2) The input signal to an ideal sampler shown below is,e(t) = 4 Cos 5tFourier Transform of Cos w̟t = ò(o+w1) + 8(w – wi)]The sampler angular velocity Ws = 20.a) Plot amplitude spectrum |E(jw|which is the input of the ideal ampler versus Ofor – 40 < O < 40b) Plot amplitude spectrum |E* (jw[ which is the output of the deal sampler versus Ofor - 40 < O < 40c) Plot amplitude spectrJEJW|which is the output of Zero-Order Hold versus Ofor – 40 < W < 401-e-TSE(s)E (s)TSE*(S)

2) The input signal to an ideal sampler shown below is, e(t) = 4 Cos 5t Fourier Transform of Cos wit = 8(o + w1) + 8(w – wi)] The sampler angular velocity Ws = 20. a) Plot amplitude spectrum |E(jw[ which is the input of the ideal ampler versus a for – 40 < O < 40 b) Plot amplitude spectrum |E* (jw| which is the output of the deal sampler versus for - 40 < 0 < 40 c) Plot amplitude spectrum |E(jw[ which is the output of Zero-Order Hold versus for - 40 < @ < 40 1-e-TS E(s) E (s) T S E*(S)

2) The input signal to an ideal sampler shown below is, e(t) = 4 Cos 5t Fourier Transform of Cos wit = 8(o + w1) + 8(w – wi)] The sampler angular velocity Ws = 20. a) Plot amplitude spectrum |E(jw[ which is the input of the ideal ampler versus a for – 40 < O < 40 b) Plot amplitude spectrum |E* (jw| which is the output of the deal sampler versus for - 40 < 0 < 40 c) Plot amplitude spectrum |E(jw[ which is the output of Zero-Order Hold versus for - 40 < @ < 40 1-e-TS E(s) E (s) T S E*(S)

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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