Datasheet PC935, PC930, PC931, PC932, PC933 Datasheet (Sharp)

PC930 Series

PC930 Series

Digital Output, High Sensitivity
Type OPIC Photocoupler

■ Features

1. High sensitivity
(I

FLH

, I

FHL

: MAX. 1mA

)

2. TTL and LSTTL compatible output

3. Operating supply voltage range
(VCC: 4.5 to 15V, PC930/PC931/PC932/PC933

)

4. Various output forms
(Open collector output, pull-up resistor
built-in type, totem pole output

)

5. Low output current dissipation
(I

: MAX. 3.8mA

CCL

)

6. High isolation voltage between input and
output (V

: 5 000V

iso

)

rms

7. Recognized by UL, file No. E64380

■ Model Line-up

Open collector

output type

Pull-up resistor

built-in type

Low active PC930 PC932 PC934
High active PC931 PC933 PC935

Totem pole
output type

■ Applications

1. Computer terminals

2. High speed line receivers

3. Interfaces with various data transmission
equipment

■ Absolute Maximum Ratings

Parameter

Forward current I

*1

Peak forward current I

Input

Reverse voltage V
Power dissipation P 70 mW

PC930/PC931

Supply voltage

PC932/PC933
PC934/PC935

High level output voltage

Output

High level output current

PC930/PC931
PC934/PC935

Low level output current
Power dissipation
Total power dissipation

*2

Isolation voltage V
Operating temperature
Storage temperature

*3

Soldering temperature

Symbol

F

FM

R

V

CC

V

OH

I

OH

I

OL

P

O

P

tot
iso

T

opr

T

stg

T

sol

Rating Unit

20 mA

1A
6V

- 0.5 to 16.0
V

- 0.5 to 7.0

- 0.5 to 16.0

V

- 800 µA

50 mA
150 mW
170 mW

5 000

- 25 to + 85

- 40 to + 125

V

rms

˚C
˚C

260 ˚C

■ Outline Dimensions

456

± 0.5

6.5

Anode

mark

0.5 TYP

* “OPIC ” (Optical IC) is a trademark of the SHARP Corporation.
An OPIC consists of a light-detecting element and signal­ processing circuit integrated onto a single chip.

*1 Pulse width<=100 µs
Duty ratio : 0.001
*2 40 to 60%RH,
AC for 1 minute
*3 For 10 seconds

123

± 0.5

7.12

± 0.5

3.5

± 0.5

3.7

± 0.1

0.5

PC930/PC931 PC932/PC933

123

PC934/PC935

123

Internal connection diagram

456

456

2.54

Amp

Amp

0.9

1.2

Model No.

± 0.2
±0.3

± 0.5

3.35

± 0.25

1 Anode
2 Cathode
3 NC

123

(

7.62

0.26

θ

θ = 0 to 13 ˚

456

Voltage

••••••

regulator

Unit : mm

± 0.3

± 0.1

Amp

4 V
5 GND
6 V

)

θ

O

CC

“ 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.”

PC930 Series

■■ Electro-optical Characteristics

Parameter

Forward voltage

Input

Output

Transfer

charac-

teristics

*4 I

represents forward current when output goes from high to low.

FHL

represents forward current when output goes from low to high.

*5 I

FLH

*6 Hysteresis stands for I

Reverse current I
Terminal capacitance C

Operating
supply
voltage

Low level
output
voltage

High level
output
voltage

High level
output
current

Low level
supply
current

High level
supply
current

Output short
circuit current

*4

“ High→

Low” Thre­shold input
current

*5

“ Low→

High” Thre­shold input
current

PC930/PC931
PC932/PC933

PC934/PC935
PC930/PC932
PC931/PC933
PC934
PC935
PC932
PC933 V
PC934
PC935
PC930

PC930

PC932/PC934
PC933/PC935

PC930/PC932
PC934
PC931/PC933
PC935

PC934
PC935

PC930/PC932
PC934
PC931/PC933
PC935
PC930/PC932
PC934
PC931/PC933
PC935
PC930/PC932

*6

Hysteresis

PC934
PC931/PC933
PC935

Isolation resistance

Fall time

PC930/PC932
PC934

PC931/PC933
PC935

PC930/PC932
PC934

PC931/PC933
PC935

“ High→Low”

propagation

delay time

“ Low→High”

propagation

delay time

Response time

Rise time t

.

FLH/IFHL

(

Ta= 0 to + 70˚C unless otherwise specified.

Symbol Conditions

IF= 2mA

V

F

= 0.1mA

I

F

Ta= 25˚C, VR=3V

R

Ta= 25˚C, V= 0, f= 1kHz

t

V

CC

-

IOL= 16mA, VCC= 5V, IF= 1mA
IOL= 16mA, VCC= 5V, IF=0

V

OL

IOL= 16mA, VCC= 4.5V, IF= 1mA
IOL= 16mA, VCC= 4.5V, IF=0
VCC= 5V, IF=0

= 5V, IF= 1mA

V

CC

OH

VCC= 4.5V, IF= 0, IOH= - 400µA
VCC= 4.5V, IF= 1mA, IOH= - 400 µ A
VCC=VO= 15V, IF=0

I

OH

V

CC=VO

= 15V, IF= 1mAPC931

VCC= 5V, IF= 1mA

CCL

CC

= 5V, IF= 1mA

V

CC

= 5V, IF=0

V

CC

I

= 5V, IF=0PC931

V

VCC= 5V, IF=0

I

CCH

I

OS

I

FHLVCC

I

FLHVCC

I

FLH/IFHL

I

FHL/IFLH

R

ISO

t

PHL

t

PLH

= 5V, IF= 1mA

V

CC

VCC= 5V, IF= 0, T= Within 1 second

= 5V, IF= 1mA, T= Within 1 second

V

CC

= 5V, RL= 280Ω

= 5V, RL= 280Ω

VCC= 5V, RL= 280Ω

Ta = 25˚C, DC500V, 40 to 60% RH

Ta= 25˚C

=5V

V

CC

= 1mA

I

F

= 280Ω

R

L

Fig.1

t

f

r

MIN. TYP. MAX. Unit

- 1.1 1.4 V

0.55 0.95 - V

--10µA

- 30 250 pF

4.5 - 15 V

4.5 5.5 V

- 0.15 0.4 V

3.5 - - V

2.4 - - V

- - 100

- - 100

µA

- 1.3 3.4 mA

- 1.3 3.4 mA

- 1.7 3.8 mA

- 1.7 3.8 mA

- 0.7 2.2 mA

61735mA

- 0.5 1.0 mA

0.1 0.4 - mA

0.1 0.4 - mA

- 0.5 1.0 mA

- 0.8 - -

10

11

-

-

10

39
515

5x10

-515

- Ω

µs

-39

- 0.05 0.5

- 0.1 0.5

)

■ Recommended Operating Conditions

Parameter

Low level output current

High level
output

PC934/PC935

current
Supply

voltage

PC930/PC931
PC932/PC933

PC934/PC935

Operating temperature

Symbol MIN. TYP. MAX. Unit

I

OL

I

OH

V

CC

- 1.6 16 mA

- - - 400 µA

4.5 5.0 15.0 V

4.5 5.0 5.5 V

T

opr

02570˚C

PC930 Series

Fig. 1 Test Circuit for t

PC930/PC931

= tf=

t

r

0.01µ s
Z

= 50 Ω

O

V

in

47Ω

PC932/PC933

= tf=

t

r

0.01µ s
Z

O

= 50Ω

V

in

47Ω

PC934/PC935

tr= tf=

0.01µ s
Z

O

= 50Ω

V

in

47Ω

Fig. 2 Forward Current vs.

Ambient Temperature

30

25

)

20
mA

(

F

15

PHL

, t

PLH

Amp.

Amp.

Amp.

, tr, t

f

Voltage regulator

Voltage regulator

Voltage regulator

280 Ω

0.01µ F

280Ω

0.01µ F

0.01µ F

5V
V

O

5V
V

O

280Ω

PC930/PC932/PC934

Input

Output

1.5V

t

PHL

t

f

50%

t

PLH

V

OH

90%

10%

V

OL

t

r

PC931/PC933/PC935

Input

t

PLH

5V

V

O

Output

1.5V

t

r

50%

t

PHL

V

OH

90%

10%

V

OL

t

f

Fig. 3 Power Dissipation vs.

Ambient Temperature

200

P

tot

P

O

)

mW

(

tot

, P

O

170
150

100

10
Forward current I

5

0

- 25 0 25 50 75 10085
Ambient temperature Ta (˚C

50

Power dissipation P

0

-25

0 25507510085

)

Ambient temperature Ta (˚C

)

PC930 Series

Fig. 4 Forward Current vs. Forward Voltage

500

200
100

)
mA

(

F

Forward current I

Ta= 75˚C

50˚C

50

20
10

5

2
1

0.5 1.0 1.5 2.0 2.5 3.0 3.5

0

Forward voltage V

25˚C

0˚C

- 25˚C

F

(V

)

Fig. 5-b Relative Threshold Input Current

vs. Supply Voltage

1.4

1.2

1 I

2 I

FHL

I

FLH

FLH

I

FHL

1.0

0.8

(PC934
(PC935
(PC934

(PC935

1

2

)
)
)

)

Fig. 5-a Relative Threshold Input Current

vs. Supply Voltage

1.4

1.2

1.0

0.8

Relative threshold input current

0.6

0.4

I

FHL

I

FLH

at V

(

I

PC930/PC932

1

FHL

(

PC931/PC933

I

FLH

(

I

PC930/PC932

2

FLH

(

PC931/PC933

I

FHL

1

2

(PC930/PC932)=1
(PC931/PC933)=1

=5V

CC

)
)
)

)

510 20015

Supply voltage VCC (V

)

Fig. 6 Relative Threshold Input Current vs.

Ambient Temperature

2.0
1 I

(PC930/PC932/PC934

FHL

(PC931/PC933/PC935

I

FLH

(PC930/PC932/PC934

2 I

FLH

(PC931/PC933/PC935

I

FHL

1.5

VCC=5V

1.0

)
)
)
)

1

2

Relative threshold input current

0.6

0.4
45 836

Supply voltage V

I

(PC934)=1

FHL

I

(PC935)=1

FLH

at V

CC

CC

=5V

(V

7

)

Fig. 7 Low Level Output Voltage vs.

Low Level Output Current

1.0
VCC= 5V (PC930/PC931

PC932/PC933

V

= 4.5V (PC934/PC935

CC

0.5

)

V

IF= 1mA (PC930/PC932/PC934

(

IF=0 (PC931/PC933/PC935

OL

T

= 25˚C

a

0.2

PC932/PC933

0.1

0.05

Low level output voltage V

0.02

0.01
1

2 5 10 1005020

Low level output current IOL (mA

)

)
)
)

PC930/PC931
PC934/PC935

0.5

Relative threshold input current

0

(PC930/PC932/PC934)=1

I

FHL

I

(PC931/PC933/PC935)=1

FLH

= 25˚C

at T

a

0 25 50 100-25 75

Ambient temperature Ta (˚C

)

Fig. 8 Low Level Output Voltage vs.

Ambient Temperature

= 5V (PC930 /PC931 /PC932 /PC933

V

CC

VCC= 4.5V (PC934/ PC935

= 1mA (PC930/ PC932/ PC934

I

F

)
(

=0 (PC931/ PC933/ PC935

I

V

F

OL

0.2

0.1

Low level output voltage V

0

)

- 25 25 50 100

0

Ambient temperature Ta (˚C

)

)

)

)

IOL= 30mA

16mA

5mA

75

)

PC930 Series

Fig. 9-a Supply Current vs. Supply Voltage Fig. 9-b Supply Current vs. Supply Voltage

(

PC930/PC931

)
(

mA

CC

4

3

2

Ta= - 25˚C

25˚C

25˚C

= -

I

Supply current I

CCH

1

I

CCH

I

CCH

0

0 4 8 12 16 20

T

a

25˚C

85˚C

Supply voltage V

85˚C

(V)

CC

Fig. 9-c Supply Current vs. Supply Voltage

(

4

)

3

mA

(

CC

2

Supply current I

1

0

3

45 7

Supply voltage V

PC934/PC935

T

= - 25˚C

a

25˚C

85˚C

Ta= - 25˚C

25˚C

85˚C

68

(V)

CC

)(

4

)

3

mA

(

CC

I

CCL

I

CCL

I

CCL

2

Supply current I

1

0

0

48 16

Supply voltage V

PC932/PC933

= - 25˚C

T

a

25˚C

85˚C

Ta= - 25˚C

25˚C

85˚C

12 20

(V)

CC

)

I

CCL

I

CCH

Fig.10 Propagation Delay Time vs.

)

I

CCL

I

CCH

Forward Current

20

)

µs

(

15

PLH

, t

PHL

(PC930/PC932/PC934

1 t

PLH

t

(PC931/PC933/PC935

PHL

2 t

(PC930/PC932/PC934

PHL

t

(PC931/PC933/PC935

PLH

10

5

Propagation delay time t

0

5 1015200

Forward current I

F

(mA)

)

VCC=5V

)

R

= 280Ω

L

)

= 25˚C

T

a

)

1

2

Fig.11-a Rise Time, Fall Time vs. Fig.11-b Rise Time, Fall Time vs.

Load Resistance Load Resistance

0.5
VCC=5V

I

=1mA

F

T

= 25˚C

a

0.4

)

µs

(

f

, t

r

0.3

(

PC930/PC931

)

0.5
V

=5V

CC

I

=1mA

F

T

= 25˚C

a

0.4

)

µs

(

f

, t

r

0.3

(

PC932/PC933

)

0.2

Rise time, fall time t

0.1

0

0.2 0.5 1

0.1
Load resistance R

0.2

t

r

Rise time, fall time t

0.1

t

f

1052

(kΩ)

L

0

0.2 0.5 1

0.1
Load resistance R

t

r

t

f

1052

(kΩ)

L

Fig.11-c Rise Time, Fall Time vs.

Resistance Load

0.5

)

0.4

µ s

(

f

, t

r

0.3

0.2

Rise time, fall time t

0.1

=5V

V

CC

I

= 1mA

F

Ta= 25˚C

0

0.2 0.5 1

0.1
Load resistance R

(

PC934/PC935

t

r

t

f

)

(kΩ

L

)

1052

■ Precautions for Use

(1)

It is recommended that a by-pass capacitor of more than 0.01µF is added between V

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 .”

CC

PC930 Series

and