PC400
PC400
Compact, Surface Mount Type
OPIC Photocoupler
■ Features
■ Outline Dimensions
1. Mini-flat package
2. “ Low ” output during light emission
3. Isolation voltage between input and output
( Viso : 3 750V rms )
4. TTL and LSTTL compatible output
5. Recognized by UL(No.E64380)
5
4
Voltage regulator
PC400
4.4 ± 0.2
2.54 ± 0.25
1. Hybrid substrate which requires high density mounting
2. Personal computers, office computers and
peripheral equipment
3. Electronic musical instruments
6
1
3
0.1 ± 0.1 2.6 ± 0.2
C0.4
( Input Side)
0.5 +- 0.4
0.2
Diameter of reel
Tape width
Taping package
( Net:3 000pcs. )
φ 370mm
12mm
PC400T
Taping package
( Net: 750pcs. )
φ 178mm
12mm
PC400Z
Sleeve package
( Net: 100pcs. )
-
-
■ Absolute Maximum Ratings
Output
7.0 +- 0.2
0.7
4 Vo
5 GND
6 Vcc
* “ OPIC ” ( Optical IC ) is a trademark of the SHARP Corporation.
An OPIC consists of a light-detecting element and signalprocessing circuit integrated onto a single chip.
( Ta = 25˚C )
Symbol
IF
VR
P
V CC
V OH
I OL
PO
P tot
V iso
T opr
T stg
T sol
Rating
50
6
70
16
16
50
130
150
3 750
- 25 to + 85
- 40 to + 125
260
Unit
mA
V
mW
V
V
mA
mW
mW
V rms
˚C
˚C
˚C
0.2mm or more
Input
5.3 ± 0.3
6˚
1 Anode
2 NC
3 Cathode
PC400
4
Amp.
0.4 ± 0.1
1
3
3.6 ± 0.3
■ Package Specifications
5
0.2 ± 0.05
■ Applications
Parameter
Forward current
Reverse voltage
Power dissipation
Supply voltage
High level output voltege
Low level output current
Power dissipation
Total power dissipation
*1
Isolation voltege
Operating temperature
Storage temperature
*2
Soldering temperature
Internal connection
diagram
1.27 ± 0.25
6
Anode mark
Model No. Package specifications
( Unit : mm )
Soldering area
*1 AC for 1 minute, 40 to 60% RH
*2 For 10 seconds
“ In the absence of confirmation by device specification sheets, SHARP takes no responsibility for any defects that occur in equipment using any of SHARP's devices, shown in catalogs,
data books, etc. Contact SHARP in order to obtain the latest version of the device specification sheets before using any SHARP's device.”
PC400
■ Electro-optical Characteristics
Parameter
Input
Symbol
Forward voltage
VF
Reverse current
IR
Terminal capacitance
Ct
Operating supply voltage
*4
V OL
High level output current
Low level supply current
High level supply current
I OH
I CCL
I CCH
“ H→L ” threshold
input current
I FHL
“ L→H ” threshold
input current
I FLH
*5
Hysteresis
I FLH /I FHL
Isolation resistance
*6
Response
time
Transfer
characteristics
Conditions
I F = 4mA
I F = 0.3mA
Ta = 25˚C, V R = 3V
Ta = 25˚C, V = 0
f = 1kHz
MIN.
R ISO
I OL = 16mA, V CC = 5V
I F = 4mA
V CC = V O = 15V, I F = 0
V CC = 5V, I F = 4mA
V CC = 5V, I F = 0
Ta = 25˚C,V CC = 5V
R L = 280Ω
V CC = 5V,R L = 280Ω
Ta = 25˚C,V CC = 5V
R L = 280Ω
V CC = 5V,R L = 280Ω
V CC = 5V,R L = 280Ω
Ta = 25˚C, DC500V
40 to 60% RH
TYP.
MAX.
1.1
1.0
-
1.4
10
µA
-
30
250
pF
3
-
15
V
-
0.2
0.4
V
-
-
100
µA
-
2.5
5.0
mA
-
1.0
5.0
mA
-
1.1
2.0
-
-
4.0
0.4
0.8
-
0.3
-
-
0.5
0.7
0.9
5 x 1010
1011
-
Ta = 25˚C
-
1
3
“ L→H ” propagation delay
time
t PLH
V CC = 5V,I F = 4 mA
-
2
6
-
0.05
0.5
-
0.1
0.5
R L = 280Ω
mA
Ω
t PHL
tf
tr
V
mA
“ H→L ” propagation delay
time
Fall time
Rise time
Unit
0.7
-
V CC
Low level output voltage
Output
*3
( Ta = 0 to + 70˚C unless otherwise specified )
µs
*3 I FHL represents forward current when output gose from high to low.
*4 I FLH represents forward current when output goes from low to high.
*5 Hysteresis stands for IFLH /I FHL .
*6 Test circuit for response time is shown below.
Voltage
regulator
5V
50%
t r = tf = 0.01 µ S
Z o = 50 Ω
280 Ω
VIN
tPHL
Vo
VIN
Amp
0.1 µ F
tPLH
VOH
90%
Vo
47 Ω
tf
1.5V
10%
VOL
tf
PC400
Fig. 2 Power Dissipation vs.
Ambient Temperature
Fig. 1 Forward Current vs.
Ambient Temperature
200
P tot ( mW )
60
30
20
10
0
- 25
0
25
50
75 85
Ambient temperature T a ( ˚C )
100
50
0
25
50
75
85
100
Fig. 4 Relative Threshold Input Current vs.
Supply Voltage
1.4
T a = 25˚C
I FHL = 1 at V CC = 5V
T a = 75˚C
50˚C
200
1.2
25˚C
0˚C
- 25˚C
100
50
Relative threshold input current
( mA )
130
Ambient temperature Ta ( ˚C )
500
F
PO
0
- 25
100
Fig. 3 Forward Current vs.
Forward Voltage
Forward current I
P tot
150
O,
40
Power dissipation P
Forward current I F ( mA )
50
20
10
5
I
FHL
1.0
I
FLH
0.8
0.6
0.4
2
1
0.2
0
0.5
1.0
1.5
2.0
2.5
Forward voltage V F ( V )
3.0
0
Fig. 5 Relative Threshold Input Current vs.
Ambient Temperature
1.0
VCC = 5V
V CC = 5V
Low level output voltage V OL ( V )
1.4
Relative threshold input current
20
Fig. 6 Low Level Output Voltage vs.
Low Level Output Current
1.6
1.2
I
1.0
FHL
0.8
I
FLH
0.6
0.4
0.2
- 25
5
10
15
Supply voltage V CC ( V )
0.5
I F = 4mA
T a = 25˚C
0.2
0.1
0.05
0.02
I FHL = 1 at T a = 25˚C
0
25
50
75
Ambient temperature T a ( ˚C )
100
0.01
1
2
5
10
20
50
Low level output current I OL ( mA )
100
PC400
Fig. 8 Supply Current vs.
Supply Voltage
Fig. 7 Low Level Output Voltage vs.
Ambient Temperature
9
VCC = 5V
I F = 4mA
I OL = 30mA
8
0.4
I CCL
7
Supply current Icc ( mA )
Low level output voltage V OL ( V )
0.5
0.3
16mA
0.2
5mA
25˚C
6
5
4
I CCL 85˚C
T a = - 25˚C
3
I CCH
2
0.1
0
- 25
25
75
50
Ambient temperature T
a
100
1
5
7
9
11
Supply voltage V
CC
13
15
17
10
20
(V)
Fig.10 Rise Time, Fall Time vs.
Load Resistance
0.5
VCC = 5V
RL = 280Ω
T a = 25˚C
4
3
( ˚C )
Fig. 9 Propagation Delay Time vs.
Forward Current
5
85˚C
- 25˚C
0
0
25˚C
I CCH
1
0.4
VCC = 5V
I F = 4mA
T a = 25˚C
Rise time,fall time ( µ s )
Propagation delay time ( µ s )
t PLH
3
2
0.3
0.2
tr
0.1
1
tf
t PHL
0
0
10
20
30
Forward current I
40
F
( mA )
50
60
0
0.1
0.2
0.5
1
2
5
Load resistance RL ( k Ω )
■ Preautions for Use
( 1 ) It is recommended that a by-pass capacitor of more than 0.01 µF be added between VCC and
GND near the device in order to stabilize power supply line.
( 2 ) Handle this product the same as with other integrated circuits against static electricity.
( 3 ) As for other general cautions, refer to the chapter “Precautions for Use ”
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