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2SC3931D [ETC]

TRANSISTOR | BJT | NPN | 20V V(BR)CEO | 15MA I(C) | TO-236 ; 晶体管| BJT | NPN | 20V V( BR ) CEO | 15MA I(C ) | TO- 236\n
2SC3931D
型号: 2SC3931D
厂家: ETC    ETC
描述:

TRANSISTOR | BJT | NPN | 20V V(BR)CEO | 15MA I(C) | TO-236
晶体管| BJT | NPN | 20V V( BR ) CEO | 15MA I(C ) | TO- 236\n

晶体 晶体管 光电二极管 放大器
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Transistor  
2SC3931  
Silicon NPN epitaxial planer type  
For high-frequency amplification  
Unit: mm  
2.1±0.1  
0.425  
1.25±0.1  
0.425  
Features  
Optimum for RF amplification of FM/AM radios.  
1
High transition frequency fT.  
S-Mini type package, allowing downsizing of the equipment and  
3
automatic insertion through the tape packing and the magazine  
packing.  
2
Absolute Maximum Ratings (Ta=25˚C)  
Parameter  
Symbol  
VCBO  
VCEO  
VEBO  
IC  
Ratings  
Unit  
V
Collector to base voltage  
Collector to emitter voltage  
Emitter to base voltage  
Collector current  
30  
0.2±0.1  
20  
V
3
15  
V
1:Base  
mA  
mW  
˚C  
2:Emitter  
3:Collector  
EIAJ:SC–70  
S–Mini Type Package  
Collector power dissipation  
Junction temperature  
Storage temperature  
PC  
150  
Tj  
150  
Marking symbol : U  
Tstg  
–55 ~ +150  
˚C  
Electrical Characteristics (Ta=25˚C)  
Parameter  
Symbol  
VCBO  
Conditions  
min  
30  
3
typ  
max  
260  
1
Unit  
V
Collector to base voltage  
Emitter to base voltage  
Forward current transfer ratio  
Base to emitter voltage  
Transition frequency  
IC = 10µA, IE = 0  
VEBO  
IE = 10µA, IC = 0  
V
*
hFE  
VCB = 6V, IE = –1mA  
65  
VBE  
fT  
VCB = 6V, IE = 1mA  
0.72  
650  
0.8  
24  
V
MHz  
pF  
VCB = 6V, IE = –1mA, f = 200MHz  
VCE = 6V, IC = 1mA, f = 10.7MHz  
VCB = 6V, IE = –1mA, f = 100MHz  
VCB = 6V, IE = –1mA, f = 100MHz  
450  
Common emitter reverse transfer capacitance Cre  
Power gain  
PG  
NF  
dB  
Noise figure  
3.3  
dB  
*hFE Rank classification  
Rank  
hFE  
C
D
65 ~ 160  
UC  
100 ~ 260  
UD  
Marking Symbol  
1
Transistor  
2SC3931  
PC — Ta  
IC — VCE  
IC — IB  
240  
200  
160  
120  
80  
12  
10  
8
12  
10  
8
Ta=25˚C  
IB=100µA  
VCE=6V  
Ta=25˚C  
80µA  
60µA  
6
6
40µA  
20µA  
4
4
40  
2
2
0
0
0
0
20 40 60 80 100 120 140 160  
0
6
12  
18  
0
60  
120  
180  
(
)
( )  
V
(
)
Ambient temperature Ta ˚C  
Collector to emitter voltage VCE  
Base current IB µA  
IC — VBE  
VCE(sat) — IC  
hFE — IC  
30  
25  
20  
15  
10  
5
100  
360  
300  
240  
180  
120  
60  
IC/IB=10  
VCE=6V  
VCE=6V  
30  
10  
25˚C  
Ta=75˚C  
–25˚C  
3
1
Ta=75˚C  
25˚C  
0.3  
0.1  
–25˚C  
Ta=75˚C  
–25˚C  
25˚C  
0.03  
0.01  
0
0
0.1  
0
0.4  
0.8  
1.2  
1.6  
2.0  
0.1  
0.3  
1
3
10  
30  
100  
0.3  
1
3
10  
30  
100  
( )  
V
(
)
(
)
Base to emitter voltage VBE  
Collector current IC mA  
Collector current IC mA  
fT — IE  
Zrb — IE  
Cre — VCE  
1200  
1000  
800  
600  
400  
200  
0
120  
100  
80  
60  
40  
20  
0
2.4  
VCB=6V  
f=2MHz  
Ta=25˚C  
IC=1mA  
f=10.7MHz  
Ta=25˚C  
VCB=6V  
Ta=25˚C  
2.0  
1.6  
1.2  
0.8  
0.4  
0
– 0.1 – 0.3  
–1  
–3  
–10 –30 –100  
– 0.1  
– 0.3  
–1  
–3  
–10  
0.1  
0.3  
1
3
10  
30  
100  
(
)
(
)
( )  
Collector to emitter voltage VCE V  
Emitter current IE mA  
Emitter current IE mA  
2
Transistor  
2SC3931  
Cob — VCB  
PG — IE  
NF — IE  
1.2  
1.0  
0.8  
0.6  
0.4  
0.2  
0
40  
35  
30  
25  
20  
15  
10  
5
12  
10  
8
IE=0  
f=1MHz  
Ta=25˚C  
f=100MHz  
Rg=50k  
Ta=25˚C  
f=100MHz  
Rg=50Ω  
Ta=25˚C  
VCE=10V  
6V  
6
4
VCE=6V, 10V  
2
0
0
0
5
10  
15  
20  
25  
30  
– 0.1 – 0.3  
–1  
–3  
–10 –30 –100  
– 0.1 – 0.3  
–1  
–3  
–10 –30 –100  
( )  
V
(
)
(
)
Collector to base voltage VCB  
Emitter current IE mA  
Emitter current IE mA  
bie — gie  
bre — gre  
bfe — gfe  
20  
0
–1  
–2  
–3  
–4  
–5  
–6  
0
–20  
10.7  
58  
yie=gie+jbie  
VCE=10V  
10.7  
25  
150  
100  
– 0.4mA  
yre=gre+jbre  
VCE=10V  
–4mA  
18  
16  
14  
12  
10  
8
–1mA  
150  
100  
–7mA  
–2mA  
–2mA  
–4mA  
–1mA  
100  
58  
–40  
150  
–4mA  
100  
58  
58  
IE=–7mA  
f=150MHz  
–60  
–1mA  
IE=–7mA  
100  
58  
–80  
100  
6
25  
4
25  
–100  
–120  
yfe=gfe+jbfe  
VCE=10V  
2
f=150MHz  
f=10.7MHz  
0
0
3
6
9
12  
15  
– 0.5 – 0.4 – 0.3 – 0.2 – 0.1  
0
0
20  
40  
60  
80  
100  
(
)
(
)
(
)
Input conductance gie mS  
Reverse transfer conductance gre mS  
Forward transfer conductance gfe mS  
boe — goe  
1.2  
1.0  
0.8  
0.6  
0.4  
0.2  
0
150  
–2mA  
–4mA  
100  
–7mA  
58  
25  
yoe=goe+jboe  
VCE=10V  
f=10.7MHz  
0
2
4
6
8
10  
(
)
Output conductance goe mS  
3
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and semiconductors described in this material  
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istics and applied circuit examples of the products. It does not constitute the warranting of industrial  
property, the granting of relative rights, or the granting of any license.  
(3) The products described in this material are intended to be used for standard applications or gen-  
eral electronic equipment (such as office equipment, communications equipment, measuring in-  
struments and household appliances).  
Consult our sales staff in advance for information on the following applications:  
Special applications (such as for airplanes, aerospace, automobiles, traffic control equipment,  
combustion equipment, life support systems and safety devices) in which exceptional quality and  
reliability are required, or if the failure or malfunction of the products may directly jeopardize life or  
harm the human body.  
Any applications other than the standard applications intended.  
(4) The products and product specifications described in this material are subject to change without  
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make sure that the latest specifications satisfy your requirements.  
(5) When designing your equipment, comply with the guaranteed values, in particular those of maxi-  
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2001 MAR  

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