Circuit analysis I : with MATLAB applications / Steven T. Karris.

Format:

Book

Author/Creator:

Karris, Steven T.

Language:

English

Subjects (All):

MATLAB.

Electric circuit analysis--Data processing.

Electric circuit analysis.

Physical Description:

vi, 592 p. : ill.

Place of Publication:

Fremont, Calif. : Orchard Publications, c2003.

Language Note:

English

Summary:

This text is an introduction to the basic principles of electrical engineering. It is intended for all engineering majors and presumes knowledge of first year differential and integral calculus and physics. The last two chapters include step-by-step procedures for the solutions of simple differential equations used in the derivation of the natural and forces responses. Appendix A is an introduction to MATLAB, and Appendices B and C provide a thorough review of complex numbers and matrices respectively.

Contents:

Cover - Front

Front matter

Preface

Table of Contents

Chapter 1 Concepts and Definitions

Chapter 2 Analysis of Simple Circuits

Chapter 3 Nodal and Mesh Equations - Circuit Theorems

Chapter 4 Introduction to Operational Amplifiers

Chapter 5 Inductance and Capacitance

Chapter 6 Sinusoidal Circuit Analysis

Chapter 7 Phasor Circuit Analysis

Chapter 8 Average and RMS Values, Complex Power, and Instruments

Chapter 9 Natural Response

Chapter 10 Forced and Total Response in RL and RC Circuits

Appendix A Introduction to MATLAB®

Appendix B A Review of Complex Numbers

Appendix C Matrices and Determinants

Chapter 01 Basic Concepts and Definitions

1.14 Answers to Exercises

1.13 Exercises

1.1 The Coulomb

1.2 Electric Current and Ampere

1.3 Two Terminal Devices

1.4 Voltage (Potential Difference)

1.5 Power and Energy

1.6 Active and Passive Devices

1.7 Circuits and Networks

1.8 Active and Passive Networks

1.9 Necessary Conditions for Current Flow

1.10 International System of Units

1.11 Sources of Energy

1.12 Summary

Chapter 02 Analysis of Simple Circuits

2.1 Conventions

2.2 Ohm's Law

2.3 Power Absorbed by a Resistor

2.4 Energy Dissipated in a Resistor

2.5 Nodes, Branches, Loops and Meshes

2.6 Kirchhoff's Current Law (KCL)

2.7 Kirchhoff's Voltage Law (KVL)

2.8 Single Mesh Circuit Analysis

2.9 Single Node-Pair Circuit Analysis

2.10 Voltage and Current Source Combinations

2.11 Resistance and Conductance Combinations

2.12 Voltage Division Expressions

2.13 Current Division Expressions

2.14 Standards for Electrical and Electronic Devices

2.15 Resistor Color Code

2.16 Power Rating of Resistors

2.17 Temperature Coefficient of Resistance

2.18 Ampere Capacity of Wires

2.19 Current Ratings for Electronic Equipment.

2.20 Copper Conductor Sizes for Interior Wiring

2.21 Summary

2.22 Exercises

2.23 Answers to Exercises

Chapter 03 Nodal and Mesh Equationbs - Circuit Theorems

3.1 Nodal, Mesh, and Loop Equations

3.2 Analysis with Nodal Equations

3.3 Analysis with Mesh or Loop Equations

3.4 Transformation between Voltage and Current Sources

3.5 Thevenin's Theorem

3.6 Norton's Theorem

3.7 Maximum Power Transfer Theorem

3.8 Linearity

3.9 Superposition Principle

3.10 Circuits with Non-Linear Devices

3.11 Efficiency

3.12 Regulation

3.13 Summary

3.14 Exercises

3.15 Answers to Exercises

Chapter 04 Introduction to Operational Amplifiers

4.1 Signals

4.2 Amplifiers

4.3 Decibels

4.4 Bandwidth and Frequency Response

4.5 The Operational Amplifier

4.6 An Overview of the Op Amp

4.7 Active Filters

4.8 Analysis of Op Amp Circuits

4.9 Input and Output Resistance

4.10 Summary

4.11 Exercises

4.12 Answers to Exercises

Chapter 05 Inductance and Capacitance

5.1 Energy Storage Devices

5.2 Inductance

5.3 Power and Energy in an Inductor

5.4 Combinations of Series and Parallel Inductors

5.5 Capacitance

5.6 Power and Energy in a Capacitor

5.7 Capacitance Combinations

5.8 Nodal and Mesh Equations in General Terms

5.9 Summary

5.10 Exercises

5.11 Answers to Exercises

Chapter 06 Sinusoidal Circuit Analysis

6.1 Excitation Functions

6.2 Circuit Response to Sinusoidal Inputs

6.3 The Complex Excitation Function

6.4 Phasors in R, L, and C Circuits

6.5 Impedance

6.6 Admittance

6.7 Summary

6.8 Exercises

6.9 Answers to Exercises

Chapter 07 Phasor Circuit Analysis

7.1 Nodal Analysis

7.2 Mesh Analysis

7.3 Application of Superposition Principle

7.4 Thevenin's and Norton's Theorems

7.5 Phasor Analysis in Amplifier Circuits.

7.6 Phasor Diagrams

7.7 Electric Filters

7.8 Basic Analog Filters

7.9 Active Filter Analysis

7.10 Summary

7.11 Exercises

7.12 Answers to Exercises

Chapter 08 Average and RMS Values, Complex Power, and Instruments

8.1 Periodic Time Functions

8.2 Average Values

8.3 Effective Values

8.4 Effective (RMS) Value of Sinusoids

8.5 RMS Values of Sinusoids with Different Frequencies

8.6 Average Power and Power Factor

8.7 Average Power in a Resistive Load

8.8 Average Power in Inductive and Capacitive Loads

8.9 Average Power in Non-Sinusoidal Waveforms

8.10 Lagging and Leading Power Factors

8.11 Complex Power - Power Triangle

8.12 Power Factor Correction

8.13 Instruments

8.14 Summary

8.15 Exercises

8.16 Answers to Exercises

Chapter 09 Natural Response

9.1 The Natural Response of a Series RL circuit

9.2 The Natural Response of a Series RC Circuit

9.3 Summary

9.4 Exercises

9.5 Answers to Exercises

10.1 The Unit Step Function

10.2 The Unit Ramp Function

10.3 The Delta Function

10.4 The Forced and Total Response in an RL Circuit

10.5 The Forced and Total Response in an RC Circuit

10.6 Summary

10.7 Exercises

10.8 Answers to Exercises

Appendix A Introduction to MATLAB

A.1 MATLAB® and Simulink®

A.2 Command Window

A.3 Roots of Polynomials

A.4 Polynomial Construction from Known Roots

A.5 Evaluation of a Polynomial at Specified Values

A.6 Rational Polynomials

A.7 Using MATLAB to Make Plots

A.8 Subplots

A.9 Multiplication, Division and Exponentiation

A.10 Script and Function Files

A.11 Display Formats

B.1 Definition of a Complex Number

B.2 Addition and Subtraction of Complex Numbers.

B.3 Multiplication of Complex Numbers

B.4 Division of Complex Numbers

B.5 Exponential and Polar Forms of Complex Numbers

C.1 Matrix Definition

C.2 Matrix Operations

C.3 Special Forms of Matrices

C.4 Determinants

C.5 Minors and Cofactors

C.6 Cramer's Rule

C.7 Gaussian Elimination Method

C.8 The Adjoint of a Matrix

C.9 Singular and Non-Singular Matrices

C.10 The Inverse of a Matrix

C.11 Solution of Simultaneous Equations with Matrices

C.12 Exercises

Index.

Notes:

Title from title screen.

Includes index.

Digitized and made available by: Books 24x7.com.

Description based on publisher supplied metadata and other sources.

ISBN:

1-280-43705-7

9786610437054

0-9744239-3-9

OCLC:

923318780