MITSUBISHI M61316SP

MITSUBISHI ICs (MONITOR)
M61311SP/M61316SP
2
I C BUS CONTROLLED VIDEO PRE-AMP FOR HIGH RESOLUTION COLOR DISPLAY
DESCRIPTION
FEATURES
PIN CONFIGURATION
GND 1
32 BRIGHT
R IN 2
31 ABL IN
3
30 R OUT
VCC1(12V)
G IN 4
SonG IN 5
GND1(12V)
6
B IN
7
GND2 8
Frequency Band Width
RGB:
200MHz (M61311SP)
150MHz (M61316SP)
(4Vp-p at -3dB)
80MHz
OSD:
Sync Sepa OUT
9
Video Det OUT 10
VCC3(5V) 11
OSD BLK IN 12
OSD R IN 13
Input
OSD G IN 14
RGB:
OSD:
OSD BLK:
Retrace BLK:
Clamp Pulse:
0.7Vp-p (typical)
3.5V --- 5.0V (positive)
3.5V --- 5.0V (positive)
2.5V --- 5.0V (positive)
2.5V --- 5.0V (positive)
OSD B IN 15
GND3 16
M61311SP/M61316SP
M61311SP/M61316SP is Semiconductor Integrated
Circuit for CRT Display Monitor.
It includes OSD Blanking, OSD Mixing, Retrace Blanking,
Video Detector, Sync Separator, Wide Band Amplifier,
Brightness Control.
Main/Sub Contrast, Video Response Adjust, Ret BLK
Adjust, 4ch D/A OUT and OSD level Adjust Function
can be controlled by IIC Bus.
29 VCC2(12V)
28 G OUT
27 GND4
26 B OUT
25 NC(GND)
24 D/A OUT 4
23 D/A OUT 3
22 D/A OUT 2
21 D/A OUT 1
20 SCL
19
SDA
18 Clamp Pulse IN
17
Retrace BLK IN
Package : 32P4B
NC:NO CONNECTION
Output
RGB:
5Vp-p
(at Brightness less than 2VDC)
OSD:
4Vp-p
(at Brightness less than 2VDC)
Sync OUT:
5Vp-p
Video Det OUT: High = 4.2VDC , Low = 0.7VDC
STRUCTURE
Bipolar Silicon Monolithic IC
32 pin plastic SDIP
APPLICATION
CRT Display Monitor
RECOMMENDED OPERATING CONDITIONS
Supply Voltage Range
11.50V --- 12.50V (V3,V29)
4.75V --- 5.25V (V11)
Rated Supply Voltage
12.00V (V3,V29)
5.00V (V11)
MAJOR SPECIFICATION
IIC Bus Controlled 3ch Video Pre-Amp with OSD Mixing Function and Retrace Blanking Function.
The difference in the M61311SP/M61316SP is RGB Video Frequency Band Width.
M61311SP is 200MHz, M61316SP is 150MHz in conditions RGB Output is 4Vp-p at -3dB.
MITSUBISHI
ELECTRIC
1
MITSUBISHI ICs (MONITOR)
M61311SP/M61316SP
2
I C BUS CONTROLLED VIDEO PRE-AMP FOR HIGH RESOLUTION COLOR DISPLAY
ABSOLUTE MAXIMUM RATING (Ambient temperature:25deg)
Parameter
Symbol
Rating
Unit
Supply voltage (Pin3,29)
Vcc12
13.0
V
Supply voltage (Pin11)
Vcc5
6.0
V
Pd
2358
mW
Ambient temperature
Topr
-20 --- +75
deg
Storage temperature
Tstg
-40 --- +150
deg
Recommend supply 12
Vopr12
12.0
V
Recommend supply 5
Vopr5
5.0
V
Voltage range 12
Vopr'12
11.5 --- 12.5
V
Voltage range 5
Vopr'5
4.75 --- 5.25
V
Power dissipation
THERMAL DERATING (Maximum Rating)
Power Dissipation Pd ( mW )
2800
2400
2358
2000
1600
1415
1200
800
400
0
-25
0
25
50
75
100
125
150
Ambient Temperature Ta (deg)
MITSUBISHI
ELECTRIC
2
MITSUBISHI
ELECTRIC
Vcc 12V
7
6
4
3
2
SonG IN
8
5
Video Det OUT 10
B IN
G IN
R IN
9
Sync
Sepa
OUT
18
Clamp
Pulse
IN
CP
Sync Sepa
Video Det
CP
CLAMP
CP
CLAMP
CP
CLAMP
ABL IN
31
1bit sw
1bit sw
14
15
12
OSD
level
7bit
OSD MIX
OSD B
OSD MIX
OSD G
OSD MIX
16
B SUB CONT 8bit
G SUB CONT 8bit
21
CP
CP
CP
R SUB CONT 8bit
OSD
BLK
IN
MAIN
CONTRAST
8bit
MAIN
CONTRAST
MAIN
CONTRAST
MAIN
CONTRAST
OSD OSD OSD
R
G
B
IN IN
IN
13
B SUB CONT 8bit
SUB
CONTRAST
G SUB CONT 8bit
SUB
CONTRAST
R SUB CONT 8bit
SUB
CONTRAST
OSD R
23
D/A OUT
22
24
Ret BLK
Adjust
4bit
1
BUS
I/F
RETRACE
BLANKING
RETRACE
BLANKING
RETRACE
BLANKING
25
20
19
SCL
SDA
11 Vcc 5V
26 B OUT
27
28 G OUT
29 Vcc 12V
30 R OUT
17
32
DAC
CLAMP
F/B
AMP
CLAMP
F/B
AMP
CLAMP
F/B
AMP
Retrace BLK IN
BRIGHT
MITSUBISHI ICs (MONITOR)
M61311SP/M61316SP
I C BUS CONTROLLED VIDEO PRE-AMP FOR HIGH RESOLUTION COLOR DISPLAY
2
BLOCK DIAGRAM
3
MITSUBISHI ICs (MONITOR)
M61311SP/M61316SP
2
I C BUS CONTROLLED VIDEO PRE-AMP FOR HIGH RESOLUTION COLOR DISPLAY
BUS CONTROL TABLE
(1) Slave address:
D7
D6
D5
D4
D3
D2
D1
R/W
1
0
0
0
1
0
0
0
=88H
(2) Slave receiver format:
Normal mode
8bit
S
8bit
SLAVE ADDRESS
A
SUB ADDRESS
Auto increment mode
8bit
S
8bit
SLAVE ADDRESS
8bit
DATA
(SUB ADDRESS=0(X+1)H)
A
SUB ADDRESS (0XH)+10H
8bit
DATA
A
(SUB ADDRESS=0(X+2)H)
8bit
A
DATA BYTE
8bit
DATA
A
(SUB ADDRESS=0XH)
A
------
A
P
A
S:Start condition
A:Acknowledge
P:Stop condition
(3) Sub address byte and data byte format:
Function
Bit
Sub
add
Main contrast
8
00H
Sub contrast R
8
01H
Sub contrast G
8
02H
Sub contrast B
8
03H
OSD level
7
04H
RE-BLK Adjust
4
05H
Sharpness control
4
Sync Sepa SW
1
06H
Video Det SW
1
TEST MODE
2
D/A OUT1
8
07H
D/A OUT2
8
08H
D/A OUT3
8
09H
D/A OUT4
8 0AH
D7
A07
0
A17
0
A27
0
A37
0
A67
0
A77
0
A87
0
A97
0
AA7
0
Data byte(top:byte format
D6
D5
D4
A06
A05
A04
0
0
0
A16
A15
A14
0
0
0
A26
A25
A24
0
0
0
A36
A35
A34
0
0
0
A46
A45
A44
0
0
0
A64
0
A65
0
A66
0
A76
A75
A74
0
0
0
A86
A85
A84
0
0
0
A95
A94
A96
0
0
0
AA6
AA5
AA4
0
0
0
under:start condition)
D3
D2
D1
A03
A02
A01
0
0
0
A12
A11
A13
0
0
0
A21
A23
A22
0
0
0
A31
A33
A32
0
0
0
A41
A43
A42
0
0
0
A51
A53
A52
0
0
0
A63
A62
A61
0
0
0
A73
A72
A71
0
0
0
A83
A82
A81
0
0
0
A93
A92
A91
0
0
0
AA3
AA2
AA1
0
0
0
D0
A00
1
A10
1
A20
1
A30
1
A40
1
A50
1
A60
1
A70
1
A80
1
A90
1
AA0
1
*)
*)
*)
*)
*)
*)
*)
*)
*)
*)
*)
*)
*)
*)
*)pre-data
*)sub add. 06H
Sync Sepa SW A64 0:Sync Sepa ON 1:Sync Sepa OFF
Video Det SW A65
0:Video Det ON 1:Video Det OFF
Always set up as A66 and A67 in 0.
For IIC Data, please transfer in the period of Vertical.
MITSUBISHI
ELECTRIC
4
MITSUBISHI ICs (MONITOR)
M61311SP/M61316SP
2
I C BUS CONTROLLED VIDEO PRE-AMP FOR HIGH RESOLUTION COLOR DISPLAY
IIC BUS CONTROL SECTION SDA,SCL CHARACTERISTICS
parameter
symbol
MIN
MAX
unit
min. input LOW voltage
VIL
-0.5
1.5
V
max. input HIGH voltage
VIH
3.0
5.5
V
SCL clock frequency
fSCL
0
400
KHz
tBUF
1.3
-
uS
tHD:STA
0.6
-
uS
The LOW period of the clock
tLOW
1.3
-
uS
The HIGH period of the clock
tHIGH
0.6
-
uS
Set up time for start condition
(Only relevant for a repeated start condition)
tSU:STA
0.6
-
uS
Hold time DATA
tHD:DAT
0
0.9
uS
Set-up time DATA
tSU:DAT
100
-
nS
Rise time both SDA and SCL lines
tR
20+0.1Cb
300
nS
Fall time both SDA and SCL lines
tF
20+0.1Cb
300
nS
tSU:STO
0.6
-
uS
Time the bus must be free
before a new transmission can start
Hold time start condition
After this period the first clock pulse is generated
Set-up time for stop condition
TIMING DIAGRAM
tR tF
tBUF
VIH
SDA
VIL
tHD:STA
tSU:DAT
tHD:DAT
tSU:STA
tSU:STO
VIH
SCL
VIL
tLOW
S
tHIGH
S
MITSUBISHI
ELECTRIC
P
S
5
MITSUBISHI ICs (MONITOR)
M61311SP/M61316SP
2
I C BUS CONTROLLED VIDEO PRE-AMP FOR HIGH RESOLUTION COLOR DISPLAY
ELECTRICAL CHARACTERISTICS (VCC = 12V, 5V ; Ta = 25ºC unless otherwise specified)
Input
No. Symbol
1
Icc1
2
Icc2
3
Icc3
4 Vomax
5 Vimax
6
7
8
9
10
Gv
Gv
VC1
VC1
VC2
11
VC2
12
VC3
13
VC3
14 VSC1
15
VSC1
16 VSC2
17
VSC2
18 VSC3
19
VSC3
20 ABL1
21
ABL1
22 ABL2
23
ABL2
24 ABL3
25
26
27
28
29
30
31
ABL3
VB1
VB1
VB2
VB2
VB3
VB3
32
Tr
33
Tr
34
35
Tf
Tf
36 VthCP
37 WCP
parameter
Test
point
3
2
4
5
7
12
14
15
17
18
31
R
G SonG B
OSD OSD OSD OSD RET CP ABL BRT Main Sub R Sub G Sub B OSD ReBLK Sharp SonG VDET D/A
Vcc
IN
IN
IN
IN
BLK R IN G IN B IN BLK
IN
( V ) ( V ) cont
cont
cont
cont
Adj
Adj
ness
FF
FF
FF
a
a
a
a
a
a
a
a
a
a
b
5
2
IA
b
a
a
a
a
a
a
a
a
a
b
5
2
Output dynamic range
26,28,
30
Maximum input
26,28,
30
Maximum gain
26,28,
30
-
Main contrast control
characteristics 1 (MAX)
Main contrast control
relative characteristics 1
Main contrast control
characteristics 2 (TYP)
Main contrast control
relative characteristics 2
Main contrast control
characteristics 3 (MIN)
Main contrast control
relative characteristics 3
Sub contrast control
characteristics 1 (MAX)
Sub contrast control
relative characteristics 1
Sub contrast control
characteristics 2 (TYP)
Sub contrast control
relative characteristics 2
Sub contrast control
characteristics 3 (MIN)
Sub contrast control
relative characteristics 3
ABL control
characteristics 1
ABL control relative
characteristics 1
ABL control
characteristics 2
ABL control relative
characteristics 2
ABL control
characteristics 3
ABL control relative
characteristics 3
Brightness control
characteristics 1
Brightness control
relative characteristics 1
Brightness control
characteristics 2
Brightness control
relative characteristics 2
Brightness control
characteristics 3
Brightness control
relative characteristics 3
Pulse characteristics 1
(4Vp-p)
Relative pulse
characteristics 1 (4Vp-p)
Pulse characteristics 2
(4Vp-p)
Relative pulse
characteristics 2 (4Vp-p)
Clamp pulse
threshold voltage
Clamp pulse
minimum width
26,28,
30
26,28,
30
b
b
b
b
b
b
a
b
b
b
b
b
a
b
b
b
b
b
a
a
a
a
a
a
a
b
b
b
b
b
a
a
a
a
a
a
a
a
a
a
a
a
a
a
a
a
a
a
a
a
a
a
a
a
a
a
a
a
a
a
b
b
b
b
b
b
5
5
5
5
5
5
2
0.5
2
2
2
2
-
-
-
-
-
-
-
-
-
-
-
-
-
-
26,28,
30
b
b
b
a
b
a
a
a
a
a
b
5
2
26,28,
30
26,28,
30
26,28,
30
26,28,
30
-
b
b
b
b
-
b
b
b
b
-
b
b
b
b
-
a
a
a
a
-
b
b
b
b
-
a
a
a
a
-
a
a
a
a
-
a
a
a
a
-
a
a
a
a
-
a
a
a
a
-
b
b
b
b
-
5
5
5
4
-
2
2
2
2
-
26,28,
30
b
b
b
a
b
a
a
a
a
a
b
2
2
-
-
-
-
-
-
-
-
-
-
-
-
-
-
26,28,
30
26,28,
30
26,28,
30
26,28,
30
-
b
b
b
b
-
b
a
a
a
-
b
a
a
a
-
a
a
a
a
-
b
a
a
a
-
a
a
a
a
-
a
a
a
a
-
a
a
a
a
-
a
a
a
a
-
a
a
a
a
-
b
b
b
b
-
0
5
5
5
-
2
4
2
0.5
-
26,28,
30
b
b
b
a
b
a
a
a
a
a
b
5
2
-
-
-
-
-
-
-
-
-
-
-
-
-
-
26,28,
30
26,28,
30
26,28,
30
07H 08H 09H 0AH
12V
IB
Relative maximum gain
Limits
32 00H 01H 02H 03H 04H 05H 06H
5V Circuit current 1
power save mode
12V Circuit current 2
normal mode
5V Circuit current 3
normal mode
IB
Bus CTL (H)
CTL Vol.
13
b
b
b
b
a
a
b
a
a
a
a
a
b
a
a
a
a
a
a
a
a
a
a
a
a
a
a
a
a
a
b
b
b
5
5
5
2
2
2
FF
00
00
08
255 255 255 255
0
0
8
FF
FF
00
00
08
255 255 255 255
FF
0
0
8
FF
00
00
08
FF
FF
FF
FF
255 255 255 255
0
0
8
FF
00
00
08
FF
FF
FF
255 255 255 255
0
0
8
46
FF
00
00
08
70
255 255 255
0
0
8
FF
FF
00
00
08
FF
FF
FF
FF
255 255 255 255
0
0
8
FF
00
00
08
FF
FF
FF
255 255 255 255
0
0
8
C8
00
00
08
FF
FF
FF
200 255 255 255
0
0
8
C8
00
00
08
FF
FF
FF
200 255 255 255
0
0
8
80
00
00
08
FF
FF
FF
128 255 255 255
0
0
8
80
FF
00
00
08
128 255 255 255
0
0
8
10
FF
FF
00
00
08
16
255 255 255
0
0
8
10
FF
00
00
08
16
255 255 255
0
0
8
FF
C8
00
00
08
FF
FF
FF
FF
C8
FF
C8
255 200 200 200
0
0
8
FF
00
00
08
C8
C8
C8
255 200 200 200
0
0
8
FF
00
00
08
80
80
80
255 128 128 128
0
0
8
FF
00
00
08
80
80
80
255 128 128 128
0
0
8
FF
00
00
08
10
10
10
255
16
16
16
0
0
8
FF
10
10
10
00
00
08
255
16
16
16
0
0
8
FF
FF
FF
FF
00
00
08
255 255 255 255
0
0
8
FF
00
00
08
8
FF
FF
FF
255 255 255 255
0
0
FF
FF
00
00
08
255 255 255 255
0
0
8
FF
FF
FF
FF
FF
00
00
08
255 255 255 255
0
0
8
FF
00
00
08
FF
FF
FF
FF
255 255 255 255
0
0
8
FF
00
00
08
FF
FF
FF
255 255 255 255
0
0
8
FF
00
00
08
FF
FF
FF
255 255 255 255
0
0
8
FF
00
00
08
FF
FF
FF
255 255 255 255
0
0
8
FF
00
00
08
FF
FF
FF
255 255 255 255
0
0
8
FF
00
00
08
FF
FF
FF
255 255 255 255
0
0
8
FF
00
00
08
FF
FF
FF
255 255 255 255
0
0
8
FF
00
00
08
8
FF
FF
FF
255 255 255 255
0
0
C8
FF
00
00
08
200 255 255 255
0
0
8
C8
FF
FF
FF
FF
00
00
08
200 255 255 255
0
0
8
C8
00
00
08
FF
FF
FF
FF
200 255 255 255
0
0
8
C8
00
00
08
FF
FF
FF
200 255 255 255
0
0
8
FF
00
00
08
FF
FF
FF
255 255 255 255
0
0
8
FF
FF
00
00
08
255 255 255 255
0
0
8
FF
FF
SW
SW
0
0
0
0
0
0
0
0
0
0
00
00
00
0
0
0
00
00
00
00
0
0
0
0
00
00
00
00
0
0
0
0
FF
FF
FF
FF
255 255 255 255
0
0
0
0
FF
FF
FF
FF
FF
FF
FF
FF
FF
255 255 255 255
FF
FF
FF
255 255 255 255
FF
0
FF
255 255 255 255
FF
0
FF
255 255 255 255
FF
0
FF
255 255 255 255
FF
0
D/A
0
FF
0
D/A
00
FF
0
D/A
FF
FF
FF
255 255 255 255
FF
FF
FF
FF
0
0
255 255 255 255
0
0
255 255 255 255
FF
FF
0
0
0
0
0
0
0
0
0
0
FF
FF
FF
FF
FF
FF
FF
FF
FF
FF
FF
FF
FF
FF
FF
FF
FF
FF
255 255 255 255
FF
0
FF
255 255 255 255
FF
0
FF
255 255 255 255
FF
0
FF
255 255 255 255
FF
0
FF
255 255 255 255
FF
0
FF
FF
255 255 255 255
FF
0
FF
FF
255 255 255 255
FF
0
FF
255 255 255 255
FF
0
FF
FF
FF
255 255 255 255
FF
FF
FF
FF
0
0
255 255 255 255
0
0
255 255 255 255
FF
FF
0
0
0
0
0
0
0
0
0
FF
FF
FF
FF
FF
FF
FF
FF
FF
FF
FF
FF
FF
FF
FF
FF
255 255 255 255
FF
0
FF
255 255 255 255
FF
0
FF
255 255 255 255
FF
0
FF
255 255 255 255
FF
0
FF
FF
255 255 255 255
FF
0
FF
FF
255 255 255 255
FF
0
FF
255 255 255 255
FF
0
FF
FF
FF
255 255 255 255
FF
FF
FF
FF
0
0
255 255 255 255
0
0
255 255 255 255
FF
FF
0
0
0
0
0
FF
FF
FF
FF
FF
FF
FF
FF
FF
255 255 255 255
FF
0
FF
FF
255 255 255 255
FF
0
FF
255 255 255 255
FF
0
MIN TYP MAX
Unit
OUT1 OUT2 OUT3 OUT4
FF
FF
FF
255 255 255 255
-
6
10
mA
105 130 mA
-
4
8
mA
7.5
9
-
VDC
1.4
-
-
Vp-p
16 17.5 19
1.2
dB
0.8
1.0
-
3.3
4
0.8
1.0
1.2
2.3
2.8
3.3 Vp-p
0.8
1.0
1.2
4.7 Vp-p
-
-
0.25 0.55 0.85 Vp-p
-0.2
0
0.2 Vp-p
3.3
4
4.7 Vp-p
0.8
1.0
1.2
2.3
2.8
3.3 Vp-p
0.8
1.0
1.2
0.2
0.5
0.8 Vp-p
-0.2
0
0.2 Vp-p
3.4
4.2
5.0 Vp-p
0.8
1.0
1.2
1.5
2.0
2.5 Vp-p
0.8
1.0
1.2
-0.3
0
0.3 Vp-p
-0.2
0
0.2 Vp-p
3.4
3.8
4.2
VDC
-0.3
0
0.3
V
1.6
1.9
2.2
VDC
-0.3
0
0.3
V
0.3
0.5
0.7
VDC
-0.3
0
0.3
V
-
2.2
2.7
3.0
3.5
nS
-
-
-
-
-0.8
0
0.8
nS
-
2.2
2.7
3.0
3.5
nS
-0.8
0
0.8
nS
0.7
1.5
2.3
VDC
0.2
-
-
uS
*)
*)
*) No. 32&34 Pulse characteristics 1&2 (4Vp-p)
top : M61311SP under : M61316SP
MITSUBISHI
ELECTRIC
6
MITSUBISHI ICs (MONITOR)
M61311SP/M61316SP
2
I C BUS CONTROLLED VIDEO PRE-AMP FOR HIGH RESOLUTION COLOR DISPLAY
Input
No. Symbol
38
39
OTr
OTf
40 Oadj1
41 Oadj1
42 Oadj2
43 Oadj2
44 Oadj3
45 Oadj3
46 VthOSD
47 OBLK
48 OBLK
50 VthBLK
51 HBLK1
52 HBLK2
53 HBLK3
54 VthHBLK
55 SS-NV
56 SS-SV
57 VSH
58
VSL
parameter
OSD pulse
characteristics 1
OSD pulse
characteristics 2
OSD adjust control
characteristics 1 (MAX)
OSD adjust control
relative characteristics 1
OSD adjust control
characteristics 2 (TYP)
OSD adjust control
relative characteristics 2
OSD adjust control
characteristics 3 (MIN)
OSD adjust control
relative characteristics 3
OSD input
threshold voltage
Black level difference
in OSD BLK on/off
Relative OBLK
OSD BLK input
threshold voltage
Retrace BLK
characteristics 1
Retrace BLK
characteristics 2
Retrace BLK
characteristics 3
Retrace BLK input
threshold voltage
SOG input maximum
noise voltage
SOG minimum input
voltage
Sync output high level
Sync output low level
59 TDS-F Sync output delay time 1
60 TDS-R Sync output delay time 2
61 VD-NV
62 VD-SV
63 VVDH
64 VVDL
V-DET input maximum
noise voltage
V-DET minimum input
voltage
V-DET output high level
V-DET output low level
Test
point
26,28,
30
69 IA+1
70 IA+2
7
12
CTL Vol.
13 14
15 17
18 31
R
G SonG B
OSD OSD OSD OSD RET CP ABL BRT Main Sub R Sub G Sub B OSD ReBLK Sharp SonG VDET D/A
Vcc
IN
IN
IN
IN
BLK R IN G IN B IN BLK
b
a
a
a
a
a
b
b
b
a
IN
b
( V ) ( V ) cont
cont
cont
cont
Adj
Adj
ness
FF
FF
FF
FF
5
2
a
a
b
b
b
a
b
5
2
26,28,
30
b
a
a
a
a
b
b
b
b
a
b
5
2
-
-
-
-
-
-
-
-
-
-
-
-
-
26,28,
30
b
a
a
a
a
b
b
b
b
a
b
5
2
-
-
-
-
-
-
-
-
-
-
-
-
-
-
26,28,
30
b
a
a
a
a
b
b
b
b
a
b
5
2
-
-
-
-
-
-
-
-
-
-
-
-
-
-
26,28,
30
b
a
a
a
a
a
b
b
b
a
b
5
2
26,28,
30
b
a
a
a
a
b
a
a
a
a
b
5
2
26,28,
30
b
a
a
a
a
b
a
a
a
a
b
5
2
26,28,
30
b
b
b
a
b
b
a
a
a
a
b
5
2
26,28,
30
b
a
a
a
a
a
a
a
a
b
b
5
2
26,28,
30
b
a
a
a
a
a
a
a
a
b
b
5
2
26,28,
30
b
a
a
a
a
a
a
a
a
b
b
5
2
26,28,
30
b
a
a
a
a
a
a
a
a
b
b
5
2
9
b
a
a
b
a
a
a
a
a
a
b
5
2
9
b
a
a
b
a
a
a
a
a
a
b
5
2
9
b
a
a
b
a
a
a
a
a
a
b
5
2
9
b
a
a
b
a
a
a
a
a
a
b
5
2
9
b
a
a
b
a
a
a
a
a
a
b
5
2
9
10
10
10
10
21,22,
23,24
b
a
a
b
a
a
a
a
a
a
b
5
2
b
b
b
a
b
a
a
a
a
a
b
5
2
b
b
b
a
b
a
a
a
a
a
b
5
2
b
b
b
b
b
b
a
a
b
b
a
a
a
a
a
a
a
a
a
a
b
b
5
5
2
2
b
b
b
a
b
a
a
a
a
a
b
5
2
b
b
b
a
b
a
a
a
a
a
b
5
2
b
a
a
a
a
a
a
a
a
a
b
5
2
21,22,
23,24
b
a
a
a
a
a
a
a
a
a
b
5
2
D/A OUT input current 1
21,22,
23,24
b
a
a
a
a
a
a
a
a
a
b
5
2
D/A OUT input current 2
21,22,
23,24
b
a
a
a
a
a
a
a
a
a
b
5
2
b
a
a
a
a
a
a
a
a
a
b
5
2
71
IA-
D/A OUT output current
21,22,
23,24
72
DNL
D/A nonlinearity
21,22,
23,24
Limits
07H 08H 09H 0AH
12V
a
-
Bus CTL (H)
32 00H 01H 02H 03H 04H 05H 06H
a
10
VDL
5
a
66 TDV-R V-DET output delay time 2
68
4
b
10
67 VDH
2
26,28,
30
65 TDV-F V-DET output delay time 1
D/A output
maximum voltage
D/A output
minimum voltage
3
b
a
a
a
a
a
a
a
a
a
b
5
2
6F
00
08
255 255 255 255 111
0
8
FF
6F
00
08
255 255 255 255 111
0
8
FF
FF
FF
FF
7F
00
08
255 255 255 255 127
0
8
FF
00
08
FF
FF
FF
FF
FF
FF
7F
255 255 255 255 127
FF
0
8
FF
40
00
08
255 255 255 255
64
0
8
FF
FF
FF
FF
FF
40
00
08
255 255 255 255
64
0
8
FF
00
00
08
FF
FF
FF
FF
255 255 255 255
0
0
8
FF
FF
00
00
08
255 255 255 255
0
0
8
FF
FF
FF
FF
FF
00
00
08
255 255 255 255
0
0
8
FF
00
00
08
FF
FF
FF
FF
255 255 255 255
0
0
8
FF
FF
00
00
08
255 255 255 255
0
0
8
FF
FF
FF
FF
FF
00
00
08
255 255 255 255
0
0
8
FF
00
0F
08
FF
FF
FF
FF
255 255 255 255
0
15
8
FF
FF
00
08
08
255 255 255 255
0
8
8
FF
FF
FF
FF
FF
00
00
08
255 255 255 255
0
0
8
FF
00
00
08
FF
FF
FF
FF
255 255 255 255
0
0
8
FF
FF
00
00
08
255 255 255 255
0
0
8
FF
FF
FF
FF
FF
00
00
08
255 255 255 255
0
0
8
FF
00
00
08
FF
FF
FF
FF
255 255 255 255
0
0
8
FF
FF
00
00
08
255 255 255 255
0
0
8
FF
FF
FF
FF
FF
00
00
08
255 255 255 255
0
0
8
FF
00
00
08
FF
FF
FF
FF
255 255 255 255
0
0
8
FF
FF
00
00
08
255 255 255 255
0
0
8
FF
FF
FF
FF
FF
00
00
08
255 255 255 255
0
0
8
FF
00
00
08
FF
FF
FF
FF
255 255 255 255
0
0
8
FF
00
00
08
8
FF
FF
FF
255 255 255 255
0
0
FF
FF
00
00
08
255 255 255 255
0
0
8
FF
FF
FF
FF
FF
00
00
08
255 255 255 255
0
0
8
FF
00
00
08
FF
FF
FF
FF
255 255 255 255
0
0
8
FF
FF
00
00
08
255 255 255 255
0
0
8
FF
FF
FF
FF
FF
00
00
08
255 255 255 255
0
0
8
FF
00
00
08
FF
FF
FF
FF
255 255 255 255
0
0
8
FF
FF
00
00
08
255 255 255 255
0
0
8
FF
FF
00
00
08
255 255 255 255
0
0
8
FF
FF
MITSUBISHI
ELECTRIC
FF
FF
D/A
D/A
D/A
SW
SW
OUT1 OUT2 OUT3 OUT4
0
0
255 255 255 255
FF
FF
FF
FF
FF
FF
FF
FF
0
0
255 255 255 255
0
0
255 255 255 255
FF
FF
0
0
FF
FF
FF
FF
FF
FF
255 255 255 255
FF
FF
FF
FF
0
0
255 255 255 255
0
0
255 255 255 255
FF
FF
0
0
FF
FF
FF
FF
FF
FF
255 255 255 255
FF
FF
FF
FF
0
0
255 255 255 255
0
0
255 255 255 255
FF
FF
0
0
FF
FF
FF
FF
FF
FF
255 255 255 255
FF
FF
FF
FF
0
0
255 255 255 255
0
0
255 255 255 255
FF
FF
0
0
FF
FF
FF
FF
FF
FF
255 255 255 255
FF
FF
FF
FF
0
0
255 255 255 255
0
0
255 255 255 255
FF
FF
0
0
FF
FF
FF
FF
FF
FF
255 255 255 255
FF
FF
FF
FF
0
0
255 255 255 255
0
0
255 255 255 255
FF
FF
0
0
FF
FF
FF
FF
FF
FF
255 255 255 255
FF
FF
FF
FF
0
0
255 255 255 255
0
0
255 255 255 255
FF
FF
0
0
FF
FF
FF
FF
FF
FF
255 255 255 255
FF
FF
FF
FF
0
0
255 255 255 255
0
0
255 255 255 255
FF
FF
0
0
0
FF
FF
FF
FF
FF
255 255 255 255
FF
0
FF
FF
FF
FF
255 255 255 255
FF
FF
FF
FF
0
0
255 255 255 255
0
0
255 255 255 255
FF
FF
0
0
0
0
0
0
0
0
FF
FF
FF
FF
FF
FF
255 255 255 255
00
00
00
00
0
0
0
0
00
00
00
00
0
0
0
0
00
00
00
00
0
0
0
0
FF
FF
FF
FF
MIN TYP MAX
Unit
-
2
5
nS
-
4
7
nS
3.3
4.0
4.9 Vp-p
0.8
1.0
1.2
1.2
1.8
2.4 Vp-p
0.8
1.0
1.2
-
-
-0.5 -0.1 0.3 Vp-p
-0.2
0
1.7
2.5
0.2
-
3.3 VDC
-0.5 -0.1 0.3 VDC
0
1.7
2.5
3.3 VDC
1.6
1.9
2.2 VDC
1.0
1.3
1.6 VDC
0.3
0.6
0.9 VDC
0.7
1.5
2.3 VDC
-
-
0.02 Vp-p
0.2
-
4.5
4.9
5.0 VDC
0
0.4
0.7 VDC
10
30
65
nS
10
30
65
nS
-
-
0.2
-
3.8
4.2
5.0 VDC
0
0.7
1.1 VDC
10
23
50
nS
1
13
40
nS
4.7
5.2
5.7 VDC
0
0
0.5 VDC
0.18
-
-
mA
0.18
-
-
mA
-
-
0.4
mA
-
1.0 LSB
0
0
255 255 255 255
0
0
Vari Vari Vari Vari
-1.0
able able able able
0.2
-
-0.2
-
Vp-p
0.05 Vp-p
-
Vp-p
7
MITSUBISHI ICs (MONITOR)
M61311SP/M61316SP
2
I C BUS CONTROLLED VIDEO PRE-AMP FOR HIGH RESOLUTION COLOR DISPLAY
Note1)
Measuring conditions are as listed in supplementary Table. Measured with a current meter at test point IB.
Note2)
Measuring conditions are as listed in supplementary Table. Measured with a current meter at test point IA.
Note3)
Measuring conditions are as listed in supplementary Table. Measured with a current meter at test point IB.
Note4)
It makes the amplitude of SG1 1.4p-p. Measure the DC voltage of the white level of the waveform output.
The measured value is called Vomax.
(VDC)
Waveform output
Vomax
0.5
0.0
Note5)
Increase the input signal(SG1) amplitude gradually, starting from 0.7Vp-p. Measure the amplitude of the
input signal when the output signal starts becoming distorted.
Note6)
Input SG1, and measure the amplitude output at OUT(26,28,30). The amplitude is called VOUT(26,28,30).
Maximum gain GV is calculated by the equation below:
GV = 20 LOG ( VOUT / 0.7 ) (dB)
Note7)
Relative maximum gain GV is calculated by the equation below:
GV = VOUT(26) / VOUT(28) , VOUT(28) / VOUT(30) , VOUT(30) / VOUT(26)
Note8)
Input SG1, and measure the amplitude output at OUT(26,28,30). The amplitude is called VOUT(26,28,30).
The measured value is called VC1.
Note9)
Relative characteristics VC1 is calculated by the equation below:
VC1 = VOUT(26) / VOUT(28) , VOUT(28) / VOUT(30) , VOUT(30) / VOUT(26)
Note10) Measuring condition and procedure are the same as described in Note8.
Note11) Measuring condition and procedure are the same as described in Note9.
Note12) Measuring condition and procedure are the same as described in Note8.
Note13) Relative characteristics VC3 is calculated by the equation below:
VC3 = VOUT(26) - VOUT(28) , VOUT(28) - VOUT(30) , VOUT(30) - VOUT(26)
NOte14) Input SG1, and measure the amplitude output at OUT(26,28,30). The amplitude is called VOUT(26,28,30).
The measured value is called VSC1.
Note15) Relative characteristics VSC1 is calculated by the equation below:
VSC1 = VOUT(26) / VOUT(28) , VOUT(28) / VOUT(30) , VOUT(30) / VOUT(26)
Note16) Measuring condition and procedure are the same as described in Note14.
Note17) Measuring condition and procedure are the same as described in Note15.
Note18) Measuring condition and procedure are the same as described in Note14.
Note19) Relative characteristics VSC3 is calculated by the equation below:
VSC3 = VOUT(26) - VOUT(28) , VOUT(28) - VOUT(30) , VOUT(30) - VOUT(26)
MITSUBISHI
ELECTRIC
8
MITSUBISHI ICs (MONITOR)
M61311SP/M61316SP
2
I C BUS CONTROLLED VIDEO PRE-AMP FOR HIGH RESOLUTION COLOR DISPLAY
Note20) Measure the amplitude output at OUT(26,28,30). The amplitude is called VOUT(26,28,30).
The measured value is ABL1.
Note21) Relative characteristics ABL1 is calculated by the equation below:
ABL1 = VOUT(26) / VOUT(28) , VOUT(28) / VOUT(30) , VOUT(30) / VOUT(26)
Note22) Measuring condition and procedure are the same as described in Note20.
Note23) Measuring condition and procedure are the same as described in Note21.
Note24) Measuring condition and procedure are the same as described in Note20.
Note25) Relative characteristics ABL3 is calculated by the equation below:
ABL3 = VOUT(26) - VOUT(28) , VOUT(28) - VOUT(30) , VOUT(30) - VOUT(26)
Note26) Measure the DC voltage at OUT(26,28,30). The amplitude is called VOUT(26,28,30).
The measured value is called VB1.
Note27) Relative characteristics VB1 is calculated by the equation below:
VB1 = VOUT(26) - VOUT(28) , VOUT(28) - VOUT(30) , VOUT(30) - VOUT(26)
Note28) Measuring condition and procedure are the same as described in Note26.
Note29) Measuring condition and procedure are the same as described in Note27.
Note30) Measuring condition and procedure are the same as described in Note26.
Note31) Measuring condition and procedure are the same as described in Note27.
Note32) Measure the time needed for the input pulse to rise from 10% to 90% (Tr1) and for the output pulse to rise
from 10% to 90% (Tr2) with an active probe.
Pulse characteristics Tr is calculated by the equations below:
(Tr2)2 - (Tr1)2 (nS)
Tr =
Note33) Relative characteristics Tr is calculated by the equation below:
Tr = Tr(26) - Tr(28) , Tr(28) - Tr(30) , Tr(30) - Tr(26)
Note34) Measure the time needed for the input pulse to fall from 90% to 10% (Tf1) and for the output pulse to fall
from 90% to 10% (Tf2) with an active probe.
Pulse characteristics Tf is calculated by the equations below:
Tf =
(Tf2)2 - (Tf1)2 (nS)
Note35) Relative characteristics Tf is calculated by the equation below:
Tf = Tf(26) - Tf(28) , Tf(28) - Tf(30) , Tf(30) - Tf(26)
100%
90%
10%
0%
Tr1
or
Tr2
Tf1
or
Tf2
MITSUBISHI
ELECTRIC
9
MITSUBISHI ICs (MONITOR)
M61311SP/M61316SP
2
I C BUS CONTROLLED VIDEO PRE-AMP FOR HIGH RESOLUTION COLOR DISPLAY
Note36) Decrease the SG5 input level gradually from 5.0Vp-p, monitoring the waveform output. Measure the top
level of input pulse when the output pedestal voltage turn decrease with unstable. And increase the SG5
input level gradually from 0Vp-p. Measure the top level of input pulse when the output pedestal voltage
turn increase with stable (a point of 2.0V). The measured value is called VthCP.
Note37) Decrease the SG5 pulse width gradually from 0.5uS, monitoring the output. Measure the SG5 pulse width
when the output pedestal voltage turn decrease with unstable. And increase the SG5 pulse width gradually
from 0uS. Measure the SG5 pulse width when the output pedestal voltage turn increase with stable (a point
of 2.0V). The measured value is called WCP.
Note38) Measure the time needed for the output pulse to rise from 10% to 90% (OTr) with an active probe.
Note39) Measure the time needed for the output pulse to fall from 90% to 10% (OTf) with an active probe.
Note40) Measure the amplitude output at OUT(26,28,30). The amplitude is called VOUT(26,28,30).
The measured value is called Oadj1.
Note41) Relative characteristics Oadj1 is calculated by the equation below:
Oadj1 = VOUT(26) / VOUT(28) , VOUT(28) / VOUT(30) , VOUT(30) / VOUT(26)
Note42) Measuring condition and procedure are the same as described in Note40.
Note43) Measuring condition and procedure are the same as described in Note41.
Note44) Measuring condition and procedure are the same as described in Note40.
Note45) Relative characteristics Oadj3 is calculated by the equation below:
Oadj3 = VOUT(26) - VOUT(28) , VOUT(28) - VOUT(30) , VOUT(30) - VOUT(26)
Note46) Decrease the SG6 input level gradually from 5.0Vp-p, monitoring the output. Measure the top level of SG6
when the output is disappeared. And increase the SG6 input level gradually from 0Vp-p. Measure the top
level of SG6 when the output is appeared. The measured value is called VthOSD.
Note47) Calculating the black level voltage minus the output voltage of high section of SG6 it makes
VOUT(26,28,30). The calculated value is called OBLK.
Note48) Relative characteristics OBLK is calculated by the equation below:
OBLK = VOUT(26) - VOUT(28) , VOUT(28) - VOUT(30) , VOUT(30) - VOUT(26)
Note50) Confirm that output signal is being blanked by the SG6 at the time.
Decrease the SG6 input level gradually from 5.0Vp-p, monitoring the output. Measure the top level of SG6
when the blanking period is disappeared. And increase the SG6 input level gradually from 0Vp-p. Measure
the top level of SG6 when the blanking period is appeared. The measured value is called VthBLK.
Note51) Measure the bottom voltage at amplitude of OUT(26,28,30). The measured value is called HBLK1.
Note52) Measuring condition and procedure are the same as described in Note51.
Note53) Measuring condition and procedure are the same as described in Note51.
Note54) Decrease the SG7 input level gradually from 5.0Vp-p, monitoring the output. Measure the top level of SG7
when the output is disappeared. And increase the SG7 input level gradually from 0Vp-p. Measure the top
level of SG7 when the output is appeared. The measured value is called VthHBLK.
MITSUBISHI
ELECTRIC
10
MITSUBISHI ICs (MONITOR)
M61311SP/M61316SP
2
I C BUS CONTROLLED VIDEO PRE-AMP FOR HIGH RESOLUTION COLOR DISPLAY
Note55) When SG4 is all black (no video), the sync's amplitude of SG4 gradually from 0Vp-p to 0.02Vp-p.
No pulse output permitted.
Note56) When SG4 is all white or all black, the sync's amplitude of SG4 gradually from 0.2Vp-p to 0.3Vp-p.
Positive pulse has occurred to Sync Sepa OUT.
Note57) Measure the high voltage at Sync Sepa OUT. The measured value is treated as VSH.
Note58) Measure the low voltage at Sync Sepa OUT. The measured value is treated as VSL.
Note59) Sync Sepa OUT becomes high with sink part of SG4.
Measure the time needed for the front edge of SG4 Sync to fall from 50% and for SyncOUT to rise from
50% with an active probe. The measured value is called TDS-F.
Note60) Sync Sepa OUT becomes high with sink part of SG4.
Measure the time needed for the rear edge of SG4 Sync to rise from 50% and for SyncOUT to fall from
50% with an active probe. The measured value is called TDS-R.
SG4
Pedestal voltage
Sync(50%)
Sync Sepa OUT
TDS-F
(50%)
TDS-R
Note61) Increase the SG1 input level gradually from 0Vp-p to 0.05Vp-p. No pulse Video Det OUT permitted.
Note62) Decrease the SG1 input level gradually from 0.2p-p to 0.3Vp-p. Positive pulse has occurred to Video Det OUT.
Note63) Measure the high voltage at Video Det OUT. The measured value is treated as VVDH.
Note64) Measure the low voltage at Video Det OUT. The measured value is treated as VVDL.
Note65) Video Det OUT becomes high with signal part of SG1.
Measure the time needed for the SG1 to fall from 50% and for Video Det OUT to fall from 50% with an active
probe. The measured value is called TDV-F.
Note66) Video Det OUT becomes high with signal part of SG1.
Measure the time needed for the SG1 to rise from 50% and for Video Det OUT to rise from 50% with an active
probe. The measured value is called TDV-R.
SG1
Video(50%)
(50%)
Pedestal voltage
Video Det OUT
TDV-R
TDV-F
MITSUBISHI
ELECTRIC
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MITSUBISHI ICs (MONITOR)
M61311SP/M61316SP
2
I C BUS CONTROLLED VIDEO PRE-AMP FOR HIGH RESOLUTION COLOR DISPLAY
Note68) Measure the DC voltage at D/A OUT. The measured value is called VDL.
Note69) Measure the input current that flows into D/A OUT through 1Kohm by 2VDC.
Note70) Measure the input current that flows into D/A OUT through 1Kohm by 0.5VDC.
Note71) Measure the output current that flows out of D/A OUT through 1Kohm by 4.2VDC.
A
1Kohm
D/A OUT
Note72) The difference of differential non-linearity of D/A OUT must be less than ±1.0LSB.
MITSUBISHI
ELECTRIC
12
MITSUBISHI ICs (MONITOR)
M61311SP/M61316SP
2
I C BUS CONTROLLED VIDEO PRE-AMP FOR HIGH RESOLUTION COLOR DISPLAY
SG No.
Input signal
33uS
SG1
Pulse with amplitude of
0.7Vp-p. (f=30KHz)
Video width 25uS. (75%)
(amplitude is variable)
8uS
Video signal
(all white)
0.7Vp-p
Video width 25uS. (75%)
All white or all black
variable.
SG4
0.7Vp-p
Video Signal
(all white, all
black)
Sync's amplitude
is variable.
3uS
0.3Vp-p
0.5uS
Pulse width and
amplitude are
variable.
SG5
5VTTL
Clamp pulse
Amplitude is variable.
SG6
5VTTL
OSD pulse
10uS
Amplitude is variable.
SG7
5VTTL
BLK pulse
5uS
MITSUBISHI
ELECTRIC
13
MITSUBISHI
ELECTRIC
IA
SW3
a
12V
A
b
47u
V32
29
1K
28
OUT(28)
27
1K
26
OUT(26)
25
1K
24
D/A
OUT
(24)
23
D/A
OUT
(23)
22
D/A
OUT
(22)
21
D/A
OUT
(21)
3
2
1
SG1
b
SW4
a
3.3u
3.3u
SW2
a
IN(4)
4
5
SG4
SW7
a
b
SW5
b a
IN(7)
7
b
8
10
Sync Video
Sepa Det
OUT OUT
9
IB
5V
A
12
14
15
SG6
b
OSD
B
IN
CP
IN
SW15
b a
OSD
G
IN
SDA
19
18
Measure point
(unless otherwise specified)
* Capacitor : 0.01uF
16
GND
Ret
BLK
IN
17
SG5
SG7
SW18 SW17
a
b a
b
CP
IN
SCL
SW14
b a
13
OSD
R
IN
SCL
20
SDA
SW13
b a
OSD
BLK
IN
SW12
a
11
5V
47u
50K
Sync Video
Sepa Det
GND OUT OUT
0.01u
B IN
3.3u
6
GND
0.01u 1u
SonG
IN
G IN
IN(2)
0.01u
12V
R IN
SonG
IN
ABL R OUT 12V G OUT GND B OUT GND D/A
D/A
D/A
D/A
IN
OUT4 OUT3 OUT2 OUT1
30
OUT(30)
GND
Bright
31
0 - 5V
V31
32
0 - 5V
MITSUBISHI ICs (MONITOR)
M61311SP/M61316SP
I C BUS CONTROLLED VIDEO PRE-AMP FOR HIGH RESOLUTION COLOR DISPLAY
2
TEST CIRCUIT
14
MITSUBISHI ICs (MONITOR)
M61311SP/M61316SP
2
I C BUS CONTROLLED VIDEO PRE-AMP FOR HIGH RESOLUTION COLOR DISPLAY
TERMINAL DESCRIPTION
No.
Name
Remark
Peripheral Circuit of pins
DC Voltage(V)
12V
2
R IN
4
G IN
7
B IN
2K
2K
3.5
CP
0.02mA
3
VCC 1 (12V)
Clamp to about 3.5V due to clamp
pulse from Pin18.
Input at low impedance.
2.25V
3.5V
Connect to the power supply that
stabilized.
12
5V
30K
1.5K
5
SonG IN
When open
2.3
6K
1.5K
6K
10K
5
1K
2.28V
0.13mA
0.2mA
1
6
8
16
27
GND
GND 1
GND 2
GND 3
GND 4
Connect to GND.
GND
Sync Sepa output pin.
When the rise time of the signal is
sped up, connect about 2.3 Kohm
between 5V power supply.
When it does not use, do openly.
So as not to flow into Pin9 8mA over,
resistance value does not make to
2.3Kohm or under.
5V
1K
9
Sync Sepa
OUT
2.4V
SYNC ON VIDEO input pin.
Sync is negative.
Input signal at Pin5, compare with the
reference voltage of internal circuit
in order to separate Sync signal from
Sync on Green signal.
Input at low impedance.
Do not input the signal without
the Sync.
When it does not use this function,
connect to capacitor between GND,
turn on Sync Sepa SW by IIC BUS.
-
9
Output is a positive.
12V
10
Video Det
OUT
Pin10 needs to connect the 50Kohm
between 5V power supply.
When it does not use this function,
turn off Video Det SW by IIC BUS.
10
50K
11
VCC (5V)
Connect to the power supply that
stabilized.
5
MITSUBISHI
ELECTRIC
15
MITSUBISHI ICs (MONITOR)
M61311SP/M61316SP
2
I C BUS CONTROLLED VIDEO PRE-AMP FOR HIGH RESOLUTION COLOR DISPLAY
No.
Name
Remark
Peripheral Circuit of pins
DC Voltage(V)
12V
3.5 --- 5V
12 OSD BLK IN
13
OSD R IN
14
OSD G IN
15
OSD B IN
Input the positive pulse.
0.1mA
1.5V --- GND
500
500
500
When it does not use this function,
connect to GND.
When input OSD RGB pulse, input
OSD BLK pulse without fail.
500
3.25V
3.25V
Input the positive pulse.
12V
2.5 --- 5V
50K
17
Retrace BLK
IN
0.5V --- GND
When it does not use this function,
connect to GND.
17
2.25V
12V
Input the positive pulse which width
200nS over.
Input at low impedance.
0.15mA
750
Clamp Pulse
18
IN
750
50K
2.5 --- 5V
-
0.5V --- GND
10K
10K
500
18
3.75V
12V
SDA of IIC BUS.
(Serial data line)
Tth = 2.3V
19
SDA
-
2K
19
3.0V
MITSUBISHI
ELECTRIC
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MITSUBISHI ICs (MONITOR)
M61311SP/M61316SP
2
I C BUS CONTROLLED VIDEO PRE-AMP FOR HIGH RESOLUTION COLOR DISPLAY
No.
Name
Peripheral Circuit of pins
DC Voltage(V)
Remark
12V
SCL of IIC BUS.
(Serial clock line)
Tth = 2.3V
20
SCL
-
2K
20
3.0V
12V
21
D/A OUT 1
22
D/A OUT 2
23
D/A OUT 3
24
D/A OUT 4
26
B OUT
28
G OUT
30
R OUT
27
GND 4
D/A output pin.
Output voltage ranges is 0V to 5V.
Input current is below 0.18mA.
Output current is below 0.4mA.
15K
This terminal needs to connect the
1 to 3Kohm resister between GND.
This resistance value may be
changed, to improve the
video output characteristics.
29
Variable
50
Connect to GND.
35
27
29 VCC 2 (12V)
It is the power supply of emitter
follower of RGB output exclusive use.
12
5V
6K
5K
31
ABL IN
ABL (Automatic beam limitter) input
pin.
When open
2.5V
Input voltage in the ranges of 0V to 5V.
9K
2K
16.25K
2.5K
31
0.4mA
12V
Output amplitude MAX with 5V.
Output amplitude MIN with 0V.
When it does not use this function,
connect to 5V.
It is recommended that the IC is used
between pedestal voltage 2V to 3V.
35K
35K
32
BRIGHT
-
To other
channel
32
25
NC
Connect to GND.
-
MITSUBISHI
ELECTRIC
17
MITSUBISHI ICs (MONITOR)
M61311SP/M61316SP
2
I C BUS CONTROLLED VIDEO PRE-AMP FOR HIGH RESOLUTION COLOR DISPLAY
ELECTRICAL CHARACTERISTICS (Reference data)
Main contrast control characteristics
6
Output amplitude (Vp-p)
Output amplitude (Vp-p)
6
4
2
Sub contrast control characteristics
4
2
Sub contrast : MAX
ABL
: 5V
0
00H
0
00H
FFH
Brightness control characteristics
6
Output amplitude (Vp-p)
Output DC voltage (VDC)
6
Main contrast control data
Main contrast : MAX
ABL
: 5V
4
2
Sub contrast control data
FFH
ABL control characteristics
4
2
Main contrast : MAX
Sub contrast : MAX
0
0
0.5 Brightness control voltage (VDC)4
OSD Adjust control characteristics
6
Output DC voltage (VDC)
Output amplitude (Vp-p)
6
0
4
2
ABL control voltage (VDC)
5
D/A OUT control characteristics
4
2
Brightness : 2VDC
0
00H
OSD adjust control data
7FH
0
00H
MITSUBISHI
ELECTRIC
D/A OUT control data
FFH
18
MITSUBISHI ICs (MONITOR)
M61311SP/M61316SP
2
I C BUS CONTROLLED VIDEO PRE-AMP FOR HIGH RESOLUTION COLOR DISPLAY
APPLICATION METHOD FOR M61311SP/M61316SP
ABOUT CLAMP PULSE INPUT
Clamp pulse needs to be always inputted.
Clamp pulse width is recommended :
15KHz at 1.0 uS over
30KHz at 0.5 uS over
64KHz at 0.3 uS over
The clamp pulse circuit in ordinary set is a long round about way,
and beside high voltage, sometimes connect to external terminal,
it is very easy affected by large surge.
Therfore, the fig. shown right is recommended.
18
NOTICE OF APPLICATION
Make the nearest distanse between output and pull down resister.
Recommend this resister is 1to 3 Kohm.
Power dissipation in 3Kohm is smaller than 1Kohm.
Recommend pedestal voltage of IC output signal is 2V.
As for the low level of the pulse input of OSD BLK, OSD, Clamp Pulse, Retrace BLK etc., avoid consisting
the GND level or under.
PIN31 connect to the voltage that stabilized, and pay attention as surge etc. does not flow into.
VCC(12V,5V) connects to the power supply that stabilized, and bypass-capacitor connects near the terminal.
When capacitor is connected to Pin29, it sometimes oscillates. Do not connect capacitor to Pin29.
Connect to bypass-capacitance of the DC line near the terminal.
Connect to the NC Pin to GND.
The time(t) is from fall of 9bit of SCL to rise of Acknowledge.
About the fowarding of IIC BUS, the time(t) changes with the resistance that connected outside.
The next SCL does not overlap into this time(t).
5V
R
20
SCL
400pF
SCL
t
Acknowledge
Acknowledge delay time characteristics (Reference data)
Delay time t (uS)
16
12
8
4
0
1.0
2.0
3.0
5.0
Resistance value (Kohm)
7.0
10
MITSUBISHI
ELECTRIC
19
MITSUBISHI ICs (MONITOR)
M61311SP/M61316SP
2
I C BUS CONTROLLED VIDEO PRE-AMP FOR HIGH RESOLUTION COLOR DISPLAY
APPLICATION EXAMPLE
110V
CRT
Cut Off Adj
SCL
SDA
5VDC
0.01u
47u
GND
Clamp Pulse IN
5VDC
3K
3K
ABL IN
0 - 5VDC
100uH
BRIGHT
2 - 3VDC
32
31
30
3K
100
29
28
27
26
25
24
0.01u 0.01u
0.01u 0.01u
23
21
22
20
GND
Ret BLK IN
19
18
17
14
15
16
M61311SP/M61316SP
1
2
3
4
5
6
7
8
9
10
11
12
13
50K
3.3u
0.01u 3.3u
75
0.01u 1u
75
3.3u
OSD B IN
OSD G IN
OSD R IN
OSD BLK IN
0.01u
75
5VDC
R IN
0.01u
12V
G IN
B IN
GND
Sync Video
Sepa Det
OUT OUT
47u
0.01u
5V
47u
SonG IN
"Purchase of Mitsubishi electric corporation's IIC components conveys a license
under the Philips IIC Patent Rights to use these components in an IIC system,
provided that the system conforms the IIC Standard Specification as defined by Philips"
MITSUBISHI
ELECTRIC
20
SEATING PLANE
1
32
EIAJ Package Code
SDIP32-P-400-1.78
A
L
MITSUBISHI
ELECTRIC
e
JEDEC Code
–
D
b1
Weight(g)
2.2
b
Lead Material
Alloy 42/Cu Alloy
16
17
b2
A2
A1
A
A1
A2
b
b1
b2
c
D
E
e
e1
L
Symbol
Plastic 32pin 400mil SDIP
c
Dimension in Millimeters
Min
Nom
Max
–
–
5.08
0.51
–
–
–
3.8
–
0.35
0.45
0.55
0.9
1.0
1.3
0.63
0.73
1.03
0.22
0.27
0.34
27.8
28.0
28.2
8.75
8.9
9.05
–
1.778
–
–
10.16
–
3.0
–
–
0°
–
15°
e1
32P4B
MITSUBISHI ICs (MONITOR)
M61311SP/M61316SP
I C BUS CONTROLLED VIDEO PRE-AMP FOR HIGH RESOLUTION COLOR DISPLAY
2
DETAILED DIAGRAM OF PACKAGE OUTLINE
21
E
MITSUBISHI ICs (MONITOR)
M61311SP/M61316SP
2
I C BUS CONTROLLED VIDEO PRE-AMP FOR HIGH RESOLUTION COLOR DISPLAY
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lMitsubishi Electric Corporation puts the maximum effort into making semiconductor products better and more
reliable, but there is always the possibility that trouble may occur with them. Trouble with semiconductors may
lead to personal injury, fire or property damage. Remember to give due consideration to safety when making your
circuit designs, with appropriate measures such as (i) placement of substitutive, auxiliary circuits, (ii) use of nonflammable material or (iii) prevention against any malfunction or mishap.
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MITSUBISHI
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