M52348FP [MITSUBISHI]
WIDE FREQUENCY BAND ANALOG SWITCH; 宽频带模拟开关
| 型号: | M52348FP |
| 厂家: | 
Mitsubishi Group |
| 描述: | WIDE FREQUENCY BAND ANALOG SWITCH |
| 文件: | 总11页 (文件大小:88K) |
| 中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
MITSUBISHI ICs (Monitor)
M52348FP
WIDE FREQUENCY BAND ANALOG SWITCH
DESCRIPTION
PIN CONFIGURATION (TOP VIEW)
The M52348FP is an semiconductor IC for RGBHV interface that
switches signals input from two types of image source and outputs
them to CRT display etc. The synchronous signal meets the
frequency band of 10 kHz to 200 kHz and is output with TTL. The
IC adopts 250 MHz for the frequency band width of video signal,
providing high resolution images. It is optimum as an IC for
interface with various types of new media including high resolution
CRT.
VCC1(R)
INPUT1(R)
VCC1(G)
VCC2(R)
OUTPUT(R)
GND
1
2
3
4
5
6
7
36
35
34
33
NC
NC
INPUT1(G)
VCC1(B)
32 NC
31 VCC2(G)
INPUT1(B)
INPUT1(H)
30
29
28
27
26
OUTPUT(G)
GND
8
9
FEATURES
INPUT1(V)
GND
VCC2(B)
• Frequency band : RGB...................................................250MHz
HV..........................................10Hz to 200kHz
OUTPUT(B)
GND
10
11
12
Input level :
RGB...........................................0.7 VP-P (typ.)
HV TTL IN PUT
INPUT2(R)
GND
3 to 5 Vo-p (bipolar)
25 OUTPUT(Sync on G)
• Only the G channel is equipped with output for sync-on-video.
• HV output adopts TTL format.
INPUT2(G) 13
24
23
22
21
20
VCC
14
NC
NC
GND
15
16
17
18
OUTPUT(H)
APPLICATION
CRT display, TV, VCR, etc.
INPUT2(B)
OUTPUT(V)
GND
INPUT2(H)
INPUT2(V)
RECOMMENDED OPERATING CONDITINO
19 SWITCH
Supply voltage range.......................................................4.5 to 5.5V
Rated supply voltage..................................................................5.0V
Outline 36P2R-D
NC : NO CONNECTION
BLOCK DIAGRAM
OUTPUT
(Sync on G)
OUTPUT(R)
VCC2(G)
GND
29
OUTPUT(B)
NC
OUTPUT(V)
SWITCH
GND
VCC2(R)
36
GND
NC
33
NC
32
OUTPUT(G)
VCC2(B)
28
GND
VCC
OUTPUT(H)
35
34
31
30
27
26
25
24
23
22
21
20
19
6
7
8
9
1
2
3
4
5
10
11
12
13
14
15
16
17
18
INPUT1(R)
NC
VCC1(B)
INPUT1(H)
GND
GND
NC
INPUT2(B)
INPUT2(V)
VCC1(R)
VCC1(G)
INPUT1(G)
INPUT1(B)
INPUT1(V)
INPUT2(R)
INPUT2(G)
GND
INPUT2(H)
1
MITSUBISHI ICs (Monitor)
M52348FP
WIDE FREQUENCY BAND ANALOG SWITCH
ABSOLUTE MAXIMUM RAGINGS (Ta=25˚C)
Symbol
VCC
Parameter
Ratings
Unit
V
Supply voltage
7.0
1603
Pd
Power dissipation
mW
˚C
˚C
V
Topr
Operating temperature
-20 to +85
-40 to +150
5.0
Tstg
Storage temperature
Vopr
Recommended operating supply voltage
Recommended operating supply voltage range
Electrostatic discharge
Vopr’
Sarge
4.5 to 5.5
±200
V
V
ELECTRICAL CHARACTERISTICS (VCC=5V,Ta=25˚C)
Power
Test conditions
SW
Limits
supply
Test
point
Symbol
Parameter
Unit
SW2 SW5 SW7 SW8 SW9 SW11 SW13 SW16 SW17 SW18
SW19
Swich
Vcc
5
Min. Typ. Max.
Bin2
Vin2
Rin1 Gin1 Bin1 Hin1 Vin1 Rin2 Gin2
Hin2
b
-
b
-
b
-
b
-
b
-
b
-
b
-
b
-
b
-
b
-
b
GND
Circuit current 1
(no signal)
ICC1
ICC1
A
46
46
66
66
86
86
mA
mA
b
-
b
-
b
-
b
-
b
-
b
-
b
-
b
-
b
-
b
-
a
Circuit current 2
(no signal)
A
5
OPEN
RGB SW block
T.P.35
T.P.30
T.P.27
Output DC
voltage 1
b
-
b
-
b
-
b
-
b
-
b
-
b
-
b
-
b
-
b
-
b
GND
VDC1
VDC2
5
5
1.8
1.8
2.2
2.2
2.6
2.6
V
V
T.P.35
T.P.30
T.P.27
Output DC
voltage 2
b
-
b
-
b
-
b
-
b
-
b
-
b
-
b
-
b
-
b
-
a
OPEN
Output DC
voltage 3
b
-
b
-
b
-
b
-
b
-
b
-
b
-
b
-
b
-
b
-
b
GND
T.P.25
T.P.25
VDC3
VDC4
5
5
1.1
1.1
1.5
1.5
1.9
1.9
V
V
Output DC
voltage 4
b
-
b
-
b
-
b
-
b
-
b
-
b
-
b
-
b
-
b
-
a
OPEN
T.P.2
T.P.5
T.P.7
abb bab bba
SG1 SG1 SG1
b
-
b
-
b
-
b
-
b
-
b
-
b
-
b
GND
Maximum allow-
able input 1
Vimax1
Vimax2
5
5
5
1.4
1.4
1.6
1.6
-
-
VP-P
VP-P
T.P.11
T.P.13
T.P.16
b
-
b
-
b
-
b
-
b
-
abb bab bba
SG1 SG1 SG1
b
-
b
-
a
Maximum allow-
able input 2
OPEN
T.P.35
T.P.30
T.P.27
abb bab bba
SG2 SG2 SG2
b
-
b
-
b
-
b
-
b
-
b
-
b
-
b
GND
GV1
Voltage gain 1
-0.5
-0.6
-0.5
0.1
0
0.7
0.6
0.7
dB
dB
dB
Relative voltage
gain 1
∆GV1
GV2
Takes ratio of the values above
T.P.35
T.P.30
T.P.27
b
-
b
-
b
-
b
-
b
-
abb bab bba
SG2 SG2 SG2
b
-
b
-
a
Voltage gain 2
5
0.1
OPEN
Relative voltage
gain 2
∆GV2
GV3
Takes ratio of the values above.
-0.6
-0.4
-0.4
0
0.6
0.8
0.8
dB
dB
dB
b
-
a
b
-
b
-
b
-
b
-
b
-
b
-
b
-
b
-
b
GND
T.P.25
T.P.25
Voltage gain 3
Voltage gain 4
5
5
0.2
0.2
SG2
b
-
b
-
b
-
b
-
b
-
b
-
a
SG2
b
-
b
-
b
-
a
GV4
OPEN
Frequency character-
istics 1
(100MHz)
T.P.35
T.P.30
T.P.27
abb bab bba
SG4 SG4 SG4
b
-
b
-
b
-
b
-
b
-
b
-
b
-
b
GND
FC1
5
-0.1
-0.1
-0.1
-0.1
-3.0
-3.0
0
0
1.0
1.0
1.0
1.0
1.0
1.0
dB
dB
dB
dB
dB
dB
Relative frequency
characteristics 1
(100MHz)
∆FC1
FC2
Takes ratio of the values above
Frequency character-
istics 2
(100MHz)
T.P.35
T.P.30
T.P.27
b
-
b
-
b
-
b
-
b
-
abb bab bba
SG4 SG4 SG4
b
-
b
-
a
5
0
OPEN
Relative frequency
characteristics 2
(100MHz)
∆FC2
FC3
Takes ratio of the values above
0
Frequency character-
istics 3
(100MHz)
T.P.35
T.P.30
T.P.27
abb bab bba
SG5 SG5 SG5
b
-
b
-
b
-
b
-
b
-
b
-
b
-
b
GND
5
5
1.5
1.5
Relative frequency
characteristics 4
(250MHz)
T.P.35
T.P.30
T.P.27
b
-
b
-
b
-
b
-
b
-
abb bab bba
SG5 SG5 SG5
b
-
b
-
a
FC4
OPEN
2
MITSUBISHI ICs (Monitor)
M52348FP
WIDE FREQUENCY BAND ANALOG SWITCH
ELECTRICAL CHARACTERISTICS (cont.)
Power
Test conditions
SW
Limits
supply
Test
point
Symbol
Parameter
Crosstalk 1
Unit
SW2 SW5 SW7 SW8 SW9 SW11 SW13 SW16 SW17 SW18
Rin1 Gin1 Bin1 Hin1 Vin1 Rin2 Gin2 Bin2 Hin2 Vin2
SW19
Swich
Vcc
5
Min. Typ. Max.
GND
T.P.35
T.P.30
T.P.27
abb bab bba
SG3 SG3 SG3
b
-
b
-
b
-
b
-
b
-
b
-
b
-
between 2 inputs
(10MHz)
C.T.I.1
C.T.I.2
C.T.I.3
C.T.I.4
C.T.C.1
C.T.C.2
C.T.C.3
C.T.C.4
-
-
-
-
-
-
-
-
-60
-60
-40
-40
-50
-50
-30
-30
-50
-50
-35
-35
-40
-40
-25
-25
dB
dB
dB
dB
dB
dB
dB
dB
OPEN
OPEN
Crosstalk 2
between 2 inputs
(10MHz)
T.P.35
T.P.30
T.P.27
b
-
b
-
b
-
b
-
b
-
abb bab bba
SG3 SG3 SG3
b
-
b
-
5
5
5
5
5
5
5
GND
GND
Crosstalk 3
between 2 inputs
(100MHz)
T.P.35
T.P.30
T.P.27
abb bab bba
SG4 SG4 SG4
b
-
b
-
b
-
b
-
b
-
b
-
b
-
OPEN
OPEN
Crosstalk 4
between 2 inputs
(100MHz)
T.P.35
T.P.30
T.P.27
b
-
b
-
b
-
b
-
b
-
abb bab bba
SG4 SG4 SG4
b
-
b
-
GND
Crosstalk 1
between channels
(10MHz)
T.P.35
T.P.30
T.P.27
abb bab bba
SG3 SG3 SG3
b
-
b
-
b
-
b
-
b
-
b
-
b
-
b
GND
Crosstalk 2
between channels
(10MHz)
T.P.35
T.P.30
T.P.27
b
-
b
-
b
-
b
-
b
-
abb bab bba
SG3 SG3 SG3
b
-
b
-
a
OPEN
Crosstalk 3
between channels
(100MHz)
T.P.35
T.P.30
T.P.27
abb bab bba
SG4 SG4 SG4
b
-
b
-
b
-
b
-
b
-
b
-
b
-
b
GND
Crosstalk 4
between channels
(100MHz)
T.P.35
T.P.30
T.P.27
b
-
b
-
b
-
b
-
b
-
abb bab bba
SG4 SG4 SG4
b
-
b
-
a
OPEN
T.P.35
T.P.30
T.P.27
a
a
a
b
-
b
-
b
-
b
-
b
-
b
-
b
-
b
GND
Tr1
Tf1
Tr2
Tf2
5
5
5
5
-
-
-
-
1.6
1.6
1.6
1.6
2.5 nsec
2.5 nsec
2.5 nsec
2.5 nsec
SG6 SG6 SG6
Pulse characteris-
tics 1
T.P.35
T.P.30
T.P.27
a
a
a
b
-
b
-
b
-
b
-
b
-
b
-
b
-
b
GND
SG6 SG6 SG6
T.P.35
T.P.30
T.P.27
b
-
b
-
b
-
b
-
b
-
a
a
a
b
-
b
-
a
SG6 SG6 SG6
OPEN
Pulse characteris-
tics 2
T.P.35
T.P.30
T.P.27
b
-
b
-
b
-
b
-
b
-
a
a
a
b
-
b
-
a
SG6 SG6 SG6
OPEN
HV SW portion
b
-
b
-
b
-
c
c
b
-
b
-
b
-
b
-
b
-
b
GND
High-level output
T.P.21
T.P.22
VOH1
VOH2
VOL1
VOL2
5
5
5
5
4.5
4.5
-
5.0
5.0
0.2
0.2
-
V
V
V
V
voltage 1
5.0V 5.0V
b
-
b
-
b
-
b
-
b
-
b
-
b
-
b
-
c
c
a
High-level output
voltage 2
T.P.21
T.P.22
-
5.0V 5.0V OPEN
b
-
b
-
b
-
c
c
b
-
b
-
b
-
b
-
b
-
b
GND
Low-level output
voltage 1
T.P.21
T.P.22
5.0
5.0
0V 0V
b
-
b
-
b
-
b
-
b
-
b
-
b
-
b
-
c
c
a
Low level output
voltage 2
T.P.21
T.P.22
-
0V 0V OPEN
b
-
b
-
b
-
c
c
b
-
b
-
b
-
b
-
b
-
b
GND
Input threshold
voltage 1
T.P.8
T.P.9
Vith1
5
2.0
2.5
3.0
3.0
V
V
Vari- Vari-
able
able
b
-
b
-
b
-
b
-
b
-
b
-
b
-
b
-
c
c
Vari-
a
Input threshold
voltage 2
T.P.17
T.P.18
Vith2
Trd1
5
5
5
5
5
5
5
2.0
2.5
100
100
50
Vari-
OPEN
able able
b
-
b
-
b
-
a
a
b
-
b
-
b
-
b
-
b
-
b
GND
T.P.21
T.P.22
Rising delay time 1
Rising delay time 2
-
-
150 nsec
150 nsec
100 nsec
100 nsec
SG7 SG7
b
-
b
-
b
-
b
-
b
-
b
-
b
-
b
-
a
a
a
T.P.21
T.P.22
Trd2
SG7 SG7 OPEN
Falling delay
time 1
b
-
b
-
b
-
a
a
b
-
b
-
b
-
b
-
b
-
b
GND
T.P.21
T.P.22
Tfd1
Tfd2
Vsth1
Vsth2
-
SG7 SG7
Falling delay
time 2
b
-
b
-
b
-
b
-
b
-
b
-
b
-
b
-
a
a
a
T.P.21
T.P.22
-
50
SG7 SG7 OPEN
a
a
a
a
a
b
-
b
-
b
-
b
-
b
-
Switching thresh-
old voltage 1
T.P.19
T.P.19
c
c
0.5
0.5
1.5
1.5
2.0
2.0
V
V
SG1 SG1 SG1 SG7 SG7
b
-
b
-
b
-
b
-
b
-
a
a
a
a
a
Switching thresh-
old voltage 2
SG1 SG1 SG1 SG7 SG7
3
MITSUBISHI ICs (Monitor)
M52348FP
WIDE FREQUENCY BAND ANALOG SWITCH
2. When this is the case, measure the output amplitude of T.P.25.
ELECTORICAL CHARACTERISTICS TEST
METHOD
3. As in the case of GV1, ∆GV1, GV2 and ∆GV2, find GV3 and GV4.
Note) Omitted because the signal input pins and SW No. have been
described in the Electrical Characteristics Table. SWA shall take
side a unless otherwise noted.
FC1, ∆FC1 frequency characteristics 1, relative frequency
characteristics 1 (100 MHz)
FC2, ∆FC2 frequency characteristics 2, relative frequency
characteristics 2 (100 MHz)
ICC1, ICC2 Circuit current 1, circuit current 2 (no signal)
The conditions shall be as provided in the Electrical Characteristics
Table. When SW19 is assigned to GND (or OPEN), and SWA is
placed on side b, take measurements in ampere meter A and
specify the value to be Icc1 (or ICC2).
1. The conditions shall be as provided in the Electrical
Characteristics Table. This measurement shall use active probe.
2. Assign SW19 to GND and input SG2 into pin 2 only. When this is
the case, specify the output amplitude of T.P.35 to be VOR1.
In the same manner, specify the output to be VOR2 with SG4
input.
VDC1, VDC2 Output DC voltage 1, output DC voltage 2
When SW19 is assigned to GND (or OPEN), and no signal is input,
measure T.P.35 (T.P.30, T.P.27) output DC voltage. Specify the
voltage to be VDC1 (or VDC2).
3. In this case, calculate frequency characteristics FC1 by the
following formula:
VOR2
VOR1
[VP-P]
[VP-P]
(dB)
FC1 = 20LOG
VDC3, VDC4, Output DC voltage 3, output DC voltage 4
Measure the output DC voltage of T.P.25 in the same manner as in
VDC1 and VDC2, and specify the voltage to be VDC3 (VDC4).
5
7
4. In response to inputs into pin
and pin
only, find frequency
characteristics Fc1 in the same manner.
5. Calculate the difference in frequency characteristics between
channels to find relative frequency characteristics∆Fc1.
Vimax1, Vimax2, maximum allowable input 1, maximum
allowable input 2
6. Assign SW19 to OPEN. In the same manner, find FC2 and ∆FC2.
2
Assign SW19 to GND and input SG1 into pin
only. Gradually
increasing the SG1 amplitude, read the amplitude of the input
signal when the output waveform of T.P.35 is strained. The value is
specified to be Vimax1. In the same manner, measure Vimax 1 in
FC3, FC4 Frequency characteristics 3, frequency
characteristics 4 (250 MHz)
In the same manner as finding FC1, ∆FC1, FC2 and∆FC2, find FC3
and FC4 in response to input signal SG5.
5
7
response to inputs into pin
and pin
only.
Then assign SW19 to OPEN, measure the values at inputs into pins
C.T.I.1 Crosstalk 1 between 2 inputs
11
13
16
,
, and
only. Then specify the values to be Vimax2.
C.T.I.2 Crosstalk 2 between 2 inputs (10 MHz)
1. The conditions shall be as provided in the Electrical
Characteristics Table. This measurement shall take active probe.
2
GV1,∆GV1, voltage gain 1, relative voltage gain 1
GV2, ∆GV2, voltage gain 2, relative voltage gain 2
1. The conditions shall be as provided in the Electrical
Characteristics Table.
2. Assign SW19 to GND and input SG3 into pin
only. Measure
the output amplitude of T.P.35 at that time and specify the value
to be VOR3.
2. Assign SW19 to GND and input SG2 into pin 2 only. When this is
the case, read the amplitude of T.P.35 output and specify the
value as VOR1.
3. Assign SW19 to ONPEN, measure the output amplitude of T.P.35
at that time and specify the value to be VOR3'.
4. When this is the case, calculate crosstalk C.T.L1 between 2
inputs by the following formula:
3. Calculate voltage gain GV1 by the following formula:
VOR1
[VP-P]
[VP-P]
VOR3’
VOR3
[VP-P]
[VP-P]
(dB)
GV1=20LOG
(dB)
C.T.I.1 = 20LOG
0.7
5. In the same manner, find crosstalk between 2 inputs in response
4. In the same manner, find voltage gain GV1 in response to inputs
5
7
5
7
to inputs into pin
and pin
only.
into pin
and pin
only.
11
5. Calculate the difference in voltage gain between channels to find
relative voltage gain ∆GV1.
6. Assign SW19 to OPEN and then input SG3 into pin
only.
Measure the output amplitude of T.P.35 at that time and specify
the value to be VOR4'.
6. In the same manner, find GV2 and ∆GV2.
7. Assign SW19 to GND and then measure the output amplitude of
T.P.35 at that time. Specify the value to be VOR4'.
GV3, ∆GV4 Voltage gain 3, voltage gain 4
1. The conditions shall be as provided in the Electrical
Characteristics Table.
4
MITSUBISHI ICs (Monitor)
M52348FP
WIDE FREQUENCY BAND ANALOG SWITCH
8. When this is the case, calculate crosstalk C.T.I.2 between 2
inputs by the following formula:
2. With active probe, measure rising Tri and falling Tfi for 10% to
90% of the input pulse.
3. With active probe, measure rising Tro and falling Tfo for 10% to
90% of the output pulse.
VOR4’
VOR4
[VP-P]
[VP-P]
(dB)
C.T.I.2 = 20LOG
4. The pulse characteristics Tr1 and Tf1 (Tr2 and Tf2) are as follows:
9. As in the same manner, find crosstalk between 2 pints in
100%
90%
13
16
response to input into pin
and pin
only.
10%
0%
C.T.I.3 Crosstalk 3 between 2 inputs
Tr
Tf
C.T.I.4 Crosstalk 4 between 2 inputs (100 MHz)
Specify input signal to be SG4. In the same manner as in C.T.I.1
and C.T.I.2, find crosstalk C.T.I.3/C.T.I.4 between 2 inputs.
2
2
(nsec)
(nsec)
Tr1(Tr2) =
Tf1(Tf2) =
(Tro) - (Tri)
2
2
(Tfo) - (Tfi)
C.T.C.1 Crosstalk 1 between channels
C.T.C.2 Crosstalk 2 between channels (10 MHz)
1. The conditions shall be as provided in the Electrical
Characteristics Table. This measurement shall take active probe.
2
VOH1, VOH2 High-level output voltage 1 and high-level output
voltage 2
The conditions shall be as provided in the Electrical Characteristics
2. Assign SW19 to GND and input signal SG3 into pin
only.
Table. Assign SW19 to GND (or OPEN), apply 5V to the input pin
and measure the output voltage. Specify the value to be VOH1
(VOH2).
Specify the output amplitude of T.P.35 to be VOR5 at that time.
3. In the same status, measure the output amplitude of T.P.30 and
T.P.27and specify the values to be VOG5 and VOB5.
4. When this is the case, calculate crosstalk C.T.C1 between
channels by the following formula:
VOL1, VOL2 Low-level output voltage 1 and low-level output
voltage 2
The conditions shall be as provided in the Electrical Characteristics
VOG5 or VOB5 [VP-P]
(dB)
C.T.C.1 = 20LOG
Table. Assign SW19 to GND (or OPEN), apply 0V to the input pin
and measure the output voltage. Specify the value to be VOL1
(VOL2).
VOR5
[VP-P]
5. In the same manner, find crosstalk between channels in
5
7
response to inputs into pin
and pin
only.
Vith1 Input threshold voltage 1
11
6. Assign SW19 to OPEN and then input signal SG3 into pin
Vith2 Input threshold voltage 2
only. Specify the output amplitude of T.P.35 to be VOR6 at that
time.
The conditions shall be as provided in the Electrical Characteristics
Table. Assign SW19 to GND (or OPEN). Gradually increasing the
voltage of input pin from 0V, measure the input voltage when the
output voltage is Hi (4.5V or more). Specify the value to be Vith1
(Vith2).
7. In the same status, measure the output amplitude of T.P.30 and
T.P.27. Specify the values to be VOG6 and VOB6.
8. When this is the case, calculate crosstalk C.T.C.2 between
channels by the following formula:
VOG6 or VOB6 [VP-P]
Trd1,Trd2 Rising delay time 1 and rising delay time 2
Tfd1,Tfd2 Falling delay time 1 and falling delay time 2
The conditions shall be as provided in the Electrical Characteristics
Table. Assign SW19 to GND (or OPEN), input SG7 into the input
pin and measure the output waveform.
(dB)
C.T.C.2 = 20LOG
VOR6
[VP-P]
9. As in the same manner, find crosstalk between channels in
13
16
response to inputs into pin
and pin
only.
Rising delay time Trd1 (Trd2) and falling delay time Tfd1 (Tfd2) shall
be found according to the following diagram.
C.T.C.3 Crosstalk 3 between channels
C.T.C.4 Crosstalk 4 between channels (100 MHz)
Specify input signal to be SG4. In the same manner as in C.T.C.1
and C.T.C.2, find crosstalk C.T.C.3/C.T.C.4 between 2 channels.
50%
SG7
Tr1,Tf1,Tr2,Tf2 Pulse characteristics 1
Tfd
Trd
and pulse characteristics 2
50%
1. The conditions shall be as provided in the Electrical
Characteristics Table. Assign SW19 to GND (or OPEN).
OOO
5
MITSUBISHI ICs (Monitor)
M52348FP
WIDE FREQUENCY BAND ANALOG SWITCH
Vsth1 Switching threshold voltage 1
TYPICAL CHARACTERISTICS
Vsth2 Switching threshold voltage 2
THERMAL DERATING (MAXIMUM RATING)
1. The conditions shall be as provided in the Electrical
1250
2
5
7
Characteristics Table. Input SG7 into pins
,
and . Input
8
9
SG7 into pins
and . Do not input signal into other pins.
1068
1000
19
2. Apply a voltage of 0V to pin
and check each of TP21, TP22,
TP25, TP27, TP30 and TP35 for output of signal.
750
19
3. Gradually increasing the voltage at pin , specify the output at
19
pin
to be Vsth1 when the signal is not output from the above
500
250
pins.
11
13
16
4. As in the same manner, input SG1 into pins
,
and
and
17
18
input SG7 into pins
pins.
and
.
Do not input signal into other
19
5. Apply a voltage of 5V to pin
and check each of TP21, TP22,
-20
0
25
50
75 85 100
125
150
TP25, TP27, TP30 and TP35 for output of signal.
AMBIENT TEMPERATURE Ta (˚C)
19
6. Gradually decreasing the voltage at pin , specify the output at
19
pin
to be Vsth2 when the signal is not output from the above
pins.
INPUT SIGNAL
SG No.
signals
Sine wave (f=60 kHz, 0.7VP-P, amplitude variable)
SG1
0.7VP-P
(Amplitude variable)
SG2
SG3
SG4
SG5
Sine wave (f=1 MHz, amplitude 0.7VP-P)
Sine wave (f=10 MHz, amplitude 0.7VP-P)
Sine wave (f=100 MHz, amplitude 0.7VP-P)
Sine wave (f=250 MHz, amplitude 0.7VP-P)
Pulse of 0.7VP-P in amplitude
(f=60kHz, duty 80%)
SG6
SG7
0.7VP-P
Square wave
(Amplitude 5.0 VO-P TTL, f=60 kHz, duty = 50%)
5V
0V
6
MITSUBISHI ICs (Monitor)
M52348FP
WIDE FREQUENCY BAND ANALOG SWITCH
TEST CIRCUIT
0.01µ
0.01µ
0.01µ
TP2
0.01µ
0.01µ
Units Reslstance : Ω
Capacitance : F
7
MITSUBISHI ICs (Monitor)
M52348FP
WIDE FREQUENCY BAND ANALOG SWITCH
DESCRIPTION OF PIN
DC voltage
Pin No.
Name
Peripheral circuit of pins
Description of function
(V)
1
3
6
VCC1(R)
VCC1(G)
VCC1(B)
5.0
Input at low impedance.
2
5
7
INPUT1(R)
INPUT1(G)
INPUT1(B)
2.0
1.0mA
Input pulse of 3V or more and 5V or less.
8
9
INPUT1(H)
INPUT1(V)
-
3 to 5V
0V
0.2mA
10 20
12 26
15 29
34
GND
GND
Input at low impedance.
11
13
16
INPUT2(R)
INPUT2(G)
INPUT2(B)
2.0
1.0mA
8
MITSUBISHI ICs (Monitor)
M52348FP
WIDE FREQUENCY BAND ANALOG SWITCH
DESCRIPTION OF PIN (cont.)
DC voltage
Pin No.
Name
Peripheral circuit of pins
Description of function
(V)
Input pulse of 3V or more and 5V or less.
3 to 5V
17
18
INPUT2(H)
INPUT2(V)
-
0V
0.2mA
Enables switching between OPEN and
GND.
7.3kΩ
19
SWITCH
2.6
2.3V
Contains output resistance.
21
22
OUTPUT(V)
OUTPUT(H)
-
VCC1(R)
(H,V,SWITCH)
Apply the same voltage.
24
5.0
-
4
14 23
32 33
NC
Contains output resistance.
25
OUTPUT
(SYNC ONG)
OUTPUT(B)
OUTPUT(G)
OUTPUT(R)
1.5
2.2
27
30
35
50Ω
50Ω
25
430
35
27 30
,
,
Ω
500Ω
28
31
36
VCC2(B)
VCC2(G)
VCC2(R)
5.0
9
MITSUBISHI ICs (Monitor)
M52348FP
WIDE FREQUENCY BAND ANALOG SWITCH
CAUTIONS FOR USING THE IC
CAUTIONS FOR MANUFACTURING BOARDS
1. Standard video inputs for R, G and B are specified to be 0.7 VP-P.
2. The H and V inputs are specified to be 5.0 VTTL.
3. Input signals into input pins at fully lowered impedance.
Built-in wide band analog switch may cause oscillation due to the
wiring shape on the board. Be careful for the following points.
• When inserting an output pull-down resistance, make wire
between the output pin and the resistance as short as possible.
• Make the load capacitance of output pins as small as possible.
21
22
4. The H and V output pins (pins
and ) are as shown in Figure
1. Resistance can be inserted into a portion between power
supplies to improve the rising speed. However, set the R value
to limit the current to 7.5 mA or less. In Figure 1, R is 2 kΩ or
more.
• Install the Vcc-GND bus controller capacitance near the pin.
• Vcc shall use a stable power supply. (Individual Vcc should use
an independent power supply.)
• Insertion of a resistance of several tens of Ω between the output
pin and the circuit at the next stage makes oscillation harder.
• GND should be as wide as possible. Basically, solid earth should
be used.
5V
5V
R
1kΩ
I=7.5 mA or less
Fig. 1
27 30
,
35
5. The R, G and B output pins (pins
and ) are as shown in
Figure 2. Pull-down resistance can be added to between GNDs
according to the driving capability. However, set the R value to
limit current I to 10 mA or less. In Figure 2, R is 500Ω or more.
5V
I=10 mA or less
50Ω
430kΩ
R
Fig. 2
19
6. The switch (pin ) can be switched with GND and OPEN.
GND: Outputs signal from the INPUT 1 side.
OPEN: Outputs signal from the INPUT 2 side.
For switching by applying voltage as shown in Figure 3;
0 to 0.5V: Outputs signal from INPUT 1 side.
2 to 5V: Outputs signal from INPUT 2 side.
The applied voltage shall be less than Vcc.
19
Fig. 3
10
MITSUBISHI ICs (Monitor)
M52348FP
WIDE FREQUENCY BAND ANALOG SWITCH
Pin configuration comparing of M52348FP and M52348SP
M52348FP is different from M52348SP in pin configuration,
but function characteristic is same.
OUTPUT
(Sync on G)
OUTPUT(R)
VCC2(R) GND
36 34
NC
33
VCC2(G)
GND
29
OUTPUT(B)
VCC2(B) GND
28 26
NC
OUTPUT(V)
GND
20
SWITCH
NC
32
OUTPUT(G)
VCC
OUTPUT(H)
35
31
30
27
25
24
21
23
20
22
21
19
32
31
30
29
28
27
26
25
24
23
22
NC
19
18
17
1
2
2
3
3
4
5
5
6
7
8
9
9
10
11
12
13
13
14
15
15
16
17
1
4
6
7
8
10
11
12
14
16
18
INPUT1(R)
NC
VCC1(B)
INPUT1(H)
GND
GND
NC
INPUT2(B)
INPUT2(V)
VCC1(R)
VCC1(G)
INPUT1(G)
INPUT1(V)
INPUT2(G)
INPUT1(B)
INPUT2(R)
GND
INPUT2(H)
Outside package
M52348FP : 36P2R - D
M52348SP : 32P4B
11
相关型号:
©2020 ICPDF网 联系我们和版权申明