Datasheet GP1L53V Datasheet (Sharp)

GP1L53V

GP1L53V

Compact, High Sensing
Accuracy Type
Photointerrupter

■ Features

1. Compact type

2. High sensing accuracy (Slit width: 0.5mm

3. High current transfer ratio
)

(CTR: MIN. 30% at I

= 1mA

F

4. PWB direct mounting type

■ Applications

1. OA equipment such as FDDs, printers,

facsimiles, etc.

2. VCRs

3. Optoelectronic switches

■ Outline Dimensions

)

4

1 Anode
2 Cathode

3.5
(

Both sides of

detector and emitter

10.0

MIN.

10.0

*Unspecified tolerances shall be as follows;

Dimensions(d)Tolerance

6.0< d<=18.0 ± 0.2

*( ): Reference dimensions

7.5

4 - 0.4

1.5

L53

±

0.3

13.7

+ 0.2

5.0

- 0.1

+

0.3

-

0.1

(

)

10.3

1

4

23

(

Unit : mm

Internal connection
diagram

3 Collector
4 Emitter

5.2

)

0.5

Slit width

d<=6.0 ± 0.1

4 - 0.45

23

1

(

2.54

C1.0

)

+ 0.3

- 0.1

)

■ 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 75 mW
Collector-emitter voltage V

Output

Emitter-collector voltage V
Collector current I
Collector power dissipation P
Operating temperature T
Storage temperature T

*2

Soldering temperature T

*1 Pulse width<=100µ s, Duty ratio= 0.01
*2 For 5 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

opr

stg

sol

35 V

6V

40 mA
75 mW

- 25 to + 85 ˚C

- 40 to + 100 ˚C
260 ˚C

GP1L53V

■ Electro-optical Characteristics

Parameter Symbol Conditions MIN. TYP. MAX. Unit

Forward voltage V

Input

Output Collector dark current I

Transfer
charac­teristics

Fig. 1 Forward Current vs.

Ambient Temperature

Peak forward voltage V
Reverse current

Collector Current Ic
Collector-emitter saturation voltage

Rise time t
Fall time t

)
mA

(

F

60

50

40

30

Response time

FIF

FMIFM

I

R

CEOVCE

V

CE(sat

r

f

(

Ta = 25˚C

= 20mA - 1.25 1.4 V

= 0.5A - 3 4 V

VR=3V - - 10 µA

= 10V - - 10

= 1mA, VCE= 2V 0.3 - mA

I

F

)

IF= 2mA, IC= 0.3mA - - 1.0 V
VCE= 2V, IC= 2mA

= 100 Ω

R

L

- 80 400 µ s

- 70 350 µ s

- 6

20

Fig. 2 Collector Power Dissipation vs.

Ambient Temperature

120

)

100

mW

(

C

80
75

60

)

A

20

Forward current I

10

0

- 25 0 25 50 75 85 100
Ambient Temperature Ta (˚C

Fig. 3 Peak Forward Current vs.

Duty Ratio

Pulse width<=100 µs

10

Duty ratio

Ta= 25˚C

-1

2000

)

1000

mA

(

FM

500

200

100

Peak forward current I

50

20

-2

52525

10

40

20

Collector power dissipation P

0

)

- 25 0 25 50 75 85 100
Ambient temperature Ta (˚C

)

Fig. 4 Forward Current vs.

Forward Voltage

500

T

= 75˚C

200

)

100

mA

(

F

50

20
10

Forward current I

5

2

1

1

a

50˚C

0

0.5 1 1.5 2 2.5 3 3.5
Forward voltage V

25˚C

(V

F

0˚C

-

25˚C

)

GP1L53V

Fig. 5 Collector Current vs.

Forward Current

24
22

VCE=2V
Ta= 25˚C

20

)

18

mA

16

(

C

14
12
10

8
6

Collector current I

4
2
0

123450

Forward current I

Fig. 7 Collector Current vs.

Ambient Temperature

4.0

3.5

)

3.0

mA

(

2.5

C

2.0

1.5

1.0

Collector current I

0.5
0

025-25

Ambient temperature T

Fig. 9 Response Time vs.

Load Resistance

1000

V

=2V

CE

I

= 10mA

C

500

T

= 25˚C

a

200

)

100

µs

(

50

20
10

Response time

5

2
1

251

10 20 50 100 200 500 1000

Load resistance R

)

(mA

F

50 10075

(˚C

a

t

t

d

t

s

)

(Ω

L

Fig. 6 Collector Current vs.

Collector-emitter Voltage

22

T

= 25˚C

a

20
18

16

)

mA

14

(

C

12
10

8
6

Collector current I

4
2

0

12 34 50

Collector-emitter voltage V

IF= 2.5mA

2.0mA

1.5mA

1.0mA

0.5mA

)

Pc(MAX.

610987

(V

CE

)

Fig. 8 Collector-emitter Saturation Voltage vs.

Ambient Temperature

1.0

I

= 1mA

F

V

=2V

CE

0.8

0.6

0.4

)

V

(

)

sat

(

0.2

CE

Collector-emitter saturation voltage

V

0

)

025-25

50 10075

Ambient temperature Ta (˚C

)

= 2mA

I

F

I

=

C

0.3mA

Test Circuit for Response Time

r

t

f

Input R

V

CC

R

D

L

Output

Output

Input

10%

t

d

t

r

90%

t

s

t

f

GP1L53V

Fig.10 Frequency Response

VCE=2V
I

= 10mA

C

T

= 25˚C

100Ω

5

)

a

10Ω

5

10

0

)

dB

(

-5

-10

Voltage gain Av

-15

-20

25

RL=

1kΩ

3

10

4

5

222

10

Frequency f (Hz

Fig.12 Relative Collector Current vs.

Shield Distance(1

100

)

%

(

50

)

I

= 1mA, VCE=2V

F

T

= 25˚C Ta= 25˚C

a

Shield

-+

(

Detector center

Fig.11 Collector Dark Current vs.

Ambient Temperature

-4

10

5

V

= 10V

CE

-5

10

)

5

A

(

-6

10

5

CEO

-7

10

5

-8

10

5

-9

10

5

Collector dark current I

-10

10

5

-11

6

5

10

10

- 25 0 25 10050 75
Ambient temperature Ta (˚C

)

Fig.13 Relative Collector Current vs.

Shield Distance (2

L

Detector

0

)

100

)
%

(

50

)

IF= 1mA, VCE=2V

Shield

L

-

Detector

+

(

Detector center

0

)

Relative collector current

0

- 2.5

-2-1.5-1-0.5
Shield distance L (mm

0 0.5 1 1.5 2 2.5

)

Relative collector current

■ Precautions for Use

(1)

In case of cleaning, use only the following type of cleaning solvent.

Ethyl alcohol, Methyl alcohol, Isopropyl alcohol

(2)

As for other general cautions, refer to the chapter“Precautions for Use”.

0

-2 -1 0 1 2
Shield distance L (mm

)