RENESAS M37270EF

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
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
DESCRIPTION
The M37270MF-XXXSP is a single-chip microcomputer designed with
CMOS silicon gate technology. It is housed in a 64-pin shrink plastic
molded DIP.
In addition to their simple instruction sets, the ROM, RAM and I/O
addresses are placed on the same memory map to enable easy programming.
The M37270MF-XXXSP has a OSD function and a data slicer function, so it is useful for a channel selection system for TV with a closed
caption decoder. The features of the M37270EF-XXXSP and the
M37270EFSP are similar to those of the M37270MF-XXXSP except
that these chips have a built-in PROM which can be written electrically.
FEATURES
• Number of basic instructions ..................................................... 71
• Memory size
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
ROM ........................................................ 60 K bytes
RAM ........................................................ 1024 bytes
ROM for OSD ....................................... 14464 bytes
RAM for OSD ......................................... 1920 bytes
The minimum instruction execution time
.......................................... 0.5µs (at 8 MHz oscillation frequency)
Power source voltage .................................................. 5 V ± 10 %
Subroutine nesting ............................................. 128 levels (Max.)
Interrupts ....................................................... 18 types, 16 vectors
8-bit timers .................................................................................. 6
Programmable I/O ports (Ports P0, P1, P2, P3 0, P31) .............. 26
Input ports (Ports P40–P4 6, P63, P6 4) ......................................... 9
Output ports (Ports P3 2, P47, P5, P60–P6 2, P65–P6 7) ............. 16
12 V withstand ports .................................................................. 11
LED drive ports ........................................................................... 2
Serial I/O ............................................................ 8-bit ✕ 1 channel
Multi-master I2C-BUS interface ............................... 1 (2 systems)
A-D converter (8-bit resolution) ................................... 4 channels
PWM output circuit ........................................................... 8-bit ✕ 8
Interrupt interval determination circuit ......................................... 1
Power dissipation
In high-speed mode .......................................................... 165mW
(at VCC = 5.5V, 8MHz oscillation frequency, CRT on, and Data
slicer on)
In low-speed mode .......................................................... 0.33mW
(at VCC = 5.5V, 32kHz oscillation frequency)
Data slicer
• OSD function
Display characters ............................... 40 characters ✕ 16 lines
Kinds of characters ..................................................... 320 kinds
(In EXOSD mode, they can be combined with 32 kinds of extra
fonts)
Dot structure ........................................ CC mode : 16 ✕ 26 dots
OSD mode : 16 ✕ 20 dots
EXOSD mode : 16 ✕ 26 dots
Kinds of character sizes ................................ CC mode : 2 types
OSD mode : 14 types
EXOSD mode : 6 types
It can be specified by a character unit (maximum 7 kinds).
Character font coloring, character background coloring
It can be specified by a screen unit (maximum 7 kinds).
Extra font coloring, raster coloring, border coloring
Kinds of character colors ............... CC mode : 7 kinds (R, G, B)
OSD mode : 15 kinds (R, G, B, I)
EXOSD mode : 7 kinds (R, G, B, I1, I2)
Display position
Horizontal ................................................................ 256 levels
Vertical .................................................................. 1024 levels
Attribute ...................... CC mode : smooth italic, underline, flash
OSD mode : border
EXOSD mode : border,
extra font (32 kinds)
Automatic solid space function
Window function
Dual layer OSD function
APPLICATION
TV with a closed caption decoder
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
PIN CONFIGURATION (TOP VIEW)
HSYNC
1
64
P52/R
VSYNC
2
63
P40/AD4
3
62
P53/G
P54/B
4
61
P55/OUT1
5
60
P04/PWM0
P43/TIM3
6
59
P05/PWM1
P24/AD3
7
58
P60
P25/AD2
8
57
P06/PWM2
P26/AD1
9
56
P61
P27
P00/PWM4
P50/PWM7
P01/PWM5
10
55
P07/PWM3
54
53
P62
P20
52
P21
P47
14
51
P22
P02/PWM6
P51
15
50
P17/SIN
17
P23
P10/OUT2
P65
P32
18
P44/INT1
19
11
12
13
16
P56
20
P45/SOUT
21
P57
P46/SCLK
AVCC
22
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
P41/INT2
P42/TIM2
49
48
47
46
45
44
P67
43
P13/SDA1
23
42
24
41
P14/SDA2
P15/I1
HLF
25
40
RVCO
26
39
VHOLD
27
38
CVIN
CNVSS
XIN
28
37
P30
P31
29
36
RESET
30
35
XOUT
VSS
31
34
P64/OSC2/XCOUT
P63/OSC1/XCIN
32
33
VCC
Outline 64P4B
2
P11/SCL1
P66
P12/SCL2
P16/I2/INT3
P03
17 40 41 42 43 45 47 49
I/O port P1
I/O ports
Output port
P30, P31
P32
P1 (8)
Processor
status
register
PS (8)
18 37 36
P3 (3)
Data bus
RAM
1024 bytes
Accumulator
A (8)
Multi-master
I2C-BUS interface
8-bit
arithmetic
and
logical unit
Address bus
Clock
generating
circuit
31
Y (8)
X (8)
P2 (8)
A-D
converter
32
29
TIM3
TIM2
P0 (8)
Stack
pointer
S (8)
ROM
60 K bytes
Index
register
PCL (8)
PCH (8)
33
Index
register
Program
counter
24
Progam
counter
36
CNVSS
I/O port P2
I/O port P0
P4 (8)
Timer 6
T6 (8)
Timer 5
T5 (8)
Timer 4
T4 (8)
Timer 3
T3 (8)
Timer 2
T2 (8)
Timer 1
T1 (8)
Output port P47
26
25
8-bit
PWM circuit
Instruction
register (8)
Instruction
decoder
Control signal
Data slicer
27
Timer count source
selection circuit
28
HLF
VHOLD
CVIN
RVCO
Input ports P40–P46
14 23 21 19 6 5 4 3
SI/O (8)
10 9 8 7 50 51 52 53 55 57 59 60 39 15 13 11
OUT2
INT3
30
SDA2
SDA1
SCL2
SCL1
Reset input
RESET AVCC VCC VSS
SIN
SCLK
SOUT
XIN XOUT
PWM7
PWM6
PWM5
PWM4
PWM3
PWM2
PWM1
PWM0
Clock input Clock output
INT1
INT2
P5 (8)
Output ports
Output port P5
P60–P42 , P65–P47
1
HSYNC
Sync
signal input
44 46 48 54 56 58 16 12 61 62 63 64 20 22 2
P6 (8)
35
CRT circuit
34
Input ports P63, P64
Clock input for OSD/ Clock output for OSD/
sub-clock input sub-clock output
OSC1 OSC2
OUT1
B
G
R
Pins for data slicer
VSYNC
FUNCTIONAL BLOCK DIAGRAM of M37270MF-XXXSP
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
3
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
FUNCTIONS
Parameter
Functions
Number of basic instructions
71
Instruction execution time
0.5 µs (the minimum instruction execution time, at 8 MHz oscillation frequency)
Clock frequency
Memory size
Input/Output ports
8 MHz (maximum)
ROM
60 K bytes
RAM
1024 bytes
OSD ROM
14464 bytes
OSD RAM
1920 bytes
P00–P0 2,
P04–P0 7
I/O
7-bit ✕ 1 (N-channel open-drain output structure, can be used as PWM
output pins)
P03
I/O
1-bit ✕ 1 (CMOS input/output structure)
P10, P1 5–P1 7
I/O
4-bit ✕ 1 (CMOS input/output structure, can be used as OSD output pin,
INT input pin, serial input pin)
P11–P1 4
I/O
4-bit ✕ 1 (N-channel open-drain output structure, can be used as multimaster I2C-BUS interface)
P2
I/O
8-bit ✕ 1 (CMOS input/output structure, can be used as A-D input pins)
P30, P3 1
P32
4
I/O
Output
2-bit ✕ 1 (CMOS input/output structure)
1-bit ✕ 1 (N-channel open-drain output structure)
P40–P4 4
Input
5-bit ✕ 1 (can be used as A-D input pins, INT input pins, external clock
input pins)
P45, P4 6
Input
2-bit ✕ 1 (N-channel open-drain output structure when serial I/O is used,
can be used as serial I/O pins)
P47
Output
1-bit ✕ 1 (N-channel open-drain output structure)
P50, P5 1, P56 ,
P57
Output
4-bit ✕ 1 (N-channel open-drain output structure, can be used as PWM
output pins)
P52–P5 5
Output
4-bit ✕ 1 (CMOS output structure, can be used as OSD output)
P60–P6 2,
P65–P6 7
Output
6-bit ✕ 1 (N-channel open-drain output)
P63
Input
1-bit ✕ 1 (can be used as sub-clock input pin, OSD clock input pin)
P64
Input
1-bit ✕ 1 (CMOS output structure when LC is oscillating, can be used as
sub-clock output pin, OSD clock output pin)
Serial I/O
8-bit ✕ 1
Multi-master I2C-BUS interface
1
A-D converter
4 channels (8-bit resolution)
PWM output circuit
8-bit ✕ 8
Timers
8-bit timer ✕ 6
Subroutine nesting
128 levels (maximum)
Interrupt interval determination circuit
1
Interrupt
External interrupt ✕ 3, Internal timer interrupt ✕ 6, Serial I/O interrupt ✕ 1,
OSD interrupt ✕ 1, Multi-master I 2 C-BUS interface interrupt ✕ 1,
Data slicer interrupt ✕ 1, f(XIN)/4092 interrupt ✕ 1, V SYNC interrupt ✕ 1, AD conversion interrupt ✕ 1, BRK instruction interrupt ✕ 1
Clock generating circuit
2 built-in circuits (externally connected a ceramic resonator or a quartzcrystal oscillator)
Data slicer
Built in
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
FUNCTIONS (continued)
OSD function
Number of display characters
40 characters ✕ 16 lines
Dot structure
CC mode: 16 ✕ 26 dots (character part : 16 ✕ 20 dots)
OSD mode: 16 ✕ 20 dots
EXOSD mode: 16 ✕ 26 dots
Kinds of characters
320 kinds
(In EXOSDmode, they can be combined with 32 kinds of extra fonts)
Kinds of character sizes
CC mode: 2 kinds
OSD mode: 14 kinds
EXOSD mode: 6 kinds
Kinds of character colors
CC mode: 7 kinds (R, G, B)
OSD mode: 15 kinds (R, G, B, I1)
EXOSD mode: 7 kinds (R, G, B, I1, I2)
Display position (horizontal, vertical)
Power source voltage
Power dissipation
256 levels (horizontal) ✕ 1024 levels (vertical)
5 V ± 10 %
In high-speed OSD ON Data slicer ON
mode
OSD OFF Data slicer OFF
165 mW typ. (at oscillation frequency fCPU = 8 MHz, fOSD = 13 MHz)
In low-speed
mode
0.33mW typ. (at oscillation frequency fCLK = 32 kHz, f(XIN) = stopped)
In stop mode
OSD OFF Data slicer OFF
82.5 mW typ. (at oscillation frequency fCPU = 8 MHz)
0.055 mW (maximum)
Operating temperature range
–10 °C to 70 °C
Device structure
CMOS silicon gate process
Package
64-pin shrink plastic molded DIP
5
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
PIN DESCRIPTION
Pin
Name
Input/
Output
Functions
VCC ,
AVCC,
VSS.
Power source
CNVSS
CNVSS
RESET
Reset input
Input
To enter the reset state, the reset input pin must be kept at a “L” for 2 µs or more (under
normal VCC conditions).
If more time is needed for the quartz-crystal oscillator to stabilize, this “L” condition should
be maintained for the required time.
XIN
Clock input
Input
XOUT
Clock output
This chip has an internal clock generating circuit. To control generating frequency, an
external ceramic resonator or a quartz-crystal oscillator is connected between pins XIN and
XOUT. If an external clock is used, the clock source should be connected to the XIN pin and
the XOUT pin should be left open.
P00/PWM4–
P02/PWM6,
P03,
P04/PWM0–
P07/PWM3
I/O port P0
PWM output
P10/OUT2, I/O port P1
P11/SCL1,
P12/SCL2,
P13/SDA1,
OSD output
P14/SDA2,
P15/I1,
P16/I2/INT3, Multi-master
I2 C-BUS interface
P17/SIN
Serial I/O data
input
Apply voltage of 5 V ± 10 % (typical) to VCC and AVCC, and 0 V to VSS.
This is connected to VSS .
Output
I/O
Port P0 is an 8-bit I/O port with direction register allowing each I/O bit to be individually
programmed as input or output. At reset, this port is set to input mode. The output structure
of P03 is CMOS output, that of P00 –P02 and P04–P07 are N-channel open-drain output.
The note out of this Table gives a full of port P0 function.
Output
Pins P00–P02 and P04–P07 are also used as PWM output pins PWM4–PWM6 and PWM0–
PWM3 respectively. The output structure is N-channel open-drain output.
I/O
Port P1 is an 8-bit I/O port and has basically the same functions as port P0. The output
structure of P10 and P15–P17 is CMOS output, that of P11–P14 is N-channel open-drain
output.
Output
Pins P10, P15, P16 are also used as OSD output pins OUT2, I1, I2 respectively. The output
structure is CMOS output.
Output
Pins P11–P14 are used as SCL1, SCL2, SDA1 and SDA2 respectively, when multi-master
I 2C-BUS interface is used. The output structure is N-channel open-drain output.
Input
P17 pin is also used as serial I/O data input pin SIN.
P20–P2 3
P24/AD3–
P26/AD1,
P27
I/O port P2
P30, P3 1
I/O port P3
P32
Output port P3
P40/AD4,
P41/INT2,
P42/TIM2,
P43/TIM3,
P44/INT1,
P45/SOUT ,
P46/SCLK ,
Input port P4
Input
Analog input
Input
P40 pin is also used as analog input pin AD4.
External interrupt
input
Input
Pins P41, P44 are also used as external interrupt input INT2, INT1.
External clock input
Input
Pins P42 and P4 3 are also used as external clock input pins TIM2, TIM3 respectively.
Analog input
Serial I/O data
output
Serial I/O
synchronizing clock
input/output
I/O
Input
I/O
Output
Port P2 is an 8-bit I/O port and has basically the same functions as port P0. The output
structure is CMOS output.
Pins P24–P2 6 are also used as analog input pins AD3–AD1 respectively.
Ports P30 and P31 are a 2-bit I/O port and has basically the same functions as port P0. The
output structure is CMOS output.
Port P3 2 is a 1-bit output port. The output structure is N-channel open-drain output.
Ports P4 0–P4 6 are a 7-bit input port.
Output
P4 5 pin is used as serial I/O data output pin SOUT. The output structure is N-channel opendrain output.
I/O
P46 pin is used as serial I/O synchronizing clock input/output pin SCLK . The output structure is N-channel open-drain output.
Output port P4
Output
Port P47 is a 1-bit output port. The output structure is N-channel open-drain output.
Output port P5
P50/PWN7,
P51, P5 2/R,
P53/G, P5 4/B, PWM output
P55/OUT1,
OSD output
P56, P5 7
Output
Ports P5 0–P57 are an 8-bit output port. The output structure of P50 , P51, P56, P57 are Nchannel open-drain output, that of P52–P5 5 is CMOS output.
P47
6
Output
P50 pin is also used as PWM output pin PWM7.
Output
Pins P52–P55 are also used as OSD output pins R, G, B, OUT1 respectively.
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
PIN DESCRIPTION (continued)
P60–P6 2,
P65–P6 7
Output port
P63/OSC1/ Input port
XCIN,
Clock input for OSD
P64/OSC2/
Clock output for OSD
XCOUT
Sub-clock output
Sub-clock input
CV IN
I/O for data slicer
Output
Input
Ports P6 3 and P64 are 2-bit input port.
Input
P63 pin is also used as OSD clock input pin OSC1.
Output
P6 4 pin is also used as OSD clock output pin OSC2. The output structure is CMOS output.
Output
P6 4 pin is also used as sub-clock output pin XCOUT. The output structure is CMOS output.
Input
P63 pin is also used as sub-clock input pin X CIN.
Input
Input composite video signal through a capacitor.
Input
VHOLD
Ports P60–P62, P65–P67 are a 6–bit output port. The output structure is N-channel opendrain output.
RVCO
Connect a capacitor between V HOLD and V SS.
Connect a resistor between RVCO and VSS.
HLF
Connect a filter using of a capacitor and a resistor between HLF and VSS .
HSYNC
HSYNC input
Input
VSYNC
VSYNC input
Input
This is a horizontal synchronizing signal input for OSD.
This is a vertical synchronizing signal input for OSD.
Note : As shown in the memory map (Figure 3), port P0 is accessed as a memory at address 00C016 of zero page. Port P0 has the port P0
direction register (address 00C116 of zero page) which can be used to program each bit as an input (“0”) or an output (“1”). The pins
programmed as “1” in the direction register are output pins. When pins are programmed as “0,” they are input pins. When pins are
programmed as output pins, the output data are written into the port latch and then output. When data is read from the output pins, the
output pin level is not read but the data of the port latch is read. This allows a previously-output value to be read correctly even if the
output “L” voltage has risen, for example, because a light emitting diode was directly driven. The input pins are in the floating state, so the
values of the pins can be read. When data is written into the input pin, it is written only into the port latch, while the pin remains in the
floating state.
7
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
FUNCTIONAL DESCRIPTION
Central Processing Unit (CPU)
CPU Mode Register
The M37270MF-XXXSP uses the standard 740 family instruction set.
Refer to the table of 740 family addressing modes and machine instructions or the SERIES 740 <Software> User’s Manual for details
on the instruction set.
Machine-resident 740 family instructions are as follows:
The FST, SLW instruction cannot be used.
The MUL, DIV, WIT and STP instruction can be used.
7
The CPU mode register contains the stack page selection bit and
internal system clock selection bit. The CPU mode register is allocated at address 00FB16.
0
1
1
0
0
CPU mode register
(CPUM (CM) : address 00FB16)
Processor mode bits
b1 b0
0
0
1
1
0 : Single-chip mode
1:
0 : Not available
1:
Stack page selection bit (Note)
0 : Zero page
1 : 1 page
Fix these bits to “1.”
XCOUT drivability selection bit
0 : Low drive
1 : High drive
Main colock (XIN–XOUT) stop bit
0 : Oscillating
1 : Stopped
Internal system clock selection bit
0 : XIN–XOUT selected (high-speed mode)
1 : XCIN–XCOUT selected (low-speed mode)
Note: Please beware of this bit when programming because it
is set to “1” after the reset release.
Fig. 1. Structure of CPU mode register
8
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
MEMORY
Special Function Register (SFR) Area
Interrupt Vector Area
The interrupt vector area contains reset and interrupt vectors.
The special function register (SFR) area in the zero page contains
control registers such as I/O ports and timers.
Zero Page
ROM
The 256 bytes from addresses 000016 to 00FF16 are called the zero
page area. The internal RAM and the special function registers (SFR)
are allocated to this area.
The zero page addressing mode can be used to specify memory and
register addresses in the zero page area. Access to this area with
only 2 bytes is possible in the zero page addressing mode.
ROM is used for storing user programs as well as the interrupt vector
area.
Special Page
RAM
RAM is used for data storage and for stack area of subroutine calls
and interrupts.
RAM for OSD
RAM for display is used for specifying the character codes and colors to display.
The 256 bytes from addresses FF0016 to FFFF 16 are called the special page area. The special page addressing mode can be used to
specify memory addresses in the special page area. Access to this
area with only 2 bytes is possible in the special page addressing
mode.
ROM for OSD
ROM for display is used for storing character data.
000016
1000016
Not used
1080016
00C016
00FF16
RAM
(1024 bytes)
Zero page
SFR1 area
020016
023F16
SFR2 area
1567F16
Not used
Not used
030016
1800016
ROM for OSD
(14464 bytes)
053F16
Not used
RAM for OSD (Note)
(1920 bytes)
080016
0FFF16
100016
ROM
(60 K bytes)
FF0016
FFDE16
FFFF16
1E43F16
Interrupt vector area
Not used
Special page
1FFFF16
Fig. 2. Memory map
9
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
00C016
00C116
00C216
00C316
00C416
00C516
00C616
00C716
00C816
00C916
00CA16
00CB16
00CC16
00CD16
00CE16
00CF16
00D016
00D116
00D216
00D316
00D416
00D516
00D616
00D716
00D816
00D916
00DA16
00DB16
00DC16
00DD16
00DE16
00DF16
Port P0
Port P0 direction register
Port P1
Port P1 direction register
Port P2
Port P2 direction register
Port P3
Port P3 direction register
Port P4
Port P4 direction register
Port P5
OSD port control register
Port P6
OSD control register
Horizontal position register
Block control register 1
Block control register 2
Block control register 3
Block control register 4
Block control register 5
Block control register 6
Block control register 7
Block control register 8
Block control register 9
Block control register 10
Block control register 11
Block control register 12
Block control register 13
Block control register 14
Block control register 15
Block control register 16
Fig. 3. Memory map of special function register 1 (SFR1)
10
00E016
00E116
00E216
00E316
00E416
00E516
00E616
00E716
00E816
00E916
00EA16
00EB16
00EC16
00ED16
00EE16
00EF16
00F016
00F116
00F216
00F316
00F416
00F516
00F616
00F716
00F816
00F916
00FA16
00FB16
00FC16
00FD16
00FE16
00FF16
Caption position register
Start bit position register
Window register
Sync slice register
Data register 1
Data register 2
Clock run-in register 1
Clock run-in register 2
Clock run-in detect register 1
Clock run-in detect register 2
Data slicer control register 1
Data slicer control register 2
Data register 3
Data register 4
A-D register
A-D control register
Timer 1
Timer 2
Timer 3
Timer 4
Timer mode register 1
Timer mode register 2
I 2 C data shift register
I 2C address register
2
I C status register
2
I C control register
I 2 C clock control register
CPU mode register
Interrupt request register 1
Interrupt request register 2
Interrupt control register 1
Interrupt control register 2
MITSUBISHI MICROCOMPUTERS
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SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
020016
020116
020216
020316
020416
020516
020616
020716
020816
020916
020A16
020B16
020C16
020D16
020E16
020F16
021016
021116
021216
021316
021416
021516
021616
021716
021816
021916
021A16
021B16
021C16
021D16
021E16
021F16
PWM0 register
PWM1 register
PWM2 register
PWM3 register
PWM4 register
PWM5 register
PWM6 register
PWM7 register
Clock run-in detect register 3
Clock run-in register 3
PWM mode register 1
PWM mode register 2
Timer 5
Timer 6
Sync pulse counter register
Data slicer control register 3
Interrupt interval determination register
Interrupt interval determination control register
Serial I/O mode register
Serial I/O register
Clock source control register
I/O polarity control register
Raster color register
Extra font color register
Border color register
Window H register 1
Window L register 1
Window H register 2
Window L register 2
022016
022116
022216
022316
022416
022516
022616
022716
022816
022916
022A16
022B16
022C16
022D16
022E16
022F16
023016
023116
023216
023316
023416
023516
023616
023716
023816
023916
023A16
023B16
023C16
023D16
023E16
023F16
Vertical register 11
Vertical register 12
Vertical register 13
Vertical register 14
Vertical register 15
Vertical register 16
Vertical register 17
Vertical register 18
Vertical register 19
Vertical register 110
Vertical register 111
Vertical register 112
Vertical register 113
Vertical register 114
Vertical register 115
Vertical register 116
Vertical register 21
Vertical register 22
Vertical register 23
Vertical register 24
Vertical register 25
Vertical register 26
Vertical register 27
Vertical register 28
Vertical register 29
Vertical register 210
Vertical register 211
Vertical register 212
Vertical register 213
Vertical register 214
Vertical register 215
Vertical register 216
Fig. 4. Memory map of special function register 2 (SFR2)
11
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
INTERRUPTS
Interrupt Causes
Interrupts can be caused by 18 different sources consisting of 4 external, 12 internal, 1 software, and reset. Interrupts are vectored interrupts with priorities shown in Table 1. Reset is also included in the
table because its operation is similar to an interrupt.
When an interrupt is accepted,
(1) The contents of the program counter and processor status
register are automatically stored into the stack.
(2) The interrupt disable flag I is set to “1” and the corresponding
interrupt request bit is set to “0.”
(3) The jump destination address stored in the vector address enters
the program counter.
Other interrupts are disabled when the interrupt disable flag is set to
“1.”
All interrupts except the BRK instruction interrupt have an interrupt
request bit and an interrupt enable bit. The interrupt request bits are
in interrupt request registers 1 and 2 and the interrupt enable bits are
in interrupt control registers 1 and 2. Figure 5 shows the structure of
the interrupt-related registers.
Interrupts other than the BRK instruction interrupt and reset are accepted when the interrupt enable bit is “1,” interrupt request bit is “1,”
and the interrupt disable flag is “0.” The interrupt request bit can be
set to “0” by a program, but not set to “1.” The interrupt enable bit can
be set to “0” and “1” by a program.
Reset is treated as a non-maskable interrupt with the highest priority.
Figure 6 shows interrupt control.
(1) VSYNC and OSD interrupts
The VSYNC interrupt is an interrupt request synchronized with
the vertical sync signal.
The OSD interrupt occurs after character block display to the
CRT is completed.
(2) INT1, INT2, INT3 interrupts
With an external interrupt input, the system detects that the level
of a pin changes from “L” to “H” or from “H” to “L,” and generates
an interrupt request. The input active edge can be selected by
bits 3, 4 and 6 of the interrupt interval determination control register (address 021216) : when this bit is “0,” a change from “L” to
“H” is detected; when it is “1,” a change from “H” to “L” is detected. Note that all bits are cleared to “0” at reset.
(3) Timer 1, 2, 3 and 4 interrupts
An interrupt is generated by an overflow of timer 1, 2, 3 or 4.
(4) Serial I/O interrupt
This is an interrupt request from the clock synchronous serial
I/O function.
(5) f(XIN)/4096 interrupt
This interrupt occurs regularly with a f(XIN)/4096 period. Set bit 0
of the PWM mode register 1 to “0.”
(6) Data slicer interrupt
An interrupt occurs when slicing data is completed.
(7) Multi-master I2C-BUS interface interrupt
This is an interrupt request related to the multi-master I2C-BUS
interface.
(8) A-D conversion interrupt
An interrupt occurs at the completion of A-D conversion. Since
A-D conversion interrupt and the INT3 interrupt share the same
vector, an interrupt source is selected by bit 7 of the interrupt
interval determination control register (address 021216).
Table 1. Interrupt vector addresses and priority
Interrupt source
Priority
Vector addresses
Reset
1
FFFF16 , FFFE16
OSD interrupt
2
FFFD16, FFFC16
INT1 interrupt
3
FFFB16, FFFA16
Data slicer interrupt
4
FFF916 , FFF816
Serial I/O interrupt
5
FFF716 , FFF616
Timer 4 interrupt
6
FFF516 , FFF416
f(XIN)/4096 interrupt
7
FFF316 , FFF216
VSYNC interrupt
8
FFF116 , FFF016
Timer 3 interrupt
9
FFEF16, FFEE16
Timer 2 interrupt
10
FFED16, FFEC16
Timer 1 interrupt
11
FFEB16, FFEA16
A-D convertion · INT3 interrupt
12
FFE916 , FFE816
Active edge selectable
INT2 interrupt
13
FFE716 , FFE616
Active edge selectable
Multi-master I2C-BUS interface interrupt
14
FFE516 , FFE416
Timer 5 · 6 interrupt
15
FFE316 , FFE216
BRK instruction interrupt
16
FFDF16, FFDE16
12
Remarks
Non-maskable
Active edge selectable
Active edge selectable
Non-maskable (software interrupt)
MITSUBISHI MICROCOMPUTERS
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SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
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(9)Timer 5 · 6 interrupt
An interrupt is generated by an overflow of timer 5 or 6. Their
priorities are same, and can be switched by software.
(10)BRK instruction interrupt
This software interrupt has the least significant priority. It does
not have a corresponding interrupt enable bit, and it is not affected by the interrupt disable flag I (non-maskable).
Interrupt request bit
Interrupt enable bit
Interrupt disable flag I
BRK instruction
Reset
Interrupt
request
Fig. 6. Interrupt control
7
0
7
Interrupt request register 1
(IREQ1: address 00FC16)
0
Interrupt request register 2
(IREQ2: address 00FD16)
0
Timer 1 interrupt request bit
INT1 interrupt request bit
Timer 2 interrupt request bit
Data slicer interrupt request bit
Timer 3 interrupt request bit
Serial I/O interrupt request bit
Timer 4 interrupt request bit
f(XIN)/4096 interrupt request bit
OSD interrupt request bit
INT2 interrupt request bit
Multi-master I2C-BUS
interface interrupt request bit
VSYNC interrupt request bit
A-D conversion • INT3 interrupt
request bit
Timer 5 • 6 interrupt request bit
Fix this bit to “0.”
0 : No interrupt request issued
1 : Interrupt request issued
7
0
7
Interrupt control register 1
( ICON1: address 00FE16)
0
Interrupt control register 2
( ICON2 : address 00FF16)
Timer 1 interrupt enable bit
INT1 interrupt enable bit
Timer 2 interrupt enable bit
Data slicer interrupt enable bit
Timer 3 interrupt enable bit
Serial I/O interrupt enable bit
Timer 4 interrupt enable bit
f(XIN)/4096 interrupt enable bit
OSD interrupt enable bit
INT2 interrupt enable bit
VSYNC interrupt enable bit
Multi-master I2C-BUS
interface enable bit
A-D conversion • INT3 interrupt
request bit
0 : Interrupt disabled
1 : Interrupt enabled
Timer 5 • 6 interrupt enable bit
Timer 5 • 6 interrupt switch bit
0 : Timer 5
1 : Timer 6
Fig. 5. Structure of interrupt-related registers
13
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
TIMERS
(5) Timer 5
The M37270MF-XXXSP has 6 timers: timer 1, timer 2, timer 3,
timer 4, timer 5, and timer 6. All timers are 8-bit timers with the 8-bit
timer latch. The timer block diagram is shown in Figure 8.
All of the timers count down and their divide ratio is 1/(n+1), where n
is the value of timer latch. The value is set to a timer at the same time
by writing a count value to the corresponding timer latch (addresses
00F016 to 00F316 : timers 1 to 4, addresses 020C 16 and 020D16 :
timers 5 and 6).
The count value is decremented by 1. The timer interrupt request bit
is set to “1” by a timer overflow at the next count pulse after the count
value reaches “0016”.
Timer 5 can select one of the following count sources:
f(X IN)/16 or f(X CIN)/16
Timer 2 overflow signal
Timer 4 overflow signal
The count source of timer 3 is selected by setting bit 6 of the timer
mode register 1 (address 00F416) and bit 7 of the timer mode register 2 (address 00F516 ). Either f(XIN) or f(XCIN) is selected by bit 7 of
the CPU mode register.
Timer 5 interrupt request occurs at timer 5 overflow.
(1) Timer 1
Timer 1 can select one of the following count sources:
f(XIN)/16 or f(XCIN)/16
f(XIN)/4096 or f(XCIN)/4096
External clock from the P42/TIM2 pin
The count source of timer 1 is selected by setting bits 5 and 0 of the
timer mode register 1 (address 00F416 ). Either f(XIN) or f(XCIN ) is
selected by bit 7 of the CPU mode register.
Timer 1 interrupt request occurs at timer 1 overflow.
•
•
•
(2) Timer 2
Timer 2 can select one of the following count sources:
f(XIN)/16 or f(XCIN)/16
Timer 1 overflow signal
External clock from the P42/TIM2 pin
The count source of timer 2 is selected by setting bits 4 and 1 of the
timer mode register 1 (address 00F416 ). Either f(XIN) or f(XCIN ) is
selected by bit 7 of the CPU mode register. When timer 1 overflow
signal is a count source for the timer 2, the timer 1 functions as an 8bit prescaler.
Timer 2 interrupt request occurs at timer 2 overflow.
•
•
•
(3) Timer 3
Timer 3 can select one of the following count sources:
f(XIN)/16 or f(XCIN)/16
f(XCIN)
External clock from the P43/TIM3 pin
The count source of timer 3 is selected by setting bit 0 of the timer
mode register 2 (address 00F516) and bit 6 at address 00C716. Either f(XIN) or f(XCIN) is selected by bit 7 of the CPU mode register.
Timer 3 interrupt request occurs at timer 3 overflow.
•
•
•
(4) Timer 4
Timer 4 can select one of the following count sources:
f(XIN)/16 or f(XCIN)/16
f(XIN)/2 or f(XCIN)/2
f(XCIN)
The count source of timer 3 is selected by setting bits 4 and 1 of the
timer mode register 2 (address 00F516 ). Either f(XIN) or f(XCIN ) is
selected by bit 7 of the CPU mode register. When timer 3 overflow
signal is a count source for the timer 4, the timer 3 functions as an 8bit prescaler.
Timer 4 interrupt request occurs at timer 4 overflow.
•
•
•
14
•
•
•
(6) Timer 6
Timer 6 can select one of the following count sources:
f(X IN)/16 or f(X CIN)/16
Timer 5 overflow signal
The count source of timer 6 is selected by setting bit 7 of the timer
mode register 1 (address 00F416). Either f(XIN) or f(XCIN) is selected
by bit 7 of the CPU mode register. When timer 5 overflow signal is a
count source for the timer 6, the timer 5 functions as an 8-bit prescaler.
Timer 6 interrupt request occurs at timer 6 overflow.
•
•
At reset, timers 3 and 4 are connected by hardware and “FF16 ” is
automatically set in timer 3; “0716” in timer 4. The f(XIN) ✽ /16 is selected as the timer 3 count source. The internal reset is released by
timer 4 overflow at these state, the internal clock is connected.
At execution of the STP instruction, timers 3 and 4 are connected by
hardware and “FF16” is automatically set in timer 3; “0716” in timer 4.
However, the f(XIN) ✽ /16 is not selected as the timer 3 count source.
So set both bit 0 of the timer mode register 2 (address 00F516) and
bit 6 at address 00C716 to “0” before the execution of the STP instruction (f(XIN) ✽ /16 is selected as the timer 3 count source). The
internal STP state is released by timer 4 overflow at these state, the
internal clock is connected.
Because of this, the program starts with the stable clock.
✽ : When bit 7 of the CPU mode register (CM 7) is “1,” f(XIN) becomes f(XCIN).
The structure of timer-related registers is shown in Figure 7.
MITSUBISHI MICROCOMPUTERS
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SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
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7
0
7
Timer mode register 1
(TMR1 : address 00F416)
Timer 1 count source selection bit 1
0 : f(XIN)/16 or f(XCIN)/16 (Note)
1 : Count source selected by bit 5
of TMR1
Timer 2 count source selection bit 1
0 : Count source selected by bit 4 of
TMR1
1 : External clock from P42/TIM2 pin
Timer 1 count stop bit
0 : Count start
1 : Count stop
Timer 2 count stop bit
0 : Count start
1 : Count stop
Timer 2 count source selection bit 2
0 : f(XIN)/16 or f(XCIN)/16 (Note)
1 : Timer 1 overflow
0
Timer mode register 2
(TMR2 : address 00F516)
Timer 3 count source selection bit
(Bit 6 at
address
00C716) b0
0
1
0
1
0 : f(XIN)/16 or f(XCIN)/16 (Note)
0 : f(XCIN)
1 : External clock from
1 : P43/TIM3 pin
Timer 4 count source selection bits
b4 b1
0 : Timer 3 overflow
0
1 : f(XIN)/16 or f(XCIN)/16 (Note)
0
0 : f(XIN)/2 or f(XCIN)/2 (Note)
1
1 : f(XCIN)
1
Timer 3 count stop bit
0 : Count start
1 : Count stop
Timer 1 count source selection bit 2
0 : f(XIN)/4096 or f(XCIN)/4096 (Note)
1 : External clock from P42/TIM2
pin
Timer 5 count source selection bit 2
0 : Timer 2 overflow
1 : Timer 4 overflow
Timer 4 count stop bit
0 : Count start
1 : Count stop
Timer 6 count source selection bit
0 : f(XIN)/16 or f(XCIN)/16 (Note)
1 : Timer 5 overflow
Timer 6 count stop bit
0 : Count start
1 : Count stop
Timer 5 count stop bit
0 : Count start
1 : Count stop
Timer 5 count source selection bit 1
0 : f(XIN)/16 or f(XCIN)/16 (Note)
1 : Count source selected by bit 6
of TMR1
Note : Either f(XIN) or f(XCIN) is selected by bit 7 of the CPU mode register.
Fig. 7. Structure of timer-related registers
15
MITSUBISHI MICROCOMPUTERS
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SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
Data bus
8
XCIN
CM7
TMR15
Timer 1 latch (8)
1/4096
8
XIN
1/8
1/2
Timer 1
interrupt request
Timer 1 (8)
TMR10
TMR12
8
TMR14
8
Timer 2 latch (8)
8
P42/TIM2
Timer 2
interrupt request
Timer 2 (8)
TMR11
TMR13
8
8
FF16
TM3EL
Reset
STP instruction
Timer 3 latch (8)
8
Timer 3
interrupt request
Timer 3 (8)
P43/TIM3
TMR20
TMR22
8
8
0716
TMR21
Timer 4 latch (8)
8
Timer 4
interrupt request
Timer 4 (8)
TMR21
TMR24
TMR23
8
8
TMR16
Timer 5 latch (8)
Selection gate : Connected to
black colored
side at reset
8
Timer 5
interrupt request
Timer 5 (8)
TMR1 : Timer mode register 1
TMR2 : Timer mode register 2
TM3EL : Timer 3 count source
switch bit (address 00C716)
CM : CPU mode register
TMR27
TMR25
8
8
Timer 6 latch (8)
8
Timer 6
interrupt request
Timer 6 (8)
TMR17
TMR26
8
Notes 1: “H” pulse width of external clock inputs TIM2 and TIM3 needs 4 machine cycles or more.
2: When the external clock source is selected, timers 1, 2, and 3 are counted at a rising edge of input signal.
3: In the stop mode or the wait mode, external clock inputs TIM2 and TIM3 cannot be used.
Fig. 8. Timer block diagram
16
MITSUBISHI MICROCOMPUTERS
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M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
SERIAL I/O
The M37270MF-XXXSP has a built-in serial I/O which can either transmit or receive 8-bit data in serial in the clock synchronous mode.
The serial I/O block diagram is shown in Figure 9. The synchronizing
clock I/O pin (SCLK), and data output pin (SOUT) also function as port
P4, data input pin (SIN) also functions as port P1.
Bit 2 of the serial I/O mode register (address 021316) selects whether
the synchronizing clock is supplied internally or externally (from the
P46/SCLK pin). When an internal clock is selected, bits 1 and 0 select
whether f(XIN) or f(XCIN) is divided by 8, 16, 32, or 64. To use P45/
SOUT and P46/SCLK pins for serial I/O, set the corresponding bits of
the port P4 direction register (address 00C916) to “0.” To use P17/SIN
pin for serial I/O, set the corresponding bit of the port P1 direction
register (address 00C316) to “0.”
The operation of the serial I/O function is described below. The function of the serial I/O differs depending on the clock source; external
clock or internal clock.
XCIN
1/2
XIN
1/2
Data bus
Frequency divider
1/2
CM7
1/2
Synchronization
circuit
P46/SCLK
P45/SOUT
1/4
1/8
1/16
SM1
SM0
SM2
S
CM : CPU mode register
SM : Serial I/O mode register
Serial I/O
interrupt request
Serial I/O counter (8)
SM5 : LSB
Selection gate: Connect to
black colored
side at reset.
MSB
(Note)
P17/SIN
Serial I/O shift register (8)
8 (Address 021416)
Note : When the data is set in the serial I/O register (address 021416), the register functions as the serial I/O shift register.
Fig. 9. Serial I/O block diagram
17
MITSUBISHI MICROCOMPUTERS
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SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
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Internal clock—the serial I/O counter is set to “7” during write cycle
into the serial I/O register (address 021416), and transfer clock goes
“H” forcibly. At each falling edge of the transfer clock after the write
cycle, serial data is output from the SOUT pin. Transfer direction can
be selected by bit 5 of the serial I/O mode register. At each rising
edge of the transfer clock, data is input from the SIN pin and data in
the serial I/O register is shifted 1 bit.
After the transfer clock has counted 8 times, the serial I/O counter
becomes “0” and the transfer clock stops at “H.” At this time the interrupt request bit is set to “1.”
External clock—when an external clock is selected as the clock
source, the interrupt request is set to “1” after the transfer clock has
counted 8 times. However, transfer operation does not stop, so control the clock externally. Use the external clock of 500kHz or less
with a duty cycle of 50%.
The serial I/O timing is shown in Figure 10. When using an external
clock for transfer, the external clock must be held at “H” for initializing
the serial I/O counter. When switching between an internal clock and
an external clock, do not switch during transfer. Also, be sure to initialize the serial I/O counter after switching.
7
0
Serial I/O mode register
(SM : address 021316)
0 0
Internal synchronizing clock
selection bits
b1 b0
0 0 : f(XIN)/8 or f(XCIN)/8
0 1 : f(XIN)/16 or f(XCIN)/16
1 0 : f(XIN)/32 or f(XCIN)/32
1 1 : f(XIN)/64 or f(XCIN)/64
Synchronizing clock selection bit
0 : External clock
1 : Internal clock
Port function selection bit
0 : P11, P13 functions as port
1 : SCL1, SDA1
Port function selection bit
0 : P12, P14 functions as port
1 : SCL2, SDA2
Notes 1: On programming, note that the serial I/O counter is set by
writing to the serial I/O register with the bit managing instructions as SEB and CLB instructions.
2: When an external clock is used as the synchronizing clock,
write transmit data to the serial I/O register at “H” of the
transfer clock input level.
Transfer direction selection bit
0 : LSB first
1 : MSB first
Fix these bits to “0”
Fig. 11. Structure of serial I/O mode register
Synchroninzing clock
Transfer clock
Serial I/O register
write signal
Serial I/O output
SOUT
(Note)
D0
D1
D2
D3
D4
D5
D6
D7
Serial I/O input
SIN
Interrupt request bit is set to “1”
Note : When an internal clock is selected, the SOUT pin is at high-impedance after transfer is completed.
Fig. 10. Serial I/O timing (for LSB first)
18
MITSUBISHI MICROCOMPUTERS
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SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
PWM OUTPUT FUNCTION
The M37270MF-XXXSP is equipped with eight 8-bit PWMs (PWM0–PWM7). PWM0–PWM7 have the same circuit structure and an 8bit resolution with minimum resolution bit width of 4µs (for f(X IN) =
8 MHz) and repeat period of 1024µs.
Figure 12 shows the PWM block diagram. The PWM timing generating circuit applies individual control signals to PWM0–PWM7 using
f(XIN) divided by 2 as a reference signal.
(1) Data Setting
When outputting PWM0–PWM7, set 8-bit output data in the PWMi
register (i means 0 to 7; addresses 020016 to 020716).
(2) Transmitting Data from Register to PWM circuit
Data transfer from the 8-bit PWM register to 8-bit PWM circuit is
executed at writing data to the register.
The signal output from the 8-bit PWM output pin corresponds to the
contents of this register.
(3) Operating of 8-bit PWM
The following is the explanation about PWM operation.
At first, set the bit 0 of PWM mode register 1 (address 020A16) to “0”
(at reset, bit 0 is already set to “0” automatically), so that the PWM
count source is supplied.
PWM0–PWM3 are also used as pins P04–P07, PWM4–PWM6 are
also used as pins P00–P02 , PWM7 is also used as pins P50, respectively. Set the corresponding bits of the port P0 direction register to “1” (output mode). And select each output polarity by bit 3 of
the PWM mode register 1 (address 020A16). Then, set bits 7 to 0 of
the PWM output control register 2 to “1” (PWM output).
The PWM waveform is output from the PWM output pins by setting
these registers.
Figure 13 shows the 8-bit PWM timing. One cycle (T) is composed
of 256 (28) segments. The 8 kinds of pulses relative to the weight of
each bit (bits 0 to 7) are output inside the circuit during 1 cycle. Refer
to Figure 13 (a). The 8-bit PWM outputs waveform which is the logical sum (OR) of pulses corresponding to the contents of bits 0 to 7 of
the 8-bit PWM register. Several examples are shown in Figure 13
(b). 256 kinds of output (“H” level area: 0/256 to 255/256) are selected by changing the contents of the PWM register. A length of
entirely “H” output cannot be output, i.e. 256/256.
(4) Output after Reset
At reset, the output of ports P00–P02 and P04 –P07 is in the highimpedance state, port P50 outputs “L,” and the contents of the PWM
register and the PWM circuit are undefined. Note that after reset, the
PWM output is undefined until setting the PWM register.
19
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
Data bus
XIN
1/2
PN0
PWM timing
generating
circuit
PWM0 register
(Address 020016)
b7
b0
8
PN3
P04
D04
PWM0
D05
PWM1
D06
PWM2
D07
PWM3
D00
PWM4
D01
PWM5
D02
PWM6
8-bit PWM circuit
PW0
P05
PWM1 register (Address 020116)
PW1
P06
PWM2 register (Address 020216)
PW2
P07
PWM3 register (Address 020316)
PW3
P00
PWM4 register (Address 020416)
PW4
P01
PWM5 register (Address 020516)
PW5
P02
PWM6 register (Address 020616)
PW6
P50
Selection gate :
Connected to
black colored
side at reset.
Inside of
Fig. 12. PWM block diagram
20
PWM7 register (Address 020716)
is as same contents with the others.
PWM7
PW7
PN : PWM mode register 1 (address 020A16)
PW : PWM mode register 2 (address 020B16)
P0 : Port P0 register (address 00C016)
D0 : Port P0 direction register (address 00C116)
FF16 (255)
1816 (24)
0116 (1)
0016 (0)
Bit 0
Bit 1
Bit 2
Bit 3
Bit 4
Bit 5
Bit 6
Bit 7
t
2
4
6
8
12
10
13 5 7 9
16
14 18
20
30
28
34
32
26 30
24
22
20
36
40
44
38 42
40
52
60
64
72
80
88
100
110
120
130
140
150
160
170
180
190
200
210
220
230
240
250 255
104
112
108
124
120
116
128
136
132
144
140
156
152
148
T = 256 t
(b) Example of 8-bit PWM
t = 4 µs T = 1024 µs
f(XIN) = 8 MHz
164
160
(a) Pulses showing the weight of each bit
96
100
168
172
176
180
184
188
192
196
200
212
208
204
216
224
220
228
232
244
240
236
248
252
94 98 102 106 110 114 118 122 126 130 134 138 142 146 150 154 158 162 166 170 174 178 182 186 190 194 198 202 206 210 214 218 222 226 230 234 238 242 246 250 254
92
90
90
PWM output
84
82 86
80
78
76
70 74
70
68
62 66
60
58
56
50 54
48
46
50
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
Fig. 13. 8-bit PWM timing
21
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
7
0
PWM mode register 1
(PN: address 020A16)
PWM mode register 2
(PW: address 020B16)
PWM count source selection bit
0 : Count source supply
1 : Count source stop
P04/PWM0 output selection bit
0 : P04 output
1 : PWM0 output
PWM output polarity selection bit
0 : Positive polarity
1 : Negative polarity
P05/PWM1 output selection bit
0 : P05 output
1 : PWM1 output
P06/PWM2 output selection bit
0 : P06 output
1 : PWM2 output
P07/PWM3 output selection bit
0 : P07 output
1 : PWM3 output
P00/PWM4 output selection bit
0 : P00 output
1 : PWM4 output
P01/PWM5 output selection bit
0 : P01 output
1 : PWM5 output
P02/PWM6 output selection bit
0 : P02 output
1 : PWM6 output
P50/PWM7 output selection bit
0 : P50 output
1 : PWM7 output
Fig. 14. Structure of PWM-related registers
22
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
A-D CONVERTER
(1)A-D Conversion Register (AD)
(5)Comparator and Control Circuit
The conversion result of the analog input voltage and the reference
voltage “Vref” is stored in the A-D conversion register. The A-D conversion completion bit and A-D conversion interrupt request bit are
set to “1” at the completion of A-D conversion.
A-D conversion reigister is a read-only register that stores the result
of an A-D conversion. This register should not be read during A-D
conversion.
(2)A-D Control Register (ADCON)
The A-D control register controls A-D conversion. Bits 1 and 0 of this
register select analog input pins. When these pins are not used as
anlog input pins, they are used as ordinary I/O pins. Bit 3 is the A-D
conversion completion bit, A-D conversion is started by writing “0” to
this bit. The value of this bit remains at “0” during an A-D conversion,
then changes to “1” when the A-D conversion is completed.
Bit 4 controls connection between the resistor ladder and V CC. When
not using the A-D converter, the resistor ladder can be cut off from
the internal V CC by setting this bit to “0.” This can realize the lowpower dissipation.
7
0
0
A-D control register
(ADCON: address 00EF16)
Analog input pin selection bits
b1 b0
0 0 : P26/AD1
0 1 : P25/AD2
1 0 : P24/AD3
1 1 : P40/AD4
A-D conversion completion bit
0 : Conversion in purogress
1 : Conversion completed
(3)Comparison Voltage Generator (Resistor
Ladder)
VCC connection selection bit
0 : OFF
1 : ON
Fix this bit to “0.”
The voltage generator divides the voltage between VSS and VCC by
256, and outputs the divided voltages to the comparator as the reference voltage Vref.
(4)Channel Selector
The channel selector connects an analog input pin selected by bits 1
and 0 of the A-D control register to the comparator.
Fig. 15. Structure of A-D control register
Data bus
b7
b0
A-D control register
( address 00EF16)
2
P26/AD1
P25/AD2
P24/AD3
P40/AD4
Channel selector
A-D control circuit
Comparator
A-D conversion
interrupt request
A-D conversion register
8 ( address 00EE16)
Switch tree
Resistor ladder
VSS VCC
Fig. 16. A-D comparator block diagram
23
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
(6) Conversion Method
(7) Internal Operation
➀ Set bit 7 of the interrupt interval determination control register (address 021216 ) to “1” to generate an interrupt request at completion of A-D conversion.
➁ Set the A-D conversion • INT3 interrupt request bit to “0” (even
when A-D conversion is started, the A-D conversion • INT3 interrupt bit is not set to “0” automatically).
➂ When using A-D conversion interrupt, enable interrupts by setting
A-D conversion • INT3 interrupt request bit to “1” and setting the
interrupt disable flag to “0.”
➃ Set the VCC connection selection bit to “1” to connect V CC to the
resistor ladder.
➄ Select analog input pins by setting the analog input selection bit of
the A-D control register.
➅ Set the A-D conversion completion bit to “0.” This write operation
starts the A-D conversion. Do not read the A-D conversion register during the A-D conversion.
➆ Verify the completion of the conversion by the state (“1”) of the
A-D conversion completion bit, that (“1”) of A-D conversion • INT3
interrupt bit, or the occurrence of an A-D conversion interrupt.
➇ Read the A-D conversion register to obtain the conversion results.
At the time when the A-D conversion starts, the following operations
are automatically performed.
➀ The A-D conversion register is set to “0016 .”
➁ The most significant bit of the A-D conversion register becomes
“1, ” and the comparison voltage “Vref” is input to the comparator.
At this point, Vref is compared with the analog input voltage “VIN .”
➂ Bit 7 is determined by the comparison result as follows.
When Vref < VIN : bit 7 holds “1”
When Vref > VIN : bit 7 becomes “0”
With the above operations, the analog value is converted into a digital value. The A-D conversion terminates in a maximum 50 machine
cycles (12.5µs at f(X IN) = 8 MHz) after it starts, and the conversion
result is stored in the A-D conversion register.
An A-D conversion interrupt request occurs at the same time of A-D
conversion completion, the A-D conversion • INT3 interrupt request
bit becomes “1.” The A-D conversion completion bit also becomes
“1.”
Note : When the ladder resistor is disconnect from VCC , set the VCC
connection selection bit to “0” between steps ➆ and ➇.
Table 2. Expression for Vref and VREF
A-D conversion register contents “n”
(decimal notation)
Vref (V)
0
0
1 to 255
VREF
✕ (n – 0.5)
256
Note: VREF indicates the voltage of internal VCC .
Contents of A-D conversion register
A-D conversion start
0 0 0 0 0 0 0 0
1st comparison start
1 0 0 0 0 0 0 0
2nd comparison start
1 1 0 0 0 0 0 0
3rd comparison start
1 2 1 0 0 0 0 0
8th comparison start
1 2 3 4 5 6 7 1
A-D conversion completion
1 2 3 4 5 6 7 8
(8th comparison completion)
Reference voltage (Vref)
0
VR EF
–
2
VR EF ±
2
VR EF ±
2
VR EF
512
VR EF VR EF
–
4
512
VR EF ± VR EF – VR EF
4
8
512
VR EF ± VR EF ± VR EF ± .....
2
4
8
VR EF
V
R
EF
....... ±
–
512
256
Digital value corresponding to
analog input voltage.
m :
Value determined by mth (m = 1 to 8) result
Fig. 17. Changes in A-D conversion register and comparison voltage during A-D conversion
24
[V]
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
(8) Definition of A-D Conversion Accuracy
• Differential non-linearity error
The deviation of the input voltage required to change output data
by “1,” from the corresponding ideal A-D conversion characteristics between 0 and VREF.
The definition of A-D conversion accuracy is described below.
Relative accuracy
• Zero transition error (V0T)
The deviation of the input voltage at which A-D conversion output
data changes from “0” to “1,” from the corresponding ideal A-D
conversion characteristics between 0 and VREF.
V0T=
Differential non-linearity error =
[LSB]
• Full-scale transition error (VFST)
The deviation of the input voltage at which A-D conversion output
data changes from “255” to “254,” from the corresponding ideal AD conversion characteristics between 0 and VREF.
VFST =
1LSB with respect to relative accuracy =
Vn – (1LSB✕ n + V0)
V254 – V0
254
[V ]
VREF
[LSB]
1LSBA with respect to absolute accuracy =
1LSB
Output
data
[LSB]
1LSBA
Note: The analog input voltage “Vn” at which A-D conversion output
data changes from “n” to “n + 1” (n ; 0 to 254) is as follows
(refer to Figure 18).
[LSB]
• Non-linearity error
The deviation of the actual A-D conversion characteristics, from the
ideal A-D conversion characteristics between V0 and V254 .
Non-linearity error =
[LSB]
Vn – 1LSBA ✕ (n + 1/2)
Absolute accuracy error =
(VREF – 3/2 ✕ VREF/256) – V254
1LSB
1LSB
Absolute accuracy
• Absolute accuracy error
The deviation of the actual A-D conversion characteristics, from the
ideal A-D conversion characteristics between 0 and VREF.
(V0 – 1/2 ✕ VREF/256)
1LSB
(Vn+1 – Vn ) – 1LSB
256
[V ]
255
Full-scale transition error
(VFST)
254
3
LSBA
2
Differential nonlinearity error
1LSB
n+1
n
Actual A-D
conversion
characteristics
Non-linearity error
Absolute accuracy
1LSB A
1
LSB A
2
Ideal A-D conversion characteristics
between V0 and V254
1LSB
0
V0 V1
Vn Vn+1
V254
VR EF
Analog input
voltage ( V )
Zero transition error (V0T)
Fig. 18. Definition of A-D conversion precision
25
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
DATA SLICER
When the data slicer function is not used, the data slicer circuit can
be cut off by setting bit 0 of the data slicer control register 1 (address
00EA16 ) to “0.” Also, the timing signal generating circuit can be cut
off by setting bit 0 of data slicer control register 2 (address 00EB16 )
to “0.” These settings can realize the low-power dissipation.
The M37270MF-XXXSP 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 chip’s polarity negative is input to the CVIN pin.
Composite
video
signal
0.1 F
1k
470
560 pF
Hundred of kiloohms
to 1 M
15 k
Sync pulse counter
register
(address 020F16)
200 pF
1 F
HSYNC
CVIN
HLF
RVC O
Synchr onizing
signal counter
Clamping
circuit
Low-pass
filter
Sync slice
circuit
Data slicer control register 2
(address 00EB16)
0
0 0
Synchronizing
separation
circuit
Timing signal
generating
circuit
VHOLD
Reference
voltage
generating
1000 pF
circuit
+
Clock run-in
determination
circuit
–
Comparator
Data slice line
specification
circuit
Data slicer control
register 3
(address 021016)
Clock run-in detect
register 3
(address 020816)
Clock run-in
register 3
(address 0209 16 )
External circuit
Note : Make the length of wiring which
is connected to VHOLD , HLF,
RVCO 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.
Fig. 19. Data slicer block diagram
26
Data clock
generating circuit
16-bit shift register
Data slicer control register 1
(address 00E A16)
0
0 0
Data slicer ON/OFF
Window register
(address 00E216)
0 0
0 1 0 1
Clock run-in register 1
(address 00E616)
1 0 0
Caption position register
(address 00E016)
Start bit position register
(address 00E116)
Clock run-in detect register 1
(address 00E816)
low - order
Clock run-in detect register 2
(address 00E916)
Data register 2
(address 00E516)
Sync slice register 3
(address 00E316)
0 0 0 0 1 0 1
Data bus
Start bit detecting
circuit
high-order
Clock run-in register 2
(address 00E 716)
1 0 0 1 1 1
Data register 4
(address 00ED16)
Data register 1
(address 00E416) Interrupt request
generating circuit
Data register 3
(address 00EC16)
Data slicer
interrupt
request
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
Figure 19 shows the structure of the data slicer control registers.
7
0
0
0
7
Data slicer control register 1
(DSC1: address 00E A16)
0
0
0
0
Data slicer control register 2
(DSC2: address 00E B16)
0
Data slicer control bit
0: Data slicer stopped
1: Data slicer operating
Timing signal generating circuit
control bit
0: Stopped
1: Operating
Field to be sliced data selection bit
b2
0
0
1
1
b1
0
1
0
1
Field of main data
slice line
Field for setting
reference voltage
F2
F1
F1 and F2
F1 and F2
F2
F1
F2
F1
Reference clock source selection
bit
0: Video signal
1: HSYNC signal
Test bit: read-only
Fix these bits to “0.”
Fix these bits to “0.”
Field determination flag
0 : Hsep
V-pulse shape determination flag
0: Match
1: Mismatch
Vsep
1 : Hsep
Fix this bit to “0.”
Vsep
Test bit: read-only
Fix this bit to “0.”
Data latch completion flag for caption
data in main data slice line
7
0
Data slicer control register 3
(DSC3: address 021016)
0: Data is not yet latched
1: Data is latched
Definition of fields 1 (F1) and 2 (F2)
Line selection bit for slice voltage
0: Main data slice line
1: Sub-data slice line
F1 : Hsep
VSYNC
Field to be sliced data selection bit
Vsep
F2 : Hsep
VSYNC
Vsep
b2
0
0
1
1
Field of sub-data Field for setting
reference voltage
b1 slice line
0
F2
1
F1
0
F1 and F2
1
F1 and F2
F2
F1
F2
F1
Setting bit of sub-data slice line
Fig. 20. Structure of data slicer control registers
27
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
(1) Clamping Circuit and Low-pass Filter
This filter attenuates the noise of the composite video signal input
from the CV IN pin. 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 M . 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 19).
7
0
0
0
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.
28
1
0
1
Sync slice register
(SSL : address 00E316)
Vertical synchronizing
signal (Vsep) generating
method selection bit
0 : Method 1
1 : Method 2
This circuit takes out a composite sync signal from the output signal
of the low-pass filter. Figure 21 shows the structure of the sync slice
register.
This circuit separates a horizontal synchronizing signal and a vertical
synchronizing signal from the composite sync signal taken out in the
sync slice circuit.
➀ Horizontal synchronizing signal (Hsep)
A one-shot horizontal synchronizing signal Hsep is generated at
the falling edge of the composite sync signal.
➁ Vertical synchronizing signal (Vsep )
As a Vsep signal generating method, it is possible to select one of
the following 2 methods by using bit 7 of the sync slice register
(address 00E316).
•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 V sep signal is generated in synchronization with
the rising of the timing signal (refer to Figure 22).
Figure 22 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 23, when the A level matches the B level, this bit is
“0.” In the case of a mismatch, the bit is “1.”
For the pins RVCO and the HLF, connect a resistor and a capacitor
as shown in Figure 19. Make the length of wiring which is connected
to these pins as short as possible so that a leakage current may not
be generated.
0
Fix these bits to “00001012”
(2) Sync Slice Circuit
(3) Synchronizing Signal Separation Circuit
0
Fig. 21. Structure of sync slice register
Composite
sync signal
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.
Fig. 22. Vsep generating timing (method 2)
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
(4) Timing Signal Generating Circuit
This circuit generates a reference clock which is 832 times as large
as the horizontal synchronizing signal frequency. It also generates
various timing signals on the basis of the reference clock, horizontal
synchronizing signal and vertical synchronizing signal. The circuit
operates by setting bit 0 of data slicer control register 2 (address
00EB16) 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 1 of data slicer
control register 2 (address 00EB16).
V-pulse
(“L” pulse width is long,
“H” pulse width is short)
Bit 5 of
DSC2
0
Composite
sync signal
1
1
A
B
Fig. 23. Determination of V-pulse waveform
29
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
(5) Data Slice Line Specification Circuit
➁ Selection of field to be sliced data
In the case of the main data slice line, the field to be sliced data is
selected by bits 2 and 1 of the data slicer control register 1 (address
00EA16). In the case of the sub-data slice line, the field is selected
by bits 2 and 1 of the data slicer control register 3. When bit 2 of
the data slicer control register 1 is set to “1,” it is possible to slice
data of both fields (refer to Figure 20).
➂ Specification of line to set slice voltage
The reference voltage for slicing (slice voltage) is generated by
integrating the amplitude of the clock run-in pulse in the particular
line (refer to Table 3).
➃ Field determination
The field determination flag can be read out by bit 5 of the data
slicer control register 1. This flag charge at the falling edge of
Vsep.
➀ Specification of data slice line
M37270MF-XXXSP has 2 data slice line specification circuits for
slicing arbitrary 2 Hsep in 1 field. The following 2 data slice lines
are specified .
<Main data slice line>
This line is specified by the caption position register (address
00E016).
<Sub-data slice line>
This line is specified by the data slicer control register 3 (address
00EB16).
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 (in case of
the sub-data slice line, by bits 3 to 7 of the data slicer control register
3), this Hsep is sliced.
The values of “0016 ” to “1F16 ” can be set in the caption position
register. Bit 7 to bit 5 are used for testing. Set “1002.” Figure 24
shows the signals in the vertical blanking interval. Figure 25 shows
the structure of the caption position register.
Table 3. Specifying of field whose sets reference voltage
Field
Bit 0 of DSC3
Line
0
Field specified by bit 1 of DSC1
0: F2
1: F1
Line specified by bits 4 to 0 of CP
(Main data slice line)
1
Field specified by bit 1 of DSC3
0: F2
1: F1
Line specified by bits 7 to 3 of DSC3
(Sub-data slice line)
DSC1 : Data slice control register 1
DSC3 : Data slice control register 3
CP : Caption position register
Vertical blanking interval
Video signal
Composite
video signal
Vsep
Line 21
Hsep
Count value to be set in the caption position register (“1116” in this case)
Hsep
Clock run-in
Composite video
signal
Start bit + 16-bit data
min. max.
Time to be set in the
start bit position register
Fig. 24. Signals in vertical blanking interval
30
Start bit
Magnified
drawing
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
(6) 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.
➀ 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.
➁ 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.
7
0
Caption position register
(CP : address 00E016)
1 0 0
Specification main data slice line
Fix these bits to “1002”
Fig. 25. Structure of caption position register
(7) Start Bit Detecting Circuit
This circuit detects a start bit at line decided in the data slice line
specification circuit. For start bit detection, it is possible to select one
of the following two types by using bit 1 of the clock run-in register 2
(address 00E716).
➀ After the lapse of the time corresponding to the set value of the
start bit position register (address 00E116), the first rising of the
composite video signal is detected as a start bit.
The time is set in bits 0 to 6 of the start bit position register (address
00E116) (refer to Figure 26). Set a value fit for the following
conditions.
Figure 26 shows the structure of the start bit position register.
7
0
Start bit position register
(SP : address 00E116)
Start bit generating time
Time from a falling of the
horizontal synchronizing signal
to occurrence of a start bit = 4
✕ set value (“0016” to “7F16”) ✕
reference clock period
DSC1 bit 7 control bit
0 : Generation of 16 pulses
1 : Generation of 16 pulses and
detection of clock run-in
Fig. 26. Structure of start bit position register
Time from the falling of the horizontal
synchronizing signal to the last rising
of the clock run-in
<
4 ✕ set value of the start bit position
register ✕ reference clock period
<
Time from the falling of the horizontal
synchronizing signal to occurrence of
the start bit
31
MITSUBISHI MICROCOMPUTERS
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SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
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➁ After a falling of the clock run-in pulse set in bits 2 to 0 of clock runin detect register 2 (address 00E9 16) is detected, a start bit is
detected by sampling a comparator output. A sampling clock for
sampling is obtained by dividing the reference clock generated in
the timing signal generating circuit by 13.
Figure 28 shows the structure of clock run-in detect register 2.
The contents of bits 2 to 0 of clock run-in detect register 2 and bit
1 of clock run-in register 2 are written at a falling of the horizontal
synchronizing signal. For this reason, even if an instruction for
setting is executed, the contents of the register cannot be rewritten
until a falling of the horizontal synchronizing signal.
7
0
Clock run-in detect register 2
(CRD2 : address 00E916)
7
0
1 0 0 1 1 1
1
Clock run-in pulses for sampling
b2 b1 b0
0 0 0 : Not available
0 0 1 : 1st pulse
0 1 0 : 2nd pulse
0 1 1 : 3rd pulse
1 0 0 : 4th pulse
1 0 1 : 5th pulse
1 1 0 : 6th pulse
1 1 1 : 7th pulse
Clock run-in register 2
(CR2 : address 00E716)
Fix this bit to “1”
Start bit detecting method
selection bit
0 : Method 1
1 : Method 2
Data clock generating time
Time from detection of a start bit
to occurrence of a data clock
= (13 + set value) ✕ reference
clock period
Fix these bits to “1001112”
Fig. 27. Structure of clock run-in register 2
Fig. 28. Structure of clock run-in detect register 2
(8) Clock run-in determination circuit
This circuit sets a window in the clock run-in portion in the composite
video signal, and then determinates clock run-in by counting the
number of pulses in this window. Set the time from a falling of the
horizontal synchronizing signal to a start of the window by bits 0 to 5
of the window register (address 00E216; refer to Figure 29). The
window ends according to the contents of the setting of the start bit
position register (refer to Figure 26).
7
0 0
0
Window register
(WN : address 00E216)
Window start time
Time from a falling of the
horizontal synchronizing signal
to a start of the window = 4 ✕ set
value (“0016” to “3F16”) ✕ reference
clock period
Fix these bits to “0”
Fig. 29. Structure of window register
32
MITSUBISHI MICROCOMPUTERS
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SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
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For the main data slice line, the count value of pulses in the window
is stored in clock run-in register 1 (address 00E616; refer to Figure
30). For the sub-data slice line, the count value of pulses in the window
is stored in clock run-in register 3 (address 020916 ; refer to Figure
29). When this count value is 4 to 6, it is determined as a clock run-in.
Accordingly, set the count value so that the window may start after
the first pulse of the clock run-in (refer to Figure 32).
The contents to be set in the window register are written at a falling
of the horizontal synchronizing signal. For this reason, even if an
instruction for setting is executed, the contents of the register cannot
be rewritten until a falling of the horizontal synchronizing signal.
For the main data slice line, reference clock is counted in the period
from a falling of the clock pulse set in bits 0 to 2 of the clock run-in
detect register 2 (address 00E916 ) to the next falling. The count value
is stored in bits 3 to 7 of the clock run-in detect register 1 (address
00E8 16) (When the count value exceeds “1F 16,” “1F16” is held). For
the sub-data slice line, the count value is stored in bits 3 to 7 of the
clock run-in detect register 3 (address 020816). Read out these bits
after the occurence of a data slicer interrupt (refer to (11) Interrupt
Request Generating Circuit).
Figure 33 shows the structure of clock run-in detect registers 1 and
3.
7
0
Clock run-in register 1
(CR1 : address 00E616)
0 1 0 1
Clock run-in count value of
main-data slice line
Fix these bits to “01012”
Fig. 30. Structure of clock run-in register 1
0
7
Clock run-in register 3
(CR3 : address 020916)
Clock run-in count value of sub-data
slice line
Data latch completion flag for caption data in
sub-data slice line
0: Data is not latched yet
1: Data is latched
Data slice line selection bit for interrupt
request
0: Main data slice line
1: Sub-data slice line
Interrupt mode selection bit
0: Interrupt occurs at end of data slice line
1: Interrupt occurs at completion of caption
data latch
Fig. 31. Structure of clock run-in register 3
Horizontal
synchronizing
signal
Clock run-in
Start bit data +
16-bit data
Composite
video signal
Window
Time to be set in the
window register
Time to be set in
the start bit position
register
✽When the count value
in the window is 4 to 6,
this is determined as a
clock run-in.
Fig. 32. Window setting
7
0
Clock run-in detect registers 1, 3
( CRD1 : address 00E816)
( CRD3 : address 020816)
Test bits : read-only
Number of reference clocks to
be counted in one clock run-in
pulse period
Fig. 33. Structure of clock run-in detect registers 1and 3
33
MITSUBISHI MICROCOMPUTERS
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SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
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(9) Data clock generating circuit
This circuit generates a data clock phase-synchronized with the start
bit detected in the start bit detecting circuit.
Set the time from detection of the start bit to occurrence of the data
clock in bits 3 to 7 of the clock run-in detect register 2 (address
00E916). The time to be set is represented by the following expression:
Time = (13 + set value) ✕ reference clock period
For a data clock, 16 pulses are generated. When just 16 pulses have
been generated, bit 7 of the data slicer control register is set to “1”
(refer to Figure 20). When method 1 is already selected as a start bit
detecting method, this bit becomes a logical product (AND) value
with a clock run-in determination result by setting bit 7 of the start bit
position register to “1.”
When method 2 is already selected as a start bit detecting method
and 16 pulses are generated of a data clock regardless of bit 7 of the
start bit position register, this bit is set to “1.” The contents of this bit
are reset at a falling of the vertical synchronizing signal (Vsep).
Table 4. Setting conditions for caption data latch completion flag
Conditions for setting bit 7 of DSC1 to “1”
Bit 7 of SP
Conditions for setting bit 4 of DSC3 to “1”
0
Data clock of 16 pulses has occured in main data slaice line
Data clock of 16 pulses has occured in sub-data slaice line
1
Data clock of 16 pulses has occured in main data slaice line
Data clock of 16 pulses has occured in sub-data slaice line
AND
AND
Clock run-in pulse are detected 4 to 6 times
Clock run-in pulse are detected 4 to 6 times
(10) 16-bit Shift Register
(11) Interrupt Request Generating Circuit
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. For the main data slice line, the contents of the high-order 8
bits of the stored caption data and the contents of the low-order 8
bits of the same data can be obtained by reading out the data register
2 (address 00E516) and data register 1 (address 00E416), respectively.
For the sub-data slice line, the contents of the high-order 8 bits and
the contents of the low-order 8 bits can be obtained by reading out
the data register 4 (address 00ED16) and the data register 3 (address
00EC16), respectively. These registers are reset to “0” at a falling of
Vsep. Read out data registers 1 and 2 after the occurence of a data
slicer interrupt (refer to (11) Interrupt Request Generating Circuit).
The occurence sources of interrupt request are selected by
combination of the following bits; bits 5 and 6 of the clock run-in register
3 (address 020916), bit 1 of the clock run-in register 2 (address 00E716)
(refer to Table 6). Read out the contents of data registers 1 to 4 and
the contents of bits 3 to 7 of the clock run-in detect registers 1 and 3
after the occurence of a data slicer interrupt request.
Table 5. Occurence sources of interrupt request
CR2
CR3
b5
b6
b1
Occurence souces of interrupt request
Slice line
0
0
1
Main data slice line
0
0
Data clock of 16 pulses has occured
AND
Clock run-in pulse are detected 4 to 6 times
1
Data clock of 16 pulses has occured
0
At end of data slice line
1
0
1
1
0
1
1
34
Sources
At end of data slice line
Sub-data slice line
Data clock of 16 pulses has occured
AND
Clock run-in pulse are detected 4 to 6 times
Data clock of 16 pulses has occured
MITSUBISHI MICROCOMPUTERS
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(12) Synchronizing Signal Counter
The synchronizing signal counter counts the composite sync signal
taken out from a video signal in the data slicer circuit or the vertical
synchronizing signal Vsep as a count source.
The count value in a certain time (T time) generated by f(XIN)/213 or
f(XIN)/213 is stored into the 5-bit latch. Accordingly, the latch value
changes in the cycle of T time. When the count value exceeds “1F16 ,”
“1F16” is stored into the latch.
The latch value can be obtained by reading out the sync pulse counter
register (address 00EA16). A count source is selected by bit 5 of the
sync pulse counter register.
The synchronizing signal counter is used when bit 0 of the PWM
mode register 1 (address 02EA16 ).
Figure 34 shows the structure of the sync pulse counter and Figure
35 shows the synchronizing signal counter block diagram.
7
0
Sync pulse counter register
(SYC : address 00EA16)
Count value
Count source
0: HSYNC
signal
1: Composite
sync signal
Count time
f(XIN)/213
(1024 s, f(XIN) = 8 MHz)
Fig. 34. Sync pulse counter register
f(XIN)/213
Composite
sync signal
Reset
HSYNC signal
b5
Selection gate : connected to black
colored side when
reset.
5-bit counter
Counter
Latch (5 bits)
Sync pulse
counter register
Data bus
Fig. 35. Synchronizing signal counter block diagram
35
MITSUBISHI MICROCOMPUTERS
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SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
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Table 6. Multi-master I2C-BUS interface functions
MULTI-MASTER I2C-BUS INTERFACE
I2C-BUS
The multi-master
interface is a circuit for serial communications conformed with the Philips I2C-BUS data transfer format. This
interface, having an arbitration lost detection function and a synchronous function, is useful for serial communications of the multi-master.
Figure 36 shows a block diagram of the multi-master I2C-BUS interface and Table 6 shows multi-master I2C-BUS interface functions.
This multi-master I2C-BUS interface consists of the I2C address register, the I2C data shift register, the I2C clock control register, the I 2C
control register, the I2C status register and other control circuits.
Function
Item
Format
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 frequency
16.1 kHz to 400 kHz (at φ = 4 MHz)
φ : System clock = f(XIN)/2
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
00F916) for connections between the I 2C-BUS interface and
ports (SCL1, SCL2, SDA1, SDA2).
b7
I2 C address register
b0
Interrupt
generating
circuit
SAD6 SAD5 SAD4 SAD3 SAD2 SAD1 SAD0 RBW
S0D
Interrupt
request signal
(IICIRQ)
Address comparator
Serial
data
(SDA)
Noise
elimination
circuit
Data
control
circuit
b7
b0
I 2C data shift register
b7
S0
b0
AL AAS AD0 LRB
MST TRX BB PIN
S1
AL
circuit
2
I C status
register
Internal data bus
BB
circuit
Serial
clock
(SCL)
Noise
elimination
circuit
Clock
control
circuit
b7
b0
ACK ACK FAST CCR4 CCR3 CCR2 CCR1 CCR0
BIT MODE
S2
I 2 C clock control register
Clock division
Fig. 36. Block diagram of multi-master I2C-BUS interface
36
b7
BSEL1 BSEL0 10BIT
SAD
b0
ALS
ES0 BC2 BC1 BC0
S1D I 2 C clock control register
System clock ( φ )
Bit counter
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(1) I2C Data Shift Register
The I 2C data shift register (S0 : address 00F616 ) 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 I2C data shift register is in a write enable status only when the
ES0 bit of the I 2C control register (address 00F916 ) is “1.” The bit
counter is reset by a write instruction to the I2C data shift register.
When both the ES0 bit and the MST bit of the I2C status register
(address 00F816) are “1,” the SCL is output by a write instruction to
the I2 C data shift register. Reading data from the I2C data shift register is always enabled regardless of the ES0 bit value.
Note: To write data into the I2C data shift register after setting the
MST bit to “0” (slave mode), keep an interval of 8 machine
cycles or more.
(2) I2C Address Register
The I2C address register (address 00F716) 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 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 I2 C 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.
7
0
SAD6 SAD5 SAD4 SAD3 SAD2 SAD1 SAD0 RBW
I2 C address register
(S0D: address 00F716)
Read/write bit
Slave address
Fig. 37. Structure of I2C address register
(3) I2C Clock Control Register
The I2C clock control register (address 00FA16) is used to set ACK
control, SCL mode and SCL frequency.
■ Bits 0 to 4: SCL frequency control bits (CCR0–CCR4)
These bits control the SCL frequency. Refer to Table 7.
■ 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 make SDA “L” 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 “H” 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 “L” (ACK is returned). If there is a mismatch between the slave
address and the address data, the SDA is automatically made
“H”(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 “H”) and receives the ACK bit generated
by the data receiving device.
Note: Do not write data into the I 2C clock control register during
transmitting. If data is written during transmitting, the I2C clock
generator is reset, so that data cannot be transmitted normally.
37
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(4) I2C Control Register
7
ACK
0
ACK FAST CCR4 CCR3 CCR2 CCR1 CCR0
BIT MODE
I2C clock control register
(S2 : address 00FA16)
SCL frequency
control bits
Refer to Table 7.
SCL mode
specification bit
0 : Standard clock
mode
1 : High-speed clock
mode
ACK bit
0 : ACK is returned.
1 : ACK is not returned.
ACK clock bit
0 : No ACK clock
1 : ACK clock
The I2C control register (address 00F916 ) controls data communication format.
■ Bits 0 to 2: Bit counter (BC0–BC2)
These bits decide the number of bits for the next 1-byte data to be
transmitted. 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.
■ Bit 3: I 2C interface use enable bit (ES0)
This bit enables to use the multimaster I2C BUS interface. 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 ES0 = “0,” the following is performed.
PIN = “1,” BB = “0” and AL = “0” are set (they are bits of the I2C
status register at address 00F816 ).
Writing data to the I2C data shift register (address 00F616) 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 “(5) I2C 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 I2 C address register (address 00F716) are compared with address data. When this bit is set
to “1,” the 10-bit addressing format is selected, all the bits of the I2C
address register are compared with address data.
■ Bits 6 and 7: Connection control bits between I2C-BUS interface
and ports (BSEL0, BSEL1)
These bits controls the connection between SCL and ports or SDA
and ports (refer to Figure 39).
•
•
Fig. 38. Structure of I2C clock control register
Table 7. Set values of I2C clock control register and SCL
frequency
Setting value of
SCL frequency
CCR4–CCR0
(at φ = 4MHz, unit : kHz)
Standard clock
High-speed clock
CCR4 CCR3 CCR2 CCR1 CCR0
mode
mode
0
0
0
0
0
Setting disabled
Setting disabled
0
0
0
0
1
Setting disabled
Setting disabled
0
0
0
1
0
Setting disabled
Setting disabled
0
0
0
1
1
Setting disabled
333
0
0
1
0
0
Setting disabled
250
0
0
1
0
1
100
0
0
1
1
0
400(Note)
…
…
…
…
166
…
83.3
1
1
1
0
1
17.2
34.5
1
1
1
1
0
16.6
33.3
1
1
1
1
1
16.1
32.3
500/CCR value
1000/CCR value
Note: At 400 kHz in the high-speed clock mode, the duty is 40%.
In the other cases, the duty is 50%.
38
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“0”
“1” BSEL0
7
SCL1/P11
SCL
Multi-master
I2C-BUS
interface
SDA
“0”
“1” BSEL1
SCL2/P12
“0”
“1” BSEL0
SDA1/P13
“0”
“1” BSEL1
SDA2/P14
Note: When using multi-master I2C-BUS interface,
set bits 3 and 4 of the serial I/O mode register
(address 021316) to “1.”
Fig. 39. Connection port control by BSEL0 and BSEL1
(5) I2C Status Register
I2C
I2C-BUS
The
status register (address 00F816) controls the
interface status. The low-order 4 bits are read-only bits and the highorder 4 bits 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 I2C data shift register (address 00F616).
■ 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.
BSEL1 BSEL0 10 BIT ALS
SAD
0
ES0 BC2 BC1 BC0
I2C control register
(S1D : address 00F916)
Bit counter (Number of
transmit/receive bits)
b2 b1 b0
0 0 0 : 8
0 0 1 : 7
0 1 0 : 6
0 1 1 : 5
1 0 0 : 4
1 0 1 : 3
1 1 0 : 2
1 1 1 : 1
I2C-BUS interface use
enable bit
0 : Disabled
1 : Enabled
Data format selection bit
0 : Addressing format
1 : Free data format
Addressing format
selection bit
0 : 7-bit addressing
format
1 : 10-bit addressing
format
Connection control bits
between I2C-BUS
interface and ports
b7 b6 Connection port
0 0 : None
0 1 : SCL1, SDA1
1 0 : SCL2, SDA2
1 1 : SCL1, SDA1,
SCL2, SDA2
Fig. 40. Structure of I2C control register
■ Bit 2: Slave address comparison flag (AAS)
This flag indicates a comparison result of address data.
➀In the slave receive mode, when the 7-bit addressing format is
selected, this bit is set to “1” in one of the following conditions.
The address data immediately after occurrence of a START
condition agrees with the slave address stored in the high-order
7 bits of the I2C address register (address 00F716).
A general call is received.
➁ 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 I 2C address
register (8 bits consisted of slave address and RBW), the first
bytes agree.
➂ The state of this bit is changed from “1” to “0” by executing a write
instruction to the I2C data shift register (address 00F6 16).
•
•
•
39
MITSUBISHI MICROCOMPUTERS
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■ Bit 3: Arbitration lost✽ detecting flag (AL)
In the master transmission mode, when the SDA is made “L” by any
other device, arbitration is judged to have been lost, so that this bit is
set to “1.” At the same time, the TRX bit is set to “0,” so that immediately after transmission of the byte whose arbitration was lost is completed, the MST bit is set to “0.” In the case 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.
■ Bit 4: I 2C-BUS interface 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 occurs to the CPU. The PIN
bit is set to “0” in synchronization with a falling of the last clock (including the ACK clock) of an internal clock and an interrupt request
signal occurs in synchronization with a falling of the PIN bit. When
the PIN bit is “0,” the SCL is kept in the “0” state and clock generation
is disabled. Figure 42 shows an interrupt request signal generating
timing chart.
The PIN bit is set to “1” in one of the following conditions.
Executing a write instruction to the I2 C data shift register (address
00F6 16).
When the ES0 bit is “0”
At reset
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 (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
ES0 bit of the I2C control register (address 00F916 ) 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 a direction of transfer for data communication. When
this bit is “0,” the reception mode is selected and the data of a transmitting device is received. When the bit is “1,” the transmission mode
is selected and address data and control data are output onto the
SDA in synchronization with the clock generated on the SCL.
When the ALS bit of the I2 C control register (address 00F916) 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 trans-
•
•
•
•
•
•
•
40
mitted 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 preventing function (Note).
With MST = “0” and when a START condition is detected.
With MST = “0” and when ACK non-return is detected.
At reset
■ Bit 7: Communication mode specification bit (master/slave specification bit: MST)
This bit is used for master/slave specification for data communication. When this bit is “0,” the slave is specified, so that a START
condition and a STOP condition generated by the master are received, and data communication is performed in synchronization with
the clock generated by the master. When this bit is “1,” the master is
specified and a START condition and a STOP condition are generated, 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 (Note).
At reset
•
•
•
•
•
•
•
•
•
•
Note: The START condition duplication prevention function disables
the occurence of a START condition, reset of bit counter and
SCL output when the following condition is satisfied:
• a START condition is set by another master device.
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
(6) START Condition Generating Method
7
0
I2C status register
MST TRX BB PIN AL AAS AD0 LRB
(S1 : address 00F816)
Last receive bit (Note)
0 : Last bit = “0”
1 : Last bit = “1”
General call detecting flag
(Note)
0 : No general call detected
1 : General call detected
Slave address comparison flag
(Note)
0 : Address disagreement
1 : Address agreement
Arbitration lost detecting flag
(Note)
0 : Not detected
1 : Detected
I2C-BUS interface interrupt
request bit
0 : Interrupt request issued
1 : No interrupt request
issued
Bus busy flag
0 : Bus free
1 : Bus busy
Communication mode
specification bits
00 : Slave receive mode
01 : Slave transmit mode
10 : Master receive mode
11 : Master transmit mode
When the ES0 bit of the I2C control register (address 00F916) is “1,”
execute a write instruction to the I2C status register (address 00F816 )
for setting the MST, TRX and BB bits to “1.” Then a START condition occurs. After that, the bit counter becomes “0002” and an SCL
for 1 byte is output. The START condition generating timing and BB
bit set timing are different in the standard clock mode and the highspeed clock mode. Refer to Figure 43, the START condition generating timing diagram, and Table 8, the START condition/STOP condition generating timing table.
I2C status register
write signal
SCL
SDA
BB flag
AAA
AAA
Setup
time
Hold time
Set time for
BB flag
Setup
time
Fig. 43. START condition generating timing diagram
(7) STOP Condition Generating Method
When the ES0 bit of the I2C control register (address 00F916) is “1,”
execute a write instruction to the I2C status register (address 00F816 )
for setting the MST bit and the TRX bit to “1” and the BB bit to “0”.
Then a STOP condition occurs. The STOP condition generating timing and the BB flag reset timing are different in the standard clock
mode and the high-speed clock mode. Refer to Figure 44, the STOP
condition generating timing diagram, and Table 8, the START condition/STOP condition generating timing table.
Note: These bit and flags can be read out but cannot
be written.
Fig. 41. Structure of I2C status register
I2C status register
write signal
SCL
SDA
BB flag
AAA
Setup
time
Hold time
Reset time for
BB flag
SCL
PIN
IICIRQ
Fig. 42. Interrupt request signal generating timing
Fig. 44. STOP condition generating timing diagram
Table 8. START condition/STOP condition generating timing
table
Item
Standard clock mode High-speed clock mode
Setup time
5.0 µs (20 cycles)
2.5 µs (10 cycles)
Hold time
5.0 µs (20 cycles)
2.5 µs (10 cycles)
Set/reset time
3.0 µs (12 cycles)
1.5 µs (6 cycles)
for BB flag
Note: Absolute time at φ = 4 MHz. The value in parentheses denotes the number of φ cycles.
41
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
(9) Address Data Communication
(8) START/STOP Condition Detecting Conditions
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.
➀ 7-bit addressing format
To meet the 7-bit addressing format, set the 10BIT SAD bit of the
I2C control register (address 00F916) 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 I2C address register (address
00F716). At the time of this comparison, address comparison of
the RBW bit of the I2C address register (address 00F716 ) is not
made. For the data transmission format when the 7-bit addressing format is selected, refer to Figure 46, (1) and (2).
➁ 10-bit addressing format
To meet the 10-bit addressing format, set the 10BIT SAD bit of the
I2C control register (address 00F916) 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 I2C address
register (address 00F716). At the time of this comparison, an address comparison between the RBW bit of the I2C address register (address 00F716) 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.
The START/STOP condition detecting conditions are shown in Figure 45 and Table 9. Only when the 3 conditions of Table 9 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” occurs to the
CPU.
AA
AA
AA
SCL release time
SCL
Setup
time
SDA
(START condition)
Hold time
Setup
time
Hold time
SDA
(STOP condition)
Fig. 45. START condition/STOP condition detecting timing
diagram
Table 9. START condition/STOP condition detecting conditions
High-speed clock mode
Standard clock mode
1.0 µs (4 cycles) < SCL
6.5 µs (26 cycles) < SCL
release time
release time
3.25 µs (13 cycles) < Setup time 0.5 µs (2 cycles) < Setup time
3.25 µs (13 cycles) < Hold time 0.5 µs (2 cycles) < Hold time
Note: Absolute time at φ = 4 MHz. The value in parentheses denotes the number of φ cycles.
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
7 bits
“0”
8 bits
1 to 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
Fig. 46. Address data communication format
42
A
From master to slave
From slave to master
A
Data
1 to 8 bits
A
P
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
When the first-byte address data matches the slave address, the
AAS bit of the I2C status register (address 00F816) is set to “1.” After
the second-byte address data is stored into the I 2C data shift register
(address 00F616), make an address comparison between the second-byte data and the slave address by software. When the address
data of the 2nd byte matches the slave address, set the RBW bit of
the I2C address register (address 00F7 16) 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 I2 C address register (address 00F716 ). For the data transmission format when the 10-bit addressing format is selected, refer to
Figure 46, (3) and (4).
➅ •When all transmitted addresses are “0” (general call)
AD0 of the I2C status register (address 00F816) is set to “1” and
an interrupt request signal occurs.
•When the transmitted addresses match the address set in ➀
AAS of the I2C status register (address 00F816) is set to “1” and
an interrupt request signal occurs.
•In the cases other than the above
AD0 and AAS of the I2 C status register (address 00F816 ) are
set to “0” and no interrupt request signal occurs.
➆ Set dummy data in the I2C data shift register (address 00F6 16).
➇ When receiving control data of more than 1 byte, repeat step ➆.
➈ When a STOP condition is detected, the communication ends.
(10) 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 I2C address
register (address 00F716) and “0” in the RBW bit.
➁ Set the ACK return mode and SCL = 100 kHz by setting “8516” in
the I2C clock control register (address 00FA16).
➂ Set “1016” in the I 2C status register (address 00F816 ) and hold
the SCL at the “H” level.
➃ Set a communication enable status by setting “4816 ” in the I2C
control register (address 00F916).
➄ Set the address data of the destination of transmission in the highorder 7 bits of the I2C data shift register (address 00F616) and set
“0” in the least significant bit.
➅ Set “F016 ” in the I2C status register (address 00F816) 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 I2C data shift register (address 00F616).
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 I2C status register (address 00F816). After this,
if ACK is not returned or transmission ends, a STOP condition
occurs.
(11) 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 and using
the addressing format is shown below.
➀ Set a slave address in the high-order 7 bits of the I2C address
register (address 00F716) and “0” in the RBW bit.
➁ Set the no ACK clock mode and SCL = 400 kHz by setting “2516”
in the I2C clock control register (address 00FA16).
➂ Set “1016” in the I 2C status register (address 00F816 ) and hold
the SCL at the “H” level.
➃ Set a communication enable status by setting “4816 ” in the I2C
control register (address 00F916).
➄ When a START condition is received, an address comparison is
made.
43
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
OSD FUNCTIONS
Table 10 outlines the OSD functions of the M37270MF-XXXSP.
The M37270MF-XXXSP incorporates an OSD control circuit of 40
characters ✕ 16 lines. OSD is controlled by the OSD control register. There are 3 display modes and they are selected by a block unit.
The display modes are selected by the block control register i (i = 1
to 6).
The features of each mode are described below.
Table 10. Features of each display mode
Parameter
Number of display
characters
Dot structure
Kinds of characters
Kinds of character sizes
Pre-divide
ratio (Note)
Dot size
CC mode
(Closed caption mode)
40 characters ✕ 16 lines
Display mode
OSD mode
(On-screen display mode)
40 characters ✕ 16 lines
EXOSD mode
(Extra on-screen display mode)
40 characters ✕ 16 lines
16 ✕ 26 dots
16 ✕ 26 dots
16 ✕ 20 dots
(Character : 20 ✕ 16 dots)
320 kinds (In EXOSD mode, they can be combined with 32 kinds of extra fonts)
6 kinds
2 kinds
14 kinds
✕ 1, ✕ 2, ✕ 3
✕ 1, ✕ 2
✕ 1, ✕ 2, ✕ 3
1TC ✕ 1/2H
1TC ✕ 1/2H, 1T C ✕ 1H, 1.5TC ✕ 1/2H,
1.5TC ✕ 1H, 2T C ✕ 2H, 3TC ✕ 3H
Border
1 screen : 7 kinds, Max. 15 kinds
(a character unit)
1TC ✕ 1/2H, 1TC ✕ 1H
Attribute
Character font coloring
Smooth italic, under line, flash
1 screen : 7 kinds, Max. 7 kinds
(a character unit)
Raster coloring
Possible (a screen unit, 1 screen : Possible (a screen unit, 1 screen : Possible (a screen unit, 1 screen :
7 kinds, max. 7 kinds)
7 kinds, max. 7 kinds)
7 kinds, max. 7 kinds)
Character background
coloring
Possible (a character unit, 1 screen Possible (a character unit, 1 screen Possible (a character unit, 1 screen :
: 7 kinds, max. 7 kinds)
: 7 kinds, max. 7 kinds)
7 kinds, max. 7 kinds)
Border coloring
Possible (a screen unit, 1 screen : Possible (a screen unit, 1 screen :
7 kinds, max. 7 kinds)
7 kinds, max. 7 kinds)
Extra font coloring
OSD output
Function
Border, extra font (32 kinds)
1 screen : 7 kinds, Max. 7 kinds
(a character unit)
Possible (a screen unit, 1 screen :
7 kinds, max. 7 kinds)
R, G, B, OUT1, OUT2
Auto solid space function
Window function
Dual layer OSD function (layer 1)
Possible
R, G, B, I1, OUT1, OUT2
Dual layer OSD function (layer 2)
R, G, B, I1, I2, OUT1, OUT2
Display expansion
Possible
Possible
(multiline display)
Notes 1: The divide ratio of the frequency divider (the pre-divide circuit) is referred as “pre-divide ratio” hereafter.
2: The character size is specified with dot size and pre-divide ratio (refer to (3) Dote size).
44
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-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 47 shows the configuration of OSD character. Figure 48 shows
the block diagram of the OSD control circuit. Figure 49 shows the
structure of the OSD control register. Figure 50 shows the structure
of the block control register.
CC mode
OSD mode
16 dots
16 dots
*
20 dots
26 dots
20 dots
Blank area
Å©Underline area
Å©Blank area
*
*
*
: Displayed only in CCD mode.
EXOSD mode
16 dots
16 dots
26 dots
26 dots
20 dots
16 dots
logical
sum
(OR)
Character font
Extra font
Fig. 47. Configuration of OSD character
45
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
Clock for OSD
OSC1 OSC2
Data slicer clock
HSYN C VSYN C
Display
oscillation
circuit
Control registers for OSD
OSD Control circuit
OSD control register
Horizontal position register
Block control registers
Clock source control register
I/O polarity control register
Raster color register
Extra font color register
Border color register
Window H/L registers
Vertical registers
RAM for OSD
20-bit ✕ 40 ✕ 16
(address 00CE16)
(address 00CF16)
(addresses 00D016 to 00DF16)
(address 021616)
(address 021716)
(address 021816)
(address 021916)
(address 021B16)
(addresses 021C16 to 021F16)
(addresses 022016 to 023F16)
RAM for OSD
(16-bit✕ 20✕ 320) +
16-bit ✕ 26 ✕ 32)
Shift register 1
16-bit
Output circuit
Shift register 2
16-bit
Data bus
Fig. 48. Block diagram of OSD control circuit
46
R
G
B
I1
I2
OUT1 OUT2
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
0
7
7
Block control register i
(i = 1 to 16)
(BCi : addresses 00D016 to 00DF)
0
OSD control register
(OC : address 00CE16)
Display mode selection bits
b1 b0
OSD control bit (Note 1)
0 : All-blocks display off
1 : All-blocks display on
0
0
1
1
Scan mode selection bit
0 : Normal scan mode
1 : Bi-scan mode
0 : Display OFF
1 : OSD mode
0 : CC mode
1 : EXOSD mode
Border control bit
0 : Border OFF
1 : Border ON
Border type selection bit
0 : All bordered
1 : Shadow bordered (Note 2)
Dot size selection bit
Refer to Table 11.
Flash mode selection bit
0 : Color signal of character
background part does not
flash
1 : Color signal of character
background part flashes
Automatic solid space control
bit
0 : OFF
1 : ON
Pre-divide ratio • layer selection
bits
Refer to Table 11.
OUT 2 output control bit (Note)
0 : OUT2 output OFF
1 : OUT2 output ON
Notes : Bit 4 of the color code 1 controls OUT1 output
when bit 7 is “0.”
Bit 4 of the color code 1 controls OUT2 output
when bit 7 is “1.”
Window control bit
0 : OFF
1 : ON
Layer mixing control bits (Note 3)
b7 b6
0 0 : Logical 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
Fig. 50. Structure of block control registers
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 : Set “00” during displaying extra fonts.
Table 11. Setting value of block control registers
Fig. 49. Structure of OSD control register
b6 b5 b4 b3 CS 6
0
0
1
1
1
0
1
0
1
1
Pre-divide
ratio
Dot size
Display layer
1TC ✕ 1/2H
0
0
0
1
1
0
1
1
3TC ✕ 3H
0
0
1TC ✕ 1/2H
0
1
1
0
1
1
3TC ✕ 3H
0
0
1TC ✕ 1/2H
0
1
1
0
1
1
—
0
—
1
0
0
1TC ✕ 1/2H
0
1
1TC ✕ 1H
1
0
1
1
—
—
—
✕1
✕2
✕3
1TC ✕ 1H
2TC ✕ 2H
1TC ✕ 1H
Layer 1
2TC ✕ 2H
1TC ✕ 1H
2TC ✕ 2H
3TC ✕ 3H
0
1
✕1
✕2
1TC ✕ 1/2H
1TC ✕ 1H
Layer 2
1.5TC ✕ 1/2H
1.5TC ✕ 1H
Notes 1: CS6 : Bit 6 of clock control register (Address 021616 )
2: TC : OSD clock cycle divided in the pre-divide circuit
3: H : H SYNC
47
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
(1) Dual Layer OSD
M37270MF-XXXSP has 2 layers; layer 1 and layer 2. These layers
display the OSD for controlling TV and the closed caption display at
the same time and overlayed on each other.
Each block can be assigned to either layer by bits 6 and 5 of the
block control register (refer to Figure 50). For example, only when
both bits 5 and 6 are “1,” the block is assigned to layer 2. Other bit
combinations assign the block to layer 1.
When a block of layer 1 is overlapped with that of layer 2, a screen is
combined (refer to Figure 52) by bits 7 and 6 of the OSD control
register (refer to Figure 49).
Layer 2
Block 13
Block 14
Block 15
Block 16
Block 1
Block 2
Block
...
Note: When using the dual layer OSD, note Table 12.
Block 11
Block 12
Block
Layer 1
Fig. 51. Image of dual layer OSD
Table 12. Conditions of dual layer
Block
Block in layer 1
Block in layer 2
Display mode
CC mode
OSD mode
OSD Clock source
Data slicer clock or OSC1
Same as layer 1
Pre-divide ratio
✕ 1 or ✕ 2 (all blocks)
Same as layer 1 (Note)
Dot size
1TC ✕ 1/2H
Horizontal display start position
Arbitrary
Parameter
Pre-divide ratio = 1
Pre-divide ratio = 2
1TC ✕ 1/2H
1TC ✕ 1/2H, 1.5TC ✕ 1/2H
1TC ✕ 1H
1TC ✕ 1H, 1.5TC ✕ 1H
Same position as layer 1
Note: For the pre-divide ratio of the layer 2, select the same as the layer 1’s ratio by bit 6 of the clock control register.
Display example of layer 1 = “HELLO,” layer 2 = “CH5”
CH5
HELLO
Logical sum (OR) of
layer 1’s color and
layer 2’s color
Bit 7 = “0,” bit 6 = “0”
Fig. 52. Display example of dual layer OSD
48
CH5
HELLO
Layer 1’s color has priority
Bit 7 = “0”, bit 6 = “1”
CH5
HELLO
Layer 2’s color has priority
Bit 7 = “1,” bit 6 = “0”
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
(2) Display Position
The display positions of characters are specified in units called a
“block.” There are 16 blocks, blocks 1 to 16. Up to 40 characters can
be displayed in each block (refer to (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 = oscillating cycle for OSD).
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:
➀ When the display position is overlapped with another block
(Figure 53, (b)), a lower block number (1 to 16) is displayed on
the front.
➁ When another block display position appears while one block is
displayed (Figure 53 (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 2T C ✕ 2H or 3T C ✕ 3H during display period ( ✽ ) of another block.
✽ In the case of OSD mode block: 20 dots in vertical from the vertical display start position.
✽ In the case of CC or EXOSD mode block: 26 dots in vertical from
the vertical display start position.
(HR)
VP11, VP21
Block 1
VP12, VP22
Block 2
VP13, VP23
Block 3
(a) Example when each block is separated
(HR)
VP11, VP21
VP12, VP22
Block 1
(Block 2 is not displayed)
(b) Example when block 2 overlaps with block 1
(HR)
VP11, VP21
VP12, VP22
Block 1
Block 2
(c) Example when block 2 overlaps in process of block 1
Note: VP1i or VP2i (i : 1 to 16) indicates the contents of vertical position registers 1i or 2i.
Fig. 53. Display position
49
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
The display position in the vertical direction is determined by counting the horizontal sync signal (HSYNC ). At this time, it starts to count
the rising edge (falling edge) of HSYNC signal from after about 1 machine cycle of rising edge (falling edge) of V SYNC signal. So interval
from rising edge (falling edge) of VSYNC signal to rising edge (falling
edge) of HSYNC signal needs enough time (2 machine cycles or more)
for avoiding jitter. The polarity of HSYNC and VSYNC signals can select with the I/O polarity control register (address 021716). For details, refer to (15) OSD Output Pin Control.
Note: When bits 0 and 1 of the I/O polarity control register (address
021716) are set to “1” (negative polarity), the vertical position
is determined by counting falling edge of HSYNC signal after
rising edge of VSYNC control signal in the microcomputer (refer to Figure 54).
7
0
Vertical position register 1i
(i = 1 to 16)
(VP1i : addresses 022016 to 022F16)
Control bits of vertical display
start positions (Note)
Vertical display start positions (low-order 8 bits)
TH ✕(setting value of low-order 2 bits of VP2i ✕16 2
+ setting value of low-order 4 bits of VP1i ✕16 1
+ setting value of low-order 4 bits of VP1i ✕160 )
7
0
Vertical position register 2i
(i = 1 to 16)
(VP2i : addresses 023016 to 023F16)
Control bits of vertical display
start positions (Note)
Vertical display start positions (high-order 2 bits)
TH ✕(setting value of low-order 2 bits of VP2i ✕16 2
+ setting value of low-order 4 bits of VP1i ✕16 1
+ setting value of low-order 4 bits of VP1i ✕16 0)
VSYNC signal input
0.25 to 0.50 [µs]
( at f(XIN) = 8MHz)
Note : Set values except “0016” and “0116” to VP1i when VP2i is “0016.”
VSYNC control
signal in
microcomputer
Period of counting
HSYNC signal
Fig. 55. Structure of vertical position registers
(Note 1)
HSYNC
signal input
1
2
3
4
5
Not count
When bits 0 and 1 of the I/O polarity control register
(address 021716) are set to “1” (negative polarity)
The horizontal position is common to all blocks, and can be set in
256 steps (where 1 step is 4TOSC, TOSC being the oscillating cycle
for display) as values “0016 ” to “FF16 ” in bits 0 to 7 of the horizontal
position register (address 00CF 16). The structure of the horizontal
position register is shown in Figure 56.
Notes 1 : Do not generate falling edge of HSYNC signal near rising edge of
VSYNC control signal in microcomputer to avoid jitter.
2 : The pulse width of VSYNC and HSYNC needs 8 machine cycles or
more.
7
Fig. 54. Supplement explanation for display position
0
Horizontal position register
(HP : address 00CF16)
Control bits of horizontal display
start positions
The vertical position for each block can be set in 1024 steps (where
each step is 1TH (TH: H SYNC cycle)) as values “0016 ” to “FF 16” in
vertical position register 1i (i = 1 to 16) (addresses 022016 to 022F16 )
and values “0016” to “FF16” in the vertical position register 2i (i = 1 to
16) (addresses 023016 to 023F16 ). The structure of the vertical position registers is shown in Figure 55.
Horizontal display start positions
4TOSC ✕(setting value of high-order 4 bits ✕16 1
+ setting value of low-order 4 bits ✕160 )
Note : The setting value synchronizes with a rising (falling) of the VSYNC.
Fig. 56. Structure of horizontal position register
50
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
Notes 1 : 1T C (TC : OSD clock cycle divided by prescaler) 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 predivide ratios, their horizontal display start position will not
match.
2 : The horizontal start position is based on the OSD clock
source cycle selected for each block. Accordingly, when 2
blocks have different OSD clock source cycles, their horizontal display start position will not match.
HSYNC
1TC
Block 1 (Pre-divide ratio = 1, clock source = data slicer clock)
1TC
4TOSC✕N
Note 1
Block 2 (Pre-divide ratio = 2, clock source = data slicer clock)
1TC
Block 3 (Pre-divide ratio = 3, clock source = data slicer clock)
Note 2
1TC
4TOSC’✕N
Block 4 (Pre-divide ratio = 3, clock source = OSC1)
Fig. 57. Notes on horizontal display start position
(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) in
the pre-divide circuit. The clock cycle divided in the pre-divide circuit
is defined as 1TC .
The dot size of the layer 1 is specified by bits 6 to 3 of the block
control register.
The dot size of the layer 2 is specified by the following bits : bits 3
and 4 of the block control register, bit 6 of the clock source control
register. Refer to Figure 50 (the structure of the block control regis-
ter), refer to Figure 59 (the structure of the clock source control register).
The block diagram of dot size control circuit is shown in Figure 58.
Notes 1 : The pre-divide ratio = 3 cannot be used in the CC mode.
2 : The pre-divide ratio of the OSD mode block on the layer 2
must be same as that of the CC mode block on the layer 1
by bit 6 of the clock source control register.
3 : In the bi-scan mode, the dot size in the vertical direction is
2 times as compared with the normal mode. Refer to “(13)
Scan Mode” about the scan mode.
OSC1
Clock cycle
= 1TC
Synchronization
circuit
Data slicer clock
CS0
Cycle✕2
Horizontal dot size
control circuit
Cycle✕3
Pre-divide circuit
HSYNC
Vertical dot size
control circuit
OSD control circuit
Fig. 58. Block diagram of dot size control circuit
51
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
(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
This OSD clock for each block can be selected by the following bits
: bit 7 of the port P3 direction register, bits 5 and 4 of the clock source
control register (addresses 021616). A variety of character sizes can
be obtained by combining dot sizes with OSD clocks. When not using the pins OSC1 and OSC2 for the OSD clock I/O pins, the pins
can be used as sub-clock I/O pins or port P6.
•
•
•
0
7
Clock source control register
(CS : address 021616)
CC mode clock selection bit
0 : Data slicer clock
1 : OSC1 clock
OSD mode clock selection bits
b2 b1
0
0
1
1
Table 13. Setting for P63/OSC1/XCIN, P64/OSC2/XCOUT
Input
Sub-clock
OSD clock
Function
port
I/O pin
I/O pin
Register
0 : Data slicer clock
1 : OSC1 clock
0:
Do not set
1:
EXOSD mode clock selection bit
0 : Data slicer clock
1 : OSC1 clock
OSD1 oscillating mode selection bits
b7 Port P3 direction
0
0
1
b5 b4
0
0
1
1
register
Clock source
b5
0
1
1
0
0
control register
b4
1
0
1
0
1
0 : 32 kHZ oscillating mode
1 : Input ports P63, P64
0 : LC oscillating mode
1 : Ceramic • quartz-crystal
oscillating mode
Pre-divide ratio of layer 2 selection bit
0:✕1
1:✕2
Test bit (Note)
Note : Be sure to set bit 7 to “0” for program of the mask and the
EPROM versions. For the emulator MCU version
(M37270ERSS), be sure to set bit 7 to “1” when using the
data slicer clock for software debugging.
Fig. 59. Structure of clock control register
Data slicer clock
Data slicer
circuit
“0”
CC mode block
“1”
CS0
“00”
32 kHZ
“0”
OSD mode block
OSC1 clock
LC
“10”
CS5, CS4
Ceramic •
quartz-crystal
CS1
CS2 = “0”
“0”
EXOSD mode block
“11”
Oscillating mode for OSD
Fig. 60. Block diagram of OSD selection circuit
52
“1”
“1”
CS3
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
(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 62) 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 V SYNC control signal (refer to Figure
54) 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 contents of this field can be read out by the field determination
flag (bit 7 of the I/O polarity control register at address 021716). A dot
line is specified by bit 6 of the I/O polarity control register (refer to
Figure 62).
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.
7
0
I/O polarity control register
(PC : address 021716)
HSYNC input polarity switch bit
0 : Positive polarity input
1 : Negative polarity input
VSYNC input polarity switch bit
0 : Positive polarity input
1 : Negative polarity input
R/G/B output polarity switch bit
0 : Positive polarity output
1 : Negative polarity output
I1, I2 output polarity switch bit
0 : Positive polarity output
1 : Negative polarity output
OUT1 output polarity switch bit
0 : Positive polarity output
1 : Negative polarity output
OUT2 output polarity switch bit
0 : Positive polarity output
1 : Negative polarity output
AA
AA
AA
Display dot line selection bit (Note)
0: “
” at even field
“
” at odd field
1: “
” at even field
“
” at odd field
Field determination flag
0 : Even field
1 : Odd field
Note : Refer to Figure 62.
Fig. 61. Structure of I/O polarity control register
53
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
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
0.25 to 0.50[ms] at
f(XIN) = 8 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, be sure to set bit 0 of the PWM mode register 1 (address 020A16) to “0.”
1
2 3 4 5
6 7 8 9 10 11 12 13 14 15 16
1 2
3 4 5
6 7 8 9 10 11 12 13 14 15 16
1
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
OSD mode
24
25
26
CC mode • EXOSD 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.
Character 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.
Fig. 62. Relation between field determination flag and display font
54
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
The OSD ROM of the character font has a capacity of 12800 bytes.
Since 40 bytes are required for 1 character data, the ROM can stores
up to 320 kinds of characters. The OSD ROM of the extra font has a
capacity of 1664 bytes. Since 52 bytes are required for 1 character
data, the ROM can stores up to 32 kinds of characters.
Data of the character font and extra font is specified shown in Figure
63.
(6) Memory for OSD
There are 2 types of memory for OSD : ROM for OSD (addresses
10800 16 to 1567F 16, 18000 16 to 1E43F16 ) used to store character
dot data (masked) and RAM for OSD (addresses 080016 to 0FFF16)
used to specify the characters and colors to be displayed. The following describes each type of memory.
➀ ROM for OSD (addresses 10800 16 to 1567F16, 18000 16 to
1E43F16)
The ROM for OSD contains dot pattern data for characters to be
displayed. To actually display the character code and the extra code
stored in this ROM, it is necessary to specify them by writing the
character code inherent to each character (code determined based
on the addresses in the ROM for OSD) into the RAM for OSD.
OSD ROM address of character font data
OSD ROM
address bit
AD16 AD15 AD14 AD13 AD12 AD11 AD10 AD9
Line number/character
code/font bit
1
0
AD8
AD7
AD6
Line number
AD5
AD4
AD3
AD2
AD1
AD0
Font
bit
Character code
= “0216” to “1516”
Line number
Character code = “0016” to “13F16”
Font bit
= 0 : left font 1 : right font
OSD ROM address of extra font data
OSD ROM
address bit
AD16 AD15 AD14 AD13 AD12 AD11 AD10
Line number/extra code
/font bit
b7
1
Line number
AD8
AD7
AD6
0
0
0
0
AD5
AD4
AD3
AD2
AD1
AD0
Font
bit
Extra code
= “0016” to “1916”
= “0016” to “1F16”
= 0 : left font 1 : right font
Line number
Extra code
Font bit
Line
number
1
AD9
Left
font
b0 b7
Right
font
0216
0316
0416
0516
0616
0716
0816
0916
0A16
0B16
0C16
0D16
0E16
0F16
10 16
11 16
12 16
13 16
14 16
15 16
b0
Data in
Line
OSD
number
ROM
000016
7FF0 16
7FF8 16
601C16
600C16
600C16
600C16
600C16
601C16
7FF8 16
7FF0 16
630016
638016
61C016
60E016
607016
603816
601C16
600C16
000016
Character font
b7
Left
font
b0 b7
Right
font
b0
Data in
OSD
ROM
FFFE16
FFFF16
000316
000316
000316
000316
000316
000316
000316
000316
000316
000316
000316
000316
000316
000316
000316
000316
000316
000316
000316
000316
FFFF16
FFFE16
0016
0116
0216
0316
0416
0516
0616
0716
0816
0916
0A16
0B16
0C16
0D16
0016
0016
1016
1116
1216
1316
1416
1516
1616
1716
1816
1916
000016
000016
Extra font
Fig. 63. OSD character data storing form
55
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
➁ RAM for OSD (addresses 080016 to 0FFF16 )
The RAM for OSD is allocated at addresses 080016 to 0FFF16, and
is divided into a display character code specification part, color code
1 specification part, and color code 2 specification part for each block.
Table 14 shows the contents of the RAM for OSD.
For example, to display 1 character position (the left edge) in block
1, write the character code in address 080016, write the color code 1
at 084016, and write the color code 2 at 082816.
The structure of the RAM for OSD is shown in Figure 65.
Note: For the OSD mode block with dot size of 1.5TC ✕ 1/2H and
1.5TC ✕ 1H, the 3nth (n = 1 to 13) character is skipped as
compared with ordinary block✽. Accordingly, maximum 26 characters are only displayed in 1 block. The RAM data for the
3nth character does not effect the display. Any character data
can be stored here.
✽ Blocks with dot size of 1TC ✕ 1/2H and 1TC ✕ 1H, or blocks
on the layer 1
Table 14. Contents of OSD RAM
Block
Block 1
Block 2
Block 3
Block 4
Block 5
56
Display position (from left)
1st character
2nd character
:
24th character
25th character
:
39th character
40th character
1st character
2nd character
:
24th character
25th character
:
39th character
40th character
1st character
2nd character
:
24th character
25th character
:
39th character
40th character
1st character
2nd character
:
24th character
25th character
:
39th character
40th character
1st character
2nd character
:
24th character
25th character
:
39th character
40th character
Character code specification
080016
080116
:
081716
081816
:
082616
082716
088016
088116
:
089716
0E9816
:
08A616
08A716
090016
090116
:
091716
091816
:
092616
092716
098016
098116
:
099716
099816
:
09A616
09A716
0A0016
0A0116
:
0A1716
0A1816
:
0A2616
0A2716
Color code 1 specification
084016
084116
:
085716
085816
:
086616
086716
08C016
08C116
:
08D716
08D816
:
08E6 16
08E7 16
094016
094116
:
095716
095816
:
096616
096716
09C016
09C116
:
09D716
08D816
:
09E6 16
09E7 16
0A40 16
0A4116
:
0A57 16
0A58 16
:
0A66 16
0A67 16
Color code 2 specification
082816
082916
:
083F16
086816
:
087616
087716
08A8 16
08A9 16
:
08BF16
08E8 16
:
08F616
08F716
092816
092916
:
093F16
096816
:
097616
097716
09A8 16
09A9 16
:
09BF16
09E8 16
:
09F616
09F716
0A28 16
0A29 16
:
0A3F16
0A68 16
:
0A76 16
0A77 16
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
Table 14. Contents of OSD RAM (continued)
Block
Block 6
Block 7
Block 8
Block 9
Block 10
Block 11
Display position (from left)
1st character
2nd character
:
24th character
25th character
:
39th character
40th character
1st character
2nd character
:
24th character
25th character
:
39th character
40th character
1st character
2nd character
:
24th character
25th character
:
39th character
40th character
1st character
2nd character
:
24th character
25th character
:
39th character
40th character
1st character
2nd character
:
24th character
25th character
:
39th character
40th character
1st character
2nd character
:
24th character
25th character
:
39th character
40th character
Character code specification
0A8016
0A8116
:
0A9716
0A9816
:
0AA616
0AA716
0B0016
0B0116
:
0B1716
0B1816
:
0B2616
0B2716
0B8016
0B8116
:
0B9716
0B9816
:
0BA616
0BA716
0C00 16
0C0116
:
0C17 16
0C18 16
:
0C26 16
0C27 16
0C80 16
0C8116
:
0C97 16
0C98 16
:
0CA616
0CA716
0D00 16
0D0116
:
0D17 16
0D18 16
:
0D26 16
0D27 16
Color code 1 specification
0AC016
0AC116
:
0AD716
0AD816
:
0AE616
0AE716
0B4016
0B4116
:
0B5716
0B5816
:
0B6616
0B6716
0BC016
0BC116
:
0BD716
0BD816
:
0BE616
0BE716
0C4016
0C4116
:
0C5716
0C5816
:
0C6616
0C6716
0CC016
0CC116
:
0CD716
0CD816
:
0CE616
0CE716
0D4016
0D4116
:
0D5716
0D5816
:
0D6616
0D6716
Color code 2 specification
0AA816
0AA916
:
0ABF16
0AE816
:
0AF6 16
0AF7 16
0B2816
0B2916
:
0B3F 16
0B6816
:
0B7616
0B7716
0BA816
0BA916
:
0BBF16
0BE816
:
0BF6 16
0BF7 16
0C28 16
0C29 16
:
0C3F16
0C68 16
:
0C76 16
0C77 16
0CA816
0CA916
:
0CBF16
0CE816
:
0CF616
0CF716
0D28 16
0D29 16
:
0D3F16
0D68 16
:
0D76 16
0D77 16
57
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
Table 14. Contents of OSD RAM (continued)
Block
Display position (from left)
1st character
2nd character
:
24th character
25th character
:
39th character
40th character
1st character
2nd character
:
24th character
25th character
:
39th character
40th character
1st character
2nd character
:
24th character
25th character
:
39th character
40th character
1st character
2nd character
:
24th character
25th character
:
39th character
40th character
1st character
2nd character
:
24th character
25th character
:
39th character
40th character
Block 12
Block 13
Block 14
Block 15
Block 16
Display
sequence
1
2
3
4
5
6
RAM
address
order
1
2
4
5
7
8
7
8
Character code specification
0D8016
0D8116
:
0D9716
0D9816
:
0DA616
0DA716
0E0016
0E0116
:
0E1716
0E1816
:
0E2616
0E2716
0E8016
0E8116
:
0E9816
0E9916
:
0EA616
0EA716
0F00 16
0F0116
:
0F17 16
0F18 16
:
0F26 16
0F27 16
0F80 16
0F8116
:
0F97 16
0F98 16
:
0FA616
0FA716
Color code 1 specification
0DC016
0DC116
:
0DD716
0DD816
:
0DE616
0DE716
0E4016
0E4116
:
0E5716
0E5816
:
0E6616
0E6716
0EC016
0EC116
:
0ED716
0ED816
:
0EE616
0EE716
0F40 16
0F4116
:
0F57 16
0F58 16
:
0F66 16
0F67 16
0FC016
0FC116
:
0FD716
0FD816
:
0FE616
0FE716
9 10 11 12 13 14 15 16 17 18 19 20
Color code 2 specification
0DA816
0DA916
:
0DBF16
0DE816
:
0DF616
0DF716
0E2816
0E2916
:
0E3F16
0E6816
:
0E7616
0E7716
0EA816
0EA916
:
0EBF16
0EE816
:
0EF616
0EF716
0F28 16
0F29 16
:
0F3F16
0F68 16
:
0F76 16
0F77 16
0FA816
0FA916
:
0FBF16
0FE816
:
0FF616
0FF716
21 22 23 24 25 26
10 11 13 14 16 17 19 20 22 23 25 26 28 29 31 32 34 35 37 38
1.5Tc size
block
Display
sequence 1 2 3 4 5 6 7 8 9 10 11 1213 14 15 1617 18 19 20 21 22 23 242526 27 28 29 30 31 32 3334 35 36 37 38 39 40
RAM
address
order
1Tc size
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 2526 27 28 29 30 31 32 33 34 35 36 37 38 39 40 block
Fig. 64. RAM data for 3nth character
58
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
Note: Do not read from and write to addresses in OSD RAM shown
in Table 15.
Table 15. List of access disable addresses
087816
087916
087A16
08F8 16
08F916
08FA16
097816
097916
097A16
09F8 16
09F916
09FA16
0A7816
0A79 16
0A7A16
0AF816
0AF916
0AFA16
0B7816
0B79 16
0B7A16
0BF816
0BF916
0BFA16
0C7816
0C7916
0C7A16
0CF816
0CF916
0CFA16
0D7816
0D7916
0D7A16
0DF816
0DF916
0DFA16
0E7816
0E79 16
0E7A16
0EF816
0EF916
0EFA16
0F78 16
0F7916
0F7A16
0FF816
0FF9 16
0FFA16
59
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
Blocks 1 to16
b7
RF7
b0
RF6
RF5 RF4 RF3 RF2
b7
b0
Color code 1
CC mode
Bit name
b0
RF1 RF0 RC17 RC16 RC15 RC14 RC13 RC12 RC11 RC10 RC23 RC22 RC21 RC20
Character code
Bit
b3
OSD mode
Function
Bit name
Color code 2
EXOSD mode
Function
Bit name
Function
RF0
RF1
RF2
RF3
Character code
RF4
(Low-order 8 bits)
RF5
Specification of
character code in
OSD ROM
Character code
(Low-order 8 bits)
Specification of
character code in
OSD ROM
Character code
(Low-order 8 bits)
Specification of
character code in
OSD ROM
RF6
RF7
RC10
RC11
RC12
RC13
RC14
Character code
Character code
Character code
(High-order 1 bit)
(High-order 1 bit)
(High-order 1 bit)
Control of
0: Color signal output OFF
Control of
0: Color signal output OFF
character color R
1: Color signal output ON
character color R
1: Color signal output ON
Control of
Control of
character color G
character color G
Control of
Control of
character color B
character color B
OUT1 control
0: Character output
OUT1 control
1: Background output
RC15
Flash control
0: Flash OFF
1: Flash ON
RC16
Underline control
RC17
Italic control
RC21
RC22
(CC2)
0: Character output
1: Background output
Control of
0: Color signal output OFF
character color I1
1: Color signal output ON
Extra code 0
Specification of
(EX0) extra code in OSD
ROM
Not used
(EX1)
0: Italic OFF
Extra code 2
(EX2)
0: Color signal output OFF Background color code 0
color R
1: Color signal output ON
1: Color signal output ON
color R
Control of background
Control of background
color G
color G
Control of background
Control of background
color B
color B
Control of background
Fig. 65. Structure of OSD RAM
0: Character output
1: Background output
Extra code 1
color I1
Notes 1: Read value of bits 4 to 7 of the color code 2 is undefined.
2: For “not used” bits, the write value is read.
3: The decode value of the extra code is “EX4.”
60
OUT1 control
0: Color signal output OFF Control of background
Not used
character color
Character color code 2
Control of background
RC23
Specification of
(CC1)
1: Italic ON
RC20
(CC0)
Character color code 1
0: Underline OFF
1: Underline ON
Character color code 0
Specification of
(BCC0) background color
Background color code 1
(BCC1)
Background color code 2
(BCC2)
Extra code 3
Specification of
(EX3) extra code in OSD
ROM
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
(7) Character color
The color for each character is displayed by the color code 1. The
kinds and specification method of character color are different depending on each mode.
CC mode .................. 7 kinds
Specified by bits 1 (R), 2 (G), and 3 (B) of
the color code 1
OSD mode ............... 15 kinds
Specified by bits 1 (R), 2 (G), 3 (B), and 5
(I1) of the color code 1
EXOSD mode .......... 7 kinds
Specified by bits 1 (CC0), 2 (CC1), and
3 (CC2) of the color code 1
The correspondence Table of the color code 1 and color signal output in the EXOSD mode is shown in Table 16.
•
•
•
Table 16. Correspondence table of color code 1 and color
signal output in EXOSD mode
Color code 1
Bit 3
CC2
0
0
0
0
1
1
1
1
Bit 2
CC1
0
0
1
1
0
0
1
1
Color signal output
Bit 1
CC0
0
1
0
1
0
1
0
1
R
G
B
I1
I2
0
1
0
1
1
1
0
1
0
0
1
1
1
1
1
1
0
0
0
0
0
1
1
1
0
0
0
1
0
1
0
0
0
0
0
0
1
0
0
0
(8) Character background color
The character background color can be displayed in the character
display area. The character background color for each character is
specified by the color code 2. The kinds and specification method of
character background color are different depending on each mode.
CC mode .................. 7 kinds
Specified by bits 0 (R), 1 (G), and 2 (B) of
the color code 2
OSD mode ............... 15 kinds
Specified by bits 0 (R), 1 (G), 2 (B), and 3
(I1) of the color code 2
EXOSD mode .......... 7 kinds
Specified by bits 0 (BCC0), 1 (BCC1), and
2 (BCC2) of the color code 2
The correspondence table of the color code 2 and color signal output
in the EXOSD mode is shown in Table 17.
•
•
•
Note : The character background color is displayed in the following
part :
(character display area)–(character font)–(border)–(extra font).
Accordingly, the character background color does not mix with
these color signal.
Table 17. Correspondence table of color code 2 and color
signal output in EXOSD mode
Color code 2
Bit 2
BCC2
0
0
0
0
1
1
1
1
Bit 1
BCC1
0
0
1
1
0
0
1
1
Bit 0
BCC0
0
1
0
1
0
1
0
1
Color signal output
R
G
B
I1
I2
0
1
0
1
1
1
0
1
0
0
1
1
1
1
1
1
0
0
0
0
0
1
1
1
0
0
0
1
0
1
0
0
0
0
0
0
1
0
0
0
61
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
(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 4 of the color code 1 (refer to Figure 65), bits 2 and
Block control register
OUT2 output
control bit (b7)
Border output
control bit (b2)
OUT1
control
(b4 of color
code 1)
0
7 of the block control register (refer to Figure 50). The setting values
for controlling OUT1, OUT2 and the corresponding output waveform
is shown in Figure 66.
Output
waveform
OUT1
OUT2
0
1
OUT1
OUT2
0
0
OUT1
OUT2
1
1
OUT1
OUT2
0
OUT1
OUT2
0
1
OUT1
OUT2
1
0
OUT1
OUT2
1
OUT1
1
OUT2
Fig. 66. Setting value for controlling OUT1, OUT2 and corresponding output waveform
62
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
(10) Attribute
The attributes (flash, underline, italic) are controlled to the character
font. The attributes for each character are specified by the color codes
1 and 2 (refer to Figure 65). The attributes to be controlled are different depending on each mode.
CC mode ..................... Flash, underline, italic
OSD mode .................. Border (all bordered, shadow bordered can
be selected)
EXOSD mode ............. Border (all bordered, shadow bordered can
be selected) , extra font (32 kinds)
➀ Under line
The underline is output at the 23th and 24th dots in vertical direction
only in the CC mode. The underline is controlled by bit 6 of the color
code 1. The color of underline is the same color as that of the character font.
➁ Flash
The parts of the character font, the underline, and the character background are flashed only in the CC mode. The color signals (R, G, B,
OUT1) of the character font and the underline are controlled by bit 5
of the color code 1. All of the color signals for the character font flash.
However, the color signal for the character background can be controlled by bit 3 of the OSD control register (refer to Figure 49). The
flash cycle bases on the VSYNC count.
• VSYNC cycle ✕ 48 ] 800 ms (at flash ON)
• VSYNC cycle ✕ 16 ] 267 ms (at flash OFF)
➂ Italic
The italic is made by slanting the font stored in OSD ROM only in the
CC mode. The italic is controlled by bit 7 of the color code 1.
The display example of the italic and underline is shown in Figure 67.
In this case, 16 26 dots are used and “R” is displayed.
Notes 1: When setting both the italic and the flash, the italic character flashes.
2: When the pre-divide ratio = 1, the italic character with slant
of 1 dot ✕ 5 steps is displayed (refer to Figure 68 (c)). When
the pre-divide ratio = 2, the italic character with slant of 1/2
dot ✕ 10 steps is displayed (refer to Figure 68 (d)).
3: 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 69).
4: 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 69).
5: When displaying the italic character in the block with the
pre-divide ratio = 1, set the OSD clock frequency to 11 MHz
to 14 MHz.
➃ Extra font
There are 32 kinds of the extra fonts configured with 16 ✕ 26 dots in
OSD ROM. 16 kinds of these fonts can be displayed by ORed with
the character font by a character unit (refer to Figure 47). For the
others, only the extra font is displayed (refer to Figure 47). In only the
EXOSD mode, the extra font is controlled the following : bits 7 to 5 of
the color code 1, bit 3 of the color code 2, and decode value (EX4) of
the character code. When the character code = “0016 ” to “13F16,”
EX4 is “0, ” when the character code = “14016 ,” EX4 is “1.” Since
there is no font with the character code = “140 16 ,” a blank is displayed.
The extra font color for each screen is specified by the extra color
register. When the character font overlaps with the extra font, the
color of the area becomes the ORed color of both fonts.
Note : When using the extra font, set bits 7 and 6 of the OSD control
register to “0” (refer to Figure 49).
7
0
Extra font color
register
(RC : address 021916)
Extra font color
R control bit
0 : No output
1 : Output
Extra font color
G control bit
0 : No output
1 : Output
Extra font color
B control bit
0 : No output
1 : Output
Extra font color
I1 control bit
0 : No output
1 : Output
Extra font color
I2 control bit
0 : No output
1 : Output
Fig. 67. Structure of extra font color register
63
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
Color code 1
Color code 1
Bit 6
Bit 7
Bit 6
0
0
1
(a) Ordinary
Bit 7
0
(b) Underline
Color code 1
Color code 1
Bit 6
Bit 7
Bit 6
Bit 7
0
1
0
1
(c) Italic (pre-divide ratio = 1)
(c) Italic (pre-divide ratio = 2)
Fig. 68. Example of attribute display (in CC mode)
Italic on one side
Bit 7 of color
code 1
1
0
0
Note : The wavy-lined is the boundary of character color
Fig. 69. Example of italic display
64
Italic on both sides
1
1
0
1
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
Notes 1 : There is no border for the extra font.
2 : The border dot area is the shaded area as shown in Figure
72. In the EXOSD mode, top and bottom of character font
display area is not bordered.
3 : When the border dot overlaps on the next character
font, the character font has priority (refer to Figure 73 A).
When the border dot overlaps on the next character back
ground, the border has priority (refer to Figure 73 B).
4 : The border is not displayed at right side of the most right
dot in the display area of the 40th character (the character
located at the most right of the block).
Border
The border is output in the OSD mode and the EXOSD 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 70) by bit 2 of the OSD control register (refer to
Figure 70). The border ON/OFF is controlled by bit 2 of the block
control register (refer to Figure 50).
The OUT1 signal is used for border output. The border color for each
screen is specified by the border color register.
The horizontal size (x) of border is 1T C (OSD clock cycle divided in
the pre-divide circuit) regardless of the character font dot size. The
vertical size (y) different depending on the screen scan mode and
the vertical dot size of character font.
All bordered
Shadow bordered
Fig. 70. 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)
Horizontal size (x)
Vertical size (y)
1H , 2H , 3H
Bi-scan mode
1/2H
1H
1H
Fig. 71. Horizontal and vertical size of border
65
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
EXOSD mode
OSD mode
16 dots
16 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
Fig. 72. Border area
7
0
Border color register
(FC : address 021B16)
Border color R control bit
0 : No output
1 : Output
Border color G control bit
0 : No output
1 : Output
Border color B control bit
0 : No output
1 : Output
Character boundary
B
Character boundary
A
Character boundary
B
Border color I1 control bit
0 : No output
1 : Output
Border color I2 control bit
0 : No output
1 : Output
Fig. 73. Border priority
66
Fig. 74. Structure of border color register
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
(11) Multiline Display
The M37270MF-XXXSP 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 OSD interrupts.
An OSD 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 OSD interrupt
occurs is different depending on the setting of the raster color register (refer to Figure 81).
• When bit 7 of the raster color register is “0”
An OSD interrupt occurs at the end of block display in the OSD
and the EXOSD mode.
• When bit 7 of the raster color register is “1”
An OSD interrupt occurs at the end of block display in the CC mode.
Notes 1: An OSD 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 (addresses 00D016 to 00DF 16), an OSD interrupt request does not occur (refer to Figure 75 (A)).
2: When another block display appeares while one block is
displayed, an OSD interrupt request occurs only once at
the end of the another block display (refer to Figure 75 (B)).
3: On the screen setting window, an OSD interrupt occurs
even at the end of the CC mode block (off display) out of
window (refer to Figure 75 (C)).
Block 1 (on display)
“OSD interrupt request”
Block 1 (on display)
“OSD interrupt request”
Block 2 (on display)
“OSD interrupt request”
Block 2 (on display)
“OSD interrupt request”
Block 3 (off display)
No
“OSD interrupt request”
No
“OSD interrupt request”
Block 3 (on display)
Block 4 (on display)
“OSD interrupt request”
“OSD interrupt request”
On display (OSD interrupt request occurs
at the end of block display)
Block 4 (off display)
Off display (OSD interrupt request does
not occur at the end of block display)
Block 1
“OSD interrupt request”
Block 1
Block 2
No
“OSD interrupt request”
Block 2
“OSD interrupt request”
“OSD interrupt request”
Block 3
“OSD interrupt request”
Window
In CC mode
(B)
(C)
Fig. 75. Note on occurence of OSD interrupt
67
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
(12) Automatic Solid Space Function
Notes 1 : Blank is disabled on the left side of the 1st character and
on the right side of the 40th character of each block.
2 : When using this function, set “00916” to the 40th character.
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 of the character area
except character code “00916 ”
This function is turned on and off by bit 4 of the OSD control register
(refer to Figure 49).
Table 18. Setting for automatic solid space
Bit 4 of OSD control register
0
Bit 7 of block control register
1
0
1
0
1
Bit 4 of color code 1
0
1
OUT1 output signal
Character
Character
Character
Solid
Character
font part
display
font part
space
font part
0
1
0
1
0
1
area
OUT2 output signal
OFF
OFF
Character
OFF
Solid
display
space
area
When setting the character code “00516” as the character A, “00616” as the character B.
Character to be displayed
(Display memory)
009 005 009 009 009 006 006
16
16
16
16
16
16
• • •
16
006 009 009 009
16
16
16
16
(Display screen)
• • •
1st
2nd
(Note 1) character character
No blank output
39th
character
40th
character
(Note 2) (Note 1)
Fig. 76. Display screen example of automatic solid space
68
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
(13) Scan Mode
M37270MF-XXXSP 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 (refer to Figure 49).
Table 19. Setting for scan mode
Parameter
Bit 1 of OSD control register
Scan mode
Vertical display start position
0
1
Value of vertical position register ✕ 1H
Value of vertical position register ✕ 2H
1TC ✕ 1/2H
1TC ✕ 1H
1TC ✕ 1H
1TC ✕ 2H
2TC ✕ 2H
2TC ✕ 4H
3TC ✕ 3H
3TC ✕ 6H
Vertical dot size
(14) Window Function
This function sets the top and bottom boundary of display limit on a
screen. The window function is valid only in the CC mode. The top
boundary is set by the window H registers 1 and 2. The bottom boundary is set by the window L registers 1 and 2. This function is turned
on and off by bit 5 of the OSD control register (refer to Figure 49).
The structure of the window H registers 1 and 2 is shown in Figure
78, the structure of the window L registers 1 and 2 is shown in Figure
79.
Notes 1: Set values except “0016” and “0116” to the window H register 1 when the window H register 2 is “0016.”
2: Set the register value fit for the following condition :
(WH1 + WH2) < (WL1 + WL2)
A B C
D E
EXOSD mode
F
I
J
CC mode
M N O
CC mode
G H
K L
P
Bi-scan
Normal scan
Q R S T
U V W X Y
Top
boundary
of window
Window
CC mode
OSD mode
Bottom
boundary
of window
Screen
Fig. 77. Example of window function
69
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
7
0
Window H register 1
(WH1 : address 021C16)
Control bits of window top boundary (Note)
Top boundary position (low-order 8bits)
TH✕(setting value of low-order 2bits of
WH2✕16 2 + setting value of high-order
4bits of WH1✕161 + setting value of
low-order 4bits of WH1✕16 0 )
7
0
Window H register 2
(WH2 : address 021E16)
Control bits of window top boundary (Note)
Top boundary position (high-order 2bits)
TH✕(setting value of low-order 2bits of
WH2 ✕16 2 + setting value of high-order
4bits of WH1✕16 1 + setting value of
low-order 4bits of WH1✕16 0 )
Note : Set values except “0016” and “0116” to the WH1 when the WH2 is “0016.”
Fig. 78. Structure of window H registers
7
0
Window L register 1
(WL1 : address 021D16)
Control bits of window bottom boundary (Note)
Bottom boundary position (low-order 8bits)
TH✕(setting value of low-order 2bits of
WL2✕16 2 +setting value of high- order
4bits of WL1✕161 + setting value of
low-order 4bits of WL1✕160 )
7
0
Window L register 2
(WL2 : address 021F16)
Control bits of window bottom boundary (Note)
Bottom boundary position (high-order 2bits)
TH✕(setting value of low-order 2bits of
WL2✕16 2 + setting value of high-order
4bits of WL1✕ 161 + setting value of
low-order 4bits of WL1✕160 )
Note : Set values fit for the following condition : (WH1+WH 2) < ( WL1+ WL2) .
Fig. 79. Structure of window L registers
70
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
(15) OSD Output Pin Control
The OSD output pins R, G, B, and OUT1 can also function as ports
P52 , P53, P5 4 and P55. Set the corresponding bit of the OSD port
control register (address 00CB16) to “0” to specify these pins as OSD
output pins, or set it to “1” to specify it as a general-purpose port P5
pins. The OUT2, I1, and I2 can also function as port P10 , P15, P16.
Set the corresponding bit of the port P1 direction register (address
00C316 ) to “1” (output mode). After that, switch between the OSD
output function and the port function by the OSD port control register. Set the corresponding bit to “1” to specify the pin as OSD output
pin, or set it to “0” to specify as port P1 pin.
The input polarity of the HSYNC , VSYNC and output polarity of signals
R, G, B, I1, I2, OUT1 and OUT2 can be specified with the I/O polarity
control register (address 021716) . Set a bit to “0” to specify positive
polarity; set it to “1” to specify negative polarity (refer to Figure 61).
The structure of the OSD port control register is shown in Figure 80.
7
0
0
OSD port control register
(PF : address 00CB16)
Port P15 output signal selection bit
0 : Port P15 output
1 : I1 signal output
Port P16 output signal selection bit
0 : Port P16 output
1 : I2 signal output
Port P52 output signal selection bit
0 : R signal output
1 : Port P52 output
Port P53 output signal selection bit
0 : G signal output
1 : Port P53 output
Port P54 output signal selection bit
0 : B signal output
1 : Port P54 output
Port P55 output signal selection bit
0 : OUT1 signal output
1 : Port P55 output
Port P10 output signal selection bit
0 : Port P10 output
1 : OUT2 signal output
Fix this bit to “0.”
Fig. 80. Structure of OSD port control register
71
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
(16) 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, I1, I2, OUT1, and
OUT2 pins can be switched to raster coloring output, 7 raster colors
can be obtained.
If the OUT1 pin has been set to raster coloring output, a raster coloring signal is always output during 1 horizontal scanning period. This
setting is necessary for erasing a background TV image.
If the R, G, B, I1, and I2 pins have been set to output, a raster coloring signal is output in the part except a no-raster colored character
(in Figure 82, a character “1”) during 1 horizontal scanning period.
This ensures that character colors are not mixed with the raster color.
The structure of the raster color register is shown in Figure 81, the
example of raster coloring is shown in Figure 82.
7
0
Raster color register
(RC : address 021816)
Raster color R control bit
0 : No output
1 : Output
Raster color G control bit
0 : No output
1 : Output
Raster color B control bit
0 : No output
1 : Output
Raster color I1 control bit
0 : No output
1 : Output
Raster color I2 control bit
0 : No output
1 : Output
Raster color OUT1 control bit
0 : No output
1 : Output
Raster color OUT2 control bit
0 : No output
1 : Output
OSD interrupt source
selection bit
0 : Interrupt occurs at end
of OSD or EXOSD block
display
1 : Interrupt occurs at end
of CC mode block display
Fig. 81. Structure of raster color register
: Character color “RED” (R)
: Border color “GREEN” (G)
: Background color “MAGENTA” (R and B)
: Raster color “BLUE” (R and OUT1)
A
A'
HSYNC
OUT1
R
G
B
Fig. 82. Example of raster coloring
72
Signals
across
A-A'
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
INTERRUPT INTERVAL DETERMINATION
FUNCTION
The M37270MF-XXXSP incorporates an interrupt interval determination circuit. This interrupt interval determination circuit has an 8-bit
binary up counter as shown in Figure 83. Using this counter, it determines an interval or a pulse width on the INT1 or INT2 (refer to Figure 85).
The following describes how the interrupt interval is determined.
1. The determination mode is selected by using bit 5 of the interrupt
interval determination control register (address 0212 16). When this
bit is set to “0,” the interrupt interval determination mode is selected; when the bit is set to “1,” the pulse width determination
mode is selected.
2. The interrupt input to be determined (INT1 input or INT2 input) is
selected by using bit 2 in the interrupt interval determination control register (address 021216). When this bit is cleared to “0,” the
INT1 input is selected ; when the bit is set to “1,” the INT2 input is
selected.
3. When the INT1 input is to be determined, the polarity is selected
by using bit 3 of the interrupt interval determination control
register ; when the INT2 input is to be determined, the polarity is
selected by using bit 4 of the interrupt interval determination
control register.
When the relevant bit is cleared to “0,” determination is made of
the interval of a positive polarity (rising transition) ; when the bit is
set to “1,” determination is made of the interval of a negative polarity (falling transition).
4. The reference clock is selected by using bit 1 of the interrupt interval determination control register. When the bit is cleared to “0,” a
32µs clock is selected ; when the bit is set to “1,” a 16 µs clock is
selected (based on an oscillation frequency of 8MHz in either case).
5. Simultaneously when the input pulse of the specified polarity
(rising or falling transition) occurs on the INT1 pin (or INT2 pin),
the 8-bit binary up counter starts counting up with the selected
reference clock (32µs or 16µs).
6. Simultaneously with the next input pulse, the value of the 8-bit
binary up counter is loaded into the interrupt interval determination register (address 021116) and the counter is immediately reset (“0016”). The reference clock is input in succession even after
the counter is reset, and the counter restarts counting up from
“0016”.
7. When count value “FE16” is reached, the 8-bit binary up counter
stops counting. Then, simultaneously when the next reference
clock is input, the counter sets value “FF 16” to the interrupt interval determination register. The reference clock is generated by
setting bit 0 of the PWM mode register 1 to “0.”
73
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
16µs
32µs
RE1
Control
circuit
8-bit binary up counter (8)
RE0
8
INT2 (Note)
INT1 (Note)
Interrupt interval determination register(8)
RE2
(Address 021116)
8
Selection gate : Connected to
black colored
side at rest.
Data bus
RE: Input interval determination control register
Note: The pulse width of external interrupt INT1 and INT2 needs 5 or more machine cycles.
Fig. 83. Block diagram of interrupt interval determination circuit
7
0
Interrupt interval determination
control register
(RE : address 021216)
Interrupt interval determination
circuit operation control bit
0 : Stopped
1 : Operating
Reference clock control selection
bit
(at f(XIN) = 8MHz)
0 : 32µs
1 : 16µs
External interrupt input pin
selection bit
0 : INT1 input
1 : INT2 input
INT1 pin input polarity switch bit
0 : Positive polarity input
1 : Negative polarity input
INT2 pin input polarity switch bit
0 : Positive polarity input
1 : Negative polarity input
Interrupt interval determination mode
switch bit
0 : Interrupt interval determination
mode
1 : Pulse width determination mode
INT3 pin input polarity switch bit
0 : Positive polarity input
1 : Negative polarity input
A-D conversion • INT3 interrupt
source selection bit
0 : INT3 interrupt
1 : A-D conversion interrupt
Fig. 84. Structure of interrupt interval determination control
register
74
INT1 or INT2 input
RE5
0
0
1
1
REi
0
1
0
1
Count interval
REi : Bit i (i = 3, 4) of interrupt interval determination
control register (address 021116)
Fig. 85. Setting value of interrpt interval determination control
register and measuring interval
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
RESET CIRCUIT
The M37270MF-XXXSP is reset according to the sequence shown
in Figure 87. It starts the program from the address formed by using
the content of address FFFF 16 as the high-order address and the
content of the address FFFE16 as the low-order address, when the
RESET pin is held at “L” level for 2 ms or more while the power source
voltage is 5 V ± 10 % and the oscillation of a quartz-crystal oscillator
or a ceramic resonator is stable and then returned to “H” level. The
internal state of microcomputer at reset are shown in Figure 88.
An example of the reset circuit is shown in Figure 86.
The reset input voltage must be kept 0.9 V or less until the power
source voltage surpasses 4.5 V.
Poweron
4.5 V
Power source voltage 0 V
0.9 V
Reset input voltage 0 V
33
Vcc
1
36
5
M51953AL
RESET
4
3
0.1
F
32
Vss
M37270MF-XXXSP
Fig. 86. Example of reset circuit
XIN
φ
RESET
Internal RESET
SYNC
Address
?
01, S 01, S-1 01, S-2
?
FFFE FFFF
ADH,
ADL
Reset address from the vector table
?
Data
32768 count of XIN
clock cycle (Note 3)
?
?
?
?
ADL
ADH
Notes 1 : f(XIN) and f( φ ) are in the relation : f(XIN) = 2·f ( φ ).
2 : A question mark (?) indicates an undefined state that
depends on the previous state.
3 : Immediately after a reset, timer 3 and timer 4 are
connected in hardware. At this time, “FF16” is set
in timer 3 and “0716” is set to timer 4. Timer 3 counts down
with f(X IN)/16, and reset state is released by the timer 4
overflow signal.
Fig. 87. Reset sequence
75
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
Address Contents of register
Contents of register
0016
Port P0 direction register
(00C116)
0016
I 2C address register
(00F716)
Port P1 direction register
(00C316)
0016
I 2 C status register
Port P2 direction register
(00C516)
0016
I 2C control register
(00F816) 0 0 0 1 0 0 0 ✽
(00F916)
0016
Port P3 direction register
(00C716) 0 0
(00C916) 0 0
I 2 C clock control register
(00FA16)
Port P4 direction register
OSD port control register
(00CB16)
OSD control register
(00CE16)
Horizontal register
0 0
CPU mode register
0016
(00FB16) 0 0 1 1 1 1 0 0
0016
Interrupt request register 1
(00FC16)
0016
Interrupt request register 2
(00FD16)
(00CF16)
0016
Interrupt control register 1
(00FE16)
Caption position register
(00E016)
0016
Interrupt control register 2
(00FF16)
Start bit position register
(00E116)
0016
Clock run-in detect register 3
(020816)
Window register
(00E216)
0016
PWM mode register 1
(020A16)
0
Sync slice register
(00E316)
0016
PWM mode register 2
(020B16)
0016
Data register 1
(00E416)
0016
Timer 5
(020C16)
0716
Data register 2
(00E516)
0016
Timer 6
(020D16)
Clock run-in register 1
(00E616)
0016
Sync pulse counter register
(020F16)
Clock run-in register 2
(00E716)
0016
Data slicer control register 3
(021016)
0016
Clock run-in detect register 1 (00E816)
0016
Interrupt interval determination control register (021216)
0016
Serial I/O mode register
(021316)
0016
Clock source control register
(021616)
0016
I/O polarity control register
(021716) ✽ 0 0 0 0 0 0 0
Raster color register
(021816)
0016
Extra font color register
(021916)
0 0 0 0 0
Border color register
(021B16)
0 0 0 0 0
0
Clock run-in detect register 2 (00E916) 0 0 0 0 1 0 0 1
Data slicer control register 1 (00EA16)
0016
Data slicer control register 2 (00EB16) ✽ 0 ✽ 0 0 ✽ 0 0
(00EC16)
Data register 3
0016
(00ED16)
Data register 4
0016
A-D control register
(00EF16) 0
0 1
Timer 1
(00F016)
FF16
Processor status register
Timer 2
(00F116)
0716
Program counter
Timer 3
(00F216)
FF16
Timer 4
(00F316)
0716
Timer mode register 1
(00F416)
0016
Timer mode register 2
(00F516)
0016
0
Note : The contents of all other registers and RAM are undefined at reset, so set their initial values.
✽
Undefined
Unused bit
Fig. 88. Internal state of microcomputer at reset
76
Address
0 0 0 0 0 0 0
0016
0 0 0 0 0 0 0
0016
0 0 0 0 0 0 0
0
FF16
0 0 0 0 0 0
(PS) ✽ ✽ ✽ ✽ ✽ 1 ✽ ✽
(PCH)
Contents of address FFFF16
(PCL)
Contents of address FFFE16
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
Ports P03, P10, P15–P17, P2, P30, P31
Direction register
CMOS output
Data bus
Port latch
Ports P0 3, P10, P15–P17,
P2, P30, P31
Note : Each port is also used as below :
P10 : OUT2
P15 : I1
P16 : I2/INT3
P17 : SIN
P24–P26 : AD3–AD1
Ports P00–P02, P04–P07
N-channel open-drain output
Direction register
Ports P0 0–P02, P04–P07
Data bus
Port latch
Note : Each port is also used as below :
P00–P02 : PWM4–PWM6
P04–P07 : PWM0–PWM3
Ports P11–P14
N-channel open-drain output
Direction register
Port P11-P14
Data bus
Port latch
Note : Each port is also used as below :
P11 : SCL1
P12 : SCL2
P13 : SDA1
P14 : SDA2
Fig. 89. I/O pin block diagram (1)
77
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
SOUT, SCLK
N-channel open-drain output
Direction register
Ports S OUT, SCLK
Note : Each pin is also used
as below :
SOUT : P45
SCLK : P46
Data bus
HSYNC, VSYNC
R, G, B, OUT1
Schmidt input
Internal circuit
CMOS output
HSYNC , VSYNC
Internal circuit
Note : Each pin is also used
as below :
R : P52 B : P54
G : P53 OUT1 : P55
Ports P40–P44
Data bus
R, G, B, OUT1
Ports P4 0–P44
Note : Each port is also used as below :
P40 : AD4
P4 1 : INT2
P4 2 : TIM2
P4 3 : TIM3
P4 4 : INT1
Data bus
N-channel open-drain output
Ports P32, P47, P50, P51, P56,
P57, P65-P67
Port latch
Ports P5 0, P60–P62
Data bus
Fig. 90. I/O pin block diagram (2)
78
Port latch
Note : Port P50 is also used
as PWM7
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
CLOCK GENERATING CIRCUIT
(3) Low-Speed Mode
The M37270MF-XXXSP has 2 built-in oscillation circuits. An oscillation circuit can be formed by connecting a resonator between XIN
and XOUT (XCIN and XCOUT). Use the circuit constants in accordance
with the resonator manufacturer’s recommended values. No external resistor is needed between XIN and XOUT since a feed-back resistor exists on-chip. However, an external feed-back resistor is
needed between XCIN and XCOUT. When using XCIN-XCOUT as subclock, clear bits 5 and 4 of the clock source control register to “0.” To
supply a clock signal externally, input it to the XIN (XCIN ) pin and
make the XOUT (XCOUT) pin open. When not using X CIN clock, connect the XCIN to VSS and make the X COUT pin open.
After reset has completed, the internal clock φ is half the frequency of
XIN. Immediately after poweron, both the XIN and XCIN clock start
oscillating. To set the internal clock φ to low-speed operation mode,
set bit 7 of the CPU mode register (address 00FB16 ) to “1.”
If the internal clock is generated from the sub-clock (XCIN ), a low
power consumption operation can be realized by stopping only the
main clock XIN. To stop the main clock, set bit 6 (CM6) of the CPU
mode register (00FB16 ) to “1.” When the main clock XIN is restarted,
the program must allow enough time to for oscillation to stabilize.
Note that in low-power-consumption mode the XCIN-XCOUT drivability
can be reduced, allowing even lower power consumption (60 A
with f (XCIN) = 32kHz). To reduce the XCIN-XCOUT drivability, clear bit
5 (CM5) of the CPU mode register (00FB16) to “0.” At reset, this bit is
set to “1” and strong drivability is selected to help the oscillation to
start. When an STP instruction is executed, set this bit to “1” by software before executing.
M37270MF-XXXSP
Oscillation Control
(1) Stop mode
The built-in clock generating circuit is shown in Figure 56. When the
STP instruction is executed, the internal clock φ stops at “H” level. At
the same time, timers 3 and 4 are connected in hardware and “FF16”
is set in the timer 3, “0716” is set in the timer 4. Select f(XIN)/16 or
f(XCIN )/16 as the timer 3 count source (set both bit 0 of the timer
mode register 2 and bit 6 at address 00C716 to “0” before the execution of the STP instruction). And besides, set the timer 3 and timer 4
interrupt enable bits to disabled (“0”) before execution of the STP
instruction. The oscillator restarts when external interrupt is accepted,
however, the internal clock φ keeps its “H” level until timer 4 overflows. Because this allows time for oscillation stabilizing when a ceramic resonator or a quartz-crystal oscillator is used.
XCIN
Rf
CCIN
XIN
XOUT
Rd
CCOUT
CIN
COUT
Fig. 91. Ceramic resonator circuit example
M37270MF-XXXSP
(2) Wait mode
When the WIT instruction is executed, the internal clock φ stops in
the “H” level but the oscillator continues running. This wait state is
released at reset or when an interrupt is accepted (Note). Since the
oscillator does not stop, the next instruction can be executed at once.
Note: In the wait mode, the following interrupts are invalid.
(1) VSYNC interrupt
(2) OSD interrupt
(3) Timers 1 and 2 interrupts using P42/TIM2 pin input as count
source
(4) Timer 3 interrupt using P43/TIM3 pin input as count source
(5) Data slicer interrupt
(6) Multi-master I2C-BUS interface interrupt
(7) f(XIN)/4096 interrupt
(8) All timer interrupts using f(XIN)/2 or f(XCIN)/2 as count source
(9) All timer interrupts using f(XIN)/4096 or f(X CIN )/4096 as
count source
(10) A-D conversion interrupt
XCOUT
XCIN
XCOUT XIN
Open
External oscillation
circuit or external
pulse
Vcc
Vss
XOUT
Open
External oscillation
circuit
Vcc
Vss
Fig. 92. External clock input circuit example
79
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
XCIN
XCOUT
OSC1 oscillating
mode selection bits
(Notes 1, 4)
XOUT
XIN
“1”
Timer 3 count
stop bit (Notes 1, 2)
Timer 4 count
stop bit (Notes 1, 2)
Timer 3
Timer 4
“1”
1/8
1/2
“0”
Internal system clock
selection bit (Notes 1, 3)
“0”
Timer 3
count source selection bit (Notes 1, 2)
Timing
(Internal clock)
Main clock (XIN–XOUT) stop bit (Notes 1, 3)
Internal system clock
selection bit (Notes 1, 3)
Q
S
R
S
STP instruction
WIT
instruction
Q
Q
R
S
R
Reset
Interrupt disable flag I
Interrupt request
Notes 1 : The value at reset is “0.”
2 : Refer to the structure of timer mode register 2.
3 : Refer to the structure of CPU mode register (next page).
4 : Refer to the structure of clock source control register.
Fig. 93. Clock generating circuit block diagram
80
Reset
STP instruction
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
High-speed operation
start mode
Reset
STP instruction
WIT instruction
8MHz oscillating
32kHz oscillating
φ is stopped (“H”)
Timer operating
8MHz oscillating
32kHz oscillating
f( φ ) = 4MHz
Interrupt
8MHz stopped
32kHz stopped
φ is stopped (“H”)
Interrupt (Note 1)
External INT,
timer interrupt,
or SI/O interrupt
External INT
CM7 = 0
CM7 = 1
WIT instruction
8MHz oscillating
32kHz oscillating
φ is stopped (“H”)
Timer operating
(Note 3)
STP instruction
8MHz oscillating
32kHz oscillating
f( φ ) = 16kHz
Interrupt
8MHz stopped
32kHz stopped
φ is stopped (“H”)
Interrupt (Note 2)
CM6 = 0
CM6 = 1
8MHz stopped
32kHz oscillating
φ is stopped (“H”)
Timer operating
(Note 3)
The program must
allow time for 8MHz
oscillation to stabilize
STP instruction
WIT instruction
8MHz stopped
32kHz stopped
φ = stopped (“H”)
8MHz stopped
32kHz oscillating
f( φ ) = 16kHz
Interrupt
Interrupt (Note 2)
CPU mode register
(Address : 00FB16)
CM6 : Main clock (XIN–XOUT) stop bit
0 : Oscillating
1 : Stopped
CM7 : Internal system clock selection bit
0 : XIN-XOUT selected (high-speed mode)
1 : XCIN-XCOUT selected (low-speed mode)
The example assumes that 8 MHz is being applied to the XIN pin and 32 kHz to the XCIN pin. The φ indicates the internal clock.
Notes 1: When the STP state is ended, a delay of approximately 8ms is automatically generated by timer 3 and timer 4.
2: The delay after the STP state ends is approximately 2s.
3: When the internal clock φ divided by 8 is used as the timer count source, the frequency of the count source is 2kHz.
Fig. 94. State transitions of system clock
81
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
DISPLAY OSCILLATION CIRCUIT
ADDRESSING MODE
The OSD oscillation circuit has a built-in clock oscillation circuits, so
that a clock for OSD can be obtained simply by connecting an LC, a
ceramic resonator, or a quartz-crystal oscillator across the pins OSC1
and OSC2. Which of the sub-clock or the OSD oscillation circuit is
selected by setting bits 5 and 4 of the clock source control register
(address 021616 ).
The memory access is reinforced with 17 kinds of addressing modes.
Refer to the SERIES 740 <Software> User’s Manual for details.
MACHINE INSTRUCTIONS
There are 71 machine instructions. Refer to the SERIES 740 <Software> User’s Manual for details.
PROGRAMMING NOTES
OSC1
(1) The divide ratio of the timer is 1/(n+1).
(2) Even though the BBC and BBS instructions are executed immediately after the interrupt request bits are modified (by the program), those instructions are only valid for the contents before
the modification. At least one instruction cycle is needed (such as
an NOP) between the modification of the interrupt request bits
and the execution of the BBC and BBS instructions.
(3) After the ADC and SBC instructions are executed (in decimal
mode), one instruction cycle (such as an NOP) is needed before
the SEC, CLC, or CLD instruction is executed.
(4) An NOP instruction is needed immediately after the execution of
a PLP instruction.
(5) In order to avoid noise and latch-up, connect a bypass capacitor
(≈ 0.1 µF) directly between the VCC pin–VSS pin, AVCC pin–VSS
pin, and the VCC pin–CNVSS pin using a thick wire.
OSC2
L
C2
C1
Fig. 95. Display oscillation circuit
AUTO-CLEAR CIRCUIT
When power source is supplied, the auto-clear function can be performed by connecting the following circuit to the RESET pin.
Circuit example 1
Vcc
RESET
Vss
Circuit example 2
RESET
Vcc
Vss
Note : Make the level change from “L” to “H” at the point at
which the power source voltage exceeds the specified
voltage.
Fig. 96. Auto-clear circuit example
82
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
DATA REQUIRED FOR MASK ORDERS
The following are necessary when ordering a mask ROM production:
(1) Mask ROM Order Confirmation Form
(2) Mark Specification Form
(3) Data to be written to ROM, in EPROM form (32-pin DIP Type
27C101, three identical copies)
PROM Programming Method
The built-in PROM of the One Time PROM version (blank) and builtin EPROM version can be read or programmed with a general-purpose PROM programmer using a special programming adapter.
Product
M37270FSP
Name of Programming Adapter
PCA7401
The PROM of the One Time PROM version (blank) is not tested or
screened in the assembly process and following processes. To ensure proper operation after programming, the procedure shown in
Figure 97 is recommended to verify programming.
Programming with
PROM programmer
Screening (Caution)
(150°C for 40 hours)
Verification with
PROM programmer
Functional check in target device
Caution : The screening temperature is far higher
than the storage temperature. Never
expose to 150°C exceeding 100 hours.
Fig. 97. Programming and testing of One Time PROM version
83
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
ABSOLUTE MAXIMUM RATINGS
Parameter
Symbol
VCC , AVCC
Power source voltage VCC, AV CC
VI
Input voltage
CNVSS
VI
Input voltage
P00–P07 , P10–P1 7, P20–P2 7,
P30, P31 , P40–P4 6, P64, OSC1,
XIN, HSYNC, VSYNC, RESET,
CVIN
VO
Output voltage
P03, P10 –P17, P2 0–P27, P3 0,
P31, P32 , P47, P5 1, P56, P5 7,
P60–P62 , P65–P6 7, R, G, B,
OUT1, SOUT, SCLK, XOUT ,
OSC2
VO
Output voltage
P00–P02 , P04–P0 7, P50, P6 0–P6 2
Conditions
Ratings
Unit
All voltages are based
on VSS.
Output transistors are
cut off.
–0.3 to 6
V
–0.3 to 6
V
–0.3 to VCC + 0.3
V
–0.3 to VCC + 0.3
V
–0.3 to 13
V
R, G, B, OUT1, OUT2, P03,
P15–P17 , P20–P2 7, P30, P3 1
0 to 1 (Note 1)
mA
Circuit current
R, G, B, OUT1, OUT2, P03,
P15–P17 , P20–P2 7, P56, P5 7,
P66, P67 , SOUT, SCLK
0 to 2 (Note 2)
mA
I OL2
Circuit current
P11–P14
0 to 6 (Note 2)
mA
I OL3
Circuit current
P00–P02 , P04–P0 7, P32, P4 7,
P50, P51 , P60–P6 2
0 to 1 (Note 2)
mA
I OL4
Circuit current
P30, P31
0 to 10 (Note 3)
mA
Pd
Power dissipation
550
mW
Topr
Operating temperature
–10 to 70
°C
Tstg
Storage temperature
–40 to 125
°C
I OH
Circuit current
I OL1
Ta = 25 °C
RECOMMENDED OPERATING CONDITIONS (Ta = –10 °C to 70 °C, VCC = 5 V ± 10 %, unless otherwise noted)
Symbol
Parameter
VCC , AVCC
VCC , AVCC
VSS
VIH1
Power source voltage (Note 4), During CPU, OSD, data slicer operation
RAM hold voltage (when clock is stopped)
Power source voltage
“H” input voltage
P00–P0 7, P10 –P17, P2 0–P27, P3 0, P3 1,
P40–P4 6, P64 , HSYNC, VSYNC, RESET,
XIN, OSC1
“H” input voltage
P11–P1 4 (When using I2C-BUS)
“L” input voltage
P00–P0 7, P10 –P17, P2 0–P27, P3 0, P3 1,
P40–P4 6, P63 , P64
“L” input voltage
SCL1, SCL2, SDA1, SDA2, (When using I2C-BUS)
“L” input voltage (Note 6)
P41–P4 4, P46 , P17, H SYNC, VSYNC,
RESET, XIN, OSC1
“H” average output current (Note 1) R, G, B, OUT1, OUT2, P03, P15–P1 7,
P20–P2 7, P30 , P31
“L” average output current (Note 2) R, G, B, OUT1, OUT2, P03, P15–P1 7,
P20–P2 7, P47 , P51, P5 6, P57, P6 5–P67 ,
SOUT, SCLK
“L” average output current (Note 2) P11–P1 4
“L” average output current (Note 2) P00–P0 2, P04 –P07, P5 0, P60–P6 2
“L” average output current (Note 3) P30, P3 1
Oscillation frequency (for CPU operation) (Note 5)
XIN
Oscillation frequency (for sub-clock operation)
XCIN
Oscillation frequency (for OSD)
OSC1
LC oscillating mode
Ceramic oscillating mode
Input frequency
TIM2, TIM3, INT1, INT2, INT3
Input frequency
SCLK
Input frequency
SCL1, SCL2
Input frequency
Horizontal sync. signal of video signal
Input amplitude video signal
CVIN
VIH2
VIL1
VIL2
VIL3
I OH
I OL1
I OL2
I OL3
I OL4
f CPU
f CLK
f OSD
f hs1
f hs2
f hs3
f hs4
VI
84
Min.
4.5
2.0
0
0.8VCC
Limits
Typ.
5.0
0
Max.
5.5
5.5
0
VCC
Unit
V
V
V
V
0.7VCC
0
VCC
0.4 VCC
V
V
0
0
0.3 VCC
0.2 VCC
V
V
7.9
29
11.0
26.5
15.262
1.5
8.0
32
27.0
15.734
2.0
1
mA
2
mA
6
1
10
8.1
35
27.0
27.5
100
1
400
16.206
2.5
mA
mA
mA
MHz
kHz
MHz
kHz
MHz
kHz
kHz
V
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
ELECTRIC CHARACTERISTICS (VCC = 5 V ± 10 %, VSS = 0 V, f(XIN) = 8 MHz, Ta = –10 °C to 70 °C, unless otherwise noted)
Parameter
Symbol
I CC
System operation
Power source current
Wait mode
Stop mode
Test conditions
Limits
Min.
Typ.
Max.
VCC = 5.5 V, CRT OFF
f(X IN) = 8 MHz Data slicer OFF
15
30
CRT ON
Data slicer ON
30
45
VCC = 5.5 V, f(XIN) = 0,
f(X CIN) = 32kHz,
OSD OFF, Data slicer OFF,
Low-power dissipation
mode set (CM 5 = “0”,
CM6 = “1”)
60
200
Unit
mA
µA
VCC = 5.5 V, f(XIN) = 8 MHz
2
4
VCC = 5.5 V, f(XIN) = 0,
f(X CIN) = 32kHz,
Low-power dissipation
mode set (CM 5 = “0”,
CM6 = “1”)
25
100
VCC = 5.5 V, f(XIN) = 0,
f(X CIN) = 0
1
mA
µA
10
VOH
“H” output voltage
R, G, B, OUT1, OUT2, P03 ,
P15–P1 7, P20–P2 7, P30 , P31
VCC = 4.5 V
I OH = –0.5 mA
VOL
“L” output voltage
R, G, B, OUT1, OUT2, SOUT ,
SCLK, P0 0–P07, P1 5–P17,
P20–P2 7, P50, P3 2, P47 , P56,
P57, P6 0–P62, P6 5–P67
VCC = 4.5 V
I OL = 0.5 mA
0.4
“L” output voltage
P30, P3 1
VCC = 4.5 V
I OL = 10.0 mA
3.0
“L” output voltage
P11–P1 4
VCC = 4.5 V
2.4
V
IOL = 3 mA
V
0.4
IOL = 6 mA
0.6
VCC = 5.0 V
0.5
Hysteresis (Note 6) HSYNC, VSYNC, P41–P4 4,
P46, P1 1–P14, P1 7
VCC = 5.0 V
0.5
I IZH
“H” input leak current RESET, P03, P1 0–P17 ,
P20–P2 7, P30, P3 1, P40 –P46,
P63, P6 4, HSYNC, VSYNC
VCC = 5.5 V
VI = 5.5 V
5
µA
I IZL
“L” input leak current RESET, P00–P0 7, P10 –P17,
P20–P2 7, P30, P3 1, P40 –P46,
P63, P6 4, HSYNC, VSYNC
VCC = 5.5 V
VI = 0 V
5
µA
I IZH
“H” input leak current
VCC = 5.5 V
VI = 12 V
10
µA
RBS
I2 C-BUS·BUS switch connection resistor
(between SCL1 and SCL2, SDA1 and SDA2)
VCC = 4.5 V
130
Ω
VT+–VT–
Hysteresis
RESET
P00–P0 2, P04–P0 7, P50,
P60–P6 2
0.7
1.3
V
Notes 1: The total current that flows out of the IC must be 20 or less.
2: The total input current to IC (IOL1 + IOL2 + IOL3) must be 20 mA or less.
3: The total average input current for ports P30, P3 1 to IC must be 10 mA or less.
4: Connect 0.1 µF or more capacitor externally across the power source pins V CC–VSS and AVCC–VSS so as to reduce power source
noise.
Also connect 0.1 µF or more capacitor externally across the pins VCC–CNVSS.
5: Use a quartz-crystal oscillator or a ceramic resonator for the CPU oscillation circuit. When using the data slicer, use 8 MHz.
6: P16, P41–P4 4 have the hysteresis when these pins are used as interrupt input pins or timer input pins. P11–P14 have the hysteresis
when these pins are used as multi-master I2C-BUS interface ports. P17 and P46 have the hysteresis when these pins are used as
serial I/O pins.
85
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
A-D CONVERTER CHARACTERISTICS
(VCC = 5 V ± 10 %, VSS = 0 V, f(XIN) = 8 MHz, Ta = –10 °C to 70 °C, unless otherwise noted)
Symbol
—
Resolution
—
Non-linearity error
—
Differential non-linearity error
Limits
Test conditions
Parameter
VOT
Zero transition error
VCC = 5.12V
IOL (SUM) = 0mA
VFST
Full-scale transition error
VCC = 5.12V
TCONV
Conversion time
VREF
Reference voltage
RLADDER
Ladder resistor
VIA
Analog input current
Min.
Typ.
Max.
Unit
8
bits
0
±2
LSB
0
±0.9
LSB
0
2
LSB
4
LSB
0
12.25
12.5
µs
VCC
V
kΩ
25
0
VREF
V
MULTI-MASTER I2C-BUS BUS LINE CHARACTERISTICS
Symbol
Standard clock mode High-speed clock mode
Parameter
Min.
Max.
Min.
Max.
Unit
tBUF
Bus free time
4.7
1.3
µs
tHD:STA
Hold time for START condition
4.0
0.6
µs
tLOW
“L” period of SCL clock
4.7
tR
Rising time of both SCL and SDA signals
tHD:DAT
Data hold time
tHIGH
“H” period of SCL clock
µs
1.3
1000
20+0.1Cb
300
ns
0
0
0.9
µs
4.0
0.6
300
µs
tF
Falling time of both SCL and SDA signals
tSU:DAT
Data set-up time
250
20+0.1Cb
100
300
ns
tSU:STA
Set-up time for repeated START condition
4.7
0.6
µs
tSU:STO
Set-up time for STOP condition
4.0
0.6
µs
Note: Cb = total capacitance of 1 bus line
SDA
tHD:STA
tBUF
tLOW
p
tR
tF
Sr
S
SCL
tHD:STA
tHD:DAT
tHIGH
Fig. 98. Definition diagram of timing on multi-master I2C-BUS
86
tSU:STO
tSU:DAT
tSU:STA
p
ns
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
PACKAGE OUTLINE
87
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
GZZ–SH09–39B < 51A0 >
Mask ROM number
740 FAMILY MASK ROM CONFIRMATION FORM
SINGLE-CHIP MICROCOMPUTER M37270MF-XXXSP
MITSUBISHI ELECTRIC
Receipt
Date :
Section head
signature
Supervisor
signature
Note : Please fill in all items marked ❈ .
Issuance
Date :
)
Supervisor
signature
(
❈ Customer
Date
issued
Submitted by
TEL
Company
name
❈1. Confirmation
Specify the name of the product being ordered and the type of EPROMs submitted.
Three EPROMs are required for each pattern.
If at least two of the three sets of EPROMs submitted contain identical data, we will produce masks based on
this data. We shall assume the responsibility for errors only if the mask ROM data on the products we produce
differs from this data. Thus, extreme care must be taken to verify the data in the submitted EPROMs.
(hexadecimal notation)
Checksum code for entire EPROM
EPROM type (indicate the type used)
27C101
EPROM address
0000016
Product name
0000F16
01000 16
0FFFF 16
10800 16
ASCII code :
‘M37270MF –’
data
ROM 60K bytes
OSD ROM
1E43F16
(1)
(2)
Set “FF 16” in the shaded area.
Write the ASCII codes that indicates the product name of “M37270MF–” to addresses 0000
16
to 000F 16.
EPROM data check item (Refer the EPROM data and check “ ” in the appropriate box)
● Do you set “FF 16” in the shaded area ?
→ Yes
● Do you write the ASCII codes that indicates the product
→ Yes
name of “M37270MF–” to addresses 0000 16 to 000F 16 ?
❈ 2. Mark specification
Mark specification must be submitted using the correct form for the type package being ordered fill out the appropriate
mark specification form (64P4B for M37270MF-XXXSP) and attach to the mask ROM confirmation form.
(1/4)
88
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
GZZ–SH09–39B < 51A0 >
740 FAMILY MASK ROM CONFIRMATION FORM
SINGLE-CHIP MICROCOMPUTER M37270MF-XXXSP
MITSUBISHI ELECTRIC
Writing the product name and character ROM data onto EPROMs
Addresses 00000 16 to 0000F 16 store the product name, and addresses 10800 16 to 1E43F 16 store the character pattern.
If the name of the product contained in the EPROMs does not match the name on the mask ROM confirmation form, the
ROM processing is disabled. Write the data correctly.
1. Inputting the name of the product with the ASCII code
ASCII codes ‘M37270MF-’ are listed on the right.
The addresses and data are in hexadecimal notation.
Address
000016
000116
000216
000316
000416
000516
000616
000716
‘M’ =
‘3’ =
‘7’ =
‘2’ =
‘7’ =
‘0’ =
‘M’ =
‘F’ =
4D
33
37
32
37
30
4D
46
16
16
16
16
16
16
16
16
Address
000816
000916
000A16
000B16
000C16
000D16
000E16
000F16
‘–’ = 2 D
FF
FF
FF
FF
FF
FF
FF
16
16
16
16
16
16
16
16
2. Inputting the character ROM
Input the character ROM data to character ROM. For the character ROM data, see the next page and on.
(2/4)
89
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
GZZ–SH09–39B < 51A0>
740 FAMILY MASK ROM CONFIRMATION FORM
SINGLE-CHIP MICROCOMPUTER M37270MF-XXXSP
MITSUBISHI ELECTRIC
Font data must be stored in the proper OSD ROM address according to the following table.
(1)OSD ROM address of character font data
OSD ROM address bit
AD16 AD15 AD14 AD13 AD12 AD11 AD10 AD9 AD8 AD7 AD6 AD5 AD4 AD3 AD2 AD1 AD0
Line number / Character
code / Font bit
1
0
Line number
Font
bit
Character code
Line number = 02 16 to 1516
Character code = 00 16 to 13F 16
Font bit = 0 : Left font
1 : Right font
Example) The font data “60” (shaded area
) of the character code “AA 16” is stored in address
1 0 0 1 0 1 0 0 1 0 1 0 1 0 1 0 0
2
=12954 16.
(2)OSD ROM address of extra font data
AD16 AD15 AD14 AD13 AD12 AD11 AD10 AD9 AD8 AD7 AD6 AD5 AD4 AD3 AD2 AD1 AD0
OSD ROM address bit
Line number / Extra code /
Font bit
1
1
Line number
0
0
0
Font
bit
Extra code
0
Line number = 00 16 to 19 16
Extra code = 00 16 to 1F 16
Font bit = 0 : Left font
1 : Right font
Example) The font data “03” (shaded area
) of the extra code “0A 16” is stored in address
1 1 0 0 1 0 1 0 0 0 0 0 1 0 1 0 1
2
=19415 16.
Left font
Right font
DB7 DB6 DB5 DB4 DB3 DB2 DB1 DB0 DB7 DB6 DB5 DB4 DB3 DB2 DB1 DB0
Left font
Right font
DB7 DB6 DB5 DB4 DB3 DB2 DB1 DB0 DB7 DB6 DB5 DB4 DB3 DB2 DB1 DB0
Line number 0216
0316
0416
0516
0616
0716
0816
0916
0A16
0B16
0C16
0D16
0E16
0F16
1016
1116
1216
1316
1416
1516
(1) Character code “AA 16”
Line number 0016
0116
0216
0316
0416
0516
0616
0716
0816
0916
0A16
0B16
0C16
0D16
0016
0016
1016
1116
1216
1316
1416
1516
1616
1716
1816
1916
(2) Extra code “0A 16”
(3/4)
90
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
GZZ–SH09–39B < 51A0 >
740 FAMILY MASK ROM CONFIRMATION FORM
SINGLE-CHIP MICROCOMPUTER M37270MF-XXXSP
MITSUBISHI ELECTRIC
The following OSD ROM addresses must be set “FF.” There are no font data in these addresses.
10A80 16 to 10BFF 16
1328016 to 133FF16
18040 16 to 183FF 16
1B040 16 to 1B3FF 16
10E80 16 to 10FFF 16
1368016 to 137FF16
18440 16 to 187FF 16
1B440 16 to 1B7FF 16
11280 16 to 113FF 16
13A80 16 to 13BFF 16
18840 16 to 18BFF 16
1B840 16 to 1BBFF 16
11680 16 to 117FF 16
13E80 16 to 13FFF 16
18C40 16 to 18FFF 16
1BC40 16 to 1BFFF 16
11A80 16 to 11BFF 16
1428016 to 143FF16
19040 16 to 193FF 16
1C040 16 to 1C3FF 16
11E80 16 to 11FFF 16
1468016 to 147FF16
19440 16 to 197FF 16
1C440 16 to 1C7FF 16
12280 16 to 123FF 16
14A80 16 to 14BFF 16
19840 16 to 19BFF 16
1C840 16 to 1CBFF 16
12680 16 to 127FF 16
14E80 16 to 14FFF 16
19C40 16 to 19FFF 16
1CC40 16 to 1CFFF 16
12A80 16 to 12BFF 16
1528016 to 153FF16
1A040 16 to 1A3FF 16
1D040 16 to 1D3FF 16
12E80 16 to 12FFF 16
1568016 to 17FFF 16
1A440 16 to 1A7FF 16
1D440 16 to 1D7FF 16
1A840 16 to 1ABFF 16
1D840 16 to 1DBFF 16
1AC4016 to 1AFFF 16
1DC4016 to 1DFFF 16
1E040 16 to 1E3FF 16
(4/4)
91
MITSUBISHI MICROCOMPUTERS
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
SINGLE-CHIP 8-BIT CMOS MICROCOMPUTER with CLOSED CAPTION DECODER
and ON-SCREEN DISPLAY CONTROLLER
92
MITSUBISHI DATA BOOK
SINGLE-CHIP 8-BIT MICROCOMPUTERS Vol.3
Sep. First Edition 1996 H-DF319-B
Editioned by
Committee of editing of Mitsubishi Semiconductor Data Book
Published by
Mitsubishi Electric Corp., Semiconductor Division
This book, or parts thereof, may not be reproduced in any form without permission of
Mitsubishi Electric Corporation.
©1996 MITSUBISHI ELECTRIC CORPORATION Printed in Japan
REVISION DESCRIPTION LIST
Rev.
No.
M37270MF-XXXSP
M37270EF-XXXSP, M37270EFSP
Revision Description
DATA SHEET
Rev.
date
1.0
First Edition
9708
2.0
Information about copyright note, revision number, release date added (last page).
971130
(1/1)