(A): Convert the Block Diagram showing in figure (2) to a Signal-Flow Graph (SFG).(B): Reduce the block diagram shown in figure (2) to a single transfer function Y(s)/R(s).(C): For the close loop system, find the values of damping ratio (), natural frequency (wn),percent overshoot (%OS), Peak time (Tp), Rise time (Tr), and settling time (Ts)Y(s)2500%3DR(s)s2 + 50 s + 2500R(s)Y(s)11Ks+0.42+1.7s+0.25G1(s)G2(s)G3(s)Figure (1)0.1s+0.1H(s)R(s)V1(s)V2(s)G1(s)V4(s)V5(s)Y(s)G3(s)G4(s)V3(s)Figure (2)G2(s)V6(s)H(s)

The given block diagram should be converted into signal flow graph by taking the summing and pickup…

(A): Convert the Block Diagram showing in figure (2) to a Signal-Flow Graph (SFG). (B): Reduce the block diagram shown in figure (2) to a single transfer function Y(s)/R(s). (C): For the close loop system, find the values of damping ratio (9), natural frequency (wn), percent overshoot (%OS), Peak time (Tp), Rise time (Tr), and settling time (Ts) Y(s) 2500 R(s) s2 + 50 s + 2500

(A): Convert the Block Diagram showing in figure (2) to a Signal-Flow Graph (SFG). (B): Reduce the block diagram shown in figure (2) to a single transfer function Y(s)/R(s). (C): For the close loop system, find the values of damping ratio (9), natural frequency (wn), percent overshoot (%OS), Peak time (Tp), Rise time (Tr), and settling time (Ts) Y(s) 2500 R(s) s2 + 50 s + 2500

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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