Loose Leaf for Engineering Circuit Analysis Format: Loose-leaf
Loose Leaf for Engineering Circuit Analysis Format: Loose-leaf
9th Edition
ISBN: 9781259989452
Author: Hayt
Publisher: Mcgraw Hill Publishers
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Chapter 14, Problem 60E
To determine

The power dissipated by the 1Ω resistor.

Expert Solution & Answer
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Answer to Problem 60E

The power dissipated by the 1Ω resistor is {[4.66et5.66e14tcos39t40.15e14tsin39t4]u(t)}2W_.

Explanation of Solution

Given data:

The required diagram is shown in Figure 1.

Loose Leaf for Engineering Circuit Analysis Format: Loose-leaf, Chapter 14, Problem 60E , additional homework tip 1

Calculation:

The conversion of mF into F is done as,

1mF=1×103F

Hence, the conversion of 200mF into F is,

200mF=200×103F=0.2F

The s domain expression for conductor is written as,

1Cs=10.2s=5s

The Laplace transform of e4tu(t) is written as,

L[4etu(t)]=4s+1

The Laplace transform of 5u(t) is written as,

L[5u(t)]=5s

The required diagram for the s domain circuit is drawn as shown in figure 2.

Loose Leaf for Engineering Circuit Analysis Format: Loose-leaf, Chapter 14, Problem 60E , additional homework tip 2

Apply nodal analysis at node 1 and the expression is written as,

V1(s)1+V1(s)V2(s)5s=4s+1V1(s)1+0.2s[V1(s)V2(s)]=4s+1V1(s)(1+0.2s)0.2sV2(s)=4s+1 (1)

Apply nodal analysis at node 2 and the expression is written as,

0.2s[V1(s)V2(s)]+V2(s)2s+5s=00.2sV1(s)+(0.2s+12s)V2(s)=5s (2)

Solve equation (1) and (2) by Cramer’s rule and it is written as,

V1(s)=|4s+10.2s5s0.2s+12s||1+0.2s0.2s0.2s0.2s+12s|=(4s+1)(0.2s+12s)(0.2s)(5s)(1+0.2s)(0.2s+12s)(0.2s)(0.2s)=(4s+1)(0.4s2+12s)1(0.04s2+0.1+0.2s+12s)0.04s2=(1.6s2+42s22s2s(s+1))(0.08s3+0.4s2+0.2s+10.08s3s)

Further simplify the above expression.

V1(s)=(0.4s2+42s2s(s+1))(0.4s2+0.2s+1s)=(s210+5s)(s+1)(s2+12s+52)

Further simplify the above expression by taking partial fractions.

V1(s)=143(s+1)173s(s2+12s+52)53(s2+12s+52)=143(s+1)17s3[(s+14)2+(394)2]53((s+14)2+(394)2)=143(s+1)173[(s+14)[(s+14)2+(394)2]141[(s+14)2+(394)2]]53((s+14)2+(394)2)

The Laplace transform of (sinat)u(t) is written as,

L[(sinat)u(t)]=as2+a2

The Laplace transform of (cosat)u(t) is written as,

L[(cosat)u(t)]=ss2+a2

The properties for Laplace transform are written as,

L{f1(t)+f2(t)}=L{f1(t)}+L{f2(t)}

L1{kF(s)}=kL1{F(s)}

The inverse Laplace of the given function is written as,

v1(t)=L1{V1(s)} (3)

Substitute [143(s+1)173[(s+14)[(s+14)2+(394)2]141[(s+14)2+(394)2]]53((s+14)2+(394)2)] for V1(s) in equation (3).

v1(t)=L1{143(s+1)173[(s+14)[(s+14)2+(394)2]141[(s+14)2+(394)2]]53((s+14)2+(394)2)}=[143L11(s+1)173[L1((s+14)[(s+14)2+(394)2])173L1(141[(s+14)2+(394)2])]53{1((s+14)2+(394)2)}]=143etu(t)173[e14tcos39t4u(t)0.16e14tsin39t4u(t)]1.06e14tsin39t4u(t)=[4.66et5.66e14tcos39t40.15e14tsin39t4]u(t)V

The power dissipated in 1Ω resistor is written as,

p(t)=v12(t)R

Here,

p(t) is the power dissipated in 1Ω resistor,

R is the resistor.

Substitute {[4.66et5.66e14tcos39t40.15e14tsin39t4]u(t)}V for v1(t) and 1Ω for R in the above formula.

p(t)=({[4.66et5.66e14tcos39t40.15e14tsin39t4]u(t)}V)21Ω={[4.66et5.66e14tcos39t40.15e14tsin39t4]u(t)}2W

Conclusion:

Therefore, the power dissipated by the 1Ω resistor is {[4.66et5.66e14tcos39t40.15e14tsin39t4]u(t)}2W_.

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Chapter 14 Solutions

Loose Leaf for Engineering Circuit Analysis Format: Loose-leaf

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