Panasonic PNZ109F Datasheet

Phototransistors

PNZ109F

Silicon NPN Phototransistor

For optical control systems

ø4.6±0.15

Unit : mm

Glass window

Features

Flat window design which is suited to optical systems
Built-in filter to cutoff visible light for reducing ambient light noise
Peak sensitivity wavelength matched with infrared light emitting

devices : λ

= 900 nm (typ.)

p

Fast response : tr = 8 µs (typ.)
Long lifetime, high reliability

Absolute Maximum Ratings (Ta = 25˚C)

Parameter Symbol Ratings Unit

Collector to emitter voltage
Collector to base voltage
Emitter to collector voltage
Emitter to base voltage
Collector current I
Collector power dissipation
Operating ambient temperature
Storage temperature T

V

CEO

V

CBO

V

ECO

V

EBO

C

P

C

T

opr
stg

20 V
30 V

3V
5V

30 mA

150 mW

–25 to +85 ˚C

–30 to +100 ˚C

4.5±0.2

12.7 min.

1.0±0.15

1.0±0.2

3

1

2

ø5.75 max.

3-ø0.45±0.05

2.54±0.25

45±3˚

1: Emitter
2: Base
3: Collector

Electro-Optical Characteristics (Ta = 25˚C)

Parameter Symbol Conditions min typ max Unit

Dark current I
Collector photo current I
Peak sensitivity wave length

CEO

CE(L)

λ

Acceptance half angle θ
Rise time t
Fall time t
Collector saturation voltage

*1

Measurements were made using a tungsten lamp (color temperature T = 2856K) as a light source.

*2

Switching time measurement circuit

Sig.IN

50Ω R

V

CC

L

Sig.OUT

V

CE(sat)ICE(L)

(Input pulse)

(Output pulse)

VCE = 10V 0.05 2 µA
VCE = 10V, L = 100 lx
VCE = 10V 900 nm

P

*1

Measured from the optical axis to the half power point

*2

VCC = 10V, I

r

*2

RL = 100Ω 9 µs

f

= 1mA, L = 1000 lx

t

d

t

r

= 1mA 8 µs

CE(L)

*1

td : Delay time

: Rise time (Time required for the collector photo current to

t

90%

r

increase from 10% to 90% of its final value)

10%

: Fall time (Time required for the collector photo current to

t

t

f

f

decrease from 90% to 10% of its initial value)

0.3 mA

40 deg.

0.3 0.6 V

1

Phototransistors PNZ109F

P

— Ta

200

160

(mW)

C

120

80

40

C

Collector power dissipation P

0

0 20406080100

– 20

Ambient temperature Ta (˚C )

I

— Ta

CEO

VCE = 10V

(µA)

CEO

10

2

10

10

1

–1

I

— V

12

CE(L)

10

L = 1000 lx

(mA)

8

CE(L)

6

4

2

Collector photo current I

0

02016812424

900 lx

CE

800 lx

Ta = 25˚C
T = 2856K

700 lx

600 lx

500 lx

400 lx

300 lx

200 lx
100 lx

50 lx
10 lx

3

10

2

(mA)

10

CE(L)

10

1

–1

10

Collector photo current I

–2

10

1

Collector to emitter voltage VCE (V)

Spectral sensitivity characteristics

100

V
Ta = 25˚C

80

60

40

10

(mA)

CE(L)

I

— Ta

CE(L)

VCE = 10V
L = 100 lx
T = 2856K

1

I

CE(L)

10 10

Illuminance L (lx)

= 10V

CE

10

— L

2

VCE = 10V
Ta = 25˚C
T = 2856K

3

4

10

Dark current I

–2

10

–3

10

– 20 0 40 8020 60 100

Ambient temperature Ta (˚C )

Directivity characteristics

0˚ 10˚ 20˚

100

90
80
70
60
50
40
30

Relative sensitivity S (%)

20

Collector photo current I

–1

10

– 40 0 40 80 120

Ambient temperature Ta (˚C )

4

10

30˚

40˚

50˚

60˚
70˚

80˚
90˚

3

10

(µs)

r

2

10

10

Rise time t

1

–1

10

–2

Collector photo current I

Relative sensitivity S (%)

20

0

700 800 900 1000 1100 1200

600

Wavelength λ (nm)

t

— I

r

CE(L)

VCC = 10V
Ta = 25˚C

RL = 1kΩ

500Ω

100Ω

–1

10

10 10

110

CE(L)

2

(mA)

4

10

3

10

(µs)

2

f

10

10

Fall time t

1

–1

10

–2

Collector photo current I

t

— I

f

CE(L)

VCC = 10V
Ta = 25˚C

RL = 1kΩ

500Ω

100Ω

–1

10

10 10

110

CE(L)

2

(mA)

2