Diotec BC549 General purpose si-epitaxial planar transistor Datasheet

BC546 ... BC549
BC546 ... BC549
General Purpose Si-Epitaxial Planar Transistors
Si-Epitaxial Planar-Transistoren für universellen Einsatz
NPN
NPN
Version 2006-05-31
Power dissipation – Verlustleistung
18
9
16
CBE
2 x 2.54
Dimensions - Maße [mm]
500 mW
Plastic case
Kunststoffgehäuse
TO-92
(10D3)
Weight approx. – Gewicht ca.
0.18 g
Plastic material has UL classification 94V-0
Gehäusematerial UL94V-0 klassifiziert
Standard packaging taped in ammo pack
Standard Lieferform gegurtet in Ammo-Pack
Maximum ratings (TA = 25°C)
Grenzwerte (TA = 25°C)
BC546
BC547
BC548/549
Collector-Emitter-voltage
E-B short
VCES
85 V
50 V
30 V
Collector-Emitter-voltage
B open
VCEO
65 V
45 V
30 V
Collector-Base-voltage
E open
VCBO
80 V
50 V
30 V
Emitter-Base-voltage
C open
VEB0
5V
Power dissipation – Verlustleistung
Ptot
500 mW 1)
Collector current – Kollektorstrom (dc)
IC
100 mA
Peak Collector current – Kollektor-Spitzenstrom
ICM
200 mA
Peak Base current – Basis-Spitzenstrom
IBM
200 mA
- IEM
200 mA
Tj
TS
-55...+150°C
-55…+150°C
Peak Emitter current – Emitter-Spitzenstrom
Junction temperature – Sperrschichttemperatur
Storage temperature – Lagerungstemperatur
Characteristics (Tj = 25°C)
Kennwerte (Tj = 25°C)
Group A
Group B
Group C
DC current gain – Kollektor-Basis-Stromverhältnis 2)
VCE = 5 V, IC = 10 µA
hFE
typ. 90
typ. 150
typ. 270
VCE = 5 V, IC = 2 mA
hFE
110 ... 220
200 ... 450
420 ... 800
VCE = 5 V, IC = 100 mA
hFE
typ. 120
typ. 200
typ. 400
Small signal current gain
Kleinsignal-Stromverstärkung
hfe
typ. 220
typ. 330
typ. 600
Input impedance – Eingangs-Impedanz
hie
1.6 ... 4.5 kΩ
3.2 ...8.5 kΩ
6 ... 15 kΩ
Output admittance – Ausgangs-Leitwert
hoe
18 < 30 µS
30 < 60 µS
60 < 110 µS
Reverser voltage transfer ratio
Spannungsrückwirkung
hre
typ. 1.5*10-4
typ. 2*10-4
typ. 3*10-4
h-Parameters at/bei VCE = 5 V, IC = 2 mA, f = 1 kHz
1
Valid, if leads are kept at ambient temperature at a distance of 2 mm from case
Gültig wenn die Anschlussdrähte in 2 mm Abstand vom Gehäuse auf Umgebungstemperatur gehalten werden
© Diotec Semiconductor AG
http://www.diotec.com/
1
BC546 ... BC549
Characteristics (Tj = 25°C)
Kennwerte (Tj = 25°C)
Min.
Typ.
Max.
Collector-Emitter cutoff current – Kollektor-Emitter-Reststrom
VCE = 80 V, (B-E short)
VCE = 50 V, (B-E short)
VCE = 30 V, (B-E short)
BC546
BC547
BC548 / BC549
ICES
ICES
ICES
–
–
–
0.2 nA
0.2 nA
0.2 nA
15 nA
15 nA
15 nA
VCE = 80 V, Tj = 125°C, (B-E short)
VCE = 50 V, Tj = 125°C, (B-E short)
VCE = 30 V, Tj = 125°C, (B-E short)
BC546
BC547
BC548 / BC549
ICES
ICES
ICES
–
–
–
–
–
–
4 µA
4 µA
4 µA
VCEsat
VCEsat
–
–
80 mV
200 mV
200 mV
600 mV
VBEsat
VBEsat
–
–
700 mV
900 mV
–
–
VBE
VBE
580 mV
–
660 mV
–
700 mV
720 mV
fT
–
300 MHz
–
CCBO
–
3.5 pF
6 pF
CEB0
–
9 pF
–
F
F
–
–
2 dB
1.2 dB
10 dB
4 dB
Collector-Emitter saturation voltage – Kollektor-EmitterSättigungsspg. 2)
IC = 10 mA, IB = 0.5 mA
IC = 100 mA, IB = 5 mA
Base saturation voltage – Basis-Sättigungsspannung 2)
IC = 10 mA, IB = 0.5 mA
IC = 100 mA, IB = 5 mA
Base-Emitter-voltage – Basis-Emitter-Spannung 2)
VCE = 5 V, IC = 2 mA
VCE = 5 V, IC = 10 mA
Gain-Bandwidth Product – Transitfrequenz
VCE = 5 V, IC = 10 mA, f = 100 MHz
Collector-Base Capacitance – Kollektor-Basis-Kapazität
VCB = 10 V, IE =ie = 0, f = 1 MHz
Emitter-Base Capacitance – Emitter-Basis-Kapazität
VEB = 0.5 V, IC = ic = 0, f = 1 MHz
Noise figure – Rauschzahl
VCE = 5 V, IC = 200 µA, RG = 2 kΩ
f = 1 kHz, Δf = 200 Hz
BC546 / BC547
BC548 / BC549
Thermal resistance junction to ambient air
Wärmewiderstand Sperrschicht – umgebende Luft
Recommended complementary PNP transistors
Empfohlene komplementäre PNP-Transistoren
Available current gain groups per type
Lieferbare Stromverstärkungsgruppen pro Typ
2
1
2
RthA
< 200 K/W 1)
BC556 ... BC559
BC546A
BC547A
BC548A
BC546B
BC547B
BC548B
BC549B
BC547C
BC548C
BC549C
Tested with pulses tp = 300 µs, duty cycle ≤ 2% – Gemessen mit Impulsen tp = 300 µs, Schaltverhältnis ≤ 2%
Valid, if leads are kept at ambient temperature at a distance of 2 mm from case
Gültig wenn die Anschlussdrähte in 2 mm Abstand vom Gehäuse auf Umgebungstemperatur gehalten werden
http://www.diotec.com/
© Diotec Semiconductor AG
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