Principles and Applications of Electrical Engineering
Principles and Applications of Electrical Engineering
6th Edition
ISBN: 9780073529592
Author: Giorgio Rizzoni Professor of Mechanical Engineering, James A. Kearns Dr.
Publisher: McGraw-Hill Education
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Current Division Method
The generalized current divider formula is given by the following relation below,
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Chapter 3, Problem 3.21HP

In the circuit in Figure P3.21, assume the source voltage and source current and all resistances are known.
a. Write the node equations required to determine the node voltages.
b. Write the matrix solution for each node voltage in terms of the known parameters.
Chapter 3, Problem 3.21HP, In the circuit in Figure P3.21, assume the source voltage and source current and all resistances are

Expert Solution
Check Mark
To determine

(a)

Thenode equations required to obtain the node voltages.

Answer to Problem 3.21HP

The required node equations are V1[1R2+1R1]V2R1=(IS+VSR2) and V1[1R1]+V2[1R1+1R3+1R4]=VSR3 .

Explanation of Solution

Calculation:

The given diagram is shown in Figure 1

  Principles and Applications of Electrical Engineering, Chapter 3, Problem 3.21HP

Apply KVL at the node V1 .

  IS=V1VSR2+V1V2R1IS+VSR2=V1[1 R 2+1 R 1]V2R1V1[1 R 2+1 R 1]V2R1=(IS+ V S R 2 ) ..... (1)

Apply KVL at the node V2 .

  V2V1R1+V2VSR3+V2R4=0V1[1 R 1]+V2[1 R 1+1 R 3+1 R 4]VSR3=0V1[1 R 1]+V2[1 R 1+1 R 3+1 R 4]=VSR3   ....... (2)

Conclusion:

Therefore, the required node equations are V1[1R2+1R1]V2R1=(IS+VSR2) and V1[1R1]+V2[1R1+1R3+1R4]=VSR3 .

Expert Solution
Check Mark
To determine

(b)

The matrix solutions for each of the node voltages in terms of the known parameters.

Answer to Problem 3.21HP

The required node voltage equations are V1=(IS+ V S R 2 )(1 R 1 +1 R 3 +1 R 4 )+VSR3R1(1 R 2 +1 R 1 )(1 R 1 +1 R 3 +1 R 4 )1R12 and V2=(1 R 2 +1 R 1 )VSR3+(IS+ V S R 2 )1R1(1 R 2 +1 R 1 )(1 R 1 +1 R 3 +1 R 4 )1R12 .

Explanation of Solution

Calculation:

The equation (1) equation (2) in the matrix form is given by,

  [ 1 R 2 + 1 R 1 1 R 1 1 R 1 1 R 1 + 1 R 3 + 1 R 4 ][ V 1 V 2]=[( I S + V S R 2 ) V S R 3 ]

The determinant of the square matrix is given by,

  Δ=[ 1 R 2 + 1 R 1 1 R 1 1 R 1 1 R 1 + 1 R 3 + 1 R 4 ]=[( 1 R 2 + 1 R 1 )( 1 R 1 + 1 R 3 + 1 R 4 )1 R 1 2]

The first determinant form of the matrix form is given by,

  Δ1=[ I S + V S R 2 1 R 1 V S R 3 1 R 1 + 1 R 3 + 1 R 4 ]=[( I S+ V S R 2 )( 1 R 1 + 1 R 3 + 1 R 4 )+ V S R 3 R 1]

The second determinant is given by,

  Δ2=[ 1 R 2 + 1 R 1 I S + V S R 2 1 R 1 V S R 3 ]=[( 1 R 2 + 1 R 1 ) V S R 3+( I S+ V S R 2 )1 R 1]

The expression to determine the node voltage V1 is given by,

  V1=Δ1Δ

Substitute (IS+VSR2)(1R1+1R3+1R4)+VSR3R1 for Δ1 and (1R2+1R1)(1R1+1R3+1R4)1R12 for Δ in the above equation.

  V1=(IS+ V S R 2 )(1 R 1 +1 R 3 +1 R 4 )+VSR3R1(1 R 2 +1 R 1 )(1 R 1 +1 R 3 +1 R 4 )1R12

The expression for the node voltage V2 is given by,

  V2=Δ2Δ

Substitute (1R2+1R1)VSR3+(IS+VSR2)1R1 for Δ2 and (1R2+1R1)(1R1+1R3+1R4)1R12 for Δ in the above equation.

  V2=(1 R 2 +1 R 1 )VSR3+(IS+ V S R 2 )1R1(1 R 2 +1 R 1 )(1 R 1 +1 R 3 +1 R 4 )1R12

Conclusion:

Therefore, the required node voltage equations are V1=(IS+ V S R 2 )(1 R 1 +1 R 3 +1 R 4 )+VSR3R1(1 R 2 +1 R 1 )(1 R 1 +1 R 3 +1 R 4 )1R12 and V2=(1 R 2 +1 R 1 )VSR3+(IS+ V S R 2 )1R1(1 R 2 +1 R 1 )(1 R 1 +1 R 3 +1 R 4 )1R12 .

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Chapter 3 Solutions

Principles and Applications of Electrical Engineering

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Ch. 3 - Use nodal analysis in the circuit of Figure P3.11...Ch. 3 - Find the power delivered to the load resistor R0...Ch. 3 - For the circuit of Figure P3.13, write the nodee...Ch. 3 - Using mesh analysis, find the currents i1 and i2...Ch. 3 - Using mesh analysis, find the currents i1 and i2...Ch. 3 - Using mesh analysis, find the voltage v across the...Ch. 3 - Using mesh analysis, find the currents I1,I2 and...Ch. 3 - Using mesh analysis. Find the voltage V across the...Ch. 3 - Prob. 3.19HPCh. 3 - For the circuit of Figure P3.20, use mesh analysis...Ch. 3 - In the circuit in Figure P3.21, assume the source...Ch. 3 - For the circuit of Figure P3.22 determine: a. The...Ch. 3 - Figure P3.23 represents a temperature measurement...Ch. 3 - Use nodal analysis on the circuit in Figure P3.24...Ch. 3 - Use mesh analysis to find the mesh currents in...Ch. 3 - Use mesh analysis to find the mesh currents in...Ch. 3 - Use mesh analysis to find the currents in Figure...Ch. 3 - Use mesh analysis to find V4 in Figure P3.28. Let...Ch. 3 - Use mesh analysis to find mesh currents in Figure...Ch. 3 - Use mesh analysis to find the current i in Figure...Ch. 3 - Use mesh analysis to find the voltage gain...Ch. 3 - Use nodal analysis to find node voltages V1,V2,...Ch. 3 - Use mesh analysis to find the currents through...Ch. 3 - Prob. 3.34HPCh. 3 - Prob. 3.35HPCh. 3 - Using the data of Problem 3.35 and Figure P3.35,...Ch. 3 - Prob. 3.37HPCh. 3 - Prob. 3.38HPCh. 3 - Use nodal analysis in the circuit of Figure P3.39...Ch. 3 - Prob. 3.40HPCh. 3 - Refer to Figure P3.10 and use the principle of...Ch. 3 - Use the principle of superposition to determine...Ch. 3 - Refer to Figure P3.43 and use the principle of...Ch. 3 - Refer to Figure P3.44 and use the principle of...Ch. 3 - Refer to Figure P3.44 and use the principle of...Ch. 3 - Prob. 3.46HPCh. 3 - Use the principle of super position to determine...Ch. 3 - Prob. 3.48HPCh. 3 - Use the principle of super position to determine...Ch. 3 - Use the principle of superposition to determine...Ch. 3 - Find the Thé venin equivalent of the network...Ch. 3 - Find the Thé venin equivalent of the network seen...Ch. 3 - Find the Norton equivalent of the network seen by...Ch. 3 - Find the Norton equivalent of the network between...Ch. 3 - Find the Thé venin equivalent of the network seen...Ch. 3 - Prob. 3.56HPCh. 3 - Find the Thé venin equivalent of the network seen...Ch. 3 - Find the Thé venin equivalent network seen by...Ch. 3 - Prob. 3.59HPCh. 3 - Prob. 3.60HPCh. 3 - Prob. 3.61HPCh. 3 - Find the Thé venin equivalent resistance seen...Ch. 3 - Find the Thé venin equivalent resistance seen by...Ch. 3 - Find the Thé venin equivalent network seen from...Ch. 3 - Find the Thé’cnin equivalent resistance seen by R3...Ch. 3 - Find the Norton equivalent of the network seen by...Ch. 3 - Find the Norton equivalent of the network seen by...Ch. 3 - Prob. 3.68HPCh. 3 - Find the Norton equivalent network between...Ch. 3 - Prob. 3.70HPCh. 3 - Prob. 3.71HPCh. 3 - Prob. 3.72HPCh. 3 - The Thé venin equivalent network seen by a load Ro...Ch. 3 - The Thévenin equivalent network seen by a load Ro...Ch. 3 - Prob. 3.75HPCh. 3 - Prob. 3.76HPCh. 3 - Many practical circuit elements are non-linear;...Ch. 3 - Prob. 3.78HPCh. 3 - The non-linear diode in Figure P3.79 has the i-v...Ch. 3 - Prob. 3.80HPCh. 3 - The non-linear device D in Figure P3.81 has the...Ch. 3 - Prob. 3.82HPCh. 3 - The so-called forward-bias i-v relationship for a...
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