1. Consider a system represented by the block diagram in Fig.1. 2 +1) 0.5r Fig.1 The transfer function N(s)/Y(s) using block diagram reduction is: O a. Y(s) а. N(s) (s+1) s2 +6 s+20 O b. Y(s) d. N(s) s(s+1) s2+ s+20 Y(s) с. N(s) s(s+1) s2 +6 s+20 O d. Y(s) %3D s(s+1) s2 +16 s+20 b. N(s)

1. Consider a system represented by the block diagram in Fig.1. 2 +1) 0.5r Fig.1 The transfer function N(s)/Y(s) using block diagram reduction is: O a. Y(s) а. N(s) (s+1) s2 +6 s+20 O b. Y(s) d. N(s) s(s+1) s2+ s+20 Y(s) с. N(s) s(s+1) s2 +6 s+20 O d. Y(s) %3D s(s+1) s2 +16 s+20 b. N(s)

Introductory Circuit Analysis (13th Edition)

13th Edition

ISBN:9780133923605

Author:Robert L. Boylestad

Publisher:Robert L. Boylestad

Chapter1: Introduction

Section: Chapter Questions

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Question

1. Consider a system represented by the block diagram in Fig.1.
N()
RUS)
10
Ys)
sts + 1)
0.5s
Fig.1
The transfer function N(s)/Y(s) using block diagram reduction is:
Оа.
Y(s)
а.
N(s)
(s+1)
%3D
s2 +6 s+20
O b.
Y(s)
d.
N(s)
s(s+1)
%3D
s2+ s+20
c.
Y(s)
с.
N(s)
s(s+1)
s² +6 s+20
O d.
s(s+1)
Y(s)
b.
N(s)
s2 +16 s+20
2.

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