English
Language : 

2SD2074 Datasheet, PDF (1/2 Pages) Panasonic Semiconductor – Silicon NPN epitaxial planer type(For low-frequency output amplification)
Transistor
2SD2074
Silicon NPN epitaxial planer type
For low-frequency output amplification
For muting
For DC-DC converter
6.9±0.1
0.7 4.0
Unit: mm
1.05 2.5±0.1
±0.05
(1.45)
0.8
s Features
q Low collector to emitter saturation voltage VCE(sat).
q Low ON resistance Ron.
q High foward current transfer ratio hFE.
q Allowing supply with the radial taping.
s Absolute Maximum Ratings (Ta=25˚C)
0.65 max.
0.45+–00..015
2.5±0.5 2.5±0.5
1
2
3
Parameter
Symbol
Ratings
Unit
Collector to base voltage
VCBO
25
V
Collector to emitter voltage VCEO
20
V
Emitter to base voltage
VEBO
12
V
Peak collector current
ICP
1
A
Collector current
IC
0.5
A
Collector power dissipation PC
1
W
Junction temperature
Tj
150
˚C
Storage temperature
Tstg
–55 ~ +150
˚C
* Printed circuit board: Copper foil area of 1cm2 or more, and the board
thickness of 1.7mm for the collector portion
s Electrical Characteristics (Ta=25˚C)
Note: In addition to the
lead type shown in
the upper figure, the
type as shown in
the lower figure is
also available.
1:Emitter
2:Collector
3:Base
MT2 Type Package
1.2±0.1
0.65
max.
0.45+–00..105
(HW type)
Parameter
Symbol
Conditions
min
typ
max Unit
Collector cutoff current
Collector to base voltage
Collector to emitter voltage
Emitter to base voltage
Forward current transfer ratio
Collector to emitter saturation voltage
Base to emitter saturation voltage
Transition frequency
Collector output capacitance
ON resistanse
ICBO
VCBO
VCEO
VEBO
hFE1*1
hFE2
VCE(sat)
VBE(sat)
fT
Cob
Ron*3
*1hFE1 Rank classification
VCB = 25V, IE = 0
IC = 10µA, IE = 0
100
nA
25
V
IC = 1mA, IB = 0
IE = 10µA, IC = 0
VCE = 2V, IC = 0.5A*2
VCE = 2V, IC = 1A*2
20
V
12
V
200
800
60
IC = 0.5A, IB = 20mA
0.13
0.4
V
IC = 0.5A, IB = 50mA
1.2
V
VCB = 10V, IE = –50mA, f = 200MHz
200
MHz
VCB = 10V, IE = 0, f= 1MHz
10
pF
1.0
Ω
*3Ron Measurement circuit
1kΩ
IB=1mA
*2 Pulse measurement
Rank
hFE1
R
S
T
200 ~ 350 300 ~ 500 400 ~ 800
VB VV VA
Ron=
VB
VA–VB
!1000(Ω)
f=1kHz
V=0.3V
1