Figure 6 shows the circuit diagram for an NMOS amplifier realized with the transistor M1. Q6 (a) What kind of amplifier is M1 part of? Draw the small signal equivalent circuit suitable for the analysis in the high frequency band and state any assumption. (b) By using Miller's theorem draw the resulting small signal equivalent circuit and derive an expression for the voltage gain G, at varying of the angular frequency w. Assume that the output impedance of the signal generator connected at the input of the circuit is Ro. (c) (d) Identify the number of poles fpi in the gain Gy and write their expression. (e) Sketch the bode plot for the gain of the circuit stating any assumption. VDD R1 Rp V out M1 Vin Cp CG RL R2 CG ||Rs Cs V ss = 0 V Figure 6

Figure 6 shows the circuit diagram for an NMOS amplifier realized with the transistor M1. Q6 (a) What kind of amplifier is M1 part of? Draw the small signal equivalent circuit suitable for the analysis in the high frequency band and state any assumption. (b) By using Miller's theorem draw the resulting small signal equivalent circuit and derive an expression for the voltage gain G, at varying of the angular frequency w. Assume that the output impedance of the signal generator connected at the input of the circuit is Ro. (c) (d) Identify the number of poles fpi in the gain Gy and write their expression. (e) Sketch the bode plot for the gain of the circuit stating any assumption. VDD R1 Rp V out M1 Vin Cp CG RL R2 CG ||Rs Cs V ss = 0 V Figure 6

Introductory Circuit Analysis (13th Edition)

13th Edition

ISBN:9780133923605

Author:Robert L. Boylestad

Publisher:Robert L. Boylestad

Chapter1: Introduction

Section: Chapter Questions

Problem 1P: Visit your local library (at school or home) and describe the extent to which it provides literature...

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