Datasheet PC715V Datasheet (Sharp)

High Sensitivity Type

PC715V

❈ Lead forming type (I type) and taping reel type (P type) are also available. (PC715VI/PC715VP)

..

❈❈ TUV (VDE0884) approved type is also available as an option.

■ Features

1. High current transfer ratio
(CTR : MIN. 600% at IF= 1mA, VCE=2V

2. High isolation voltage between input and
output
(V

: 5 000V

iso

)

rms

3. Recognized by UL, file No. E64380

■ Applications

1. System appliances, measuring instruments

2. Copiers, automatic vending machines

3. Signal transmission between circuits of
different potentials and impedances

)

Photocoupler

■ Outline Dimensions

± 0.2

Anode mark

TYP.

0.5

0.5

0.9

± 0.5

3.5

± 0.5

3.7

± 0.1

6

123

1 Anode
2 Cathode
3 NC

5

PC715V

± 0.5

7.12

2.54

1.2

± 0.25

± 0.3

4

± 0.5

6.5

± 0.5

3.35

(

Internal connection

diagram

65 4

123

7.62

0.26

θ = 0 to 13 ˚

4 Emitter
5 Collector
6 NC

PC715V

Unit : mm

± 0.3

± 0.1

θθ

)

■ Absolute Maximum Ratings

(

Ta= 25˚C

)

Parameter Symbol Rating Unit

Input

Forward current I

*1

Peak forward current I
Reverse voltage V

F

FM

R

50 mA

1A

6V
Power dissipation P 70 mW
Collector-emitter voltage V

Output

Emitter-collector voltage V
Collector current I
Collector power dissipation P
Total power dissipation P

*2

Isolation voltage V
Operating temperature T
Storage temperature T

*3

Soldering temperature T

*1 Pulse width<=100µs, Duty ratio : 0.001
*2 40 to 60%RH, AC for 1 minutes
*3 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.”

CEO

ECO

C

C

tot

iso

opr

stg

sol

35 V

6V

80 mA
150 mW
170 mW

5 000

V

rms

- 25 to + 100 ˚C

- 40 to + 125 ˚C
260 ˚C

PC715V

■ Electro-optical Characteristics

Parameter Symbol Conditions MIN. TYP. MAX. Unit

Forward voltage

Input

Output Collector dark current I

Transfer

charac-

teristics

Fig. 1 Forward Current vs.

Ambient Temperature

)

mA

(

F

Forward current I

Peak forward voltage
Reverse current
Terminal capacitance

Current transfer ratio CTR I
Collector-emitter saturation voltage V
Isolation resistance R
Floating capacitance C
Cut-off frequency f

Response time

60

50

40

20

10

Rise time
Fall time

V

IF= 10mA - 1.2 1.4 V

F

V

FMIFM

I

R

C

t

CEO

CE(sat

ISO

f

C

t

r

t

f

= 0.5A - - 3.0 V
VR=4V - 10 µA
V= 0, f= 1kHz - 30 250 pF
VCE= 10V, IF=0 - - 10

= 1mA, VCE= 2V 600 %

F

)

IF= 20mA, IC= 5mA - - 1.0 V
DC500V, 40 to 60%RH

5x101010

1 600 7 500

11

V= 0, f= 1MHz - 0.6 1.0 pF
VCE= 2V, IC= 2mA, R

= 100Ω , - 3dB

L

VCE= 2V, IC= 10mA, RL= 100Ω

- 6 - kHz

- 60 250 µs

- 53 250 µs

Fig. 2 Collector Power Dissipation vs.

Ambient Temperature

200

)
mW

(

150

C

100

50

Collector power dissipation P

(

Ta= 25˚C

-6

- Ω

)

A

0

-25300 25 50 75 100 125

Ambient temperature T

(˚C)

a

Fig. 3 Peak Forward Current vs. Duty Ratio

10 000

5 000

)

2 000

mA

1 000

(

FM

500
200
100

50

20

Peak forward current I

10

5

-3

2

10

5

5

10

Duty ratio

-2

2

Pulse width <=100µs

Ta= 25˚C

-1

2

10

5

1

5

0

-25

0 125

25 50 75 100

Ambient temperature T

Fig. 4 Forward Current vs.

Forward Voltage

500

200
100

)

50

mA

(

F

20
10

5

Forward current I

1

020.5 1.0 1.5 2.0 2.5 3.0 3.5

= 75˚C

T

a

50˚C

Forward voltage V

(˚C)

a

25˚C

0˚C

- 25˚C

(V)

F

PC715V

Fig. 5 Current Transfer Ratio vs.

Forward Current

2 000
1 800

)

1 600

%

(

1 400
1 200
1 000

800
600

Current transfer ratio CTR

400
200

0

0.1

0.2 0.5 1 2 5 10
Forward current I

F

Fig. 6-b Collector Current vs.

Collector-emitter Voltage

100

90
80

)
mA

(

C

Collector current I

I

= 10mA

F

70
60
50
40
30
20
10

0

0

12345

Collector-emitter voltage VCE (V

5mA

2mA

P

C

( MAX.)

(mA

Ta= 25˚C

VCE=2V

T

)

1mA

)

= 25˚C

a

Fig. 6-a Collector Current vs.

Collector-emitter Voltage

(mA)

C

16

IF= 1mA

14

12

10

0.9mA

0.8mA

0.7mA

(MAX.

0.6mA

P

C

(Ta= 25˚C)

)

8

0.5mA

6

4

Collector current I

2
0

0

12345678910111213

Collector-emitter voltage V

0.4mA

0.3mA

0.2mA0.1mA

)

(V

CE

Fig. 7 Relative Current Transfer Ratio vs.

Ambient Temperature

150

)

%

(

100

50

Relative current transfer ratio

0

0 255075100

-25
Ambient temperature Ta (˚C

IF= 1mA

=2V

V

CE

)

Fig. 8 Collector-emitter Saturation Voltage

vs. Ambient Temperature

1.0

)
V

(

)
sat

(

0.8

CE

0.6

0.4

0.2

Collector emitter saturation voltage V

0

0 255075100

-25
Ambient temperature T

I

F

I

C

a

= 20mA

= 5mA

)

(˚C

Fig. 9 Collector Dark Current vs.

Ambient Temperature

-5

10

5

V

= 10V

CE

-6

10

)

5

A

(

-7

10

CEO

5

-8

10

5

-9

10

5

Collector dark current I

-10

10

5

-11

10

-25

25

0

50 75

Ambient temperature Ta (˚C

100

)

PC715V

Fig.10 Response Time vs. Load Resistance

5

VCE=2V

I

= 10mA

C

2

Ta= 25˚C

3

10

5

)
µs

2

(

2

10

5

2

Response time

10

5

2

0

10

0.1 1 10

Load resistance R

L

t

d

(kΩ)

t

f

t

r

t

s

Test Circuit for Response Time

Input

V

CC

R

D

R

L

Output

Input

Output

t

d

t

Fig.11 Frequency Response

V

CE = 2V

IC= 2mA
Ta= 25˚C

)

0
dB

(

v

RL= 10kΩ

-10

Voltage gain A

-20

0.05 0.1 0.2

1kΩ 100 Ω

1

0.5
Frequency f (kHz

201052

50

100

)

Test Circuit for Frepuency Response

V

CC

R

10%

R

t

r

90%

s

t

r

D

L

Output

●

Please refer to the chapter “Precautions for Use ”.