Philips BC850, BC849 Datasheet

DISCRETE SEMICONDUCTORS

DATA SH EET

ook, halfpage

M3D088

BC849; BC850

NPN general purpose transistors

Product specification
Supersedes data of 1998 Aug 06

1999 Apr 08

Philips Semiconductors Product specification

NPN general purpose transistors BC849; BC850

FEATURES

• Low current (max. 100 mA)

• Low voltage (max. 45 V).

APPLICATIONS

• General purpose switching and amplification.

DESCRIPTION

NPN transistor in a SOT23 plastic package.
PNP complements: BC859 and BC860.

MARKING

TYPE

NUMBER

MARKING

(1)

CODE

TYPE

NUMBER

MARKING

CODE

BC849B 2B∗ BC850B 2F∗
BC849C 2C∗ BC850C 2G∗

Note

1. ∗ = p : Made in Hong Kong.
∗ = t : Made in Malaysia.

(1)

PINNING

PIN DESCRIPTION

1 base
2 emitter
3 collector

handbook, halfpage

Top view

3

21

MAM255

Fig.1 Simplified outline (SOT23) and symbol.

3

1

2

LIMITING VALUES

In accordance with the Absolute Maximum Rating System (IEC 134).

SYMBOL PARAMETER CONDITIONS MIN. MAX. UNIT

V

CBO

collector-base voltage open emitter

BC849 − 30 V
BC850 − 50 V

V

CEO

collector-emitter voltage open base

BC849 − 30 V
BC850 − 45 V

V

EBO

I

C

I

CM

I

BM

P

tot

T

stg

T

j

T

amb

emitter-base voltage open collector − 5V
collector current (DC) − 100 mA
peak collector current − 200 mA
peak base current − 200 mA
total power dissipation T

≤ 25 °C; note 1 − 250 mW

amb

storage temperature −65 +150 °C
junction temperature − 150 °C
operating ambient temperature −65 +150 °C

Note

1. Transistor mounted on an FR4 printed-circuit board.

1999 Apr 08 2

Philips Semiconductors Product specification

NPN general purpose transistors BC849; BC850

THERMAL CHARACTERISTICS

SYMBOL PARAMETER CONDITIONS VALUE UNIT

R

th j-a

Note

1. Transistor mounted on an FR4 printed-circuit board.

CHARACTERISTICS

=25°C unless otherwise specified.

T

j

SYMBOL PARAMETER CONDITIONS MIN. TYP. MAX. UNIT

I

CBO

I

EBO

h

FE

V

CEsat

V

BEsat

V

BE

C

c

C

e

f

T

F noise figure I

thermal resistance from junction to ambient note 1 500 K/W

collector cut-off current IE= 0; VCB=30V −−15 nA

I

= 0; VCB=30V; Tj= 150 °C −−5µA

E

emitter cut-off current IC= 0; VEB=5V −−100 nA
DC current gain IC=10µA; VCE=5V;

BC849B; BC850B − 240 −

see Figs 2 and 3

BC849C; BC850C − 450 −

DC current gain I

BC849B; BC850B 200 290 450

= 2 mA; VCE=5V;

C

see Figs 2 and 3

BC849C; BC850C 420 520 800

collector-emitter saturation
voltage

IC= 10 mA; IB= 0.5 mA − 90 250 mV
I

= 100 mA; IB=5mA − 200 600 mV

C

base-emitter saturation voltage IC= 10 mA; IB= 0.5 mA; note 1 − 700 − mV

I

= 100 mA; IB= 5 mA; note 1 − 900 − mV

C

base-emitter voltage IC= 2 mA; VCE= 5 V; note 2 580 660 700 mV

I

= 10 mA; VCE= 5 V; note 2 −−770 mV

C

collector capacitance IE=ie= 0; VCB= 10 V; f = 1 MHz − 2.5 − pF
emitter capacitance IC=ic= 0; VEB= 500 mV; f = 1 MHz − 11 − pF
transition frequency IC= 10 mA; VCE= 5 V; f = 100 MHz 100 −−MHz

= 200 µA; VCE=5V; RS=2kΩ;

C

−−4dB

f = 10 Hz to 15.7 kHz

= 200 µA; VCE=5V; RS=2kΩ;

I

C

−−4dB

f = 1 kHz; B = 200 Hz

Notes

1. V

decreases by about 1.7 mV/K with increasing temperature.

BEsat

2. VBE decreases by about 2 mV/K with increasing temperature.

1999 Apr 08 3