Engineering Electromagnetics and Waves is designed for upper-division college and university engineering students, for those who wish to learn the subject through self-study, and for practicing engineers who need an up-to-date reference text. The student using this text is assumed to have completed typical lower-division courses in physics and mathematics as well as a first course on electrical engineering circuits.
This book provides engineering students with a solid grasp of electromagnetic fundamentals and electromagnetic waves by emphasizing physical understanding and practical applications. The topical organization of the text starts with an initial exposure to transmission lines and transients on high-speed distributed circuits, naturally bridging electrical circuits and electromagnetics.
Teaching and Learning Experience
This program will provide a better teaching and learning experience–for you and your students. It provides:
● Modern Chapter Organization
● Emphasis on Physical Understanding
● Detailed Examples, Selected Application Examples, and Abundant Illustrations
● Numerous End-of-chapter Problems,
● Emphasizing Selected Practical Applications
● Historical Notes on the Great Scientific Pioneers
● Emphasis on Clarity without Sacrificing Rigor and Completeness
● Hundreds of Footnotes Providing Physical Insight, Leads for Further Reading, and Discussion of Subtle and Interesting Concepts and Applications.
Cover
Title Page
Contents
Preface
Biography
1 Introduction
1.1 Lumped versus Distributed Electrical Circuits
1.2 Electromagnetic Components
1.3 Maxwell’s Equations and Electromagnetic Waves
1.4 Summary
2 Transient Response of Transmission Lines
2.1 Heuristic Discussion of Transmission Line Behavior and Circuit Models
2.2 Transmission Line Equations and Wave Solutions
2.3 Reflection at Discontinuities
2.4 Transient Response of Transmission Lines with Resistive Terminations
2.5 Transient Response of Transmission Lines with Reactive Terminations
2.6 Time-Domain Reflectometry
2.7 Transmission Line Parameters
2.8 Summary
3 Steady-State Waves on Transmission Lines
3.1 Wave Solutions Using Phasors
3.2 Voltage and Current on Lines with Short- or Open-Circuit Terminations
3.3 Lines Terminated in an Arbitrary Impedance
3.4 Power Flow on a Transmission Line
3.5 Impedance Matching
3.6 The Smith Chart
3.7 Sinusoidal Steady-State Behavior of Lossy Lines
3.8 Summary
4 The Static Electric Field
4.1 Electric Charge
4.2 Coulomb’s Law
4.3 The Electric Field
4.4 The Electric Potential
4.5 Electric Flux and Gauss’s Law
4.6 Divergence: Differential Form of Gauss’s Law
4.7 Metallic Conductors
4.8 Poisson’s and Laplace’s Equations
4.9 Capacitance
4.10 Dielectric Materials
4.11 Electrostatic Boundary Conditions
4.12 Electrostatic Energy
4.13 Electrostatic Forces
4.14 Microelectromechanical Systems (MEMS)
4.15 Summary
5 Steady Electric Currents
5.1 Current Density and the Microscopic View of Conduction
5.2 Current Flow, Ohm’s Law, and Resistance
5.3 Electromotive Force and Kirchhoff’s Voltage Law
5.4 The Continuity Equation and Kirchhoff’s Current Law
5.5 Redistribution of Free Charge
5.6 Boundary Conditions for Steady Current Flow
5.7 Duality of J and D: The Resistance–Capacitance Analogy
5.8 Joule’s Law
5.9 Surface and Line Currents
5.10 Summary
6 The Static Magnetic Field
6.1 Ampere’s Law of Force
6.2 The Biot–Savart Law and Its Applications
6.3 Ampere’s Circuital Law
6.4 Curl of the Magnetic Field: Differential Form of Ampere’s Law
6.5 Vector Magnetic Potential
6.6 The Magnetic Dipole
6.7 Divergence of B, Magnetic Flux, and Inductance
6.8 Magnetic Fields in Material Media
6.9 Boundary Conditions for Magnetostatic Fields
6.10 Magnetic Forces and Torques
6.11 Summary
7 Time-Varying Fields and Maxwell’s Equations
7.1 Faraday’s Law
7.2 Induction Due to Motion
7.3 Energy in a Magnetic Field
7.4 Displacement Current and Maxwell’s Equations
7.5 Review of Maxwell’s Equations
7.6 Summary
8 Waves in an Unbounded Medium
8.1 Plane Waves in a Simple, Source-Free, and Lossless Medium
8.2 Time-Harmonic Uniform Plane Waves in a Lossless Medium
8.3 Plane Waves in Lossy Media
8.4 Electromagnetic Energy Flow and the Poynting Vector
8.5 Polarization of Electromagnetic Waves
8.6 Arbitrarily Directed Uniform Plane Waves
8.7 Nonplanar Electromagnetic Waves
8.8 Summary
9 Reflection, Transmission, and Refraction of Waves at Planar Interfaces
9.1 Normal Incidence on a Perfect Conductor
9.2 Normal Incidence on a Lossless Dielectric
9.3 Multiple Dielectric Interfaces
9.4 Normal Incidence on a Lossy Medium
9.5 Oblique Incidence upon a Perfect Conductor
9.6 Oblique Incidence at a Dielectric Boundary
9.7 Total Internal Reflection
9.8 Oblique Incidence on a Lossy Medium
9.9 Summary
10 Parallel-Plate and Dielectric Slab Waveguides
10.1 Waves between Parallel Metal Plates
10.2 Dielectric Waveguides
10.3 Wave Velocities and Waveguide Dispersion
10.4 Summary
11 Field–Matter Interactions and Metamaterials
11.1 Wave Propagation in Ionized Gases (Plasmas)
11.2 Frequency Response of Dielectrics and Conductors
11.3 Metamaterials
11.4 Summary
A Vector Analysis
A.1 VECTOR COMPONENTS, UNIT VECTORS, AND VECTOR ADDITION
A.2 Vector Multiplication
A.3 Cylindrical and Spherical Coordinate Systems
A.4 Vector Identities
B Uniqueness Theorem
C Derivation of Ampere’s Circuital Law from the Biot–Savart Law
Symbols and Units for Basic Quantities
General Bibliography
Answers to Odd-Numbered Problems
Index
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