Synopses & Reviews
Fundamental of Engineering Electromagnetics not only presents the fundamentals of electromagnetism in a concise and logical manner, but also includes a variety of interesting and important applications. While adapted from his popular and more extensive work,
Field and Wave Electromagnetics, this text incorporates a number of innovative pedagogical features. Each chapter begins with an overview, which serves to offer qualitative guidance to the subject matter and motivate the student. Review questions and worked examples throughout each chapter reinforce the student's understanding of the material. Remarks boxes following the review questions and margin notes throughout the book serve as additional pedagogical aids.
Back Cover
Fundamentals of Engineering Electromagnetics is a shorter version of Dr. Cheng's best-selling Field and Wave Electromagnetics, Second Edition. Fundamentals has been written in summaries. Emphasizes examples and exercises that invite students to build their knowledge of electromagnetics by solving problems.
Besides presenting electromagnetics in a concise and logical manner, the text covers application topics such as electric motors, transmission lines, waveguides, antennas, antenna arrays, and radar systems.
Synopsis
Back Cover
Fundamentals of Engineering Electromagnetics is a shorter version of Dr. Cheng's best-selling Field and Wave Electromagnetics, Second Edition. Fundamentals has been written in summaries. Emphasizes examples and exercises that invite students to build their knowledge of electromagnetics by solving problems.
Besides presenting electromagnetics in a concise and logical manner, the text covers application topics such as electric motors, transmission lines, waveguides, antennas, antenna arrays, and radar systems.
Synopsis
This book is designed for use as an undergraduate text on engineering electromagnetics. Electromagnetics is one of the most fundamental subjects in an electrical engineering curriculum. Knowledge of the laws governing electric and magnetic fields is essential to the understanding of the principle of operation of electric and magnetic instruments and machines, and mastery of the basic theory of electromagnetic waves is indispensible to explaining action-at-a-distance electromagnetic phenomena and systems.
Description
Includes bibliographical references (p. 473-474) and indexes.
Table of Contents
1. The Electromagnetic Model.
Overview. The electromagnetic model. SI units and universal constants. Summary.
2. Vector Analysis.
Overview. Vector addition and subtraction. Vector multiplication. Orthogonal coordinate systems. Gradient of a scalar field. Divergence of a vector field. Divergence theorem. Curl of a vector field. Stoke's theorem. Two null identities. Field classification and Helmholtz's theorem. Summary. Problems.
3. Static Electric Fields.
Overview. Fundamental postulates of electrostatics in free space. Coulomb's law. Gauss's law and applications. Electric potential. Material media in static electric field. Electric flux density and dielectric constant. Boundary conditions for electrostatic fields. Capacitances and capacitors. Electrostatic energy and forces. Solution of electrostatic boundary-value problems. Summary. Problems.
4. Steady Electric Currents.
Overview. Current density and Ohm's law. Equation of continuity and Kirchoff's current law. Power dissipation and Joule's law. Governing equations for steady current density. Resistance calculations. Summary. Problems.
5. Static Magnetic Fields.
Overview. Fundamental postulates of magnetostatics in free space. Vector magnetic potential. The Biot-Savart law and applications. The magnetic dipole. Magnetization and equivalent current densities. Magnetic field intensity and relative permeability. Behavior of magnetic materials. Boundary conditions for magnetostatic fields. Inductances and inductors. Magnetic energy. Magnetic forces and torques. Summary. Problems.
6. Time-Varying Fields and Maxwell's Equations.
Overview. Faraday's law of electromagnetic induction. Maxwell's equations. Potential functions. Time-harmonic fields. Summary. Problems.
7. Plane Electromagnetic Waves.
Overview. Plane waves in lossless media. Plane waves in lossy media. Group velocity. Flow of electromagentic power and the poynting vector. Normal incidence of plane waves at plane boundaries. Oblique incidence of plane waves at plane boundaries. Summary. Problems.
8. Transmission Lines.
Overview. General transmission-line equations. Transmission-line parameters. Wave characteristics on an infinite transmission line. Wave characteristics on finite transmission lines. The Smith chart. Transmission-line impedance matching. Summary. Problems.
9. Waveguides and Cavity Resonators.
Overview. General wave behaviors along uniform guiding structures. Rectrangular waveguides. Other waveguide types. Cavity resonators. Summary. Problems.
10. Antennas and Antenna Arrays.
Overview. The elemental electric dipole. Antenna patterns and directivity. Thin linear antennas. Antenna arrays. Effective area and backscatter cross section. Friis transmission formula and radar equation. Summary. Problems.
Appendix A: Symbols and Units.
Appendix B: Some Useful Material Constants.
Bibliography.
Answers to Odd-numbered Problems.
Index.
Back Endpapers.