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Electrical Engineering: Principles and Applications, 6e Allan R. Hambley
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CHAPTER 2RESISTIVE CIRCUITS
Electrical Engineering: Principles and Applications, 6e Allan R. Hambley
Copyright ©2014 by Pearson Education, Inc. All rights reserved.
Figure 2.42 A two-terminal circuit consisting of resistances and sources can be replaced by a Thévenin equivalent circuit.
Electrical Engineering: Principles and Applications, 6e Allan R. Hambley
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Figure 2.43 Thévenin equivalent circuit with open-circuited terminals. The open-circuit voltage voc is equal to the Thévenin voltage Vt.
Electrical Engineering: Principles and Applications, 6e Allan R. Hambley
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Figure 2.44 Thévenin equivalent circuit with short-circuited terminals. The short-circuit current is isc = Vt/Rt.
Electrical Engineering: Principles and Applications, 6e Allan R. Hambley
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Figure 2.45 Circuit for Example 2.16.
Electrical Engineering: Principles and Applications, 6e Allan R. Hambley
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Figure 2.45 Circuit for Example 2.16.
Electrical Engineering: Principles and Applications, 6e Allan R. Hambley
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Figure 2.46 Circuit for Exercise 2.26.
Electrical Engineering: Principles and Applications, 6e Allan R. Hambley
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Figure 2.48 Circuit for Example 2.17.
Electrical Engineering: Principles and Applications, 6e Allan R. Hambley
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Figure 2.48 Circuit for Example 2.17.
Electrical Engineering: Principles and Applications, 6e Allan R. Hambley
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Figure 2.49 Circuits for Exercise 2.28.
Electrical Engineering: Principles and Applications, 6e Allan R. Hambley
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Figure 2.50 Circuit for Example 2.18.
Electrical Engineering: Principles and Applications, 6e Allan R. Hambley
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Figure 2.50 Circuit for Example 2.18.
Electrical Engineering: Principles and Applications, 6e Allan R. Hambley
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Figure 2.51 The Norton equivalent circuit consists of an independent current source In in parallel with the Thévenin resistance Rt.
Electrical Engineering: Principles and Applications, 6e Allan R. Hambley
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Figure 2.52 The Norton equivalent circuit with a short circuit across its terminals.
Electrical Engineering: Principles and Applications, 6e Allan R. Hambley
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Figure 2.53 Circuit of Example 2.19.
Electrical Engineering: Principles and Applications, 6e Allan R. Hambley
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Figure 2.53 Circuit of Example 2.19.
Electrical Engineering: Principles and Applications, 6e Allan R. Hambley
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Figure 2.54 Circuits for Exercise 2.29.
Electrical Engineering: Principles and Applications, 6e Allan R. Hambley
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Figure 2.55 A voltage source in series with a resistance is externally equivalent to a current source in parallel with the resistance, provided that In = Vt /Rt .
Electrical Engineering: Principles and Applications, 6e Allan R. Hambley
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Figure 2.56 Circuit for Example 2.20.
Electrical Engineering: Principles and Applications, 6e Allan R. Hambley
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Figure 2.57 Circuit for Exercise 2.30.
Electrical Engineering: Principles and Applications, 6e Allan R. Hambley
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Figure 2.58 Circuits for analysis of maximum power transfer.
Electrical Engineering: Principles and Applications, 6e Allan R. Hambley
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Figure 2.59 Circuit for Example 2.21.
Electrical Engineering: Principles and Applications, 6e Allan R. Hambley
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Figure 2.60 Circuit used to illustrate the superposition principle.
Electrical Engineering: Principles and Applications, 6e Allan R. Hambley
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Figure 2.61 A resistance that obeys Ohm’s law is linear.
Electrical Engineering: Principles and Applications, 6e Allan R. Hambley
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Figure 2.62 Circuit for Example 2.22 and Exercise 2.31.
Electrical Engineering: Principles and Applications, 6e Allan R. Hambley
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Figure P2.83
Electrical Engineering: Principles and Applications, 6e Allan R. Hambley
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Figure P2.85
Electrical Engineering: Principles and Applications, 6e Allan R. Hambley
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Figure P2.86
Electrical Engineering: Principles and Applications, 6e Allan R. Hambley
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Figure P2.87
Electrical Engineering: Principles and Applications, 6e Allan R. Hambley
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Figure P2.91