A laboratory experiment can be modelled as a system with an open-looptransfer functionQ3P(s) =(s + 2)(s + 3)A controller C(s) with the transfer functionKC(s) =is used to control P(s) ir a unity-feedback configuration.(a)(i)Determine the open loop transfer function G(s) = C(s)P(s), andidentifv the open-loop poles and open-loop zeros of the system.(ii)What is the relative degree of G(s)? Determine the number ofasymptotes of the root locus and where they meet, and calculate thelocation of any double point(s).(iii)Sketch the root-locus for this system, using the information derived in(i) (ii). Discuss the characteristics of the closed loop system fordifferent values of K, e.g. for small K and for larger values of K.(b)Explain how the controller C(s) could be modified to guarantee that the closedloop system is stable for any value of K > 0. What additional term can beadded? Sketch a root locus diagram for your chosen additional term and discussthe differences to the diagram which you obtained in (a).

As per guidelines i have to answer first three sub parts please post remaining again Given that P(s)…

A laboratory experiment can be modelled as a system with an open-loop transfer function Q3 1 P(s) = (s + 2)(s + 3) A controller C(s) with the transfer function K C(s) = is used to control P(s) ir a unity-feedback configuration. (a) (i) Determine the open loop transfer function G(s) = C(s)P(s), and identify the open-loop poles and open-loop zeros of the system. W. hat is the relative degree of G(s)? Determine the number of asymptotes of the root locus and where they meet, and calculate the location of any double point(s). (ii) (iii) Sketch the root-locus for this system, using the information derived in (i)-(ii). Discuss the characteristics of the closed loop system for different values of K, e.g. for small K and for larger values of K.

A laboratory experiment can be modelled as a system with an open-loop transfer function Q3 1 P(s) = (s + 2)(s + 3) A controller C(s) with the transfer function K C(s) = is used to control P(s) ir a unity-feedback configuration. (a) (i) Determine the open loop transfer function G(s) = C(s)P(s), and identify the open-loop poles and open-loop zeros of the system. W. hat is the relative degree of G(s)? Determine the number of asymptotes of the root locus and where they meet, and calculate the location of any double point(s). (ii) (iii) Sketch the root-locus for this system, using the information derived in (i)-(ii). Discuss the characteristics of the closed loop system for different values of K, e.g. for small K and for larger values of K.

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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