Philips BCV64B Datasheet

DISCRETE SEMICONDUCTORS

DATA SH EET

M3D071

BCV64B

PNP general purpose double
transistor

Product specification
Supersedes data of 1997 Mar 10

1999 May 21

Philips Semiconductors Product specification

PNP general purpose double transistor BCV64B

FEATURES

• Low current (max. 100 mA)

• Low voltage (max. 30 and 6 V).

APPLICATIONS

• General purpose switching and amplification

• For use in Schmitt-trigger applications.

DESCRIPTION

PNP double transistor in a SOT143B plastic package.
NPN complement: BCV63B.

MARKING

TYPE NUMBER MARKING CODE

BCV64B C96

PINNING

PIN DESCRIPTION

1 collector TR2 and base TR1
2 collector TR1
3 emitter TR1 and TR2
4 base TR2

handbook, halfpage

4

Top view

3

12

21

TR1

TR2

34

MAM291

Fig.1 Simplified outline (SOT143B) and symbol.

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

TR1 −−30 V
TR2 −−6V

V

CEO

collector-emitter voltage open base

TR1 −−30 V
TR2 −−6V

V

EBO

I

C

I

CM

I

B

P

tot

T

stg

T

j

T

amb

emitter-base voltage open collector −−6V
collector current (DC) −−100 mA
peak collector current −−200 mA
base current (DC) −−100 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 a printed-circuit board.

1999 May 21 2

Philips Semiconductors Product specification

PNP general purpose double transistor BCV64B

THERMAL CHARACTERISTICS

SYMBOL PARAMETER CONDITIONS VALUE UNIT

R

th j-a

Note

1. Transistor mounted on a printed-circuit board.

CHARACTERISTICS

=25°C unless otherwise specified.

T

j

SYMBOL PARAMETER CONDITIONS MIN. TYP. MAX. UNIT

I

CBO

h

FE

V

CEsat

V

BEsat

V

BE

C

c

f

T

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

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

I

= 0; VCB= −30 V; Tj= 150 °C −−−5µA

E

DC current gain

TR1 I
TR2 I

= −2 mA; VCE= −5 V 220 − 475

C

= −2 mA; VCE= −700 mV; note 1 220 − 475

C

collector-emitter saturation voltage IC= −10 mA; IB= −0.5 mA −−75 −300 mV
collector-emitter saturation voltage I

= −100 mA; IB= −5mA

C

TR1 −−250 −650 mV

TR2 −−250 − mV
base-emitter saturation voltage IC= −10 mA; IB= −0.5 mA; note 2 −−700 − mV
base-emitter saturation voltage I

= −100 mA; IB= −5 mA; note 2

C

TR1 −−850 − mV
base-emitter voltage

TR1 I

TR1 I

TR2 I

= −2 mA; VCE= −5 V; note 3 −600 −650 −750 mV

C

= −10 mA; VCE= −5 V; note 3 −−−820 mV

C

= −2 mA; VCE= −700 mV; note 3 −−700 − mV

C

collector capacitance IE=ie= 0; VCB= −10 V; f = 1 MHz

TR1 − 4 − pF
transition frequency IC= −10 mA; VCE= −5V;

TR1 100 −−MHz

f = 100 MHz

Notes

1. Group selection will be done on TR1. Due to matched dies, h

2. V

decreases by approximately 1.7 mV/K with increasing temperature.

BEsat

values for TR2 are the same as for TR1.

FE

3. VBE decreases by approximately −2 mV/K with increasing temperature.

1999 May 21 3