chapter 3 resistive circuits
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Chapter 3 Resistive Circuits. Adjustable Voltage Source. Figure 3.1-1 The circuit being designed provides an adjustable voltage, v, to the load circuit. Figure 3.1-2 (a) A proposed circuit for producing the variable voltage v (b) the equivalent circuit after the potentiometer is modeled. - PowerPoint PPT PresentationTRANSCRIPT
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Chapter 3
Resistive Circuits
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Figure 3.1-1The circuit being designed provides an adjustable voltage, v, to the load circuit.
Figure 3.1-2(a) A proposed circuit for producing the variable voltage v(b) the equivalent circuit after the potentiometer is modeled
Adjustable Voltage Source
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Kirchhoff’s Law
Figure 3.3-1(a) An electric circuit. (b) The same circuit, redrawn using straight lines and horizontal and vertical elements. (c) The circuit after labeling the nodes and elements.
Example 3.3-1
Figure 3.3-2 Four circuit drawings.
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Kirchhoff’s Law
Kirchhoff’s Current Law (KCL)The algebraic sum of the currents into a node at any instant is zero
Kirchhoff’s Voltage Law (KVL)The algebraic sum of the voltages around any loop in a circuit is identically zero for all time
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Example 3.3-2
Kirchhoff’s Law
Figure 3.3-4 (a) The circuit considered in Example 3.3.2 and (b) the circuit redrawn to emphasize the nodes.
Example 3.3-3
Figure 3.3-5Circuit with two constant-voltage sources.
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Figure 3.3-6(a)Circuit with dependent source and an ammeter(b)Equivalent circuit after replacing the ammeter by a short circuit
Example 3.3-4
Figure 3.3-7The circuit of Figure 3.3-10 after labeling the nodes and some element currents and voltages.
Kirchhoff’s Law
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Figure 3.3-8(a)Circuit with dependent source and a voltmeter(b)Equivalent circuit after replacing the voltmeter by a open circuit.
Figure 3.3-9The circuit of Figure 3.3-12b after labeling the nodes and some element currents and voltages.
Example 3.3-5
Kirchhoff’s Law
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Exercise 3.3-1
Exercise 3.3-2
Exercise 3.3-4
Kirchhoff’s Law
Exercise 3.3-3
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Figure 3.4-1Single loop circuit with a voltage source vs.
- KCL
- KVL
A Single Loop Circuit – Voltage Divider
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Figure 3.4-2Voltage divider circuit with R1=9Ω
Figure 3.4-3Equivalent circuit for a series connection of resistors.
Example 3.4-1
A Single Loop Circuit – Voltage Divider
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Figure 3.4-4(a) A circuit containing series resistors(b) The circuit after the ideal ammeter has been replaced by the equivalent short circuit and a label has been added to indicate the current measured by the ammeter, im.
Example 3.4-2
A Single Loop Circuit – Voltage Divider
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Exercise 3.4-1
Exercise 3.4-3
Exercise 3.4-4
Exercise 3.4-2
A Single Loop Circuit – Voltage Divider
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Figure 3.5-1A circuit with a current wource.
Figure 3.5-2Parallel circuit with a current source.
Figure 3.5-3Equivalent circuit for a parallel circuit.
Parallel Resistors and Current Division
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Figure 3.5-4Set of N parallel conductances with a current source is.
Parallel Resistors and Current Division
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Example 3.5-1
Example 3.5-2
Figure 3.5-7(a) A circuit containing parallel resistors(b) The circuit after the ideal voltmeter has been replaced by the equivalent open circuit and a label has been added to indicated the voltage measured by the voltmeter, vm.(c) The circuit after the parallel resistors have been replaced by an equivalent resistance.
Parallel Resistors and Current Division
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Parallel Resistors and Current Division
Exercise 3.5-2
Exercise 3.5-1
Figure E3.5-2(a) A current divider. (b) The current divider after the ideal ammeter has been replaced by the equivalent short circuit and a label has been added to indicate the current measured by the ammeter im.
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Figure 3.6-1(a) A circuit containing voltage sources connected in series(b) an equivalent circuit.
Serious Voltage Source and Parallel Current Source
Figure 3.6-2(a) A circuit containing parallel current sources
(b) an equivalent circuit.
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Table 3.6-1Parallel and Series Voltage and Current Sources.
Serious Voltage Source and Parallel Current Source
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Figure 3.7-1Circuit with a set of series resistors and a set of parallel resistors.
Figure 3.7-2Equivalent circuit of Figure 3.7-1.
Circuit Analysis
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Figure 3.7-3(a) Circuit for Example 3.7-1. (b) Partially reduced circuit.
Figure 3.7-4 Equivalent circuit.
Example 3.7-1
Circuit Analysis
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Example 3.7-2
Figure 3.7-5.
Circuit Analysis
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Figure 3.7-6The equivalent resistance looking into terminals c-d is denoted as Reqc-d .
Circuit Analysis
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Exercise 3.7-1
Exercise 3.7-2
Exercise 3.7-3
Circuit Analysis
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Figure 3.8-1 (a) A resistive circuit and (b) an equivalent circuit.
Circuit Analysis using MATLAB
Figure 3.8-2 Plot of I versus Vs for the circuit shown in Figure 3.8-1.
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Figure 3.9-1 (a) An example circuit and (b) computer analysis using Mathcad.
Circuit Analysis using Mathcad
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Figure 3.10-1 The circuit being designed provides an adjustable voltage, v, to the load circuit.
Adjustable Voltage Source
Figure 3.10-3 The circuit after setting R1=R2=R.
Figure 3.10-2 (a) A proposed circuit for producing the variable voltage, v, and (b) the equivalent circuit after the potentiometer is modeled.
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Table 3.12-1Equivalent Circuits for Series and Parallel Elements.
Equivalent Circuits
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Problems 3.3 – 2, 4, 7, 93.4 – 2, 4, 63.5 – 2, 4, 63.7 – 2, 4, 6, 10, 14
Homework #2