Q4: A feedback control system has the characteristic equation shown below; examine itsstability using Routh's stability criterion and find all the equation's roots.P(s) = 25 + 65 + 8s* + 125 + 1os? + 65 +405: Reduce the block diagram shown below to obtain C(s)/R(s).R(s)-GG:C(s)G3 Q2: For the system shown in the figure below, find the following when the input is a unit step:100R(s)-C(s)Ks1- The transfer function (C(s)/R(s)).2- The value of K that makes the maximum overshoot (M,) value is 0.25.3- The steady-state error (e,).4- The time response (C(t)).Q3: Find the transfer function for the mechanical system shown below (XF):M wwwwK30202K102K104020

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04: A feedback control system has the characteristic equation shown below; examine its stability using Routh's stability criterion and find all the equation's roots. P(s) = 25 + 6S + 8s* + 125 + 10s? + 65 +4

04: A feedback control system has the characteristic equation shown below; examine its stability using Routh's stability criterion and find all the equation's roots. P(s) = 25 + 6S + 8s* + 125 + 10s? + 65 +4

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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