E5.4 A feedback system with negative unity feedback hasa loop transfer function2(s + 8)L(s) = G(s)G(s)s(s + 4)(a) Determine the closed-loop transfer function T(s) =Y(s)/R(s). (b) Find the time response, y(t), for a stepinput r(t) = A for t> 0. (c) Determine the percentovershoot of the response. (d) Using the final-valuetheorem, determine the steady-state value of y(t).Answer: (b) y(1) = 1 - 1.07e-3 sin( V7t + 1.2)

The plant transfer function of a negative unity feedback is, (a) Determine the closed-loop transfer…

E5.4 A feedback system with negative unity feedback has a loop transfer function 2(s + 8) L(s) = G,(s)G(s) (+ + s)s (a) Determine the closed-loop transfer function T(s) = Y(s)/R(s). (b) Find the time response, y(t), for a step input r(1) = A for t> 0. (c) Determine the percent overshoot of the response. (d) Using the final-value theorem, determine the steady-state value of y(t). Answer: (b) y(t) = 1- 1.07e sin(V7t + 1.2)

E5.4 A feedback system with negative unity feedback has a loop transfer function 2(s + 8) L(s) = G,(s)G(s) (+ + s)s (a) Determine the closed-loop transfer function T(s) = Y(s)/R(s). (b) Find the time response, y(t), for a step input r(1) = A for t> 0. (c) Determine the percent overshoot of the response. (d) Using the final-value theorem, determine the steady-state value of y(t). Answer: (b) y(t) = 1- 1.07e sin(V7t + 1.2)

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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