Datasheet GP1A58HR Datasheet (Sharp)

GP1A58HR

GP1A58HR

OPIC Photointerrupter

■ Features

1. High sensing accuracy (Slit width: 0.5mm

2. PWB mounting type

■ Applications

1. OA equipment such as printers, facsimiles, etc.

2. VCRs

(

0.5

1.27

)

Unit : mm

Voltage regulator

3 V
4 V
5 GND

5.2

C1.0

5-0.45

(

1.27

)

Tolerance

■ Outline Dimensions

)

S

A58

±

0.3

13.7

+

0.2

5.0

-

0.1

1A58HR

2-φ0.7

)

(

)

10.3
1

5

2.5

23

7.5

5-0.4

(2.5)

0.7

-

2

+

0.3

-

0.1

(

1.5

6.5
4

Internal connection

diagram

1

23
1 Anode
2 Cathode

(

Both sides of

detector and

)

emitter

Slit width

3.5

10.0

MIN.

10.0

* Unspecified tolerances
shall be as follows ;

Dimensions(d

d<=6.0 ± 0.1

6.0< d<=18.0 ± 0.2

* ( ): Reference dimensions

)

Amp.

5

15kΩ

4

CC
O

+

0.3

-

0.1

)(

*“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.

■ Absolute Maximum Ratings

(

Ta= 25˚C

)

Paramerter Symbol Rating Unit

Input

Forward currnt I

*1

Peak forward current I
Reverse voltage 6 V

F

FM

V

R

50 mA

1A

Power dissipation P 75 mW
Supply voltage V

Output

Output current I
Power dissipation P
Operating temperature
Storage temperature

*2

Soldering temperature T

*1 Pulse width<= 100µs, 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.”

T
T

- 0.5 to + 17 mA

CC

O

O

opr

stg

sol

- 25 to + 85 ˚C

- 40 to + 100 ˚C

50 mA

250 mW

260 ˚C

GP1A58HR

■ Electro-optical Characteristics

Parameter Symbol Conditions MIN. TYP. MAX. Unit

Input

Forward voltage V
Reverse current I
Operating supply voltage

V

Low level output voltage V

Output

High level output voltage V
Low level supply current V

I

High level supply current I

*1

Transfer
charac­terisitics

"Low→High" threshold input current

*2

Hysteresis

"Low→High"propagation delay time
"High→Low"propagation delay time

Response
time

Rise time t

I

I

FHL/IFLHVCC

t
t

Fall time - 0.05 0.5 µ s

*1 I

represents forward current when output changes from low to high.

FLH

represents forward current when output changes from high to low.

*2 I

FHL

■ Recommended Operating Conditions

Parameter Symbol
Output current I
Forward current I

O

F

Operating temperature range

Ta = 0 to + 70˚C

= 8mA - 1.14 1.4 V

FIF

VR= 3V - - 10.0 µ A

R

- 4.5 - 17.0 V

CC

OLVCC

OHVCC

CCL

CCHVCC

FLHVCC

= 5V, IF= 0mA, IOL= 16mA
= 5V, IF= 8mA 4.9 - - V
= 5V, IF= 0mA - 1.7 3.8 mA

CC

= 5V, IF= 8mA - 0.7 2.2 mA

= 5V - 1.5 8.0 mA

- 0.15 0.4 V

= 5V 0.55 0.75 0.95 -

PLH

VCE= 5V, IF= 8mA

PHL

= 280Ω

R

r

L

t

f

- 3.0 9.0 µ s

- 5.0 15.0 µ s

- 0.1 0.5 µ s

MIN. MAX. Unit

- 16.0 mA

10.0 20.0 mA

(

Ta= 25˚C

)

Fig. 1 Forward Current vs. Ambient

Temperature

60

50
)
mA

40

(

F

30

20
Forward current I

10

0

Ambient temperature Ta (˚C

)

Fig. 2 Output Power Dissipation vs.

Ambient Temperature

300

)

250

mW

(

O

200

150

100

Output power dissipation P

50

100755025085-25 -25 850 25 50 75 100

0

Ambient temperature Ta (˚C

)

GP1A58HR

Fig. 3 Low Level Output Current vs.

Ambient Temperature

60

)

50

mA

(

OL

40

30

20

Low level output current I

10

0

0

0

Ambient temperature Ta (˚C

100755025

85-25

)

Fig. 5 Relative Threshold Input Current vs.

Supply Voltage

1.1
Ta= 25˚C

1.0

0.9

0.8

0.7

Relative threshold input current

0.6

0.5

0 5 10 15 20

I

FLH

I

FHL

I

= 1 at VCC=5V

FLH

Supply voltage VCC (V

)

25

Fig. 7 Low Level Output Voltage vs.

Low Level Output Current

1.0
=5V

V

CC

= 25˚C

T

a

0.5

)
V

(

OL

0.2

Fig. 4 Forward Current vs. Forward Voltage

500

200

)

100

mA

(

50

F

20

10

Forward current I

5

2

1

Ta= 75˚C

50˚C

Forward voltage VF (V

-

25˚C

0˚C
25˚C

32.521.510.50

3.5

)

Fig. 6 Relative Threshold Input Current vs.

Ambient Temperature

V

=5V

1.6

FLH

, I

1.4

FHL

1.2

1.0

0.8

0.6

Relative threshold input current I

0.4

-25

0

25 50 75 100

Ambient temperature T

I

FLH

CC

I

FLH

I

FHL

= 1 at Ta= 25˚C

)

(˚C

a

Fig. 8 Low Level Output Voltage vs.

Ambient Temperature

0.6

)

0.5
V

(

OL

0.4

VCC=5V

0.1

0.05

Low levle output voltage V

0.02

0.01
1 10 1002 5 20 50

Low level output current IOL (mA

0.3

0.2

Low levle output voltage V

0.1

0

)

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

I

OL

= 30mA

16mA

5mA

)

GP1A58HR

Fig. 9 Supply Current vs. Ambient Temperature

3.0

2.5
)
mA

2.0

(

CC

1.5

1.0
Supply current I

0.5

0

-25

0

25 50 75 100

Ambient temperature Ta (˚C

VCC= 17V

10V

VCC= 17V

10V

5V

}

I

}

CCH

5V

)

I

CCL

Fig.11 Rise Time, Fall Time vs.

Load Resistance

0.8

0.7
)

0.6

µ s
(

f

,t

r

0.5

0.4

0.3

0.2

Rise time, fall time t

0.1

0

0.1

0.5 2 5

0.2 1 10
Load resistance RL (kΩ

Ta= 25˚C
V

=5V

CC

= 5mA

I

F

t

r

t

f

)

5020

Fig.10 Propagation Delay Time vs.

Forward Current

12

VCC=5V

= 280Ω

R

)
(

L

= 25˚C

T

a

µ s

10

PHL

,t

8

PLH

6

4

2

Propagation delay time t

0

0

10

Forward current IF (mA

20 30

t

PHL

t

PLH

40 50

Test Circuit for Response Time

t

r=tf

Z

O

I

F

Input

=0.01µ s

=50Ω

=

5mA

Input

Output

47Ω

Voltage regulator

Amp.

50%

t

PLH

t

t

PHL

10%

r

15kΩ

t

)

90%

f

GND

1.5V

V

OH

V

OL

60

+ 5V

280Ω

Output

0.01 µF

■ Precautions for Use

(1)

In order to stabilize power supply line, connect a by-pass capacitor of more than 0.01µF

between Vcc and GND near the device.

(2)

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

Ethyl alcohol, Methyl alcohol, Isopropyl alcohol

(3)

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