MITSUBISHI M52756SP

MITSUBISHI ICs (Monitor)
M52756SP
WIDE BAND ANALOG SWITCH
DESCRIPTION
PIN CONFIGURATION (TOP VIEW)
The M52756SP is a semiconductor integrated circuit for the
RGBHV interface. The device features switching signals input
from two types of image sources and outputting the signals to
the CRT display, etc. Synchronous signals, meeting a
frequency band of 10kHz to 200kHz, are output at TTL. The
frequency band of video signals is 250MHz, acquiring highresolution images, and are optimum as an interface IC with
high-resolution CRT display and various new media.
DESCRIPTION
• Frequency band: RGB ............................................250MHz
HV...................................10kHz to 200kHz
• Input level: RGB................................................0.7Vp-p(typ.)
HV TTL input....................3.5Vo-p(both channel)
• RGBOUT can drive connected load of 75Ω.
• Only the G channel is provided with sync-on video output.
• The TTL format is adopted for HV output.
• It is possible to save the consumption current by stopping
current supply to Pin 2, 4, 24, 27, 30.
• Sync Separation circuit
INPUT1 (R) 1
VCC1(R)(5V) 2
INPUT1 (B) 3
VCC1(B)(5V) 4
INPUT1 (G) 5
INPUT1 (H) 6
INPUT1 (V) 7
INPUT2 (R) 8
VCC(G)(5V) 9
INPUT2 (B) 10
VCC(H,V,
Buffer,SW,sync Sepa)(5V) 11
INPUT2 (G) 12
INPUT2 (H) 13
INPUT2 (V) 14
SWITCH 15
30
29
28
27
26
25
24
23
22
21
20
19
18
17
VCC(R)(12V)
OUTPUT (R)
GND(R)
VCC(B)(12V)
OUTPUT (B)
GND(B)
VCC(G)(12V)
OUTPUT (G)
GND(G)
G Buffer OUT
Sync Sepa IN
Sync Sepa OUT
OUTPUT (H)
OUTPUT (V)
16 GND(H,V,Buffer,
SW,sync Sepa)
Outline 30P4B
APPLICATION
Display monitor
RECOMMENDED OPERATING CONDITION
Supply voltage range.....................4.75 to 5.25V, 11.5 to 12.5V
Rated supply voltage................................................5.0V, 12.0V
30 pin plastic SDIP
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MITSUBISHI ICs (Monitor)
M52756SP
WIDE BAND ANALOG SWITCH
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M52756SP
WIDE BAND ANALOG SWITCH
Absolute Maximum Rating
Parameter
(Ambient temperature: 25˚C)
Symbol
Rating
Unit
Supply voltage
Vcc
6.0,13.0
V
Power dissipation
Pd
1736
mW
Ambient temperature
Topr
-20~+75
˚C
Storage temperature
Recommended supply
voltage
Recommended sopply
voltage range
Tstg
-40~+150
˚C
Vopr'
4.75~5.25,11.5~12.5
V
Electrostatic discharge
Surge
+150
V
Vopr
V
5.0,12.0
Thermal Derating Curve
2000
1736
1000
-20
0
25
50
75
100
125
Ambient temperature Ta (˚C)
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150
MITSUBISHI ICs (Monitor)
M52756SP
WIDE BAND ANALOG SWITCH
Pin Description
Pin
No.
Description
1
Input 1 (R)
3
Input 1 (B)
5
Input 1 (G)
2
4
9
11
Vcc(R)
Vcc(B)
Vcc(G)
Vcc(H,V,Buffer,
DC
Voltage[V]
Peripheral circuits at pins
Input signal with low
impedance.
5.0V
2.25
Notes
3.0V
750µ
5.0
SW,SyncSep)
6
Input 1 (H)
7
Input 1 (V)
5.0V
4.5K
20K
Input pulse between
2V and 5V.
2~5V
V
0~0.8V
10K
8
Input 2 (R)
10
Input 2 (B)
12
Input 2 (G)
13
Input 2 (H)
14
Input 2 (V)
Input signal with low
impedance.
5.0V
2.25
3.0V
750µ
5.0V
4.5K
Input pulse between
2V and 5V.
20K
2~5V
V
0~0.8V
10K
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MITSUBISHI ICs (Monitor)
M52756SP
WIDE BAND ANALOG SWITCH
Pin Description
Pin
No.
Description
15
Switch
DC
Voltage[V]
2.4
Peripheral circuits at pins
Notes
Switch by OPEN and
GND.
5.0V
10K
13K
7.3K
12K
V
2.25V
16 GND(H,V,Buffer,
SW,SyncSep)
22 GND(G)
25 GND(B)
28 GND(R)
17
Output(V)
18
Output(H)
GND
Output impedance is
built in.
5.0V
1K
19 Sync Sepa
OUT
Connect resistance more
5.0V
than 1KΩ is necessary
790
during power supply and
terminal that open
collector output type.
When not used, ground
the pin to GND.
20 Sync Sepa
IN
Input signal with low
impedance.
When not used, set to
OPEN
5.0V
2.3
500
3.0V
21 OUTPUT
(G Buffer)
1K
5.0V
0.75
1K
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Output impedance is
built in.
75
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MITSUBISHI ICs (Monitor)
M52756SP
WIDE BAND ANALOG SWITCH
Pin Description
Pin
No.
Description
DC
Voltage[V]
Peripheral circuits at pins
22 OUTPUT(G)
26 OUTPUT(B)
12.0V
50
1.8
Notes
This output pin can
drive connected load
of 75Ω.
75
29 OUTPUT(R)
24 Vcc(G)
27 Vcc(B)
30 Vcc(R)
1.6m
8.0m
12.0
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MITSUBISHI ICs (Monitor)
M52756SP
WIDE BAND ANALOG SWITCH
Attached Fig.3
Measuring Circuit Diagram
B
(Vcc12V)
A
(Vcc5V)
SW A
b
SW B
a
b
A
SW B
a
A
SW B
b
a
b
a
A
A
47µ
47µ
47µ
47µ
0.01µ
0.01µ
0.01µ
0.01µ
100µ
b
47µ
75Ω
a SW 1
0.01µ
0.01µ
0.01µ
75Ω
b
a SW 2
100µ
b
75Ω
TP29
75Ω
TP26
75Ω
TP23
75Ω
a SW 3
0.01µ
0.01µ
47µ
b
a SW 4
100µ
b
0.01µ
75Ω
75Ω
a SW 5
0.01µ
b
a SW 6
47µ
b
a SW 7
100µ
b
0.01µ
75Ω
75Ω
a SW 8
0.01µ
0.01µ
b
a SW 9
100µ
b
75Ω
a SW 10
0.01µ
0.01µ
1µ
b
a
TP21
b
a SW 11
100µ
b
SW 20
100KΩ
75Ω
a SW 12
0.01µ
TP19
1KΩ
b
a SW 13
TP18
b
a SW 14
TP15
TP17
b
a SW 15
SG
RGB
SG
HV
SW GND :INPUT1
SW OPEN :INPUT2
SG
SS
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M52756SP
WIDE BAND ANALOG SWITCH
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M52756SP
WIDE BAND ANALOG SWITCH
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M52756SP
WIDE BAND ANALOG SWITCH
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M52756SP
WIDE BAND ANALOG SWITCH
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M52756SP
WIDE BAND ANALOG SWITCH
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M52756SP
WIDE BAND ANALOG SWITCH
note ) It omits the SW.No accorded with signal input pin because it is already written in Table 1.
SW A is in side a if there is not defined specially.
note1) The condition is shown as Table 1. Set SW15 to GND(or OPEN) and SW A to side b, measure the
current by current meter A(or B). The current is as Icc1(Icc2,Icc3).
note2) Set SW15 to GND (or OPEN), measure the DC voltage of T.P.29(T.P.26,T.P.23) when there is no
signal input.The DC voltage is as VDC1(or VDC2).
note3) Measure the DC voltage of T.P.21 same as note2, the DC voltage is as VDC3(or VDC4).
note4) Set SW15 to GND, SG1 as the input signal of Pin 1.Rising up the amplitude of SG1 slowly, read the
amplitude of input signal when the output waveform is distorted. The amplitude is as Vimax1. And
measure Vimax1 when SG1 as the input signal of Pin 3,Pin 5 in same way.
Next, set SW 15 to OPEN, measure Vimax2 when SG1 as the input signal of Pin8, 10, 12.
note5) 1. The condition is shown as Table 1.
2. Set SW15 to GND, SG2 as the input signal of Pin 1. At this time, read the amplitude output from
T.P 29. The amplitude is as VOR1.
3. Voltage gain Gv1 is
GV1= 20 LOG
VOR1 [Vp-p]
[dB]
0.7 [Vp-p]
4. The method as same as 2 and 3, measure the voltage gain Gv1 when SG2 as the input signal of
Pin 3, 5.
5. The difference of each channel relative voltage gain is as ∆Gv1.
∆Gv1=Gv1R-Gv1B,Gv1B-Gv1G,Gv1G-Gv1R
6. Set SW15 to OPEN, measure Gv2, ∆Gv2 in the same way.
note5') Voltage gain ∆Gv' is
∆Gv'=Gv1R-Gv2R,Gv1G-Gv2G,Gv1B-Gv2B
note6) 1. The condition is shown as table 1. This test is by active probe.
2. Measure the amplitude output from T.P.21.
3. Measure the GV3,GV4 by the same way as note5.
note7) 1. The condition is shown as table 1. This test is by active probe.
2. Set SW15 to GND, SG2 as the input signal of Pin 1. Measure the amplitude output from T.P.29.
The amplitude is as VOR1.By the same way, measure the output when SG4 is as input signal of
Pin 1, the output is as VOR2.
3. The frequency characteristic Fc1 is
FC1 = 20 LOG
VOR2 [Vp-p]
VOR1 [Vp-p]
[dB]
4. The method as same as 2 and 3, measure the frequency Fc1 when input signal to Pin 3, 5.
5. The difference between of each channel frequency characteristic is as ∆Fc1.
6. Set SW15 to OPEN, measure Fc2,∆Fc2.
note8) By the same way as Note7 measure the Fc3, Fc4 when SG5 of input signal.
note9) 1. The condition is shown as Table1. This test is by active prove.
2. Set SW15 to GND, SG3 as the input signal of Pin 1. Measure the amplitude output from T.P.29.
The amplitude is as VOR3.
3. Set SW15 to OPEN, measure the amplitude output from T.P.29. The amplitude is as VOR3'.
4. The crosstalk between two inputs C.T.I.1 is
C.T.I.1= 20 LOG
VOR3' [Vp-p]
[dB]
VOR3 [Vp-p]
5. By the same way, measure the crosstalk between two inputs when SG3 as the input
signal of Pin3, Pin 5.
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MITSUBISHI ICs (Monitor)
M52756SP
WIDE BAND ANALOG SWITCH
6. Next, set SW15 to OPEN, SG3 as the input signal of Pin 8, measure the amplitude output
from T.P.29. The amplitude is as VOR4.
7. Set SW15 to GND, measure the amplitude output from T.P.29. The amplitude is as VOR4'.
8. The crosstalk between two inputs C.T.I.2 is
C.T.I.2= 20 LOG
VOR4'[Vp-p]
[dB]
VOR4[Vp-p]
9. By the same way, measure the crosstalk between channels when SG3 as the input signal
of Pin 10,12.
note10) Set SG4 as the input signal, and then the same method as note9, measure C.T.I.3, C.T.I.4.
note11) 1. The condition is as Table 1. This test is by active prove.
2. Set SW15 to GND, SG3 as the input signal of Pin 1. Measure the amplitude output from
T.P.29. The amplitude is as VOR5.
3. Next, measure T.P.26, T.P.23 in the same state, and the amplitude is as VOG 5, VOB 5.
4. The crosstalk between channels C.T.C.1 is
C.T.C1= 20 LOG
VOG5 or VOB5 [dB]
VOR5
5. Measure the crosstalk between channels when SG3 is as the input signal of Pin 3, Pin 5 .
6. Next, set SW15 to OPEN, SG3 as the input signal of Pin8, measure the amplitude output
from T.P.29. The amplitude is as VOR6.
7.Next, measure the amplitude output from T.P.26, T.P.23 in the same state. The amplitude is
as
VOG6, VOB6.
8. The crosstalk between channels C.T.C.2 is C.T.C2= 20 LOG
VOG6 or VOB6 [dB]
VOR6
9. By the same way, measure the crosstalk between channels when input signal to Pin10, 12.
note12) Set SG4 as the input signal, and the same method as note11, measure C.T.C.3, C.T.C.4.
note13) 1. The condition is as Table 1. Set SW15 to GND (or OPEN).
2. The rising of 10 % ~ 90 % for input pulse is Tri, the falling
of 10 % ~ 90 % for input pulse is Tfi.
3. Next, the rising of 10 % ~ 90 % for output pulse is Tro, the
falling of 10 % ~ 90 % for output pulse is Tfo.
4. The pulse characteristic Tr1, Tf1 ( Tr2, Tf2 ) is
Tr1(Tr2) =
(Tro)2 -
2
(Tri)
(nsec)
Tf1(Tf2) =
100%
90%
0%
10%
Tr
(Tfo) 2 -
Tf
(Tfi) 2 (nsec)
note14) The condition is as Table 1. Set SW15 to GND (OPEN), input 5V at input terminal. Measure the
output voltage, the voltage is as VOH1 (VOH2).
note15) The condition is as Table 1. Set SW15 to GND (OPEN), input 0V at input terminal. Measure the
output voltage, the voltage is as VOL1 (VOL2).
note16) The condition is as table 1. Set SW15 to GND (OPEN), increasing gradually the voltage of input
terminal from 0V, measure the voltage of input terminal when output terminal is 4.5V. The input
voltage is as Vith1(Vith 2).
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M52756SP
WIDE BAND ANALOG SWITCH
note17, note18) The condition is as table 1. Set SW15 to GND (OPEN), SG7 is as the input signal of
input terminal, measure the waveform of output. Rising delay time is as Trd1 (Trd2).
Falling delay time is as Tfd1(Tfd2). Reference to the Fig. as shown below.
50%
SG7
Tfd
Trd
50%
Output waveform
note19) 1. The condition is as table 1. SG1 is as the input signal of Pin1, Pin3, Pin5, and SG7 is as the
input signal of Pin6, Pin7. There is no input at another pins.
2. Input 0V at Pin15, confirm that there are signals output from T.P.29, T.P.26, T.P.23, T.P.21,
T.P.18,T.P.17.
3. Increasing gradually the voltage of terminal Pin15. Read the voltage when there is no signal
output from the terminals listed as above. The voltage is as Vsth1.
4. SG1 as the input signal of Pin8, Pin10, Pin12, and SG7 as the input signal of Pin13, Pin14.
There is no input at another pins.
5. Inputs 5V at Pin15, confirm that there is no signal output from T.P29, T.P.26, T.P.23, T.P.21,
T.P.18,T.P.17.
6. Decreasing gradually the voltage of terminal Pin 15. Read the voltage when there are signals
output from the terminals listed as above. The voltage is as Vsth2.
note20) The condition is as table 1. SG8 of luminance 0% is the input signal of Pin20. Increase sync level
from 0Vp-p to 0.02Vp-p. Confirm outputting no pluse.
note21) The condition is as table 1. SG8 of luminance 100%(or 0%) is the input signal of Pin20. Decrease
sync level from 0.3Vp-p to 0.2Vp-p. Confirm no malfunction produced by noise.
note22) The condition is as table 1. SG8 of luminance 100%(or 0%) is the input signal of Pin20. Measure
the high(low) at SyncOUT. The measured value is treated as VSH(VSL).
note23) The condition is as table 1. SG8 of luminance 100%(or 0%) is the input signal of Pin20. SyncOUT
becomes High with sync part of SG8. Measure the time needed for the front(rear) edge of SG8
sync to fall(rise) from 50% and for SyncOUT to rise(fall) from 50% with an active prove. The
measured value is treated as Tdsf(Tdsr).
SG8
sync(50%)
Tdsf
(50%)
Tdsr
Pedestal voltage
(50%)
SyncOUT
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M52756SP
WIDE BAND ANALOG SWITCH
Symbol
Input Signal
Sine wave ( f = 60 kHz, 0.7Vp-p, amplitude variable )
SG1
0.7Vp-p(amplitude variable)
SG2
Sine wave ( f = 1 MHz, amplitude 0.7Vp-p )
SG3
Sine wave ( f = 10 MHz, amplitude 0.7Vp-p )
SG4
Sine wave ( f = 100 MHz, amplitude 0.7Vp-p )
SG5
Sine wave ( f = 250 MHz, amplitude 0.7Vp-p )
Pulse with amplitude 0.7Vp-p ( f = 60 kHz, duty 80% )
SG6
0.7Vp-p
Square wave ( Amplitude 5.0 Vo-p TTL, f = 60 KHz, duty 50% )
5V
SG7
0V
Video signal (luminance 100%,0%) 60KHz
Video width of 12.5µsec(75%)
Luminance 100% or 0% variable
SG8
0.7Vp-p
0.3Vp-p
1.5µsec
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Sync level is
variable
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MITSUBISHI ICs (Monitor)
M52756SP
WIDE BAND ANALOG SWITCH
Note how to use this IC
1. R, G, B input signal is 0.7Vp-p of standard video signal.
5V
5V
2. H, V input is 2.0V(minimum) TTL type.
1KΩ
R
3. Input signal with sufficient low impedance to input terminal.
4. The terminal of H, V output pin are shown as Fig.4. It is possible to
reduce rise time by insert the resistor between Vcc line and H, V output
Pin, but set the value of resistor in order that the current is under 7.5 mA.
Setting the value of R is more than 2kΩ as shown in Fig.4 .
5. Switch (Pin 15) can be changed when this terminal is GND or OPEN
When GND : Signal output from input 1
When OPEN : Signal output from input 2
When the switch is being used as Fig.5
0 ~ 0.5V
: Signal output from input 1
2~5 V
: Signal output from input 2
It is not allowable to set voltage higher than Vcc.
I<7.5mA
Fig.4
15
Fig.5
Notice of making printed circuit board.
Please notice following as shown below. It will maybe cause something oscillation because of the
P.C.B. layout of the wide band analog switch.
• The distance between resistor and output pin is as short as possible.
• The capacitance of output terminal as small as possible.
• Set the capacitance between Vcc and GND near the pins if possible.
• Using stable power-source.
The separated 12V-power-source (if possible the separated 5V-power-source will be better).
• Assign an area as large as possible for grounding.
• Pay attention to leak of signaling from the output.
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M52756SP
WIDE BAND ANALOG SWITCH
Attached Fig.6 Application Example
SWITCH
GND
OUTPUT(V)
INPUT2(V)
OUTPUT(H)
INPUT2(H)
1kΩ
5V
100µ
INPUT2(G)
Sync Sepa OUT
0.01µ
100kΩ
Sync Sepa IN
75Ω
47µ
VCC(5V)
1µ
0.01µ
100µ
INPUT2(B)
OUTPUT(G Buffer)
0.01µ
75Ω
47µ
GND(G)
VCC(G)(5V)
0.01µ
OUTPUT(G)
100µ
75Ω
INPUT2(R)
75Ω
0.01µ
47µ
75Ω
VCC(G)(12V)
INPUT1(V)
0.01µ
GND(B)
OUTPUT(B)
INPUT1(H)
100µ
75Ω
INPUT1(G)
75Ω
0.01µ
47µ
VCC(B)(12V)
75Ω
47µ
VCC(B)(5V)
0.01µ
0.01µ
100µ
GND(R)
INPUT1(B)
0.01µ
OUTPUT(R)
75Ω
75Ω
47µ
VCC(R)(5V)
75Ω
0.01µ
47µ
100µ
VCC(R)(12V)
INPUT1(R)
0.01µ
0.01µ
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M52756SP
WIDE BAND ANALOG SWITCH
Marking
Mark Lot Number
XXXXXX
M52756SP
Model Type Number
Structure
Outer Passivation
Inner Lead Plating
Pellet
Wire
Die Bond
Lead Flame
Back Metalize
Lead Flame
Lead Flame
Plastic Molding
Material
Mold Material
Wire Material
Outer Lead Treatment
Lead Flame Material
Inner Lead Treatment
Over Passivation
: Epoxy
: Au
: Solder Plating
: Tin Nickel Copper
: Silver Plating
: SiN
Factory
Fukuoka,Japan
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