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Edition: 4TH 06

Copyright: 2006

Publisher: Oxford University Press

Published: 2006

International: No

Copyright: 2006

Publisher: Oxford University Press

Published: 2006

International: No

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Elements of Electromagnetics , Fourth Edition, uses a vectors-first approach to explain electrostatics, magnetostatics, fields, waves, and applications like transmission lines, waveguides, and antennas. It also provides a balanced presentation of time-varying and static fields, preparing students for employment in today's industrial and manufacturing sectors.

Streamlined to facilitate student understanding, this edition features worked examples in every chapter that explain how to use the theory presented in the text to solve different kinds of problems. Numerical methods, including MATLAB and vector analysis, are also included to help students analyze situations that they are likely to encounter in industry practice.

Elements of Electromagnetics , Fourth Edition, is designed for introductory undergraduate courses in electromagnetics. An Instructor's Solutions Manual and PowerPoint slides of all figures in the text are available to adopters.

**Features**

- Devotes an entire chapter to modern computer tools--including MATLAB--that are used in electromagnetics
- Contains more than 100 illustrations and 600 figures to help students visualize different electromagnetic phenomena
- Highlights key terms and boxes essential formulae
- Includes numerous examples-each worked step-by-step-and a set of multiple-choice review questions at the end of each chapter
- Presents a section on real-world applications of the material at the end of every chapter

PART 1: VECTOR ANALYSIS

1. Vector Algebra

1.1. Introduction

1.2. A Preview of the Book

1.3. Scalars and Vectors

1.4. Unit Vector

1.5. Vector Addition and Subtraction

1.6. Position and Distance Vectors

1.7. Vector Multiplication

1.8. Components of a Vector

2. Coordinate Systems and Transformation

2.1. Introduction

2.2. Cartesia Coordinates

2.3. Circular Cylindrical Coordinates

2.4. Spherical Coordinates

2.5. Constant-Coordinate Surfaces

3. Vector Calculus

3.1. Introduction

3.2. Differential Length, Area, and Volume

3.3. Line, Surface, and Volume Integrals

3.4. Del Operator

3.5. Gradient of a Scalar

3.6. Divergence of a Vector and Divergence Theorem

3.7. Curl of a Vector and Stokes's Theorem

3.8. Laplacian of a Scalar

3.9. Classification of Vector Fields

PART 2: ELECTROSTATICS

4. Electrostatic Fields

4.1. Introduction

4.2. Coulomb's Law and Field Intensity

4.3. Electric Fields due to Continuous Charge Distributions

4.4. Electric Flux Density

4.5. Gauss's Law--Maxwell's Equation

4.6. Applications of Gauss's Law

4.7. Electric Potential

4.8. Relationship between E and V--Maxwell's Equation

4.9. An Electric Dipole and Flux Lines

4.10. Energy Density in Electrostatic Fields

4.11. Application Note 1--Electrostatic Discharge

5. Electric Fields in Material Space

5.1. Introduction

5.2. Properties of Materials

5.3. Convection and Conduction Currents

5.4. Conductors

5.5. Polarization in Dielectrics

5.6. Dielectric Constant and Strength

5.7. Linear, Isotropic, and Homogenous Dielectrics

5.8. Continuity Equation and Relaxation Time

5.9. Boundary Conditions

5.10. Application Note 1--High Dielectric-Constant Materials

6. Electrostatic Boundary-Value Problems

6.1. Introduction

6.2. Poisson's and Laplace's Equations

6.3. Uniqueness Theorem

6.4. General Procedures for Solving Poisson's or Laplace's Equation

6.5. Resistance and Capacitance

6.6. Method of Images

6.7. Application Note 1--Capacitance of Microchip Lines

PART 3: MAGNETOSTATICS

7. Magnetostatic Fields

7.1. Introduction

7.2. Biot-Savart's Law

7.3. Ampere's Circuit Law--Maxwell's Equation

7.4. Applications of Ampere's Law

7.5. Magnetic Flux Density--Maxwell's Equation

7.6. Maxwell's Equations for Static Fields

7.7. Magnetic Scalar and Vector Potentials

7.8. Derivation of Biot-Savart's Law and Ampere's Law

7.9. Application Note 1--Lightning

8. Magnetic Forces, Materials, and Devices

8.1. Introduction

8.2. Forces due to Magnetic Fields

8.3. Magnetic Torque and Moment

8.4. A Magnetic Dipole

8.5. Magnetization in Materials

8.6. Classification of Magnetic Materials

8.7. Magnetic Boundary Conditions

8.8. Inductors and Inductances

8.9. Magnetic Energy

8.10. Magnetic Circuits

8.11. Force on Magnetic Materials

8.12. Application Note 1--Magnetic Levitation

PART 4: WAVES AND APPLICATIONS

9. Maxwell's Equations

9.1. Introduction

9.2. Faraday's Law

9.3. Transformer and Motional Electromotive Forces

9.4. Displacement Current

9.5. Maxwell's Equations in Final Forms

9.6. Time-Varying Potentials

9.7. Time-Harmonic Fields

10. Electromagnetic Wave Propagation

10.1. Introduction

10.2. Waves in General

10.3. Wave Propagation in Lossy Dielectrics

10.4. Plane Waves in Lossless Dielectrics

10.5. Plane Waves in Free Space

10.6. Plane Waves in Good Conductors

10.7. Power and the Poynting Vector

10.8. Reflection of a Plane Wave at Normal Incidence

10.9. Reflection of a Plane Wave at Oblique Incidence

10.10. Application Note 1--Microwaves

11. Transmission Lines

11.1. Introduction

11.2. Transmission Line Parameters

11.3. Transmission Line Equations

11.4. Input Impedance, Standing Wave Ratio, and Power

11.5. The Smith Chart

11.6. Some Applications of Transmission Lines

11.7. Transients on Transmission Lines

11.8. Application Notes 1--Microchip Transmission, Lines, and Characterization of Data Cables

12. Waveguides

12.1. Introduction

12.2. Rectangular Waveguides

12.3. Transverse Magnetic (TM) Modes

12.4. Transverse Electric (TE) Modes

12.5. Wave Propagation in the Guide

12.6. Power Transmission and Attenuation

12.7. Waveguide Current and Mode Excitation

12.8. Waveguide Resonators

12.9. Application Note 1--Optical Fiber

13. Antennas

13.1. Introduction

13.2. Hertzian Dipole

13.3. Half-Wave Dipole Antenna

13.4. Quarter-Wave Monopole Antenna

13.5. Small Loop Antenna

13.6. Antenna Characteristics

13.7. Antenna Arrays

13.8. Effective Area and the Friis Equation

13.9. The Radar Equation

13.10. Application Note 1--Electromagnetic Interference and Compatibility

14. Numerical Methods

14.1. Introduction

14.2. Field Plotting

14.3. The Finite Difference Method

14.4. The Moment Method

14.5. The Finite Element Method

14.6. Application Note 1--Microstrip Lines

Appendix A: Mathematical Formulas

Appendix B: Material Constants

Appendix C: MATLAB

Appendix D: The Complete Smith Chart

Appendix E: Answers to Odd-Numbered Problems

Index

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Summary

Elements of Electromagnetics , Fourth Edition, uses a vectors-first approach to explain electrostatics, magnetostatics, fields, waves, and applications like transmission lines, waveguides, and antennas. It also provides a balanced presentation of time-varying and static fields, preparing students for employment in today's industrial and manufacturing sectors.

Streamlined to facilitate student understanding, this edition features worked examples in every chapter that explain how to use the theory presented in the text to solve different kinds of problems. Numerical methods, including MATLAB and vector analysis, are also included to help students analyze situations that they are likely to encounter in industry practice.

Elements of Electromagnetics , Fourth Edition, is designed for introductory undergraduate courses in electromagnetics. An Instructor's Solutions Manual and PowerPoint slides of all figures in the text are available to adopters.

**Features**

- Devotes an entire chapter to modern computer tools--including MATLAB--that are used in electromagnetics
- Contains more than 100 illustrations and 600 figures to help students visualize different electromagnetic phenomena
- Highlights key terms and boxes essential formulae
- Includes numerous examples-each worked step-by-step-and a set of multiple-choice review questions at the end of each chapter
- Presents a section on real-world applications of the material at the end of every chapter

Table of Contents

PART 1: VECTOR ANALYSIS

1. Vector Algebra

1.1. Introduction

1.2. A Preview of the Book

1.3. Scalars and Vectors

1.4. Unit Vector

1.5. Vector Addition and Subtraction

1.6. Position and Distance Vectors

1.7. Vector Multiplication

1.8. Components of a Vector

2. Coordinate Systems and Transformation

2.1. Introduction

2.2. Cartesia Coordinates

2.3. Circular Cylindrical Coordinates

2.4. Spherical Coordinates

2.5. Constant-Coordinate Surfaces

3. Vector Calculus

3.1. Introduction

3.2. Differential Length, Area, and Volume

3.3. Line, Surface, and Volume Integrals

3.4. Del Operator

3.5. Gradient of a Scalar

3.6. Divergence of a Vector and Divergence Theorem

3.7. Curl of a Vector and Stokes's Theorem

3.8. Laplacian of a Scalar

3.9. Classification of Vector Fields

PART 2: ELECTROSTATICS

4. Electrostatic Fields

4.1. Introduction

4.2. Coulomb's Law and Field Intensity

4.3. Electric Fields due to Continuous Charge Distributions

4.4. Electric Flux Density

4.5. Gauss's Law--Maxwell's Equation

4.6. Applications of Gauss's Law

4.7. Electric Potential

4.8. Relationship between E and V--Maxwell's Equation

4.9. An Electric Dipole and Flux Lines

4.10. Energy Density in Electrostatic Fields

4.11. Application Note 1--Electrostatic Discharge

5. Electric Fields in Material Space

5.1. Introduction

5.2. Properties of Materials

5.3. Convection and Conduction Currents

5.4. Conductors

5.5. Polarization in Dielectrics

5.6. Dielectric Constant and Strength

5.7. Linear, Isotropic, and Homogenous Dielectrics

5.8. Continuity Equation and Relaxation Time

5.9. Boundary Conditions

5.10. Application Note 1--High Dielectric-Constant Materials

6. Electrostatic Boundary-Value Problems

6.1. Introduction

6.2. Poisson's and Laplace's Equations

6.3. Uniqueness Theorem

6.4. General Procedures for Solving Poisson's or Laplace's Equation

6.5. Resistance and Capacitance

6.6. Method of Images

6.7. Application Note 1--Capacitance of Microchip Lines

PART 3: MAGNETOSTATICS

7. Magnetostatic Fields

7.1. Introduction

7.2. Biot-Savart's Law

7.3. Ampere's Circuit Law--Maxwell's Equation

7.4. Applications of Ampere's Law

7.5. Magnetic Flux Density--Maxwell's Equation

7.6. Maxwell's Equations for Static Fields

7.7. Magnetic Scalar and Vector Potentials

7.8. Derivation of Biot-Savart's Law and Ampere's Law

7.9. Application Note 1--Lightning

8. Magnetic Forces, Materials, and Devices

8.1. Introduction

8.2. Forces due to Magnetic Fields

8.3. Magnetic Torque and Moment

8.4. A Magnetic Dipole

8.5. Magnetization in Materials

8.6. Classification of Magnetic Materials

8.7. Magnetic Boundary Conditions

8.8. Inductors and Inductances

8.9. Magnetic Energy

8.10. Magnetic Circuits

8.11. Force on Magnetic Materials

8.12. Application Note 1--Magnetic Levitation

PART 4: WAVES AND APPLICATIONS

9. Maxwell's Equations

9.1. Introduction

9.2. Faraday's Law

9.3. Transformer and Motional Electromotive Forces

9.4. Displacement Current

9.5. Maxwell's Equations in Final Forms

9.6. Time-Varying Potentials

9.7. Time-Harmonic Fields

10. Electromagnetic Wave Propagation

10.1. Introduction

10.2. Waves in General

10.3. Wave Propagation in Lossy Dielectrics

10.4. Plane Waves in Lossless Dielectrics

10.5. Plane Waves in Free Space

10.6. Plane Waves in Good Conductors

10.7. Power and the Poynting Vector

10.8. Reflection of a Plane Wave at Normal Incidence

10.9. Reflection of a Plane Wave at Oblique Incidence

10.10. Application Note 1--Microwaves

11. Transmission Lines

11.1. Introduction

11.2. Transmission Line Parameters

11.3. Transmission Line Equations

11.4. Input Impedance, Standing Wave Ratio, and Power

11.5. The Smith Chart

11.6. Some Applications of Transmission Lines

11.7. Transients on Transmission Lines

11.8. Application Notes 1--Microchip Transmission, Lines, and Characterization of Data Cables

12. Waveguides

12.1. Introduction

12.2. Rectangular Waveguides

12.3. Transverse Magnetic (TM) Modes

12.4. Transverse Electric (TE) Modes

12.5. Wave Propagation in the Guide

12.6. Power Transmission and Attenuation

12.7. Waveguide Current and Mode Excitation

12.8. Waveguide Resonators

12.9. Application Note 1--Optical Fiber

13. Antennas

13.1. Introduction

13.2. Hertzian Dipole

13.3. Half-Wave Dipole Antenna

13.4. Quarter-Wave Monopole Antenna

13.5. Small Loop Antenna

13.6. Antenna Characteristics

13.7. Antenna Arrays

13.8. Effective Area and the Friis Equation

13.9. The Radar Equation

13.10. Application Note 1--Electromagnetic Interference and Compatibility

14. Numerical Methods

14.1. Introduction

14.2. Field Plotting

14.3. The Finite Difference Method

14.4. The Moment Method

14.5. The Finite Element Method

14.6. Application Note 1--Microstrip Lines

Appendix A: Mathematical Formulas

Appendix B: Material Constants

Appendix C: MATLAB

Appendix D: The Complete Smith Chart

Appendix E: Answers to Odd-Numbered Problems

Index

Publisher Info

Publisher: Oxford University Press

Published: 2006

International: No

Published: 2006

International: No

Elements of Electromagnetics , Fourth Edition, uses a vectors-first approach to explain electrostatics, magnetostatics, fields, waves, and applications like transmission lines, waveguides, and antennas. It also provides a balanced presentation of time-varying and static fields, preparing students for employment in today's industrial and manufacturing sectors.

Streamlined to facilitate student understanding, this edition features worked examples in every chapter that explain how to use the theory presented in the text to solve different kinds of problems. Numerical methods, including MATLAB and vector analysis, are also included to help students analyze situations that they are likely to encounter in industry practice.

Elements of Electromagnetics , Fourth Edition, is designed for introductory undergraduate courses in electromagnetics. An Instructor's Solutions Manual and PowerPoint slides of all figures in the text are available to adopters.

**Features**

- Devotes an entire chapter to modern computer tools--including MATLAB--that are used in electromagnetics
- Contains more than 100 illustrations and 600 figures to help students visualize different electromagnetic phenomena
- Highlights key terms and boxes essential formulae
- Includes numerous examples-each worked step-by-step-and a set of multiple-choice review questions at the end of each chapter
- Presents a section on real-world applications of the material at the end of every chapter

PART 1: VECTOR ANALYSIS

1. Vector Algebra

1.1. Introduction

1.2. A Preview of the Book

1.3. Scalars and Vectors

1.4. Unit Vector

1.5. Vector Addition and Subtraction

1.6. Position and Distance Vectors

1.7. Vector Multiplication

1.8. Components of a Vector

2. Coordinate Systems and Transformation

2.1. Introduction

2.2. Cartesia Coordinates

2.3. Circular Cylindrical Coordinates

2.4. Spherical Coordinates

2.5. Constant-Coordinate Surfaces

3. Vector Calculus

3.1. Introduction

3.2. Differential Length, Area, and Volume

3.3. Line, Surface, and Volume Integrals

3.4. Del Operator

3.5. Gradient of a Scalar

3.6. Divergence of a Vector and Divergence Theorem

3.7. Curl of a Vector and Stokes's Theorem

3.8. Laplacian of a Scalar

3.9. Classification of Vector Fields

PART 2: ELECTROSTATICS

4. Electrostatic Fields

4.1. Introduction

4.2. Coulomb's Law and Field Intensity

4.3. Electric Fields due to Continuous Charge Distributions

4.4. Electric Flux Density

4.5. Gauss's Law--Maxwell's Equation

4.6. Applications of Gauss's Law

4.7. Electric Potential

4.8. Relationship between E and V--Maxwell's Equation

4.9. An Electric Dipole and Flux Lines

4.10. Energy Density in Electrostatic Fields

4.11. Application Note 1--Electrostatic Discharge

5. Electric Fields in Material Space

5.1. Introduction

5.2. Properties of Materials

5.3. Convection and Conduction Currents

5.4. Conductors

5.5. Polarization in Dielectrics

5.6. Dielectric Constant and Strength

5.7. Linear, Isotropic, and Homogenous Dielectrics

5.8. Continuity Equation and Relaxation Time

5.9. Boundary Conditions

5.10. Application Note 1--High Dielectric-Constant Materials

6. Electrostatic Boundary-Value Problems

6.1. Introduction

6.2. Poisson's and Laplace's Equations

6.3. Uniqueness Theorem

6.4. General Procedures for Solving Poisson's or Laplace's Equation

6.5. Resistance and Capacitance

6.6. Method of Images

6.7. Application Note 1--Capacitance of Microchip Lines

PART 3: MAGNETOSTATICS

7. Magnetostatic Fields

7.1. Introduction

7.2. Biot-Savart's Law

7.3. Ampere's Circuit Law--Maxwell's Equation

7.4. Applications of Ampere's Law

7.5. Magnetic Flux Density--Maxwell's Equation

7.6. Maxwell's Equations for Static Fields

7.7. Magnetic Scalar and Vector Potentials

7.8. Derivation of Biot-Savart's Law and Ampere's Law

7.9. Application Note 1--Lightning

8. Magnetic Forces, Materials, and Devices

8.1. Introduction

8.2. Forces due to Magnetic Fields

8.3. Magnetic Torque and Moment

8.4. A Magnetic Dipole

8.5. Magnetization in Materials

8.6. Classification of Magnetic Materials

8.7. Magnetic Boundary Conditions

8.8. Inductors and Inductances

8.9. Magnetic Energy

8.10. Magnetic Circuits

8.11. Force on Magnetic Materials

8.12. Application Note 1--Magnetic Levitation

PART 4: WAVES AND APPLICATIONS

9. Maxwell's Equations

9.1. Introduction

9.2. Faraday's Law

9.3. Transformer and Motional Electromotive Forces

9.4. Displacement Current

9.5. Maxwell's Equations in Final Forms

9.6. Time-Varying Potentials

9.7. Time-Harmonic Fields

10. Electromagnetic Wave Propagation

10.1. Introduction

10.2. Waves in General

10.3. Wave Propagation in Lossy Dielectrics

10.4. Plane Waves in Lossless Dielectrics

10.5. Plane Waves in Free Space

10.6. Plane Waves in Good Conductors

10.7. Power and the Poynting Vector

10.8. Reflection of a Plane Wave at Normal Incidence

10.9. Reflection of a Plane Wave at Oblique Incidence

10.10. Application Note 1--Microwaves

11. Transmission Lines

11.1. Introduction

11.2. Transmission Line Parameters

11.3. Transmission Line Equations

11.4. Input Impedance, Standing Wave Ratio, and Power

11.5. The Smith Chart

11.6. Some Applications of Transmission Lines

11.7. Transients on Transmission Lines

11.8. Application Notes 1--Microchip Transmission, Lines, and Characterization of Data Cables

12. Waveguides

12.1. Introduction

12.2. Rectangular Waveguides

12.3. Transverse Magnetic (TM) Modes

12.4. Transverse Electric (TE) Modes

12.5. Wave Propagation in the Guide

12.6. Power Transmission and Attenuation

12.7. Waveguide Current and Mode Excitation

12.8. Waveguide Resonators

12.9. Application Note 1--Optical Fiber

13. Antennas

13.1. Introduction

13.2. Hertzian Dipole

13.3. Half-Wave Dipole Antenna

13.4. Quarter-Wave Monopole Antenna

13.5. Small Loop Antenna

13.6. Antenna Characteristics

13.7. Antenna Arrays

13.8. Effective Area and the Friis Equation

13.9. The Radar Equation

13.10. Application Note 1--Electromagnetic Interference and Compatibility

14. Numerical Methods

14.1. Introduction

14.2. Field Plotting

14.3. The Finite Difference Method

14.4. The Moment Method

14.5. The Finite Element Method

14.6. Application Note 1--Microstrip Lines

Appendix A: Mathematical Formulas

Appendix B: Material Constants

Appendix C: MATLAB

Appendix D: The Complete Smith Chart

Appendix E: Answers to Odd-Numbered Problems

Index