- Book Name: Circuit Analysis Theory and Practice 5th Edition by Robbins and Miller
- Author: Robbins and Miller
- Pages: 1042
- Size: 76 MB
Circuit Analysis Theory and Practice Pdf Free Download

Contents of Circuit Analysis Theory and Practice Pdf
I Foundation dc Concepts
1 Introduction
1.1 Introduction
1.2 The SI System of Units
1.3 Converting Units
1.4 Power of Ten Notation
1.5 Prefixes, Engineering Notation, and Numerical Results
1.6 Circuit Diagrams
1.7 Circuit Analysis Using Computers and Calculators
2 Voltage and Current
2.1 Atomic Theory Review
2.2 The Unit of Electrical Charge: The Coulomb
2.3 Voltage
2.4 Current
2.5 Practical dc Voltage Sources
2.6 Measuring Voltage and Current
2.7 Switches, Fuses, and Circuit Breakers
3 Resistance
3.1 Resistance of Conductors
3.2 Electrical Wire Tables
3.3 Resistance of Wires—Circular Mils
3.4 Temperature Effects
3.5 Types of Resistors
3.6 Color Coding of Resistors
3.7 Measuring Resistance—The Ohmmeter
3.8 Thermistors
3.9 Photoconductive Cells
3.10 Nonlinear Resistance
3.11 Conductance
3.12 Superconductors
4 Ohm’s Law, Power, and Energy
4.1 Ohm’s Law
4.2 Voltage Polarity and Current Direction
4.3 Power
4.4 Power Direction Convention
4.5 Energy
4.6 Efficiency
4.7 Nonlinear and Dynamic Resistances
4.8 Computer-Aided Circuit Analysis
5 Series Circuits
5.1 Series Circuits
5.2 Kirchhoff’s Voltage Law
5.3 Resistors in Series
5.4 Voltage Sources in Series
5.5 Interchanging Series Components
5.6 The Voltage Divider Rule
5.7 Circuit Ground
5.8 Voltage Subscripts
5.9 Internal Resistance of Voltage Sources
5.10 Ammeter Loading Effects
5.11 Circuit Analysis Using Computers
6 Parallel Circuits
6.1 Parallel Circuits
6.2 Kirchhoff’s Current Law
6.3 Resistors in Parallel
6.4 Voltage Sources in Parallel
6.5 Current Divider Rule
6.6 Analysis of Parallel Circuits
6.7 Voltmeter Loading Effects
6.8 Circuit Analysis Using Computers
7 Series-Parallel Circuits
7.1 The Series-Parallel Network
7.2 Analysis of Series-Parallel Circuits
7.3 Applications of Series-Parallel Circuits
7.4 Potentiometers
7.5 Loading Effects of Instruments
7.6 Circuit Analysis Using Computers
8 Methods of Analysis
8.1 Constant-Current Sources
8.2 Source Conversions
8.3 Current Sources in Parallel and Series
8.4 Branch-Current Analysis
8.5 Mesh (Loop) Analysis
8.6 Nodal Analysis
8.7 Delta-Wye (Pi-Tee) Conversion
8.8 Bridge Networks
8.9 Circuit Analysis Using Computer
9 Network Theorems
9.1 Superposition Theorem
9.2 Thévenin’s Theorem
9.3 Norton’s Theorem
9.4 Maximum Power Transfer Theorem
9.5 Substitution Theorem
9.6 Millman’s Theorem
9.7 Reciprocity Theorem
9.8 Circuit Analysis Using Computers
10 Capacitors and Capacitance
10.1 Capacitance
10.2 Factors Affecting Capacitance
10.3 Electric Fields
10.4 Dielectrics
10.5 Nonideal Effects
10.6 Types of Capacitors
10.7 Capacitors in Parallel and Series
10.8 Capacitor Current and Voltage During Charging
10.9 Energy Stored by a Capacitor
10.10 Capacitor Failures and Troubleshooting
11 Capacitor Charging, Discharging, and Simple Waveshaping Circuits
11.1 Introduction
11.2 Capacitor Charging Equations
11.3 Capacitor with an Initial Voltage
11.4 Capacitor Discharging Equations
11.5 More Complex Circuits
11.6 An RC Timing Application
11.7 Pulse Response of RC Circuits
11.8 Transient Analysis Using Computers
12 Magnetism and Magnetic Circuits
12.1 The Nature of a Magnetic Field
12.2 Electromagnetism
12.3 Magnetic Flux and Flux Density
12.4 Magnetic Circuits and Their Applications
12.5 Air Gaps, Fringing, and Laminated Cores
12.6 Series Elements and Parallel Elements
12.7 Magnetic Circuits with dc Excitation
12.8 Magnetic Field Intensity and Magnetization Curves
12.9 Ampere’s Circuital Law
12.10 Series Magnetic Circuits: Given , Find NI
12.11 Series-Parallel Magnetic Circuits
12.12 Series Magnetic Circuits: Given NI, Find
12.13 Force Due to an Electromagnet
12.14 Properties of Magnetic Materials
12.15 Sensing and Measuring Magnetic Fields
13 Inductance and Inductors
13.1 Electromagnetic Induction
13.2 Induced Voltage and Inductance
13.3 Self-Inductance
13.4 Computing Induced Voltage
13.5 Inductances in Series and Parallel
13.6 Practical Considerations
13.7 Inductance and Steady State dc
13.8 Energy Stored by an Inductance 449
13.9 Inductor Troubleshooting Hints
14 Inductive Transients
14.1 Introduction
14.2 Current Buildup Transients
14.3 Interrupting Current in an Inductive Circuit
14.4 De-Energizing Transients
14.5 More Complex Circuits
14.6 RL Transients Using Computers
15 AC Fundamentals
15.1 Introduction
15.2 Generating ac Voltages
15.3 Voltage and Current Conventions for ac
15.4 Frequency, Period, Amplitude, and Peak Value
15.5 Angular and Graphic Relationships for Sine Waves
15.6 Voltages and Currents as Functions of Time
15.7 Introduction to Phasors
15.8 ac Waveforms and Average Value
15.9 Effective (RMS) Values
15.10 Rate of Change of a Sine Wave (Derivative)
15.11 AC Voltage and Current Measurement
15.12 Circuit Analysis Using Computers
16 R, L, and C Elements and the Impedance Concept
16.1 Complex Number Review
16.2 Complex Numbers in ac Analysis
16.3 R, L, and C Circuits with Sinusoidal Excitation
16.4 Resistance and Sinusoidal ac
16.5 Inductance and Sinusoidal ac
16.6 Capacitance and Sinusoidal ac
16.7 The Impedance Concept
16.8 Computer Analysis of ac Circuits
17 Power in ac Circuits
17.1 Introduction
17.2 Power to a Resistive Load
17.3 Power to an Inductive Load
17.4 Power to a Capacitive Load
17.5 Power in More Complex Circuits
17.6 Apparent Power 580
17.7 The Relationship between P, Q, and S
17.8 Power Factor
17.9 ac Power Measurement
17.10 Effective Resistance
17.11 Energy Relationships for ac
17.12 Circuit Analysis Using Computers
18 AC Series-Parallel Circuits
18.1 Ohm’s Law for ac Circuits
18.2 AC Series Circuits
18.3 Kirchhoff’s Voltage Law and the Voltage Divider Rule
18.4 AC Parallel Circuits
18.5 Kirchhoff’s Current Law and the Current Divider Rule
18.6 Series-Parallel Circuits
18.7 Frequency Effects
18.8 Applications
18.9 Circuit Analysis Using Computers
19 Methods of ac Analysis
19.1 Dependent Sources
19.2 Source Conversion
19.3 Mesh (Loop) Analysis
19.4 Nodal Analysis 668
19.5 Delta-to-Wye and Wye-to-Delta Conversions
19.6 Bridge Networks
19.7 Circuit Analysis Using Computers
20 AC Network Theorems
20.1 Superposition Theorem—Independent Sources
20.2 Superposition Theorem—Dependent Sources
20.3 Thévenin’s Theorem—Independent Sources
20.4 Norton’s Theorem—Independent Sources
20.5 Thévenin’s and Norton’s Theorems for Dependent Sources
20.6 Maximum Power Transfer Theorem
20.7 Circuit Analysis Using Computers
21 Resonance
21.1 Series Resonance
21.2 Quality Factor, Q
21.3 Impedance of a Series Resonant Circuit
21.4 Power, Bandwidth, and Selectivity of a Series Resonant Circuit
21.5 Series-to-Parallel RL and RC Conversion
21.6 Parallel Resonance
21.7 Circuit Analysis Using Computers
22 Filters and the Bode Plot
22.1 The Decibel
22.2 Multistage Systems
22.3 Simple RC and RL Transfer Functions
22.4 The Low-Pass Filter
22.5 The High-Pass Filter
22.6 The Band-Pass Filter
22.7 The Band-Reject Filter
22.8 Circuit Analysis Using Computers
23 Transformers and Coupled Circuits
23.1 Introduction
23.2 Iron-Core Transformers: The Ideal Model
23.3 Reflected Impedance
23.4 Power Transformer Ratings
23.5 Transformer Applications
23.6 Practical Iron-Core Transformers
23.7 Transformer Tests
23.8 Voltage and Frequency Effects
23.9 Loosely Coupled Circuits
23.10 Magnetically Coupled Circuits with Sinusoidal
23.11 Coupled Impedance
23.12 Circuit Analysis Using Computers
24 Three-Phase Systems
24.1 Three-Phase Voltage Generation
24.2 Basic Three-Phase Circuit Connections
24.3 Basic Three-Phase Relationships
24.4 Examples 888
24.5 Power in a Balanced System
24.6 Measuring Power in Three-Phase Circuits
24.7 Unbalanced Loads
24.8 Power System Loads
24.9 Circuit Analysis Using Computers
25 Nonsinusoidal Waveforms
25.1 Composite Waveforms
25.2 Fourier Series
25.3 Fourier Series of Common Waveforms
25.4 Frequency Spectrum
25.5 Circuit Response to a Nonsinusoidal Waveform
25.6 Circuit Analysis Using Computers
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