EBK FUNDAMENTALS OF ELECTRIC CIRCUITS
EBK FUNDAMENTALS OF ELECTRIC CIRCUITS
6th Edition
ISBN: 8220102801448
Author: Alexander
Publisher: YUZU
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Textbook Question
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Chapter 14, Problem 44P

For the circuit in Fig. 14.83, find:

  1. (a) the resonant frequency ω0
  2. (b) Zin(ω0)

Chapter 14, Problem 44P, For the circuit in Fig. 14.83, find: (a) the resonant frequency 0 (b) Zin(0) Figure 14.83

Figure 14.83

a.

Expert Solution
Check Mark
To determine

Find the value of the resonant frequency (ω0) for the circuit in Figure 14.83.

Answer to Problem 44P

The value of the resonant frequency (ω0) is 2.357krads.

Explanation of Solution

Given data:

Refer to Figure 14.83 in the textbook.

Formula used:

Write a general expression to calculate the impedance of a resistor in frequency domain.

ZR=R (1)

Here,

R is the value of the resistor.

Write a general expression to calculate the impedance of an inductor in frequency domain.

ZL=jωL (2)

Here,

L is the value of the inductor.

Write a general expression to calculate the impedance of a capacitor in frequency domain.

ZC=1jωC (3)

Here,

C is the value of the capacitor.

Calculation:

The given circuit is redrawn as Figure 1.

EBK FUNDAMENTALS OF ELECTRIC CIRCUITS, Chapter 14, Problem 44P , additional homework tip 1

The Figure 1 is converted into frequency domain and drawn as Figure 2 using the equations (1), (2), and (3).

EBK FUNDAMENTALS OF ELECTRIC CIRCUITS, Chapter 14, Problem 44P , additional homework tip 2

Refer to Figure 2, the resistor R1 and inductor is connected in parallel form and the combination is connected in parallel with the series combination of the capacitor and resistor R2.

Write the expression to calculate impedance of the circuit in Figure 2.

Zin=(R1jωL)(R2+1jωC)=(R1×jωLR1+jωL)(R2+1jωC)=(jωR1LR1+jωL)×(R2+1jωC)(jωR1LR1+jωL+R2+1jωC)=(jωR1R2LR1+jωL+jωR1LjωC(R1+jωL))((jωR1L)(jωC)+R2(jωC)(R1+jωL)+1(R1+jωL)jωC(R1+jωL))

Simplify the above equation to find Zin.

Zin=(jωR1R2L(jωC)+jωR1LjωC(R1+jωL))((jωR1L)(jωC)+R2(jωC)(R1+jωL)+1(R1+jωL)jωC(R1+jωL))=j2ω2R1R2LC+jωR1Lj2ω2R1LC+jωR1R2C+j2ω2R2LC+R1+jωL=ω2R1R2LC+jωR1Lω2R1LC+jωR1R2Cω2R2LC+R1+jωL {j2=1}=ω2R1R2LC+j(ωR1L)(R1ω2R1LCω2R2LC)+jω(L+R1R2C)

Multiply and divide the above equation by the conjugate of denominator to find Zin.

Zin=((ω2R1R2LC+j(ωR1L)(R1ω2R1LCω2R2LC)+jω(L+R1R2C))×((R1ω2R1LCω2R2LC)jω(L+R1R2C)(R1ω2R1LCω2R2LC)jω(L+R1R2C)))=((ω2R1R2LC+jωR1L)(R1ω2R1LCω2R2LCjωLjωR1R2C))(R1ω2R1LCω2R2LC)2(jω(L+R1R2C))2 {(a2b2)=(a+b)(ab)}=(ω2R12R2LC+ω4R12R2L2C2+ω4R1R22L2C2+jω3R1R2L2C+jω3R12R22LC2+jωR12Ljω3R12L2Cjω3R1R2L2Cj2ω2R1L2j2ω2R12R2LC)(R1ω2R1LCω2R2LC)2(jω(L+R1R2C))2=(ω2R12R2LC+ω4R12R2L2C2+ω4R1R22L2C2+jω3R1R2L2C+jω3R12R22LC2+jωR12Ljω3R12L2Cjω3R1R2L2C(1)ω2R1L2(1)ω2R12R2LC)(R1ω2R1LCω2R2LC)2(1)(ω(L+R1R2C))2{j2=1}

Simplify the above equation to find Zin.

Zin=(ω2R12R2LC+ω4R12R2L2C2+ω4R1R22L2C2+jω3R1R2L2C+jω3R12R22LC2+jωR12Ljω3R12L2Cjω3R1R2L2C+ω2R1L2+ω2R12R2LC)(R1ω2R1LCω2R2LC)2+(ω(L+R1R2C))2

Zin=((ω4R1R2L2C2(R1+R2)+ω2R1L2)+j(ω3R1R2LC(L+R1R2C)+ωR1L(R1ω2R1LCω2R2LC)))(R1ω2R1LCω2R2LC)2+(ω(L+R1R2C))2 (4)

Equate the imaginary part to zero in equation (4).

(ω3R1R2LC(L+R1R2C)+ωR1L(R1ω2R1LCω2R2LC))(R1ω2R1LCω2R2LC)2+(ω(L+R1R2C))2=0ωR1L(ω2R2C(L+R1R2C)+(R1ω2R1LCω2R2LC))=0(ω2R2CL+ω2R1R22C2+R1ω2R1LCω2R2LC)=0ω2R1R22C2+R1ω2R1LC=0

Simplify the above equation.

R1(ω2R22C2+1ω2LC)=0ω2R22C2+1ω2LC=0ω2LCω2R22C2=1ω2(LCR22C2)=1

Rearrange the above equation to find ω02.

ω02=1(LCR22C2)

Take square root on both sides of the above equation to find ω0.

ω02=1(LCR22C2)

ω0=1(LCR22C2) (5)

Substitute 20mH for L, 9μF for C and 0.1Ω for R2 in equation (5) to find ω0.

ω0=1((20mH)(9μF)(0.1Ω)2(9μF)2)=1((20×103)(9×106)HF(0.1)2(9×106)2Ω2F2){1m=103,1μ=106}=1((1.8×107)(s2F)F(8.1×1013)(sF)2F2) {1H=1s21F,1Ω=1s1F}=1((1.8×107)s2(8.1×1013)s2)

Simplify the above equation to find ω0.

ω0=1(1.7999×107)s2=2.357×103rads=2.357krads {1k=103}

Conclusion:

Thus, the value of the resonant frequency (ω0) is 2.357krads.

b.

Expert Solution
Check Mark
To determine

Find the value of the input impedance Zin(ω0).

Answer to Problem 44P

The value of the input impedance Zin(ω0) is 1Ω.

Explanation of Solution

Calculation:

From part a, ω0=ω=2.357krads and

Zin(ω0)=(R1jωL)(R2+1jωC) (6)

To find (R1jωL):

(R1jωL)=(R1×jωLR1+jωL)

(R1jωL)=jωR1LR1+jωL (7)

Substitute 1Ω for R1, 20mH for L and 2.357krads for ω in equation (7) to find (R1jωL).

(R1jωL)=j(2.357krads)(1Ω)(20mH)1Ω+j(2.357krads)(20mH)=j(2.357×103)(1)(20×103)ΩHs1Ω+j(2.357×103)(20×103)Hs {1k=103,1m=103}

(R1jωL)=j47.14ΩΩss1Ω+j47.14Ωss {1H=1Ω1s}=j47.14Ω21Ω+j47.14Ω

To find (R2+1jωC):

Substitute 0.1Ω for R2, 9μF for C and 2.357krads for ω to find (R2+1jωC).

(R2+1jωC)=(0.1Ω)+(1j(2.357krads)(9μF))=0.1Ω+(1j(2.357×103)(9×106)Fs) {1k=103,1μ=106}=0.1Ω+(1j0.0212(sΩ)s) {1F=1s1Ω}=0.1Ωj47.14Ω

Substitute j47.14Ω21Ω+j47.14Ω for (R1jωL) and 0.1Ωj47.14Ω for (R2+1jωC) in equation (6) to find Zin(ω0).

Zin(ω0)=(j47.14Ω21Ω+j47.14Ω)(0.1Ωj47.14Ω)=(0.9996Ω+j0.0212Ω)(0.1Ωj47.14Ω)=(0.9996Ω+j0.0212Ω)×(0.1Ωj47.14Ω)(0.9996Ω+j0.0212Ω)+(0.1Ωj47.14Ω)=1Ω

Conclusion:

Thus, the value of the input impedance Zin(ω0) is 1Ω.

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