Preface <br/>Contents <br/>Chapter 1 The Subject of Electromagnetics <br/>1.1 Historical Background <br/>1.2 Objectives of the Chapter <br/>1.3 Electric Charge <br/>1.4 Units <br/>1.5 Vectors <br/>1.6 Electrical Force, Field, Flux, and Potential <br/>1.7 Magnetic Force, Field, Flux, and Potential <br/>1.8 Electromagnetic Induction <br/>1.9 Mathematical Operators and Identities <br/>1.10 Maxwell’s Equations <br/>1.11 Electromagnetic Waves <br/>1.12 Trajectory of a Sinusoidal Motion in Two Dimensions <br/>1.13 Wave Polarization <br/>1.14 Electromagnetic Spectrum <br/>1.15 Transmission Lines <br/>Chapter 2 Vector Analysis <br/>2.1 Introduction <br/>2.2 Vector Notation <br/>2.3 Vector Functions <br/>2.4 Vector Algebra <br/>2.5 Coordinate Systems <br/>2.6 Differential Volume, Surface, and Line Elements <br/>Chapter 3 Electric Field <br/>3.1 Introduction <br/>3.2 Coulomb’s Law in Vector Form <br/>3.3 Superposition <br/>3.4 Electric Field Intensity <br/>3.5 Charge Distributions <br/>3.6 Standard Charge Configurations <br/>Chapter 4 Electric Flux <br/>4.1 Net Charge in a Region <br/>4.2 Electric Flux and Flux Density <br/>4.3 Gauss’s Law <br/>4.4 Relation between Flux Density and Electric Field Intensity <br/>4.5 Special Gaussian Surfaces <br/>Chapter 5 Gradient, Divergence, Curl, and Laplacian <br/>5.1 Introduction <br/>5.2 Gradient <br/>5.3 The Del Operator <br/>5.4 The Del Operator and Gradient <br/>5.5 Divergence <br/>5.6 Expressions for Divergence in Coordinate Systems <br/>5.7 The Del Operator and Divergence <br/>5.8 Divergence of D <br/>5.9 The Divergence Theorem <br/>5.10 Curl <br/>5.11 Laplacian <br/>5.12 Summary of Vector Operations <br/>Chapter 6 Electrostatics: Work, Energy, and Potential <br/>6.1 Work Done in Moving a Point Charge <br/>6.2 Conservative Property of the Electrostatic Field <br/>6.3 Electric Potential between Two Points <br/>6.4 Potential of a Point Charge <br/>6.5 Potential of a Charge Distribution <br/>6.6 Relationship between E and V <br/>6.7 Energy in Static Electric Fields <br/>Chapter 7 Electric Current <br/>7.1 Introduction <br/>7.2 Charges in Motion <br/>7.3 Convection Current Density J <br/>7.4 Conduction Current Density J <br/>7.5 Conductivity σ <br/>7.6 Current I <br/>7.7 Resistance R <br/>7.8 Current Sheet Density K <br/>7.9 Continuity of Current <br/>7.10 Conductor-Dielectric Boundary Conditions <br/>Chapter 8 Capacitance and Dielectric Materials <br/>8.1 Polarization P and Relative Permittivity εr <br/>8.2 Capacitance <br/>8.3 Multiple-Dielectric Capacitors <br/>8.4 Energy Stored in a Capacitor <br/>8.5 Fixed-Voltage D and E <br/>8.6 Fixed-Charge D and E <br/>8.7 Boundary Conditions at the Interface of Two Dielectrics <br/>8.8 Method of Images <br/>Chapter 9 Laplace’s Equation <br/>9.1 Introduction <br/>9.2 Poisson’s Equation and Laplace’s Equation <br/>9.3 Explicit Forms of Laplace’s Equation <br/>9.4 Uniqueness Theorem <br/>9.5 Mean Value and Maximum Value Theorems <br/>9.6 Cartesian Solution in One Variable <br/>9.7 Cartesian Product Solution <br/>9.8 Cylindrical Product Solution <br/>9.9 Spherical Product Solution <br/>Chapter 10 Magnetic Field and Boundary Conditions <br/>10.1 Introduction <br/>10.2 Biot-Savart Law <br/>10.3 Ampère’s Law <br/>10.4 Relationship of J and H <br/>10.5 Magnetic Flux Density B <br/>10.6 Boundary Relations for Magnetic Fields <br/>10.7 Current Sheet at the Boundary <br/>10.8 Summary of Boundary Conditions <br/>10.9 Vector Magnetic Potential A <br/>10.10 Stokes’ Theorem <br/>Chapter 11 Forces and Torques in Magnetic Fields <br/>11.1 Magnetic Force on Particles <br/>11.2 Electric and Magnetic Fields Combined <br/>11.3 Magnetic Force on a Current Element <br/>11.4 Work and Power <br/>11.5 Torque <br/>11.6 Magnetic Moment of a Planar Coil <br/>Chapter 12 Inductance and Magnetic Circuits <br/>12.1 Inductance <br/>12.2 Standard Conductor Configurations <br/>12.3 Faraday’s Law and Self-Inductance <br/>12.4 Internal Inductance <br/>12.5 Mutual Inductance <br/>12.6 Magnetic Circuits <br/>12.7 The B-H Curve <br/>12.8 Ampère’s Law for Magnetic Circuits <br/>12.9 Cores with Air Gaps <br/>12.10 Multiple Coils <br/>12.11 Parallel Magnetic Circuits <br/>Chapter 13 Time-Varying Fields and Maxwell’s Equations <br/>13.1 Introduction <br/>13.2 Maxwell’s Equations for Static Fields <br/>13.3 Faraday’s Law and Lenz’s Law <br/>13.4 Conductors’ Motion in Time-Independent Fields <br/>13.5 Conductors’ Motion in Time-Dependent Fields <br/>13.6 Displacement Current <br/>13.7 Ratio of Jcto JD <br/>13.8 Maxwell’s Equations for Time-Varying Fields <br/>Chapter 14 Electromagnetic Waves <br/>14.1 Introduction <br/>14.2 Wave Equations <br/>14.3 Solutions in Cartesian Coordinates <br/>14.4 Plane Waves <br/>14.5 Solutions for Partially Conducting Media <br/>14.6 Solutions for Perfect Dielectrics <br/>14.7 Solutions for Good Conductors; Skin Depth <br/>14.8 Interface Conditions at Normal Incidence <br/>14.9 Oblique Incidence and Snell’s Laws <br/>14.10 Perpendicular Polarization <br/>14.11 Parallel Polarization <br/>14.12 Standing Waves <br/>14.13 Power and the Poynting Vector <br/>Chapter 15 Transmission Lines <br/>15.1 Introduction <br/>15.2 Distributed Parameters <br/>15.3 Incremental Models <br/>15.4 Transmission Line Equation <br/>15.5 Impedance, Admittance, and Other Features of Interest <br/>15.6 Sinusoidal Steady-State Excitation <br/>15.7 Lossless Lines <br/>15.8 The Smith Chart <br/>15.9 Admittance Plane <br/>15.10 Quarter-Wave Transformer <br/>15.11 Impedance Matching <br/>15.12 Single-Stub Matching <br/>15.13 Double-Stub Matching <br/>15.14 Impedance Measurement <br/>15.15 Transients in Lossless Lines <br/>Chapter 16 Waveguides <br/>16.1 Introduction <br/>16.2 Transverse and Axial Fields <br/>16.3 TE and TM Modes; Wave Impedances <br/>16.4 Determination of the Axial Fields <br/>16.5 Mode Cutoff Frequencies <br/>16.6 Dominant Mode <br/>16.7 Power Transmitted in a Lossless Waveguide <br/>16.8 Power Dissipation in a Lossy Waveguide <br/>Chapter 17 Antennas <br/>17.1 Introduction <br/>17.2 Current Source and the E and H Fields <br/>17.3 Electric (Hertzian) Dipole Antenna <br/>17.4 Antenna Parameters <br/>17.5 Small Circular-Loop Antenna <br/>17.6 Finite-Length Dipole <br/>17.7 Monopole Antenna <br/>17.8 Self- and Mutual Impedances <br/>17.9 The Receiving Antenna <br/>17.10 Linear Arrays <br/>17.11 Reflectors <br/>Chapter 18 Propagation of Electromagnetic Waves in the Atmosphere <br/>18.1 Introduction and Summary <br/>18.2 Plane Waves in Homogeneous Media <br/>18.3 Propagation Parameters <br/>18.4 Complex Dielectric Constant <br/>18.5 Power Equation <br/>18.6 Refraction <br/>18.7 Reflection, Diffraction, and Scattering <br/>18.8 The Atmosphere <br/>18.9 Atmospheric Effects on Propagation of Radio Waves <br/>18.10 Attenuation by Gaseous Absorption <br/>18.11 Attenuation by Hydrometeors <br/>18.12 Ground and Sky Waves <br/>18.13 Models of the Troposphere <br/>18.14 Tropospheric Refractivity <br/>18.15 Tropospheric Excess Delay <br/>18.16 Bending Effect of Tropospheric Refraction <br/>18.17 Conductivity, Permittivity, and Refraction Index of the Ionosphere <br/>18.18 Satellite Microwave Ranging <br/>18.19 Ionospheric Range Error <br/>18.20 Tropospheric Range Error <br/>Appendix <br/>Index <br/>Advertisement