PS9308L2-AX Datasheet PS9308L2-V-E3-AX, PS9308L2-AX, PS9308L-E3-AX | P10-P12

PS9308L, PS9308L2 Chapter Title

R08DS0048EJ0200 Rev.2.00 Page 10 of 20

Sep 27, 2013

TYPICAL CHARACTERISTICS (T

A

= 25°C, unless otherwise specified)

Total Power Dissipation P

T

(mW)

TOTAL POWER DISSIPATION

vs. AMBIENT TEMPERATURE

25 50 75 125

100

25 50 75 125

100

0

300

250

200

150

100

50

0

400

350

300

250

200

150

100

50

5

4

3

2

1

0

−40 −200 20406080100

102 435

35

30

25

20

15

10

5

0

1.0 1.2 1.4 1.6 1.8 2.0 2.2 2.4

0.01

0.1

1

10

100

T

A

= +110°C

+100°C

+85°C

+50°C

+25°C

0°C

−40°C

0.0

−0.5

−1.0

−1.5

−2.0

−2.5

−3.0

V

CC

= 30 V,

V

O

> 5 V,

I

O

= 0 mA

V

CC

= 30 V,

I

F

= 10 mA,

I

O

= −100 mA

V

CC

= 30 V

Ambient Temperature T

A

(°C)Ambient Temperature T

A

(°C)

Detector Power Dissipation P

C

(mW)

DETECTOR POWER DISSIPATION

vs. AMBIENT TEMPERATURE

Forward Voltage V

F

(V)

Forward Current I

F

(mA)

FORWARD CURRENT vs.

FORWARD VOLTAGE

Ambient Temperature T

A

(°C)

Threshold Input Current I

FLH

(mA)

Forward Current I

F

(mA)

Output Voltage V

O

(V)

OUTPUT VOLTAGE vs.

FORWARD CURRENT

Ambient Temperature T

A

(°C)

High Level Output Voltage – Supply Voltage

V

OH

– V

CC

(V)

HIGH LEVEL OUTPUT VOLTAGE − SUPPLY

VOLTAGE vs. AMBIENT TEMPERATURE

THRESHOLD INPUT CURRENT vs.

AMBIENT TEMPERATURE

Remark The graphs indicate nominal characteristics.

<R>

PS9308L, PS9308L2 Chapter Title

R08DS0048EJ0200 Rev.2.00 Page 11 of 20

Sep 27, 2013

T

A

= 25°C

T

A

= 110°C

0.5

0.4

0.3

0.2

0.1

0

−40 −20

0.0 0.5

1.0 1.5 2.0

5.0

4.0

3.0

2.0

1.0

0.0

V

O

= V

CC

−4 V

V

O

= V

CC

−15 V

V

O

= V

EE

+15 V

V

O

= V

EE

+2.5 V

V

CC

= 30 V,

I

F

= 0 mA

V

CC

= 30 V,

I

F

= 10 mA

V

CC

= 30 V,

I

F

= 0 mA,

I

O

= 100mA

V

CC

= 30 V,

V

O

= OPEN

0 20 40 60 80 100

−40 −20

0 20 40 60 80 100

6

5

4

3

2

1

0

2.0

1.5

1.0

0.5

0.0

−40 −20

0 20 40 60 80 100

−40 −20 0 20 40 60 80 100

−2.0 −1.5 −1.0 −0.5

0.0

0

−1

−2

−3

−4

−5

−6

0.0

1.0

2.0

3.0

4.0

−5.0

V

CC

= 30 V,

I

F

= 0 mA

I

CCH

(I

F

= 10 mA)

I

CCL

(I

F

= 0 mA)

V

CC

= 30 V,

I

F

= 10 mA

T

A

= −40°C

T

A

= 110°C

Ambient Temperature T

A

(°C)

High Level Output Current I

OH

(A)

HIGH LEVEL OUTPUT CURRENT vs.

AMBIENT TEMPERATURE

Ambient Temperature T

A

(°C)

Low Level Output Current I

OL

(A)

LOW LEVEL OUTPUT CURRENT vs.

AMBIENT TEMPERATURE

Ambient Temperature T

A

(°C)

Low Level Output Voltage V

OL

(V)

LOW LEVEL OUTPUT VOLTAGE vs.

AMBIENT TEMPERATURE

Ambient Temperature T

A

(°C)

High Level Supply Current I

CCH

(mA)

Low Level Supply Current I

CCL

(mA)

SUPPLY CURRENT vs.

AMBIENT TEMPERATURE

High Level Output Current I

OH

(A)

High Level Output Voltage – Supply Voltage

V

OH

– V

CC

(V)

HIGH LEVEL OUTPUT VOLTAGE − SUPPLY

VOLTAGE vs. HIGH LEVEL OUTPUT CURRENT

Low Level Output Current I

OL

(A)

Low Level Output Voltage V

OL

(V)

LOW LEVEL OUTPUT VOLTAGE vs.

LOW LEVEL OUTPUT CURRENT

T

A

= 25°C

T

A

= −40°C

Remark The graphs indicate nominal characteristics.

PS9308L, PS9308L2 Chapter Title

R08DS0048EJ0200 Rev.2.00 Page 12 of 20

Sep 27, 2013

15 20 3025

2.0

1.5

1.0

0.5

0.0

V

O

= OPEN

I

CCH

(I

F

= 10 mA)

I

CCL

(I

F

= 0 mA)

0−40 −20 20

40 60 80

250

200

150

100

50

0

250

200

150

100

50

0

250

200

150

100

50

0

250

200

150

100

50

0

250

200

150

100

50

0

100

PWD

t

PLH

t

PHL

7101316

V

CC

= 30 V, R

g

= 10 Ω,

C

g

= 10 nF, f = 10 kHz,

Duty Cycle = 50%

I

F

= 10 mA, R

g

= 10 Ω,

C

g

= 10 nF, f = 10 kHz,

Duty Cycle = 50%

PWD

t

PLH

t

PHL

15 20 25 30

PWD

t

PLH

t

PHL

01020

30 40 50

V

CC

= 30 V, I

F

= 10 mA,

R

g

= 10 Ω, f = 10 kHz,

Duty Cycle = 50%

PWD

t

PLH

t

PHL

0 1020304050

V

CC

= 30 V, I

F

= 10 mA,

C

g

= 10 nF, f = 10 kHz,

Duty Cycle = 50%

PWD

t

PLH

t

PHL

Supply Voltage V

CC

(V)

High Level Supply Current I

CCH

(mA)

Low Level Supply Current I

CCL

(mA)

SUPPLY CURRENT vs.

SUPPLY VOLTAGE

Propagation Delay Time t

PHL

, t

PLH

(ns),

PROPAGATION DELAY TIME, PULSE WIDTH

DISTORTION vs. AMBIENT TEMPERATURE

Pulse Width Distortion |t

PHL

−t

PLH

| (ns)

Ambient Temperature T

A

(°C)

Propagation Delay Time t

PHL

, t

PLH

(ns),

PROPAGATION DELAY TIME, PULSE WIDTH

DISTORTION vs. FORWARD CURRENT

PROPAGATION DELAY TIME, PULSE WIDTH

DISTORTION vs. SUPPLY VOLTAGE

Pulse Width Distortion |t

PHL

−t

PLH

| (ns)

Propagation Delay Time t

PHL

, t

PLH

(ns),

Pulse Width Distortion |t

PHL

−t

PLH

| (ns)

Forward Current I

F

(mA) Supply Voltage V

CC

(V)

PROPAGATION DELAY TIME, PULSE WIDTH

DISTORTION vs. LOAD CAPACITANCE

Propagation Delay Time t

PHL

, t

PLH

(ns),

Pulse Width Distortion |t

PHL

−t

PLH

| (ns)

Load Capacitance C

g

(nF)

PROPAGATION DELAY TIME, PULSE WIDTH

DISTORTION vs. LOAD RESISTANCE

Propagation Delay Time t

PHL

, t

PLH

(ns),

Pulse Width Distortion |t

PHL

−t

PLH

| (ns)

Load Resistance R

g

(Ω)

V

CC

= 30 V, I

F

= 10 mA,

R

g

= 10 Ω, C

g

= 10 nF,

f = 10 kHz, Duty cycle = 50%

Remark The graphs indicate nominal characteristics.

PS9308L2-AX

PS9308L2-AX

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