a second-order process is controlled using a P controller with a feedback closed-loop controlsystem, using my transfer functions given below in the case that Kc = 5. after applying a stepeffect of magnitude 2 at the set point;Gp(s)=2(s + 1)(2s + 1)Gy(s) = G, (s) = 1SP(s) = 2Kc = 5b) We calculate when I will reach the maximum value of the controlled variable (CV)(hint: the first peak time).c) Calculate the time constant and the Damping coefficient.d) Calculate the highest deviation.f) Calculate the salmim period.g) Calculate the polarity of the control system.

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a second-order process is controlled using a P controller with a feedback closed-loop control system, using my transfer functions given below in the case that Kc = 5. after applying a step effect of magnitude 2 at the set point; Gp(s) = 2 (s + 1)(2s + 1) Gy(s) = G(s) = 1 SP(s) = 2 Kc = 5 Ke b) We calculate when I will reach the maximum value of the controlled variable (CV) (hint: the first peak time). c) Calculate the time constant and the Damping coefficient. d) Calculate the highest deviation. f) Calculate the salmim period. g) Calculate the polarity of the control system.

a second-order process is controlled using a P controller with a feedback closed-loop control system, using my transfer functions given below in the case that Kc = 5. after applying a step effect of magnitude 2 at the set point; Gp(s) = 2 (s + 1)(2s + 1) Gy(s) = G(s) = 1 SP(s) = 2 Kc = 5 Ke b) We calculate when I will reach the maximum value of the controlled variable (CV) (hint: the first peak time). c) Calculate the time constant and the Damping coefficient. d) Calculate the highest deviation. f) Calculate the salmim period. g) Calculate the polarity of the control system.

Introductory Circuit Analysis (13th Edition)

13th Edition

ISBN:9780133923605

Author:Robert L. Boylestad

Publisher:Robert L. Boylestad

Chapter1: Introduction

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Question

a second-order process is controlled using a P controller with a feedback closed-loop control
system, using my transfer functions given below in the case that Kc = 5. after applying a step
effect of magnitude 2 at the set point;
Gp(s)
=
2
(s + 1)(2s + 1)
Gy(s) = G, (s) = 1
SP(s) = 2
Kc = 5
b) We calculate when I will reach the maximum value of the controlled variable (CV)
(hint: the first peak time).
c) Calculate the time constant and the Damping coefficient.
d) Calculate the highest deviation.
f) Calculate the salmim period.
g) Calculate the polarity of the control system.

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