a)i. How to identify the system's stability using frequency domain technique?ii. Normalised the following open-loop transfer functions and identify all the breakfrequencies.100(s+6)а)G;(s) =(s+0.2)(s+10)(s+50)1b)G2(s) =(s+10)(s²+2s+2)b)Sketch a Bode plot (magnitude and phase) using approximation method for the systemshown in Figure Q1.(b). Set gain K=100.R(s)C(s)1Ks(s + 10)Figure Q1.(b)

a) i. How to identify the system's stability using frequency domain technique? ii. Normalised the following open-loop transfer functions and identify all the break frequencies. 100(s+6) a) G;(s) = (s+0.2)(s+10)(s+50) 1 b) G2(s) = (s+10)(s²+2s+2) b) Sketch a Bode plot (magnitude and phase) using approximation method for the system shown in Figure Q1.(b). Set gain K-100. R(s) C(s) 1 K s(s + 10) Figure Q1.(b)

a) i. How to identify the system's stability using frequency domain technique? ii. Normalised the following open-loop transfer functions and identify all the break frequencies. 100(s+6) a) G;(s) = (s+0.2)(s+10)(s+50) 1 b) G2(s) = (s+10)(s²+2s+2) b) Sketch a Bode plot (magnitude and phase) using approximation method for the system shown in Figure Q1.(b). Set gain K-100. R(s) C(s) 1 K s(s + 10) Figure Q1.(b)

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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