By applying a 1 kHz sine wave of 15 mVp to the input terminal (Vs). Simulate the circuit (Common Emitter Amplifier circuit) shown in Fig. 1 and observe the voltage drop across the resistor RL. • Remove the capacitor Ce, simulate the circuit shown in Fig. 1 and observe the voltage drop across the resistor RL. • Compare the results of the simulated circuits and explain. What are the gains (with and without Ce) in two simulated circuits? • Draw the input and output ac signals, and compare the phases.
By applying a 1 kHz sine wave of 15 mVp to the input terminal (Vs). Simulate the circuit (Common Emitter Amplifier circuit) shown in Fig. 1 and observe the voltage drop across the resistor RL. • Remove the capacitor Ce, simulate the circuit shown in Fig. 1 and observe the voltage drop across the resistor RL. • Compare the results of the simulated circuits and explain. What are the gains (with and without Ce) in two simulated circuits? • Draw the input and output ac signals, and compare the phases.
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You don't need to simulite. Just solve a and b options. Thanks.
Transcribed Image Text:Common Emitter Amplifier:
Vee 4
+12 V
Re IK
RI
27 KA
C2
1 uF
Rs
502
1 uF
RL4.7 KN
Vs
R2
2.7 KN
Re
200 2
Ce:
500 uF
Fig. 1: Common Emitter Amplifier
By applying a 1 kHz sine wave of 15 mVp to the input terminal (Vs).
• Simulate the circuit (Common Emitter Amplifier circuit) shown in Fig. 1 and observe the
voltage drop across the resistor RL.
• Remove the capacitor Ce, simulate the circuit shown in Fig. 1 and observe the voltage drop
across the resistor RL.
• Compare the results of the simulated circuits and explain. What are the gains (with and
without Ce) in two simulated circuits?
6.
Draw the input and output ac signals, and compare the phases.
Transcribed Image Text:haat e Ct
ie v Teel G Da ay l
Kh t e Captre
638 mV
39.9 mV
CE
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