M61323SP/FP
Wide Frequency Band Analog Switch
REJ03F0201-0201
Rev.2.01
Mar 31, 2008
Description
The M61323SP/FP 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 10 kHz to 200 kHz, are output at TTL. The frequency band of video signals is 250 MHz,
acquiring high-resolution images, and are optimum as an interface IC with high-resolution CRT display and various
new media.
The M61323SP/FP keeps the power saving mode, and it can reduce ICC about 10 mA under the condition that all VCC
are supplied.
Features
•
•
•
Frequency band : RGB
H, V
250 MHz
10 kHz to 200 kHz
0.7 VP-P (Typ.)
3 to 5 VO-P (bipolar
Input level:
RGB
H, V TTL input
Only the G channel is provided with Sync-on video outped for HV output.
Application
Display monitor
Recommended Operating Cond
Supply voltage range:
Rated voltage range:
REJ03F0201-0201 Rev.2.01 Mar 31, 2008
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M61323SP/FP
Pin Arrangement
M61323SP
M61323FP
V
CC1 (R)
V
CC1 (R)
VCC2 (R)
Output (R)
GND2 (R)
36
35
32
1
1
NC
VCC2 (R)
31
30
Input1 (R)
VCC1 (G)
Input1 (R)
VCC1 (G)
Input1 (G)
VCC1 (B)
Input1 (B)
Input1 (H)
Input1 (V)
GND1
2
3
2
3
34
33
Output (R)
GND2 (R)
VCC2 (G)
Input1 (G)
VCC1 (B)
29
28
4
5
4
5
Output (G)
GND2 (G)
VCC2 (G)
32
31
Input1 (B)
Input1 (H)
Input1 (V)
GND1
6
27
26
6
Output (G)
V
CC2 (B)
30 GND2 (G)
29
28 Output (B)
7
7
Output (B)
25
VCC2 (B)
8
8
24 GND2 (B)
9
9
Input2 (R)
Power Save SW
Input2 (G)
G Buffer out
23
27
26
25
GND1
Input2 (R)
GND2 (B)
10
11
12
13
14
15
16
10
11
2
Sync SEP in
22
G Buffer out
Sync SEP in
Sync SEP out
21
20
Power Save S
Inpu
VCC3
24 Sync SEP out
Input SW
Input2 (B)
Input2 (H)
Input2 (V)
Output (H)
Output (V)
GND3
V
CC3
CC3
23
22
19
18
V
21 Output (H)
17
20
19
Output (V)
GND3
(Top view)
Outline: PRDP0032BA-A (32P4B)
(Top view)
Outline: PRSP0036GA-B (36P2R-D)
REJ03F0201-0201 Rev.2.01 Mar 31, 2008
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M61323SP/FP
Absolute Maximum Ratings
(Ta = 25°C)
Item
Supply voltage
Symbol
Ratings
Unit
V
VCC
Pd
7.0
1603 (SP), 1068 (FP)
−20 to +85 (SP), −20 to +75 (FP)
−40 to +150
Power dissipation
mW
°C
°C
V
Operating temperature
Storage temperature
Topr
Tstg
Electrostatic discharge
Recommended supply voltage
Recommended supply voltage range
Surge
Vopr
±200
5.0
V
Vopr'
4.75 to 5.25
V
Electrical Characteristics
(M61323SP VCC = 5.0 V, Ta = 25°C)
Test
Point
Symbol Min. Typ. Max. Unit (s)
Limits
Input
SW
SW13
Switch
SW22
Sync
SW2 SW4 SW6 SW7 SW8 S12 SW14 SW15 SW16
Rin1 Gin1 Bin1 Hin1 Vin1 Bin2 Hin2 Vin2
SW11
P.sav
Item
a
3 V
Circuit current1
70
mA
mA
b
b
b
b
b
b
b
b
b
ICC
Circuit current2
10
b
b
b
b
b
b
b
b
b
ICCSTBY
RGB SW
Output DC voltage1
1.5
1.5
V
V
31
28
25
31
28
25
23
b
b
b
b
b
b
b
b
b
b
b
a
3 V
b
Vdc1
Vdc2
Output DC voltage2
a
3 V
a
3 V
Output DC voltage3
Output DC voltage4
0.9
0.9
1.8
V
V
b
b
b
b
b
b
b
b
b
b
b
b
b
b
b
b
b
b
a
b
Vdc3
3 V
a
2
a
3 V
Vdc4
3 V
Maximum allowable
input level1
VP
a
3 V
b
Vimax1
Maximum allowable
input level2
1.8
b
b
b
b
abb
bab
bba
SG1 SG1 SG1
b
b
b
b
b
b
a
3 V
a
3 V
Vimax2
GV1
Voltage gain1
−0.1
G2 SG2
bba
b
b
b
a
3 V
b
Relative to measured values above
abb bab bba
SG2 SG2 SG2
Relative voltage gain1
Voltage gain2
∆GV1
8
25
b
b
b
b
b
b
b
b
a
3 V
a
3 V
GV2
Relative voltage gain2
Voltage gain3
−0.4
0
dB
Relative to measured values above
∆GV2
−0.6
23
b
b
a
SG2
b
b
b
b
b
b
b
b
b
b
b
b
b
b
a
b
GV3
3 V
a
Voltage gain4
−0.6
0
0.6
dB
23
b
b
b
a
SG2
b
a
3 V
GV4
3 V
REJ03F0201-0201 Rev.2.01 Mar 31, 2008
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M61323SP/FP
Electrical Characteristics (cont.)
Limits
Test
Point
Unit (s)
Symbol Min. Typ. Max.
Input
SW
SW13
SW22
Sync
SW2 SW4 SW6 SW7 SW8 SW10 SW12 SW14 SW15 SW16
Rin1 Gin1 Bin1 Hin1 Vin1 Rin2 Gin2 Bin2 Hin2 Vin2
SW11
P.sav
a
Item
Switch
b
Freq. characteristic1
(100 MHz)
−1
0
1
dB
31 abb bab
28 SG4 SG4 SG4
bba
b
b
b
b
b
b
b
b
FC1
3 V
25
Relative
Freq.characteristic1
(100 MHz)
−1
0
1
∆FC1
dB
dB
dB
dB
Relative to measured values above
Freq.characteristic2
(100 MHz)
−1
−1
−3
0
0
1
1
31
28
25
b
b
b
b
b
abb
bab
bba
SG4 SG4 SG4
b
b
b
b
b
b
a
3 V
a
3 V
FC2
Relative
Freq.characteristic2
(100 MHz)
Relative to measured values above
∆FC2
31
28
25
31
28
25
31
Freq.characteristic3
(250 MHz)
abb bab bba
SG5 SG5 SG5
b
b
b
b
b
a
3 V
b
FC3
Freq.characteristic4
(250 MHz)
−3
dB
dB
b
b
b
b
b
b
b
abb
bab
SG5 SG5 SG5
bba
b
b
b
b
b
b
a
3 V
a
3 V
FC4
Crosstalk between
two inputs1 (10 MHz)
−60 −45
abb bab
bba
b
b
b
a
3 V
a
3 V
C.T.I.1
28 SG3 SG3 SG3
25
Crosstalk between
two inputs2 (10 MHz)
−60 −45 dB
31
28
25
b
b
b
b
b
SG3
bba
b
b
b
a
3 V
b
C.T.I.2
Crosstalk between
two inputs3 (100 MHz)
31
28
25
b
b
b
b
a
3 V
a
3 V
abb bab bba
SG4 SG4 SG4
b
b
b
b
b
b
b
C.T.I.3
C.T.I.4
C.T.C1
C.T.C2
C.T.C3
C.T.C4
Tr1
−40 −30 dB
−40 −30 dB
−50 −40 dB
Crosstalk between
two inputs4 (100 MHz)
31
28
25
31
b
b
b
4
a
3 V
b
b
Crosstalk between
channels1 (10 MHz)
abb ba
b
a
3 V
28 SG3
25
Crosstalk between
channels2 (10 MHz)
−50 −40 dB
31
28
2
bba
G3 SG3 SG3
bab
b
b
a
3 V
a
3 V
Crosstalk between
channels3 (100 MHz)
a
3 V
−30 −25 dB
b
b
b
b
b
b
b
b
b
b
b
b
b
Crosstalk between
channels4 (100 MHz)
−30 −25
abb bab
SG4 SG4 SG4
bba
a
3 V
a
3 V
Pulse characteristic1
Pulse characteristic2
1.
bba
b
b
b
b
b
b
b
b
b
b
b
b
b
b
b
b
b
b
b
b
b
b
b
a
3 V
b
b
SG6
bab
bba
a
3 V
Tf1
SG6 SG6
8
25
b
b
b
b
b
b
abb
SG6 SG6 SG6
bab
bba
a
3 V
a
3 V
Tr2
1.
31
28
25
b
b
abb
SG6 SG6 SG6
bab
bba
b
a
3 V
a
3 V
Tf2
REJ03F0201-0201 Rev.2.01 Mar 31, 2008
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M61323SP/FP
Electrical Characteristics (cont.)
Test
Limits
Input
SW
Point
Symbol Min. Typ. Max. Unit
(s)
SW13
Switch
SW22
Sync
SW2 SW4 SW6 SW7 SW8 SW10 SW12 SW14 SW15 SW16
Rin1 Gin1 Bin1 Hin1 Vin1 Rin2 Gin2 Bin2 Hin2 Vin2
SW11
P.sav
Item
HV SW
High level
output voltage1
3.8 4.2
3.8 4.2
V
V
V
V
V
18
19
b
b
b
b
b
b
b
b
b
a
a
SG8 SG8
b
b
b
b
b
b
b
b
b
b
a
b
a
b
b
b
a
3 V
b
Vdch1
Vdch2
Vdcl1
Vdcl2
VithH
High level
output voltage2
18
19
b
b
a
3 V
a
3 V
SG8 SG8
Low level
output voltage1
0.2 0.5
0.2 0.5
18
19
a a
SG8 SG8
b
b
a
3 V
b
Low level
output voltage2
18
19
a
SG8 SG8
a
a
3 V
a
3 V
b
b
b
b
b
b
b
b
b
b
b
b
b
b
b
b
Input threshold
voltage H
1.8 2.0 2.2
1.0 1.4 1.6
18
19
a
SG8 SG8
a
b
b
a
3 V
b
Input threshold
voltage L
V
18
19
b
b
b
b
b
b
b
b
b
b
b
b
b
b
b
a a
SG8 SG8
b
b
b
b
b
b
b
b
b
b
b
b
b
b
b
b
b
b
b
b
b
b
b
b
b
b
b
b
a
3 V
b
b
b
b
b
VithL
Tr3
Rising time3
25
15
40
40
60
60
ns
ns
ns
18
19
a a
SG8 SG8
a
3 V
Falling time3
18
19
a
SG8 SG8
a
a
3 V
Tf3
Rising delay time
Falling delay time
18
19
a
SG8 SG8
a
a
3 V
HVDr
HVDf
ns
18
19
a
SG8 SG8
a
a
3 V
Sync SEP.
Sync on G input
minimum voltage
0.2
VP-P
V
21
21
21
b
b
b
b
b
b
b
b
b
b
b
b
b
b
b
b
a
SG7
a
3 V
SYrv
SYVH
SYVL
STr
Sync output
high level voltage
3.8 4.3
a
SG7
a
3 V
Sync output
low level voltage
0.2 0.5
V
a
SG7
a
3 V
Sync output
rising time 3
25
ns
21
b
b
b
b
b
a
SG7
a
3 V
Sync output
falling time 3
15
40
40
60
60
ns
ns
21
b
b
b
b
b
b
b
b
b
b
b
b
b
b
b
b
a
SG7
a
3 V
STf
SDr
SDf
Sync output
rising delay time
a
SG7
a
3 V
Sync output
falling delay time
a
SG7
a
3 V
Channel Select SW, Power Save SW
Channel select SW
threshold voltage1
2.5
SG6 SG8 SG8
a
a
a
b
b
b
b
b
a
SG7
a
3 V
a
variable
Vthch1
Channel select SW
threshold voltage2
a
SG6 SG6 SG8 SG8
a
a
a
b
b
b
b
b
b
b
b
b
b
a
SG7
a
3 V
a
variable
Vthch2
VthPH
VthPL
Power save SW
threshold voltage1
a a
SG6 SG6 SG6 SG8 SG8
a
a
a
a
SG7
a
variable
b
b
Power save SW
threshold voltage2
a
SG6 SG6 SG6 SG8 SG8
a
a
a
a
a
SG7
a
variable
b
b
b
b
b
REJ03F0201-0201 Rev.2.01 Mar 31, 2008
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M61323SP/FP
Electrical Characteristics Test Method (M61323SP)
Circuit Current 1
No signal. Measure the total circuit current as ICC when supplying 3 VDC to pin 11.
Circuit Current 2
No signal. Measure the total circuit current as ICCSTBY when pin 11 connected to GND.
Output DC Voltage 1, 2
Set SW13 to GND (or OPEN), measure the DC voltage of TP31 (TP28, TP25) when there is no signal input.
The DC voltage is as vdc1 (vdc2).
Output DC Voltage 3, 4
Measure the DC voltage TP23 same as "Output DC voltage 1, 2". The DC voltage is Vdc3 (Vdc4).
Maximum Allowable Input Level 1, 2
Set SW13 to GND, input SG1 to pin 2 only. Gradually increasing the SG1 amread the amplitude of the input
signal when the output waveform of TP31 is strained. The value is as Vimme way, measure Vimax1 in
response to inputs in pin 4 and pin 6 only.
Then set SW13 to OPEN, measure Vimax2 in response to inputs in
Voltage Gain 1, 2
1. The conditions is as table.
2. Set SW13 to GND, input SG2 (0.7 VP-P) to pin 2 oude of TP31. The value is as VOR1.
3. Voltage gain GV1 is
VOR1 [VP-P
]
GV1 = 20log
(dB)
0.7
4. In the same way, calculate GV1 in repin 6 only.
5. Then set SW13 to OPEN, measuin pin l0, 12 and 14 only.
Relative Voltage Gain 1, 2
1. Calculate relative volwing formula.
∆GV1 = GV1R − GV1B − GV1R
2. In the same way, calculate
Voltage Gain 3, 4
1. The conditions is as table.
2. Read the output amplitude of TP23.
3. Calculate GV3, GV4 same as "Voltage gain 1".
Freq. Characteristic 1, 2/Relative Freq. Characteristic 1, 2
1. The conditions is as table. This measurement shall use active probe.
2. Set SW13 to GND, input SG4 (0.7 VP-P) to pin 2 only. Measure TP31 output amplitude as VOR1.
In the same way, input SG2 (0.7 VP-P) to pin 2 only. Measure TP31 output amplitude as VOR2.
3. Freq.characteristic1 FC1 is
VOR2 [VP-P
]
FC1 = 20log
(dB)
V
OR1 [VP-P
]
4. In the same way, calculate FC1 in response to inputs in pin 4 and pin 6 only.
5. The difference between of each channel Freq.characteristic is as ∆FC1.
6. Then set SW13 to OPEN, measure FC2 and ∆FC2 in response to inputs in pin 10, 12 and 14 only.
REJ03F0201-0201 Rev.2.01 Mar 31, 2008
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M61323SP/FP
Freq. Characteristic 3, 4
Measure the FC3, FC4 when SG5 of input signal. (For reference)
Crosstalk between Two Inputs 1, 2
1. The conditions is as table. This measurement shall use active probe.
2. Set SW13 to GND, input SG3 to pin 2 only. Read the output amplitude of TP31. The value is as VOR3.
3. Then set SW13 to OPEN, read the output amplitude of TP31. The value is as VOR3'.
4. Crosstalk between two inputs 1 C.T.I.1 is
VOR3' [VP-P
]
C.T.I.1 = 20log
(dB)
V
OR3 [VP-P]
5. In the same way, calculate C.T.I.1 in response to inputs in pin 4 and pin 6 only.
6. Then set SW13 to OPEN, input SG2 to pin 10 only. Read the output amplitude of TP31. The value is as VOR4.
7. Set SW13 to GND, read the output amplitude of TP31. The value is as VOR4'.
8. Crosstalk between two inputs 1 C.T.I.2 is
VOR4' [VP-P
]
C.T.I.2 = 20log
(dB)
V
OR4 [VP-P]
9. In the same way, calculate C.T.I.2 in response to inputs in pin 12 and pin
Crosstalk between Two Inputs 3, 4
Set SG4 as the input signal, and then the same method as table, m
Crosstalk between Channels 1, 2
1. The conditions is as table. This measurement shall
2. Set SW13 to GND, input SG3 (0.7 VP-P) to pin 2 itude of TP31. The value is as VOR5.
3. Next, measure TP28, TP25 in the same state, 5, VOB5.
4. Crosstalk between channels1 C.T.C1 is
VOG5 or VOB
5
C.T.C1 = 20log
V
OR5
5. In the same way, calculate C.Tpin 4 and pin 6 only.
6. Then set SW13 to OPEN, i0 only.
Read the output amplituVOR6.
7. Next, measure TP28, the amplitude is as VOG6, VOB6.
8. Crosstalk between two
VOG6
C.T.C2 = 20log
V
OR6
9. In the same way, calculate C.T.C2 in response to inputs in pin 9 and pin 11 only.
Crosstalk between Channels 3, 4
Set SG4 as the input signal, and then the same method astable, measure C.T.C3, C.T.C4.
REJ03F0201-0201 Rev.2.01 Mar 31, 2008
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M61323SP/FP
Pulse Characteristic 1, 2
1. The conditions is as table (SG5 amplitude 0.7 VP-P). Set SW13 to GND (or OPEN).
2. Measure rising Tri and falling Tfi for 10% to 90% of the input pulse with active probe.
3. Next, measure rising Tro and falling Tfo for 10% to 90% of the output pulse with active probe.
4. Pulse characteristic Tr1, Tf1 (Tr2, Tf2) is
100%
90%
Tr1 (Tr2) = (Tro)2 − (Tri)2 (ns)
√
10%
0%
Tf1 (Tf2) = (Tfo)2 − (Tfi)2 (ns)
√
Tr
Tf
<HV-SW>
High Level Output Voltage 1, 2/Low Level Output Voltage 1, 2
1. The conditions is as table. Input SG8 to pin 7 (or pin 8). Set SW13 to GNDd the output high level and low
voltage of TP19, TP18. The value is as Vdch1, Vdcl1.
2. Input SG8 to pin 15 (or pin 16). Set SW13 to OPEN, read the output voltage of TP19, TP18.
The value is as Vdch2, Vdcl2.
Input Threshold Voltage H/Input Threshold Voltage L
1. Set SW13 to GND (or OPEN). Gradually increasing th) from 0 V, measure the input
voltage of pin 7 (or pin 15) when the TP19 voltage tore). The value is as VithH.
2. Gradually decreasing the voltage of pin 7 (or pin nput voltage of pin 7 (or pin 15) when
the TP19 voltage turned low level (0.5 V or le
3. In the same way, measure the input voltagH, VithL.
Rising Time/Falling Time
1. The conditions is as table. This ve probe.
2. Measure rising Tri and fallinoutput pulse as Tr3, Tf3 (Tr4, Tf4).
80%
20%
Tr'
Tf'
Rising Delay Time/Falling Delay Time
Set SW13 to GND (or OPEN), input SG8 to pin 7 (or pin 15).
Measure the rising delay time HVDr and the falling delay time HVDf.
In the same way, measure HVDr and HVDf when input SG8 to pin 8 (or pin 16)
50%
50%
SG8
HVDr
HVDf
Waveform output
REJ03F0201-0201 Rev.2.01 Mar 31, 2008
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M61323SP/FP
<Sync-Separation>
Sync Input Minimum Voltage
Gradually decreasing the amplitude of SG7 in pin 22, measure the amplitude of SG7 when the Sync-Sep output signal
turn off. The value is as SYrv.
Sync Output High Level Voltage/Sync Output Low Level Voltage
Input SG7 to pin 22, read the output high level and low voltage of TP21. The value is as SYVH, SYVL.
Sync Output Rising Time/Sync Output Falling Time
1. The conditions is as table. (SG7 amplitude 0.3 VP-P
)
This measurement shall use active probe.
2. Measure rising Tri and falling Tfi for 10% to 90% of the input pulse as STr, STf.
100%
90%
0%
STr
STf
Sync Output Rising Delay Time/Sync Output Falling
Input SG7 to pin 22. Measure the rising delay time SDr Df.
50%
50%
SG7
SDf
Wavef
<Others>
Channel Select SW Threshold
1. Gradually increasing the voltage of pin 13 from 0 V, measure the maximum voltage of pin 13 when the channel 1 is
selected. The value is as Vthch1.
2. Gradually decreasing the voltage of pin 13 from 5 V, measure the minimum voltage of pin 13 when the channel 2 is
selected. The value is as Vthch2.
Power Save SW Threshold 1, 2
1. Gradually increasing the voltage of pin 11 from 0 V, measure the maximum voltage of pin 11 when the power save
mode. The value is as VthPL.
2. Gradually decreasing the voltage of pin 13 from 5 V, measure the minimum voltage of pin 11 when the power save
mode. The value is as VthPH.
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M61323SP/FP
Input Signal
SG No.
Signals
Sine wave (f = 60 kHz, 0.7 VP-P (Amplitude variable) )
SG1
0.7 VP-P
(variable)
SG2
SG3
SG4
SG5
SG6
Sine wave (f = 1 MHz, 0.7 VP-P (Amplitude variable) )
Sine wave (f = 10 MHz, 0.7 VP-P (Amplitude variable) )
Sine wave (f = 100 MHz, 0.7 VP-P (Amplitude variable) )
Sine wave (f = 250 MHz, 0.7 VP-P (Amplitude variable) )
DUTY 80%
fH = 60 kHz
0.7 VP-P
0.7 VP-P
SG7
SG8
Sync (fH = 60 kHz)
mplitude variable
. = 0.3 VP-P)
TTL
5 V
0 V
DUTY 50%
fH = 60 kHz
Typical Characteristics
Thermal Derating (M613
Thermal Derating (M61323FP)
1750
1750
1500
1250
1603
1500
1250
1000
1068
1000
833
750
750
640
500
500
250
0
250
0
−25
0
25
50
75 85 100 125 150
−25
0
25
50
75
100 125 150
Ambient Temperature Ta (°C)
Ambient Temperature Ta (°C)
REJ03F0201-0201 Rev.2.01 Mar 31, 2008
Page 11 of 19
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M61323SP/FP
Test Circuit (M61323SP)
TP23
SG
SS
b
a
0.01 µ
VCCC 5 V
SW C
SW22
b
a
SW32
b
a
SW29
b
a
SW26
47 µ
b
a
A
TP31
TP28
TP25
TP21
+
a
0.01 µ
47 µ
VCCB
5 V
+
1 µ
+
+
+
TP19 TP18
b
SW B
32
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
R-OUT
VCC
G-OUT
VCC
B-OUT
VCC
VCC
R-SW
VCC
G-SW
VCC
B-SW
VCC
1
2
3
4
5
6
7
8
13
14
15
16
0.01 µ
0.01 µ
0.01 µ
13
a
+
A
c
b
a
b
en
open
+
+
SW A
+
+
75
75
VCC A 5 V
SW15 SW16
75
75
a
b
a
b
SW2
a
SW4
SW10
a
SW12
a
SW14
a
b
b
b
b
SG
HV
Units Resistance: Ω
Capacitance: F
REJ03F0201-0201 Rev.2.01 Mar 31, 2008
Page 12 of 19
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M61323SP/FP
Application Example (M61323SP)
OUTPUT
VCC
5 V
ROUT
GOUT
BOUT
+
0.01 µ
47 µ
G Buffer OUT
Sync SEP OUT
Hout Vout
+
+
+
1 µ
VCC
5 V
0.01 µ
+
VCC
5 V
47 µ
+
POWER SAVE VCC
(H-SW, V-SW,
G-Buffer, Sync-SEP)
32
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
0.01 µ
47 µ
VCC
VCC
VCC
VCC
Sync
Sepa
R
G
B
G
H
V
VCC
(5 V)
VCC
(5 V)
VCC
(5 V)
Powe
1
2
3
4
5
6
7
8
9
10
15
16
0.01 µ
0.01 µ
0.01 µ
0 to 0.8 V : INPUT1
2.0 to 5.0 V: INPUT2
+
+
+
PowerSave VCC
+
75
75
75
75
INPUT1
INPUT2
Rin2
Gin2
Bin2
Hin2
Vin2
Rin1
Gin1
Bin1
Hin1
Vin1
Units Resistance: Ω
Capacitance: F
REJ03F0201-0201 Rev.2.01 Mar 31, 2008
Page 13 of 19
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M61323SP/FP
Pin Description (M61323SP)
pin No.
Name
VCC (R)
DC Voltage (V)
Peripheral Circuit
Function
1
3
5.0
VCC (G)
5
VCC (B)
20
VCC (H, V,
Sync-Sep.)
26
29
32
2
VCC (ROUT)
VCC (GOUT)
VCC (BOUT)
Input1 (R)
Input1 (G)
Input1 (B)
Input2 (R)
Input2 (G)
Input2 (B)
5.0
2.3
Input signal with low impedance
4
750
6
3 V
10
12
14
643
2.48 V
2.2 mA
7
8
Input1 (H)
Input1 (V)
Input2 (H)
Input2 (V)
lse between 3 V and 5 V
3 to 5 V
15
16
0 to 0.8 V
SW
9
GND (V-SW)
GND
17
(H, V, Sync-
Sep.)
24
27
30
GND (B-out)
GND (G-out)
GND (R-out)
REJ03F0201-0201 Rev.2.01 Mar 31, 2008
Page 14 of 19
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M61323SP/FP
Pin Description (M61323SP) (cont.)
pin No.
Name
DC Voltage (V)
Peripheral Circuit
Function
11
PwrSave-SW
2.5
Do not apply more 5 V DC
voltage
30 k
15 k
25 k
2.0 V
10 k
25 k
20 k 20 k
20 k
13
CONT-SW
2.4
Do not apply more 5 V DC
voltage
26 k
15 k
5 k
2.4 V
24 k
18
19
Vout
Hout
100
REJ03F0201-0201 Rev.2.01 Mar 31, 2008
Page 15 of 19
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M61323SP/FP
Pin Description (M61323SP) (cont.)
pin No.
Name
DC Voltage (V)
Peripheral Circuit
Function
21
Sync sep OUT
15 k
100
15 k
15 k
22
Sync sep IN
Connect a capacitance
between the pin and GND
when not use SYNC-SEP
10 k
10 k
CLAMPref
23
G Buffer OUT
5 k
2 k
25
28
31
Video OUT (B)
Video OUT (
Video OUT (R)
32, 29, 26 pin
50
31, 28, 25 pin
30, 27, 24 pin
REJ03F0201-0201 Rev.2.01 Mar 31, 2008
Page 16 of 19
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M61323SP/FP
Note How to Use This IC (M61323SP)
1. R, G, B input signal is 0.7 VP-P of standard video signal.
2. H, V input is 5.0 V TTL type.
3. Input signal with sufficient low impedance to input terminal.
4. The terminal of R, G, B output pin are shown as figure 1.
When resistance is connected between the pin 31 (28, 25) and GND, ICC will be increase.
5. Switch (pin 13) can be changed by supplying some voltage as figure 2.
0 to 0.5 V: INPUT1
2.5 to 5 V: INPUT2
Do not apply VCC or more DC voltage.
6. Power save mode is provided for saving ICC less than about 10 mA as figure 3.
0 to 0.5 V: Power save mode (H.V-SW, Sync-Sep., G-Buffer)
2.5 to 5 V: Normal mode
Do not apply 5 V or more DC voltage
7. When not use the Sync-separation circuit built in this IC, capacitance of several tens of pF is required between the
pin 22 and GND.
5 V
I < 5 mA
50
600 Ω
13
Figure 2
11
Figure 3
REJ03F0201-0201 Rev.2.01 Mar 31, 2008
Page 17 of 19
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M61323SP/FP
Cautions for Manufacturing Boards
Built-in wide band preamplifier may cause oscillation due to the wiring shape on the board.
Be careful for the following points.
•
VCC shall use a stable power supply.
(Individual VCC should use an independent power supply.)
•
GND should be as wide as possible. Basically, solid earth should be used.
Make the load capacitance of output pins as small as possible.
Also ground the hold capacitance to stable GND, which is as near to the pin as possible.
Insertion of a resistance of several tens of ohms between the output pin and the circuit at the next stage makes
oscillation harder.
•
•
•
When inserting an output pull-down resistance, make wire between the output pin and the resistance as short as
possible.
REJ03F0201-0201 Rev.2.01 Mar 31, 2008
Page 18 of 19
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M61323SP/FP
Package Dimensions
JEITA Package Code
P-SDIP32-8.9x28-1.78
RENESAS Code
Previous Code
32P4B
MASS[Typ.]
2.2g
PRDP0032BA-A
32
17
NOTE)
1. DIMENSIONS "*1" AND "*2"
1
16
DO NOT INCLUDE MOLD FLASH.
2. DIMENSION "*3" DOES NOT
INCLUDE TRIM OFFSET.
*2
D
Dimension in Millimeters
Reference
Symbol
Min Nom Max
e1
D
9.86 10.16 10.46
27.8 28.0 28.2
E
8.9
8.75
9.05
5.08
A
A1
A2
bp
b2
b3
c
0.51
*3
*3
bp
b3
b2
e
3.8
SEATING PLANE
0.35 0.45 0.55
0.63 0.73 1.03
0.9 1.0 1.3
0.22 0.27 0.34
0°
15°
1.528 1.778 2.028
3.0
e
L
JEITA Package Code
P-SSOP36-8.4x15-0.80
RENESAS Code
PRSP0036GA-B
Previo
F
NOTE)
1. DIMENSIONS "*1" AND "*2"
DO NOT INCLUDE MOLD FLASH.
2. DIMENSION "*3" DOES NOT
INCLUDE TRIM OFFSET.
18
1
Index mark
*2
D
Dimension in Millimeters
Reference
Symbol
A2
A1
Min Nom Max
D
E
14.8 15.0 15.2
8.2 8.4 8.6
2.05
*3
bp
y
e
A2
A
2.35
0.1 0.2
A1
bp
c
0
0.3 0.35 0.45
0.18 0.2 0.25
0°
8°
HE
e
11.63 11.93 12.23
0.65 0.8 0.95
0.10
Detail F
y
L
0.3 0.5 0.7
REJ03F0201-0201 Rev.2.01 Mar 31, 2008
Page 19 of 19
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Notes:
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