OSD2 interrupt requests
Data slicer interrupt request
VSYNC interrupt request
Software triggers
Channel priority
DMA0 takes precedence if DMA0 and DMA1 requests are generated simultaneously
Transfer unit
8 bits or 16 bits
Transfer address direction
forward/fixed (forward direction cannot be specified for both source and
destination simultaneously)
Transfer mode
• Single transfer
mode
After the transfer counter underflows, the DMA enable bit turns to “0”, and the
DMAC turns inactive
• Repeat transfer mode
After the transfer counter underflows, the value of the transfer counter reload
register is reloaded to the transfer counter.
The DMAC remains active unless a “0” is written to the DMA enable bit.
DMA interrupt request generation timing When an underflow occurs in the transfer counter
Active
When the DMA enable bit is set to “1”, the DMAC is active.
When the DMAC is active, data transfer starts every time a DMA transfer request signal occurs.
Inactive
• When the DMA enable bit is set to “0”, the DMAC is inactive.
• After the transfer counter underflows in single transfer mode
Forward address pointer and
reload timing for transfer counter
At the time of starting data transfer immediately after turning the DMAC active,
the value of one of source pointer and destination pointer - the one specified for
the forward direction - is reloaded to the forward direction address pointer, and
the value of the transfer counter reload register is reloaded to the transfer counter.
Writing to register
Registers specified for forward direction transfer are always write enabled.
Registers specified for fixed address transfer are write-enabled when the DMA enable bit is “0”.
Reading the register
Can be read at any time.
However, when the DMA enable bit is “1”, reading the register set up as the
forward register is the same as reading the value of the forward address pointer.
Note: DMA transfer is not effective to any interrupt. DMA transfer is affected neither by the interrupt enable
flag (I flag) nor by the interrupt priority level.
Rev. 1.0
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DMA0 request cause select register
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
DM0SL
Bit symbol
DSEL0
Address
03B8 16
When reset
0016
Bit name
DMA request cause
select bit
DSEL1
DSEL2
DSEL3
Function
R
W
b3 b2 b1 b0
0 0 0 0 : Falling edge of INT 0 pin
0 0 0 1 : Software trigger
0 0 1 0 : Timer A0
0 0 1 1 : Timer A1
0 1 0 0 : Timer A2
0 1 0 1 : Timer A3
0 1 1 0 : Timer A4 (DMS = 0)
/two edges of INT 0 pin (DMS=1)
0 1 1 1 : Timer B0 (DMS = 0)
/OSD1 (DMS=1)
1 0 0 0 : Timer B1 (DMS = 0)
/OSD2 (DMS=1)
1 0 0 1 : Timer B2 (DMS = 0)
/Multi-master I 2C-BUS interface 0
(DMS=1)
1 0 1 0 : UART0 transmit
1 0 1 1 : UART0 receive
1 1 0 0 : UART2 transmit
1 1 0 1 : UART2 receive
1 1 1 0 : A-D conversion
1 1 1 1 : Data slicer
Nothing is assigned.
In an attempt to write to these bits, write “0.”
The value, if read, turns out to be “0.”
DMS
DMA request cause
expansion bit
0 : Normal
1 : Expanded cause
DSR
Software DMA
request bit
If software trigger is selected, a
DMA request is generated by
setting this bit to “1” (When read,
the value of this bit is always “0”)
Figure 2.9.2 DMA0 request cause select register
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DMA1 request cause select register
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
DM1SL
Address
03BA 16
Function
Bit name
Bit symbol
DSEL0
When reset
0016
DMA request cause
select bit
DSEL1
DSEL2
DSEL3
R
W
b3 b2 b1 b0
0 0 0 0 : Falling edge of INT 1 pin
0 0 0 1 : Software trigger
0 0 1 0 : Timer A0
0 0 1 1 : Timer A1
0 1 0 0 : Timer A2
0 1 0 1 : Timer A3 (DMS = 0)
/OSD1 (DMS = 1)
0 1 1 0 : Timer A4 (DMS = 0)
/OSD2 (DMS = 1)
0 1 1 1 : Timer B0
/Multi-master I 2C-BUS interface 1
(DMS = 1)
1 0 0 0 : Timer B1
1 0 0 1 : Timer B2
1 0 1 0 : UART0 transmit
1 0 1 1 : UART0 receive
1 1 0 0 : UART2 transmit
1 1 0 1 : UART2 receive
1 1 1 0 : A-D conversion
1 1 1 1 : V SYNC
Nothing is assigned.
In an attempt to write to these bits, write “0.”
The value, if read, turns out to be “0.”
DMS
DMA request
cause expansion bit
DSR
Software DMA
request bit
0 : Normal
1 : Expanded cause
If software trigger is selected, a
DMA request is generated by
setting this bit to “1” (When read,
the value of this bit is always “0”)
Figure 2.9.3 DMA1 request cause select register
DMAi control register
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
DMiCON(i=0,1)
Address
002C16, 003C16
When reset
00000?002
Bit symbol
Bit name
DMBIT
Transfer unit bit select bit
0 : 16 bits
1 : 8 bits
DMASL
Repeat transfer mode
select bit
0 : Single transfer
1 : Repeat transfer
DMAS
DMA request bit (Note 1)
0 : DMA not requested
1 : DMA requested
DMA enable bit
0 : Disabled
1 : Enabled
DSD
Source address direction
select bit (Note 3)
0 : Fixed
1 : Forward
DAD
Destination address
0 : Fixed
direction select bit (Note 3) 1 : Forward
DMAE
Function
R
W
(Note 2)
Nothing is assigned.
In an attempt to write to these bits, write “0”. The value, if read, turns out to be “0.”
Notes 1: DMA request can be cleared by resetting the bit.
2:This bit can only be set to “0.”
3:Source address direction select bit and destination address direction select bit
cannot be set to “1” simultaneously.
Figure 2.9.4 DMAi control register (i = 0, 1)
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DMAi source pointer (i = 0, 1)
(b23)
b7
(b19)
b3
(b16)(b15)
b0 b7
(b8)
b0 b7
b0
Symbol
SAR0
SAR1
Address
002216 to 0020 16
003216 to 0030 16
When reset
Indeterminate
Indeterminate
Transfer count
specification
Function
• Source pointer
Stores the source address
R W
00000 16 to FFFFF 16
Nothing is assigned.
In an attempt to write to these bits, write “0”. The value, if read, turns out to be “0.”
Figure 2.9.5 DMAi source pointer (i = 0, 1)
DMAi destination pointer (i = 0, 1)
(b23)
b7
(b19)
b3
(b16) (b15)
b0 b7
(b8)
b0 b7
b0
Symbol
DAR0
DAR1
Address
002616 to 0024 16
003616 to 0034 16
When reset
Indeterminate
Indeterminate
Transfer count
specification
Function
• Destination pointer
Stores the destination address
R W
00000 16 to FFFFF 16
Nothing is assigned.
In an attempt to write to these bits, write “0”. The value, if read, turns out to be “0.”
Figure 2.9.6 DMAi destination pointer (i = 0, 1)
DMAi transfer counter (i = 0, 1)
(b15)
b7
(b8)
b0 b7
b0
Symbol
TCR0
TCR1
Address
002916, 0028 16
003916, 0038 16
Function
• Transfer counter
Set a value one less than the transfer count
When reset
Indeterminate
Indeterminate
Transfer count
specification
R W
0000 16 to FFFF 16
Figure 2.9.7 DMAi transfer counter (i = 0, 1)
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2.9.1 Transfer Cycle
The transfer cycle consists of the bus cycle in which data is read from memory or from the SFR area
(source read) and the bus cycle in which the data is written to memory or to the SFR area (destination
write). The number of read and write bus cycles depends on the source and destination addresses. Also,
the bus cycle itself is longer when software waits are inserted.
(1) Effect of source and destination addresses
When 16-bit data is transferred on a 16-bit data bus, and the source and destination both start at odd
addresses, there are one more source read cycle and destination write cycle than when the source
and destination both start at even addresses.
(2) Effect of software wait
When the SFR area or a memory area with a software wait is accessed, the number of cycles is
increased for the wait by 1 bus cycle. The length of the cycle is determined by BCLK.
Figure 2.9.8 shows the example of the transfer cycles for a source read. For convenience, the destination
write cycle is shown as one cycle and the source read cycles for the different conditions are shown. In
reality, the destination write cycle is subject to the same conditions as the source read cycle, with the
transfer cycle changing accordingly. When calculating the transfer cycle, remember to apply the respective conditions to both the destination write cycle and the source read cycle.
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(1)16-bit transfers from even address and the source address is even.
BCLK
Address
bus
CPU use
Source
Destination
Dummy
cycle
CPU use
RD signal
WR signal
Data
bus
CPU use
Source
Destination
Dummy
cycle
CPU use
(2) 16-bit transfers and the source address is odd
BCLK
Address
bus
CPU use
Source
Source + 1 Destination
Dummy
cycle
CPU use
RD signal
WR signal
Data
bus
CPU use
Source + 1 Destination
Source
Dummy
cycle
CPU use
(3) One wait is inserted into the source read under the conditions in (1)
BCLK
Address
bus
CPU use
Source
Destination
Dummy
cycle
CPU use
RD signal
WR signal
Data
bus
CPU use
Source
Destination
Dummy
cycle
CPU use
(4) One wait is inserted into the source read under the conditions in (2)
BCLK
Address
bus
CPU use
Source
Source + 1
Destination
Dummy
cycle
CPU use
RD signal
WR signal
Data
bus
CPU use
Source
Source + 1
Destination
Dummy
cycle
CPU use
Note: The same timing changes occur with the respective conditions at the destination as at the source.
Figure 2.9.8 Example of the transfer cycles for a source read
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2.9.2 DMAC Transfer Cycles
Any combination of even or odd transfer read and write addresses is possible. Table 2.9.2 shows the
number of DMAC transfer cycles.
The number of DMAC transfer cycles can be calculated as follows:
No. of transfer cycles per transfer unit = No. of read cycles ✕ j + No. of write cycles ✕ k
Table 2.9.2 No. of DMAC transfer cycles
Single-chip mode
Transfer unit
8-bit transfers
Bus width
16-bit
Access address
Even
Odd
1
1
16-bit
Even
1
1
Odd
2
2
(DMBIT= “1”)
16-bit transfers
(DMBIT= “0”)
No. of read cycles
1
No. of write cycles
1
Coefficient j, k
Internal ROM/RAM
Internal memory
Internal ROM/RAM
SFR area
/OSD RAM
No wait
1
With wait
No wait
2
2
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2.9.3 DMA Enable Bit
Setting the DMA enable bit to 1 makes the DMAC active. The DMAC carries out the following operations
at the time data transfer starts immediately after DMAC is turned active.
(1) Reloads the value of one of the source pointer and the destination pointer - the one specified for the
forward direction - to the forward direction address pointer.
(2) Reloads the value of the transfer counter reload register to the transfer counter.
Thus overwriting 1 to the DMA enable bit with the DMAC being active carries out the operations given
above, so the DMAC operates again from the initial state at the instant 1 is overwritten to the DMA
enable bit.
2.9.4 DMA Request Bit
The DMAC can generate a DMA transfer request signal triggered by a factor chosen in advance out of
DMA request factors for each channel.
DMA request factors include the following.
* Factors effected by using the interrupt request signals from the built-in peripheral functions and software
DMA factors (internal factors) effected by a program.
* External factors effected by utilizing the input from external interrupt signals.
For the selection of DMA request factors, see the descriptions of the DMAi factor selection register.
The DMA request bit turns to 1 if the DMA transfer request signal occurs regardless of the DMAC’s state
(regardless of whether the DMA enable bit is set 1 or to 0). It turns to 0 immediately before data transfer
starts.
In addition, it can be set to 0 by use of a program, but cannot be set to 1.
There can be instances in which a change in DMA request factor selection bit causes the DMA request bit
to turn to 1. So be sure to set the DMA request bit to 0 after the DMA request factor selection bit is
changed.
The DMA request bit turns to 1 if a DMA transfer request signal occurs, and turns to 0 immediately before
data transfer starts. If the DMAC is active, data transfer starts immediately, so the value of the DMA
request bit, if read by use of a program, turns out to be 0 in most cases. To examine whether the DMAC
is active, read the DMA enable bit.
Here follows the timing of changes in the DMA request bit.
(1) Internal factors
Except the DMA request factors triggered by software, the timing for the DMA request bit to turn to 1
due to an internal factor is the same as the timing for the interrupt request bit of the interrupt control
register to turn to 1 due to several factors.
Turning the DMA request bit to 1 due to an internal factor is timed to be effected immediately before
the transfer starts.
(2) External factors
_______
An external factor is a factor caused to occur by the leading edge of input from the INTi pin (i depends
on which DMAC channel is used).
_______
Selecting the INTi pins as external factors using the DMA request factor selection bit causes input
from these pins to become the DMA transfer request signals.
Rev. 1.0
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The timing for the DMA request bit to turn to 1 when an external factor is selected synchronizes with
the signal’s edge applicable to the function specified by the DMA request factor selection bit (synchro_______
nizes with the trailing edge of the input signal to each INTi pin, for example).
With an external factor selected, the DMA request bit is timed to turn to 0 immediately before data
transfer starts similarly to the state in which an internal factor is selected.
(3) The priorities of channels and DMA transfer timing
If a DMA transfer request signal falls on a single sampling cycle (a sampling cycle means one period
from the leading edge to the trailing edge of BCLK), the DMA request bits of applicable channels
concurrently turn to 1. If the channels are active at that moment, DMA0 is given a high priority to start
data transfer. When DMA0 finishes data transfer, it gives the bus right to the CPU. When the CPU
finishes single bus access, then DMA1 starts data transfer and gives the bus right to the CPU. Figure
2.9.9 illustrates these operations.
An example in which DMA transfer is carried out in minimum cycles at the time when DMA transfer
request signals due to external factors concurrently occur.
An example in which DMA transmission is carried out in minimum
cycles at the time when DMA transmission request signals due to
external factors concurrently occur.
BCLK
DMA0
DMA1
CPU
INT0
AAAA
AAAA AAAA
AAAAAA AAA AAAAAA
AA
AAAAAA AAA AAAAAA
AA
Obtainm
ent of the
bus right
DMA0
request bit
INT1
DMA1
request bit
Figure 2.9.9 An example of DMA transfer effected by external factors
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2.10 Timer
There are eight 16-bit timers. These timers can be classified by function into timers A (five) and timers B
(three). All these timers function independently. Figures 2.10.1 and 2.10.2 show the block diagram of
timers.
f1
XIN
f8
1/8
1/4
f32
f1 f8 f32
• Timer mode
• One-shot mode
Timer A0 interrupt
Timer A0
• Event counter mode
• Timer mode
• One-shot mode
Timer A1 interrupt
Timer A1
• Event counter mode
• Timer mode
• One-shot mode
• PWM mode
Timer A2 interrupt
Timer A2
• Event counter mode
• Timer mode
• One-shot mode
• PWM mode
Timer A3 interrupt
Timer A3
• Event counter mode
• Timer mode
• One-shot mode
Timer A4 interrupt
Timer A4
• Event counter mode
Timer B2 overflow
Figure 2.10.1 Timer A block diagram
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f1
XIN
f8
1/8
1/4
f32
f1 f8 f32
Timer A
• Timer mode
• Pulse width measuring mode
TB0IN
Timer B0 interrupt
Noise
filter
Timer B0
• Event counter mode
• Timer mode
• Pulse width measuring mode
Timer B1 interrupt
Timer B1
• Event counter mode
• Timer mode
• Pulse width measuring mode
Timer B2 interrupt
Timer B2
• Event counter mode
Figure 2.10.2 Timer B block diagram
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2.10.1 Timer A
Figure 2.10.3 shows the block diagram of timer A. Figures 2.10.4 to 2.10.10 show the timer A-related
registers.
Except the pulse output function, timers A0 through A4 all have the same function. Use the timer Ai mode
register (i = 0 to 4) bits 0 and 1 to choose the desired mode.
Timer A has the four operation modes listed as follows:
• Timer mode: The timer counts an internal count source.
• Event counter mode: The timer counts a timer over flow.
• One-shot timer mode: The timer stops counting when the count reaches “000016”.
• Pulse width modulation (PWM) mode: The timer outputs pulses of a given width.
Data bus high-order bits
Clock source
selection
Data bus low-order bits
• Timer
• One shot
• PWM
f1
f8
f32
Low-order
8 bits
High-order
8 bits
Reload register (16)
Counter (16)
Up count/down count
Clock selection
Always down count except
in event counter mode
Count start flag
(Address 0380 16)
TAi
Timer A0
Timer A1
Timer A2
Timer A3
Timer A4
Down count
TB2 overflow
External
trigger
TAj overflow
(j = i – 1. Note, however, that j = 4 when i = 0)
Up/down flag
(Address 0384 16)
Addresses
038716 038616
038916 038816
038B16 038A16
038D16 038C16
038F 16 038E16
TAj
Timer A4
Timer A0
Timer A1
Timer A2
Timer A3
TAk
Timer A1
Timer A2
Timer A3
Timer A4
Timer A0
TAk overflow
(k = i + 1. Note, however, that k = 0 when i = 4)
Pulse output
TAi OUT
(i = 2, 3)
Toggle flip-flop
Figure 2.10.3 Block diagram of timer A
Timer Ai mode register
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
TAiMR(i=0 to 4)
Bit symbol
TMOD0
Bit name
Operation mode select bit
TMOD1
MR0
MR1
Address
When reset
039616 to 039A 16
0016
Function
R W
b1 b0
0 0 : Timer mode
0 1 : Event counter mode
1 0 : One-shot timer mode
1 1 : Pulse width modulation
(PWM) mode
Function varies with each operation mode
MR2
MR3
TCK0
TCK1
Count source select bit
(Function varies with each operation mode)
Figure 2.10.4 Timer Ai mode register (i = 0 to 4)
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Timer Ai register (Note)
(b15)
b7
(b8)
b0 b7
b0
Symbol
TA0
TA1
TA2
TA3
TA4
Address
038716,0386 16
038916,0388 16
038B16,038A 16
038D16,038C 16
038F16,038E 16
When reset
Indeterminate
Indeterminate
Indeterminate
Indeterminate
Indeterminate
Function
Values that can be set
• Timer mode
Counts an internal count source
000016 to FFFF 16
• Event counter mode
Counts pulses from an timer overflow
000016 to FFFF 16
• One-shot timer mode
Counts a one shot width
0000 16 to FFFF 16
• Pulse width modulation mode (16-bit PWM) (TA2, TA3)
Functions as a 16-bit pulse width modulator
000016 to FFFE 16
• Pulse width modulation mode (8-bit PWM) (TA2, TA3)
Timer low-order address functions as an 8-bit
prescaler and high-order address functions as an 8-bit
pulse width modulator
0016 to FE 16
(Both high-order
and low-order
addresses)
R W
Note: Read and write data in 16-bit units.
Figure 2.10.5 Timer Ai register (i = 0 to 4)
Count start flag
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
TABSR
Bit symbol
Address
0380 16
Bit name
TA0S
Timer A0 count start flag
TA1S
Timer A1 count start flag
TA2S
Timer A2 count start flag
TA3S
Timer A3 count start flag
TA4S
Timer A4 count start flag
TB0S
Timer B0 count start flag
TB1S
Timer B1 count start flag
TB2S
Timer B2 count start flag
When reset
0016
Function
R W
0 : Stops counting
1 : Starts counting
Figure 2.10.6 Count start flag
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Up/down flag
b7
b6
b5
b4
b3
b2
b1
Symbol
UDF
b0
0 0 0
Address
0384 16
Bit symbol
When reset
0016
Bit name
TA0UD
Timer A0 up/down flag
TA1UD
Timer A1 up/down flag
TA2UD
Timer A2 up/down flag
TA3UD
Timer A3 up/down flag
TA4UD
Timer A4 up/down flag
Function
R W
0 : Down count
1 : Up count
This specification becomes valid
when the up/down flag content is
selected for up/down switching
cause
Must always be set to “0”
Reserved bit
Figure 2.10.7 Up/down flag
One-shot start flag
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
ONSF
Bit symbol
Address
038216
When reset
00X00000 2
Bit name
TA0OS
Timer A0 one-shot start flag
TA1OS
Timer A1 one-shot start flag
TA2OS
Timer A2 one-shot start flag
TA3OS
Timer A3 one-shot start flag
TA4OS
Timer A4 one-shot start flag
Function
R W
1 : Timer start
When read, the value is “0”
Nothing is assigned.
This bit can neither be set nor reset. When read, its content is indeterminate.
TA0TGL
TA0TGH
Timer A0 event/trigger
select bit
b7 b6
0 0 : Do not set
0 1 : TB2 overflow is selected
1 0 : TA4 overflow is selected
1 1 : TA1 overflow is selected
Figure 2.10.8 One-shot start flag
Rev. 1.0
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Trigger select register
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
TRGSR
Address
038316
Bit symbol
TA1TGL
Bit name
Timer A1 event/trigger
select bit
TA1TGH
TA2TGL
Timer A3 event/trigger
select bit
b5 b4
Timer A4 event/trigger
select bit
b7 b6
TA4TGH
R W
0 0 : Do not set
0 1 : TB2 overflow is selected
1 0 : TA0 overflow is selected
1 1 : TA2 overflow is selected
b3 b2
TA3TGH
TA4TGL
Function
b1 b0
Timer A2 event/trigger
select bit
TA2TGH
TA3TGL
When reset
0016
0 0 : Do not set
0 1 : TB2 overflow is selected
1 0 : TA1 overflow is selected
1 1 : TA3 overflow is selected
0 0 : Do not set
0 1 : TB2 overflow is selected
1 0 : TA2 overflow is selected
1 1 : TA4 overflow is selected
0 0 : Do not set
0 1 : TB2 overflow is selected
1 0 : TA3 overflow is selected
1 1 : TA0 overflow is selected
Figure 2.10.9 Trigger select register
Reserved register 6
b7
0
b6
b5
b4
b3
b2
b1
b0
Symbol
INVC6
Bit symbol
Address
038116
Bit name
When reset
0XXXXXXX 2
Function
RW
Nothing is assigned.
In an attempt to write to these bits, write “0.” The value, if read, turns out to be indeterminate.
Reserved bit
Must always be set to “0.”
Figure 2.10.10 Reserved register 6
Rev. 1.0
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(1) Timer mode
In this mode, the timer counts an internally generated count source. (See Table 2.10.1.) Figure 2.10.11
shows the timer Ai mode register in timer mode.
Table 2.10.1 Specifications of timer mode
Item
Specification
Count source
f1, f8, f32
Count operation
• Down count
• When the timer underflows, it reloads the reload register contents before continuing counting
Divide ratio
1/(n+1)
n : Set value
Count start condition
Count start flag is set (= 1)
Count stop condition
Count start flag is reset (= 0)
Interrupt request generation timing
When the timer underflows
TA2OUT/TA3OUT pin function
Programmable I/O port or pulse output
Read from timer
Count value can be read out by reading timer Ai register
Write to timer
• When counting stopped
When a value is written to timer Ai register, it is written to both reload register and counter
• When counting in progress
When a value is written to timer Ai register, it is written to only reload register
(Transferred to counter at next reload time)
Select function
• Pulse output function
Each time the timer underflows, the TAiOUT pin’s polarity is reversed
Timer Ai mode register
b7
b6
b5
b4
b3
0 0 0
b2
b1
b0
0 0
Symbol
TAiMR(i=0 to 4)
Bit symbol
TMOD0
TMOD1
MR0
Address
When reset
039616 to 039A 16
0016
Bit name
Operation mode
select bit
Pulse output function
select bit
(Note 2)
Function
R W
b1 b0
0 0 : Timer mode
0 : Pulse is not output
(TA2OUT/TA3OUT pin is a normal port pin)
1 : Pulse is output (Note 1)
(TA2OUT/TA3OUT pin is a pulse output pin)
Must always be set to “0”
Reserved bits
MR3
0 (Must always be set to “0” in timer mode)
TCK0
Count source select bit
TCK1
b7 b6
0 0 : f1
0 1 : f8
1 0 : f 32
1 1 : Do not set
Notes 1 : The settings of the corresponding port register and port direction register
are invalid.
2 : This bit of TAiMR (i = 0, 1, 4) must always be set to “0.”
Figure 2.10.11 Timer Ai mode register in timer mode (i = 0 to 4)
Rev. 1.0
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(2) Event counter mode
In this mode, the timer counts an internal timer’s overflow.
Table 2.10.2 Timer specifications in event counter mode
Item
Count source
Count operation
Divide ratio
Count start condition
Count stop condition
Interrupt request generation timing
TA2OUT/TA3OUT pin function
Read from timer
Write to timer
Select function
Specification
• TB2 overflow, TAj overflow, TAk overflow
• Up count or down count can be selected by external signal or software
• When the timer overflows or underflows, it reloads the reload register contents
before continuing counting (Note)
1/ (FFFF16 - n + 1) for up count
1/ (n + 1) for down count
n : Set value
Count start flag is set (= 1)
Count start flag is reset (= 0)
The timer overflows or underflows
Programmable I/O port, pulse output, or up/down count select input
Count value can be read out by reading timer Ai register
• When counting stopped
When a value is written to timer Ai register, it is written to both reload register and counter
• When counting in progress
When a value is written to timer Ai register, it is written to only reload register
(Transferred to counter at next reload time)
• Free-run count function
Even when the timer overflows or underflows, the reload register content is not reloaded to it
• Pulse output function
Each time the timer overflows or underflows, the TAiOUT pin’s polarity is reversed
Note: This does not apply when the free-run function is selected.
Rev. 1.0
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Timer Ai mode register
b7
0
b6
b5
0
b4
b3
0
b2
b1
b0
Symbol
0 1
Bit symbol
TMOD0
Address
When reset
TAiMR(i = 0 to 4) 039616 to 039A16
0016
Bit name
Operation mode select bit
Pulse output function
select bit
0 : Pulse is not output
(TA2OUT/TA3OUT pin is a normal port pin)
1 : Pulse is output (Note 2)
(TA2OUT/TA3OUT pin is a pulse output pin)
TMOD1
MR0
Reserved bit
MR2
Function
b1 b0
0 1 : Event counter mode (Note 1)
Must always be set to “0”
Up/down switching
cause select bit
0 : Up/down flag’s content
1 : TA2OUT/TA3OUT pin’s input signal
(Notes 3, 4)
MR3
0 : (Must always be set to “0” in event counter mode)
TCK0
Count operation type select 0 : Reload type
bit
1 : Free-run type
Reserved bit
R W
Must always be set to “0”
Notes 1: In event counter mode, the count source is selected by the event / trigger
select bit (addresses 038216 and 038316).
2: The settings of the corresponding port register and port direction register
are invalid.
3: This bit of TAiMR (i = 0, 1, 4) must always be set to “0.”
4: When an “L” signal is input to the input signal from TA2OUT/TA3OUT pin,
the downcount is activated. When “H,” the upcount is activated. Set the
corresponding port direction register to “0.”
Figure 2.10.12 Timer Ai mode register in event counter mode (i = 0 to 4)
Rev. 1.0
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(3) One-shot timer mode
In this mode, the timer operates only once. (See Table 2.10.3.) When a trigger occurs, the timer starts up
and continues operating for a given period. Figure 2.10.13 shows the timer Ai mode register in one-shot
timer mode.
Table 2.10.3 Timer specifications in one-shot timer mode
Item
Specification
Count source
f1, f8, f32
Count operation
• The timer counts down
• When the count reaches 000016, the timer stops counting after reloading a new count
• If a trigger occurs when counting, the timer reloads a new count and restarts counting
Divide ratio
1/n
n : Set value
Count start condition
• The timer overflows
• The one-shot start flag is set (= 1)
Count stop condition
• A new count is reloaded after the count has reached 000016
• The count start flag is reset (= 0)
Interrupt request generation timing The count reaches 000016
TA2OUT/TA3OUT pin function Programmable I/O port or pulse output
Read from timer
When timer Ai register is read, it indicates an indeterminate value
Write to timer
• When counting stopped
When a value is written to timer Ai register, it is written to both reload register and
counter
• When counting in progress
When a value is written to timer Ai register, it is written to only reload register
(Transferred to counter at next reload time)
Timer Ai mode register
b7
b6
b5
0
b4
b3
0
b2
b1
b0
1 0
Symbol
TAiMR(i = 0 to 4)
Address
When reset
0016
0396 16 to 039A 16
Bit symbol
Bit name
TMOD0
Operation mode select bit
b1 b0
Pulse output function
select bit
(Note 2)
0 : Pulse is not output
TMOD1
MR0
Function
R W
1 0 : One-shot timer mode
(TA2OUT/TA3OUT pin is a normal port pin)
1 : Pulse is output (Note 1)
(TA2OUT/TA3OUT pin is a pulse output pin)
Reserved bits
Must always be set to “0”
MR2
Trigger select bit
MR3
0 (Must always be “0” in one-shot timer mode)
TCK0
Count source select bit
TCK1
0 : Count start flag is valid
1 : Selected by event/trigger select register
b7 b6
0 0 : f1
0 1 : f8
1 0 : f 32
1 1 : Do not set
Notes 1 : The settings of the corresponding port register and port direction register
are invalid.
2 : This bit of TAiMR (i = 0, 1, 4) must always be set to “0.”
Figure 2.10.13 Timer Ai mode register in one-shot timer mode (i = 0 to 4)
Rev. 1.0
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(4) Pulse width modulation (PWM) mode
In this mode, the timer outputs pulses of a given width in succession. (See Table 2.10.4.) In this mode, the
counter functions as either a 16-bit pulse width modulator or an 8-bit pulse width modulator. Figure 2.10.14
shows the timer Ai mode register in pulse width modulation mode. Figure 2.10.15 shows the example of how
an 8-bit pulse width modulator operates.
Table 2.10.4 Timer specifications in pulse width modulation mode
Item
Specification
Count source
Count operation
f1, f8, f32
• The timer counts down (operating as an 8-bit or a 16-bit pulse width modulator)
• The timer reloads a new count at a rising edge of PWM pulse and continues counting
• The timer is not affected by a trigger that occurs when counting
16-bit PWM
• High level width n / fi n : Set value
• Cycle time
(216-1) / fi fixed
8-bit PWM
• High level width n ✕ (m+1) / fi n : values set to timer Ai register’s high-order address
• Cycle time
(28-1) ✕ (m+1) / fi
m : values set to timer Ai register’s low-order address
Count start condition
• The timer overflows
• The count start flag is set (= 1)
Count stop condition
• The count start flag is reset (= 0)
Interrupt request generation timing PWM pulse goes “L”
TA2OUT/TA3OUT pin function Pulse output
Read from timer
When timer Ai register is read, it indicates an indeterminate value
Write to timer
• When counting stopped
When a value is written to timer Ai register, it is written to both reload register and
counter
• When counting in progress
When a value is written to timer Ai register, it is written to only reload register
(Transferred to counter at next reload time)
Timer Ai mode register
b7
b6
b5
b4
b3
b1
b0
0 1 1
b2
1
Symbol
TAiMR(i=2 and 3)
Bit symbol
TMOD0
TMOD1
MR0
Address
When reset
0398 16 and 0399 16 0016
Bit name
Operation mode
select bit
Function
R W
b1 b0
1 1 : PWM mode
1 (Must always be “1” in PWM mode)
Reserved bits
Must always be set to “0”
MR2
Trigger select bit
0: Count start flag is valid
1: Selected by event/trigger select register
MR3
16/8-bit PWM mode
select bit
0: Functions as a 16-bit pulse width modulator
1: Functions as an 8-bit pulse width modulator
TCK0
Count source select bit
0 0 : f1
0 1 : f8
1 0 : f 32
1 1 : Do not set
b7 b6
TCK1
Figure 2.10.14 Timer Ai mode register in pulse width modulation mode (i = 2 and 3)
Rev. 1.0
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Condition : Reload register high-order 8 bits = 0216
Reload register low-order 8 bits = 0216
Timer overflow is selected
8
1 / fi X (m + 1) X (2 – 1)
Count source (Note1)
“H”
Timer overflow
“L”
1 / fi X (m + 1)
“H”
Underflow signal of
8-bit prescaler (Note2) “L”
1 / fi X (m + 1) X n
PWM pulse output
from TAiOUT pin
“H”
Timer Ai interrupt
request bit
“1”
“L”
“0”
fi : Frequency of count source
(f1, f8, f32, fC32)
Cleared to “0” when interrupt request is accepted, or cleared by software
Notes 1: The 8-bit prescaler counts the count source.
2: The 8-bit pulse width modulator counts the 8-bit prescaler's underflow signal.
3: m = 0016 to FE16; n = 0016 to FE16.
Figure 2.10.15 Example of how an 8-bit pulse width modulator operates
Rev. 1.0
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2.10.2 Timer B
Figure 2.10.17 shows the block diagram of timer B. Figures 2.10.17 and 2.10.20 show the timer B-related
registers.
Use the timer Bi mode register (i = 0 to 2) bits 0 and 1 to choose the desired mode.
Timer B has three operation modes listed as follows:
• Timer mode: The timer counts an internal count source.
• Event counter mode: The timer counts pulses from an external source or a timer overflow.
• Pulse period/pulse width measuring mode: The timer measures an external signal’s pulse period or
pulse width.
Data bus high-order bits
Data bus low-order bits
Clock source selection
High-order 8 bits
Low-order 8 bits
f1
• Timer
• Pulse period/pulse width measurement
f8
f32
Reload register (16)
Counter (16)
• Event counter
Count start flag
Polarity switching
and edge pulse
TB0 IN
(address 0380 16)
Counter reset circuit
Can be selected in only
event counter mode
TBi
Timer B0
Timer B1
Timer B2
TBj overflow
(j = i – 1.
Note, however,
j = 2 when i = 0)
Address
0391 16 0390 16
0393 16 0392 16
0395 16 0394 16
TBj
Timer B2
Timer B0
Timer B1
Figure 2.10.16 Block diagram of timer B
Timer Bi mode register
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
Address
TBiMR(i = 0 to 2) 039B16 to 039D 16
Bit symbol
Bit name
TMOD0
Operation mode select bit
TMOD1
MR0
When reset
00?X0000 2
Function
R
W
b1 b0
0 0 : Timer mode
0 1 : Event counter mode
1 0 : Pulse period/pulse width
measurement mode
1 1 : Inhibited
Function varies with each operation mode
MR1
MR2
(Note 1)
(Note 2)
MR3
TCK0
TCK1
Count source select bit
(Function varies with each operation mode)
Notes 1: Timer B0.
2: Timer B1, timer B2.
Figure 2.10.17 Timer Bi mode register (i = 0 to 2)
Rev. 1.0
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Timer Bi register (Note)
(b15)
b7
(b8)
b0 b7
b0
Symbol
TB0
TB1
TB2
Address
039116, 0390 16
039316, 0392 16
039516, 0394 16
Function
When reset
Indeterminate
Indeterminate
Indeterminate
R W
Values that can be set
• Timer mode
Counts the timer's period
000016 to FFFF 16
• Event counter mode
Counts external pulses input or a timer overflow
000016 to FFFF 16
• Pulse period / pulse width measurement mode
Measures a pulse period or width
Note: Read and write data in 16-bit units.
Figure 2.10.18 Timer Bi register (i = 0 to 2)
Count start flag
b7
b6
b5
b4
b3
b2
b1
Symbol
TABSR
b0
Bit symbol
Address
038016
When reset
0016
Bit name
Function
TA0S
Timer A0 count start flag
TA1S
Timer A1 count start flag
TA2S
Timer A2 count start flag
TA3S
Timer A3 count start flag
TA4S
Timer A4 count start flag
TB0S
Timer B0 count start flag
TB1S
Timer B1 count start flag
TB2S
Timer B2 count start flag
R W
0 : Stops counting
1 : Starts counting
Figure 2.10.19 Count start flag
Reserved register 6
b7
0
b6
b5
b4
b3
b2
b1
b0
Symbol
INVC6
Bit symbol
Address
038116
Bit name
When reset
0XXXXXXX 2
Function
RW
Nothing is assigned.
In an attempt to write to these bits, write “0.” The value, if read, turns out to be indeterminate.
Reserved bit
Must always be set to “0.”
Figure 2.10.20 Reserved register
Rev. 1.0
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(1) Timer mode
In this mode, the timer counts an internally generated count source. (See Table 2.10.5) Figure 2.10.21
shows the timer Bi mode register in timer mode.
Table 2.10.5 Timer specifications in timer mode
Item
Specification
Count source
f1, f8, f32
Count operation
• Counts down
• When the timer underflows, it reloads the reload register contents before continuing
counting
Divide ratio
1/(n+1)
n : Set value
Count start condition
Count start flag is set (= 1)
Count stop condition
Count start flag is reset (= 0)
Interrupt request generation timing The timer underflows
TB0IN pin function
Programmable I/O port
Read from timer
Count value is read out by reading timer Bi register
Write to timer
• When counting stopped
When a value is written to timer Bi register, it is written to both reload register and counter
• When counting in progress
When a value is written to timer Bi register, it is written to only reload register
(Transferred to counter at next reload time)
Timer Bi mode register
b7
b6
b5
b4
b3
b2
b1
b0
0 0
Symbol
TBiMR(i=0 to 2)
Bit symbol
TMOD0
Address
039B16 to 039D16
Bit name
Operation mode select bit
TMOD1
MR0
When reset
00?X00002
Function
R
W
b1 b0
0 0 : Timer mode
M R1
Invalid in timer mode
Can be “0” or “1”
M R2
0 (Fixed to “0” in timer mode ; i = 0)
(Note 1)
Nothing is assigned (i = 1, 2).
In an attempt to write to this bit, write “0.” The value, if read, turns out to (Note 2)
be indeterminate.
M R3
Invalid in timer mode.
In an attempt to write to this bit, write “0.” The value, if read in
timer mode, turns out to be indeterminate.
TCK0
Count source select bit
TCK1
b7 b6
0 0 : f1
0 1 : f8
1 0 : f32
1 1 : Do not set
Notes 1: Timer B0.
2: Timer B1, timer B2.
Figure 2.10.21 Timer Bi mode register in timer mode (i = 0 to 2)
Rev. 1.0
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(2) Event counter mode
In this mode, the timer counts an external signal or an internal timer’s overflow. (See Table 2.10.6) Figure
2.10.22 shows the timer Bi mode register in event counter mode.
Table 2.10.6 Timer specifications in event counter mode
Item
Specification
Count source
• External signals input to TB0IN pin
• Effective edge of count source can be a rising edge, a falling edge, or falling and
rising edges as selected by software
Count operation
• Counts down
• When the timer underflows, it reloads the reload register contents before continuing
counting
Divide ratio
1/(n+1)
n : Set value
Count start condition
Count start flag is set (= 1)
Count stop condition
Count start flag is reset (= 0)
Interrupt request generation timing The timer underflows
TB0IN pin function
Count source input
Read from timer
Count value can be read out by reading timer Bi register
Write to timer
• When counting stopped
When a value is written to timer Bi register, it is written to both reload register and counter
• When counting in progress
When a value is written to timer Bi register, it is written to only reload register
(Transferred to counter at next reload time)
Timer Bi mode register
b7
b6
b5
b4
b3
b2
b1
b0
0 1
Symbol
TBiMR(i=0 to 2)
Address
039B16 to 039D16
Bit symbol
Bit name
TMOD0
Operation mode select bit
Count polarity select
bit (Note 1)
MR1
MR2
R
Function
W
b1 b0
0 1 : Event counter mode
TMOD1
M R0
When reset
00?X00002
b3 b2
0 0 : Counts external signal's falling
edges
0 1 : Counts external signal's rising
edges
1 0 : Counts external signal's falling
and rising edges
1 1 : Inhibited
0 (Fixed to “0” in event counter mode; i = 0)
(Note 2)
Nothing is assigned (i = 1, 2).
In an attempt to write to this bit, write “0.” The value, if read, turns out to
(Note 3)
be indeterminate.
MR3
Invalid in timer mode.
In an attempt to write to this bit, write “0.” The value, if read in
event counter mode, turns out to be indeterminate.
TCK0
Invalid in event counter mode.
Can be “0” or “1”.
TCK1
Event clock select
0 : Input from TB0IN pin (Note 4)
1 : TBj overflow
(j = i – 1; however, j = 2 when i = 0)
Notes 1: Valid only when input from the TB0IN pin is selected as the event clock.
If timer's overflow is selected, this bit can be “0” or “1”.
2: Timer B0.
3: Timer B1, timer B2.
4: Set the corresponding port direction register to “0”.
Figure 2.10.22 Timer Bi mode register in event counter mode (i = 0 to 2)
Rev. 1.0
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(3) Pulse period/pulse width measurement mode
In this mode, the timer measures the pulse period or pulse width of an external signal. (See Table 2.10.7)
Figure 2.10.23 shows the timer B0 mode register in pulse period/pulse width measurement mode. Figure
2.10.24 shows the operation timing when measuring a pulse period. Figure 2.10.25 shows the operation
timing when measuring a pulse width.
Table 2.10.7 Timer specifications in pulse period/pulse width measurement mode
Item
Specification
Count source
f1, f8, f32
Count operation
• Up count
• Counter value “000016” is transferred to reload register at measurement pulse's
effective edge and the timer continues counting
Count start condition
Count start flag is set (= 1)
Count stop condition
Count start flag is reset (= 0)
Interrupt request generation timing • When measurement pulse's effective edge is input (Note 1)
• When an overflow occurs. (Simultaneously, the timer Bi overflow flag changes to “1”.
The timer B0 overflow flag changes to “0” when the count start flag is “1” and a value
is written to the timer B0 mode register.)
TB0IN pin function
Measurement pulse input
Read from timer
When timer B0 register is read, it indicates the reload register’s content
(measurement result) (Note 2)
Write to timer
Cannot be written to
Notes 1: An interrupt request is not generated when the first effective edge is input after the timer has started counting.
2: The value read out from the timer B0 register is indeterminate until the second effective edge is input after the timer.
Timer B0 mode register
b7
b6
b5
b4
b3
b2
b1
b0
1 0
Symbol
TB0MR
Bit symbol
TMOD0
TMOD1
MR0
Address
039B16
When reset
00?X00002
Bit name
Operation mode
select bit
Measurement mode
select bit
M R1
Function
W
1 0 : Pulse period / pulse width
measurement mode
b3 b2
0 0 : Pulse period measurement (Interval between
measurement pulse's falling edge to falling edge)
0 1 : Pulse period measurement (Interval between
measurement pulse's rising edge to rising edge)
1 0 : Pulse width measurement (Interval between
measurement pulse's falling edge to rising edge,
and between rising edge to falling edge)
1 1 : Inhibited
M R2
0: Fixed to “0” in pulse period/pulse width measurement mode
M R3
Timer Bi overflow
flag ( Note 1)
TCK0
Count source
select bit
TCK1
R
b1 b0
0 : Timer did not overflow
1 : Timer has overflowed
b7 b6
0 0 : f1
0 1 : f8
1 0 : f32
1 1 : Do not set
Note: The timer B0 overflow flag changes to “0” when the count start flag is “1” and a value is written to the
timer B0 mode register. This flag cannot be set to “1” by software.
Figure 2.10.23 Timer B0 mode register in pulse period/pulse width measurement mode
Rev. 1.0
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When measuring measurement pulse time interval from falling edge to falling edge
Count source
“H”
Measurement pulse
Reload register
transfer timing
“L”
Transfer
(indeterminate value)
Transfer
(measured value)
counter
(Note 1)
(Note 1)
(Note 2)
Timing at which counter
reaches “0000 16”
“1”
Count start flag
“0”
Timer B0 interrupt
request bit
“1”
Timer B0 overflow flag
“1”
“0”
Cleared to “0” when interrupt request is accepted, or cleared by software.
“0”
Notes 1: Counter is initialized at completion of measurement.
2: Timer has overflowed.
Figure 2.10.24 Operation timing when measuring a pulse period
Count source
Measurement pulse
Reload register
transfer timing
“H”
“L”
counter
Transfer
(indeterminate
value)
(Note 1)
Transfer
(measured value)
(Note 1)
Transfer
(measured
value)
(Note 1)
Transfer
(measured value)
(Note 1)
(Note 2)
Timing at which counter
reaches “0000 16”
Count start flag
“1”
“0”
Timer B0 interrupt
request bit
“1”
“0”
Cleared to “0” when interrupt request is accepted, or cleared by software.
Timer B0 overflow flag
“1”
“0”
Notes 1: Counter is initialized at completion of measurement.
2: Timer has overflowed.
Figure 2.10.25 Operation timing when measuring a pulse width
Rev. 1.0
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Reserved register i
b7
b6
b5
b4
b3
b2
0
0
0
0
0
0 0
b1
b0
0
Symbol
Address
When reset
INVC0
INVC1
INVC2
INVC5
0348 16
0340 16
03A8 16
0376 16
00000000 2
000????? 2
00000000 2
00000000 2
Bit symbol
Bit name
Reserved bits
Description
R
W
R
W
Must always be set to “0”
Figure 2.10.26 Reserved register i (i = 0 to 2, 5)
Reserved register i
b7
b6
b5
b4
b3
b2
0
1
0
0
0
0 0
b1
b0
0
Symbol
Address
When reset
INVC3
INVC4
0362 16
0366 16
4016
4016
Bit symbol
Bit name
Description
Reserved bits
Must always be set to “0”
Reserved bit
Must always be set to “1”
Reserved bits
Must always be set to “0”
Note: Set data to this register after setting bit 2 of the protect register (address 000A
16)
to “1.”
Figure 2.10.27 Reserved register i (i = 3 and 4)
Rev. 1.0
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(4) TB0IN noise filter
The input signal of pin TB0IN has the noise filter. The ON/OFF of noise filter and selection of filter clock
are set by bits 2 to 4 of the peripheral mode register.
Note: When using the noise filter, set bit 7 of the peripheral mode register according to the main clock
frequency.
Peripheral mode register
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
PM
Address
027D16
Bit symbol
BSEL0
Bit name
I2C-BUS
interface port
selection bits
BSEL1
WSEL0
Clock selection bits of
TB0IN noise filter
(Note)
WSEL1
NFON
When reset
0XX000002
ON/OFF selection
bit of TB0IN pin noise filter
Function
R
W
b1 b0
0 0 : None
0 1 : SCL1, SDA1
1 0 : SCL2, SDA2
1 1 : SCL1 and SDA1,
SCL2 and SDA2
b3 b2
0 0 : 0.25 µs
(removed bus width: max 0.75 µs)
0 1 : 8 µs
(removed bus width: max 24 µs)
1 0 : 16 µs
(removed bus width: max 48 µs)
1 1 : 32 µs
(removed bus width: max 96 µs)
0 : Noise filter OFF
1 : Noise filter ON
Nothing is assigned.
In an attempt to write to this bit, write “0.” The value, if read, turns out to be
indeterminate.
SSCK
Main clock frequency
selection bit
0 : f(XIN) = 10 MHZ
1 : f(XIN) = 16 MHZ
Note: The operation of MCU is not guaranteed when f(XIN) = 16 MHz.
Figure 2.10.28 Peripheral mode register
Rev. 1.0
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2.11 Serial I/O
Serial I/O is configured as 4 unites: UART0, UART2, multi-master I2C-BUS interface 0, and multi-master
I2C-BUS interface 1.
2.11.1 UART0 and UART2
UART0 and UART2 each have an exclusive timer to generate a transfer clock, so they operate independently of each other.
Figure 2.11.1 shows the block diagram of UART0 and UART2. Figures 2.11.2 and 2.11.3 show the block
diagram of the transmit/receive unit.
UARTi (i = 0 and 2) has two operation modes: a clock synchronous serial I/O mode and a clock asynchronous
serial I/O mode (UART mode). The contents of the serial I/O mode select bits (bits 0 to 2 at addresses 03A016
and 037816) determine whether UARTi is used as a clock synchronous serial I/O or as a UART. Although a
few functions are different, UART0 and UART2 have almost the same functions.
UART0 and UART2 are almost equal in their functions with minor exceptions. UART2, in particular, is
compliant with the SIM interface. It also has the bus collision detection function that generates an interrupt
request if the TxD pin and the RxD pin are different in level.
Table 2.11.1 shows the comparison of functions of UART0 and UART2, and Figures 2.11.4 to 2.11.14
show the registers related to UARTi.
Table 2.11.1 Comparison of functions of UART0 and UART2
Function
UART0
UART2
CLK polarity selection
Possible
(Note 1)
Possible
(Note 1)
LSB first / MSB first selection
Possible
(Note 1)
Possible
(Note 2)
Continuous receive mode selection
Possible
(Note 1)
Possible
(Note 1)
Transfer clock output from multiple
pins selection
Impossible
Impossible
Serial data logic switch
Impossible
Possible
Sleep mode selection
Possible
TxD, RxD I/O polarity switch
Impossible
Possible
TxD, RxD port output format
CMOS output
N-channel open-drain
output
Parity error signal output
Impossible
Possible
Bus collision detection
Impossible
Possible
(Note 3)
(Note 4)
Impossible
(Note 4)
Notes 1: Only when clock synchronous serial I/O mode.
2: Only when clock synchronous serial I/O mode and 8-bit UART mode.
3: Only when UART mode.
4: Using for SIM interface.
Rev. 1.0
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(UART0)
RxD0
TxD0
UART reception
Clock source selection UART 0 bit rate
f1
f8
f32
Internal
generator
(address 03A1 16)
1 / (n0+1)
1/16
Reception
control circuit
Clock synchronous type
UART transmission
1/16
Transmission
control circuit
Clock synchronous type
External
Receive
clock
Transmit/
receive
unit
Transmit
clock
Clock synchronous type
(when internal clock is selected)
1/2
Clock synchronous type
(when internal clock is selected)
CLK
polarity
reversing
circuit
CLK0
Clock synchronous type
(when external clock is
selected)
(UART2)
TxD
polarity
reversing
circuit
RxD polarity
reversing circuit
RxD2
Clock source selection
f1
f8
f32
Internal
1/16
UART reception
UART2 bit rate
Clock synchronous type
generator
(address 0379 16)
1 / (n2+1)
External
Reception
control circuit
UART transmission
1/16
Clock synchronous type
Transmission
control circuit
Receive
clock
TxD2
Transmit/
receive
unit
Transmit
clock
Clock synchronous type
1/2
CLK2
CLK
polarity
reversing
circuit
Clock synchronous type
(when internal clock is selected)
(when internal clock is selected)
Clock synchronous type
(when external clock is
selected)
n0 : Values set to UART0 bit rate generator (BRG0)
n2 : Values set to UART2 bit rate generator (BRG2)
Figure 2.11.1 Block diagram of UARTi (i = 0 and 2)
Rev. 1.0
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Clock
synchronous type
PAR
disabled
1SP
RxD0
SP
SP
UART (7 bits)
UART (8 bits)
Clock
synchronous
type
UARTi receive register
UART (7 bits)
PAR
PAR
enabled
2SP
UART
UART (9 bits)
Clock
synchronous type
UART (8 bits)
UART (9 bits)
0
0
0
0
0
0
0
D8
D7
D6
D5
D4
D3
D2
D1
D0
UART0 receive
buffer register
Address 03A616
Address 03A716
MSB/LSB conversion circuit
Data bus high-order bits
Data bus low-order bits
MSB/LSB conversion circuit
D7
D8
D6
D5
D4
D3
D2
D1
D0
UART0 transmit
buffer register
Address 03A216
Address 03A316
UART (8 bits)
UART (9 bits)
UART (9 bits)
PAR
enabled
2SP
SP
SP
Clock synchronous
type
UART
TxD0
PAR
1SP
PAR
disabled
“0”
Clock
synchronous
type
UART (7 bits)
UART0 transmit register
UART (7 bits)
UART (8 bits)
Clock synchronous
type
SP: Stop bit
PAR: Parity bit
Figure 2.11.2 Block diagram of UART0 transmit/receive unit
Rev. 1.0
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No reverse
RxD data
reverse circuit
RxD2
Reverse
Clock
synchronous type
PAR
disabled
1SP
SP
UART2 receive register
UART(7 bits)
PAR
SP
2SP
PAR
enabled
0
UART
(7 bits)
UART
(8 bits)
Clock
synchronous
type
0
0
0
UART
0
Clock
synchronous type
UART
(9 bits)
0
0
UART
(8 bits)
UART
(9 bits)
D8
D0
UART2 receive
buffer register
Logic reverse circuit + MSB/LSB conversion circuit
Address 037E16
Address 037F16
D7
D6
D5
D4
D3
D2
D1
Data bus high-order bits
Data bus low-order bits
Logic reverse circuit + MSB/LSB conversion circuit
D7
D8
D6
D5
D4
D3
D2
D1
D0
UART2 transmit
buffer register
Address 037A16
Address 037B16
UART
(8 bits)
UART
(9 bits)
PAR
enabled
2SP
SP
SP
UART
(9 bits)
Clock
synchronous type
UART
PAR
1SP
PAR
disabled
“0”
Clock
synchronous
type
UART
(7 bits)
UART
(8 bits)
UART(7 bits)
UART2 transmit register
Clock
synchronous type
Error signal output
disable
No reverse
TxD data
reverse circuit
Error signal
output circuit
Error signal output
enable
TxD2
Reverse
SP: Stop bit
PAR: Parity bit
Figure 2.11.3 Block diagram of UART2 transmit/receive unit
Rev. 1.0
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UARTi transmit buffer register
(b15)
b7
(b8)
b0 b7
b0
Symbol
U0TB
U2TB
Address
03A3 16, 03A216
037B 16, 037A16
When reset
Indeterminate
Indeterminate
Function
R W
Transmit data (Note)
Nothing is assigned.
In an attempt to write to these bits, write “0.” The value, if read, turns out to be indeterminate.
Figure 2.11.4 UARTi transmit buffer register (i = 0 and 2)
UARTi receive buffer register
(b15)
b7
(b8)
b0 b7
Symbol
U0RB
U2RB
b0
0
Bit
symbol
Address
03A7 16, 03A6 16
037F16, 037E 16
When reset
Indeterminate
Indeterminate
Function
(During clock synchronous
serial I/O mode)
Bit name
Receive data
Function
(During UART mode)
R W
Receive data
Nothing is assigned.
In an attempt to write to these bits, write “0.” The value, if read, turns out to be “0.”
Reserved bit
Must always be set to “0”
Must always be set to “0”
OER
Overrun error flag (Note 1)
0 : No overrun error
1 : Overrun error found
0 : No overrun error
1 : Overrun error found
FER
Framing error flag (Note 1) Invalid
0 : No framing error
1 : Framing error found
PER
Parity error flag (Note 1)
Invalid
0 : No parity error
1 : Parity error found
SUM
Error sum flag (Note 1)
Invalid
0 : No error
1 : Error found
Notes 1: Bits 15 through 12 are set to “0” when the serial I/O mode select bit (bits 2 to 0 at addresses
03A0 16 and 0378 16) are set to “000 2” or the receive enable bit is set to “0”.
(Bit 15 is set to “0” when bits 14 to 12 all are set to “0.”) Bits 14 and 13 are also set to “0” when
the lower byte of the UARTi receive buffer register (addresses 03A6 16 and 037E 16) is read out.
2: The arbtration lost detecting flag is assigned to U2RB and is written only “0.” Nothing is
assinged to bit 11 of U0RB. This bit can neither be set nor reset, when read, he the value is “0.”
Figure 2.11.5 UARTi receive buffer register (i = 0 and 2)
UARTi bit rate generator
b7
b0
Symbol
U0BRG
U2BRG
Address
03A1 16
0379 16
When reset
Indeterminate
Indeterminate
Function
Assuming that set value = n, BRGi divides the count source by
n+1
Values that can be set
R W
0016 to FF16
Figure 2.11.6 UARTi bit rate generator (i = 0 and 2)
Rev. 1.0
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UART0 transmit/receive mode register
b7
b6
b5
b4
b3
b2
b1
Symbol
U0MR
b0
Address
03A0 16
When reset
0016
Function
(During clock synchronous
serial I/O mode)
Bit
symbol
Bit name
SMD0
Serial I/O mode select bit
Must be fixed to 001
b2 b1 b0
0 0 0 : Serial I/O invalid
0 1 0 : Inhibited
0 1 1 : Inhibited
1 1 1 : Inhibited
SMD1
SMD2
Function
(During UART mode)
R W
b2 b1 b0
1 0 0 : Transfer data 7 bits long
1 0 1 : Transfer data 8 bits long
1 1 0 : Transfer data 9 bits long
0 0 0 : Serial I/O invalid
0 1 0 : Inhibited
0 1 1 : Inhibited
1 1 1 : Inhibited
CKDIR Internal/external clock
select bit
0 : Internal clock
1 : External clock
0 : Internal clock
1 : External clock
STPS
Stop bit length select bit
Invalid
0 : One stop bit
1 : Two stop bits
PRY
Odd/even parity select bit
Invalid
Valid when bit 6 = “1”
0 : Odd parity
1 : Even parity
PRYE
Parity enable bit
Invalid
0 : Parity disabled
1 : Parity enabled
SLEP
Sleep select bit
Must always be “0”
0 : Sleep mode deselected
1 : Sleep mode selected
Figure 2.11.7 UART0 transmit/receive mode register
UART2 transmit/receive mode register
b7
b6
b5
b4
b3
b2
b1
Symbol
U2MR
b0
Address
037816
Bit
symbol
Bit name
SMD0
Serial I/O mode select bit
When reset
0016
Function
(During clock synchronous
serial I/O mode)
Must be fixed to 001
b2 b1 b0
0 0 0 : Serial I/O invalid
0 1 0 : Inhibited
0 1 1 : Inhibited
1 1 1 : Inhibited
SMD1
SMD2
Function
(During UART mode)
R W
b2 b1 b0
1 0 0 : Transfer data 7 bits long
1 0 1 : Transfer data 8 bits long
1 1 0 : Transfer data 9 bits long
0 0 0 : Serial I/O invalid
0 1 0 : Inhibited
0 1 1 : Inhibited
1 1 1 : Inhibited
CKDIR
Internal/external clock
select bit
0 : Internal clock
1 : External clock
0 : Internal clock
1 : External clock
STPS
Stop bit length select bit
Invalid
0 : One stop bit
1 : Two stop bits
PRY
Odd/even parity select bit
Invalid
Valid when bit 6 = “1”
0 : Odd parity
1 : Even parity
PRYE
Parity enable bit
Invalid
0 : Parity disabled
1 : Parity enabled
IOPOL
TxD, RxD I/O polarity
reverse bit
0 : No reverse
1 : Reverse
Usually set to “0”
0 : No reverse
1 : Reverse
Usually set to “0”
Figure 2.11.8 UART2 transmit/receive mode register
Rev. 1.0
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UART0 transmit/receive control register 0
b7
b6
b5
b4
1
b3
b2
b1
b0
Symbol
U0C0
0
Bit
symbol
CLK0
Address
03A416
Bit name
BRG count source
select bit
CLK1
Reserved bit
TXEPT
Transmit register empty
flag
Reserved bit
When reset
0816
Function
(During clock synchronous
serial I/O mode)
b1 b0
Function
(During UART mode)
b1 b0
0 0 : f 1 is selected
0 1 : f 8 is selected
1 0 : f 32 is selected
1 1 : Inhibited
0 0 : f 1 is selected
0 1 : f 8 is selected
1 0 : f 32 is selected
1 1 : Inhibited
Must always be set to “0”
Must always be set to “0”
0 : Data present in transmit
register (during transmission)
1 : No data present in transmit
register (transmission
completed)
0 : Data present in transmit register
(during transmission)
1 : No data present in transmit
register (transmission completed)
Must always be set to “1”
Must always be set to “1”
NCH
Data output select bit
0 : TXDi pin is CMOS output
1 : TXDi pin is N-channel
open-drain output
0: TXDi pin is CMOS output
1: TXDi pin is N-channel
open-drain output
CKPOL
CLK polarity select bit
0 : Transmit data is output at
falling edge of transfer clock
and receive data is input at
rising edge
1 : Transmit data is output at
rising edge of transfer clock
and receive data is input at
falling edge
Must always be set to “0”
UFORM Transfer format select bit
0 : LSB first
1 : MSB first
R W
Must always be set to “0”
Figure 2.11.9 UART0 transmit/receive control register 0
Rev. 1.0
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UART2 transmit/receive control register 0
b7
b6
b5
b4
1
b3
b2
b1
b0
Symbol
U2C0
0
Bit
symbol
CLK0
Address
037C16
Bit name
BRG count source
select bit
CLK1
Reserved bit
TXEPT
When reset
0816
Function
(During clock synchronous
serial I/O mode)
Function
(During UART mode)
b1 b0
b1 b0
0 0 : f1 is selected
0 1 : f8 is selected
1 0 : f32 is selected
1 1 : Inhibited
0 0 : f1 is selected
0 1 : f8 is selected
1 0 : f32 is selected
1 1 : Inhibited
Must always be set to “0”
Must always be set to “0”
R W
0 : Data present in transmit
0 : Data present in transmit register
Transmit register empty
register (during transmission)
(during transmission)
flag
1 : No data present in transmit
1 : No data present in transmit
register (transmission
completed)
Reserved bit
Must always be set to “1”
register (transmission completed)
Must always be set to “1”
Nothing is assigned.
In an attempt to write to this bit, write “0.” The value, if read, turns out to be “0.”
CKPOL
CLK polarity select bit
0 : Transmit data is output at
falling edge of transfer clock
and receive data is input at
rising edge
1 : Transmit data is output at
rising edge of transfer clock
and receive data is input at
falling edge
UFORM Transfer format select bit 0 : LSB first
(Note 3)
1 : MSB first
Must always be set to “0”
0 : LSB first
1 : MSB first
Note 1: Only clock synchronous serial I/O mode and 8-bit UART mode are valid.
Figure 2.11.10 UART2 transmit/receive control register 0
Rev. 1.0
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UART0 transmit/receive control register 1
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
U0C1
Bit
symbol
Address
03A516
When reset
0216
Function
(During clock synchronous
serial I/O mode)
Bit name
Function
(During UART mode)
TE
Transmit enable bit
0 : Transmission disabled
1 : Transmission enabled
0 : Transmission disabled
1 : Transmission enabled
TI
Transmit buffer
empty flag
0 : Data present in
transmit buffer register
1 : No data present in
transmit buffer register
0 : Data present in
transmit buffer register
1 : No data present in
transmit buffer register
RE
Receive enable bit
0 : Reception disabled
1 : Reception enabled
0 : Reception disabled
1 : Reception enabled
RI
Receive complete flag
0 : No data present in
receive buffer register
1 : Data present in
receive buffer register
0 : No data present in
receive buffer register
1 : Data present in
receive buffer register
RW
Nothing is assigned.
In an attempt to write to these bits, write “0.” The value, if read, turns out to be “0.”
Figure 2.11.11 UART0 transmit/receive control register 1
UART2 transmit/receive control register 1
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
U2C1
Bit
symbol
Address
037D 16
Bit name
When reset
0216
Function
(During clock synchronous
serial I/O mode)
Function
(During UART mode)
TE
Transmit enable bit
0 : Transmission disabled
1 : Transmission enabled
0 : Transmission disabled
1 : Transmission enabled
TI
Transmit buffer
empty flag
0 : Data present in
transmit buffer register
1 : No data present in
transmit buffer register
0 : Data present in
transmit buffer register
1 : No data present in
transmit buffer register
RE
Receive enable bit
0 : Reception disabled
1 : Reception enabled
0 : Reception disabled
1 : Reception enabled
RI
Receive complete flag
0 : No data present in
receive buffer register
1 : Data present in
receive buffer register
0 : No data present in
receive buffer register
1 : Data present in
receive buffer register
UART2 transmit interrupt
cause select bit
0 : Transmit buffer empty
(TI = 1)
1 : Transmit is completed
(TXEPT = 1)
0 : Transmit buffer empty
(TI = 1)
1 : Transmit is completed
(TXEPT = 1)
U2RRM UART2 continuous
receive mode enable bit
0 : Continuous receive
mode disabled
1 : Continuous receive
mode enabled
Invalid
U2LCH Data logic select bit
0 : No reverse
1 : Reverse
0 : No reverse
1 : Reverse
U2ERE Error signal output
enable bit
Must always be set to “0”
0 : Output disabled
1 : Output enabled
U2IRS
RW
Figure 2.11.12 UART2 transmit/receive control register 1
Rev. 1.0
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UART transmit/receive control register 2
b7
b6
b5
0 0
b4
b3
b2
0 0
b1
b0
Symbol
UCON
0
Bit
symbol
Address
03B016
Function
(During clock synchronous
serial I/O mode)
Bit name
0 : Transmit buffer empty (Tl = 1)
1 : Transmission completed
UART0 transmit
interrupt cause select bit
U0IRS
When reset
X00000002
(TXEPT = 1)
Function
(During UART mode)
R W
0 : Transmit buffer empty (Tl = 1)
1 : Transmission completed
(TXEPT = 1)
Reserved bit
Must always be set to “0”
Must always be set to “0”
U0RRM UART0 continuous
receive mode select bit
0 : Continuous receive mode
Invalid
Reserved bits
Must always be set to “0”
disabled
0 : Continuous receive mode
enable
Must always be set to “0”
Nothing is assigned.
In an attempt to write to this bit, write “0.” The value, if read, turns out to be “0.”
Figure 2.11.13 UART transmit/receive control register 2
UART2 special mode register
b7
0
b6
b5
b4
b3
0 0
b2
b1
b0
Symbol
U2SMR
0 0 0
Bit
symbol
Address
037716
Bit name
When reset
0016
Function
(During clock synchronous
serial I/O mode)
Function
(During UART mode)
Reserved bits
Must always be set to “0”
Must always be set to “0”
ACSE
Auto clear function
select bit of transmit
enable bit
Must always be set to “0”
0 : No auto clear function
1 : Auto clear at occurrence of
bus collision
SSS
Transmit start condition
select bit
Must always be set to “0”
0 : Ordinary
1 : Falling edge of RxD2
Must always be set to “0”
Must always be set to “0”
Reserved bit
R W
Figure 2.11.14 UART2 special mode register
Rev. 1.0
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2.11.2 Clock Synchronous Serial I/O Mode
The clock synchronous serial I/O mode uses a transfer clock to transmit and receive data. Tables 2.11.2
and 2.11.3 list the specifications of the clock synchronous serial I/O mode. Figures 2.11.15 and 2.11.16
show the UARTi transmit/receive mode register in clock synchronous serial I/O mode.
Table 2.11.2 Specifications of clock synchronous serial I/O mode (1)
Item
Specification
Transfer data format
• Transfer data length: 8 bits
Transfer clock
• When internal clock is selected (bit 3 at addresses 03A016, 037816 = “0”) :
fi/ 2(n+1) (Note 1) fi = f1, f8, f32
• When external clock is selected (bit 3 at addresses 03A016, 037816 = “1”) :
Input from CLKi pin
Transmission start condition • To start transmission, the following requirements must be met:
_ Transmit enable bit (bit 0 at addresses 03A516, 037D16) = “1”
_ Transmit buffer empty flag (bit 1 at addresses 03A516, 037D16) = “0”
• Furthermore, if external clock is selected, the following requirements must
also be met:
_ CLKi polarity select bit (bit 6 at addresses 03A416, 037C16) = “0”:
CLKi input level = “H”
_ CLKi polarity select bit (bit 6 at addresses 03A416, 037C16) = “1”:
CLKi input level = “L”
Reception start condition • To start reception, the following requirements must be met:
_ Receive enable bit (bit 2 at addresses 03A516, 037D16) = “1”
_ Transmit enable bit (bit 0 at addresses 03A516, 037D16) = “1”
_ Transmit buffer empty flag (bit 1 at addresses 03A516, 037D16) = “0”
• Furthermore, if external clock is selected, the following requirements must
also be met:
_ CLKi polarity select bit (bit 6 at addresses 03A416, 037C16) = “0”:
CLKi input level = “H”
_ CLKi polarity select bit (bit 6 at addresses 03A416, 037C16) = “1”:
CLKi input level = “L”
Interrupt request
• When transmitting
_ Transmit interrupt cause select bit (bit 0 at address 03B016, bit 4 at
generation timing
address 037D16) = “0”: Interrupts requested when data transfer from UARTi
transfer buffer register to UARTi transmit register is completed
_ Transmit interrupt cause select bit (bit 0 at address 03B016, bit 4 at
address 037D16) = “1”: Interrupts requested when data transmission from
UARTi transfer register is completed
• When receiving
_ Interrupts requested when data transfer from UARTi receive register to
UARTi receive buffer register is completed
Error detection
• Overrun error (Note 2)
This error occurs when the next data is ready before contents of UARTi
receive buffer register are read out
Rev. 1.0
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Table 2.11.3 Specifications of clock synchronous serial I/O mode (2)
Item
Select function
Specification
• CLK polarity selection
Whether transmit data is output/input at the rising edge or falling edge of the
transfer clock can be selected
• LSB first/MSB first selection
Whether transmission/reception begins with bit 0 or bit 7 can be selected
• Continuous receive mode selection
Reception is enabled simultaneously by a read from the receive buffer register
• Switching serial data logic (UART2)
Whether to reverse data in writing to the transmission buffer register or
reading the reception buffer register can be selected.
• TxD, RxD I/O polarity reverse (UART2)
This function is reversing TxD port output and RxD port input. All I/O data
level is reversed.
Notes 1: “n” denotes the value 0016 to FF16 that is set to the UART bit rate generator.
2: If an overrun error occurs, the UARTi receive buffer will have the next data written in. Note also
that the UARTi receive interrupt request bit is not set to “1”.
Rev. 1.0
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UART0 transmit/receive mode register
b7
b6
b5
b4
b3
0
b2
b1
b0
0 0 1
Symbol
U0MR
Address
03A0 16
Bit symbol
SMD0
When reset
0016
Bit name
Serial I/O mode select bit
SMD1
SMD2
CKDIR
Internal/external clock
select bit
Function
RW
b2 b1 b0
0 0 1 : Clock synchronous serial
I/O mode
0 : Internal clock
1 : External clock
STPS
PRY
Invalid in clock synchronous serial I/O mode
PRYE
SLEP
0 (Must always be set to “0” in clock synchronous serial I/O mode)
Figure 2.11.15 UART0 transmit/receive mode registers in clock synchronous serial I/O mode
UART2 transmit/receive mode register
b7
0
b6
b5
b4
b3
b2
b1
b0
0 0 1
Symbol
U2MR
Address
037816
Bit symbol
SMD0
Bit name
Serial I/O mode select bit
SMD1
SMD2
CKDIR
When reset
0016
Internal/external clock
select bit
Function
R W
b2 b1 b0
0 0 1 : Clock synchronous serial
I/O mode
0 : Internal clock
1 : External clock
STPS
PRY
Invalid in clock synchronous serial I/O mode
PRYE
IOPOL
TxD, RxD I/O polarity
reverse bit (Note)
0 : No reverse
1 : Reverse
Note: Usually set to “0”.
Figure 2.11.16 UART2 transmit/receive mode register in clock synchronous serial I/O mode
Rev. 1.0
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Table 2.11.4 lists the functions of the input/output pins during clock synchronous serial I/O mode. Note
that for a period from when the UARTi operation mode is selected to when transfer starts, the TxDi pin
outputs a “H”. (If the N-channel open-drain is selected, this pin is in floating state.)
Table 2.11.4 Input/output pin functions in clock synchronous serial I/O mode
Pin name
Function
Method of selection
TxDi
(P63, P70)
Serial data output
(Outputs dummy data when performing reception only)
RxDi
(P62, P71)
Serial data input
Port P6 2 and P7 1 direction register (bits 2 at address 03EE 16,
bit 1 at address 03EF 16)= “0”
(Can be used as an input port when performing transmission only)
CLKi
(P55, P72)
Transfer clock output
Internal/external clock select bit (bit 3 at address 03A0 16, 0378 16) = “0”
Port P5 5 and P7 2 direction register (bit 5 at address 03EB 16,
bit 2 at address 03EF 16) = “0”
Transfer clock input
Internal/external clock select bit (bit 3 at address 03A0 16, 0378 16) = “1”
Port P5 5 and P7 2 direction register (bit 5 at address 03EB 16,
bit 2 at address 03EF 16) = “0”
Rev. 1.0
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• Example of transmit timing (when internal clock is selected)
Tc
Transfer clock
“1”
Transmit enable
bit (TE)
“0”
Data is set in UARTi transmit buffer register
“1”
Transmit buffer
empty flag (Tl)
“0”
TCLK Transferred from UARTi transmit buffer register to UARTi transmit register
Stopped pulsing because CTS = “H”
Stopped pulsing because transfer enable bit = “0”
CLKi
TxDi
D0 D1 D2 D3 D4 D5 D6 D7
Transmit
register empty
flag (TXEPT)
“1”
Transmit interrupt
request bit (IR)
“1”
D0 D 1 D2 D3 D4 D5 D6 D7
D0 D1 D 2 D 3 D4 D5 D6 D7
“0”
“0”
Cleared to “0” when interrupt request is accepted, or cleared by software
Shown in ( ) are bit symbols.
The above timing applies to the following settings:
• Internal clock is selected.
• CLK polarity select bit = “0”.
• Transmit interrupt cause select bit = “0”.
Tc = TCLK = 2(n + 1) / fi
fi: frequency of BRGi count source (f 1, f8, f32)
n: value set to BRGi
• Example of receive timing (when external clock is selected)
Receive enable
bit (RE)
Transmit enable
bit (TE)
Transmit buffer
empty flag (Tl)
“1”
“0”
“1”
“0”
Dummy data is set in UARTi transmit buffer register
“1”
“0”
Transferred from UARTi transmit buffer register to UARTi transmit register
1 / fEXT
CLKi
Receive data is taken in
D0 D1 D2 D3 D4 D5 D6 D7
RxDi
“1”
Receive complete
“0”
flag (Rl)
Receive interrupt
request bit (IR)
Transferred from UARTi receive register
to UARTi receive buffer register
D 0 D1 D2
D3 D4 D5
Read out from UARTi receive buffer register
“1”
“0”
Cleared to “0” when interrupt request is accepted, or cleared by software
Shown in ( ) are bit symbols.
The above timing applies to the following settings:
• External clock is selected.
• CLK polarity select bit = “0”.
Meet the following conditions are met when the CLK
input before data reception = “H”
• Transmit enable bit “1”
• Receive enable bit “1”
• Dummy data write to UARTi transmit buffer register
fEXT: frequency of external clock
Figure 2.11.17 Typical transmit/receive timings in clock synchronous serial I/O mode
Rev. 1.0
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(1) Polarity select function
As shown in Figure 2.11.18, the CLK polarity select bit (bit 6 at addresses 03A416, 037C16) allows
selection of the polarity of the transfer clock.
• When CLK polarity select bit = “0”
CLKi
TXDi
D0
D1
D2
D3
D4
D5
D6
D7
RXDi
D0
D1
D2
D3
D4
D5
D6
D7
D4
D5
D6
D7
Note 1: The CLK pin level when not
transferring data is “H”.
• When CLK polarity select bit = “1”
CLKi
D0
TXDi
D1
D2
D3
Note 2: The CLK pin level when not
transferring data is “L”.
Figure 2.11.18 Polarity of transfer clock
(2) LSB first/MSB first select function
As shown in Figure 2.11.19, when the transfer format select bit (bit 7 at addresses 03A416, 037C16) =
“0”, the transfer format is “LSB first”; when the bit = “1”, the transfer format is “MSB first”.
• When transfer format select bit = “0”
CLKi
TXDi
D0
D1
D2
D3
D4
D5
D6
D7
RXDi
D0
D1
D2
D3
D4
D5
D6
D7
D2
D1
D0
LSB first
• When transfer format select bit = “1”
CLKi
TXDi
D7
D6
D5
D4
D3
MSB first
RXDi
D7
D6
D5
D4
D3
D2
D1
D0
Note: This applies when the CLK polarity select bit = “0”.
Figure 2.11.19 Transfer format
Rev. 1.0
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(3) Continuous receive mode
If the continuous receive mode enable bit (bits 2 at address 03B016, bit 5 at address 037D16) is set to
“1”, the unit is placed in continuous receive mode. In this mode, when the receive buffer register is
read out, the unit simultaneously goes to a receive enable state without having to set dummy data to
the transmit buffer register back again.
(4) Serial data logic switch function (UART2)
When the data logic select bit (bit6 at address 037D16) = “1”, and writing to transmit buffer register or
reading from receive buffer register, data is reversed. Figure 2.11.20 shows the example of serial data
logic switch timing.
•When LSB first
Transfer clock
“H”
“L”
TxD2
“H”
(no reverse) “L”
TxD2
“H”
(reverse) “L”
D0
D1
D2
D3
D4
D5
D6
D7
D0
D1
D2
D3
D4
D5
D6
D7
Figure 2.11.20 Serial data logic switch timing
Rev. 1.0
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2.11.3 Clock Asynchronous Serial I/O (UART) Mode
The UART mode allows transmitting and receiving data after setting the desired transfer rate and transfer
data format. Tables 2.11.5 and 2.11.6 list the specifications of the UART mode. Figure 2.11.21 and
2.11.22 show the UARTi transmit/receive mode register in UART mode.
Table 2.11.5 Specifications of UART Mode (1)
Item
Transfer data format
Specification
• Character bit (transfer data): 7 bits, 8 bits, or 9 bits as selected
• Start bit: 1 bit
• Parity bit: Odd, even, or nothing as selected
• Stop bit: 1 bit or 2 bits as selected
Transfer clock
• When internal clock is selected (bit 3 at addresses 03A016, 037816 = “0”) :
fi/16(n+1) (Note 1) fi = f1, f8, f32
• When external clock is selected (bit 3 at addresses 03A016, 037816 =“1”) :
fEXT/16(n+1)(Note 1) (Note 2)
Transmission start condition • To start transmission, the following requirements must be met:
- Transmit enable bit (bit 0 at addresses 03A516, 037D16) = “1”
- Transmit buffer empty flag (bit 1 at addresses 03A516, 037D16) = “0”
Reception start condition • To start reception, the following requirements must be met:
- Receive enable bit (bit 2 at addresses 03A516, 037D16) = “1”
- Start bit detection
Interrupt request
• When transmitting
generation timing
- Transmit interrupt cause select bits (bits 0 at address 03B016, bit4 at
address 037D16) = “0”: Interrupts requested when data transfer from UARTi
transfer buffer register to UARTi transmit register is completed
- Transmit interrupt cause select bits (bits 0 at address 03B016, bit4 at
address 037D16) = “1”: Interrupts requested when data transmission from
UARTi transfer register is completed
• When receiving
- Interrupts requested when data transfer from UARTi receive register to
UARTi receive buffer register is completed
Error detection
• Overrun error (Note 3)
This error occurs when the next data is ready before contents of UARTi
receive buffer register are read out
• Framing error
This error occurs when the number of stop bits set is not detected
• Parity error
This error occurs when if parity is enabled, the number of 1’s in parity and
character bits does not match the number of 1’s set
• Error sum flag
This flag is set (= 1) when any of the overrun, framing, and parity errors is
encountered
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Table 2.11.6 Specifications of UART Mode (2)
Item
Select function
Specification
• Sleep mode selection (UART0)
This mode is used to transfer data to and from one of multiple slave microcomputers
• Serial data logic switch (UART2)
This function is reversing logic value of transferring data. Start bit, parity bit
and stop bit are not reversed.
• TxD, RxD I/O polarity switch
This function is reversing TxD port output and RxD port input. All I/O data
level is reversed.
Notes 1: ‘n’ denotes the value 0016 to FF16 that is set to the UARTi bit rate generator.
2: fEXT is input from the CLKi pin.
3: If an overrun error occurs, the UARTi receive buffer will have the next data written in. Note also
that the UARTi receive interrupt request bit is not set to “1”.
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UART0 transmit/receive mode register
b7
b6
b5
b4
b3
b2
b1
Symbol
U0MR
b0
Address
03A0 16
Bit symbol
SMD0
Bit name
Serial I/O mode select bit
SMD1
SMD2
CKDIR
When reset
0016
Function
1 0 0 : Transfer data 7 bits long
1 0 1 : Transfer data 8 bits long
1 1 0 : Transfer data 9 bits long
Internal / external clock
select bit
Stop bit length select bit
0 : Internal clock
1 : External clock
0 : One stop bit
1 : Two stop bits
PRY
Odd / even parity
select bit
Valid when bit 6 = “1”
0 : Odd parity
1 : Even parity
PRYE
Parity enable bit
0 : Parity disabled
1 : Parity enabled
SLEP
Sleep select bit
0 : Sleep mode deselected
1 : Sleep mode selected
STPS
RW
b2 b1 b0
Figure 2.11.21 UART0 transmit/receive mode register in UART mode
UART2 transmit/receive mode register
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
U2MR
Address
0378 16
Bit symbol
SMD0
Bit name
Serial I/O mode select bit
SMD1
SMD2
CKDIR
When reset
0016
Function
1 0 0 : Transfer data 7 bits long
1 0 1 : Transfer data 8 bits long
1 1 0 : Transfer data 9 bits long
Internal / external clock
select bit
Stop bit length select bit
0 : Internal clock
1 : External clock
0 : One stop bit
1 : Two stop bits
PRY
Odd / even parity
select bit
Valid when bit 6 = “1”
0 : Odd parity
1 : Even parity
PRYE
Parity enable bit
0 : Parity disabled
1 : Parity enabled
IOPOL
TxD, RxD I/O polarity
reverse bit (Note)
0 : No reverse
1 : Reverse
STPS
RW
b2 b1 b0
Note: Usually set to “0”.
Figure 2.11.22 UART2 transmit/receive mode register in UART mode
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Table 2.11.7 lists the functions of the input/output pins during UART mode. Note that for a period from
when the UARTi operation mode is selected to when transfer starts, the TxDi pin outputs a “H”. (If the Nchannel open-drain is selected, this pin is in floating state.)
Table 2.11.7 Input/output pin functions in UART mode
Pin name
Function
Method of selection
TxDi
(P63, P70)
Serial data output
RxDi
(P62, P71)
Serial data input
Port P62 and P71 direction register (bit 2 at address 03EE16,
bit 1 at address 03EF16)= “0”
(Can be used as an input port when performing transmission only)
CLKi
(P55, P72)
Programmable input port
Internal/external clock select bit (bit 3 at address 03A016, 037816) = “0”
Port P55 and P72 direction register (bit 5 at address 03EB16,
bit 2 at address 03EF16) = “0”
Transfer clock input
Internal/external clock select bit (bit 3 at address 03A016, 037816) = “1”
Port P55 and P72 direction register (bit 5 at address 03EB16,
bit 2 at address 03EF16) = “0”
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<UART0>
• Example of transmit timing when transfer data is 8 bits long (parity enabled, one stop bit)
The transfer clock stops momentarily as CTS is “H” when the stop bit is checked.
The transfer clock starts as the transfer starts immediately CTS changes to “L”.
Tc
Transfer clock
Transmit enable
bit(TE)
“1”
Transmit buffer
empty flag(TI)
“1”
“0”
Data is set in UARTi transmit buffer register.
“0”
Transferred from UARTi transmit buffer register to UARTi transmit register
Start
bit
TxDi
Parity
bit
ST D0 D1 D2 D3 D4 D5 D6 D7
Transmit register
empty flag (TXEPT)
“1”
Transmit interrupt
request bit (IR)
“1”
P
Stopped pulsing because transmit enable bit = “0”
Stop
bit
SP
ST D0 D1 D2 D3 D4 D5 D6 D7
P
ST D0 D1
SP
“0”
“0”
Cleared to “0” when interrupt request is accepted, or cleared by software
Shown in ( ) are bit symbols.
The above timing applies to the following settings :
• Parity is enabled.
• One stop bit.
• Transmit interrupt cause select bit = “1”.
Tc = 16 (n + 1) / fi or 16 (n + 1) / f EXT
fi : frequency of BRGi count source (f 1, f8, f32)
fEXT : frequency of BRGi count source (external clock)
n : value set to BRGi
<UART0>
• Example of transmit timing when transfer data is 9 bits long (parity disabled, two stop bits)
Tc
Transfer clock
Transmit enable
bit(TE)
“1”
Transmit buffer
empty flag(TI)
“1”
“0”
Data is set in UARTi transmit buffer register
“0”
Transferred from UARTi transmit buffer register to UARTi transmit register
Start
bit
TxDi
Stop
bit
ST D0 D1 D2 D3 D4 D5 D6 D7 D8 SP SP
Stop
bit
ST D0 D1 D2 D3 D4 D5 D6 D7 D8 SPSP
ST D0 D1
“1”
Transmit register
empty flag (TXEPT)
“0”
Transmit interrupt
request bit (IR)
“1”
“0”
Cleared to “0” when interrupt request is accepted, or cleared by software
Shown in ( ) are bit symbols.
The above timing applies to the following settings :
• Parity is disabled.
• Two stop bits.
• Transmit interrupt cause select bit = “0”.
Tc = 16 (n + 1) / fi or 16 (n + 1) / f EXT
fi : frequency of BRGi count source (f 1, f8, f32)
fEXT : frequency of BRGi count source (external clock)
n : value set to BRGi
Figure 2.11.23 Typical transmit/receive timings in UART mode
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<UART2>
• Example of transmit timing when transfer data is 8 bits long (parity enabled, one stop bit)
Tc
Transfer clock
Transmit enable
bit(TE)
“1”
Transmit buffer
empty flag(TI)
“1”
Data is set in UART2 transmit buffer register
“0”
Note
“0”
Transferred from UART2 transmit buffer register to UARTi transmit register
Parity
bit
Start
bit
TxD2
ST D0 D1 D2 D3 D4 D5 D6 D7
P
Stop
bit
SP
ST D0 D1 D2 D3 D4 D5 D6 D7
P
SP
“1”
Transmit register
empty flag (TXEPT) “0”
Transmit interrupt
request bit (IR)
“1”
“0”
Cleared to “0” when interrupt request is accepted, or cleared by software
Shown in ( ) are bit symbols.
The above timing applies to the following settings :
• Parity is enabled.
• One stop bit.
• Transmit interrupt cause select bit = “1”.
Tc = 16 (n + 1) / fi
fi : frequency of BRG2 count source (f 1, f8, f32)
n : value set to BRG2
Note: The transmit is started with overflow timing of BRG after having written in a value at the transmit buffer in the above timing.
<UART2, UART0>
• Example of receive timing when transfer data is 8 bits long (parity disabled, one stop bit)
BRGi count
source
Receive enable bit
“1”
“0”
Stop bit
Start bit
RxDi
D1
D0
D7
Sampled “L”
Receive data taken in
Transfer clock
Receive
complete flag
“1”
Receive interrupt
request bit
“1”
“0”
Reception triggered when transfer clock
is generated by falling edge of start bit
Transfered from UARTi receive register to
UARTi receive buffer register
“0”
Cleared to “0” when interrupt request is accepted, or cleared by software
The above timing applies to the following settings :
•Parity is disabled.
•One stop bit.
Figure 2.11.23 Typical transmit/receive timings in UART mode
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(1) Sleep mode (UART0)
This mode is used to transfer data between specific microcomputers among multiple microcomputers
connected using UART0. The sleep mode is selected when the sleep select bit (bit 7 at address
03A016) is set to “1” during reception. In this mode, the unit performs receive operation when the MSB
of the received data = “1” and does not perform receive operation when the MSB = “0”.
(2) Function for switching serial data logic (UART2)
When the data logic select bit (bit 6 of address 037D16) is assigned 1, data is inverted in writing to the
transmission buffer register or reading the reception buffer register. Figure 2.11.24 shows the example of timing for switching serial data logic.
• When LSB first, parity enabled, one stop bit
Transfer clock
“H”
“L”
TxD2
“H”
(no reverse)
“L”
TxD2
“H”
(reverse)
“L”
ST
D0
D1
D2
D3
D4
D5
D6
D7
P
SP
ST
D0
D1
D2
D3
D4
D5
D6
D7
P
SP
ST : Start bit
P : Even parity
SP : Stop bit
Figure 2.11.24 Timing for switching serial data logic
(3) TxD, RxD I/O polarity reverse function (UART2)
This function is to reverse TxD pin output and RxD pin input. The level of any data to be input or output
(including the start bit, stop bit(s), and parity bit) is reversed. Set this function to “0” (not to reverse) for
usual use.
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(4) Bus collision detection function and other functions (UART2)
This function is to sample the output level of the TxD pin and the input level of the RxD pin at the rising
edge of the transfer clock; if their values are different, then an interrupt request occurs. Figure 2.11.26
shows the example of detection timing of a buss collision (in UART mode).
And also, bit 5 of the special UART2 mode register is used as the selection bit for auto clear function
select bit of enable bit. Setting this bit to “1” automatically resets the transmit enable bit to “0” when “1”
is set in the bus collision detection interrupt request bit (nonconformity) (refer to Figure 2.11.25).
Bit 6 of the special UART2 mode register is used as the transmit start condition select bit. Setting this
bit to “1” starts the TxD transmission in synchronization with the falling edge of the RxD terminal (refer
to Figure 2.11.26).
Transfer clock
“H”
“L”
TxD2
“H”
ST
SP
ST
SP
“L”
RxD2
“H”
“L”
Bus collision detection
interrupt request signal
“1”
Bus collision detection
interrupt request bit
“1”
“0”
“0”
ST : Start bit
SP : Stop bit
Figure 2.11.25 Detection timing of a bus collision (in UART mode)
Transmit start condition select bit (Bit 6 of the UART2 special mode register)
0: In normal state
CLK
TxD
Enabling transmission
With "1: falling edge of RxD2" selected
CLK
TxD
RxD
Figure 2.11.26 Some other functions
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2.11.4 Clock-asynchronous Serial I/O Mode (Compliant with the SIM Interface)
The SIM interface is used for connecting the microcomputer with a memory card I/C or the like; adding
some extra settings in UART2 clock-asynchronous serial I/O mode allows the user to effect this function.
Tables 2.11.8 and 2.11.9 show the specifications of clock-asynchronous serial I/O mode (compliant with
the SIM interface).
Table 2.11.8 Specifications of clock-asynchronous serial I/O mode (compliant with the SIM
interface) (1)
Item
Specification
Transfer data format
• Transfer data 8-bit UART mode (bit 2 through bit 0 of address 037816 = “1012”)
• One stop bit (bit 4 of address 037816 = “0”)
• With the direct format chosen
Set parity to “even” (bit 5 and bit 6 of address 037816 = “1” and “1” respectively)
Set data logic to “direct” (bit 6 of address 037D16 = “0”).
Set transfer format to LSB (bit 7 of address 037C16 = “0”).
• With the inverse format chosen
Set parity to “odd” (bit 5 and bit 6 of address 037816 = “0” and “1” respectively)
Set data logic to “inverse” (bit 6 of address 037D16 = “1”)
Set transfer format to MSB (bit 7 of address 037C16 = “1”)
Transfer clock
• With the internal clock chosen (bit 3 of address 037816 = “0”) :
fi / 16 (n + 1) (Note 1) : fi=f1, f8, f32
• With an external clock chosen (bit 3 of address 037816 = “1”) :
fEXT / 16 (n+1) (Note 1) (Note 2)
Other settings
• The sleep mode select function is not available for UART2
• Set transmission interrupt factor to “transmission completed”
(bit 4 of address 037D16 = “1”)
Transmission start condition • To start transmission, the following requirements must be met:
- Transmit enable bit (bit 0 of address 037D16) = “1”
- Transmit buffer empty flag (bit 1 of address 037D16) = “0”
Reception start condition • To start reception, the following requirements must be met:
- Reception enable bit (bit 2 of address 037D16) = “1”
- Detection of a start bit
Interrupt request
generation timing
• When transmitting
When data transmission from the UART2 transfer register is completed
(bit 4 of address 037D16 = “1”)
• When receiving
When data transfer from the UART2 receive register to the UART2 receive
buffer register is completed
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Table 2.11.9 Specifications of clock-asynchronous serial I/O mode (compliant with the SIM
interface) (2)
Item
Error detection
Specification
• Overrun error (see the specifications of clock-asynchronous serial I/O) (Note 3)
• Framing error (see the specifications of clock-asynchronous serial I/O)
• Parity error (see the specifications of clock-asynchronous serial I/O)
- On the reception side, an “L” level is output from the TxD2 pin by use of the parity error
signal output function (bit 7 of address 037D16 = “1”) when a parity error is detected
- On the transmission side, a parity error is detected by the level of input to
the RxD2 pin when a transmission interrupt occurs
• The error sum flag (see the specifications of clock-asynchronous serial I/O)
Notes 1: ‘n’ denotes the value 0016 to FF16 that is set to the UARTi bit rate generator.
2: fEXT is input from the CLK2 pin.
3: If an overrun error occurs, the UART2 receive buffer will have the next data written in. Note also
that the UARTi receive interrupt request bit is not set to “1”.
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Tc
Transfer clock
Transmit enable
bit(TE)
“1”
Transmit buffer
empty flag(TI)
“1”
“0”
Data is set in UARTi transmit buffer register
“0”
Transferred from UARTi transmit buffer register to UARTi transmit register
Start
bit
TxD2
Parity
bit
ST D0 D1 D2 D3 D4 D5 D6 D7
P
Stop
bit
ST D0 D1 D2 D3 D4 D5 D6 D7
SP
P
SP
P
SP
RxD2
A “L” level returns from TxD 2 due to
the occurrence of a parity error.
Signal conductor level
(Note 1)
ST D0 D1 D2 D3 D4 D5 D6 D7
P
SP
ST D0 D1 D2 D3 D4 D5 D6 D7
The level is
detected by the
interrupt routine.
The level is detected by the
interrupt routine.
“1”
Transmit register
empty flag (TXEPT)
“0”
Transmit interrupt
request bit (IR)
“1”
“0”
Cleared to “0” when interrupt request is accepted, or cleared by software
Shown in ( ) are bit symbols.
The above timing applies to the following settings :
• Parity is enabled.
• One stop bit.
• Transmit interrupt cause select bit = “1”.
Tc = 16 (n + 1) / fi or 16 (n + 1) / f EXT
fi : frequency of BRGi count source (f 1, f8, f32)
fEXT : frequency of BRGi count source (external clock)
n : value set to BRGi
Tc
Transfer clock
Receive enable
bit (RE)
“1”
“0”
Start
bit
RxD2
Parity
bit
ST D0 D1 D2 D3 D4 D5 D6 D7
P
Stop
bit
SP
ST D0 D1 D2 D3 D4 D5 D6 D7
P
SP
TxD2
A “L” level returns from TxD 2 due to
the occurrence of a parity error.
Signal conductor level
(Note 1)
Receive complete
flag (RI)
“1”
Receive interrupt
request bit (IR)
“1”
ST D0 D1 D2 D3 D4 D5 D6 D7
P
SP
ST D0 D1 D2 D3 D4 D5 D6 D7
P
SP
“0”
Read to receive buffer
Read to receive buffer
“0”
Cleared to “0” when interrupt request is accepted, or cleared by software
Shown in ( ) are bit symbols.
The above timing applies to the following settings :
• Parity is enabled.
• One stop bit.
• Transmit interrupt cause select bit = “0”.
Tc = 16 (n + 1) / fi or 16 (n + 1) / f EXT
fi : frequency of BRGi count source (f 1, f8, f32)
fEXT : frequency of BRGi count source (external clock)
n : value set to BRGi
Note: Equal in waveform because TxD 2 and RxD 2 are connected.
Figure 2.11.27 Typical transmit/receive timing in UART mode (compliant with the SIM interface)
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(1) Function for outputting a parity error signal
With the error signal output enable bit (bit 7 of address 037D16) assigned “1”, you can output an “L”
level from the TxD2 pin when a parity error is detected. In step with this function, the generation timing
of a transmission completion interrupt changes to the detection timing of a parity error signal. Figure
2.11.28 shows the output timing of the parity error signal.
• LSB first
Transfer
clock
“H”
RxD2
“H”
TxD2
“H”
Receive
complete flag
“L”
ST
D0
D1
D2
D3
D4
D5
D6
D7
P
SP
“L”
Hi-Z
“L”
“1”
“0”
ST : Start bit
P : Even Parity
SP : Stop bit
Figure 2.11.28 Output timing of the parity error signal
(2) Direct format/inverse format
Connecting the SIM card allows you to switch between direct format and inverse format. If you choose
the direct format, D0 data is output from TxD2. If you choose the inverse format, D7 data is inverted
and output from TxD2.
Figure 2.11.29 shows the SIM interface format.
Transfer
clcck
TxD2
(direct)
D0
D1
D2
D3
D4
D5
D6
D7
P
TxD2
(inverse)
D7
D6
D5
D4
D3
D2
D1
D0
P
P : Even parity
Figure 2.11.29 SIM interface format
Figure 2.11.30 shows the example of connecting the SIM interface. Connect TxD2 and RxD2 and apply
pull-up.
Microcomputer
SIM card
TxD2
RxD2
Figure 2.11.30 Connecting the SIM interface
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2.11.5 Serial Interface Ports
The I/O ports (P67, P70 to P72) function as I/O ports of UART2 and multi-master I2C-BUS interface 0
(refer to “2.11.6 Multi-master I2C-BUS interface i”) . Set the connection between both serial interfaces
and each port by bits 0 and 1 (BSEL0 and BSEL1) of the peripheral mode register (address 027D16) and
bit 2 (FIICON) of the I2C0 port selection register (address 02E516).
FIICON
RxD2
UART2
CLK2
TxD2
“1”
“0”
“1”
“0”
“1”
“0”
BSEL0
“0”
“1”
SCL1/RxD2/P71
BSEL1
“0”
“1”
“0”
SCL
“1”
SCL2/CLK2/P72
BSEL0
Multi-master I2C-BUS
interface 0
“0”
SDA
“0”
“1”
“1”
SDA1/TxD2/P70
BSEL1
“0”
“1”
SDA2/P67
Figure 2.11.31 Serial interface port control
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and ON-SCREEN DISPLAY CONTROLLER
2.11.6 Multi-master I2C-BUS Interface 0 and Multi-master I2C-BUS Interface 1
The multi-master I2C-BUS interface 0 and 1 have each dedicated circuit and operate independently.
The multi-master I2C-BUS interface i is a serial communications circuit, conforming to the Philips I2CBUS data transfer format. This interface i, offering both arbitration lost detection and a synchronous
functions, is useful for the multi-master serial communications.
Figures 2.11.32 and Figure 2.11.33 show a block diagram of the multi-master I2C-BUS interface i and
Table 2.11.13 shows multi-master I2C-BUS interface i functions.
This multi-master I2C-BUS interface i consists of the I2Ci address register, the I2Ci data shift register, the
I2Ci clock control register, the I2Ci control register, the I2Ci status register, the I2Ci port selection register
and other control circuits.
Table 2.11.13 Multi-master I2C-BUS Interface Functions
Item
Format
Function
In conformity with Philips I2C-BUS standard:
10-bit addressing format
7-bit addressing format
High-speed clock mode
Standard clock mode
Communication mode
In conformity with Philips I2C-BUS standard:
Master transmission Master reception
Slave transmission
Slave reception
SCL clock frequencyn
16.1 kHz to 400 kHz (at BCLK = 10 MHz)
Note : We are not responsible for any third party’s infringement of patent rights or other rights attributable
to the use of the control function (bits 6 and 7 of the I2C control register at address 027D16) for
connections between the I2C-BUS interface 0 and ports (SCL1, SCL2, SDA1, SDA2).
Rev. 1.0
118
P72/CLK2/SCL2
P71/RxD2/SCL1
P67/SDA2
P71/TxD2/SDA1
“0”
“1”
“0”
“1”
“0”
“1”
“0”
“1”
(SCL)
Serial
clock
(SDA)
Serial
data
Noise
elimination
circuit
Noise
elimination
circuit
Clock
control
circuit
BB
circuit
AL
circuit
Data
control
circuit
clock control register
(IIC0S2)
Clock division
I2C0
b0
ACK F AST
CCR4 CCR3 CCR2 CCR1 CCR0
BIT MODE
b0
b7
I2C0 data shift register (IIC0S0)
ACK
b7
Address comparator
BCLK
10 BIT
S AD
AL S
b0
ESO BC2 BC1 BC0
b0
I2C0 status
register (IIC0S1)
AL AAS AD0 LRB
Interrupt
request signal
(IICIRQ)
Bit counter
I2C0 control register (IIC0S1D)
b7
Internal data bus
MST TRX BB PIN
b7
Interrupt
generating
circuit
Note: Select ports to use for multi-master I2C-BUS interface by bits 0 and 1 (BSEL0, BSEL1) of peripheral mode register.
BSEL1
BSEL0
BSEL1
BSEL0
2
b7 I C0 address register (IIC0S0D) b0
SAD6 SAD5 SAD4 SAD3 SAD2 SAD1 SAD0 RBW
0
0
0
0
FIICON
0
0
b0
I2C0 port selection register (IIC0S2D)
0
b7
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
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Fig. 2.11.32 Block Diagram of Multi-master I2C-BUS Interface 0
Rev. 1.0
119
120
P94/DA1/SCL3
P93/DA0/SDA3
(SCL)
Serial
clock
(SDA)
Serial
data
Noise
elimination
circuit
Noise
elimination
circuit
Clock
control
circuit
BB
circuit
AL
circuit
Data
control
circuit
2
b7 I C1 address register (IIC1S0D) b0
b0
b0
ACK F AST
CCR4 CCR3 CCR2 CCR1 CCR0
BIT MODE
I2C1 data shift register (IIC1S0)
I2C1 clock control register
(IIC1S2)
Clock division
ACK
b7
b7
Address comparator
SAD6 SAD5 SAD4 SAD3 SAD2 SAD1 SAD0 RBW
BCLK
10 BIT
S AD
AL S
b0
ESO BC2 BC1 BC0
b0
I2C1 status
register (IIC1S1)
AL AAS AD0 LRB
Interrupt
request signal
(IICIRQ)
Bit counter
I2C1 control register (IIC1S1D)
b7
Internal data bus
MST TRX BB PIN
b7
Interrupt
generating
circuit
0
0
0
0
FIICON
0
0
b0
I2C1 port selection register (IIC1S2D)
0
b7
MITSUBISHI MICROCOMPUTERS
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
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Fig. 2.11.33 Block Diagram of Multi-master I2C-BUS Interface 1
Rev. 1.0
MITSUBISHI MICROCOMPUTERS
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
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(1) I2Ci port selection register (i = 0, 1)
The I2Ci port selection register consists of bit to validate the multi-master I2C-BUS interface i function.
■ Bit 2: Multi-master I2C-BUS interface valid bit (FIICON)
When this bit is “0,” the multi-master I2C-BUS interface i is nonactive; when “1,” it is active. When
selecting active, multi-master I2C-BUS interface 0 is connected with the ports selected by bits 0 and 1
of the peripheral mode register (address 027D16) and multi-master I2C-BUS interface 1 is connected
with the ports P93 and P94.
Note: It needs 10-BCLK cycles from setting this bit to “1” to being active of multi-master I2C-BUS
interface i. Accordingly, do not access multi-master I2C-BUS interface i-related registers in this
period.
I2Ci port selection register (i = 0, 1)
b7 b6 b5 b4 b3 b2 b1 b0
0 0 0 0 0
0 0
Symbol
IIC0S2D
IIC1S2D
Bit Symbol
Address
02E516
02ED16
Bit name
Reserved bits
FIICON
When reset
00??00002
00??00002
Function
R W
Must always be set to “0”
2
Multi-master I C-BUS
interface valid bit
Reserved bits
0 : Nonactive
1 : Active
Must always be set to “0”
Fig. 2.11.34 I2Ci port selection register (i = 0, 1)
Rev. 1.0
121
MITSUBISHI MICROCOMPUTERS
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
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(2) I2Ci data shift register, I2Ci transmit buffer register (i = 0, 1)
The I2Ci data shift register 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 clock, and each time one-bit data is output, the data of this register are shifted one bit
to the left. When data is received, it is input to this register from bit 0 in synchronization with the SCL
clock, and each time one-bit data is input, the data of this register are shifted one bit to the left.
The I2Ci data shift register is in a write enable status only when the ESO bit of the I2Ci control register
is “1.” The bit counter is reset by a write instruction to the I2Ci data shift register. When both the ESO
bit and the MST bit of the I2Ci status register are “1,” the SCL is output by a write instruction to the I2Ci
data shift register. Reading data from the I2Ci data shift register is always enabled regardless of the
ESO bit value.
The I2Ci transmit buffer register is a register to store transmit data (slave address) to the I2Ci data shift
register before RESTART condition generation. That is, in master, transmit data written to the I2Ci
transmit buffer register is written to the I2Ci data shift register simultaneously. However, the SCL is not
output. The I2Ci transmit buffer register can be written only when the ESO bit is “1,” reading data from
the I2Ci transmit buffer register is disabled regardless of the ESO bit value.
Notes 1: To write data into the I2Ci data shift register or the I2Ci transmit buffer register after the MST
bit value changes from “1” to “0” (slave mode), keep an interval of 20 BCLK or more.
2: To generate START/RESTART condition after the I2Ci data shift register or the I2Ci transmit
buffer register is written, keep an interval of 2 BCLK or more.
Rev. 1.0
122
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
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I2Ci data shift register (i = 0, 1)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
IIC0S0
IIC1S0
Bit Symbol
D0
Address
02E016
02E816
Bit name
Data shift register
D1
When reset
Indeterminate
Indeterminate
Function
R W
This is an 8-bit shift register to store
receive data and write transmit data.
D2
D3
D4
D5
D6
D7
Note: To write data into the I2Ci data shift register after setting the MST bit to “0” (slave
mode), keep an interval of 8 machine cycles or more.
Fig. 2.11.35 I2Ci data shift register (i = 0, 1)
I2Ci transmit buffer register (i = 0, 1)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
IIC0S0S
IIC1S0S
Address
02E616
02EE16
Bit Symbol
Bit name
S0S0
Transmit buffer register
S0S1
When reset
Indeterminate
Indeterminate
Function
R W
This is an 8-bit register to write transmit
data to I2Ci data shift register.
S0S2
S0S3
S0S4
S0S5
S0S6
S0S7
Fig. 2.11.36 I2Ci transmit buffer register (i = 0, 1)
Rev. 1.0
123
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
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(3) I2Ci address register (i = 0, 1)
_______
The I2Ci address register 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 are detected.
_______
■ Bit 0: read/write bit (RBW)
Not used when comparing addresses, in the 7-bit addressing mode. In the 10-bit addressing mode,
the first address data to be received is compared with the contents (SAD6 to SAD0 + RBW) of the I2Ci
address register.
The RBW bit 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 and the 10-bit addressing
mode, the address data transmitted from the master is compared with the contents of these bits.
I2Ci address register (i = 0, 1)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
IIC0S0D
IIC1S0D
Bit Symbol
Address
02E116
02E916
Bit name
When reset
0016
0016
Function
RBW
Read/write bit
<Only in 10-bit addressing (in slave) mode>
The last significant bit of address data is
compared.
0 : Wait the first byte of slave address
after START condition
(read state)
1 : Wait the first byte of slave address
after RESTART condition
(write state)
SAD0
Slave address
<In both modes>
The address data is compared.
SAD1
R W
SAD2
SAD3
SAD4
SAD5
SAD6
Fig. 2.11.37 I2Ci address register (i = 0, 1)
Rev. 1.0
124
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
(4) I2Ci clock control register (i = 0, 1)
The I2Ci clock control register 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.
■ 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 set. When the
bit is set to “1,” the high-speed clock mode is set.
■ 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 set and SDA goes to LOW at the occurrence of an ACK clock. When the bit is set to “1,”
the ACK non-return mode is set. The SDA is held in the HIGH status at the occurrence of an ACK
clock.
However, when the slave address matches the address data in the reception of address data at ACK
BIT = “0,” the SDA is automatically made LOW (ACK is returned). If there is a mismatch between the
slave address and the address data, the SDA is automatically made HIGH (ACK is not returned).
✽ACK clock: Clock for acknowledgement
■ Bit 7: ACK clock bit (ACK)
This bit specifies a mode of acknowledgment which is an acknowledgment response of data transmission. When this bit is set to “0,” the no ACK clock mode is set. In this case, no ACK clock occurs after
data transmission. When the bit is set to “1,” the ACK clock mode is set and the master generates an
ACK clock upon completion of each 1-byte data transmission.The device for transmitting address data
and control data releases the SDA at the occurrence of an ACK clock (make SDA HIGH) and receives
the ACK bit generated by the data receiving device.
Note: Do not write data into the I2Ci clock control register during transmission. If data is written during
transmission, the I2Ci clock generator is reset, so that data cannot be transmitted normally.
Rev. 1.0
125
MITSUBISHI MICROCOMPUTERS
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
I2Ci clock control register (i = 0, 1)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
IIC0S2
IIC1S2
Bit Symbol
CCR0
Address
02E416
02EC16
When reset
0016
0016
Bit name
SCL frequency control
bits
Function
Setup value of
CCR4–CCR0
00 to 02
CCR1
CCR2
Setup disabled Setup disabled
Setup disabled
04
Setup disabled
250
05
100
400 (See note)
83.3
166
:
CCR4
R W
High speed
clock mode
03
06
CCR3
Standard
clock mode
333
500/CCR value 1000/CCR value
1D
17.2
34.5
1E
16.6
33.3
1F
16.1
32.3
(at BCLK = 10 MHz, unit : kHz)
FAST MODE
ACK BIT
ACK
SCL mode specification 0 : Standard clock mode
bit
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
Note: At 400 kHz in the high-speed clock mode, the duty is as below.
“0” period : “1” period = 3 : 2
In the other cases, the duty is as below.
“0” period : “1” period = 1 : 1
Fig. 2.11.38 I2Ci clock control register (i = 0, 1)
Rev. 1.0
126
MITSUBISHI MICROCOMPUTERS
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
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(5) I2Ci control register (i = 0, 1)
The I2Ci control register controls the 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. An interrupt request
signal occurs immediately after the number of bits specified with these bits are transmitted.
When a START condition is received, these bits become “0002” and the address data is always transmitted and received in 8 bits.
Note: When the bit counter value = “1112,” a STOP condition and START condition cannot be waited.
■ Bit 3: I2C-BUS interface i use enable bit (ESO)
This bit enables usage of the multimaster I2C-BUS interface i. When this bit is set to “0,” the use
disable status is provided, so the SDA and the SCL become high-impedance. When the bit is set to
“1,” use of the interface is enabled.
When ESO = “0,” the following is performed.
• PIN = “1,” BB = “0” and AL = “0” are set (they are bits of the I2Ci status register).
• Writing data to the I2Ci data shift register and the I2Ci transmit buffer register 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 “(6) I2Ci status
register,” bit 1) is received, transmission 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 I2Ci address register
are compared with address data. When this bit is set to “1,” the 10-bit addressing format is selected, all
the bits of the I2Ci address register are compared with address data.
Rev. 1.0
127
MITSUBISHI MICROCOMPUTERS
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
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I2Ci control register (i = 0, 1)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
IIC0S1D
IIC1S1D
Bit Symbol
BC0
Address
02E316
02EB16
When reset
0016
0016
Bit name
Function
Bit counter
(Number of
transmit/receive bits)
b2 b1 b0
ESO
I2C-BUS interface i use
enable bit
0 : Disabled
1 : Enabled
ALS
Data format selection
bit
0 : Addressing format
1 : Free data format
BC1
BC2
10BIT SAD
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0
1
0
1
0
1
0
1
R W
:8
:7
:6
:5
:4
:3
:2
:1
Address format selection 0 : 7-bit addressing format
bit
1 : 10-bit addressing format
Nothing is assigned.
In an attempt to write to these bits, write “0.”
The value, if read, turns out to be “0.”
Fig. 2.11.39 I2Ci control register (i = 0, 1)
Rev. 1.0
128
MITSUBISHI MICROCOMPUTERS
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
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(6) I2Ci status register (i = 0, 1)
The I2Ci status register controls the I2C-BUS interface i status. Bits 0 to 3, 5 are read-only bits and bits
4, 6, 7 can be read out and written to.
■ 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 I2Ci data shift register or the I2Ci transmit
buffer register.
■ Bit 1: general call detecting flag (AD0)
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.
✽General call: The master transmits the general call address “0016” to all slaves.
■ Bit 2: slave address comparison flag (AAS)
This flag indicates a comparison result of address data.
<<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 matches the slave address
stored in the high-order 7 bits of the I2Ci address register.
• A general call is received.
<<In the slave reception 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 I2Ci address register (8 bits consists of slave address
and RBW), the first bytes match.
<<The state of this bit is changed from “1” to “0” by executing a write instruction to the I2Ci data shift
register or the I2Ci transmit buffer register.>>
■ Bit 3: arbitration lost✽ detecting flag (AL)
n the master transmission mode, when a device other than the microcomputer sets the SDA to “L,”,
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.” 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 receive and recognize its own
slave address transmitted by another master device.
✽Arbitration lost: The status in which communication as a master is disabled.
Rev. 1.0
129
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■ Bit 4: I2C-BUS interface i interrupt request bit (PIN)
This bit generates an interrupt request signal. Each time 1-byte data is transmitted, the state of the
PIN bit changes from “1” to “0.” At the same time, an interrupt request signal is sent to the CPU. The
PIN bit is set to “0” in synchronization with a falling edge of the last clock (including the ACK clock) of
an internal clock and an interrupt request signal occurs in synchronization with a falling edge of the
PIN bit. When detecting the STOP condition in slave, the multi-master I2C-BUS interface interrupt
request bit (IR) is set to “1” (interrupt requested) regardless of falling of PIN bit. When the PIN bit is “0,”
the SCL is kept in the “0” state and clock generation is disabled. Figure 2.11.41 shows an interrupt
request signal generating timing chart.
The PIN bit is set to “1” in any one of the following conditions.
• Writing “1” to the PIN bit
• Executing a write instruction to the I2Ci data shift register or the I2Ci transmit buffer register (See note).
• When the ESO bit is “0”
• At reset
Note : It takes 8 BCLK cycles or more until PIN bit becomes “1” after write instructions are executed
to these registers.
The conditions in which the PIN bit is set to “0” are shown below:
• 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 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. When this bit is set to “1,” this bus system is busy and
the occurrence of a START condition is disabled by the START condition duplication prevention function (See note).
This flag can be written by software only in the master transmission mode. In the other modes, this bit is
set to “1” by detecting a START condition and set to “0” by detecting a STOP condition. When the ESO bit
of the I2Ci control register is “0” and at reset, the BB flag is kept in the “0” state.
■ Bit 6: communication mode specification bit (transfer direction specification bit: TRX)
This bit decides the 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 into the SDA in synchronization with
the clock generated on the SCL.
When the ALS bit of the I2Ci control register is “0” in the slave reception mode is selected, the TRX bit
___
is set to “1” (transmit) if the least significant bit (R/W bit) of the address data transmitted by the master
___
is “1.” When the ALS bit is “0” and the R/W bit is “0,” the TRX bit is cleared to “0” (receive).
The TRX bit is cleared to “0” in one of the following conditions.
• When arbitration lost is detected.
• When a STOP condition is detected.
• When occurence of a START condition is disabled by the START condition duplication prevention
function (Note).
• With MST = “0” and when a START condition is detected.
• With MST = “0” and when ACK non-return is detected.
• At reset
Rev. 1.0
130
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■ 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, and also the clocks required for data communication are generated on the SCL.
The MST bit is cleared to “0” in one of the following conditions.
• Immediately after completion of 1-byte data transmission when arbitration lost is detected
• When a STOP condition is detected.
• When occurence of a START condition is disabled by the START condition duplication preventing
function (See note).
• At reset
Note: The START condition duplication prevention function disables the following: the START condition generation; bit counter reset, and SCL output with the generation. This bit is valid from
setting of BB flag to the completion of 1-byte transmittion/reception (occurrence of transmission/
reception interrupt request) <IICIRQ>.
I2Ci status register (i = 0, 1)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
IIC0S1
IIC1S1
Bit Symbol
LRB
Address
02E216
02EA16
When reset
0001000?2
0001000?2
Bit name
Last receive bit
Function
0 : Last bit = “0”
1 : Last bit = “1”
R W
(See note 1)
AD0
General call detecting
flag (See note)
AAS
Slave address comparison 0 : Address mismatch
flag (See note)
1 : Address match
(See note 1)
Arbitration lost detecting 0 : Not detected
flag (See note)
1 : Detected
(See note 1)
AL
2
0 : No general call detected
1 : General call detected (See note 1)
PIN
I C-BUS interface i
interrupt request bit
0 : Interrupt request issued
1 : No interrupt request issued (See note 2)
BB
Bus busy flag
0 : Bus free
1 : Bus busy
Communication mode
specification bits
b7b6
TRX
MST
0
0
1
1
(See note 1)
0 : Slave receive mode
1 : Slave transmit mode
0 : Master receive mode
1 : Master transmit mode
Notes 1: These bits and flags can be read out, but cannot be written.
2: This bit can be written only “1.”
Fig. 2.11.40 I2Ci status register (i = 0, 1)
SCL
PIN
IICIRQ
Fig. 2.11.41 Interrupt request signal generation timing
Rev. 1.0
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(7) START condition generation method
When the ESO bit of the I2Ci control register is “1,” execute a write instruction to the I2Ci status register
to set the MST, TRX and BB bits to “1.” A START condition will then be generated. After that, the bit
counter becomes “0002” and an SCL for 1 byte is output. The START condition generation timing and
BB bit set timing are different in the standard clock mode and the high-speed clock mode. Refer to
Figure 2.11.42 for the START condition generation timing diagram, and Table 2.11.13 for the START
condition/STOP condition generation timing table.
I2Ci status register write signal
SCL
SDA
Setup
time
Hold time
Set time for
BB flag
BB flag
Fig. 2.11.42 START condition generation timing diagram
(8) STOP condition generation method
When the ESO bit of the I2Ci control register is “1,” execute a write instruction to the I2Ci status register
for setting the MST bit and the TRX bit to “1” and the BB bit to “0”. A STOP condition will then be
generated. The STOP condition generation timing and the BB flag reset timing are different in the
standard clock mode and the high-speed clock mode. Refer to Figure 2.11.43 for the STOP condition
generation timing diagram, and Table 2.11.13 for the START condition/STOP condition generation
timing table.
I2Ci status register write signal
SCL
SDA
Setup
time
BB flag
Hold time
Reset time
for
BB flag
Fig. 2.11.43 STOP condition generation timing diagram
Table 2.11.13 START condition/STOP condition generation timing table
Item
Standard Clock Mode
High-speed Clock Mode
Setup time
5.35 µs (53.5 cycles)
1.85 µs (18.5 cycles)
Hold time
4.9 µs (49 cycles)
2.4 µs (24 cycles)
Set/reset time for BB flag
3.75 µs (37.5 cycles)
0.85 µs (8.5 cycles)
Note: Absolute time at BCLK = 10 MHz. The value in parentheses denotes the number of BCLK cycles.
Rev. 1.0
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(9) START/STOP condition detect conditions
The START/STOP condition detect conditions are shown in Figure 2.11.44 and Table 2.11.14. Only
when the 3 conditions of Table 2.11.14 are satisfied, a START/STOP condition can be detected.
Note: When a STOP condition is detected in the slave mode (MST = 0), an interrupt request signal
<IICIRQ> is generated to the CPU.
SCL release time
SCL
SDA
(START condition)
Setup
time
Hold time
Setup
time
Hold time
SDA
(STOP condition)
Fig. 2.11.44 START condition/STOP condition detect timing diagram
Table 2.11.14 START condition/STOP condition detect conditions
Standard Clock Mode
High-speed Clock Mode
6.5 µs (65 cycles) < SCL release time
1.0 µs (10 cycles) < SCL release time
3.25 µs (32.5 cycles) < Setup time
0.5 µs (5 cycles) < Setup time
3.25 µs (32.5 cycles) < Hold time
0.5 µs (5 cycles) < Hold time
Note: Absolute time at BCLK = 10 MHz. The value in parentheses denotes the number of BCLK cycles.
Rev. 1.0
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(10) Address data communication
There are two address data communication formats, namely, 7-bit addressing format and 10-bit addressing format. The respective address communication formats is described below.
■ 7-bit addressing format
To meet the 7-bit addressing format, set the 10BIT SAD bit of the I2Ci control register to “0.” The first
7-bit address data transmitted from the master is compared with the high-order 7-bit slave address
stored in the I2Ci address register. At the time of this comparison, address comparison of the RBW bit
of the I2Ci address register is not made. For the data transmission format when the 7-bit addressing
format is selected, refer to Figure 2.11.45, (1) and (2).
■ 10-bit addressing format
To meet the 10-bit addressing format, set the 10BIT SAD bit of the I2Ci control register to “1.” An
address comparison is made between the first-byte address data transmitted from the master and the
7-bit slave address stored in the I2Ci address register. At the time of this comparison, an address
___
comparison between the RBW bit of the I2Ci 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 R/W 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 matches the slave address, the AAS bit of the I2Ci status register is
set to “1.” After the second-byte address data is stored into the I2Ci data shift register, make an
address comparison between the second-byte data and the slave address by software. When the
address data of the 2nd bytes matches the slave address, set the RBW bit of the I2Ci address register
___
to “1” by software. This processing can match the 7-bit slave address and R/W data, which are received after a RESTART condition is detected, with the value of the I2Ci address register. For the data
transmission format when the 10-bit addressing format is selected, refer to Figure 2.11.45, (3) and (4).
Rev. 1.0
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(11) Example of Master Transmission
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 I2Ci address register and “0” in the RBW bit.
➁ Set the ACK return mode and SCL = 100 kHz by setting “8516” in the I2Ci clock control register.
➂ Set “1016” in the I2Ci status register and hold the SCL at the HIGH.
➃ Set a communication enable status by setting “0816” in the I2Ci control register.
➄ Set the address data of the destination of transmission in the high-order 7 bits of the I2Ci data shift
register and set “0” in the least significant bit.
➅ Set “F016” in the I2Ci status register to generate a START condition. At this time, an SCL for 1 byte
and an ACK clock automatically occurs.
➆ Set transmit data in the I2Ci data shift register. At this time, an SCL and an ACK clock automatically
occurs.
➇ When transmitting control data of more than 1 byte, repeat step ➆.
➈ Set “D016” in the I2Ci status register. After this, if ACK is not returned or transmission ends, a STOP
condition will be generated.
(12) Example of Slave Reception
An example of slave reception in the high-speed clock mode, at the SCL frequency of 400 kHz, in the
ACK non-return mode, using the addressing format, is shown below.
➀ Set a slave address in the high-order 7 bits of the I2Ci address register and “0” in the RBW bit.
➁ Set the no ACK clock mode and SCL = 400 kHz by setting “2516” in the I2Ci clock control register.
➂ Set “1016” in the I2Ci status register and hold the SCL at the HIGH.
➃ Set a communication enable status by setting “0816” in the I2Ci control register.
➄ When a START condition is received, an address comparison is made.
➅
•When all transmitted address are“0” (general call):
AD0 of the I2Ci status register is set to “1”and an interrupt request signal occurs.
•When the transmitted addresses match the address set in ➀:
ASS of the I2Ci status register is set to “1” and an interrupt request signal occurs.
•In the cases other than the above:
AD0 and AAS of the I2Ci status register are set to “0” and no interrupt request signal occurs.
➆ Set dummy data in the I2Ci data shift register.
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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S
Slave address R/W
A
Data
A
Data
A/A
P
A
P
Data
A
7 bits
“ 0”
1 to 8 bits
1 to 8 bits
(1) A master-transmitter transmits data to a slave-receiver
S
Slave address R/W
A
Data
A
Data
7 bits
“ 1”
1 to 8 bits
1 to 8 bits
(2) A master-receiver receives data from a slave-transmitter
S
Slave address
R/W
1st 7 bits
A
Slave address
2nd byte
A
Data
A/A
P
1 to 8 bits
7 bits
“ 0”
8 bits
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
A
Slave address
2nd byte
A
Sr
Slave address
R/W
1st 7 bits
Data
7 bits
“0”
8 bits
7 bits
“1” 1 to 8 bits
(4) A master-receiver receives data from a slave-transmitter with a 10-bit address
S : START condition
A : ACK bit
Sr : Restart condition
P : STOP condition
R/W : Read/Write bit
A
Data
A
P
1 to 8 bits
From master to slave
From slave to master
Fig. 2.11.45 Address data communication format
(13) Precautions when using multi-master I2C-BUS interface i
■ BCLK operation mode
Select the no-division mode and set the main clock frequency to f(XIN) = 10 MHz.
■ Used instructions
Specify byte (.B) as data size to access multi-master I2C-BUS interface i-related registers.
■ Read-modify-write instruction
The precautions when the read-modify-write instruction such as BSET, BCLR etc. is executed for
each register of the multi-master I2C-BUS interface are described below.
•I2Ci data shift register (IICiS0)
When executing the read-modify-write instruction for this register during transfer, data may
become a value not intended.
•I2Ci address register (IICiS0D)
When the read-modify-write instruction is executed for this register at detecting the STOP con______
dition, data may become a value not intended. It is because hardware changes the read/write
bit (RBW) at the above timing.
•I2Ci
status register (IICiS1)
Do not execute the read-modify-write instruction for this register because all bits of this register
are changed by hardware.
control register (IICiS1D)
•I2Ci
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
hardware changes the bit counter (BC0–BC2) at the above timing.
•I2Ci
clock control register (IICiS2)
The read-modify-write instruction can be executed for this register.
•I2Ci
port selection register (IICiS2D)
Since the read value of high-order 4 bits is indeterminate, the read-modify-write instruction
cannot be used.
•I2Ci
transmit buffer register (IICiS0S)
Since the value of all bits is indeterminate, the read-modify-write instruction cannot be used.
Rev. 1.0
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■ START condition generating procedure using multi-master
:
FCLR
I
(Interrupt disabled)
BTST
5, IICiS1
(BB flag confirming and branch process)
JC
BUSBUSY
BUSFREE:
MOV.B
SA, IICiS0
(Writing of slave address value <SA>)
NOP
NOP
MOV.B
FSET
➀
#F0H, IICiS1
(Trigger of START condition generating)
I
(Interrupt enabled)
➁
:
BUSBUSY:
FSETI
(Interrupt enabled)
:
➀ Be sure to add NOP instruction ✕ 2 between writing the slave address value and setting trigger of
START condition generating shown the above procedure example.
➁ When using multi-master system, 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.
When using single-master system, it is not necessary to disable interrupts above.
■ RESTART condition generating procedure
MOV.B
:
SA, IICiS0S
(Writing of slave address value <SA>)
#F0H, IICiS1
(Trigger of RESTART condition generating)
➀
NOP
NOP
MOV.B
:
➀ Use the I2Ci transmit buffer register to write the slave address value to the I2Ci data shift register.
And also, be sure to add NOP instruction ✕ 2.
■ Writing to I2Ci 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.
■ Process of after STOP condition generating
Do not write data in the I2Ci data shift register (IICiS0) and the I2Ci status register (IICiS1) 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 do not have
the problem.
Rev. 1.0
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2.12 A-D Converter
The A-D converter consists of one 8-bit successive approximation A-D converter circuit with a capacitive
coupling amplifier. Pins P36, P37, P40–P43 also function as the analog signal input pins. The direction
registers of these pins for A-D conversion must therefore be set to input. The Vref connect bit (bit 5 at
address 03D716) can be used to isolate the resistance ladder of the A-D converter from the reference
voltage (VREF) when the A-D converter is not used. Doing so stops any current flowing into the resistance
ladder from VREF, reducing the power dissipation. When using the A-D converter, start A-D conversion only
after setting bit 5 of 03D716 to connect VREF.
The result of A-D conversion is stored in the A-D registers of the selected pins.
Table 2.12.1 shows the performance of the A-D converter. Figure 2.12.1 shows the block diagram of the AD converter, and Figures 2.12.2 to 2.12.5 show the A-D converter-related registers.
Table 2.12.1 Performance of A-D converter
Item
Performance
Method of A-D conversion Successive approximation (capacitive coupling amplifier)
Analog input voltage (Note 1) 0V to AVCC (VCC)
Operating clock φAD (Note 2) fAD/divide-by-2 of fAD/divide-by-4 of fAD, fAD=f(XIN)
Resolution
Absolute precision
8-bit
VCC = 5V
• Without sample and hold function: ±5 LSB
• With sample and hold function: ±5 LSB
Operating modes
One-shot mode, repeat mode, single sweep mode, repeat sweep mode 0,
and repeat sweep mode 1
Analog input pins
6 pins (AN0 to AN5)
A-D conversion start condition • Software trigger
A-D conversion starts when the A-D conversion start flag changes to “1”
Conversion speed per pin • Without sample and hold function
49 φAD cycles
• With sample and hold function
28 φAD cycles
Notes 1: Does not depend on use of sample and hold function.
2: Divide the frequency if f(XIN) exceeds 10 MHz, and make φAD frequency equal to 10 MHz. Without
sample and hold function, set the φAD frequency to 250kHz min.
With the sample and hold function, set the φAD frequency to 1MHz min.
Rev. 1.0
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CKS1=1
φAD
CKS0=1
fAD
1/2
1/2
CKS0=0
CKS1=0
A-D conversion rate
selection
(VCC) VREF
VCUT=0
Resistor ladder
VSS
VCUT=1
Successive conversion register
A-D control register 1 (address 03D7 16)
A-D control register 0 (address 03D6 16)
Addresses
(03C4 16)
(03C6 16)
A-D register 0(8)
A-D register 1(8)
(03C8 16)
A-D register 2(8)
(03CA 16)
A-D register 3(8)
(03CC16)
A-D register 4(8)
(03CE 16)
A-D register 5(8)
Vref
Decoder
V IN
Comparator
Data bus high-order
Data bus low-order
AN0
CH2,CH1,CH0=010
AN1
CH2,CH1,CH0=011
AN2
CH2,CH1,CH0=100
AN3
CH2,CH1,CH0=101
AN4
CH2,CH1,CH0=110
AN5
CH2,CH1,CH0=111
Figure 2.12.1 Block diagram of A-D converter
Rev. 1.0
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A-D control register 0 (Note 1)
b7
b6
b5
b4
b3
b2
b1
b0
0
Symbol
ADCON0
Bit symbol
Address
03D616
When reset
00000??? 2
Bit name
R W
Function
b2 b1 b0
Analog input pin select bit
CH0
CH1
CH2
A-D operation mode
select bit 0
MD0
MD1
Reserved bit
0 0 0 : Do not set
0 0 1 : Do not set
0 1 0 : AN 0 is selected
0 1 1 : AN 1 is selected
1 0 0 : AN 2 is selected
1 0 1 : AN 3 is selected
1 1 0 : AN 4 is selected
1 1 1 : AN 5 is selected
(Note 2)
b4 b3
0 0 : One-shot mode
0 1 : Repeat mode
1 0 : Single sweep mode
1 1 : Repeat sweep mode 0
Repeat sweep mode 1
(Note 2)
Must always be set to “0”
ADST
A-D conversion start flag
0 : A-D conversion disabled
1 : A-D conversion started
CKS0
Frequency select bit 0
0 : fAD/4 is selected
1 : fAD/2 is selected
Notes 1: If the A-D control register is rewritten during A-D conversion, the conversion result is
indeterminate.
2: When changing A-D operation mode, set analog input pin again.
Figure 2.12.2 A-D control register 0
A-D control register 1 (Note)
b7
b6
0 0
b5
b4
b3
0
b2
b1
b0
Symbol
ADCON1
Bit symbol
Address
03D716
When reset
00 16
Bit name
A-D sweep pin select bit
SCAN0
Function
R W
When single sweep and repeat sweep
mode 0 are selected
b1 b0
0 0 : Do not set
0 1 : AN 0 and AN 1 (2 pins)
1 0 : AN 0 to AN 3 (4 pins)
1 1 : AN 0 to AN 5 (6 pins)
When repeat sweep mode 1 is selected
SCAN1
b1 b0
0 0 : Do not set
0 1 : Do not set
1 0 : AN 0 (1 pin)
1 1 : AN 0 and AN 1 (2 pins)
MD2
A-D operation mode
select bit 1
Reserved bit
CKS1
VCUT
0 : Any mode other than repeat sweep
mode 1
1 : Repeat sweep mode 1
Most always be set to “0”
Frequency select bit 1
0 : f AD/2 or f AD/4 is selected
1 : f AD is selected
Vref connect bit
0 : Vref not connected
1 : Vref connected
Reserved bits
Most always be set to “0”
Note: If the A-D control register is rewritten during A-D conversion, the conversion result is
indeterminate.
Figure 2.12.3 A-D control register 1
Rev. 1.0
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A-D control register 2 (Note)
b7
b6
b5
b4
b3
b2
b1
b0
0 0 0
Symbol
Address
When reset
ADCON2
03D4 16
0000???0 2
Bit symbol
Bit name
A-D conversion method
select bit
SMP
Function
RW
0 : Without sample and hold
1 : With sample and hold
Must always be set to “0”
Reserved bits
Nothing is assigned.
In an attempt to write to these bits, write “0.”
The value, if read, turns out to be “0.”
Note: If the A-D control register is rewritten during A-D conversion, the conversion
result is indeterminate.
Figure 2.12.4 A-D control register 2
A-D register i
Symbol
ADi(i=0 to 5)
b7
b0
Address
When reset
03C4 16, 03C6 16, 03C8 16 Indeterminate
03CA 16, 03CC 16, 03CE 16 Indeterminate
Function
RW
Eight bits of A-D conversion result
Figure 2.12.5 A-D register i (i = 0 to 5)
Rev. 1.0
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2.12.1 One-shot Mode
In one-shot mode, the pin selected using the analog input pin select bit is used for one-shot A-D conversion. Table 2.12.2 shows the specifications of one-shot mode. Figures 2.12.6 and 2.12.7 show the A-D
control register in one-shot mode.
Table 2.12.2 One-shot mode specifications
Item
Function
Specification
The pin selected by the analog input pin select bit is used for one A-D conversion
Start condition
Writing “1” to A-D conversion start flag
Stop condition
• End of A-D conversion
• Writing “0” to A-D conversion start flag
Interrupt request generation timing
End of A-D conversion
Input pin
One of AN0 to AN5, as selected
Reading of result of A-D converter
Read A-D register corresponding to selected pin
Rev. 1.0
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A-D control register 0 (Note)
b7
b6
b5
b4
b3
b2
b1
b0
0 0 0
Symbol
ADCON0
Address
03D616
Bit symbol
CH0
Bit name
b2 b1 b0
A-D operation mode
select bit 0
b4 b3
CH2
MD1
Function
Analog input pin select
bit
CH1
MD0
When reset
00000??? 2
Reserved bit
0 0 0 : Do not set
0 0 1 : Do not set
0 1 0 : AN 0 is selected
0 1 1 : AN 1 is selected
1 0 0 : AN 2 is selected
1 0 1 : AN 3 is selected
1 1 0 : AN 4 is selected
1 1 1 : AN 5 is selected
0 0 : One-shot mode
RW
(Note 2)
(Note 2)
Must always be set to “0”
ADST
A-D conversion start flag
0 : A-D conversion disabled
1 : A-D conversion started
CKS0
Frequency select bit 0
0: fAD/4 is selected
1: fAD/2 is selected
Notes 1: If the A-D control register is rewritten during A-D conversion, the conversion
result is indeterminate.
2: When changing A-D operation mode, it is necessary to set analog input pins
again.
Figure 2.12.6 A-D control register 0 in one-shot mode
A-D control register 1 (Note)
b7
b6
b5
0 0 1
b4
b3
b2
0
0
b1
b0
Symbol
ADCON1
Bit symbol
SCAN0
Address
03D716
When reset
0016
Bit name
Function
A-D sweep pin
select bit
Invalid in one-shot mode
A-D operation mode
select bit 1
0 : Any mode other than repeat sweep
mode 1
RW
SCAN1
MD2
Reserved bit
Must always be set to “0”
CKS1
Frequency select bit1
0 : fAD/2 or fAD/4 is selected
1 : fAD is selected
VCUT
Vref connect bit
1 : Vref connected
Reserved bits
Must always be set to “0”
Note: If the A-D control register is rewritten during A-D conversion, the conversion
result is indeterminate.
Figure 2.12.7 A-D control register 1 in one-shot mode
Rev. 1.0
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2.12.2 Repeat Mode
In repeat mode, the pin selected using the analog input pin select bit is used for repeated A-D conversion.
Table 2.12.3 shows the specifications of repeat mode. Figures 2.12.8 and 2.12.9 show the A-D control
register in repeat mode.
Table 2.12.3 Repeat mode specifications
Item
Specification
Function
Star condition
The pin selected by the analog input pin select bit is used for repeated A-D conversion
Writing “1” to A-D conversion start flag
Stop condition
Writing “0” to A-D conversion start flag
Interrupt request generation timing
None generated
Input pin
One of AN0 to AN5, as selected
Reading of result of A-D converter
Read A-D register corresponding to selected pin
Rev. 1.0
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A-D control register 0 (Note)
b7
b6
b5
b4
b3
b2
b1
b0
0 0 1
Symbol
ADCON0
Bit symbol
CH0
Address
03D6 16
When reset
00000??? 2
Bit name
Function
0 0 0 : Do not set
0 0 1 : Do not set
0 1 0 : AN 0 is selected
0 1 1 : AN 1 is selected
1 0 0 : AN 2 is selected
1 0 1 : AN 3 is selected
1 1 0 : AN 4 is selected
1 1 1 : AN 5 is selected
CH1
CH2
MD0
MD1
RW
b2 b1 b0
Analog input pin
select bit
(Note 2)
b4 b3
A-D operation mode
select bit 0
0 1 : Repeat mode
(Note 2)
Must always be set to “0”
Reserved bit
ADST
A-D conversion start flag
0 : A-D conversion disabled
1 : A-D conversion started
CKS0
Frequency select bit 0
0 : fAD/4 is selected
1 : fAD/2 is selected
Notes 1: If the A-D control register is rewritten during A-D conversion, the conversion
result is indeterminate.
2: When changing A-D operation mode, it is necessary to set analog input pins
again.
Figure 2.12.8 A-D conversion register 0 in repeat mode
A-D control register 1 (Note)
b7
b6
b5
0 0 1
b4
b3
b2
0 0
b1
b0
Symbol
ADCON1
Bit symbol
SCAN0
Address
03D7 16
When reset
00 16
Bit name
Function
A-D sweep pin
select bit
Invalid in repeat mode
A-D operation mode
select bit 1
0 : Any mode other than repeat sweep mode 1
RW
SCAN1
MD2
Reserved bit
Most always be set to “0”
CKS1
Frequency select bit 1
0 : f AD/2 or f AD/4 is selected
1 : f AD is selected
VCUT
Vref connect bit
1 : Vref connected
Reserved bits
Most always be set to “0”
Note: If the A-D control register is rewritten during A-D conversion, the conversion
result is indeterminate.
Figure 2.12.9 A-D conversion register 1 in repeat mode
Rev. 1.0
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2.12.3 Single Sweep Mode
In single sweep mode, the pins selected using the A-D sweep pin select bit are used for one-by-one A-D
conversion. Table 2.12.4 shows the specifications of single sweep mode. Figures 2.12.10 and 2.12.11
show the A-D control register in single sweep mode.
Table 2.12.4 Single sweep mode specifications
Item
Specification
Function
Start condition
The pins selected by the A-D sweep pin select bit are used for one-by-one A-D conversion
Writing “1” to A-D converter start flag
Stop condition
• End of A-D conversion
• Writing “0” to A-D conversion start flag
Interrupt request generation timing
End of A-D conversion
Input pin
AN0 and AN1 (2 pins), AN0 to AN3 (4 pins), AN0 to AN5 (6 pins)
Reading of result of A-D converter
Read A-D register corresponding to selected pin
Rev. 1.0
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A-D control register 0 (Note)
b7
b6
b5
b4
b3
b2
b1
b0
0 1 0
Symbol
ADCON0
Address
03D616
Bit symbol
CH0
When reset
00000??? 2
Bit name
Analog input pin
select bit
Function
RW
Invalid in single sweep mode
CH1
CH2
MD0
A-D operation mode
select bit 0
b4 b3
1 0 : Single sweep mode
MD1
Reserved bit
Must always be set to “0”
ADST
A-D conversion start flag
0 : A-D conversion disabled
1 : A-D conversion started
CKS0
Frequency select bit 0
0 : f AD/4 is selected
1 : f AD/2 is selected
Note: If the A-D control register is rewritten during A-D conversion, the conversion result
is indeterminate.
Figure 2.12.10 A-D control register 0 in single sweep mode
A-D control register 1 (Note 1)
b7
b6
b5
0 0 1
b4
b3
b2
0 0
b1
b0
Symbol
ADCON1
Address
03D7 16
Bit symbol
SCAN0
When reset
00 16
Bit name
A-D sweep pin select bit
Function
R W
When single sweep and repeat sweep mode 0
are selected
b1 b0
0 0 : Do not set
0 1 : AN 0 and AN 1 (2 pins)
1 0 : AN 0 to AN 3 (4 pins)
1 1 : AN 0 to AN 5 (6 pins)
SCAN1
MD2
A-D operation mode
select bit 1
Reserved bit
0 : Any mode other than repeat sweep mode 1
Must always be set to “0”
CKS1
Frequency select bit 1
0 : f AD/2 or f AD/4 is selected
1 : f AD is selected
VCUT
Vref connect bit
1 : Vref connected
Reserved bits
Must always be set to “0”
Note: If the A-D control register is rewritten during A-D conversion, the conversion result
is indeterminate.
Figure 2.12.11 A-D control register 1 in single sweep mode
Rev. 1.0
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2.12.4 Repeat Sweep Mode 0
In repeat sweep mode 0, the pins selected using the A-D sweep pin select bit are used for repeat sweep
A-D conversion. Table 2.12.5 shows the specifications of repeat sweep mode 0. Figures 2.12.12 and
2.12.13 show the A-D control register in repeat sweep mode 0.
Table 2.12.5 Repeat sweep mode 0 specifications
Item
Specification
Function
The pins selected by the A-D sweep pin select bit are used for repeat sweep A-D conversion
Start condition
Writing “1” to A-D conversion start flag
Stop condition
Writing “0” to A-D conversion start flag
Interrupt request generation timing
None generated
Input pin
Reading of result of A-D converter
AN0 and AN1 (2 pins), AN0 to AN3 (4 pins), AN0 to AN5 (6 pins)
Read A-D register corresponding to selected pin (at any time)
Rev. 1.0
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A-D control register 0 (Note)
b7
b6
b5
b4
0
1 1
b3
b2
b1
b0
Symbol
ADCON0
Address
03D6 16
Bit symbol
CH0
When reset
00000??? 2
Bit name
Analog input pin
select bit
Function
RW
Invalid in repeat sweep mode 0
CH1
CH2
MD0
A-D operation mode
select bit 0
b4 b3
1 1 : Repeat sweep mode 0
MD1
Reserved bit
Must always be set to “0”
ADST
A-D conversion start flag
0 : A-D conversion disabled
1 : A-D conversion started
CKS0
Frequency select bit 0
0 : fAD/4 is selected
1 : fAD/2 is selected
Note: If the A-D control register is rewritten during A-D conversion, the conversion result
is indeterminate.
Figure 2.12.12 A-D control register 0 in repeat sweep mode 0
A-D control register 1 (Note)
b7
b6
b5
0 0 1
b4
b3
b2
0
0
b1
b0
Symbol
ADCON1
Address
03D7 16
Bit symbol
SCAN0
When reset
0016
Bit name
A-D sweep pin select bit
Function
R W
When single sweep and repeat sweep mode 0
are selected
b1 b0
0 0 : Do not set
0 1 : AN 0 and AN 1 (2 pins)
1 0 : AN 0 to AN 3 (4 pins)
1 1 : AN 0 to AN 5 (6 pins)
SCAN1
MD2
A-D operation mode
select bit 1
Reserved bit
0 : Any mode other than repeat sweep mode 1
Must always be set to “0”
CKS1
Frequency select bit 1
0 : f AD/2 or f AD/4 is selected
1 : f AD is selected
VCUT
Vref connect bit
1 : Vref connected
Reserved bits
Must always be set to “0”
Note: If the A-D control register is rewritten during A-D conversion, the conversion result
is indeterminate.
Figure 2.12.13 A-D control register 1 in repeat sweep mode 0
Rev. 1.0
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2.12.5 Repeat Sweep Mode 1
In repeat sweep mode 1, all pins are used for A-D conversion with emphasis on the pin or pins selected
using the A-D sweep pin select bit. Table 2.12.6 shows the specifications of repeat sweep mode 1.
Figures 2.12.14 and 2.12.15 show the A-D control register in repeat sweep mode 1.
Table 2.12.6 Repeat sweep mode 1 specifications
Item
Specification
Function
All pins perform repeat sweep A-D conversion, with emphasis on the pin or
pins selected by the A-D sweep pin select bit
Example : AN0 selected
AN0
AN1
AN0
AN2
AN0
Start condition
Writing “1” to A-D conversion start flag
Stop condition
Writing “0” to A-D conversion start flag
Interrupt request generation timing
None generated
Input pin
Reading of result of A-D converter
AN0 (1 pin), AN0 and AN1 (2 pins)
Read A-D register corresponding to selected pin (at any time)
AN3, etc
A-D control register 0 (Note)
b7
b6
b5
b4
b3
0 1 1
b2
b1
b0
Symbol
ADCON0
Bit symbol
CH0
Address
03D616
When reset
00000??? 2
Bit name
Function
Analog input pin
select bit
Invalid in repeat sweep mode 1
A-D operation mode
select bit 0
1 1 : Repeat sweep mode 1
RW
CH1
CH2
MD0
b4 b3
MD1
Reserved bit
Must always be set to “0”
ADST
A-D conversion start flag
0 : A-D conversion disabled
1 : A-D conversion started
CKS0
Frequency select bit 0
0 : f AD/4 is selected
1 : f AD/2 is selected
Note: If the A-D control register is rewritten during A-D conversion, the conversion result
is indeterminate.
Figure 2.12.14 A-D control register 0 in repeat sweep mode 1
Rev. 1.0
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A-D control register 1 (Note)
b7
b6
b5
0 0 1
b4
b3
b2
0 1
b1
b0
Symbol
ADCON1
Address
03D7 16
Bit symbol
Bit name
SCAN0
A-D sweep pin select bit
When reset
00 16
Function
RW
When repeat sweep mode 1 is selected
b1 b0
0 0 : Do not set
0 1 : Do not set
1 0 : AN 0 (1 pin)
1 1 : AN 0 and AN 1 (2 pins)
SCAN1
MD2
A-D operation mode
select bit 1
Reserved bit
1 : Repeat sweep mode 1
Must always be set to “0”
CKS1
Frequency select bit 1
0 : fAD/2 or f AD/4 is selected
1 : fAD is selected
VCUT
Vref connect bit
1 : Vref connected
Reserved bits
Must always be set to “0”
Note : If the A-D control register is rewritten during A-D conversion, the conversion result
is indeterminate.
Figure 2.12.15 A-D control register 1 in repeat sweep mode 1
Rev. 1.0
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2.12.6 Sample and Hold
Sample and hold is selected by setting bit 0 of the A-D control register 2 (address 03D416) to “1”. When
sample and hold is selected, the rate of conversion of each pin increases. As a result, a 28 φAD cycle is
achieved. Sample and hold can be selected in all modes. However, in all modes, be sure to specify before
starting A-D conversion whether sample and hold is to be used.
Rev. 1.0
152
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2.13 D-A Converter
This is an 8-bit, R-2R type D-A converter. The microcomputer contains two independent D-A converters of
this type.
D-A conversion is performed when a value is written to the corresponding D-A register. Bits 0 and 1 (D-A
output enable bits) of the D-A control register decide if the result of conversion is to be output. Do not set the
target port to output mode if D-A conversion is to be performed.
Output analog voltage (V) is determined by a set value (n : decimal) in the D-A register.
V = VREF X n/ 256 (n = 0 to 255)
VREF : reference voltage
Table 2.13.1 lists the performance of the D-A converter. Figure 2.13.1 shows the block diagram of the D-A
converter. Figure 2.13.2 shows the A-D control register, Figure 2.13.3 shows the D-A register and Figure
2.13.4 shows the D-A converter equivalent circuit.
Table 2.13.1 Performance of D-A converter
Item
Conversion method
Performance
R-2R method
Resolution
8 bits
Analog output pin
2 channels
Data bus low-order bits
D-A register0 (8)
(Address 03D816)
D-A0 output enable bit
R-2R resistor ladder
D-A register1 (8)
P93/DA0
(Address 03DA16)
D-A1 output enable bit
R-2R resistor ladder
P94/DA1
Figure 2.13.1 Block diagram of D-A converter
Rev. 1.0
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D-A control register
b7
b6
b5
b4
b3
b2
b1
Symbol
DACON
b0
Address
03DC 16
Bit symbol
When reset
00 16
Bit name
Function
DA0E
D-A0 output enable bit
0 : Output disabled
1 : Output enabled
DA1E
D-A1 output enable bit
0 : Output disabled
1 : Output enabled
RW
Nothing is assigned.
In an attempt to write to these bits, write “0.” The value, if read, turns out to be “0.”
Figure 2.13.2 D-A control register
D-A register i (i = 0, 1)
b7
Symbol
DAi (i = 0,1)
b0
Address
03D8 16, 03DA 16
When reset
Indeterminate
Function
R
RW
W
Output value of D-A conversion
Figure 2.13.3 D-A register i (i = 0 and 1)
D-A0 output enable bit
"0"
R
R
R
R
2R
2R
2R
2R
R
R
R
2R
DA0
"1"
2R
MSB
2R
2R
2R
LSB
D-A0 register0
VSS
VCC(VREF)
Note 1: The above diagram shows an instance in which the D-A register is assigned 2A16.
2: The same circuit as this is also used for D-A1.
3: To reduce the current consumption when the D-A converter is not used, set the D-A output enable bit to 0 and set the D-A register to
0016 so that no current flows in the resistors Rs and 2Rs.
Figure 2.13.4 D-A converter equivalent circuit
Rev. 1.0
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2.14 Data Slicer
This microcomputer includes the data slicer function for the closed caption decoder (referred to as the
CCD). This function takes out the caption data superimposed in the vertical blanking interval of a composite
video signal. A composite video signal which makes the sync.tip’s polarity negative is input to the CVIN pin.
When the data slicer function is not used, the data slicer circuit and the timing signal generating circuit can
be cut off by setting bit 0 of the data slicer control register 1 (address 026016) to “0.” These settings can
realize the low-power dissipation.
Note: When using the data slicer, set bit 7 of the peripheral mode register (address 027D16) according to
the main clock frequency.
0.1 µF
Composite
video
signal
470 Ω
1 kΩ
560 pF
1 MΩ
CVIN
1 µF
200 pF
HSYNC
HLF
Synchronizing
signal counter
Data slicer control register 2
(address 026116)
Clamping
circuit
Low-pass
filter
Sync slice
circuit
Synchronizing
separation
circuit
Data slicer control register 1
(address 026016)
Timing signal
generating
circuit
Data slicer ON/OFF
VHOLD
Reference
voltage
generating
1000 pF circuit
+
–
Clock run-in
determination
circuit
Comparator
Data slice line
specification
circuit
Start bit detecting
circuit
Clock run-in detect
register
(address 026916)
Caption position register
(address 026616)
External circuit
Note : Make the length of wiring which is connected
to VHOLD, HLF, and CVIN pin as short as
possible so that a leakage current may not
be generated when mounting a resistor or a
capacitor on each pin.
Data clock
generating circuit
Data clock position register
(address 026A16)
16-bit shift register
Interrupt request
generating circuit
Data slicer
interrupt
request
Caption data register 1
(addresses 026316, 026216)
Caption data register 2
(addresses 026516, 026416)
Data bus
Figure 2.14.1 Data slicer block diagram
Rev. 1.1
1.0
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2.14.1 Notes when not Using Data Slicer
When bit 0 of data slicer control register 1 (address 0260 16) is “0,” terminate the pins as shown in
Figure 2.14.2
<When data slicer circuit and timing signal generating circuit is in OFF state>
Apply the same voltage as VCC to
AVCC pin.
99
Leave HLF pin open.
Open
Open
Leave VHOLD pin open.
2
HLF
1
VHOLD
5 kΩ or more
Pull-up CVIN pin to Vcc through
a resistor of 5 kΩ or more.
AVCC
100
CVIN
Figure 2.14.2 Termination of data slicer input/output pins when data slicer circuit and timing
generating circuit is in OFF state
When both bits 0 and 2 of data slicer control register 1 (address 026016) are “1,” terminate the pins as shown
in Figure 2.14.3.
<When using a reference clock generated in timing signal generating circuit as OSD clock>
Apply the same voltage as VCC to AVCC pin.
99
AVCC
1 kΩ
Connect the same external circuit as when
using data slicer to HLF pin.
Leave VHOLD pin open.
Pull-up CVIN to VCC through a resistor
of 5 kΩ or more.
1µF
2
HLF
1
VHOLD
200pF
Open
5 kΩ or more
100
CVIN
Figure 2.14.3 Termination of data slicer input/output pins when timing signal generating circuit is
in ON state
Rev. 1.0
156
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Figures 2.14.4 and 2.14.5 the data slicer control registers.
Data slicer control register 1
b7 b6 b5 b4 b3 b2 b1 b0
0 0 0 0 0
Symbol
Address
When reset
DSC1
026016
0016
Bit symbol
Bit name
Data slicer and timing signal
generating circuit control bit
Selection bit of data slice reference
voltage generating field
Reference clock source
selection bit
DSC10
DSC11
DSC12
Reserved bits
Function
0: Stopped
1: Operating
0: F2
1: F1
0: Video signal
1: HSYNC signal
R W
Must always be set to “0”
Definition of fields 1 (F1) and 2 (F2)
F1: Hsep
Vsep
F2: Hsep
Vsep
Figure 2.14.4 Data slicer control register 1
Data slicer control register 2
b7 b6 b5 b4 b3 b2 b1 b0
0
0
Symbol
DSC2
Address
026116
Function
Bit name
Bit symbol
Caption data latch
completion flag 1
DSC20
When reset
?0?0??0?2
Reserved bit
Must always be set to “0”
Test bit
Read-only
DSC23
DSC24
DSC25
R W
0: Data is not latched yet and a
clock-run-in is not determined.
1: Data is latched and a
clock-run-in is determined.
Field determination flag
0: F2
1: F1
Vertical synchronous signal
(Vsep) generating method
selection bit
0: Method (1)
1: Method (2)
V-pulse shape
determination flag
0: Match
1: Mismatch
Reserved bit
Must always be set to “0”
Test bit
Read-only
Definition of fields 1 (F1) and 2 (F2)
F1: Hsep
Vsep
F2: Hsep
Vsep
Figure 2.14.5 Data slicer control register 2
Rev. 1.0
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2.14.2 Clamping Circuit and Low-pass Filter
The clamp circuit clamps the sync.tip part of the composite video signal input from the CVIN pin. The lowpass filter attenuates the noise of clamped composite video signal. The CVIN pin to which composite video
signal is input requires a capacitor (0.1 µF) coupling outside. Pull down the CVIN pin with a resistor of
hundreds of kiloohms to 1 MΩ. In addition, we recommend to install externally a simple low-pass filter
using a resistor and a capacitor at the CVIN pin (refer to Figure 2.14.1).
2.14.3 Sync Slice Circuit
This circuit takes out a composite sync signal from the output signal of the low-pass filter.
2.14.4 Synchronous Signal Separation Circuit
This circuit separates a horizontal synchronous signal and a vertical synchronous signal from the composite sync signal taken out in the sync slice circuit.
(1) Horizontal synchronous signal (Hsep)
A one-shot horizontal synchronizing signal Hsep is generated at the falling edge of the composite sync
signal.
(2) Vertical synchronous signal (Vsep)
As a Vsep signal generating method, it is possible to select one of the following 2 methods by using bit
4 of the data slicer control register 2 (address 026116).
•Method 1 The “L” level width of the composite sync signal is measured. If this width exceeds a
certain time, a Vsep signal is generated in synchronization with the rising of the timing
signal immediately after this “L” level.
•Method 2 The “L” level width of the composite sync signal is measured. If this width exceeds a
certain time, it is detected whether a falling of the composite sync signal exits or not in the
“L” level period of the timing signal immediately after this “L” level. If a falling exists, a Vsep
signal is generated in synchronization with the rising of the timing signal (refer to Figure
2.14.6).
Figure 2.14.6 shows a Vsep generating timing. The timing signal shown in the figure is generated from the
reference clock which the timing generating circuit outputs.
Reading bit 5 of data slicer control register 2 permits determinating the shape of the V-pulse portion of the
composite sync signal. As shown in Figure 2.14.7, when the A level matches the B level, this bit is “0.” In
the case of a mismatch, the bit is “1.”
Composite s
Measure “L” period
Timing
signal
Vsep signal
A Vsep signal is generated at a rising of the timing signal
immediately after the “L” level width of the composite
sync signal exceeds a certain time.
Figure 2.14.6 Vsep generating timing (method 2)
Rev. 1.1
1.0
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2.14.5 Timing Signal Generating Circuit
This circuit generates a reference clock which is 832 times as large as the horizontal synchronous signal
frequency. It also generates various timing signals on the basis of the reference clock, horizontal synchronous signal and vertical synchronizing signal. The circuit operates by setting bit 0 of data slicer
control register 1 (address 026016) to “1.”
The reference clock can be used as a display clock for OSD function in addition to the data slicer. The
HSYNC signal can be used as a count source instead of the composite sync signal. However, when the
HSYNC signal is selected, the data slicer cannot be used. A count source of the reference clock can be
selected by bit 2 of data slicer control register 1 (address 026016).
For the pins HLF, connect a resistor and a capacitor as shown in Figure 2.14.1 Make the length of wiring
which is connected to these pins as short as possible so that a leakage current may not be generated.
Note: It takes a few tens of milliseconds until the reference clock becomes stable after the data slicer and
the timing signal generating circuit are started. In this period, various timing signals, Hsep signals
and Vsep signals become unstable. For this reason, take stabilization time into consideration
when programming.
Bit 5 of DSC2
0
Composite
sync signal
1
1
A
B
Figure 2.14.7 Determination of v-pulse waveform
Rev. 1.0
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M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
2.14.6 Data Slice Line Specification Circuit
(1) Specification of data slice line
This circuit decides a line on which caption data is superimposed. The line 21 (fixed), 1 appropriate
line for a period of 1 field (total 2 line for a period of 1 field), and both fields (F1 and F2) are sliced their
data. The caption position register (address 026616) is used for each setting (refer to Table 2.14.1).
The counter is reset at the falling edge of Vsep and is incremented by 1 every Hsep pulse. When the
counter value matched the value specified by bits 4 to 0 of the caption position register, this Hsep is
sliced.
The values of “0016” to “1F16” can be set in the caption position register (at setting only 1 appropriate
line). Figure 2.14.8 shows the signals in the vertical blanking interval. Figure 2.14.9 shows the caption
position register.
(2) Specification of line to set slice voltage
The reference voltage for slicing (slice voltage) is generated for the clock run-in pulse in the particular
line (refer to Table 2.14.1). The field to generate slice voltage is specified by bit 1 of data slicer control
register 1. The line to generate slice voltage 1 field is specified by bits 6, 7 of the caption position
register (refer to Table 2.14.1).
(3) Field determination
The field determination flag can be read out by bit 3 of data slicer control register 2. This flag change
at the falling edge of Vsep.
Vertical blanking interval
Video signal
Composite video
signal
1 appropriate line is set by
the caption position register
Line 21
(when setting line 19)
Vsep
Hsep
Count value to be set in the caption position register (“0F16” in this case)
Magnified drawing
Hsep
Clock run-in
Composite video
signal
Start bit + 16-bit data
Start bit
Window for
deteminating
clock-run-in
Figure 2.14.8 Signals in vertical blanking interval
Rev. 1.0
160
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
Caption position register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
CPS
Address
026616
Bit symbol
CPS0
Bit name
When reset
00?000002
Function
R W
Caption position bits
CPS1
CPS2
CPS3
CPS4
CPS5
Caption data latch
completion flag 2
0: Data is not latched yet and a
clock-run-in is not determined.
1: Data is latched and a
clock-run-in is determined.
CPS6
Slice line mode
specification bits
(in 1 field)
Refer to the corresponding table
(Table 2.14.1).
CPS7
Figure 2.14.9 Caption position register
Table 2.14.1 Specification of data slice line
CPS
Field and Line to Be Sliced Data
Field and Line to Generate Slice Voltage
b7
b6
0
0
• Both fields of F1 and F2
• Line 21 and a line specified by bits 4 to 0 of CPS
(total 2 lines) (See note 2)
• Field specified by bit 1 of DSC1
• Line 21 (total 1 line)
0
1
• Both fields of F1 and F2
• A line specified by bits 4 to 0 of CPS
(total 1 line) (See note 3)
• Field specified by bit 1 of DSC1
• A line specified by bits 4 to 0 of CPS
(total 1 line) (See note 3)
1
0
• Both fields of F1 and F2
• Line 21 (total 1 line)
• Field specified by bit 1 of DSC1
• Line 21 (total 1 line)
1
1
• Both fields of F1 and F2
• Line 21 and a line specified by bits 4 to 0 of CPS
(total 2 lines) (See note 2)
• Field specified by bit 1 of DSC1
• Line 21 and a line specified by bits 4 to 0 of CPS
(total 2 lines) (See note 2)
Notes 1: DSC is data slicer control register 1.
CPS is caption position register.
2: Set “0016” to “1016” to bits 4 to 0 of CPS.
3: Set “0016” to “1F16” to bits 4 to 0 of CPS.
Rev. 1.0
161
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
2.14.7 Reference Voltage Generating Circuit and Comparator
The composite video signal clamped by the clamping circuit is input to the reference voltage generating
circuit and the comparator.
(1) Reference voltage generating circuit
This circuit generates a reference voltage (slice voltage) by using the amplitude of the clock run-in
pulse in line specified by the data slice line specification circuit. Connect a capacitor between the
VHOLD pin and the VSS pin, and make the length of wiring as short as possible so that a leakage
current may not be generated.
(2) Comparator
The comparator compares the voltage of the composite video signal with the voltage (reference voltage) generated in the reference voltage generating circuit, and converts the composite video signal
into a digital value.
2.14.8 Start Bit Detecting Circuit
This circuit detects a start bit at line decided in the data slice line specification circuit.
The detection of a start bit is described below.
➀ A sampling clock is generated by dividing the reference clock output by the timing signal.
➁ A clock run-in pulse is detected by the sampling clock.
➂ After detection of the pulse, a start bit pattern is detected from the comparator output.
2.14.9 Clock Run-in Determination Circuit
This circuit determinates clock run-in by counting the number of pulses in a window of the composite
video signal.
The reference clock count value in one pulse cycle is stored in bits 3 to 7 of the clock run-in detect register
(address 026916). Read out these bits after the occurrence of a data slicer interrupt (refer to 2.14.12
Interrupt request generating circuit).
Figure 2.14.10 shows the structure of clock run-in detect register.
Clock run-in detect register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
CRD
Address
026916
Bit name
Bit symbol
Test bits
CRD3
When reset
0016
Function
R W
Read-only
Clock run-in detection bits
CRD4
CRD5
Number of reference clocks to
be counted in one clock run-in
pulse period.
CRD6
CRD7
Figure 2.14.10 Clock run-in detect register
Rev. 1.0
162
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
2.14.10 Data Clock Generating Circuit
This circuit generates a data clock synchronized with the start bit detected in the start bit detecting circuit.
The data clock stores caption data to the 16-bit shift register. When the 16-bit data has been stored and
the clock run-in determination circuit determines clock run-in, the caption data latch completion flag is set.
This flag is reset at a falling of the vertical synchronous signal (Vsep).
Data clock position register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
DPS
Address
026A16
Bit name
Bit symbol
DPS0
DPS1
DPS2
DPS3
DPS4
When reset
XXX000012
Function
R
W
Data clock position
set bits
Nothing is assigned.
If an attempt to write to these bits, write “0.” The read turns out to be “0.”
Figure 2.14.11 Data clock position register
2.14.11 16-bit Shift Register
The caption data converted into a digital value by the comparator is stored into the 16-bit shift register in
synchronization with the data clock. The contents of the stored caption data can be obtained by reading
out the caption data register 1 (addresses 026316, 026216) and caption data register 2 (addresses
026516, 026416). These registers are reset to “0” at a falling of Vsep. Read out data registers 1 and 2 after
the occurrence of a data slicer interrupt (refer to “2.14.12 Interrupt request generating circuit)”.
Rev. 1.0
163
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
2.14.12 Interrupt Request Generating Circuit
The interrupt requests as shown in Table 2.14.3 are generated by combination of the following bits; bits 6
and 7 of the caption position register (address 026616). Read out the contents of data registers 1, 2 and
the contents of bits 3 to 7 of the clock run-in detect register after the occurrence of a data slicer interrupt
request.
Table 2.14.2 Contents of caption data latch completion flag and 16-bit shift register
Slice Line Specification Mode
CPS
Contents of 16-bit Shift Register
ContentsofCaptionDataLatchCompletionFlag
bit 7
bit 6
Completion Flag 1
(bit 0 of DSC2)
Completion Flag 2
(bit 5 of CPS)
Caption Data
Register 1
Caption Data
Register 2
0
0
Line 21
A line specified by
bits 4 to 0 of CPS
16-bit data of line 21
16-bit data of a line specified
by bits 4 to 0 of CPS
0
1
A line specified by
bits 4 to 0 of CPS
Invalid
16-bit data of a line specified
by bits 4 to 0 of CPS
Invalid
1
0
Line 21
Invalid
16-bit data of line 21
Invalid
1
1
Line 21
A line specified by
bits 4 to 0 of CPS
16-bit data of line 21
16-bit data of a line specified
by bits 4 to 0 of CPS
CPS: Caption position register
DSC2: Data slicer control register 2
Table 2.14.3 Occurrence sources of Interrupt request
CPS
b7
Occurrence Sources of Interrupt Request at End of Data Slice Line
b6
0
1
0
After slicing line 21
1
After a line specified by bits 4 to 0 of CPS
0
After slicing line 21
1
After slicing line 21
CPS: Caption position register
Data slicer reserved register i (i =1, 2)
b7
b6
0
0 0 0 0
b5
b4
b3
b2
b1
0 0
b0
0
Symbol
Address
When reset
DR1
DR2
026816
026716
0016
0016
Bit symbol
Bit name
Reserved bits
Description
R
W
Mest always be set to “0”
Figure 2.14.12 Data slicer reserved register i (i = 1, 2)
Rev. 1.0
164
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
2.15 HSYNC Counter
The synchronous signal counter counts HSYNC from HSYNC count input pins (HC0/P75, HC1/P77) as a
count source.
The count value in a certain time (T time; 1024 µs, 2048 µs, 4096 µs and 8192 µs) divided system clock f 32
is stored into the 8-bit latch.
Accordingly, the latch value changes in the cycle of T time. When the count value exceeds “FF16,” “FF16”
is stored into the latch.
The latch value can be obtained by reading out the HSYNC counter latch (address 027F16). A count source
and count update cycle (T time) are selected by bits 0, 3 and 4 of the HSYNC counter register.
Figure 2.15.1 shows the HSYNC counter and Figure 2.15.2 shows the synchronous signal counter block
diagram.
Note: When using the HSYNC counter, set the port direction register corresponding to the HSYNC count
input pins for input.
HSYNC counter register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
HC
Address
027E16
Bit symbol
Bit name
When reset
XXX00X0016
R
Function
HCC0
Count source switch bit
0 : HC0/P34 pin input
1 : HC1/P35 pin input
HCC1
Input polarity
switch bit
0:
1:
W
(Falling edge count)
(Rising edge count)
Nothing is assigned. In an attempt to write to this bit, write “0.”
The value, if read, turns out to be “0.”
HCC3
Count freguency
selection bits
HCC4
b4 b3 <Count freguency>
0 0 : 1024 µs
0 1 : 2048 µs
1 0 : 4096 µs
1 1 : 8192 µs
Nothing is assigned. In an attempt to write to these bits, write “0.”
The value, if read, turns out to be “0.”
Note: When HC0 and HC1 input are positive polarity (negetive polarity),
HIGH width (LOW width) needs 3 main clock cycles or more of system clock.
Figure 2.15.1 HSYNC counter register
1024 µs
System clock f32
2048 µs
Freguency divider
4096 µs
HCC3, HCC4
8192 µs
HC0/P34
HCC1
HC1/P35
Polarity switch
Reset
8-bit counter
Counter
Latch (8 bits)
HSYNC
counter latch
HCC0
Selection gate : connected to black
side when reset.
Data bus
Figure 2.15.2 HSYNC counter block diagram
Rev. 1.0
165
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
2.16 OSD Functions
Table 2.16.1 outlines the OSD functions of this microcomputer. This OSD function can display the following: the block display (32 characters ✕ 16 lines or 42 characters ✕ 16 lines) and the SPRITE display, and
can display the both display at the same time. There are 3 display modes and they are selected by a block
unit. The display modes are selected by block control register i (i = 1 to 16). The features of each display are
described below.
Note: When using OSD function, select “No-division mode” as BCLK operating mode and set the main
clock frequency to f(XIN) = 10 MHz.
Table 2.16.1 Features of each display style
Display style
Parameter
Block display
CC mode
(Closed caption mode)
OSD mode
(On-screen display mode)
OSDS mode
Number of display characters
16 ✕ 20 dots
16 ✕ 20 dots
12 ✕ 20 dots
8 ✕ 20 dots
4 ✕ 20 dots
(Character display area:
16 ✕ 26 dots)
OSDL
enable mode
OSDL
disable mode
Kinds of character sizes
(See note 1) Pre-divide
ratio (Note)
Dot size
OSDL mode
32 characters ✕ 16 lines/42 characters ✕ 16 lines
Dot structure
Kinds of
character
ROM
OSDP mode
254 kinds
254 kinds
14 kinds
4 kinds
16 ✕ 26 dots
32 ✕ 20 dots
254 kinds
126 kinds
2 kinds of RAM font
12 kinds
14 kinds
✕ 1, ✕ 2, ✕ 3
Attribute
Smooth italic,
under line, flash
Border
Character font
coloring
1 screen: 8 kinds
(a character unit)
1 screen: 16 kinds
(a character unit)
1TC ✕ 1/2H,
1TC ✕ 1H,
2TC ✕ 2H,
3TC ✕ 3H
Max. 512 kinds
Max. 512 kinds
1TC ✕ 1/2H,
1TC ✕ 1H,
1.5TC ✕ 1/2H,
1.5TC ✕ 1H,
2TC ✕ 2H,
3TC ✕ 3H
Possible
Possible
(a character unit, 1 screen: 4 (a character unit,1 screen: 16 kinds,
kinds, Max. 512 kinds)
Max. 512 kinds)
Display layer
Layer 1
Layers 1, 2
Layer 1
Layers 1, 2
Analog R, G, B output (each 8 adjustment levels: 512 colors), Digital OUT1, OUT2 output
Raster coloring
8 kinds
✕ 1, ✕ 2
1TC ✕ 1/2H,
1TC ✕ 1H,
2TC ✕ 2H,
3TC ✕ 3H
1 screen: 16 kinds (a dot unit)
1 screen: 16 kinds
(only specified dots are colored (a dot unit)
by a character unit)
Max. 512 kinds
Max. 512 kinds
Character
background
coloring
Display expansion
(multiline display)
1 character ✕ 2 lines
24 ✕ 32 dots
✕ 1, ✕ 2
1TC ✕ 1/2H,
1TC ✕ 1H,
1.5TC ✕ 1/2H,
1.5TC ✕ 1H,
2TC ✕ 2H,
3TC ✕ 3H
Other function
(See note 3)
SPRITE display
508 kinds
1TC ✕ 1/2H,
1TC ✕ 1H
OSD output (See note 2)
CDOSD mode
(Color dot on-screen
display mode)
Layer 3 (with highest priority)
Possible (a screen unit, max 512 kinds)
Auto solid space function
Triple layer OSD function, window function, blank function
Possible
Notes 1: The character size is specified with dot size and pre-divide ratio (refer to “2.16.3 Dot Size”).
2: As for SPRITE display, OUT2 is not output.
3: As for SPRITE display, the window function does not operate.
4: The divide ratio of the frequency divider (the pre-divide circuit) is referred as “pre-divide ratio” hereafter.
Rev. 1.0
166
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
The OSD circuit has an extended display mode. This mode allows multiple lines (16 lines or more) to be
displayed on the screen by interrupting the display each time one line is displayed and rewriting data in the
block for which display is terminated by software.
Figure 2.16.1 shows the display-enable fonts for each display style. Figure 2.16.2 shows the block diagram
of the OSD circuit. Figure 2.16.3 shows the OSD control register 1. Figure 2.16.4 shows the block control
register i.
Rev. 1.0
167
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
Display Styles
Display-enable Fonts
16 dots
← Blank area
26 dots
CC Mode
← Underline area
← Blank area
16 dots
20 dots
OSDS Mode
20 dots
20 dots
8 dots
*
**
4 dots
**
20 dots
12 dots
20 dots
16 dots
OSDP Mode
* : Only character
codes
**: Blank font
24 dots
32 dots
OSDL Mode
26 dots
CDOSD Mode
32 dots
20 dots
SPRITE
Figure 2.16.1 Display-enable fonts for each display style
Rev. 1.0
168
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
Clock for OSD
OSC1 OSC2
Data slicer clock
HSYNC VSYNC
Display
oscillation
circuit
OSD control circuit
OSD RAM (SPRITE)
32 dots ✕ 20 dots ✕ 4 planes ✕ 2 lines
Control register for OSD
SPRITE OSD control register
OSD control register 1
OSD control register 2
Horizontal position register
Clock control register
I/O polarity control register
OSD control register 3
Raster color register
Top border control register
Bottom border control register
Block control register i
Vertical position register i
Color palette register i
OSD reserved register i
(address 020116)
(address 020216)
(address 020316)
(address 020416)
(address 020516)
(address 020616)
(address 020716)
(addresses 020916, 020816)
(addresses 020D16, 020C16)
(addresses 020F16, 020E16)
(addresses 021016 to 021F16)
(addresses 022016 to 023F16)
(addresses 024016 to 025B16)
(addresses 025D16 to 027A16,
027B16 to 027C16)
(address 025F16)
(addresses 027116, 027016)
(addresses 027316, 027216)
(addresses 027416 to 027716)
(addresses 027916, 027816)
OSD control register 4
Left border control register
Right border control register
SPRITE vertical position register i
SPRITE horizontal position register
Shift register
OSD RAM (See note 1)
19 bits ✕ 32 characters ✕ 16 lines
OSD ROM (character font) (See note 2)
16 dots ✕ 20 dots ✕ 254 characters
24 dots ✕ 32 dots ✕ 254 characters
Shift register
Output circuit
Shift register
R
G
B
OUT1
OUT2
OSD ROM (color dot font)
16 dots ✕ 26 dots ✕ 4 planes ✕
94 characters
Shift register
Notes 1: In 42 character-mode, 19 bits ✕ 42 characters ✕ 16 lines
2: In OSDL disable mode, 16 dots ✕ 20 dots ✕ 762 characters.
Data bus
Figure 2.16.2 Block diagram of OSD circuit
Rev. 1.0
169
MITSUBISHI MICROCOMPUTERS
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
OSD control register 1
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
OC1
Bit symbol
OC10
OC11
OC12
OC13
Address
020216
Bit name
OSD control bit
(See note 1)
Scan mode
selection bit
Border type
selection bit
Flash mode
selection bit
When reset
0016
Function
0 : All bordered
1 : Shadow bordered (See note 2)
0 : Color signal of character background
part does not flash
1 : Color signal of character background
part flashes
OC14
Automatic solid
space control bit
0 : OFF
1 : ON
OC15
Vertical window/blank
control bit
0 : OFF
1 : ON
OC16
OC17
Layer mixing
control bits
(See note 3)
R W
0 : All-blocks and SPRITE display OFF
1 : All-blocks and SPRITE display ON
0 : Normal scan mode
1 : Bi-scan mode
b7 b6
0 0: Logic sum (OR) of layer 1’s
color and layer 2’s color
0 1: Layer 1’s color has priority
1 0: Layer 2’s color has priority
1 1: Do not set.
Notes 1 : Even this bit is switched during display, the display screen
remains unchanged until a rising (falling) of the next VSYNC.
2 : Shadow border is output at right and bottom side of the font.
3 : OUT2 is always ORed, regardless of values of these bits.
Figure 2.16.3 OSD control register 1
Rev. 1.0
170
MITSUBISHI MICROCOMPUTERS
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
Block control register i
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
BCi (i = 1 to 16)
Bit symbol
BCi_0
Address
021016 to 021F16
Bit name
Function
Display mode
selection bits
b0 b1
Dot size
selection bits
b6
BCi_1
BCi_2
BCi_3
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
Pre-divide ratio
selection bits
BCi_6
b0
0
1
0
1
0
1
0
1
b5 b4
R
W
Functions
Display OFF
OSDS mode (No bordered)
CC mode
CDOSD mode
OSDP mode (No bordered)
OSDS mode (Bordered)
OSDP mode (Bordered)
OSDL mode
b3 Pre-divide
Dot size
ratio
0
0
0
1
1
1
1
1
BCi_4
BCi_5
When reset
Indeterminate
0
0
1
1
0
0
1
1
0
0
0
0
1
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
✕ 1
✕ 2
✕3
1Tc ✕ 1/2H
1Tc ✕ 1H
2Tc ✕ 2H
3Tc ✕ 3H
1Tc ✕ 1/2H
1Tc ✕ 1H
2Tc ✕ 2H
3Tc ✕ 3H
1.5Tc ✕ 1/2H (See notes 3, 4)
1.5Tc ✕ 1H (See notes 3, 4)
1Tc ✕ 1/2H
1Tc ✕ 1H
2Tc ✕ 2H
3Tc ✕ 3H
Nothing is assigned. In an attempt to write to this bit, write “0.”
The value, if read, turns out to be indeterminate.
Notes 1: Tc is OSD clock cycle divided in pre-divide circuit
2: H is HSYNC
3: This character size is available only in Layer 2. At this time, set layer 1’s
pre-divide ratio = ✕ 2, layer 1’s horizontal dot size = 1Tc.
4: In OSDL and OSDP modes, 1.5Tc size cannot be used.
Figure 2.16.4 Block control register i (i = 0 to 16)
Rev. 1.0
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
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2.16.1 Triple Layer OSD
Three built-in layers of display screens accommodate triple display of channels, volume, etc., closed
caption, and sprite displays within layers 1 to 3.
The layer to be displayed in each block is selected by bit 0 or 1 of the OSD control register 2 for each
display mode (refer to Figure 2.16.7). Layer 3 always displays the sprite display.
When the layer 1 block and the layer 2 block overlay, the screen is composed with layer mixing by bit
6 or 7 of the OSD control register 1, as shown in Figure 2.16.5. Layer 3 always takes display priority of
layers 1 and 2.
Notes 1: When mixing layer 1 and layer 2, note Table 2.16.2.
2: OSDP mode is always displayed on layer 1. And also, it cannot be overlapped with layer 2’s block.
3: OUT2 is always ORed, regardless of values of bits 6, 7 of the OSD control register 1. And
besides, even when OUT2 (layer 1 and layer 2) overlaps with SPRITE display (layer 3),
OUT2 is output without masking.
Table 2.16.2 Mixing layer 1 and layer 2
Block
Block in Layer 1
Parameter
Display mode
Block in Layer 2
CC, OSDS/L, CDOSD mode
OSDS/L, CDOSD mode
✕ 1, ✕ 2 (CC mode)
Same as layer 1 (See note)
Pre-divide ratio
✕ 1 to ✕ 3 (OSD, CDOSD mode)
Dot size
1TC ✕ 1/2H, 1TC ✕ 1H
Pre-divide ratio = ✕ 1
Pre-divide ratio = ✕ 2
(CC mode)
1TC ✕ 1/2H
1TC ✕ 1/2H, 1.5TC ✕ 1/2H
1TC ✕ 1H
1TC ✕ 1H, 1.5TC ✕ 1H (See note)
1TC ✕ 1H, 1TC ✕ 1/2H, 2TC ✕ 2H, • Same size as layer 1
3TC ✕ 3H
(OSDS/L, CDOSD mode)
•1.5TC can be selected only when: layer 1’s pre-divide ratio =
✕ 2 AND layer 1’s horizontal dot size = 1TC.
As this time, vertical dot size is the same as layer 1.
Arbitrary
Horizontal display start position
Same position as layer 1
Arbitrary
Vertical display start position
However, when dot size is 2Tc ✕ 2H or 2Tc ✕ 3H, set difference between vertical display position
of layer 1 and that of layer 2 as follows.
•2Tc ✕ 2H: 2H units
•3Tc ✕ 3H: 3H units
Note: In the OSDL mode, 1.5TC size cannot be used.
Note : When layer 1/layer 2 and SPRITE display
overlay each other, only OUT2 in layer 1/layer 2
is output.
SPRITE
Layer 1/layer 2
(except transparent)
Block 9
Block 10
...
Sprite
A
Layer 3
Block 15
Block 16
...
Layer 2
A'
Block 1
Block 2
Block 7
Block 8
SPRITE
R, G, B of layer 1/layer 2
OUT2 of layer 1/layer 2
Layer 1
Fig 2.16.5 Triple layer OSD
Rev. 1.0
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Display example of layer 1 = “HELLO,” layer 2 = “CH5”
CH5
HELLO
CH5
HELLO
CH5
HELLO
Layer 1’s color has priority
OC17 = “0”, OC16 = “1”
Logical sum (OR) of
layer 1’s color and
layer 2’s color (See note)
OC17 = “0,” OC16 = “0”
Layer 2’s color has priority
OC17 = “1,” OC16 = “0”
Note: The logical sum (OR) of layer mixing is not OR of the color palette registers’ contents (color), but
that of color pallet registers’ numbers (i).
Example) When the logical sum (OR) is performed on the color palettes 1 and 4;
the number 1 (00012) and number 4 (01002) are ORed and it results in the number 5
(01012). That is, the contents (color) of color palette register 5 is output. The color of
color palette register 5 is output in the ORed part, regardless of colors of color palettes
registers 1 and 4.
Figure 2.16.6 Display example of triple layer OSD
OSD control register 2
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
OC2
Bit symbol
OC20
Address
020316
When reset
0016
Function
Bit name
Display layer
selection bits
OC21
b1
0
0
1
1
b0
0
1
0
1
Layer 1
Layer 2
CC, OSDS/L/P, CDOSD
CC, OSDS/L/P
CDOSD
CC, OSDP, CDOSD
OSDS/L
CC, OSDP
CDOSD
OSDS/L
OC22
R, G, B signal output 0: Digital output
selection bit
1: Analog output (8 gradations)
OC23
Solid space output bit 0: OUT1 output
1: OUT2 output
OC24
Horizontal
window/blank control
bit
Window/blank
selection bit 1
(horizontal)
OC25
R W
0: OFF
1: ON
0: Horizontal blank function
1: Horizontal window function
OC26
Window/blank
selection bit 2
(vertical)
0: Vertical blank function
1: Vertical window function
OC27
OSD interrupt
request selection bit
0: At completion of layer 1 block display
1: At completion of layer 2 block display
Figure 2.16.7 OSD control register 2
Rev. 1.0
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2.16.2 Display Position
The display positions of characters are specified by a block. There are 16 blocks, blocks 1 to 16. Up to 32
characters (32-character mode)/42 characters (42-character mode)/ can be displayed in each block (refer to 2.16.6 Memory for OSD).
The display position of each block can be set in both horizontal and vertical directions by software.
The display position in the horizontal direction can be selected for all blocks in common from 256-step
display positions in units of 4 TOSC (TOSC = OSD oscillation cycle).
The display position in the vertical direction for each block can be selected from 1024-step display positions in units of 1 TH ( TH = HSYNC cycle).
Blocks are displayed in conformance with the following rules:
• When the display position is overlapped with another block in the dame layer (Figure 2.16.8 (b)), a lower
block number (1 to 16) is displayed on the front.
• When another block display position appears while one block is displayed in the dame layer (Figure
2.16.8 (c)), the block with a larger set value as the vertical display start position is displayed. However,
do not display block with the dot size of 2TC ✕ 2H or 3TC ✕ 3H during display period (✽) of another block.
✽ In the case of OSDS/P mode block: 20 dots in vertical from the vertical display start position.
✽ In the case of OSDL mode block: 32 dots in vertical from the vertical display start position.
✽ In the case of CC or CDOSD mode block: 26 dots in vertical from the vertical display start position.
HP
VP1
Block 1
VP2
Block 2
VP3
Block 3
(a) Example when each block is separated
HP
VP1 = VP2
Block 1
(Block 2 is not displayed)
(b) Example when block 2 overlaps with block 1
HP
VP1
VP2
Block 1
Block 2
(c) Example when block 2 overlaps in process of block 1
Note: VPi (i = 1 to 16) indicates the vertical display start position of display block i.
Figure 2.16.8 Display position
Rev. 1.0
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The display position in the vertical direction is determined by counting the horizontal sync signal (HSYNC).
At this time, when VSYNC and HSYNC are positive polarity (negative polarity), it starts to count the rising
edge (falling edge) of HSYNC signal from after fixed cycle of rising edge (falling edge) of VSYNC signal. So
interval from rising edge (falling edge) of VSYNC signal to rising edge (falling edge) of HSYNC signal needs
enough time (2 ✕ BCLK cycles or more) for avoiding jitter. The polarity of HSYNC and VSYNC signals can
select with the I/O polarity control register (address 020616).
8 ✕ BCLK cycles or more
VSYNC signal input
VSYNC control
signal in
microcomputer
Period of counting
HSYNC signal
0.1 to 0.2 [µs]
(BCLK = 10 MHz)
(Note 2)
HSYNC
signal input
26 ✕ BCLK cycles
or more
1
2
3
4
5
Not count
When bits 0 and 1 of the I/O polarity control register
(address 020616) are set to “1” (negative polarity)
Notes 1 : The vertical position is determined by counting falling edge of
HSYNC signal after rising edge of VSYNC control signal in the
microcomputer.
2 : Do not generate falling edge of HSYNC signal near rising edge
of VSYNC control signal in microcomputer to avoid jitter.
3 : The pulse width of HSYNC needs 26 ✕ BCLK cycles or more
(BCLK = 10 MHz).
Figure 2.16.9 Supplement explanation for display position
Rev. 1.0
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The vertical position for each block can be set in 1024 steps (where each step is 1TH (TH: HSYNC cycle))
as values “00216” to “3FF16” in vertical position register i (i = 1 to 16) (addresses 022016 to 023F16). The
vertical position register i is shown in Figure 2.16.10.
Vertical position register i
(b15)
(b8)
b7 b6 b5 b4 b3 b2 b1 b0 b7 b6 b5 b4 b3 b2 b1 b0
Symbol
VPi (i = 1 to 16)
Bit symbol
Address
When reset
Even addresses within addresses 022016 to 023F16, Indeterminate
Odd addresses within addresses 022016 to 023F16
Bit name
Function
VPi_9 to VPi_0 Vertical display start
position control bits of
SPRITE font
R W
Vertical display start position = TH ✕ n
(n: setting value, TH: HSYNC cycle)
Nothing is assined.
In an attempt to write to this bit, write “0.”
The value, if read, turns out to be indeterminate.
Note : Do not set VPi ≤ “00116,” VPi ≥ “40016.”
Figure 2.16.10 Vertical position register i (i = 1 to 16)
The horizontal position is common to all blocks, and can be set in 256 steps (where 1 step is 4TOSC, TOSC
being OSD oscillation cycle) as values “0016” to “FF16” in bits 0 to 7 of the horizontal position register
(address 020416). The horizontal position register is shown in Figure 2.16.11.
Horizontal position register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol
HP
Bit symbol
Address
020416
Bit name
HP_7 to HP_0 Horizontal display start
position control bits
When reset
0016
Function
R W
Horizontal display start position = 4TOSC ✕ n
(n: setting value, TOSC: OSD oscillation cycle)
Note : The setting value synchronizes with the VSYNC.
Figure 2.16.11 Horizontal position register
Rev. 1.0
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Note : 1TC (TC : OSD clock cycle divided in pre-divide circuit) gap occurs between the horizontal display
start position set by the horizontal position register and the most left dot of the 1st block. Accordingly, when 2 blocks have different pre-divide ratios, their horizontal display start position will not
match.
Ordinary, this gap is 1TC regardless of character sizes, however, the gap is 1.5TC only when the
character size is 1.5TC.
HSYNC
1TC
Note 1
Tdef
4TOSC ✕ N
Block 1 (Pre-divide ratio = 1)
1TC
Block 2 (Pre-divide ratio = 2)
1TC
Block 3 (Pre-divide ratio = 3)
1.5TC
Block 4 (Pre-divide ratio = 2, character size = 1.5Tc)
N
Tc
Tosc
Tdef
= Value of horizontal position register (decimal notation)
= OSD clock cycle divided in pre-divide circuit
= OSD oscillation cycle
= 50Tosc
Figure 2.16.12 Notes on horizontal display start position
Rev. 1.0
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2.16.3 Dot Size
The dot size can be selected by a block unit. The dot size in vertical direction is determined by dividing
HSYNC in the vertical dot size control circuit. The dot size in horizontal is determined by dividing the
following clock in the horizontal dot size control circuit : the clock gained by dividing the OSD clock source
(data slicer clock, OSC1, main clock) in the pre-divide circuit. The clock cycle divided in the pre-divide
circuit is defined as 1TC.
The dot size is specified by bits 3 to 6 of the block control register.
Refer to Figure 2.16.4 (the block control register i), refer to Figure 2.16.15 (the clock control register).
The block diagram of dot size control circuit is shown in Figure 2.16.13.
Notes 1 : The pre-divide ratio = 3 cannot be used in the CC mode.
2 : The pre-divide ratio of the layer 2 must be same as that of the layer 1 by the block control
register i.
3 : In the bi-scan mode, the dot size in the vertical direction is 2 times as compared with the normal
mode. Refer to “2.16.18 Scan Mode” about the scan mode.
Clock cycle
= 1TC
OSC1
Synchronous
circuit
Data slicer
clock
(See note)
Cycle✕2
Horizontal dot size
control circuit
Cycle✕3
Pre-divide circuit
Vertical dot size
control circuit
HSYNC
OSD control circuit
Note: To use data slicer clock, set bit 0 of data slicer control register 1 to “0.”
Figure 2.16.13 Block diagram of dot size control circuit
1 dot
1TC
1/2H
1TC
2TC
3TC
Scanning line of F1 (F2)
Scanning line of F2 (F1)
1H
2H
3H
In normal scan mode
Figure 2.16.14 Definition of dot sizes
Rev. 1.0
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2.16.4 Clock for OSD
As a clock for display to be used for OSD, it is possible to select one of the following 3 types.
• Data slicer clock output from the data slicer (approximately 26 MHz)
• Clock from the LC oscillator supplied from the pins OSC1 and OSC2
• Clock from the ceramic resonator (or the quartz-crystal oscillator) from the pins OSC1 and OSC2
Clock control register
b7 b6 b5 b4 b3 b2 b1 b0
0 0 0 0 0
Symbol
CS
Bit symbol
Address
020516
When reset
0016
Function
Bit name
CS0
Clock selection bit
0: Data slicer clock
1: OSC1 clock
CS1
OSC1 oscillating mode
selection bits
b2
CS2
Reserved bits
R W
b1
0 0: Stopped
0 1: Do not set.
1 0: LC oscillating mode
1
1: Ceramic • quartz-crystal
oscillating mode
Must always be set to “0”
Figure 2.16.15 Clock control register
Data slicer
circuit
(See note)
Data slicer clock
“0”
OSD control circuit
“10”
LC
Ceramic •
quartz-crystal
OSC1 clock
CS0
“1”
“11”
CS2, CS1
Oscillating mode for OSD
Note : To use data slicer clock, set bit 0 of data slicer control register 1 to “1.”
Figure 2.16.16 Block Diagram of OSD selection circuit
Rev. 1.0
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2.16.5 Field Determination Display
To display the block with vertical dot size of 1/2H, whether an even field or an odd field is determined
through differences in a synchronizing signal waveform of interlacing system. The dot line 0 or 1 (refer to
Figure 2.16.18) corresponding to the field is displayed alternately.
In the following, the field determination standard for the case where both the horizontal sync signal and
the vertical sync signal are negative-polarity inputs will be explained. A field determination is determined
by detecting the time from a falling edge of the horizontal sync signal until a falling edge of the VSYNC
control signal (refer to Figure 2.16.9) in the microcomputer and then comparing this time with the time of
the previous field. When the time is longer than the comparing time, it is regarded as even field. When the
time is shorter, it is regarded as odd field.
The field determination flag changes at a rising edge of VSYNC control signal in the microcomputer .
The contents of this field can be read out by the field determination flag (bit 7 of the I/O polarity control
register at address 020616). A dot line is specified by bit 6 of the I/O polarity control register (refer to
Figure 2.16.18).
However, the field determination flag read out from the CPU is fixed to “0” at even field or “1” at odd field,
regardless of bit 6.
I/O polarity control register
b7 b6 b5 b4 b3 b2 b1 b0
0
Address
020616
Symbol
PC
Bit symbol
When reset
1000X0002
Bit name
Function
PC0
HSYNC input
polarity switch bit
0 : Positive polarity input
1 : Negative polarity input
PC1
VSYNC input
polarity switch bit
0 : Positive polarity input
1 : Negative polarity input
PC2
R, G, B output
polarity switch bit
0 : Positive polarity output
1 : Negative polarity output
Reserved bit
Must always be set to “0.”
PC4
OUT1 output
polarity switch bit
0 : Positive polarity output
1 : Negative polarity output
PC5
OUT2 output
polarity switch bit
0 : Positive polarity output
1 : Negative polarity output
PC6
Display dot line
selection bit
(See note)
0:“
“
1:“
“
PC7
R W
” at even field
” at odd field
” at even field
” at odd field
Field determination 0 : Even field
flag
1 : Odd field
Note: Refer to Figure 2.16.19.
Figure 2.16.17 I/O polarity control register
Rev. 1.0
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Both HSYNC signal and VSYNC signal are negative-polarity input
HSYNC
Field
VSYNC and
VSYNC
control
signal
in microcomputer
Upper :
VSYNC signal
(n - 1) field
(Odd-numbered)
Field
Display dot line
determination
selection bit
flag(Note)
Odd
T1
0.5 to 0.1 [ms] at
f(BCLK) = 10 MHz
(n) field
(Even-numbered)
Even
(n + 1) field
(Odd-numbered)
Odd
0
Dot line 1
1
Dot line 0
0
Dot line 0
1
Dot line 1
0 (T2 > T1)
T2
Lower :
VSYNC control
signal in
microcomputer
Display dot line
1 (T3 < T2)
T3
When using the field determination flag, set bit 7 of the peripheral mode register (address 027D16) according to the main clock frequency.
1
2 3 4 5
6 7 8 9 10 11 12 13 14 15 16
1 2
3 4 5
6 7 8 9 10 11 12 13 14 15 16
1
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
OSDS mode
24
25
26
CC mode · CDOSD mode
When the display dot line selection bit is “0,”
the “
” font is displayed at even field, the
“
” font is displayed at odd field. Bit 7 of the
I/O polarity control register can be read as the
field determination flag : “1” is read at odd field,
“0” is read at even field.
OSD ROM font configuration diagram
Note : The field determination flag changes at a rising edge of the VSYNC control signal (negative-polarity input) in
the microcomputer.
Figure 2.16.18 Relation between field determination flag and display font
Rev. 1.0
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2.16.6 Memory for OSD
There are 2 types of memory for OSD : OSD ROM (addresses 9000016 to AFFFF16) used to store
character dot data and OSD RAM (addresses 040016 to 13FF16) used to specify the kinds of display
characters, display colors, and SPRITE display. The following describes each type of memory.
(1) ROM for OSD (addresses 9000016 to AFFFF16)
The dot pattern data for OSD characters is stored in the character font area in the OSD ROM and the
CD font data for OSD characters is stored in the color dot font area in the OSD ROM. To specify the
kinds of the character font and the CD font, it is necessary to write the character code into the OSD
RAM.
For character font, there are the following 2 mode.
• OSDL enable mode
16 ✕ 20-dot font and 24 ✕ 32-dot font
• OSDL disable mode
16 ✕ 20-dot font
The modes are selected by bit 3 of the OSD control register 3 for each screen.
The character font data storing address for OSDL enable/OSDL disable mode are shown in Figures
2.16.20 and 2.16.21. The conditions for each OSDL enable/disable mode are shown in Figure
2.16.22. The CD font data storing address is shown in Figure 2.16.23.
OSD control register 4
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
OC4
Bit symbol
OC40
OC41
Address
025F16
Bit name
When reset
XXXXX002
Function
OSDL mode
selection bit
0 : OSDL enable mode
1 : OSDL disable mode
Number of horizontal
display characters
selection bit
0 : 32 characters for each block
(32-character mode)
1 : 42 characters for each block
(42-character mode)
RW
Nothing is assigned.
In an attempt to write to these bits, write “0.” The value, if read, turns out to be “0.”
Figure 2.16.19 OSD control register 4
Rev. 1.0
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OSD ROM address of character font data (OSDL enable mode)
OSD ROM
AD16 AD15 AD14 AD13 AD12 AD11 AD10
address bit
AD8
AD7
AD6
AD5
AD4
AD3
AD2
AD1
AD0
Structure of address pointer
Kinds of font
0
Line number (1) (MSB to LSB)
Character
code
(C8)=0
Areas 0, 1
0
Line number (2) (MSB to LSB)
Character
code
(C8)=1
Area 2
1
Line number (2) (MSB to LSB)
Font (1)
Character codes
00016 to 0FF16
Font (2)
Character codes
10016 to 1FF16
AD9
0
0
Character code (C7 to C0)
0
Area
bit
Character code (C7 to C0)
0
Area
bit
0
Character
code
(C7)
Character code (C6 to C0)
Line number (1) = “0216” to “1516”
Line number (2) = “0016” to “1F16”
Character code = “00016” to “1FF16” (“0FE16,” “0FF16,” “10016” and “18016” cannot be used. Write “FF16” to corresponding addresses.)
Area bit = 0: Area 0
1: Area 1
Line
number (1)
b7
Area 0
b0 b7
Area 1
0216
0316
0416
0516
0616
0716
0816
0916
0A16
0B16
0C16
0D16
0E16
0F16
1016
1116
1216
1316
1416
1516
Font (1)
(Character codes 00016 to 0FF16)
b0
Line
number (2)
b7
Area 0
b0 b7
Area 1
b0 b7
Area 2
b0
0016
0116
0216
0316
0416
0516
0616
0716
0816
0916
0A16
0B16
0C16
0D16
0E16
0F16
1016
1116
1216
1316
1416
1516
1616
1716
1816
1916
1A16
1B16
1C16
1D16
1E16
1F16
Font (2)
(Character codes 10016 to 1FF16)
Figure 2.16.20 Character font data storing address (OSDL enable mode)
Rev. 1.0
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OSD ROM address of character font data (OSDL disable mode)
OSD ROM
AD16 AD15 AD14 AD13 AD12 AD11 AD10
address bit
AD9
AD8
AD7
AD6
AD5
AD4
AD3
AD2
AD1
AD0
Structure of address pointer
Kinds of font
Font (1)
Character codes
00016 to 1FF16
Character
code
(C9)=0
Font (2)
Character codes
20016 to 27F16
Character
code
(C9)=1
Font (3)
Character codes
28016 to 2FF16
0
Line number (1) (MSB to LSB)
Character code (C8 to C0)
0
Area
bit
Line number (1) (MSB to LSB)
Character code (C8 to C0)
0
Area
bit
0
Area
bit
1
Line number (3)
(NL3 to NL0)
1
Line
number
(3)
(NL4)
Character code (C6 to C0)
Line number (1) = “0216” to “1516”
Line number (3) = “0616” to “0F16” and “1616” to “1F16”
Character code = “00016” to “2FF16” (“0FE16,” “0FF16,” “10016,” “18016,” “20016” and “28016” cannot be used. Write “FF16” to corresponding addresses.)
Area bit = 0: Area 0
1: Area 1
Line
number (1)
b7
Area 0
b0 b7
Area 1
0216
0316
0416
0516
0616
0716
0816
0916
0A16
0B16
0C16
0D16
0E16
0F16
1016
1116
1216
1316
1416
1516
b0
Line
number (2)
b7
Area 0
b0 b7
Area 1
b0
0616
0716
0816
0916
0A16
0B16
0C16
0D16
0E16
0F16
1616
1716
1816
1916
1A16
1B16
1C16
1D16
1E16
1F16
Font (1)
Font (2)
Font (3)
(Character codes 28016 to 2FF16)
(Character codes 00016 to 27F16)
Figure 2.16.21 Character font data storing address (OSDL disable mode)
Rev. 1.0
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Depending on the relationship of OSDL enable/disable mode, display mode and character code, note the conditions below.
OSDL enable/
disable mode
Specified
character
code
CC
00016
to
0FF16
S
10016
to
1FF16
L (See note 1)
OSDS/P
OSDL
OSDL disable mode
Character size
Display mode
Character size
Display mode
& character code
OSDL enable mode
(Bit 0 of OSD control register 4 = “0”)
(Bit 0 of OSD control register 4 = “1”)
CC
OSDL
Used
Used
Not used
(See note 3)
Used
Used
Display OFF
Used
Used
(See note 1)
Used
Used
Used
Display OFF
Used
Display OFF
S
20016
to
27F16
28016
to
2FF16
Not used
(See note 3)
Not used
(See note 3)
30016
to
3FF16
Used
(No border ) Display OFF
(See note 2)
Not used
16
20
OSDS/P
24
Display OFF
Notes 1: Part of 24 ✕ 32 font is displayed.
2: In OSDL disable mode, character
codes “28016” to “2FF16” are used
in OSDS/P mode (no border).
3: As setting this make output of
font data indeterminate, do not use.
However, “3FE16” and “3FF16” can
be used as character codes of
blank font output in OSDP mode.
32
Figure 2.16.22 Conditions for each OSDL enable/disable mode
Rev. 1.0
185
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
OSD ROM address of CD font data
OSD ROM
address bit
AD16 AD15 AD14 AD13 AD12 AD11 AD10 AD9
Line number/
CD code/Area bit
CD
code
(C6)
1
Plane
selection bit
AD8
AD7
AD6
Line number (MSB to LSB)
AD5
AD4 AD3
AD2 AD1
Area
bit
1
CD code (C5 to C0)
AD0
Line number = “0016” to “1916”
CD code
= “0016” to “7F16” (“3F16” and “4016” can not be used. Write “FF16” to the corresponding address.)
Area bit
= 0 : Area 0
1 : Area 1
Plane 3
(Color palette selection bit 3)
Plane 2
(Color palette selection bit 2)
Plane 1
(Color palette selection bit 1)
Plane 0
(Color palette selection bit 0)
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
1
1
0
0
0
0
0
0
0
0
0
0
0
0
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
1
1
0
0
0
0
0
0
0
0
0
0
0
0
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
1
1
0
0
0
0
0
0
0
0
0
0
0
0
1
1
0
0
0
0
0
0
1
1
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
1
1
0
0
0
0
0
0
0
0
0
0
0
0
1
1
0
0
0
0
0
0
1
1
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
1
1
0
0
0
0
0
0
0
0
0
0
0
0
1
1
0
0
0
0
0
0
1
1
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
1
1
0
0
0
0
0
0
0
0
0
0
0
0
1
1
0
0
0
0
0
0
1
1
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
1
1
0
0
0
0
0
0
0
0
0
0
0
0
1
1
0
0
0
0
0
0
1
1
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
1
1
0
0
0
0
0
0
0
0
0
0
0
0
1
1
0
0
0
0
0
0
1
1
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
1
1
0
0
0
0
0
0
0
0
0
0
0
0
1
1
0
0
0
0
0
0
1
1
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
1
1
0
0
0
0
0
0
0
0
0
0
0
0
1
1
0
0
0
0
0
0
1
1
1
1
0
0
0
0
0
0
0
0
0
1
1
1
1 1
1
1
1 1
1
0
0
0
0
0
0
0
0
0
0 1
1
0
0 0
0
0
0
0
1
1
0
0
0
0
0
0
0
0
0
0
0
0
1
1
0
0
0
0
0
0
1
1
1
1
0
0
0
0
0
0
0
0
0
1
1
1
1 1
1
1
1 1
1
0
0
0
0
0
0
0
0
0
0 1
1
0
0 0
0
0
0
0
1
1
0
0
0
0
0
0
0
0
0
0
0
0
1
1
0
0
0
0
0
0
1
1
1
1
0
0
0
0
0
0
0
0
0
1
1
1
1 1
1
1
1 1
1
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
1
1
0
0
0
0
0
0
0
0
0
0
0
0
1
1
0
0
0
0
0
0
1
1
1
1
0
0
0
0
0
0
0
0
0
1
1
1
1 1
1
1
1 1
1
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
1
1
0
0
0
0
0
0
0
0
0
0
0
0
1
1
0
0
0
0
0
0
1
1
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
1
1
0
0
0
0
0
0
0
0
0
0
0
0
1
1
0
0
0
0
0
0
1
1
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
1
1
0
0
0
0
0
0
0
0
0
0
0
0
1
1
0
0
0
0
0
0
1
1
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
1
1
0
0
0
0
0
0
0
0
0
0
0
0
1
1
0
0
0
0
0
0
1
1
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
1
1
0
0
0
0
0
0
0
0
0
0
0
0
1
1
0
0
0
0
0
0
1
1
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
1
1
0
0
0
0
0
0
0
0
0
0
0
0
1
1
0
0
0
0
0
0
1
1
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
1
1
0
0
0
0
0
0
0
0
0
0
0
0
1
1
0
0
0
0
0
0
1
1
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
1
1
0
0
0
0
0
0
0
0
0
0
0
0
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
1
1
0
0
0
0
0
0
0
0
0
0
0
0
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0 0
0
0
0 0
0
0
0
0
Line
number
0016
0116
0216
0316
0416
1616
1716
1816
1916
b7
Area 0
b0 b7
Area 1
4 4 4 4 4 4 4 4 4 4 4 4 4 4 4
4 4 4 4 4 4 4 4 4 4 4 4 4 4 4
4 4 0 0 0 0 0 0 0 0 0 0 0 0 4
4 4 0 0 0 0 0 0 0 0 0 0 0 0 4
0516
4 4 0 0 0 0 2 2 2 2 0 0 0 0 4
0616
4 4 0 0 0 0 2 2 2 2 0 0 0 0 4
0716
4 4 0 0 0 0 2 2 2 2 0 0 0 0 4
2 162 2 0 0 0 0 4
4 4 0 0 0 0 2 08
0916
4 4 0 0 0 0 2 2 2 2 0 0 0 0 4
0A16
4 4 0 0 0 0 2 2 2 2 0 0 0 0 4
0B16
4 4 0 0 0 0 2 2 2 2 0 0 0 0 4
0C16
4 4 0 1 1 1 3 3 3 3 1 1 1 0 4
0D16
4 4 0 1 1 1 3 11 11 3 1 1 1 0 4
0E16
4 4 0 1 1 1 3 11
11 3 1 1 1 0 4
0F16
4 4 0 1 1 1 3 3 3 3 1 1 1 0 4
16
4 4 0 0 0 0 2 10
2 2 2 0 0 0 0 4
2 162 2 0 0 0 0 4
4 4 0 0 0 0 2 11
1216
4 4 0 0 0 0 2 2 2 2 0 0 0 0 4
13
4 4 0 0 0 0 2 2 162 2 0 0 0 0 4
4 4 0 0 0 0 2 14
2 162 2 0 0 0 0 4
1516
4 4 0 0 0 0 2 2 2 2 0 0 0 0 4
4 4 0 0 0 0 2 2 2 2 0 0 0 0 4
4 4 0 0 0 0 0 0 0 0 0 0 0 0 4
4 4 0 0 0 0 0 0 0 0 0 0 0 0 4
4 4 4 4 4 4 4 4 4 4 4 4 4 4 4
4 4 4 4 4 4 4 4 4 4 4 4 4 4 4
b0
Line
number b7
4
4
4
4
4
4
4
4
4
4
4
4
4
4
4
4
4
4
4
4
4
4
4
4
4
4
0016
0116
0216
0316
0416
0516
0616
0716
0816
0916
0A16
0B16
0C16
0D16
0E16
0F16
1016
1116
1216
1316
1416
1516
1616
1716
1816
1916
0 Color palette set by RC13 to
RC16 of OSD RAM is selected
1 Color palette 1 is selected
2 Color palette 2 is selected
3 Color palette 3 is selected
4 Color palette 4 is selected
11 Color palette 11 is selected
Area 0
b0 b7
Area 1
b0
Display example
Figure 2.16.23 Color dot font data storing address
Rev. 1.0
186
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
(2) OSD RAM (OSD RAM for character, addresses 040016 to 0EFF16)
The OSD RAM for character is allocated at addresses 040016 to 0EFF16, and is divided into a display
character code specification part, color code 1 specification part, and color code 2 specification part
for each block. The number of characters for 1 block (32- or 42-character mode) is selected by bit 1 of
the OSD control register 4. Tables 2.16.3 to 2.16.7 show the address map.
For example, to display 1 character position (the left edge) in block 1, write the character code in
address 040016, write color code 1 at 040116, and write color code 2 at 048016. The structure of the
OSD RAM is shown in Figure 2.16.25.
Note : For blocks of the following dot sizes, the 3nth (n = 1 to 14) character is skipped as compared
with ordinary block.
■In OSDL mode: all dot size.
■In OSDS and CDOSD modes of layer 2: 1.5Tc ✕ 1/2H or 1.5Tc ✕ 1H
Accordingly, maximum 22 characters (32-character mode)/28 characters (42-character mode)
are only displayed in 1 block. Blocks with dot size of 1TC ✕ 1/2H and 1TC ✕ 1H, or blocks on the
layer 1. The RAM data for the 3nth character does not effect the display. Any character data can
be stored here. And also, note the following only in 32-character mode. As the character is
displayed in the 28th’s character area in 42-character mode, set ordinarily.
• In OSDS mode
The character is not displayed, and only the left 1/3 part of the 22nd character back
ground is displayed in the 22nd’s character area. When not displaying this background, set transparent for character background color.
• In OSDL mode
Set a blank character or a character of transparent color to the 22nd character.
• In CDOSD mode
The character is not displayed, and color palette color specified by bits 3 to 6 of color
code 1 can be output in the 22nd’s character area (left 1/3 part).
Display
sequence
RAM
address
order
1
2
3
4
5
6
1
2
4
5
7
8
7
8
9 10 11 12 13 14 15 16 17 18 19 20 21 22
10 11 13 14 16 17 19 20 22 23 25 26 28 29 31 32
• 1.5Tc size block
• OSDL block
Display
sequence 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
RAM
address 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
order
• 1Tc size block
Figure 2.16.24 RAM data for 3rd character (in 32-character mode)
Rev. 1.0
187
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
Table 2.16.3 Contents of OSD RAM (1st to 32nd character)
Block
Block 1
Display Position (from left)
1st character
Character Code Specification
Color Code 1 Specification
Color Code 2 Specification
040016
040116
048016
2nd character
:
31st character
040216
:
040316
:
048216
:
043C16
043D16
04BC16
043F16
04BE16
1st character
043E16
044016
044116
04C016
2nd character
:
31st character
044216
:
047C16
32nd character
047E16
044316
:
047D16
047F16
04C216
:
04FC16
04FE16
1st character
050016
050116
058016
2nd character
:
31st character
050216
:
053C16
050316
:
053D16
058216
:
05BC16
32nd character
053E16
053F16
05BE16
1st character
054016
2nd character
:
31st character
054216
:
057C16
054116
054316
:
057D16
05C016
05C216
:
05FC16
32nd character
057E16
057F16
05FE16
1st character
060016
060116
068016
2nd character
:
31st character
060216
:
063C16
060316
:
063D16
068216
:
06BC16
32nd character
1st character
063E16
063F16
06BE16
064016
064116
06C016
2nd character
:
31st character
064216
:
067C16
064316
:
067D16
06C216
:
06FC16
32nd character
067E16
070016
067F16
06FE16
1st character
070116
078016
2nd character
:
31st character
070216
:
073C16
070316
:
073D16
078216
:
07BC16
32nd character
073E16
073F16
07BE16
1st character
074016
074116
07C016
2nd character
:
31st character
074216
:
077C16
074316
:
077D16
07C216
:
07FC16
32nd character
077E16
1st character
080016
077F16
080116
07FE16
088016
2nd character
:
31st character
080216
:
083C16
080316
:
083D16
088216
:
08BC16
32nd character
083E16
083F16
08BE16
1st character
084016
084116
08C016
2nd character
:
31st character
32nd character
084216
:
087C16
084316
:
087D16
08C216
:
08FC16
087E16
087F16
08FE16
32nd character
Block 2
Block 3
Block 4
Block 5
Block 6
Block 7
Block 8
Block 9
Block 10
Rev. 1.0
188
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
Table 2.16.4 Contents of OSD RAM (1st to 32nd character) (continued)
Block
Block 11
Block 12
Block 13
Block 14
Block 15
Block 16
Display Position (from left)
1st character
Character Code Specification
Color Code 1 Specification
Color Code 2 Specification
090016
090116
098016
2nd character
:
31st character
090216
:
093C16
32nd character
093E16
090316
:
093D16
093F16
098216
:
09BC16
09BE16
1st character
094016
094116
09C016
2nd character
:
31st character
094216
:
097C16
094316
:
097D16
09C216
:
09FC16
32nd character
097E16
097F16
09FE16
1st character
0A0016
2nd character
:
31st character
0A8016
0A8216
:
0ABC16
32nd character
0A0216
:
0A3C16
0A3E16
0A0116
0A0316
:
0A3D16
0A3F16
0ABE16
1st character
0A4016
0A4116
0AC016
2nd character
:
31st character
0A4216
:
0A7C16
0A4316
:
0A7D16
0AC216
:
0AFC16
32nd character
0A7E16
0A7F16
0AFE16
1st character
0B0016
0B0216
:
0B3C16
0B0116
0B8016
0B0316
:
0B3D16
0B8216
:
0BBC16
32nd character
1st character
0B3E16
0B3F16
0BBE16
0B4016
0B4116
0BC016
2nd character
:
31st character
0B4216
:
0B7C16
32nd character
0B7E16
0B4316
:
0B7D16
0B7F16
0BC216
:
0BF016
0BFE16
2nd character
:
31st character
Rev. 1.0
189
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
Table 2.16.5 Contents of OSD RAM (33rd to 42nd character)
Block
Display Position (from left)
Character Code Specification
0C0016
Color Code 1 Specification
0C0116
Color Code 2 Specification
0C8016
41st character
42nd character
0C0216
:
0C0C16
0C0E16
0E0016
0E0216
0C0316
:
0C0D16
0C0F16
0E0116
0C8216
:
0C8C16
0C8E16
0E8016
0E0316
0E8216
33rd character
0C1016
0C1116
0C9016
34th character
:
39th character
0C1216
0C1316
0C9216
:
0C1C16
:
0C1D16
:
0C9C16
:
0C1E16
0E0816
0E0A16
0C2016
0C2216
:
0C1F16
0E0916
0E0B16
0C2116
0C2316
:
0C9E16
0E8816
0E8A16
0CA016
0CA216
:
39th character
0C2C16
0C2D16
0CAC16
40th character
0C2E16
0E1016
0C2F16
0E1116
0CAE16
0E9016
42nd character
0E1216
0E1316
0E9216
33rd character
0C3016
0C3116
0CB016
34th character
:
39th character
0C3216
:
0C3C16
0C3E16
0E1816
0E1A16
0C4016
0C4216
:
0C4C16
0C4E16
0E2016
0E2216
0C3316
:
0C3D16
0C3F16
0E1916
0E1B16
0C4116
0C4316
:
0C4D16
0C4F16
0E2116
0E2316
0CB216
:
0CBC16
0CBE16
0E9816
0E9A16
0CC016
0CC216
:
0CCC16
0CCE16
0EA016
0EA216
0C5016
0C5216
:
0C5C16
0C5E16
0E2816
0E2A16
0C6016
0C6216
:
0C6C16
0C5116
0C5316
:
0C5D16
0C5F16
0E2916
0E2B16
0C6116
0C6316
:
0C6D16
0CD016
0CD216
:
0CDC16
0CDE16
0EA816
0EAA16
0CE016
0CE216
:
0CEC16
0C6E16
0E3016
0E3216
0C6F16
0E3116
0E3316
0CEE16
0EB016
0EB216
33rd character
34th character
:
39th character
Block 1
Block 2
40th character
40th character
41st character
42nd character
33rd character
34th character
Block 3
41st character
Block 4
40th character
41st character
42nd character
33rd character
Block 5
34th character
:
39th character
40th character
41st character
42nd character
33rd character
Block 6
34th character
:
39th character
40th character
41st character
42nd character
33rd character
Block 7
34th character
:
39th character
40th character
41st character
42nd character
Rev. 1.0
190
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
Table 2.16.6 Contents of OSD RAM (33rd to 42nd character) (continued)
Block
Display Position (from left)
Character Code Specification
0C7016
Color Code 1 Specification
0C7116
Color Code 2 Specification
0CF016
0C7216
:
0C7C16
0C7E16
0E3816
0E3A16
0D0016
0C7316
:
0C7D16
0C7F16
0E3916
0E3B16
0D0116
0CF216
:
0CFC16
0CFE16
0EB816
0EBA16
0D8016
33rd character
0D0216
:
0D0C16
0D0E16
0E4016
0E4216
0D1016
0D0316
:
0D0D16
0D0F16
0E4116
0E4316
0D1116
0D8216
:
0D8C16
0D8E16
0EC016
0EC216
0D9016
34th character
0D1216
0D1316
0D9216
:
39th character
:
:
:
0D1C16
0D1D16
0D9C16
40th character
41st character
0D1E16
0E4816
0D1F16
0D9E16
0E4916
0EC816
42nd character
0E4A16
0E4B16
0ECA16
33rd character
0D2016
0D2116
0DA016
34th character
:
39th character
0D2216
0D2316
:
0D2D16
0D2F16
0E5116
0E5316
0D3116
0D3316
:
0D3D16
0D3F16
0E5916
0E5B16
0D4116
0D4316
:
0D4D16
0D4F16
0DA216
:
0DAC16
0DAE16
0ED016
0ED216
0DB016
0DB216
:
0DBC16
0DBE16
0ED816
0EDA16
0DC016
0DC216
:
0DCC16
0DCE16
0E6116
0E6316
0D5116
0D5316
:
0D5D16
0D5F16
0E6916
0E6B16
0EE016
0EE216
0DD016
0DD216
:
0DDC16
0DDE16
0EE816
0EEA16
33rd character
Block 8
34th character
:
39th character
40th character
41st character
42nd character
33rd character
Block 9
34th character
:
39th character
40th character
41st character
42nd character
Block 10
Block 11
40th character
41st character
42nd character
33rd character
Block 12
34th character
:
39th character
40th character
41st character
Block 13
42nd character
33rd character
34th character
:
39th character
40th character
41st character
42nd character
33rd character
Block 14
34th character
:
39th character
40th character
41st character
42nd character
:
0D2C16
0D2E16
0E5016
0E5216
0D3016
0D3216
:
0D3C16
0D3E16
0E5816
0E5A16
0D4016
0D4216
:
0D4C16
0D4E16
0E6016
0E6216
0D5016
0D5216
:
0D5C16
0D5E16
0E6816
0E6A16
Rev. 1.0
191
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
Table 2.16.7 Contents of OSD RAM (33rd to 42nd character) (continued)
Block
Block 15
Block 16
Display Position (from left)
33rd character
Character Code Specification
0D6016
34th character
:
39th character
0D6216
:
0D6C16
40th character
41st character
Color Code 1 Specification
0D6116
0D6316
:
0D6D16
Color Code 2 Specification
0DE016
0DE216
:
0DEC16
0D6E16
0E7016
0D6F16
0DEE16
0E7116
0EF016
42nd character
0E7216
0E7316
0EF216
33rd character
0D7016
34th character
:
39th character
0D7216
:
0D7C16
0D7E16
0E7816
0E7A16
0D7116
0D7316
:
0D7D16
0D7F16
0E7916
0E7B16
0DF016
0DF216
:
0DFC16
0DFE16
0EF816
0EFA16
40th character
41st character
42nd character
Rev. 1.0
192
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
Blocks 1 to 16
b1
b0
b0
b7
C9 RC21 RC20 RC17 RC16 RC15 RC14 RC13 RC12 RC11 C8
C7
b2
b7
Color code 2
C6
C5
Color code 1
C4
C3
C2
C1
C0
Character code
OSDS/L/P mode
CC mode
Bit name
Function
Bit
b0
Bit name
CDOSD mode
Bit name
Function
Function
C0
C1
C2
Character
C3
code
C4
(Low-order 9 bits)
Character
Specify
character code in
code
(Low-order 9 bits)
OSD ROM
C5
CD code
Specify
(7 bits)
character code in
Specify
character code
in
OSD ROM
(color dot)
OSD ROM
C6
C7
C8
Not used
RC11
(See note 3)
Color palette
selection bit 1
Color palette
selection bit 2
RC13
0: Italic OFF
0: Flash OFF
1: Flash ON
RC16 Underline control 0: Underline OFF
1: Underline ON
RC17
C9
0: OUT2 output OFF
Color palette Specify color palette
for background
selection bit 0
(See note 3)
Color palette
selection bit 1
Color palette Specify color palette
selection bit 0
for character
Color palette
selection bit 1
OUT2 output
control
1: OUT2 output ON
Character background
RC21
Character background
RC20
OUT2 output
control
Color palette
selection bit 0
Color palette
selection bit 3
Character background
Flash control
(See note 3)
Color palette
selection bit 1
Color palette
selection bit 2
1: Italic ON
RC15
Color palette Specify color palette
selection bit 0
for character
(See note 3)
0: OUT2 output OFF
1: OUT2 output ON
Dot color
Italic control
RC14
Character
Character
RC12
Color palette Specify color palette
selection bit 0
for character
Color palette
selection bit 1
Color palette
selection bit 2
Specify a dot
which selects
color palette 0
by OSD ROM
(See note 4)
Color palette
selection bit 3
OUT2 output
control
0: OUT2 output OFF
1: OUT2 output ON
Color palette Specify color palette
for background
selection bit 2
(See note 3)
Not used
Specify character
code in OSD ROM
Not used
Color palette
selection bit 3
Character code
Specify character Character code
(High-order 1 bit) code in OSD ROM (High-order 1 bit)
Notes 1: Read value of bits 3 to 7 of the color code 2 is undefined.
2: For “not used” bits, the write value is read.
3: Refer to Figure 2.16.26.
4: Only in CDOSD mode, a dot which selects color palette 0 is colored to the color palette set by RC13 to RC16 of
OSD RAM in character units. When the character size is 1.5TC ✕ 1H or 1.5TC ✕ 1/2H, however, set RCI3 to RC16
and RC17 of all characters (including the 3nth character) within the same block to the same value.
Figure 2.16.25 Structure of OSD RAM
Rev. 1.0
193
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
(3) OSD RAM (OSD RAM for SPRITE, addresses 100016 to 13E716)
The OSD RAM for SPRITE fonts 1 and 2, consisting of 4 planes for each font, is assigned to addresses 100016 to 13E716. Each plane corresponds to each color palette selection bit and the color
palette of each dot is determined from among 16 kinds.
Table 2.16.8 OSD RAM address (SPRITE font 1)
Planes
Plane 3
Plane 2
(Color paleltte selection bit 3)
9 to 16
Plane 1
(Color paleltte selection bit 2)
9 to 16
Plane 0
(Color paleltte selection bit 1)
9 to 16
(Color paleltte selection bit 0)
Dots
1 to 8
17 to 24
25 to 32
1 to 8
17 to 24
25 to 32
1 to 8
17 to 24 25 to 32
1 to 8
Bits
b7 to b0 b7 to b0 b7 to b0
b7 to b0
b7 to b0 b7 to b0 b7 to b0
b7 to b0
b7 to b0 b7 to b0
b7 to b0 b7 to b0
b7 to b0 b7 to b0
9 to 16
b7 to b0
17 to 24
25 to 32
Line 1
10C016
10C116
11C016
11C116
108016
108116
118016
118116
104016
104116
114016
114116
100016
100116
110016
110116
Line 2
•
•
•
Line 19
10C216
•
•
•
10E416
10C316
•
•
•
10E516
11C216
•
•
•
11E416
11C316
•
•
•
11E516
108216
•
•
•
10A416
108316
•
•
•
10A516
118216
•
•
•
11A416
118316
•
•
•
11A516
104216
•
•
•
106416
104316
•
•
•
106516
114216
•
•
•
116416
114316
•
•
•
116516
100216
•
•
•
102416
100316
•
•
•
102516
110216
•
•
•
112416
110316
•
•
•
112516
Line 20
10E616
10E716
11E616
11E716
10A616
10A716
11A616
11A716
106616
106716
116616
116716
102616
102716
112616
112716
b7 to b0
Table 2.16.9 OSD RAM address (SPRITE font 2)
Planes
Plane 3
Plane 2
(Color paleltte selection bit 3)
9 to 16
Plane 1
(Color paleltte selection bit 2)
9 to 16
Plane 0
(Color paleltte selection bit 1)
9 to 16
(Color paleltte selection bit 0)
Dots
1 to 8
17 to 24
25 to 32
1 to 8
17 to 24
25 to 32
1 to 8
17 to 24 25 to 32
1 to 8
Bits
b7 to b0 b7 to b0 b7 to b0
b7 to b0
b7 to b0 b7 to b0 b7 to b0
b7 to b0
b7 to b0 b7 to b0
b7 to b0 b7 to b0
b7 to b0 b7 to b0
9 to 16
b7 to b0
17 to 24
25 to 32
Line 1
12C016
12C116
13C016
13C116
128016
128116
138016
138116
124016
124116
134016
134116
120016
120116
130016
130116
Line 2
•
•
•
Line 19
12C216
•
•
•
12E416
12C316
•
•
•
12E516
13C216
•
•
•
13E416
13C316
•
•
•
13E516
128216
•
•
•
12A416
128316
•
•
•
12A516
138216
•
•
•
13A416
138316
•
•
•
13A516
124216
•
•
•
126416
124316
•
•
•
126516
134216
•
•
•
136416
134316
•
•
•
136516
120216
•
•
•
122416
120316
•
•
•
122516
130216
•
•
•
132416
130316
•
•
•
132516
Line 20
12E616
12E716
13E616
13E716
12A616
12A716
13A616
13A716
126616
126716
136616
136716
122616
122716
132616
132716
b7 to b0
Plane 3
Dot structure of SPRITE font
Plane 2
Dot number
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
1
2
3
4
5
6
7
8
9
Line 10
number 11
12
13
14
15
16
17
18
19
20
Plane 1
Plane 0
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
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
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
Rev. 1.0
194
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
2.16.7 Character Color
As shown in Figure 2.16.26, there are 16 built-in color codes. Color palette 0 is fixed at transparent, and
color palette 8 is fixed at black. The remaining 14 colors can be set to any of the 512 colors available. The
setting procedure for character colors is as follows:
• CC mode ........................................ 8 kinds
Color palette selection range (color palettes 0 to 7 or 8 to 15) can be selected by bit 0 of the OSD control
register 3 (address 020716). Color palettes are set by bits RC11 to RC13 of the OSD RAM from among
the selection range.
• OSDS/L/P mode ........................... 16 kinds
Color palettes are set by bits RC11 to RC14 of the OSD RAM.
• CDOSD mode ............................... 16 kinds
Color palettes are set in dot units according to CD font data.
Only in CDOSD mode, a dot which selects color palette 0 or 8 is colored to the color palette set by RC13
to RC16 of OSD RAM in character units (refer to Figure 2.16.28).
• SPRITE display ............................ 16 kinds
Color palettes are set in dot units according to the CD font data.
Notes 1: Color palette 8 is always selected for bordering and solid space output (OUT 1 output) regardless
of the set value in the register.
2: Color palette 0 (transparent) and the transparent setting of other color palettes will differ. When
there are multiple layers overlapping (on top of each other, piled up), and the priority layer is color
palette 0 (transparent), the bottom layer is displayed, but if the priority layer is the transparent
setting of any other color palette, the background is displayed without displaying the bottom layer
(refer to Figure 2.16.28).
2.16.8 Character Background Color
The display area around the characters can be colored in with a character background color. Character
background colors are set in character units.
• CC mode ........................................ 4 kinds
Color palette selection range (color codes 0 to 3, 4 to 7, 8 to 11, or 12 to 15) can be selected by bits 1 and
2 of the OSD control register 3 (address 020716). Color palettes are set by bits RC20 and RC21 of the
OSD RAM from among the selection range.
• OSDS/L/P mode ........................... 16 kinds
Color palettes are set by bits RC15, RC16, RC20, and RC21 of the OSD RAM.
Note: The character background is displayed in the following part:
(character display area) – (character font) – (border).
Accordingly, the character background color and the color signal for these two sections cannot be
mixed.
Rev. 1.0
195
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
CC mode
(background)
CC mode
(character)
OSDS/L/P mode (character, background)
CDOSD mode (character) (See note 2)
SPRITE display
Color palette 0 (Transparent)
Color palette 1
Color palette 2
Color palette 3
Color palette 4
Color palette 5
Color palette 6
Color palette 7
Color palette 8 (Black)
Color palette 9
Select one
palette in
screen units.
(See note 1)
Select either
palette in
screen units.
(See note 1)
Any palette
can be
selected.
Color palette 10
Color palette 11
Color palette 12
Color palette 13
Color palette 14
Color palette 15
Notes 1: Color palettes are selected by OSD control register 3 (address 020716).
2: Only in CDOSD mode, a dot which selects color palette 0 or 8 is colored to
of OSD RAM in character units.
Figure 2.16.26 Color palette selection
Rev. 1.0
196
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
Dot area specified to color palette 1
Set values of OSD RAM (RC16 to RC13)
0001
0010
0000
Transparent
Black
Blue
Dot area specified to color palette 0
When setting black and blue to color palettes 1 and 2, respectively
(only in CDOSD mode).
Figure 2.16.27 Set of color palette 0 or 8 in CDOSD mode
Color palette 1 (Transparent)
Layer 1
(CC mode)
26 dots
Color palette 0 (Transparent)
Black
Layer 2
(OSDS/L mode)
20 dots
Color palette 2 (Blue)
26 dots
20 dots
Blue
Transparent
(video signal)
When layer 1 has priority.
Color palette 8 (Black)
Figure 2.16.28 Difference between color palette 0 (transparent) and transparent setting of other
color palettes
Rev. 1.0
197
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
OSD control register 3
b7 b6 b5 b4 b3 b2 b1 b0
0
Symbol
OC3
Address
020716
Bit symbol
Bit name
OC30
CC mode character
color selection bit
OC31
CC mode character
background color
selection bits
(See note)
OC32
When reset
0016
Reserved bits
Function
R W
0: Color palettes 0 to 7
1: Color palettes 8 to 15
b2 b1
0
0
1
1
0: Color palettes 0 to 3
1: Color palettes 4 to 7
0: Color palettes 8 to 11
1: Color palettes 12 to 15
Must always be set to “0”
OC34
Flash cycle
selection bit
0: 1 cycle = VSYNC cycle ✕ 32
1: 1 cycle = VSYNC cycle ✕ 64
OC35
OSDS/L/P mode
window control bit
0: Window OFF
1: Window ON
OC36
CC mode window
control bit
0: Window OFF
1: Window ON
OC37
CDOSD mode
window control bit
0: Window OFF
1: Window ON
Note: Color palette 8 is always selected for solid space (when OUT1 output is
selected), regardless of value of this register.
Figure 2.16.29 OSD control register 3
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
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Color palette register i
(b15)
(b8)
b7 b6 b5 b4 b3 b2 b1 b0 b7 b6 b5 b4 b3 b2 b1 b0
Symbol
CRi (i = 1 to 7)
CRi (i = 8 to 15)
Bit symbol
Addresses
Even addresses within addresses 024016 to 024D16,
Odd addresses within addresses 024016 to 024D16
Even addresses within addresses 024E16 to 025B16,
Odd addresses within addresses 024E16 to 025B16
Bit name
CRi_2 to CRi_0 R signal output
control bits
Function
When reset
Indeterminate
Indeterminate
R W
b2 b1 b0
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0 : VSS
1 : 1/7VCC
0 : 2/7VCC
1 : 3/7VCC
0 : 4/7VCC
1 : 5/7VCC
0 : 6/7VCC
1 : VCC
Nothing is assined.
In an attempt to write to this bit, write “0.”
The value, if read, turns out to be indeterminate.
CRi_6 to CRi_4 G signal output
control bits
b6 b5 b4
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0 : VSS
1 : 1/7VCC
0 : 2/7VCC
1 : 3/7VCC
0 : 4/7VCC
1 : 5/7VCC
0 : 6/7VCC
1 : VCC
Nothing is assined.
In an attempt to write to this bit, write “0.”
The value, if read, turns out to be indeterminate.
CRi_10 to CRi_8 B signal output
control bits
b10 b9 b8
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0 : VSS
1 : 1/7VCC
0 : 2/7VCC
1 : 3/7VCC
0 : 4/7VCC
1 : 5/7VCC
0 : 6/7VCC
1 : VCC
Nothing is assined.
In an attempt to write to this bit, write “0.”
The value, if read, turns out to be indeterminate.
CRi_12
OUT1 signal output
control bit
0: No output
1: Output
Nothing is assined.
In an attempt to write to this bit, write “0.”
The value, if read, turns out to be indeterminate.
Figure 2.16.30 Color palette register i (i = 1 to 7, 9 to 15)
Rev. 1.1
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2.16.9 OUT1, OUT2 Signals
The OUT1, OUT2 signals are used to control the luminance of the video signal. The output waveform of
the OUT1, OUT2 signals is controlled by bit 6 of the color palette register i (refer to Figure 2.16.30), bits
0 to 2 of the block control register i (refer to Figure 2.16.4) and RC17 of OSD RAM. The setting values for
controlling OUT1, OUT2 and the corresponding output waveform is shown in Figure 2.16.31.
Conditions
OUT2 output
control
(RC 17 of
OSD RAM)
Border output
OUT1 signal output control bit
(See note 2)
bit12(CRi12) of color pallet
Output
register i
Background
Character
waveform
0
H
L
1
H
L
0
H
L
1
H
L
0
H
L
1
H
L
0
H
L
1
H
L
H
L
0
No output
1
OUT1
signal
✕
0
Output
(See note 1)
1
0
✕
✕
✕
1
✕
✕
✕
OUT2
signal
H
L
Notes 1: This control is only valid in the OSDS/P mode. It is invalid in CC/CDOSD/OSDL mode .
2: In the CDOSD mode, coloring is performed for each dot. Accordingly, OUT1 outputs to dots
which bit 12 (CRi12) of the color pallet register i is set to “0.”
3: OUT2 cannot be output in sprite OSD.
4: ✕ is an arbitrary value.
Figure 2.16.31 Setting value for controlling OUT1, OUT2 and corresponding output waveform
Rev. 1.0
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2.16.10 Attribute
The attributes (flash, underline, italic fonts) are controlled to the character font. The attributes for each
character are specified by RC14 to RC16 of OSD RAM (refer to Figure 2.16.26). The attributes to be
controlled are different depending on each mode.
CC mode ................... Flash, underline, italic for each character
OSDS/P mode .......... Border (all bordered, shadow bordered can be selected) for each block
(1) Under line
The underline is output at the 23rd and 24th lines in vertical direction only in the CC mode. The
underline is controlled by RC16 of OSD RAM. The color of underline is the same color as that of the
character font.
(2) Flash
The parts of the character font, the underline, and the character background are flashed only in the CC
mode. The flash for each character is controlled by RC15 of OSD RAM. The ON/OFF for flash is
controlled by bit 3 of the OSD control register 1 (refer to Figure 2.16.3). When this bit is “0, ” only
character font and underline flash. When “1,” for a character without solid space output, R, G, B and
OUT1 (all display area) flash, for a character with solid space output, only R, G, and B (all display
area) flash. The flash cycle bases on the VSYNC count.
<NTSC method>
■ When bit 4 = “0”
· VSYNC cycle ✕ 24 ≈ 400 ms (at flash ON)
· VSYNC cycle ✕ 8 ≈ 133 ms (at flash OFF)
■ When bit 4 = “1”
· VSYNC cycle ✕ 48 ≈ 800 ms (at flash ON)
· VSYNC cycle ✕ 8 ≈ 133 ms (at flash OFF)
(3) Italic
The italic is made by slanting the font stored in OSD ROM to the right only in the CC mode. The italic
is controlled by RC14 of OSD RAM.
The display example attribute is shown in Figure 2.16.33. In this case, “R” is displayed.
Notes 1: When setting both the italic and the flash, the italic character flashes.
2: When a flash character (with flash character background) adjoin on the right side of a nonflash italic character, parts out of the non-flash italic character is also flashed.
3: OUT2 is not flashed.
4: When the pre-divide ratio = 1, the italic character with slant of 1 dot ✕ 5 steps is displayed ;
when the pre-divide ratio = 2, the italic character with slant of 1/2 dot ✕ 10 steps is displayed
(refer to Figure 2.16.32 (c), (d)). However, when displaying the italic character with the predivide ratio = 1, set the OSD clock frequency to 11 MHz to 14 MHz.
5: The boundary of character color is displayed in italic. However, the boundary of character
background color is not affected by the italic (refer to Figure 2.16.33).
6: The adjacent character (one side or both side) to an italic character is displayed in italic even
when the character is not specified to display in italic (refer to Figure 2.16.33).
7: When displaying the 32nd character (in 32-character mode)/42nd character (in 42-character
mode) in the italic and when solid space is off (OC14 = “0”), parts out of character area is not
displayed (refer to Figure 2.16.33).
Rev. 1.0
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Color code 1
Color code 1
Bit 6
Bit 4
Bit 6
0
0
1
(a) Ordinary
Bit 4
0
(b) Underline
Color code 1
Color code 1
Bit 6
Bit 4
Bit 6
Bit 4
0
1
0
1
(c) Italic (pre-divide ratio = 1)
(d) Under line and Italic (pre-divide ratio = 2)
Color code
Bit 6
Bit 4
Bit 5
(RC 16) (RC 15) (RC 16)
flash
flash
flash
ON
OFF
1
1
1
ON
OFF
(e) Under line and Italic and flash
Figure 2.16.32 Example of attribute display (in CC mode)
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26th chracter
32nd chracter
(Refer to “12.16.10 Notes 6, 7”)
(Refer to “12.16.10 Notes 5, 6”)
Bit 4 of color
code 1
1
0
0
1
1
0
1
Notes 1 : The dotted line is the boundary of character color.
2 : When bit 4 of OSD control register 1 is “0.”
Figure 2.16.33 Example of italic display
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(4) Border
The border is output in the OSDS/P mode. The all bordered (bordering around of character font) and
the shadow bordered (bordering right and bottom sides of character font) are selected (refer to Figure
2.16.34) by bit 2 of the OSD control register 1 (refer to Figure 2.16.3). The ON/OFF switch for borders
can be controlled in block units by bits 0 to 2 of the block control register i (refer to Figure 2.16.4).
The OUT1 signal is used for border output. The border color is fixed at color palette 8 (block). The
border color for each screen is specified by the border color register i.
The horizontal size (x) of border is 1TC (OSD clock cycle divided in the pre-divide circuit) regardless of
the character font dot size. However, only when the pre-divide ratio = 2 and character size = 1.5TC, the
horizontal size is 1.5TC. The vertical size (y) different depending on the screen scan mode and the
vertical dot size of character font.
Notes 1 : The border dot area is the shaded area as shown in Figure 2.16.36.
2 : When the border dot overlaps on the next character font, the character font has priority
(refer to Figure 2.16.37 A). When the border dot overlaps on the next character back
ground, the border has priority (refer to Figure 2.16.37 B).
3 : The border in vertical out of character area is not displayed (refer to Figure 2.16.38).
All bordered
Shadow bordered
Figure 2.16.34 Example of border display
y
x
Scan mode
Border
dot size
Vertical dot size of
character font
Normal scan mode
1/2H
1/2H, 1H, 2H, 3H
1TC (OSD clock cycle divided in pre-divide circuit)
1.5TC when selecting 1.5TC for character size.
Horizontal size (x)
Vertical size (y)
1H, 2H, 3H
Bi-scan mode
1/2H
1H
1H
Figure 2.16.35 Horizontal and vertical size of border
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OSDS/L/P mode
16 dots
12 dots
20 dots
20 dots
Character
font area
1 dot width of border
1 dot width of border
1 dot width of border
1 dot width of border
Figure 2.16.36 Border area
Character boundary
B
Character boundary
A
Character boundary
B
Figure 2.16.37 Border priority
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2.16.11 Automatic Solid Space Function
This function generates automatically the solid space (OUT1 or OUT2 blank output) of the character area
in the CC mode.
The solid space is output in the following area :
• the character area except character code “00916 ”
•the character area on the left and right sides
This function is turned on and off by bit 4 of the OSD control register 1 (refer to Figure 2.16.3).
OUT1 or OUT2 output is selected by bit 3 of the OSD control register 2.
Notes 1: When selecting OUT1 as solid space output, character background color with solid space
output is fixed to color palette 8 (black) regardless of setting.
2: When selecting any font except blank font as the character code “00916,” the set font is output.
Table 2.16.10 Setting for automatic solid space
0
Bit 4 of OSD control register 1
1
1
0
Bit 3 of OSD control register 2
0
RC17 of OSD RAM
OUT1 output signal
1
0
0
1
0
1
1
•Solid space area
•Character font area
•Character background
area
•Character font area
•Character background
area
0
1
•Character font area
•Character background
area
OUT2 output signal
OFF
•Character
display area
OFF
•Character
display area
OFF
•Solid space
•Character
•Solid space •Character
display area
display area
When setting the character code “00516” as the character A, “00616” as the character B.
(OSD RAM)
005 009 009 009 006 006 •
16
16
16
16
16
• •
16
006
16
(Display screen)
• • •
1st
2nd
character character
No solid space
output
32nd character (in 32-character mode)
42nd character (in 42-character mode)
Figure 2.16.38 Display screen example of automatic solid space
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2.16.12 Particular OSD Mode Block
This function can display with mixing the fonts below within the OSDP mode block.
<horizontal dot structure with vertical dot structure of 20 dots>
• 16 dots
• 12 dots
• 8 dots
• 4 dots
Each font is selected by a character code. Figure 2.16.39 shows the display example of particular OSD
mode block and Table 2.16.11 shows the corresponding between character codes and display fonts.
Note: As for 8 ✕ 20-dot and 4 ✕ 20-dot fonts, only these character background color can be displayed.
And also, any character is not displayed on the right side area nor any following areas of these
fonts.
Any character is not displayed on the right side area nor any following areas of this font.
16 dots
12 dots
16 dots
16 dots
16 dots
16 dots
12 dots
16 dots
16 dots
16 dots
16 dots
12 dots
4 dots
OSDP mode
12 dots
16 dots
16 dots
12 dots
16 dots
16 dots
16 dots
16 dots
OSDP mode
16 dots
16 dots
16 dots
16 dots
16 dots
16 dots
16 dots
16 dots
16 dots
8 dots
OSDP mode
Any character is not displayed on the right side area nor any following areas of this font.
Figure 2.16.39 Display example of OSD mode block
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Table 2.16.11 Corresponding between character codes and display fonts
Character code
Display fonts
Notes
16 dots
(except 10016, 18016,
20016, 28016)
20 dots
00016 to 0EF16,
10016 to 2FF16
12 dots
0F016 to 0FD16
Not displayed
• The left 12-dot part (16 ✕ 12 dots) of set
font is displayed.
20 dots
• In CC and OSDS modes, entire part
(16 ✕ 20 dots) of set font is displayed.
8 dots
• The blank font (only character background)
is displayed.
• Any character is not displayed on the right
side area nor any following areas of this
font.
20 dots
3FE16
• Do not set this font for the 1st character
(left edge) of a block.
4 dots
• The blank font (only character background)
is displayed.
20 dots
3FF16
• Any character is not displayed on the right
side area nor any following areas of this
font.
• Do not set this font for the 1st character
(left edge) of a block.
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2.16.13 Multiline Display
This microcomputer can ordinarily display 16 lines on the CRT screen by displaying 16 blocks at different
vertical positions. In addition, it can display up to 16 lines by using OSD1 interrupts.
An OSD1 interrupt request occurs at the point at which display of each block has been completed. In
other words, when a scanning line reaches the point of the display position (specified by the vertical
position registers) of a certain block, the character display of that block starts, and an interrupt occurs at
the point at which the scanning line exceeds the block. The mode in which an OSD1 interrupt occurs is
different depending on the setting of the OSD control register 2 (refer to Figure 2.16.7).
• When bit 7 of the OSD control register 2 is “0”
An OSD1 interrupt request occurs at the completion of layer 1 block display.
• When bit 7 of the OSD control register 2 is “1”
An OSD1 interrupt request occurs at the completion of layer 2 block display.
Notes 1: An OSD1 interrupt does not occur at the end of display when the block is not displayed. In other
words, if a block is set to off display by the display control bit of the block control register i
(addresses 021016 to 021F16), an OSD1 interrupt request does not occur (refer to Figure
2.16.41 (A)).
2: When another block display appears while one block is displayed, an OSD1 interrupt request
occurs only once at the end of the another block display (refer to Figure 2.16.40 (B)).
3: On the screen setting window, an OSD1 interrupt occurs even at the end of the CC mode block
(off display) out of window (refer to Figure 2.16.40 (C)).
Block 1 (on display)
Block 2 (on display)
“OSD1 interrupt request”
“OSD1 interrupt request”
Block 3 (on display)
Block 1 (on display)
“OSD1 interrupt request”
Block 2 (on display)
“OSD1 interrupt request”
Block 3 (off display)
No
“OSD1 interrupt request”
“OSD1 interrupt request”
Block 4 (on display)
Block 4 (off display)
No
“OSD1 interrupt request”
“OSD1 interrupt request”
On display (OSD1 interrupt request occurs
at the end of block display)
Off display (OSD1 interrupt request does
not occur at the end of block display)
(A)
Block 1
“OSD1 interrupt request”
Block 1
Block 2
No
“OSD1 interrupt request”
Block 2
“OSD1 interrupt request”
“OSD1 interrupt request”
Block 3
“OSD1 interrupt request”
Window
(B)
(C)
Figure 2.16.40 Note on occurrence of OSD1 interrupt
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2.16.14 SPRITE OSD Function
This is especially suitable for cursor and other displays as its function allows for display in any position,
regardless of the validity of block OSD displays or display positions. SPRITE font consists of 2 characters: SPRITE fonts 1 and 2. Each SPRITE font is a RAM font consisting of 32 horizontal dots ✕ 20 vertical
dots, 4 planes, and 4 bits of data per dot. Each plane has corresponding color palette selection bit, and
16 kinds of color palettes can be selected by the plane bit combination (three bits) for each dot. The color
palette is set in dot units according to the OSD RAM (SPRITE) contents from among the selection range.
It is possible to add arbitrary font data by software as the SPRITE fonts consist of RAM font.
The SPRITE OSD control register can control SPRITE display and dot size. The display position can
also be set independently of the block display by the SPRITE horizontal position registers and the sprite
horizontal vertical position registers. The vertical fonts 1 and 2 can be set independently. An OSD interrupt request occurs at each completion of font display. The horizontal position is set in 2048 steps in
2TOSC units, and the vertical position is set in 1024 steps in 1TH units.
When SPRITE display overlaps with other OSD displays, SPRITE display is always given priority. However, the SPRITE display overlaps with the display which includes OUT2 output, OUT2 in the OSD is
output without masking.
Notes 1: The SPRITE OSD function cannot output OUT2.
2: When using SPRITE OSD, do not set HS ≤ “00316”, HS ≥ “80016.”
3: When using SPRITE OSD, do not set VSi = “00016,” VSi ≥ “40016.”
4: When displaying with SPRITE fonts 1 and 2 overlapped, the SPRITE font with a larger set value
as the vertical display start position is displayed. When the set values of the vertical display
start position are the same, the SPRITE font 1 is displayed.
dot
1
......
dot dot
16 17
......
dot
32
Line 1
......
SPRITE font 1
Video adjustment
Tint
Contrast
Color tone
Picture
Brightness
Line 20
Line 1
–••|••+
–••|••+
–••|••+
–••|••+
–••|••+
......
SPRITE font 2
Example of SPRITE display
Line 20
Example of SPRITE font
Figure 2.16.41 SPRITE OSD display example
Rev. 1.0
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SPRITE OSD control register
Symbol
SC
b7 b6 b5 b4 b3 b2 b1 b0
Bit symbol
Address
020116
When reset
XXX000002
Bit name
Function
SC0
SPRITE font 1
control bit
0: Do not display
1: Display
SC1
Pre-divide ratio
selection bit
0: Pre-divide ratio 1
1: Pre-divide ratio 2
SC2
Dot size selection
bits
b3
SC3
SC4
SPRITE font 2
control bit
0
0
1
1
R W
b2
0: 1Tc ✕ 1/2H
1: 1Tc ✕ 1H
0: 2Tc ✕ 1H
1: 2Tc ✕ 2H
0: Do not display
1: Display
Nothing is assigned.
In an attempt to write to these bits, write “0.”
The value, if read, turns out to be “0.”
Notes 1: Tc is OSD clock cycle divided in pre-divide circuit.
2: H is HSYNC
Figure 2.16.42 SPRITE OSD control register
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SPRITE horizontal position register
(b15)
(b8)
b7 b6 b5 b4 b3 b2 b1 b0 b7 b6 b5 b4 b3 b2 b1 b0
Symbol
HS
Address
027916, 027816
Bit symbol
Bit name
HS10 to HS0
Horizontal display start
position control bits of
SPRITE font
When reset
Indeterminate
Function
R W
Horizontal display start position = 2TOSC ✕ n
(n: setting value, TOSC: OSD oscillation cycle)
Nothing is assined.
In an attempt to write to this bit, write “0.”
The value, if read, turns out to be indeterminate.
Note : Do not set HS ≤ “00316,” HS ≥ “80016.”
Figure 2.16.43 SPRITE horizontal position register
SPRITE vertical position register i
(b15)
(b8)
b7 b6 b5 b4 b3 b2 b1 b0 b7 b6 b5 b4 b3 b2 b1 b0
Symbol
VS1
VS2
Bit symbol
VSi9 to VSi0
Address
027516, 027416
027716, 027616
Bit name
Vertical display start
position control bits of
SPRITE font i (i = 1, 2)
When reset
Indeterminate
Indeterminate
Function
R W
Vertical display start position = TH ✕ n
(n: setting value, TH: HSYNC cycle)
Nothing is assined.
In an attempt to write to this bit, write “0.”
The value, if read, turns out to be indeterminate.
Note : Do not set VSi = “00016,” VSi ≥ “40016” (i = 1, 2).
Figure 2.16.44 SPRITE vertical position register i (i = 1, 2)
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2.16.15 Window Function
The window function can be set windows on-screen and output OSD within only the area where the
window is set.
The ON/OFF for vertical window function is performed by bit 5 of the OSD control register 1 and is used
to select vertical window function or vertical blank function by bit 6 of the OSD control register 2. Accordingly, the vertical window function cannot be used simultaneously with the vertical blank function. The
display mode to validate the window function is selected by bits 5 to 7 of the OSD control register 3. The
top border is set by the top border control register (TBR) and the bottom border is set by the bottom
border control register (BBR).
The ON/OFF for horizontal window function is performed by bit 4 of the OSD control register 2 and is
used interchangeably for the horizontal blank function with bit 5 of the OSD control register 2. Accordingly, the horizontal blank function cannot be used simultaneously with the horizontal window function.
The display mode to validate the window function is selected by bits 5 to 7 of the OSD control register 3.
The left border is set by the left border control register (LBR), and the right border is set by the right
border control register (RBR).
Notes 1: Horizontal blank and horizontal window, as well as vertical blank and vertical window can not be
used simultaneously.
2: When the window function is ON by OSD control registers 1 and 2, the window function of
OUT2 is valid in all display mode regardless of setting value of the OSD control register 3 (bits
5 to 7). For example, even when make the window function valid in only CC mode, the function
of OUT2 is valid in OSDS/L/P and CDOSD modes.
3: As for SPRITE display, the window function does not operate.
Left border
of window
Right border
of window
Window
Top border
of window
A B C D E
F
G H
K L
I
CDOSD mode
J
M N O
CC mode
Window
P Q R S T
U V W X Y
OSDS/L/P mode
Bottom border
of window
Screen
Figure 2.16.45 Example of window function (When CC mode is valid)
Rev. 1.0
213
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
2.16.16 Blank Function
The blank function can output blank (OUT1) area on all sides (vertical and horizontal) of the screen. This
provides the blank signal, wipe function, etc., when outputting a 3 : 4 image on a wide screen.
The ON/OFF for vertical blank function is performed by bit 5 of the OSD control register 1 and is used to
select vertical window function or vertical blank function by bit 6 of the OSD control register 2. Accordingly, the vertical blank function cannot be used simultaneously with the vertical window function. The top
border is set by the top border control register (TBR), and the bottom border is set by the bottom border
control register (BBR), in 1H units.
The ON/OFF for horizontal blank function is performed by bit 4 of the OSD control register 2 and is used
interchangeably for the horizontal window function with bit 5 of the OSD control register 2 . Accordingly,
the horizontal blank function cannot be used simultaneously with the horizontal window function. The left
border is set by the left border control register (LBR) and the right border is set by the right border control
register (RBR), in 4TOSC units.
The OSD output (except raster) in area with blank output is not deleted.
These blank signals are not output in the horizontal/vertical blanking interval.
Notes 1. Horizontal blank and horizontal window, as well as vertical blank and vertical window can not be
used simultaneously.
2. When using the window function, be sure to set “1” to bit 0 of OSD control register 1.
A
OUT1 B
A
4
Blank output
signal in
microcomputer
4
A'
H
OUT1
L
H
B
L
Blank output
signal in
microcomputer
H
A'
L
Output example of horizontal blank
L H L H
L H
Output example of top and vertical blank
Figure 2.16.46 Blank output example (when OSD output is B + OUT1)
Rev. 1.0
214
MITSUBISHI MICROCOMPUTERS
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M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
Top border control register
(b15)
(b8)
b7 b6 b5 b4 b3 b2 b1 b0 b7 b6 b5 b4 b3 b2 b1 b0
Symbol
TBR
Bit symbol
Address
020D16, 020C16
Bit name
When reset
Indeterminate
Function
TBR_9 to TBR_0 Top border control bits
R W
Top border position = TH ✕ n
(n: setting value, TH: HSYNC cycle)
Nothing is assined.
In an attempt to write to this bit, write “0.”
The value, if read, turns out to be indeterminate.
Notes 1 : Do not set TBR ≤ “00116,” TBR ≥ “40016.”
2 : Set as TBR < BBR.
Figure 2.16.47 Top border control register
Bottom border control register
(b15)
(b8)
b7 b6 b5 b4 b3 b2 b1 b0 b7 b6 b5 b4 b3 b2 b1 b0
Symbol
BBR
Bit symbol
Address
020F16, 020E16
Bit name
When reset
Indeterminate
Function
R W
BBR_9 to BBR_0 Bottom border control bits Bottom border position = TH ✕ n
(n: setting value, TH: HSYNC cycle)
Nothing is assined.
In an attempt to write to this bit, write “0.”
The value, if read, turns out to be indeterminate.
Notes 1 : Do not set BBR ≥ “40016.”
2 : Set as TBR < BBR.
Figure 2.16.48 Bottom border control register
Rev. 1.0
215
MITSUBISHI MICROCOMPUTERS
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
Left border control register
(b15)
(b8)
b7 b6 b5 b4 b3 b2 b1 b0 b7 b6 b5 b4 b3 b2 b1 b0
Symbol
LBR
Bit symbol
Address
027116, 027016
Bit name
When reset
XXXXX000000000012
Function
LBR_10 to LBR_0 Left border control bits
R W
Left border position = 4TOSC ✕ n
(n: setting value, TOSC: OSD oscillation cycle)
Nothing is assined.
In an attempt to write to this bit, write “0.”
The value, if read, turns out to be indeterminate.
Notes 1 : Do not set LBR ≤ “00316,” LBR ≥ “80016.”
2 : Set as LBR < RBR.
Figure 2.16.49 Left border control register
Right border control register
(b15)
(b8)
b7 b6 b5 b4 b3 b2 b1 b0 b7 b6 b5 b4 b3 b2 b1 b0
Symbol
RBR
Bit symbol
Address
027316, 027216
Bit name
RBR_10 to RBR_0 Right border control bits
When reset
XXXXX000000000002
Function
R W
Left border position = 4TOSC ✕ n
(n: setting value, TOSC: OSD oscillation cycle)
Nothing is assined.
In an attempt to write to this bit, write “0.”
The value, if read, turns out to be indeterminate.
Notes 1 : Do not set RBR ≥ “80016.”
2 : Set as LBR < RBR.
Figure 2.16.50 Bottom border control register
Rev. 1.0
216
MITSUBISHI MICROCOMPUTERS
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
2.16.17 Raster Coloring Function
An entire screen (raster) can be colored by setting the bits 6 to 0 of the raster color register. Since each of
the R, G, B, OUT1, and OUT2 pins can be switched to raster coloring output, 512 raster colors can be
obtained.
When the character color/the character background color overlaps with the raster color, the color (R, G,
B, OUT1, OUT2), specified for the character color/the character background color, takes priority of the
raster color. This ensures that the character color/the character background color is not mixed with the
raster color.
The raster color register is shown in Figure 2.16.51, the example of raster coloring is shown in Figure
2.16.52.
Note: Raster is not output to the area which includes blank area.
Raster color register
(b15)
(b8)
b7 b6 b5 b4 b3 b2 b1 b0 b7 b6 b5 b4 b3 b2 b1 b0
Symbol
RSC
Bit symbol
Address
020916, 020816
Bit name
RSC2 to RSC0 R singnal output
control bits
When reset
000016
Function
R W
b2 b1 b0
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0 : VSS
1 : 1/7VCC
0 : 2/7VCC
1 : 3/7VCC
0 : 4/7VCC
1 : 5/7VCC
0 : 6/7VCC
1 : VCC
Nothing is assined.
In an attempt to write to this bit, write “0.”
The value, if read, turns out to be indeterminate.
RSC6 to RSC4 G singnal output
control bits
b6 b5 b4
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0 : VSS
1 : 1/7VCC
0 : 2/7VCC
1 : 3/7VCC
0 : 4/7VCC
1 : 5/7VCC
0 : 6/7VCC
1 : VCC
Nothing is assined.
In an attempt to write to this bit, write “0.”
The value, if read, turns out to be indeterminate.
RSC10 to RSC8 B singnal output
control bits
b10 b9 b8
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0 : VSS
1 : 1/7VCC
0 : 2/7VCC
1 : 3/7VCC
0 : 4/7VCC
1 : 5/7VCC
0 : 6/7VCC
1 : VCC
Nothing is assined.
In an attempt to write to this bit, write “0.”
The value, if read, turns out to be indeterminate.
RSC12
OUT1 singnal output
control bit
0: No output
1: Output
RSC13
OUT2 singnal output
control bit
0: No output
1: Output
Nothing is assined.
In an attempt to write to this bit, write “0.”
The value, if read, turns out to be indeterminate.
Figure 2.16.51 Raster color register
Rev. 1.0
217
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
: Character color “RED” (R and OUT1)
: Border color “BLACK” (OUT1)
: Background color “MAGENTA” (R, B and OUT1)
: Raster color “BLUE” (B and OUT1)
A
A'
HSYNC
OUT1
Signals
across
A-A'
R
G
B
<At horizontal blank output>
: Character color “RED” (R and OUT1)
: Border color “BLACK” (OUT1)
: Background color “MAGENTA” (R, B and OUT1)
: Raster color “BLUE” (B and OUT1)
: Horizontal blank (OUT1)
A
A'
HSYNC
OUT1
R
G
Signals
across
A-A'
B
Blank control
signal in
microcomputer
Figure 2.16.52 Example of raster coloring
Rev. 1.0
218
MITSUBISHI MICROCOMPUTERS
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
2.16.18 Scan Mode
This microcomputer has the bi-scan mode for corresponding to HSYNC of double speed frequency. In the
bi-scan mode, the vertical start display position and the vertical size is two times as compared with the
normal scan mode. The scan mode is selected by bit 1 of the OSD control register 1 (refer to Figure
2.16.3).
Table 2.16.12 Setting for scan mode
Scan Mode
Parameter
Bit 1 of OSD control register 1
Vertical display start position
Normal Scan
Bi-Scan
0
1
Value of vertical position register ✕ 1H
Value of vertical position register ✕ 2H
Vertical dot size
1TC ✕ 1/2H
1TC ✕ 1H
1TC ✕ 1H
1TC ✕ 2H
2TC ✕ 2H
2TC ✕ 4H
3TC ✕ 3H
3TC ✕ 6H
2.16.19 R, G, B Signal Output Control
The form of R, G, B signal output is controlled by bit 2 of the OSD control register 2 as the table below.
Table 2.16.13 R, G, B signal output control
Bit 2 of OSD control register 2
Form of R, G, B signal output
0
Each R, G, B pin outputs 2 values (digital output).
1
Each R, G, B pin outputs 8 values (analog output).
Rev. 1.0
219
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
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2.16.20 OSD Reserved Register
OSD reserved register i (i=1, 2)
b7
b6
0
0 0 0 0
b5
b4
b3
b2
b1
0 0
b0
0
Symbol
Address
When reset
OR1
OR2
025D16
027C16
0016
0016
Bit symbol
Bit name
Reserved bits
Description
R
W
Mest always be sed to “0”
Figure 2.16.53 OSD reserved register i (i=1, 2)
OSD reserved register 3
b7
b6
0
0 0 0 0
b5
b4
b3
b2
b1
0 0
b0
0
Symbol
Address
When reset
OR3
027B16
XX0000002
Bit symbol
Bit name
Description
Reserved bits
Mest always be set to “0”
Reserved bits
Mest always be set to “0”
R
W
R
W
Figure 2.16.54 OSD reserved register 3
OSD reserved register 4
b7
b6
0 0
b5
b4
b3
0 0 0
b2
b1
0 0
b0
1
Symbol
Address
When reset
OR4
027A16
XX0000002
Bit symbol
Bit name
Description
Reserved bit
Mest always be set to “1”
Reserved bits
Mest always be set to “0”
Reserved bit
Mest always be set to “0”
Figure 2.16.55 OSD reserved register 4
Rev. 1.0
220
MITSUBISHI MICROCOMPUTERS
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
2.17 Programmable I/O Ports
There are 46 programmable I/O ports: P00–P07, P20–P27, P30–P37, P40–P43, P50, P52, P53, P62, P63,
P67, P70–P72, P74, P76, P82, P90, P93, P94, P100 and P101. Each port can be set independently for input
or output using the direction register. A pull-up resistance for each block of 4 ports can be set.
Figures 2.17.1 to 2.17.3 show the programmable I/O ports.
Each pin functions as a programmable I/O port and as the I/O for the built-in peripheral devices.
To use the pins as the inputs for the built-in peripheral devices, set the direction register of each pin to input
mode. When the pins are used as the outputs for the built-in peripheral devices (other than the D-A converter), they function as outputs regardless of the contents of the direction registers. When pins are to be
used as the outputs for the D-A converter, do not set the direction registers to output mode. See the
descriptions of the respective functions for how to set up the built-in peripheral devices.
2.17.1 Direction Registers
Figures 2.17.5 to 2.17.12 show the direction registers.
These registers are used to choose the direction of the programmable I/O ports. Each bit in these registers corresponds one for one to each I/O pin.
(1) Effect of the protection register
Data written to the direction register of P9 is affected by the protection register. The direction register
of P9 cannot be easily written.
2.17.2 Port Registers
Figures 2.17.13 to 2.17.20 show the port registers.
These registers are used to write and read data for input and output to and from an external device. A
port register consists of a port latch to hold output data and a circuit to read the status of a pin. Each bit
in port registers corresponds one for one to each I/O pin.
(1) Reading a port register
With the direction register set to output, reading a port register takes out the content of the port register, not the content of the pin. With the direction register set to input, reading the port register takes out
the content of the pin.
(2) Writing to a port register
With the direction register set to output, the level of the written values from each relevant pin is output
by writing to a port register. Writing to the port register, with the direction register set to input, inputs a
value to the port register, but nothing is output to the relevant pins. The output level remains floating.
Rev. 1.0
221
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2.17.3 Pull-up Control Registers
Figures 2.17.24 to 2.17.26 show the pull-up control registers.
The pull-up control register can be set to apply a pull-up resistance to each block of 4 ports. When ports
are set to have a pull-up resistance, the pull-up resistance is connected only when the direction register is
set for input.
Rev. 1.0
222
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
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Pull-up selection
Direction register
P00–P07,
P20–P27,
P30–P32,
P50–P53
Data bus
Port latch
(Note)
Pull-up selection
Direction register
P34, P35,
P62,
P90,
P100, P101
Data bus
Port latch
(Note)
Input to respective peripheral functions
Pull-up selection
P33, P82
Direction register
Data bus
Port latch
(Note)
Input to respective peripheral functions
Note :
symbolizes a parasitics diode.
Do not apply a voltage higher than Vcc each port.
Figure 2.17.1 Programmable I/O ports (1)
Rev. 1.0
223
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Pull-up selection
Direction register
P63,
P74, P76
“1”
Output
Data bus
Port latch
(Note)
Pull-up selection
Direction register
P55
“1”
Output
Data bus
Port latch
(Note)
Input to respective peripheral functions
Direction register
P70, P71
“1”
Output
Data bus
Port latch
(Note)
Input to respective peripheral functions
Note:
symbolizes a parasitics diode.
Do not apply a voltage higher than Vcc each port.
Figure 2.17.2 Programmable I/O ports (2)
Rev. 1.0
224
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Pull-up selection
P36, P37,
P40–P43
Direction register
Port latch
Data bus
(Note)
Analog input
SDA3, SCL3 select
Pull-up selection
D-A output enabled
Direction register
P93,P94
“1”
Output
Data bus
Port latch
(Note)
Input to respective peripheral functions
Analog output
D-A output enabled
SDA2, SCL2 select
P67, P72
Pull-up selection
Direction register
“1”
Output
Data bus
Port latch
(Note)
Input to respective peripheral functions
Note:
symbolizes a parasitics diode.
Do not apply a voltage higher than Vcc each port.
Figure 2.17.3 Programmable I/O ports (3)
Rev. 1.0
225
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SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
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R, G, B
OUT1, OUT2
Internal circuit
.....
Internal circuit
.....
(Note)
.....
(Note)
Notes1:
(Note 2)
CNVSS
CNVSS signal input
(Note 1)
RESET
RESET signal input
(Note 1)
symbolizes a parasitic diode.
Don't apply a voltage higher than Vcc to each pin.
2: A parasitic diode on the V CC side is added to the mask ROM version.
Don't apply a voltage higher than Vcc to each pin.
Figure 2.17.4 I/O pins
Rev. 1.0
226
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Port Pi direction register
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
PDi (i = 0, 2, 3)
Bit symbol
Address
03E216, 03E616, 03E716,
Bit name
PDi_0
Port Pi0 direction register
PDi_1
Port Pi1 direction register
PDi_2
Port Pi2 direction register
PDi_3
Port Pi3 direction register
PDi_4
Port Pi4 direction register
PDi_5
Port Pi5 direction register
PDi_6
Port Pi6 direction register
PDi_7
Port Pi7 direction register
When reset
0016
Function
RW
0 : Input mode
(Functions as an input port)
1 : Output mode
(Functions as an output port)
(i = 0, 2, 3)
Figure 2.17.5 Port Pi direction register (i = 0, 2, 3)
Port P4 direction register
b7
b6
b5
b4
1 1 1 1
b3
b2
b1
b0
Symbol
PD4
Address
03EA 16
When reset
00 16
Bit symbol
Bit name
Function
PD4_0
Port P4 0 direction register
PD4_1
Port P4 1 direction register
PD4_2
Port P4 2 direction register
0 : Input mode
(Functions as an input port)
1 : Output mode
(Functions as an output port)
PD4_3
Port P4 3 direction register
Reserved bits
RW
Must always be set to “1”
Figure 2.17.6 Port P4 direction register
Rev. 1.0
227
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Port P5 direction register
b7
b6
b5
1 1
b4
b3
b2
1
b1
b0
1
Symbol
PD5
Address
03EB 16
When reset
00 16
Bit symbol
Bit name
Function
Port P5 0 direction register
0 : Input mode
(Functions as an input port)
1 : Output mode
(Functions as an output port)
PD5_0
Must always be set to “1”
Reserved bit
PD5_2
Port P5 2 direction register
PD5_3
Port P5 3 direction register
0 : Input mode
(Functions as an input port)
1 : Output mode
(Functions as an output port)
Must always be set to “1”
Reserved bit
PD5_5
RW
Port P5 5 direction register
0 : Input mode
(Functions as an input port)
1 : Output mode
(Functions as an output port)
Must always be set to “1”
Reserved bits
Figure 2.17.7 Port P5 direction register
Port P6 direction register
b7
b6
b5
b4
1 1 1
b3
b2
b1
b0
0 1
Symbol
PD6
Address
03EE 16
Bit symbol
Bit name
When reset
00 16
Function
Reserved bit
Must always be set to “1”
Reserved bit
Must always be set to “0”
PD6_2
Port P6 2 direction register
PD6_3
Port P6 3 direction register
0 : Input mode
(Functions as an input port)
1 : Output mode
(Functions as an output port)
Must always be set to “1”
Reserved bit
PD6_7
RW
Port P6 7 direction register
0 : Input mode
(Functions as an input port)
1 : Output mode
(Functions as an output port)
Figure 2.17.8 Port P6 direction register
Rev. 1.0
228
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and ON-SCREEN DISPLAY CONTROLLER
Port P7 direction register
b7
b6
0
b5
b4
0
b3
b2
b1
b0
1
Symbol
PD7
Address
03EF16
Bit symbol
When reset
0016
Bit name
Function
PD7_0
Port P7 0 direction register
PD7_1
Port P7 1 direction register
PD7_2
Port P7 2 direction register
0 : Input mode
(Functions as an input port)
1 : Output mode
(Functions as an output port)
Must always be set to “1”
Reserved bit
PD7_4
Port P7 4 direction register
0 : Input mode
(Functions as an input port)
1 : Output mode
(Functions as an output port)
Must always be set to “0”
Reserved bit
PD7_6
RW
Port P7 6 direction register
0 : Input mode
(Functions as an input port)
1 : Output mode
(Functions as an output port)
Must always be set to “0”
Reserved bit
Figure 2.17.9 Port P7 direction register
Port P8 direction register
b7
b6
1 1
b5
b4
b3
1 0
b2
b1
b0
0 0
Symbol
PD8
Address
03F2 16
Bit symbol
Bit name
Function
RW
Must always be set to “0”
Reserved bits
PD8_2
When reset
00X00000 2
Port P8 2 direction register
0 : Input mode
(Functions as an input port)
1 : Output mode
(Functions as an output port)
Reserved bit
Must always be set to “0”
Reserved bit
Must always be set to “1”
Nothing is assigned.
In an attempt to write to these bits, write “0.”
The value, if read, turns out to be indeterminate.
Reserved bits
Must always be set to “1”
Figure 2.17.10 Port P8 direction register
Rev. 1.0
229
MITSUBISHI MICROCOMPUTERS
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and ON-SCREEN DISPLAY CONTROLLER
Port P9 direction register
b7
b6
b5
b4
b3
1 1 1
b2
b1
b0
1 1
Symbol
PD9
Address
03F3 16
Bit symbol
PD9_0
When reset
00 16
Bit name
Function
Port P9 0 direction register
0 : Input mode
(Functions as an input port)
1 : Output mode
(Functions as an output port)
RW
Must always be set to “1”
Reserved bits
PD9_3
Port P9 3 direction register
PD9_4
Port P9 4 direction register
0 : Input mode
(Functions as an input port)
1 : Output mode
(Functions as an output port)
Must always be set to “1”
Reserved bits
Figure 2.17.11 Port P9 direction register
Port P10 direction register
b7
b6
b5
b4
b3
b2
0 0 0 0 0 0
b1
b0
Symbol
PD10
Address
03F6 16
When reset
0016
Bit symbol
Bit name
Function
PD10_0
PD10_1
RW
Port P10 0 direction register 0 : Input mode
(Functions as an input port)
1 : Output mode
Port P10 1 direction register
(Functions as an output port)
Reserved bits
Must always be set to “0”
Figure 2.17.12 Port P10 direction register
Rev. 1.0
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Port Pi register
b7
b6
b5
b4
b3
b2
b1
b0
Symbol
Pi (i = 0, 2, 3)
Bit symbol
Address
03E016, 03E416, 03E516
Bit name
Pi_0
Port Pi0 register
Pi_1
Port Pi1 register
Pi_2
Port Pi2 register
Pi_3
Port Pi3 register
Pi_4
Pi_5
Port Pi4 register
Port Pi5 register
Pi_6
Port Pi6 register
Pi_7
Port Pi7 register
When reset
Indeterminate
Function
RW
Data is input and output to and from
each pin by reading and writing to
and from each corresponding bit
0 : “L” level data
1 : “H” level data
(i = 0, 2, 3)
Figure 2.17.13 Port Pi register (i = 0, 2, 3)
Port P4 register
b7
b6
0
0
b5
b4
0 0
b3
b2
b1
b0
Symbol
P4
Bit symbol
Address
03E8 16
Bit name
P4_0
Port P4 0 register
P4_1
Port P4 1 register
P4_2
Port P4 2 register
P4_3
Port P4 3 register
Reserved bits
When reset
Indeterminate
Function
R W
Data is input and output to and from
each pin by reading and writing to
and from each corresponding bit
0 : “L” level data
1 : “H” level data
Must always be set to “0”
Figure 2.17.14 Port P4 register
Rev. 1.0
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Port P5 register
b7
b6
0
0
b5
b4
b3
b2
0
b1
b0
Symbol
P5
0
Address
03E9 16
Bit symbol
P5_0
Bit name
When reset
Indeterminate
Function
Port P5 0 register
Data is input and output to and from
each pin by reading and writing to
and from each corresponding bit
0 : “L” level data
1 : “H” level data
P5_2
Port P5 2 register
P5_3
Port P5 3 register
Data is input and output to and from
each pin by reading and writing to
and from each corresponding bit
0 : “L” level data
1 : “H” level data
Must always be set to “0”
Reserved bit
Must always be set to “0”
Reserved bit
P5_5
R W
Port P5 5 register
Data is input and output to and from
each pin by reading and writing to
and from each corresponding bit
0 : “L” level data
1 : “H” level data
Must always be set to “0”
Reserved bits
Figure 2.17.15 Port P5 register
Port P6 register
b7
b6
b5
0
0 0
b4
b3
b2
b1
b0
0
0
Symbol
P6
Bit symbol
Address
03EC 16
Bit name
Function
R W
Must always be set to “0”
Reserved bits
P6_2
Port P6 2 register
P6_3
Port P6 3 register
Data is input and output to and from
each pin by reading and writing to
and from each corresponding bit
0 : “L” level data
1 : “H” level data
Must always be set to “0”
Reserved bit
P6_7
When reset
Indeterminate
Port P6 7 register
Data is input and output to and from
each pin by reading and writing to
and from each corresponding bit
0 : “L” level data
1 : “H” level data
Figure 2.17.16 Port P6 register
Rev. 1.0
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Port P7 register
b7
b6
0
b5
b4
0
b3
b2
b1
b0
0
Symbol
P7
Bit symbol
Address
03ED 16
Bit name
P7_0
Port P7 0 register
P7_1
Port P7 1 register
P7_2
Port P7 2 register
Port P7 4 register
R W
Data is input and output to and from
each pin by reading and writing to
and from each corresponding bit
0 : “L” level data
1 : “H” level data
Must always be set to “0”
Reserved bit
P7_6
Function
Data is input and output to and from
each pin by reading and writing to
and from each corresponding bit
0 : “L” level data
1 : “H” level data
Must always be set to “0”
Reserved bit
P7_4
When reset
Indeterminate
Port P7 6 register
Data is input and output to and from
each pin by reading and writing to
and from each corresponding bit
0 : “L” level data
1 : “H” level data
Must always be set to “0”
Reserved bit
Note: Since P7 0 and P7 1 are N-channel open-drain ports, the data is high-impedance.
Figure 2.17.17 Port P7 register
Port P8 register
b7
b6
b5
b4
b3
0
0
0 0
0
b2
b1
b0
0
0
Symbol
P8
Bit symbol
Address
03F0 16
Bit name
Reserved bits
Function
R W
Must always be set to “0”
Reserved bits
P8_2
When reset
Indeterminate
Port P8 2 register
Data is input and output to and from
each pin by reading and writing to
and from each corresponding bit
0 : “L” level data
1 : “H” level data
Must always be set to “0”
Figure 2.17.18 Port P8 register
Rev. 1.0
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Port P9 register
b7
b6
0
0 0
b5
b4
b3
b2
b1
0
0
b0
Symbol
P9
Bit symbol
P9_0
Address
03F1 16
Bit name
Port P9 0 register
When reset
Indeterminate
Function
R W
Data is input and output to and from
each pin by reading and writing to
and from each corresponding bit
0 : “L” level data
1 : “H” level data
Must always be set to “0”
Reserved bits
P9_3
Port P9 3 register
P9_4
Port P9 4 register
Reserved bits
Data is input and output to and from
each pin by reading and writing to
and from each corresponding bit
0 : “L” level data
1 : “H” level data
Must always be set to “0”
Figure 2.17.19 Port P9 register
Port P10 register
b7
b6
0
0 0
b5
b4
b3
b2
0 0
0
b1
b0
Symbol
P10
Bit symbol
Address
03F4 16
Bit name
P10_0
Port P10 0 register
P10_1
Port P10 1 register
Reserved bits
When reset
Indeterminate
Function
R W
Data is input and output to and from
each pin by reading and writing to
and from each corresponding bit
0 : “L” level data
1 : “H” level data
Must always be set to “0”
Figure 2.17.20 Port P10 register
Rev. 1.0
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Port reserved register 1
b7
b6
0 0
b5
b4
0 0
b3
b2
0 0
b1
b0
Symbpl
PR1
0 0
Bit symbol
Address
03E1 16
When reset
Indeterminate
Bit name
Reserved bits
Function
R W
Must always be set to “0”
Figure 2.17.21 Port reserved register 1
Port reserved register 2
b7
b6
1 1
b5
b4
1 1
b3
b2
1 1
b1
b0
Symbpl
PR2
1 1
Bit symbol
Address
03E3 16
When reset
0016
Bit name
Reserved bits
Function
R W
Must always be set to “1”
Figure 2.17.22 Port reserved register 2
Port reserved register 3
b7
b6
b5
b4
b3
b2
b1
b0
0
Symbpl
PR3
Bit symbol
Address
03FF 16
Bit name
Reserved bit
When reset
0016
Function
R W
Must always be set to “0”
Nothing is assigned.
In an attempt to write to this bit, write “0.”
The value, if read, turns out to be “0.”
Figure 2.17.23 Port reserved register 3
Rev. 1.0
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Pull-up control register 0
b7
b6
b5
b4
b3
b2
0
0
b1
b0
Symbol
PUR0
Bit symbol
Address
03FC 16
Bit name
PU00
P00 to P0 3 pull-up
PU01
P04 to P0 7 pull-up
Reserved bits
When reset
0016
Function
RW
The corresponding port is pulled
high with a pull-up resistor
0 : Not pulled high
1 : Pulled high
Must always be set to “0”
PU04
P20 to P2 3 pull-up
PU05
P24 to P2 7 pull-up
PU06
P30 to P3 3 pull-up
PU07
P34 to P3 7 pull-up
Figure 2.17.24 Pull-up control register 0
Pull-up control register 1
b7
b6
b5
b4
b3
b2
b1
0
b0
Symbol
PUR1
Address
03FD 16
Bit symbol
PU10
Bit name
When reset
0016
Function
P40 to P4 3 pull-up
The corresponding port is pulled
high with a pull-up resistor
0 : Not pulled high
1 : Pulled high
PU12
PU13
P50, P52, P53 pull-up
P55 pull-up
PU14
P62, P63 pull-up
The corresponding port is pulled
high with a pull-up resistor
0 : Not pulled high
1 : Pulled high
PU15
P67 pull-up(Note 2)
Reserved bit
R W
Must always be set to “0”
PU16
P72 pull-up (Note 2)
PU17
P74, P76 pull-up
Notes 1: Since P7 0 and P7 1 are N-channel open drain ports, pull-up is not available for them.
2: Pull-up is not available for P6 7 and P7 2, when they are used as I 2C-BUS interface
ports.
Figure 2.17.25 Pull-up control register 1
Rev. 1.0
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Pull-up control register 2
b7
b6
b5
b4
0 0
b3
b2
b1
0
b0
Symbol
PUR2
Address
03FE 16
Bit symbol
Bit name
PU20
P82 pull-up
Reserved bit
When reset
00 16
Function
R W
The corresponding port is pulled
high with a pull-up resistor
0 : Not pulled high
1 : Pulled high
Must always be set to “0”
PU22
P90, P93 pull-up
PU23
P94 pull-up
Reserved bits
The corresponding port is pulled
high with a pull-up resistor
0 : Not pulled high
1 : Pulled high
Must always be set to “0”
Nothing is assigned.
In an attempt to write to these bits, write “0.”
The value, if read, turns out to be “0.”
Figure 2.17.26 Pull-up control register 2
Rev. 1.0
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Table 2.17.1 Example connection of unused pins in single-chip mode
Pin name
Connection
Ports P0, P2 to P10
After setting for input mode, connect every pin to VSS or VCC via a
resistor; or after setting for output mode, leave these pins open.
XOUT (Note)
Open
AVCC
Connect to VCC
CNVSS
Connect via resistor to VSS (pull-down)
Note: With external clock input to XIN pin.
Microcomputer
Port P0 to P10
(Input mode)
·
·
·
(Input mode)
(Output mode)
XOUT
·
·
·
Open
Open
VCC
AVCC
0.47 µF
CNVSS
VSS
In single-chip mode
Figure 2.17.27 Example connection of unused pins
Rev. 1.0
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3. USAGE PRECAUTION
3.1 Timer A (timer mode)
(1) Reading the timer Ai register while a count is in progress allows reading, with arbitrary timing, the
value of the counter. Reading the timer Ai register with the reload timing gets “FFFF16”. Reading
the timer Ai register after setting a value in the timer Ai register with a count halted but before the
counter starts counting gets a proper value.
3.2 Timer A (event counter mode)
(1) Reading the timer Ai register while a count is in progress allows reading, with arbitrary timing, the
value of the counter. Reading the timer Ai register with the reload timing gets “FFFF16” by underflow or “000016” by overflow. Reading the timer Ai register after setting a value in the timer Ai
register with a count halted but before the counter starts counting gets a proper value.
(2) When stop counting in free run type, set timer again.
3.3 Timer A (one-shot timer mode)
(1) Setting the count start flag to “0” while a count is in progress causes as follows:
• The counter stops counting and a content of reload register is reloaded.
• The TAiOUT pin outputs “L” level.
• The interrupt request generated and the timer Ai interrupt request bit goes to “1”.
(2) The timer Ai interrupt request bit goes to “1” if the timer's operation mode is set using any of the
following procedures:
• Selecting one-shot timer mode after reset.
• Changing operation mode from timer mode to one-shot timer mode.
• Changing operation mode from event counter mode to one-shot timer mode.
Therefore, to use timer Ai interrupt (interrupt request bit), set timer Ai interrupt request bit to “0”
after the above listed changes have been made.
3.4 Timer A (pulse width modulation mode)
(1) The timer Ai interrupt request bit becomes “1” if setting operation mode of the timer in compliance
with any of the following procedures:
• Selecting PWM mode after reset.
• Changing operation mode from timer mode to PWM mode.
• Changing operation mode from event counter mode to PWM mode.
Therefore, to use timer Ai interrupt (interrupt request bit), set timer Ai interrupt request bit to “0”
after the above listed changes have been made.
(2) Setting the count start flag to “0” while PWM pulses are being output causes the counter to stop
counting. If the TAiOUT pin is outputting an “H” level in this instance, the output level goes to “L”,
and the timer Ai interrupt request bit goes to “1”. If the TAiOUT pin is outputting an “L” level in this
instance, the level does not change, and the timer Ai interrupt request bit does not becomes “1”.
Rev. 1.0
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3.5 Timer B (timer mode, event counter mode)
(1) Reading the timer Bi register while a count is in progress allows reading , with arbitrary timing, the
value of the counter. Reading the timer Bi register with the reload timing gets “FFFF16”. Reading the
timer Bi register after setting a value in the timer Bi register with a count halted but before the counter
starts counting gets a proper value.
3.6 Timer B (pulse period, pulse width measurement mode)
(1) If changing the measurement mode select bit is set after a count is started, the timer Bi interrupt
request bit goes to “1”.
(2) When the first effective edge is input after a count is started, an indeterminate value is transferred to
the reload register. At this time, timer Bi interrupt request is not generated.
3.7 A-D Converter
(1) Write to each bit (except bit 6) of A-D control register 0, to each bit of A-D control register 1, and to bit
0 of A-D control register 2 when A-D conversion is stopped (before a trigger occurs).
In particular, when the Vref connection bit is changed from “0” to “1”, start A-D conversion after an
elapse of 1 µs or longer.
(2) When changing A-D operation mode, select analog input pin again.
(3) When using A-D converter in the one-shot mode and in the single sweep mode
After confirming the completion of A-D conversion, read the A-D register (the completion of A-D conversion is determined by A-D interrupt request bit).
(4) When using A-D converter in the repeat mode and in the repeat sweep mode
Use the main clock without dividing as the internal clock of CPU.
(5) The A-D conversion in the sweep mode needs the time as follows; (number of sweep pins + 2 pins) ✕
repeat times ✕ A-D conversion time for 1 pin.
(6) When operating OSD or operating data slicer using the HSYNC and VSYNC input, do not use the A-D
sweap mode (single sweap mode, repeat sweap mode 0, and repeat sweap mode 1).
3.8 Stop Mode and Wait Mode
____________
(1) When returning from stop mode by hardware reset, RESET pin must be set to “L” level until main clock
oscillation is stabilized.
(2) When switching to either wait mode or stop mode, instructions occupying four bytes either from the
WAIT instruction or from the instruction that sets the every-clock stop bit to “1“ within the instruction
queue are perfected and then the program stops. So put at least four NOPs in succession either to the
WAIT instruction or to the instruction that sets the every-clock stop bit to “1.”
Rev. 1.0
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3.9 Interrupts
(1) Reading address 0000016
• When maskable interrupt is occurred, CPU read the interrupt information (the interrupt number
and interrupt request level) in the interrupt sequence.
The interrupt request bit of the certain interrupt written in address 0000016 will then be set to “0”.
Reading address 0000016 by software sets enabled highest priority interrupt source request bit to
“0”.
Though the interrupt is generated, the interrupt routine may not be executed.
Do not read address 0000016 by software.
(2) Setting the stack pointer
• The value of the stack pointer immediately after reset is initialized to 000016. Accepting an
interrupt before setting a value in the stack pointer may become a factor of runaway. Be sure to
set a value in the stack pointer before accepting an interrupt.
(3) External interrupt
_______
_______
• When the polarity of the INT0 and INT1 pins is changed, the interrupt request bit is sometimes set
to “1.” After changing the polarity, set the interrupt request bit to “0.”
(4) Rewrite the interrupt control register
• To rewrite the interrupt control register, do so at a point that does not generate the interrupt
request for that register. If there is possibility of the interrupt request occur, rewrite the interrupt
control register after the interrupt is disabled. The program examples are described as follow:
Example 1:
INT_SWITCH1:
FCLR
I
AND.B #00h, 0055h
NOP
NOP
FSET
I
; Disable interrupts.
; Clear TA0IC int. priority level and int. request bit.
; Enable interrupts.
Example 2:
INT_SWITCH2:
FCLR
I
AND.B #00h, 0055h
MOV.W MEM, R0
FSET
I
; Disable interrupts.
; Clear TA0IC int. priority level and int. request bit.
; Dummy read.
; Enable interrupts.
Example 3:
INT_SWITCH3:
PUSHC FLG
FCLR
I
AND.B #00h, 0055h
POPC FLG
; Push Flag register onto stack
; Disable interrupts.
; Clear TA0IC int. priority level and int. request bit.
; Enable interrupts.
The reason why two NOP instructions or dummy read are inserted before FSET I in Examples 1 and 2 is
to prevent the interrupt enable flag I from being set before the interrupt control register is rewritten due to
effects of the instruction queue.
• When a instruction to rewrite the interrupt control register is executed but the interrupt is disabled, the
interrupt request bit is not set sometimes even if the interrupt request for that register has been generated. This will depend on the instruction. If this creates problems, use the below instructions to change
the register.
Instructions : AND, OR, BCLR, BSET
Rev. 1.0
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3.10 Built-in PROM Version
3.10.1 All Built-in PROM Versions
High voltage is required to program to the built-in PROM. Be careful not to apply excessive voltage. Be
especially careful during power-on.
3.10.2 One Time PROM Version
One Time PROM versions shipped in blank, of which built-in PROMs are programmed by users, are also
provided. For these microcomputers, a programming test and screening are not performed in the assembly process and the following processes. To improve their reliability after programming, we recommend to program and test as flow shown in Figure 3.10.1 before use.
Programming with PROM programmer
Screening (Note)
(Leave at 150˚C for 40 hours)
Verify test PROM programmer
Function check in target device
Note: Never expose to 150˚C exceeding 100 hours.
Figure 3.10.1 Programming and test flow for One Time PROM version
Rev. 1.0
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4. ITEMS TO BE SUBMITTED WHEN ORDERING MASKED ROM VERSION
Please submit the following when ordering masked ROM products.
(1) Mask ROM confirmation form
(2) Mark specification sheet
(3) ROM data : EPROMs (3 sets)
*: In the case of EPROMs, there sets of EPROMs are required per pattern.
*: In the case of floppy disks, 3.5-inch double-sided high-density disk (IBM format) is required per pattern.
Rev. 1.0
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5. ELECTRICAL CHARACTERISTICS
5.1. Absolute Maximum Ratings
Table 5.1.1 Absolute maximum ratings
Symbol
Parameter
Vcc
AVcc
Supply voltage
VI
Input voltage
Condition
Analog supply voltage
P00 to P07, P20 to P27,
P30 to P37, P40 to P43,
P50, P52, P53, P55, P62, P63, P67,
P70, P71, P72, P74, P76, P82,
P90, P93, P94, P100, P101,
XIN, OSC1, RESET
Rated value
Unit
–0.3 to 6.0
V
–0.3 to 6.0
V
–0.3 to Vcc+0.3
V
VI
Input voltage
CNVss
–0.3 to 6.0 (Note)
V
VO
Output voltage
P00 to P07, P20 to P27,
P30 to P37, P40 to P43,
P50, P52, P53, P55, P62, P63, P67,
P70, P71, P72, P74, P76, P82,
P90, P93, P94, P100, P101,
R, G, B, OUT1, OUT2, OSC2, XOUT
–0.3 to Vcc+0.3
V
500
– 1 0 to 7 0
–40 to 125
mW
°C
°C
Pd
Topr
Tstg
Power dissipation
Operating ambient temperature
Storage temperature
Ta=25 °C
Note: When writing to EPROM, only CNVSS is –0.3 to 13(V).
Rev. 1.0
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5.2 Recommended Operating Conditions
Table 5.2.1 Recommended operating conditions (referenced to VCC = 4.5 V to 5.5 V at Ta = – 10 oC
to 70 oC unless otherwise specified)
Symbol
Vcc
AVcc
Parameter
Min
4.5
Supply voltage (Note 3)
Standard
Typ.
Max.
5 .0
5.5
Unit
V
Vcc
V
0
V
Vss
Analog supply voltage (Note 3)
Supply voltage
VIH
HIGH input voltage
P00 to P07, P20 to P27, P30 to P37, P40 to P43,
P50, P52, P53, P55, P62, P63, P67,
P70, P71, P72, P74, P76, P82,
P90, P93, P94, P100, P101,
XIN, OSC1, RESET, CNVSS
0.8Vcc
V cc
V
VIL
LOW input voltage
P00 to P07, P20 to P27, P30 to P37, P40 to P43,
P50, P52, P53, P55, P62, P63, P67,
P70, P71, P72, P74, P76, P82,
P90, P93, P94, P100, P101,
XIN, OSC1, RESET, CNVSS
0
0.2Vcc
V
IOH (peak)
HIGH peak output
current
–10.0
mA
IOH (avg)
HIGH average output P00 to P07, P20 to P27, P30 to P37, P40 to P43,
current
P50, P52, P53, P55, P62, P63, P67, P72, P74, P76,
P82, P90, P93, P94, P100, P101, R, G, B, OUT1, OUT2
–5.0
mA
IOL (peak)
LOW peak output
current
10.0
mA
IOL (avg)
LOW average output
current
P00 to P07, P20 to P27, P30 to P37, P40 to P43,
P50, P52, P53, P55, P62, P63, P74, P76,
P82, P90, P100, P101, R, G, B, OUT1, OUT2
5.0
mA
IOL (avg)
LOW average output
current
P67, P70 to P72, P93, P94
6.0
mA
f (XIN)
Main clock input oscillation frequency
10
MHz
fOSC
Oscillation frequency (for OSD)
f CVIN
VI
P00 to P07, P20 to P27, P30 to P37, P40 to P43,
P50, P52, P53, P55, P62, P63, P67, P72, P74, P76,
P82, P90, P93, P94, P100, P101, R, G, B, OUT1, OUT2
P00 to P07, P20 to P27, P30 to P37, P40 to P43,
P50, P52, P53, P55, P62, P63, P67,
P70, P71, P72, P74, P76,
P82, P90, P93, P94, P100, P101, R, G, B, OUT1, OUT2
OSC1
LC oscillating mode
11.0
27.0
Ceramic oscillating mode
15.0
27.0
Input frequency
Horizontal sync. signal of video signal
Input amplitude video signal
CVIN
MHz
15.262
15.743
16.206
kHz
1.5
2.0
2.5
V
Notes 1: The mean output current is the mean value within 100 ms.
2: The total IOL (peak) for ports P0, P2, P9, and P10 must be 80 mA max. The total IOH (peak) for ports P0, P2, P9,
and P10 must be 80 mA max. The total IOL (peak) for ports P3, P4, P5, P6, P7 and P82 must be 80 mA max.
The total IOH (peak) for ports P3, P4, P5, P6, P72, P74, P76, and P82 must be 80 mA max.
3: Connect 0.1 µF or more capacitor externally between the power source pins VCC–VSS and AVCC–VSS so as to
reduce power source noise. Also connect 0.1 µF or more capacitor externally between the power source pins
VCC–CNVSS.
Rev. 1.1
1.0
245
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
5.3 Electrical Characteristics
Table 5.3.1 Electrical characteristics (referenced to VCC = 5 V, VSS = 0 V at Ta = 25 oC, f(XIN) = 10 MHz
unless otherwise specified)
Symbol
Parameter
Measuring condition
Standard
Min. Typ. Max. Unit
VOH
HIGH output
voltage
P00 to P07, P20 to P27,
P30 to P37, P40 to P43,
P50, P52, P53, P55, P62, P63, P67,
P72, P74, P76,
P82, P90, P93, P94, P100, P101, R,
G, B, OUT1, OUT2
IO H = – 5 m A
3.0
V
VOH
HIGH output
voltage
P00 to P07,P20 to P27, P30 to P37,
P40 to P43, P50, P52, P53, P55
IO H = – 2 0 0 µ A
4.7
V
VOH
HIGH output
voltage
XOUT
IO H = – 1 m A
IOH = –0.5 mA
3.0
3.0
V
VOL
LOW output
voltage
P00 to P07, P20 to P27,
P30 to P37, P40 to P43,
P50, P52, P53, P55,
P62, P63, P74, P76,
P82, P90, P100, P101, R, G, B,
OUT1, OUT2
IO L = 5 m A
2.0
V
VOL
LOW output
voltage
P67, P70 to P72, P93, P94
IOL = 6.0 mA
0.6
V
VOL
LOW output
voltage
P00 to P07,P20 to P27, P30 to P37,
P40 to P43, P50, P52, P53, P55
IOL = 200 µA
0.45
V
VOL
LOW output
voltage
XOUT
IO L = 1 m A
IOL = 0.5 mA
2.0
2.0
V
VT+-VT-
Hysteresis
0.2
0.8
V
VT+-VT-
Hysteresis
TB0IN, INT0, INT1, CLK0, CLK2,
SCL1, SCL2, SCL3,
SDA1, SDA2, SDA3,
HSYNC, VSYNC, HC0, HC1, RxD0,
RxD2
RESET
0.2
1.8
V
VT+-VT-
Hysteresis
XIN
0.2
0.8
V
IIH
HIGH input
current
P00 to P07, P20 to P27,
P30 to P37, P40 to P43,
P50, P52, P53, P55, P62, P63, P67,
P70, P71, P72, P74, P76,
P82, P90, P93, P94, P100, P101
XIN, RESET, CNVss, OSC1
VI = 5 V
5.0
µA
IIL
LOW input
current
P00 to P07, P20 to P27,
P30 to P37, P40 to P43,
P50, P52, P53, P55, P62, P63, P67,
P70, P71, P72, P74, P76,
P82, P90, P93, P94, P100, P101
XIN, RESET, CNVss, OSC1
VI = 0 V
–5.0
µA
PPULLUP
Pull-up resistor
P00 to P07, P20 to P27,
P30 to P37, P40 to P43,
P50, P52, P53, P55, P62, P63, P67,
P72, P74, P76, P82, P90, P93, P94
VI = 0 V
50.0
167.0
kΩ
Icc
Power supply current
f(XIN) = 10 MHz OSD ON, Data slicer ON
70
90
Square wave,
no division
30
50
HIGH POWER
LOW POWER
HIGHPOWER
LOWPOWER
30.0
In single-chip f(XIN) = 10 MHz
mode, the
Square wave,
output pins
division by 8
are open and
other pins are
Ta=25 °C when
VS S
OSD OFF, Data slicer OFF
mA
OSD OFF, Data slicer OFF
10
mA
10
clock is stopped
µA
Ta = 70 °C when
clock is stopped
200
130
Ω
RBS
Vcc = 4.5 V
I2C-BUS • BUS switch connection resistor
(between SCL1 and SCL2, SDA1 and SDA2)
RfXIN
Feedback resistor XIN
1.0
MΩ
RfXCIN
Feedback resistor XCIN
6.0
MΩ
Rev. 1.0
246
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
5.4 A-D Conversion Characteristics
Table 5.4.1 A-D conversion characteristics (referenced to VCC = AVCC = 5V, VSS = AVSS = 0 V at Ta
= 25 oC, f(XIN) = 10 MHz unless otherwise specified)
Symbol
Parameter
Measuring condition
—
Resolution
VREF = VCC
—
Absolute
accuracy
Sample & hold function not available
VREF = VCC = 5 V
Sample & hold function available (8 bit)
VREF = VCC = 5 V
RLADDER
tCONV
tSAMP
VREF
VIA
Ladder resistance
Conversion time
Sampling time
Reference voltage
Analog input voltage
VREF = VCC
Standard
Min. Typ. Max.
Unit
8
±5
±5
Bits
LSB
LSB
40
kΩ
10
µs
µs
2.8
0.3
VCC
0
V
VCC
V
5.5 D-A Conversion Characteristics
Table 5.5.1 D-A conversion characteristics (referenced to VCC = 5V, VSS = AVSS = 0V at Ta = 25 oC,
f(XIN) = 10 MHz unless otherwise specified)
Symbol
—
—
tsu
RO
IVREF
Parameter
Resolution
Absolute accuracy
Setup time
Output resistance
Reference power supply input current
Measuring condition
Min.
4
Standard
Typ. Max.
8
10
3
20
1.5
10
(Note )
Unit
Bits
%
µs
kΩ
mA
Note: This applies when using one D-A converter, with the D-A register for the unused D-A converter set to “0016.”
The A-D converter’s ladder resistance is not included.
Also, when the Vref is unconnected at the A-D control register, IVREF is sent.
5.6 Analog R, G, B Output Characteristics
Table 5.6.1 Analog R, G, B output characteristics (VCC = 5V, VSS = 0V at Ta = 25 oC, f(XIN) = 10 MHz
unless otherwise specified)
Symbol
RO
VOE
TST
Parameter
Output impedance
Output deviation
Settling time
Test conditions
Standard
Min.
Max.
2
±0.5
load capacity of 10 pF,
load resistance of 20 k Ω,
70 % DC level
50
Unit
kΩ
V
ns
Rev. 1.0
247
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
5.7 Timing Requirements
Table 5.7.1 External clock input (referenced to VCC = 5 V, VSS = 0 V at Ta = 25 oC unless otherwise
specified)
Symbol
tc
tw(H)
tw(L)
tr
tf
Parameter
External clock input cycle time
External clock input HIGH pulse width
External clock input LOW pulse width
External clock rise time
External clock fall time
Standard
Min.
Max.
Unit
100
ns
40
ns
ns
40
15
ns
15
ns
Table 5.7.2 Timer B input (counter input in event counter mode)
(referenced to VCC = 5 V, VSS = 0 V at Ta = 25 oC unless otherwise specified)
Symbol
Parameter
Standard
Min.
Max.
Unit
tc(TB)
TB0IN input cycle time (counted on one edge)
100
ns
tw(TBH)
TB0IN input HIGH pulse width (counted on one edge)
40
ns
tw(TBL)
TB0IN input LOW pulse width (counted on one edge)
TB0IN input cycle time (counted on both edges)
40
200
ns
tc(TB)
ns
tw(TBH)
TB0IN input HIGH pulse width (counted on both edges)
80
ns
tw(TBL)
TB0IN input LOW pulse width (counted on both edges)
80
ns
Table 5.7.3 Timer B input (pulse period measurement mode)
(referenced to VCC = 5 V, VSS = 0 V at Ta = 25 oC unless otherwise specified)
Symbol
Parameter
Standard
Min.
Max.
Unit
tc(TB)
TB0IN input cycle time
400
ns
tw(TBH)
tw(TBL)
TB0IN input HIGH pulse width
TB0IN input LOW pulse width
200
200
ns
ns
Table 5.7.4 Timer B input (pulse width measurement mode)
(referenced to VCC = 5 V, VSS = 0 V at Ta = 25 oC unless otherwise specified)
Symbol
Parameter
Standard
Min.
Max.
Unit
tc(TB)
TB0IN input cycle time
400
tw(TBH)
TB0IN input HIGH pulse width
200
ns
tw(TBL)
TB0IN input LOW pulse width
200
ns
ns
Rev. 1.0
248
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
Table 5.7.5 Serial I/O (referenced to VCC = 5 V, VSS = 0 V at Ta = 25 oC unless otherwise specified)
Symbol
Parameter
Standard
Min.
Max.
Unit
tc(CK)
CLKi input cycle time
200
ns
tw(CKH)
CLKi input HIGH pulse width
100
ns
tw(CKL)
CLKi input LOW pulse width
100
ns
td(C-Q)
TxDi output delay time
th(C-Q)
TxDi hold time
tsu(D-C)
RxDi input setup time
RxDi input hold time
th(C-D)
80
ns
0
30
ns
90
ns
ns
_______
Table 5.7.6 External interrupt INTi inputs (referenced to VCC = 5 V, VSS = 0 V at Ta = 25 oC unless
otherwise specified)
Symbol
tw(INH)
tw(INL)
Parameter
Standard
Min.
Max.
Unit
INTi input HIGH pulse width
250
ns
INTi input LOW pulse width
250
ns
Rev. 1.0
249
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
5.8 Timing Diagram
tc(TB)
tw(TBH)
TB0 IN input
tw(TBL)
tc(CK)
tw(CKH)
CLKi
tw(CKL)
th(C–Q)
TxD i
tsu(D–C)
td(C–Q)
th(C–D)
RxDi
tw(INL)
INT i input
tw(INH)
Figure 5.8.1 Timing diagram
Rev. 1.0
250
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
6. MASK CONFIRMATION FORM
GZZ
SH56
45B <93A0>
Mask ROM number
MITSUBISHI ELECTRIC SINGLE-CHIP 16-BIT
MICROCOMPUTER M306V5ME-XXXSP
MASK ROM CONFIRMATION FORM
Receipt
Date :
Section head
signature
Supervisor
signature
Note : Please complete all items marked
)
Date :
Issuance
(
Customer
.
Supervisor
signature
TEL
Company
name
Date
issued
Submitted by
1. Check sheet
Name the product you order, and choose which to give in, EPROMs or floppy disks.
If you order by means of EPROMs, three sets of EPROMs are required per pattern. If you order by
means of floppy disks, one floppy disk is required per pattern.
In the case of EPROMs
Mitsubishi will create the mask using the data on the EPROMs supplied, providing the data is the
same on at least two of those sets. Mitsubishi will, therefore, only accept liability if there is any
discrepancy between the data on the EPROM sets and the ROM data written to the product.
Please carefully check the data on the EPROMs being submitted to Mitsubishi.
Checksum code for total EPROM area :
(hex)
EPROM type :
27C401
Address
00000 16 Product : Area
containing ASCII
0000F 16 code for M306V5ME 00010 16
0FFFF16
10000 16
OSD ROM
30000 16
50000 16
7FFFF16
ROM(192K)
(1) The area from 00000 16 to 0000F 16 is for storing
data on the product type name.
The ASCII code for 'M306V5ME-' is shown at right.
The data in this table must be written to address
00000 16 to 0000F 16.
Both address and data are shown in hex.
(2) Write “FF 16” to the lined area.
Address
Address
00000 16
00001 16
00002 16
00003 16
00004 16
00005 16
00006 16
00007 16
'M '
'3 '
'0 '
'6 '
'V '
'5 '
'M '
'E '
= 4D16
= 3316
= 3016
= 3616
= 5616
= 3516
= 4D16
= 4516
00008 16 ' — ' = 2D16
00009 16
FF16
0000A 16
FF16
0000B 16
FF16
0000C 16
FF16
FF16
0000D 16
0000E 16
FF16
0000F 16
FF16
(1/4)
Rev. 1.0
251
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
GZZ
SH56
45B <93A0>
Mask ROM number
MITSUBISHI ELECTRIC SINGLE-CHIP 16-BIT
MICROCOMPUTER M306V5ME-XXXSP
MASK ROM CONFIRMATION FORM
(3) Be sure to store “FF 16” in the following test font addresses in OSD ROM.
When producing OSD ROM data with the OSD font editor program of Mitsubishi,
“FF 16” is set automatically to these test font addresses.
(All addresses below are shown in hex.)
100FE
100FF
101FE
101FF
102FE
102FF
103FE
103FF
104FE
104FF
105FE
105FF
106FE
106FF
107FE
107FF
108FE
108FF
109FE
109FF
10AFE
10AFF
10BFE
10BFF
10CFE
10CFF
10DFE
10DFF
10EFE
10EFF
10FFE
10FFF
110FE
110FF
111FE
111FF
112FE
112FF
113FE
113FF
114FE
114FF
115FE
115FF
116FE
116FF
117FE
117FF
118FE
118FF
119FE
119FF
120FE
120FF
121FE
121FF
122FE
122FF
123FE
123FF
124FE
124FF
125FE
125FF
126FE
126FF
127FE
127FF
128FE
128FF
129FE
129FF
12AFE
12AFF
12BFE
12BFF
12CFE
12CFF
12DFE
12DFF
12EFE
12EFF
12FFE
12FFF
130FE
130FF
131FE
131FF
132FE
132FF
133FE
133FF
134FE
134FF
135FE
135FF
136FE
136FF
137FE
137FF
138FE
138FF
139FE
139FF
140FE
140FF
141FE
141FF
142FE
142FF
143FE
143FF
144FE
144FF
145FE
145FF
146FE
146FF
147FE
147FF
148FE
148FF
149FE
149FF
14AFE
14AFF
14BFE
14BFF
14CFE
14CFF
14DFE
14DFF
14EFE
14EFF
14FFE
14FFF
150FE
150FF
151FE
151FF
152FE
152FF
153FE
153FF
154FE
154FF
155FE
155FF
156FE
156FF
157FE
157FF
158FE
158FF
159FE
159FF
160FE
160FF
161FE
161FF
162FE
162FF
163FE
163FF
164FE
164FF
165FE
165FF
166FE
166FF
167FE
167FF
168FE
168FF
169FE
169FF
16AFE
16AFF
16BFE
16BFF
16CFE
16CFF
16DFE
16DFF
16EFE
16EFF
16FFE
16FFF
170FE
170FF
171FE
171FF
172FE
172FF
173FE
173FF
174FE
174FF
175FE
175FF
176FE
176FF
177FE
177FF
178FE
178FF
179FE
179FF
18002
18003
18102
18103
18202
18203
18302
18303
18402
18403
18502
18503
18602
18603
18702
18703
18802
18803
18902
18903
18A02
18A03
18B02
18B03
18C02
18C03
18D02
18D03
18E02
18E03
18F02
18F03
19002
19003
19102
19103
19202
19203
19302
19303
19402
19403
19502
19503
19602
19603
19702
19703
19802
19803
19902
19903
1A002
1A003
1A102
1A103
1A202
1A203
1A302
1A303
1A402
1A403
1A502
1A503
1A602
1A603
1A702
1A703
1A802
1A803
1A902
1A903
1AA02
1AA03
1AB02
1AB03
1AC02
1AC03
1AD02
1AD03
1AE02
1AE03
1AF02
1AF03
1B002
1B003
1B102
1B103
1B202
1B203
1B302
1B303
1B402
1B403
1B502
1B503
1B602
1B603
1B702
1B703
1B802
1B803
1B902
1B903
1C002
1C003
1C102
1C103
1C202
1C203
1C302
1C303
1C402
1C403
1C502
1C503
1C602
1C603
1C702
1C703
1C802
1C803
1C902
1C903
1CA02
1CA03
1CB02
1CB03
1CC02
1CC03
1CD02
1CD03
1CE02
1CE03
1CF02
1CF03
1D002
1D003
1D102
1D103
1D202
1D203
1D302
1D303
1D402
1D403
1D502
1D503
1D602
1D603
1D702
1D703
1D802
1D803
1D902
1D903
1E002
1E003
1E102
1E103
1E202
1E203
1E302
1E303
1E402
1E403
1E502
1E503
1E602
1E603
1E702
1E703
1E802
1E803
1E902
1E903
1EA02
1EA03
1EB02
1EB03
1EC02
1EC03
1ED02
1ED03
1EE02
1EE03
1EF02
1EF03
1F002
1F003
1F102
1F103
1F202
1F203
1F302
1F303
1F402
1F403
1F502
1F503
1F602
1F603
1F702
1F703
1F802
1F803
1F902
1F903
20400
21400
22400
23400
24400
25400
26400
27400
28400
29400
2A400
2B400
2C400
2D400
2E400
2F400
20C00
21C00
22C00
23C00
24C00
25C00
26C00
27C00
28C00
29C00
2AC00
2BC00
2CC00
2DC00
2EC00
2FC00
10000
11000
12000
13000
14000
15000
16000
17000
18000
19000
1A000
1B000
1C000
1D000
1E000
1F000
20401
21401
22401
23401
24401
25401
26401
27401
28401
29401
2A401
2B401
2C401
2D401
2E401
2F401
20C01
21C01
22C01
23C01
24C01
25C01
26C01
27C01
28C01
29C01
2AC01
2BC01
2CC01
2DC01
2EC01
2FC01
10800
11800
12800
13800
14800
15800
16800
17800
18800
19800
1A800
1B800
1C800
1D800
1E800
1F800
20600
21600
22600
23600
24600
25600
26600
27600
28600
29600
2A600
2B600
2C600
2D600
2E600
2F600
20E00
21E00
22E00
23E00
24E00
25E00
26E00
27E00
28E00
29E00
2AE00
2BE00
2CE00
2DE00
2EE00
2FE00
10001
11001
12001
13001
14001
15001
16001
17001
18001
19001
1A001
1B001
1C001
1D001
1E001
1F001
20601
21601
22601
23601
24601
25601
26601
27601
28601
29601
2A601
2B601
2C601
2D601
2E601
2F601
20E01
21E01
22E01
23E01
24E01
25E01
26E01
27E01
28E01
29E01
2AE01
2BE01
2CE01
2DE01
2EE01
2FE01
10801
11801
12801
13801
14801
15801
16801
17801
18801
19801
1A801
1B801
1C801
1D801
1E801
1F801
213F8
223F8
233F8
243F8
253F8
263F8
273F8
283F8
293F8
2A3F8
21BF8
22BF8
23BF8
24BF8
25BF8
26BF8
27BF8
28BF8
29BF8
2ABF8
213F9
223F9
233F9
243F9
253F9
263F9
273F9
283F9
293F9
2A3F9
21BF9
22BF9
23BF9
24BF9
25BF9
26BF9
27BF9
28BF9
29BF9
2ABF9
213FC
223FC
233FC
243FC
253FC
263FC
273FC
283FC
293FC
2A3FC
21BFC
22BFC
23BFC
24BFC
25BFC
26BFC
27BFC
28BFC
29BFC
2ABFC
213FD
223FD
233FD
243FD
253FD
263FD
273FD
283FD
293FD
2A3FD
21BFD
22BFD
23BFD
24BFD
25BFD
26BFD
27BFD
28BFD
29BFD
2ABFD
(2/4)
Rev. 1.0
252
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
GZZ
SH56
45B <93A0>
Mask ROM number
MITSUBISHI ELECTRIC SINGLE-CHIP 16-BIT
MICROCOMPUTER M306V5ME-XXXSP
MASK ROM CONFIRMATION FORM
The ASCII code for the type No. can be written to EPROM addresses 00000 16 to 0000F 16 by specifying the
pseudo-instructions shown in the following table at the beginning of the assembler source program.
EPROM type
Code entered in
source program
27C401
.SECTION ASCIICODE, ROM DATA
.ORG 080000H
.BYTE
' M306V5ME- '
Note: The ROM cannot be processed if the type No. written to the EPROM does not match the type No.
in the check sheet.
In the case of floppy disks
Mitsubishi processes the mask files generated by the mask file generation utilities out of those held on
the floppy disks you give in to us, and forms them into masks. Hence, we assume liability provided that
there is any discrepancy between the contents of these mask files and the ROM data to be burned into
products we produce. Check thoroughly the contents of the mask files you give in.
Prepare 3.5 inches 2HD(IBM format) floppy disks. And store only one mask file in a floppy disk.
File code :
(hex)
Mask file name :
.MSK (alpha-numeric 8-digit)
Note: When using the floppy disks, do not store the type No. to addresses 0000 16 to 0000F 16.
2. Mark specification
The mark specification differs according to the type of package. After entering the mark specification on
the separate mark specification sheet (for each package), attach that sheet to this masking check sheet
for submission to Mitsubishi.
For the M306V5ME-XXXSP, submit the 64P4B mark specification sheet.
(3/4)
Rev. 1.0
253
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
GZZ
SH56
45B <93A0>
Mask ROM number
MITSUBISHI ELECTRIC SINGLE-CHIP 16-BIT
MICROCOMPUTER M306V5ME-XXXSP
MASK ROM CONFIRMATION FORM
3. Usage Conditions
For our reference when of testing our products, please reply to the following questions about the usage of
the products you ordered.
(1) Which kind of X IN-XOUT oscillation circuit is used?
Ceramic resonator
Quartz-crystal oscillator
External clock input
Other (
)
What frequency do you use?
f(XIN) =
MH Z
(2) Which operation mode do you use?
Single-chip mode
Memory expansion mode
Microprocessor mode
Thank you cooperation.
4. Special item (Indicate none if there is no specified item)
(4/4)
Rev. 1.0
254
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
7. MARK SPECIFICATION FORM
Rev. 1.0
255
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
8. ONE TIME PROM VERSION M306V5EESP MARKING
M306V5EESP
XXXXXXX
XXXXXXX is mitsubishi lot number
Rev. 1.0
256
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
9. PACKAGE OUTLINE
MMP
64P4B
JEDEC Code
–
Plastic 64pin 750mil SDIP
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
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°
Rev. 1.0
257
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
Structure of Register
Refer to the figure below as for each register.
<Example>
Processor mode register 1 (Note)
Values immediately
after reset release
(Note 1)
(Note 2)
b7
b6
b5
0 0
b4
b3
0 0
b2
b1
b0
1
0
Symbol
PM1
Address
000516
Bit symbol
Bit name
When reset
00000X002
Bit attributes
Function
Reserved bit
Must always be set to “0”
Reserved bit
Must always be set to “1”
R W
Nothing is assigned.
In an attempt to write to this bit, write “0.” The value, if read, turns out to be
indeterminate.
Reserved bits
PM17
Must always be set to “0”
Wait bit
0 : No wait state
1 : Wait state inserted
Note: As bit 1 of this register becomes “0” at reset, must always be set to “1” after reset
release. Set bit 1 of the protect register (address 000A16) to “1” when writing new
values to this register.
: Bit in which nothing is assigned
Notes 1: Values immediately after reset release
0 ••••••••••••••••••“0” after reset release
1 ••••••••••••••••••“1” after reset release
? ••••••••••••••••••Indeterminate after reset release
✕••••••••••••••••••Bit in which nothing is assigned
2: Bit attributes••••••The attributes of control register bits are classified into 3 types : read-only,
write-only and read and write. In the figure, these attributes are represented
as follows :
R••••••Read
••••••Read enabled
✕••••••Read disabled
••••••Bit in which nothing is assigned (The read value is indeterminate unless otherwise mentioned.)
W••••••Write
••••••Write enabled
✕••••••Write disabled
••••••Bit in which nothing is assigned
Rev. 1.0
258
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
------Register Index-----[A]
DMAi destination pointer (DARi) ................... 62
A-D conversion interrupt control register (ADIC)
DMAi transfer counter (TCRi) ....................... 62
...................................................................... 43
DMAi source pointer (SARi) .......................... 62
Address match interrupt enable register (AIER)
...................................................................... 53
[H]
Address match interrupt register i (RMADi) .. 53
Horizontal position register (HP) ................. 176
A-D register i (ADi) ...................................... 141
A-D control register 2 (ADCON2) ................ 141
HSYNC counter register (HC) ....................... 165
HSYNC counter latch ...................................... 13
A-D control register 1 (ADCON1) ......................
............................ 140, 143, 145, 147, 149, 150
[I]
A-D control register 0 (ADCON0)
I2Ci
............................ 140, 143, 145, 147, 149, 151
I2Ci address register (IICiS0D) ................... 124
data shift register (IICiS0) .................... 123
I2Ci status register (IICiS1) ......................... 131
[B]
I2Ci control register (IICiS1D) ..................... 128
Block control register i (BCi) ....................... 171
Bottom border control register (BBR) .......... 215
I2Ci clock control register (IICiS2) ............... 126
I2Ci port selection register (IICiS2D) ........... 121
Bus collision detection interrupt control register
I2Ci transmit buffer register (IICiS0S) ......... 123
(BCNIC) ....................................................... 43
I/O polarity control register (PC) ................. 180
Interrupt control reserved register i (REiIC) ......... 52
[C]
Interrupt request cause select register (IFSR)
Caption data register i (CDi) ......................... 13
...................................................................... 52
Caption position register (CPS) .................. 161
INTi interrupt control register (INTiIC) ........... 43
Clock control register (CS) .......................... 179
Clock run-in detect register (CRD) .............. 162
Color palette register i (CRi) ....................... 119
[L]
Left border control register (LBR) ............... 216
Count start flag (TABSR) ........................ 71, 81
[M]
[D]
D-A control register (DACON) ..................... 154
Multi-master I2C-BUS interface i interrupt
control register (IICiIC) .................................. 43
D-A register i (DAi) ...................................... 154
Data clock position register (DPS) .............. 163
Data slicer control register 1 (DSC1) .......... 157
[O]
One-shot start flag (ONSF) ........................... 72
Data slicer control register 2 (DSC2) .......... 157
OSD control register 1 (OC1) ...................... 170
Data slicer interrupt control register (DSIC) .. 43
OSD control register 2 (OC2) ...................... 173
Data slicer reserved register i (DRi) ............ 164
OSD control register 3 (OC3) ...................... 198
DMA0 request cause select register (DM0SL)
OSD control register 4 (OC4) ...................... 182
...................................................................... 60
OSD reserved register i (ORi) ..................... 220
DMA1 request cause select register (DM1SL) ..
OSDi interrupt control register (OSDiIC) ........ 43
...................................................................... 61
DMAi control register (DMiCON) ................... 61
DMAi interrupt control register (DMiIC) ......... 43
[P]
Peripheral mode register (PM) ...................... 87
Rev. 1.0
259
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
Port P0, P2, P3 register
(P0 to P0, P2, P3) ....................................... 231
Timer Bi register (TBi) ................................... 81
Timer Ai mode register (TAiMR)
Port P0, P2, P3 direction register
.............................................. 70, 74, 76, 77, 78
(PD0, PD2, PD3) ......................................... 227
Timer Bi mode register (TBiMR)
Port P4 register (P4) ................................... 231
.................................................... 80, 82, 83, 84
Port P4 direction register (PD4) .................. 227
Top border control register (TBR) ............... 215
Port P5 register (P5) ................................... 232
Port P5 direction register (PD5) .................. 228
Trigger select register (TRGSR) ................... 73
Port P6 register (P6) ................................... 232
[U]
Port P6 direction register (PD6) .................. 228
UART transmit/receive control register 2 (UCON)
Port P7 register (P7) ................................... 233
...................................................................... 97
Port P7 direction register (PD7) .................. 229
UART0 transmit/receive control register 0 (U0C0)
Port P8 register (P8) ................................... 233
...................................................................... 94
Port P8 direction register (PD8) .................. 229
Port P9 register (P9) ................................... 234
UART0 transmit/receive control register 1 (U0C1)
Port P9 direction register (PD9) .................. 230
Port P10 register (P10) ............................... 234
UART0 transmit/receive mode register (U0MR)
...................................................... 93, 100, 107
Port P10 direction register (PD10) .............. 230
UART2 special mode register (U2SMR) ........... 97
Port reserved register i (PRi) ...................... 235
UART2 transmit/receive mode register (U2MR)
Processor mode register 0 (PM0) ................. 23
...................................................... 93, 100, 107
Processor mode register 1 (PM1) ................. 23
UART2 transmit/receive control register 0 (U2C0)
Protect register (PRCR) ................................ 35
Pull-up control register 0 (PUR0) ................ 236
...................................................................... 95
Pull-up control register 1 (PUR1) ................ 236
Pull-up control register 2 (PUR2) ................ 237
...................................................................... 96
UART2 transmit/receive control register 1 (U2C1)
...................................................................... 96
UARTi bit rate generator (UiBRG) ................ 92
UARTi receive buffer register (UiRB) ............ 92
[R]
UARTi receive interrupt control register (SiRIC)
Raster color register (RSC) ......................... 217
...................................................................... 43
Reserved register i (INVCi) ............... 73, 81, 86
UARTi transmit buffer register (UiTB) ........... 92
Right border control register (RBR) ............ 216
UARTi transmit interrupt control register (SiTIC)
...................................................................... 43
[S]
Up/down flag (UDF) ...................................... 72
SPRITE horizontal position register (HS) .... 212
SPRITE OSD control register (SC) ............. 211
[V]
SPRITE vertical position register i (VSi) ..... 212
VSYNC interrupt control register (VSYNCIC) ........ 43
System clock control register 0 (CM0) .......... 30
Vertical position register i (VPi) ................... 176
System clock control register 1 (CM1) .......... 30
[W]
[T]
Timer Ai interrupt control register (TAiIC)
Watchdog timer control register (WDC) ........ 57
Watchdog timer start register (WDTS) .......... 57
...................................................................... 43
Timer Bi interrupt control register (TBiIC)
...................................................................... 43
Timer Ai register (TAi) ................................... 71
Rev. 1.0
260
MITSUBISHI MICROCOMPUTERS
M306V5ME-XXXSP
M306V5EESP
SINGLE-CHIP 16-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
Keep safety first in your circuit designs!
•
Mitsubishi Electric Corporation puts the maximum effort into making semiconductor products better and more reliable, but there is always the possibility that trouble may occur with them. Trouble with semiconductors may lead to
personal injury, fire or property damage. Remember to give due consideration to safety when making your circuit designs, with appropriate measures such as (i) placement of substitutive, auxiliary circuits, (ii) use of non-flammable
material or (iii) prevention against any malfunction or mishap.
•
These materials are intended as a reference to assist our customers in the selection of the Mitsubishi semiconductor product best suited to the customer’s application; they do not convey any license under any intellectual property
rights, or any other rights, belonging to Mitsubishi Electric Corporation or a third party.
Mitsubishi Electric Corporation assumes no responsibility for any damage, or infringement of any third-party’s rights, originating in the use of any product data, diagrams, charts, programs, algorithms, or circuit application examples
contained in these materials.
All information contained in these materials, including product data, diagrams, charts, programs and algorithms represents information on products at the time of publication of these materials, and are subject to change by
Mitsubishi Electric Corporation without notice due to product improvements or other reasons. It is therefore recommended that customers contact Mitsubishi Electric Corporation or an authorized Mitsubishi Semiconductor product
distributor for the latest product information before purchasing a product listed herein.
The information described here may contain technical inaccuracies or typographical errors. Mitsubishi Electric Corporation assumes no responsibility for any damage, liability, or other loss rising from these inaccuracies or errors.
Please also pay attention to information published by Mitsubishi Electric Corporation by various means, including the Mitsubishi Semiconductor home page (http://www.mitsubishichips.com).
When using any or all of the information contained in these materials, including product data, diagrams, charts, programs, and algorithms, please be sure to evaluate all information as a total system before making a final decision
on the applicability of the information and products. Mitsubishi Electric Corporation assumes no responsibility for any damage, liability or other loss resulting from the information contained herein.
Mitsubishi Electric Corporation semiconductors are not designed or manufactured for use in a device or system that is used under circumstances in which human life is potentially at stake. Please contact Mitsubishi Electric
Corporation or an authorized Mitsubishi Semiconductor product distributor when considering the use of a product contained herein for any specific purposes, such as apparatus or systems for transportation, vehicular, medical,
aerospace, nuclear, or undersea repeater use.
The prior written approval of Mitsubishi Electric Corporation is necessary to reprint or reproduce in whole or in part these materials.
If these products or technologies are subject to the Japanese export control restrictions, they must be exported under a license from the Japanese government and cannot be imported into a country other than the approved
destination.
Any diversion or reexport contrary to the export control laws and regulations of Japan and/or the country of destination is prohibited.
Please contact Mitsubishi Electric Corporation or an authorized Mitsubishi Semiconductor product distributor for further details on these materials or the products contained therein.
Notes regarding these materials
•
•
•
•
•
•
•
© 2001 MITSUBISHI ELECTRIC CORP.
New publication, effective Aug. 2001.
Specifications subject to change without notice.
REVISION HISTORY
Rev.
M306V5ME-XXXSP, M306V5EESP (REV.1.1) DATA SHEET
Rev.
Revision Description
No.
1.0
First Edition of PDF File
1.1
P199 Fugure 2.16.30
date
0006
BEFORE
AFTER
G signal output control bit
b2 b1 b0
→
B signal output control bit
b2 b1 b0
→ b10 b9 b8
b6 b5 b4
P245 Table 5.2.1
fosc Oscillation frequency (for OSD) OSC1
Ceramic oscillating mode
(1/1)
BEFORE
AFTER
Min. 24.0 MHZ →
15.0MHZ
Max. 25.0 MHZ →
27.0MHZ
0108