Datasheet M52744SP, M52743SP Datasheet (Mitsubishi)

OSD BLK IN

INPUT(R)

V

CC1(R)

OSD IN(R)

GND 1(R)
INPUT(G)

INPUT(SOG)

OSD IN(G)

GND 1(G)
INPUT(B)

OSD IN(B)

GND 1(B)

ABL IN

NC

SOG SEP OUT

V

CC2

OUTPUT(R)
EXT FEED BACK(R)
GND2
OUTPUT(G)
EXT FEED BACK(G)
MAIN BRIGHTNESS
OUTPUT(B)
EXT FEED BACK(B)
RETRACE BLK IN
D/A OUT1

D/A OUT3
D/A OUT4
GND(5V)
SDA

D/A OUT2

SCL
CLAMP PULSE IN

Outline 36P4E

36

33

34

35

1

4

3

2

325
316

289
2710
2611
2512

13
14

24
23

7
8

30
29

15 22
16 21

17

20

18 19

VCC1(G)

V

CC1(B)

V

CC (5V)

M52743SP/M52744SP

NC:NO CONNECTION

MITSUBISHI ICs (Monitor)

M52743SP/M52744SP

2

I

C BUS CONTROLLED 3-CHANNEL VIDEO PREAMPLIFIER

DESCRIPTION

M52743SP and M52744SP is semiconductor integrated circuit for
CRT display monitor.
It includes OSD blanking, OSD mixing, retrace blanking, wide band
amplifre, brightness control.
Main/sub contrast and OSD adjust function can be controlled by I

2

bus.

FEATURES

Frequency band width: RGB.............................150MHz (at -3dB)

•

OSD..............................................80MHz

Input :RGB.............................................................0.7V

OSD..........................................3V

BLK (for OSD)...........................3V

Retrace BLK.............................3V

minimum (positive)

P-P

minimum (positive)

P-P

minimum (positive)

P-P

Output :RGB...........................................................5.5V

OSD..............................................................5V

•

Main contrast and sub contrast can be controlled by I

•

Include internal and external pedestal clamp circuit.

P-P

P-P
P-P

2

C bus.

(typ.)

(max.)
(max.)

STRUCTURE

Bipola silicon monolisic IC

APPLICATION

CRT display monitor

PIN CONFIGURATION (TOP VIEW)

C

RECOMMENDED OPERATING CONDITION

Supply voltage range......................11.5 to 12.5V (V3, V8, V12, V36)

4.5 to 4.4V (V17)

Rated supply voltage..................................12.0V (V3, V8, V12, V36)

MAJOR SPECIFICATION

Bus controlled 3ch video pre-amp with OSD mixing function and
retrace blanking function

5.0V (V17)

1

BLOCK DIAGRAM

MITSUBISHI ICs (Monitor)

M52743SP/M52744SP

2

I

C BUS CONTROLLED 3-CHANNEL VIDEO PREAMPLIFIER

27

30

MAIN BRIGHTNESS RETRACE BLK IN

OUTPUT (R)
35

RETRACE

BLANKING

AMPOSD MIX

MAIN

CONTRAST

EXT FEED BACK (R)
34

F/B

CLAMP

OUTPUT (G)
32

RETRACE

AMPOSD MIX

MAIN

BLANKING

CONTRAST

EXT FEED BACK (G)
31

F/B

CLAMP

OUTPUT (B)
29

RETRACE

BLANKING

AMPOSD MIX

MAIN

CONTRAST

EXT FEED BACK (B)
28

F/B

CLAMP

OSD

Main

VCC 5V

17

4bit

LEVEL

8bit

CONTRAST

(DIGITAL)

SDA

SCL

GND(5V)

21

20

22

I/F

BUS

DAC

B SUB CONT 8bit

R SUB CONT 8bit

G SUB CONT 8bit

23 24 25 26

FOR CUT-OFF Adj

1

33

GND2 OSD BLK IN DAC OUTPUT

SUB

CLAMP

2

4

INPUT (R)

OSD IN (R)

SUB CONT

CONTRAST

3

CC1 (R) 12V

V

(8bit)

5

GND 1(R)

SUB

CLAMP

6

9

INPUT (G)

OSD IN (G)

SUB CONT

CONTRAST

8

CC1 (G) 12V

V

(8bit)

10

GND 1(G)

SUB

CLAMP

11

13

INPUT (B)

OSD IN (B)

SUB CONT

CONTRAST

12

CC1 (B) 12V

V

(8bit)

14

GND 1(B)

Sync On

GreenSep

7

15

INPUT (SOG)

CONTRAST (ABL) IN

36

CC2=12V

V

19

CLAMP PULSE

18

SOG SEP OUT

IN

2

°

°

θ

°

−

∆

∆

∆

∆

∆

∆

∆

−

MITSUBISHI ICs (Monitor)

M52743SP/M52744SP

2

I

C BUS CONTROLLED 3-CHANNEL VIDEO PREAMPLIFIER

ABSOLUTE MAXIMUM RATINGS

(Ta=25 ° C)

Symbol Parameter Ratings Unit

V

CC

P

d

T

opr

T

stg

V

opr

V

opr’

Supply voltage 13.0 V
Power dissipation 2403 mW
Ambient temperature -20 to +75
Storage temperature -40 to +150
Recommended supply 12.0 V
Voltage range 10.5 to 12.5 V

jc Case temperature 22

CC

(V

ELECTRICAL CHARACTERISTICS

Test

Symbol Parameter

Gv

C1

V

C2

V

C3

V

SC1

V

SC2

V

SC3

V

C1

C2

C3

SC1

SC2

SC3

Circuit
current1

Circuit
current2

Output
dynamic range

Maximum
input

Maximum
gain

Relative max­imum gain

Main contrast
control
characteristics1

Main contrast
control relative
characteristics1

Main contrast
control
characteristics2

Main contrast
control relative
characteristics2

Main contrast
control
characteristics3

Main contrast
control relative
characteristics3

Sub contrast
control
characteristics1

Sub contrast
control relative
characteristics1

ub contrast

S

control
characteristics2

Sub contrast
control relative
characteristics2

Sub contrast
control
characteristics3

Sub contrast
control relative
characteristics3

I

CC1

I

CC2

Vomax

Vimax

Gv

V

V

V

V

V

V

point

(s)

I

A

I

B

OUT

IN

OUT

OUT

1

2,6,11

OSD

RGB

BLK

in

aaa

aaa
b

aa

SG2

b

aa

SG2

Variable

b

aa

SG1

− −−−−−− −−−

b

OUT

SG1

aa

− −−−−−− −−−

b

OUT

SG1

aa

− −−−−−− −−−

b

OUT

SG1

aa

− −−−−−− −−−

b

OUT

SG1

aa

− − − − − − − − − −−−−

b

OUT

SG1

aa

− − − − − − − − − −−−−

b

OUT

SG1

aa

− − − − − − − − − −−−−

=12V, 5V, Ta=25 ° C, unless otherwise noted)

CTL

voltage

15

30

ABL

Bri­ght

Vari

5.0 6.0 8.0 − V

able

4,9,13

OSD

in

Input

19

CP in27ReT

b

SG5

b

SG5

b

SG5

b

SG5

b

SG5

b

SG5

b

SG5

b

SG5

b

SG5

b

SG5

b

SG5

7

SOG

in

BLK

a a 4.0 5.0

a a 4.0 5.0

aa

a a 2.0 5.0

a a 2.0 5.0

a a 2.0 5.0

a a 2.0 5.0

a a 2.0 5.0

a a 2.0 5.0

a a 2.0 5.0

a a 2.0 5.0

00H

Main

cont

FFH
255

64H
100

FFH
255

C8H

200

64H
100

14H

FFH
255

FFH
255

FFH
255

20

C
C

C/W

BUS CTL (H) Limits

01H

02H

03H

04H

05H

06H

07H

08H

Sub

Sub

cont

cont

1

2

FFH

FFH

255

255

C8H

C8H

200

200

64H

64H

100

100

14H2014H2014H

Sub
cont

3

FFH
255

C8H

200

64H
100

20

OSD

BLK

Adj

Adj

OUT

00H000H0FFH

D/A

1

255

OUT

09H

D/A

D/A

D/A

OUT

OUT

2

3

4

FFH

FFH

FFH

255

255

255

0BH

INT

EXT

Min. Typ. Max.

00H

0

110 130 mA

18 22 mA

1.6 −− V

16.5 17.7 19.7 dB

0.8 1.0 1.2 −

14.5 16.0 17.5 dB

0.8 1.0 1.2 −

8.5 10.0 11.5 dB

0.8 1.0 1.2 −

0.2 0.4 0.6 V

0.8 1.0 1.2 −

14.8 16.3 17.8 dB

0.8 1.0 1.2 −

11.1 12.6 14.1 dB

0.8 1.0 1.2 −

1.4 1.7 2.0 V

0.8 1.0 1.2 −

Unit

P-P

P-P

P-P

P-P

3

MITSUBISHI ICs (Monitor)

M52743SP/M52744SP

2

I

C BUS CONTROLLED 3-CHANNEL VIDEO PREAMPLIFIER

∆

∆

ELECTRICAL CHARACTERISTICS

Test

Symbol Parameter

Main/sub

ABL1

B1

B1

B2

B3

C1

C1’

C2

contrast control
characteristics2

Main/sub contrast
control relative
characteristics2

ABL control
characteristics1

ABL control
relative
characteristics1

ABL control
characteristics2

ABL control
relative
characteristics2

Brightness
control
characteristics1

Brightness
control relative
characteristics1

Brightness
control
characteristics2

Brightness
control relative
characteristics2

Brightness
control
characteristics3

Brightness
control relative
characteristics3

Frequency
characteristics1
(f=50MHz)

Frequency relative
characteristics1
(f=50MHz)

Frequency
characteristics1
(f=150MHz)

Frequency relative
characteristics1

(f=150MHz)

Frequency
characteristics2
(f=150MHz)

Frequency relative
characteristics2
(f=150MHz)

Crosstalk 1
(f=50MHz)

Crosstalk 1
(f=150MHz)

Crosstalk 2
(f=50MHz)

Crosstalk 2
(f=150MHz)

Crosstalk 3
(f=50MHz)

Crosstalk 3
(f=150MHz)

VMSC

VMSC

ABL1

ABL2

∆ABL2

V

∆V

VB2

∆V

VB3

∆V

FC1

∆F

F

∆FC1’

FC2

∆F

C.T.1

C.T.1’

C.T.2

C.T.2’

C.T.3

C.T.3’

point

(s)

OUT

2,6,11

RGB

in

b

SG1

4,9,13

1

OSD

BLK

aa

− − − − − − − − − −−−−

b

OUT

SG1

aa

− −−−−−− −− 0.8 1.0 1.2 −
b

OUT

SG1

aa

− −−−−−− −− 0.8 1.0 1.2 −

OUT a a a

− −−−−−− −− -0.3 0 0.3 −

OUT a a a

− −−−−−− −− -0.3 0 0.3 −

OUT a a a

− −−−−−− −− -0.3 0 0.3 −

b

OUT

SG3

aa

− −−−−−− −−− -1.0 0 1.0 dB

b

OUT

SG3

aa

− −−−−−− -1.0 0 1.0 dB

b

OUT

SG3

aa

− −−−−−− −− -1.0 0 1.0 dB

2bSG3

OUT(29)

6a
11a

2bSG3
6a
11a

2a
6bSG3
11a

2a
6bSG3
11a

2a
6a
11bSG3

2a
6a
11bSG3

aa

aa

aa

aa

aa

aa

OUT(32)

OUT(29)
OUT(32)

OUT(29)
OUT(35)

OUT(29)
OUT(35)

OUT(32)
OUT(35)

OUT(32)
OUT(35)

(cont.)

OSD

in

Input

19

CP in27ReT

b

SG5

b

SG5

b

SG5

b

SG5

b

SG5

b

SG5

a

5V

a

5V

a

5V

a

5V

a

5V

a

5V

a

5V

a

5V

a

5V

CTL

voltage

BLK

7

SOG

in

30

Bri­ght

a a 2.0 5.0

15

ABL

00H

Main

cont

C8H

200

BUS CTL (H) Limits

01H

02H

03H

04H

05H

06H

07H

08H

Sub

Sub

Sub

OSD

BLK

cont

cont

cont

1

2

3

C8H

C8H

C8H

200

200

200

Adj

Adj

OUT

00H000H0FFH

D/A

1

255

OUT

09H

D/A

D/A

D/A

OUT

OUT

2

3

4

FFH

FFH

FFH

255

255

255

0BH

INT

EXT

Min. Typ. Max.

00H

3.2 3.8 4.4 V

0

0.8 1.0 1.2 −

a a 2.0 4.0

255

FFH

255

255

255

3.8 4.6 5.4 V

FFH

FFH

FFH

a a 2.0 2.0 2.2 2.7 3.2 V

a a 4.0 5.0 3.3 3.7 4.1 V

a a 2.0 5.0 1.5 1.8 2.1 V

a a 1.0 5.0 0.7 0.9 1.1 V

aa

aa

aa

aa

aa

aa

aa

aa

aa

Vari
able

Vari
able

Vari
able

Vari
able

Vari
able

Vari
able

Vari
able

Vari
able

Vari
able

Va

5.0

5.0

ria

ble

Va
ria

ble

FFH

FFH

FFH

255

00H000H0FFH

255

255

FFH

FFH

255

255

255

-2.0 0 2.5 dB

FFH

00H

-3.0 0 3.0 dB

255

0

5.0 -3.0 3.0 5.0 dB

5.0

FFH
255

− -25 -20 dB

5.0 − -15 -10 dB

5.0 − -25 -20 dB

5.0 − -15 -10 dB

5.0 − -25 -20 dB

5.0 − -15 -10 dB

Unit

P-P

P-P

P-P

4

ELECTRICAL CHARACTERISTICS (cont.)

Symbol Parameter

Pulse

Tr

characteristics1

P-P)

(4V
Pulse

Tf

characteristics2

P-P)

(4V

Clamp pulse

VthCP

threshold
voltage

Clamp pulse

WCP

minimum
width

Pedestal voltage

DCL

temperature
characteristics1

Pedestal voltage
temperature
characteristics2

OSD pulse
characteristics1

OSD pulse
characteristics2

OSD adjust control
characteristics1

OSD adjust control
relative
characteristics1

OSD adjust control
characteristics2

OSD adjust control
relative

characteristics2
OSD adjust control

characteristics3
OSD adjust control

relative
characteristics3

PDCH

P

OTr

OTf

Oaj1

∆Oaj1

Oaj2

∆Oaj2

Oaj3

∆Oaj3

OSD input

VthOSD

threshold
voltage

OSD BLK input

VthBLK

HBLK1

HBLK2

HBLK3

threshold
voltage

Retrace BLK
characteristics1

Retrace BLK
characteristics2

Retrace BLK
characteristics3

Retrace BLK

VthRET

input threshold
voltage

SOG input

SS-NV

maximum
noize voltage

SOG

SS-SV

minimum
input voltage

VSH

VSL

TDS-F

Sync output
hi level

Sync output
lo level

Sync output
delay time1

Test

point

2,6,11

(s)

OUT

OUT

OUT

OUT

OUT

OUT

RGB

in

b

SG1

b

SG1

b

SG1

b

SG1

b

SG1

b

SG1

OSD

BLK

OUT a a

OUT a a

OUT a

SG6bSG6

− −−−−−− −− − 0.8 1.0 1.2 −

OUT a

SG6bSG6

− −−−−−− −− − 0.8 1.0 1.2 −

OUT a

SG6bSG6

− −−−−−− −− − 0.8 1.0 1.2 −

OUT a

OUT

b

SG1

SG6

SG6

Variable

OUT a a a

OUT a a a

OUT a a a

OUT a a a

SonG

IN

aaaaa

Sync
OUT

SonG

IN

aaaaa

Sync
OUT

Sync

aaaaa

OUT
Sync

aaaaa

OUT
Sync

aaaaa

OUT

4,9,13

1

OSD

in

aa

aa

aa

aa

aa

aa

b

SG6

b

SG6

b

b

b

b

b

SG6

Variable

b

a

Input

CP in27ReT

SG5

SG5

SG5

Variable

SG5

Variable

SG5

SG5

SG5

SG5

SG5

SG5

SG5

SG5

SG5

SG5

SG5

SG5

SG5

MITSUBISHI ICs (Monitor)

M52743SP/M52744SP

I2C BUS CONTROLLED 3-CHANNEL VIDEO PREAMPLIFIER

CTL

voltage

19

b

b

b

b

b

b

b

b

b

b

b

b

b

b

b

b

b

SOG

BLK

aa

aa

7
in

30

Bri­ght

Vari
able

Vari
able

a a 2.0 5.0

a a 2.0 5.0 0.2 0.5 −µs

a a 2.0 5.0 -3.0 0 0.3 V

a a 2.0 5.0 -3.0 0 0.3 V

a a 2.0 5.0

a a 2.0 5.0

a a 2.0 5.0

a a 2.0 5.0

a a 2.0 5.0

a a 2.0 5.0

a a 2.0 5.0

b

a 2.0 5.0

SG7

b

a 2.0 5.0

SG7

b

a 2.0 5.0

SG7

b

a 2.0 5.0

SG7

Variable

b

SG4

Variable

b

SG4

Variable

b

SG4

b

SG4

b

SG4

2.0 5.0 0 0.01 0.02 VP-P

2.0 5.0 0.2 0.3 − VP-P

2.0 5.0 4.5 4.9 5.0 V

2.0 5.0 0 0.3 0.6 V

2.0 5.0 0 60 90 ns

15

ABL

5.0

5.0

00H

Main

Va
ria

ble

Va
ria

ble

cont

FFH
255

BUS CTL (H) Limits

01H

02H

03H

04H

05H

06H

07H

08H

Sub
cont

FFH
255

Sub

Sub

OSD

BLK

Adj

Adj

OUT

00H000H0FFH

08H

8

08H

8

0FH

15

08H

8

08H

8

08H

8

00H

0

0FH

15

06H

6

00H

0

08H

8

D/A

1

255

cont

cont

1

2

3

FFH

FFH

255

255

OUT

09H

D/A

D/A

D/A

OUT

OUT

2

3

4

FFH

FFH

FFH

255

255

255

0BH

INT

EXT

Min. Typ. Max.

00H

− 1.7 − ns

0

− 3.0 − ns

1.0 1.5 2.0 V

− 3.0 6.0 ns

− 3.0 6.0 ns

4.6 5.4 6.2 VP-P

2.8 3.3 3.8 VP-P

0 0.1 0.5 VP-P

2.2 2.7 3.2 V

2.2 2.7 3.2 V

1.7 2.0 2.3 V

0.7 1.0 1.3 V

0.1 0.4 0.7 V

1.0 1.5 2.0 V

Unit

5

ELECTRICAL CHARACTERISTICS (cont.)

VC1=20Log (dB)

VOUT

0.7

Input

4,9,13

1

OSD

CP in27ReT

in

Symbol Parameter

TDS-R

VOH

VOL

IAO

DNL

Sync output
delay time2

D/A H output
voltage

D/A L output
voltage

D/A output
current range

D/A
nonlinearity

Test

point

2,6,11

(s)

Sync
OUT

D/A

OUT

D/A

OUT

D/A

OUT

D/A

OUT

OSD

RGB

BLK

in

aaaaa

aaaaa

aaaaa

aaaaa

aaaaa

MITSUBISHI ICs (Monitor)

M52743SP/M52744SP

I2C BUS CONTROLLED 3-CHANNEL VIDEO PREAMPLIFIER

CTL

voltage

15

ABL

00H

Main

cont

FFH
255

BLK

7

SOG

in

b

SG4

a

a

a

a

30

Bri­ght

2.0 5.0 0 60 90 ns

2.0 5.0

2.0 5.0

2.0 5.0

2.0 5.0

19

BUS CTL (H) Limits

01H

02H

03H

04H

05H

06H

07H

08H

Sub
cont

FFH
255

Sub

Sub

OSD

BLK

Adj

Adj

OUT

00H000H0FFH

Vari

Vari

D/A

1

255

00H000H000H000H

abl

e

abl

e

cont

cont

1

2

3

FFH

FFH

255

255

OUT

Vari

Vari

09H

D/A

D/A

D/A

OUT

OUT

2

3

4

FFH

FFH

FFH

255

255

255

0

Vari

Vari

abl

abl

abl

e

e

e

Vari

Vari

abl

abl

abl

e

e

e

0BH

INT

EXT

Min. Typ. Max.

00H

4.5 5.0 5.5 VDC

0

0 0.5 1.0 VDC

-1.0 − 0.4 mA

-1.0 − 1.0 LSB

Unit

ELECTRICAL CHARACTERISTICS TEST METHOD

ICC1 Circuit current1

Measuring conditions are as listed in supplementary Table.
Mesured with a current meter at test point IA.

ICC2 Circuit current2

Measureing conditions are as listed in supplemtary Table.
Measured with a current meter at test point IB.

Vomax Output dynamic range

Decrease V30 gradually, and measure the voltage when the bottom
of waveform output is distorted. The voltage is called VCL.
Next, increase V30 gradually, and measure the voltage when the
top of waveform output is distorted. The voltage is called VOH.
Voltage Vomax is calculated by the equation below:
Vomax = VOH-VOL

(V)

VOH

5.0
Waveform output

VOL

0.0

Vimax Maximum input

Increase the input signal (SG2) amplitude gradually, starting from
700mV

P-P. Measure the amplitude of the input signal when the

output signal starts becoming distorted.

Gv Maximum gain

Input SG1, and read the amplitude output at OUT (29, 32, 35). The
amplitude is called VOUT (29, 32, 35). Maximum gain GV is
calculated by the equation below:

GV=20Log (dB)

VOUT

0.7

∆Gv Relative maximum gain

Relative maximum gain ∆G
∆G

V is calculated by the equation bellow:

V= VOUT (29)/VOUT (32),

VOUT (32)/VOUT (35),
VOUT (35)/VOUT (29)

C1 Main contrast control characteristics1

V

Measureing the amplitude output at OUT (29, 32, 35). The
measured value is called VOUT (29, 32, 35). Main contrast control
characterics V

C1 is calculated by the equation bellow:

∆VC1 Main contrast control relative characteristics1

Relative characteristics ∆VC1 is calculated by the equation bellow:
∆VC1=VOUT (29)/VOUT (32),

VOUT (32)/VOUT (35),
VOUT (35)/VOUT (29)

C2 Main contrast control characteristics2

V

Measuring condition and procedure are the same as described in
V

C1.

∆VC2 Main contrast control relative characteristics2

Measuring condition and procedure are the same as described in
∆VC1.

C3 Main contrast control characteristics3

V

Measuring condition and procedure are the same as described in
V

C1.

∆VC3 Main contrast control relative characteristics3

Measuring condition and procedure are the same as described in
∆VC1.

6

MITSUBISHI ICs (Monitor)

FC1=20Log (dB)

VOUT VP-P

Output amplitude when inputed SG3 (1MHz):4VP-P

M52743SP/M52744SP

I2C BUS CONTROLLED 3-CHANNEL VIDEO PREAMPLIFIER

VSC1 Sub contrast control characteristics1

Measur the amplitude output at OUT (29, 32, 35). The measured
value is called VOUT (29, 32, 35). Sub contrast control
characteristics V

SC1 Sub contrast control relative characteristics1

∆V

SC1 is calculated by the equation below:

SC1=20Log (dB)

V

VOUT

0.7

Relative characteristics ∆VSC1 is calculated by the equation below:
∆VSC1=VOUT (29)/VOUT (32),

VOUT (32)/VOUT (35),
VOUT (35)/VOUT (29).

SC2 Sub contrast control characteristics2

V

Measuring condition and procedure are the same as described in
V

SC1.

∆VSC2 Sub contrast control relative characteristics2

Measuring condition and procedure are the same as described in
∆VSC1.

SC3 Sub contrast control characteristics3

V

Measuring condition and procedure are the same as described in
V

SC1.

∆VSC3 Sub contrast control relative characteristics3

Measuring condition and procedure are the same as described in
∆VSC1.

VMSC Main/sub contrast control characteristics2

Measure the amplitude output at OUT (29, 32, 35). The measured
value is called VOUT (29, 32, 35). Main/Sub contrast control
characteristics VMSC1 is calculated by the equation below:

VMSC1=20Log (dB)

VOUT

0.7

ABL2 ABL control characteristics2

Measuring condition and procedure are the same as described in
ABL1.

∆ABL2 ABL control relative characteristics2

Measuring condition and procedure are the same as described in
∆ABL1.

B1 Brightness control characteristics1

V

Measure the DC voltage at OUT (29, 32, 35) with a voltmeter. The
measured value is called VOUT (29, 32, 35), and is ttreated as V

B1.

∆VB1 Brightness control relative characteristics1

Relative characteristics ∆VB1 is calculated by the difference in the
output between the channels.
∆VB1= VOUT (29)-VOUT (32),

VOUT (32)-VOUT (35),
VOUT (35)-VOUT (29)

B2 Brightness control characteristics2

V

Measuring condition and procedure are the same as described in
V

B1.

∆VB2 Brightness control relative characteristics2

Measuring condition and procedure are the same as described in
∆VB1.

B3 Brightness control characteristics3

V

Measuring condition and procedure are the same as described in
V

B1.

∆VB3 Brightness control relative characteristics3

Measuring condition and procedure are the same as described in

∆VB1.

∆VMSC Main/sub contrast control relative characteristics2

Relative characteristics ∆VMSC1 is calculated by the equation
below:
∆VMSC= VOUT (29)/VOUT (32),

VOUT (32)/VOUT (35),
VOUT (35)/VOUT (29)

ABL1 ABL control characteristics1

Measure the amplitude output at OUT (29, 32, 35). The measured
value is called VOUT (29, 32, 35), and is ttreated as ABL1.

∆ABL1 ABL control relative characteristics1

Relative characteristics ∆ABL1 is calculated by the equation below:
∆ABL1= VOUT (29)/VOUT (32),

VOUT (32)/VOUT (35),
VOUT (35)/VOUT (29)

7

C1 Frequency characteristics1 (f=50MHz)

F

First, SG3 to 1MHz is as input signal. Input a resister that is about
2kΩ to offer the voltage at input pins (2, 6, 11) in order that the bot­tom of input signal is 2.5V. Control the main contrast in order that
the amplitude of sine wave output is 4.0V

P-P. Control the brightness

in order that the bottom of sine wave output is 2.0VP-P. By the same
way, measure the output amplitude when SG3 to 50MHz is as input
signal. The measured value is called VOUT (29, 32, 35). Frequency
characteristics F

∆F

C1 Frequency relative characteristics1 (f=50MHz)

Relative characteristics ∆F

C1 (29, 32, 35) is calculated by the equation below:

C1 is calculated by the difference in the

output between the channels.

MITSUBISHI ICs (Monitor)

M52743SP/M52744SP

I2C BUS CONTROLLED 3-CHANNEL VIDEO PREAMPLIFIER

FC1' Frequency characteristics1 (f=150MHz)

Measuring condition and procedure are the same as described in
F

C1, expect SG3 to 150MHz.

C1' Frequency relative characteristics1 (f=150MHz)

∆F

Relative characteristics ∆F

C1' is calculated by the difference in the

output between the channels.

C2 Frequency characteristics2 (f=150MHz)

F

SG3 to 1MHz is as input signal. Control the main contrast in order
that the amplitude of sine wave output is 1.0V

P-P. By the same way,

measure the output amplitude when SG3 to 150MHz is as input
signal.
The measured value is called VOUT (29, 32, 35). Frequency
characteristics FC2 (29, 32, 35) is calculated by the equation below:

FC1=20Log (dB)

∆F

C2 Frequency relative characteristics2 (f=150MHz)

Output amplitude when inputed SG3 (1MHz):4VP-P

Relative characteristics ∆F

VOUT VP-P

C2 is calculated by the difference in the

output between the channels.

C.T.1 Crosstalk1 (f=50MHz)

Input SG3 (50MHz) to pin2 only, and then measure the waveform
amplitude output at OUT (29, 32, 35). The measured value is called
VOUT (29, 32, 35). Crosstalk C.T.1 is calculated by the equation
below:

C.T.1=20Log (dB)

VOUT (29, 32)

VOUT (35)

C.T.3 Crosstalk3 (f=50MHz)

Input SG3 (50MHz) to pin11 only, and then measure the waveform
amplitude output at OUT (29, 32, 35). The measured value is called
VOUT (29, 32, 35). Crosstalk C.T.2 is calculated by the equation
below:

C.T.3=20Log (dB)

VOUT (32, 35)

VOUT (29)

C.T.3' Crosstalk3 (f=150MHz)

Measuring condition and procedure are the same as described in
C.T.3, expect SG3 to 150MHz.

Tr Pulse characteristics1 (4V

P-P)

Control the main contrast (00H) in order that the amplitude of output
signal is 4.0V

P-P.

Control the brightness (V30) in order that the Black level of output
signal is 2.0V.
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 prove.
Pulse characteristics TR is calculated by the equations below:

TR= [(Tr2)2-(Tr1)2] (nsec)

Tf Pulse characteristics2 (4V

P-P)

Measure the time needed for the input pulseto fall from 90% to 10%
(Tf1) and for the output pulse to fall from 90% to 10% (Tf2) with an
active prove.
Pulse characteristics TF is calculated by the equations below:

TR= [(Tf2)2-(Tf1)2] (nsec)

C.T.1' Crosstalk1 (f=150MHz)

Measuring condition and procedure are the same as described in
C.T.1, expect SG3 to 150MHz.

C.T.2 Crosstalk2 (f=50MHz)

Input SG3 (50MHz) to pin6 only, and then measure the waveform
amplitude output at OUT (29, 32, 35). The measured value is called
VOUT (29, 32, 35). Crosstalk C.T.2 is calculated by the equation
below:

C.T.2=20Log (dB)

VOUT (29, 35)

VOUT (32)

C.T.2' Crosstalk2 (f=150MHz)

Measuring condition and procedure are the same as described in
C.T.2, expect SG3 to 150MHz.

100%

0%

Tf1 or Tf2Tr1 or Tr2

90%

10%

VthCP Clamp pulse threshold voltage

Turn down the SG5 input level gradually from 5.0V

P-P, monitoring

the waveform output.
Measure the top level of input pulse when the output pedestal
voltage turn decrease with unstable.

WCP Clamp pulse minimum width

Decrease the SG5 pulse width gradually from 0.5µs, monitoring the
output. Measure the SG5 pulse width (a point of 1.5V) when the
output pedestal voltage turn decrease with unstable.

8

MITSUBISHI ICs (Monitor)

M52743SP/M52744SP

I2C BUS CONTROLLED 3-CHANNEL VIDEO PREAMPLIFIER

PDCH Pedestal voltage temperature characteristics1

Measure the pedestal voltage at 25°C. The measured value is
called PDC1.
Measure the pedestal voltage at temperature of -20°C.
The measured value is called PDC2.
Pedestal voltage temperature characteristics 1 is calculated by the
equation below:
P

DCL Pedestal voltage temperature characteristics2

P

Measure the pedestal voltage at 25°C. The measured value is
called PDC1.
Measure the pedestal voltage at temperature of 75°C.
The measured value is called PDC3.
Pedestal voltage temperature characteristics 2 is calculated by the
equation below:
P

OTr OSD pulse characteristics1

Measure the time needed for the output pulse to rise from 10% to
90% (OTR) with an active prove.

OTf OSD pulse characteristics2

Measure the time needed for the output pulse to fall from 90% to
10% (OTF) with an active prove.

DCH=PDC1-PDC2

DCL=PDC1-PDC3

VthOSD OSD input threshold voltage

Reduce the SG6 input level gradually, monitoring output. Measure
the SG6 level when the output reaches 0V. The measured value is
called VthOSD.

VthBLK OSD BLK input threshold voltage

Confirm that output signal is being blanked by the SG6 at the time.
Monitoring to output signal, decreasing the level of SG6. Measure
the top level of SG6 when the blanking period is disappeared. The
measured value is called VthBLK.

HBLK1 Retrace BLK characteristics1

Measure the amplitude output is blanked by the SG7 at OUT (29,
32, 35). The measured value is called VOUT (29, 32, 35), and is
treated as HBLK1.

HBLK2 Retrace BLK characteristics2

Measure the amplitude output is blanked by the SG7 at OUT (29,
32, 35). The measured value is called VOUT (29, 32, 35), and is
treated as HBLK2.

HBLK3 Retrace BLK characteristics3

Measure the amplitude output is blanked by the SG7 at OUT (29,
32, 35). The measured value is called VOUT (29, 32, 35), and is
treated as HBLK3.

Oaj1 OSD adjust control characteristics1

Measure the amplitude output at OUT (29, 32, 35). The measured
value is called VOUT (29,32,35), and is treated as Oaj1.

∆Oaj1 OSD adjust control relative characteristics1

Relative characteristics ∆Oaj1 is calculated by the equation below:
∆Oaj1=VOUT (29)/VOUT (32),

VOUT (32)/VOUT (35),
VOUT (35)/VOUT (29)

Oaj2 OSD adjust control characteristics2

Measuring condition and procedure are the same as described in
Oaj1.

∆Oaj2 OSD adjust control relative characteristics2

Measuring condition and procedure are the same as described in
∆Oaj1.

Oaj3 OSD adjust control characteristics3

Measuring condition and procedure are the same as described in
Oaj1.

∆Oaj3 OSD adjust control relative characteristics3

Measuring condition and procedure are the same as described in
∆Oaj1.

VthRET Retrace BLK input threshold voltage

Confirm that output signal is being blanked by the SG7 at the time.
Monitoring to output signal, decreasing the level of SG7. Measure
the top level of SG7 when the blanking period is disappeared. The
measured value is called VthRET.

SS-NV SOG input maximum noize voltage

The sync's amplitude of SG4 be changed all white into all black,
increase from 0VP-P to 0.02VP-P. No pulse output permitted.

SS-SV SOG minimum input voltage

The sync's amplitude of SG4 be changed all white or all black,
decrease from 0.3VP-P to 0.2VP-P. Confirm no malfunction produced
by noise.

VSH Sync output hi level

Measure the high voltage at SyncOUT. The measured value is
treated as VSH.

VSL Sync output lo level

Measure the low voltage at SyncOUT. The measured value is
treated as VSL.

9

MITSUBISHI ICs (Monitor)

M52743SP/M52744SP

I2C BUS CONTROLLED 3-CHANNEL VIDEO PREAMPLIFIER

TDS-F Sync output delay time1

SyncOUT becomes High with sync 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 prove. The
measured value is treated as TDS-F, less than 90nsec.

TDS-R Sync output delay time2

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 prove. The
measured value is treated as TDS-R, less than 90nsec.

SG4

SyncOUT

Pedestal voltage

(50%)sync (50%)

TDS-RTDS-F

BUS CONTROL TABLE

(1) Slave address

D7 D6 D5 D4 D3 D2 D1 R/W

10001000=88H

VOH D/A H output voltage

Measure the DC voltage at D/AOUT. The measured value is
ttreated as VOH.

VOL D/A L output voltage

Measure the DC voltage at D/AOUT. The measured value is
ttreated as VOL.

IAO D/A output current range

Electric current flow from the output of D/AOUT must be less than

1.0mA.
Electric current flow in the output of D/AOUT must be less than

0.4mA.

DNL D/A nonlinearity

The difference of differential non-linearity of D/AOUT must be less
than ±1.0LSB.

(2) Each function’s sub address

Function bit

Main contrast 8 00H

Sub contrast R 8 01H

Sub contrast G 8 02H

Sub contrast B 8 03H

OSD level 4 04H

RE-BLK adjust 4 05H

D/A OUT1 8 06H

D/A OUT2 8 07H

D/A OUT3 8 08H

D/A OUT4 8 09H

Pedestal clamp INT/EXT SW 1 0BH

sub

add.

Data byte (up:bit information down: preset)

D7 D6 D5 D4 D3 D2 D1 D0

A07 A06 A05 A04 A03 A02 A01 A00

01000000

A17 A16 A15 A14 A13 A12 A11 A10

10000000

A27 A26 A25 A24 A23 A22 A21 A20

10000000

A37 A36 A35 A34 A33 A32 A31 A30

10000000

−−−−A43 A42 A41 A40
00001000

−−−−A53 A52 A51 A50
00001000

A67 A66 A65 A64 A63 A62 A61 A60

10000000

A77 A76 A75 A74 A73 A72 A71 A70

10000000

A87 A86 A85 A84 A83 A82 A81 A80

10000000

A97 A96 A95 A94 A93 A92 A91 A90

10000000

−−−−−−−AB0
00000000

Notes) pedestal level INT/EXT SW
0→INT 1→EXT

10

MITSUBISHI ICs (Monitor)

M52743SP/M52744SP

I2C BUS CONTROLLED 3-CHANNEL VIDEO PREAMPLIFIER

I2C BUS CONTROL SECTION SDA, SCL CHARACTERISTICS

Symbol Parameter Min. Max. Unit
VIL min. input LOW voltage -0.5 1.5 V
VIH max. input HIGH voltage 3.0 5.5 V
fSCL SCL clock frequency 0 100 kHz
tBUF Time the bus must be free before a new transmission can start 4.7 −µs
tHD:STA Hold time start condition. After this period the first clock pulse is generated 4.0 −µs
tLOW The LOW period of the clock 4.7 −µs

HIGH The HIGH period of the clock 4.0 −µs

t
tSU:STA Set up time for start condition (Only relevant for a repeated start condition) 4.7 −µs
tHD:DAT Hold time DATA 0 −µs
tSU:DAT Set-up time DATA 250 − ns
tr Rise time of both SDA and SCL lines − 1000 ns
tf Fall time of both SDA and SCL lines − 300 ns
tSU:STO Set-up time for stop condition 4.0 −µs

TIMING DIAGRAM

VIH

SDA

VIL

IH

V

SCL

VIL

SSPS

tr, tf

tLOW tHIGH

tBUF

tHD:DATtSU:DATtHD:STA

tSU:STA

tSU:STO

11

I2C BUS CONTROLLED 3-CHANNEL VIDEO PREAMPLIFIER

INPUT SIGNAL

SG No. Signals

Pulse with amplitude of 0.7VP-P (f=30kHz). Video width of 25µs. (75%)

33µs

SG1

Video signal

(all white)

SG2

Video signal

(step wave)

8µs

MITSUBISHI ICs (Monitor)

M52743SP/M52744SP

P-P

0.7V

0.7VP-P
(Amplitude is partially variable.)

SG3

Sine wave

(for freq. char.)

SG4

Video signal

(all white,
all black)

SG5

Clamp

pulse

SG6

OSD pulse

Video width of 25µs. (75%)

3µs

Pulse width and amplitude are variable.

0.5µs

5V

TTL

Sine wave amplitude of 0.7VP-P.
f=1MHz, 50MHz, 150MHz (variable)

0.3VP-P

5V

TTL

all white or all black
variable.

Sync’s amplitude
is variable.

0.7VP-P

Amplitude is partially variable.

SG7

BLK pulse

5µs

5µs

5V

TTL

Amplitude is partially variable.

∗) f=30kHz

12

TEST CIRCUIT

OUT (35)

100

100µH

MITSUBISHI ICs (Monitor)

M52743SP/M52744SP

I2C BUS CONTROLLED 3-CHANNEL VIDEO PREAMPLIFIER

D/A

D/A

D/A

OUT (32)

V30

0 to 5V

1k

1k

OUT (29)

SG7

a

1k

b

SW27

OUT1

OUT2

OUT3

D/A

OUT4

SCLSDA

b

SW19

SG5

C/P IN

a

35

36

34

out f/b brt dac dac sda12V gndf/b f/boutout blk dac gnddac c/pscl

31

3233

29

30 2627 252324

28

22

M52743SP/M52744SP

R G SonG B 12V NC

blk osd12V osd12Vgnd gnd gnd ablosd sync5V

13245 98101211 13 146 7 15 16 17 18

100k

SONG

IN (6)

IN

0.01µ

3.3µ

1µ

SW7

SW6

b

a

a

b

b

SG4

SW9

a

b

IN (11)

0.01µ

3.3µ

V15

SW11

a

∗ Condenser : 0.01µF (unless otherwise specified.)

SW13

a

b

: MEASURE POINT

b

0 to 5V

47µ

SW1

a

A

IA

12V

IN (2)

3.3µ

SW2

b

SG6

0.01µ

SW4

SG1
SG2
SG3

a

a

b

202119

47µ

A

5V

SYNC

OUT

1k

B

I

TYPICAL CHARACTERISTICS

THERMAL DERATING

2800
2403

2400

2000

1600

1200

800

400

POWER DISSIPATION Pd (mW)

0

-20 0 25 50 75 100 125 150

AMBIENT TEMPERATURE Ta (°C)

13

1442

Units Resistance : Ω

Capacitance : F

MAIN CONTRAST CONTROL CHARACTERISTICS

6

5

4

3

2

1

OUTPUT AMPLITUDE (VP-P)

0

00H

Sub contrast: Max

FFH

MAIN CONTRAST CONTROL DATA

MITSUBISHI ICs (Monitor)

M52743SP/M52744SP

I2C BUS CONTROLLED 3-CHANNEL VIDEO PREAMPLIFIER

SUB CONTRAST CONTROL CHARACTERISTICS

6

5

4

3

2

1

OUTPUT AMPLITUDE (VP-P)

0

00H

Main contrast: Max

FFH

SUB CONTRAST CONTROL DATA

ABL CHARACTERISTICS

6

5

4

BRIGHTNESS CONTROL CHARACTERISTICS

6

5

4

3

2

1

OUTPUT DC VOLTAGE (VDC)

0

0

BRIGHTNESS CONTROL VOLTAGE (VDC)

OSD ADJUST CONTROL CHARACTERISTICS

6

5

4

5

OUTPUT AMPLITUDE (VP-P)

SYNC ON GREEN INPUT MIN. PULSE WIDTH

SYNC DUTY (%)

7

100k

1µ

IN

3

2

1

0

0

Main contrast: Max

Sub contrast : Max

ABL CONTROL VOLTAGE (VDC)

12

10

8

6

4

2

0

0

(Video duty=75%)

Sync separate
normal operating range

INPUT SYNC AMPLITUDE (VP-P)

5

0.5

3

2

1

OUTPUT AMPLITUDE (VP-P)

0

0H

FH

OSD ADJUST CONTROL DATA

14

APPLICATION EXAMPLE

MITSUBISHI ICs (Monitor)

M52743SP/M52744SP

I2C BUS CONTROLLED 3-CHANNEL VIDEO PREAMPLIFIER

110V

100µH

100

CRT

Cut Off Adj

DAC OUT×4

TTL

5V

BLK IN

1k

35 313336

1k 1k

0 to 5V

0.01µ

2932 28 27 2324 22 202126 2534 30

0.01µ 0.01µ

0.01µ

0.01µ

(for retrace)
SDA

SCL

Clamp pulse
IN

19

12V

5V

5VTTL

3.3µ

INPUT
(R)

0.01µ

M52743SP/M52744SP

0.01µ

47µ

3.3µ

75

5VTTL

INPUT
(G)

∗ Circuit example of pin6 and pin7 same signal input

1µ

0.01µ

75

100k

∗

INPUT

S

ONG

0.01µ

47µ

5VTTL

3.3µ

INPUT

(B)

0.01µ

75

0.01µ

47µ

•FEED BACK IS
INTERNAL FEED BACK

0 to 5V

5VTTL

0.01µ

NC

1k

47µ

Units Resistance : Ω

1885 9 10 1413 15 171611 12372641

ABL IN
Sync

Sep
OUT

OSD IN (B)
OSD IN (G)
OSD IN (R)
BLK IN

(for OSD)

Capacitance : F

15

MITSUBISHI ICs (Monitor)

M52743SP/M52744SP

I2C BUS CONTROLLED 3-CHANNEL VIDEO PREAMPLIFIER

DESCRIPTION OF PIN

Pin No. Name DC voltage (V ) Peripheral circuit of pins Description of function

1 OSD BLK IN −

2
6

11

3
8

12

INPUT (R)
INPUT (G)
INPUT (R)

CC1 (R)

V
VCC1 (G)
VCC1 (B)

R
G

2.5

1

2

B

0.8mA

2k

0.3mA

12 −

CP

⋅Input pulses

3.7 to 5V

1.7V
maximum

2.7V

2k

⋅Connected to GND if not
used.

⋅Clamped to about 2.5V
due to clamp pulses
from pin 19.
⋅Input at low impedance.

2.5V

⋅Apply equivalent
voltage to 3 channels.

13

10
14
22
33

⋅Input pulses

4
9

OSD IN (R)
OSD IN (G)

−

OSD IN (B)

1k

4

3.7 to 5V

1.7V
maximum

⋅Connected to GND if not

0.5mA

5

GND 1 (R)

2.7V

used.

GND 1 (G)
GND 1 (B)

GND −
GND (5V)
GND 2

⋅SYNC ON GREEN
input pin for sync
separation.
Sync is negative.

7

INPUT
(S on G)

When open≈2.5V

1k

500

input signal at Pin7,
compare with the
reference voltage of
internal circuit in order to

3.2V

7

separate sync signal.
⋅When not used, set to
OPEN.

16

MITSUBISHI ICs (Monitor)

M52743SP/M52744SP

I2C BUS CONTROLLED 3-CHANNEL VIDEO PREAMPLIFIER

DESCRIPTION OF PIN (cont.)

Pin No. Name DC voltage (V ) Peripheral circuit of pins Description of function

2.5V

20k

15 ABL IN When open 2.5V

1.2k

0.5mA

1.2k

30k

15

16 NC −−
17 V

18

CC (5V) 5 −

S on G Sep
OUT

−

18

⋅ABL (Automatic Beam
Limitter) input pin.
Recommended voltage
range is 0 to 5V.
When ABL function is not
used, set to 5V.

⋅Sync signal output pin,
Being of open collector
output type.

19

Clamp Pulse
IN

20 SCL −

21 SDA −

41k

−

19

2.2V

50k

0.15mA

⋅Input pulses

2.5 to 5V

0.5V
maximum

⋅Input at low impedance.

⋅SCL of I

2

C BUS

(Serial clock line)

20

2k

3V

50k

VTH=2.3V

⋅SDA of I

2

C BUS

(Serial data line)

21

2k

3V

VTH=2.3V

17

MITSUBISHI ICs (Monitor)

M52743SP/M52744SP

I2C BUS CONTROLLED 3-CHANNEL VIDEO PREAMPLIFIER

DESCRIPTION OF PIN (cont.)

Pin No. Name DC voltage (V ) Peripheral circuit of pins Description of function

23
24
25
26

27

28
31
34

D/A OUT −

Retrace BLK
IN

EXT Feed
Back (B)

EXT Feed
Back (G)

Variable −

EXT Feed
Back (R)

⋅D/A output pin.
Output voltage range is

23

50k

−

27

R
G
B

2.25V

0 to 5V, Max output
current is 0.4mA.

⋅Input pulses

2.5 to 5V

0.5V
maximum

⋅Connected to GND if not
used.

35k

29
32
35

36 V

30

OUTPUT (B)
OUTPUT (G)
OUTPUT (R)

CC2

Main
Brightness

Variable

12

Impressed

−

35k

28

⋅A resistor is needed on

36

50

the GND side.
Set discretionally to
maximum 15mA,
depending on the
required driving capacity .

50

29

⋅Used to supply power to
output emitter follower
only.

⋅It is recommended that
the IC be used between
pedestal voltage 2V and
3V.

30

18

I2C BUS CONTROLLED 3-CHANNEL VIDEO PREAMPLIFIER

APPLICATION METHOD FOR M52743SP

CLAMP PULSE INPUT

Clamp pulse width is recommended
above 15kHz, 1.0µsec
above 30kHz, 0.5µsec
above 64kHz, 0.3µsec.
The clamp pulse circuit in ordinary set is a long round about way,
and beside high voltage, sometimes connected to external terminal,
it is very easy affected by large surge.
Therefore, the Fig. shown right is recommended.

19

MITSUBISHI ICs (Monitor)

M52743SP/M52744SP

EXT-FEED BACK

In case of application circuit example of lower figure, Set up R1, R2
which seems that the black level of the signal feedbacked from
Power AMP is 1V, when the bottom of output signal is 1V.

MAIN BRIGHTNESS
DC:1 to 5V

Pre Amp
INPUT R

M52743SP/M52744SP

R OUT PUT
Black level 1 to 5V

R Feed back
Black level 1 to 5V

EXT-FEED BACK APPLICATION CIRCUIT

NOTICE OF APPLICATION

⋅ Make the nearest distance between output pin and pull down

resister.

⋅ Recommended pedestal voltage of IC output signal is 2V.

Power Amp

Power Amp OUT

R1

R2

TAILING

There is the case that a screen tailing like a figure by characteristic
of the next stage amplifier connected to M52744SP.
That case recommends use of M52743SP.

19

Window

signal

SCREEN

Shadow
tailing