(a) Figure 2.1 shows the circuit of a silicon transistor amplifier. The amplifier is to have an output impedance of 3.3 k and a collector current of 2 mA. Assuming the transistor has a large Boc and making other reasonable approximations, calculate the following quantities for the circuit: (i) DC collector voltage, Vc (ii) DC emitter voltage (iii) DC base voltage (iv) R₂. Voc HH R₁ R₂ K Rc RE Figure 2.1 CE OV Vc Vcc = 12 V R1 = 68 ΚΩ RE=1 KQ
(a) Figure 2.1 shows the circuit of a silicon transistor amplifier. The amplifier is to have an output impedance of 3.3 k and a collector current of 2 mA. Assuming the transistor has a large Boc and making other reasonable approximations, calculate the following quantities for the circuit: (i) DC collector voltage, Vc (ii) DC emitter voltage (iii) DC base voltage (iv) R₂. Voc HH R₁ R₂ K Rc RE Figure 2.1 CE OV Vc Vcc = 12 V R1 = 68 ΚΩ RE=1 KQ
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Transcribed Image Text:Question 2
(a) Figure 2.1 shows the circuit of a silicon transistor amplifier. The amplifier is to
have an output impedance of 3.3 k and a collector current of 2 mA.
Assuming the transistor has a large Boc and making other reasonable
approximations, calculate the following quantities for the circuit:
(i) DC collector voltage, Vc
(ii) DC emitter voltage
(iii) DC base voltage
(iv) R₂.
Vcc
R₁
R₂
ŒK
Rc
RE
Figure 2.1
CE
OV
Vc
Vcc= 12 V
R1 = 68 ΚΩ
RE= 1 KQ
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