电磁场与电磁波（第2版）

　　本书是关于电磁场与电磁波的一本很有特色的教材，取材新颖，笔法灵活，逻辑性强。教材从矢量分析和场论人手，以简捷清晰的方式建立了电磁模型。紧接着，全面地阐述了电磁场和电磁波的基础理论，包括静电场、静磁场、稳恒电流的场、边值问题的经典解法、时变电磁场与麦克斯韦方程组、平面电磁波及其传播、传输线、阻抗圆图、微带线、波导与谐振腔、天线与电磁辐射、电磁屏蔽等内容。本书除了内容全面之外，还具有很大的灵活性，这是因为全书的内容安排具有较完整的模块性，从而可以灵活地取舍和组合成适合不同行业和不同对象的电磁场与电磁波的教材。本书特别适合用作理科大学本科高年级和工科院校硕士研究生基础课的英文授课教材或英文参考书。

暂缺《电磁场与电磁波（第2版）》作者简介

1 The Electromagnetic Model
　1-1 Introduction
　1-2 The Electromagnetic Model
　1-3 SI Units and Universal Constants
　Review Questions
2 Vector Analysis
　2-1 Introduction
　2-2 Vector Addition and Subtraction
　2-3 Products of Vectors
　　2-3.1 Scalar or Dot Product
　　2-3.2 Vector or Cross Product
　　2-3.3 Product of Three Vectors
　2-4 Orthogonal Coordinate Systems
　　2-4.1 Cartesian Coordinates
　　2-4.2 Cylindrical Coordinates
　　2-4.3 Spherical Coordinates
　2-5 Integrals Containing Vector Functions
　2-6 Gradient of a Scalar Field
　2-7 Divergence of a Vector Field
　2-8 Divergence Theorem
　2-9 Curt of a Vector Field
　2-10 Stokes's Theorem
　2-11 Two Null Identities
　　2-11.1 Identity Ⅰ
　　2-11.2 Identity Ⅱ
　2-12 Helmholtz's Theorem
　Review Questions
　Problems
3 Static Electric Fields
　3-1 Introduction
　3-2 Fundamental Postulates of Electrostatics in Free Space
　3-3 Coulomb's Law
　　3-3.1 Electric Field Due to a System of Discrete Charges
　　3-3.2 Electric Field Due to a Continuous Distribution of Charge
　3-4 Gauss's Law and Applications
　3-5 Electric Potential
　　3 5.1 Electric Potential Due to a Charge Distribution
　3-6 Conductors in Static Electric Field
　3-7 Dielectrics in Static Electric Field
　　3-7.1 Equivalent Charge Distributions of Polarized Dielectrics
　3-8 Electric Flux Density and Dielectric Constant
　　3-8.1 Dielectric Strength
　3-9 Boundary Conditions for Electrostatic Fields
　3-10 Capacitance and Capacitors
　　3-10.1 Series and Parallel Connections of Capacitors
　　3-10.2 Capacitances in Multiconductor Systems
　　3-10.3 Electrostatic Shielding
　3-11 Electrostatic Energy and Forces
　　3-11.1 Electrostatic Energy in Terms of Field Quantities
　　3-11.2 Electrostatic Forces
　Review Questions
　Problems
4 Solution of Electrostatic Problems
　4-1 Introduction
　4-2 Poisson's and Laplace's Equations
　4-3 Uniqueness of Electrostatic Solutions
　4-4 Method of Images
　　4-4.1 Point Charge and Conducting Planes
　　4-4.2 Line Charge and Parallel Conducting Cylinder
　　4-4.3 Point Charge and Conducting Sphere
　　4-4.4 Charged Sphere and Grounded Plane
　4-5 Boundary-Value Problems in Cartesian Coordinates
　4-6 Boundary-Value Problems in Cylindrical Coordinates
　4-7 Boundary-Value Problems in Spherical Coordinates
　Review Questions
　Problems
5 Steady Electric Currents
　5-1 Introduction
　5-2 Current Density and Ohm's Law
　5-3 Electromotive Force and Kirchhoff's Voltage Law
　5-4 Equation of Continuity and Kirchhoff's Current Law
　5-5 Power Dissipation and Joule's Law
　5-6 Boundary Conditions for Current Density
　5-7 Resistance Calculations
　Review Questions
　Problems
6 Static Magnetic Fields
　6-1 Introduction
　6-2 Fundamental Postulates of Magnetostatics in Free Space
　6-3 Vector Magnetic Potential
　6-4 The Biot-Savart Law and Applications
　6-5 The Magnetic Dipole
　　6-5.1 Scalar Magnetic Potential
　6-6 Magnetization and Equivalent Current Densities
　　6-6.1 Equivalent Magnetization Charge Densities
　6-7 Magnetic Field Intensity and Relative Permeability
　6-8 Magnetic Circuits
　6-9 Behavior of Magnetic Materials
　6-10 Boundary Conditions for Magnetostatic Fields
　6-11 Inductances and Inductors
　6-12 Magnetic Energy
　　6-12.1 Magnetic Energy in Terms of Field Quantities
　6-13 Magnetic Forces and Torques
　　6-13.1 Hall Effect
　　6-13.2 Forces and Torques on Current-Carrying Conductors
　　6-13.3 Forces and Torques in Terms of Stored Magnetic Energy
　　6-13.4 Forces and Torques in Terms of Mutual Inductance
　Review Questions
　Problems
7 Time-Varying Fields and Maxwelrs Equations
　7-1 Introduction
　7-2 Faraday's Law of Electromagnetic Induction
　　7-2.1 A Stationary Circuit in a Time-Varying Magnetic Field
　　7-2.2 Transformers
　　7-2.3 A Moving Conductor in a Static Magnetic Field
　　7-2.4 A Moving Circuit in a Time-Varying Magnetic Field
　7-3 Maxwell's Equations
　　7-3.1 Integral Form of Maxwell's Equations
　7-4 Potential Functions
　7-5 Electromagnetic Boundary Conditions
　　7-5.1 Interface between Two Lossless Linear Media
　　7-5.2 Interface between a Dielectric and a Perfect Conductor
　7-6 Wave Equations and Their Solutions
　　7-6.1 Solution of Wave Equations for Potentials
　　7-6.2 Source-Free Wave Equations
　7-7 Time-Harmonic Fields
　　7-7.1 The Use of Phasors—A Review
　　7-7.2 Time-Harmonic Electromagnetics
　　7-7.3 Source-Free Fields in Simple Media
　　7-7.4 The Electromagnetic Spectrum
　Review Questions
　Problems
8 Plane Electromagnetic Waves
　8-1 Introduction
　8-2 Plane Waves in Lossless Media
　　8-2.1 Doppler Effect
　　8-2.2 Transverse Electromagnetic Waves
　　8-2.3 Polarization of Plane Waves
　8-3 Plane Waves in Lossy Media
　　8-3.1 Low-Loss Dielectrics
　　8-3.2 Good Conductors
　　8-3.3 Ionized Gases
　8-4 Group Velocity
　8-5 Flow of Electromagnetic Power and the Poynting Vector
　　8-5.1 Instantaneous and Average Power Densities
　8-6 Normal Incidence at a Plane Conducting Boundary
　8-7 Oblique Incidence at a Plane Conducting Boundary
　　8-7.1 Perpendicular Polarization
　　8-7.2 Parallel Polarization
　8-8 Normal Incidence at a Plane Dielectric Boundary
　8-9 Normal Incidence at Multiple Dielectric Interfaces
　　8-9.1 Wave Impedance of the Total Field
　　8-9.2 Impedance Transformation with Multiple Dielectrics
　8-10 Oblique Incidence at a Plane Dielectric Boundary
　　8-10.l Total Reflection
　　8-10.2 Perpendicular Polarization
　　8-10.3 Parallel Polarization
　Review Questions
　Problems
9 Theory and Applications of Transmission Lines
　9-1 Introduction
　9-2 Transverse Electromagnetic Wave along a Parallel-Plate Transmission Line
　　9-2.1 Lossy Parallel-Plate Transmission Lines
　　9-2.2 Microstrip Lines
　9-3 General Transmission-Line Equations
　　9-3.1 Wave Characteristics on an Infinite Transmission Line
　　9-3.2 Transmission-Line Parameters
　　9-3.3 Attenuation Constant from Power Relations
　9-4 Wave Characteristics on Finite Transmission Lines
　　9-4.1 Transmission Lines as Circuit Elements
　　9-4.2 Lines with Resistive Termination
　　9-4.3 Lines with Arbitrary Termination
　　9-4.4 Transmissionq~ine Circuits
　9-5 Transients on Transmission Lines
　　9-5.1 Reflection Diagrams
　　9-5.2 Pulse Excitation
　　9-5.3 Initially Charged Line
　　9-5.4 Line with Reactive Load
　9-6 The Smith Chart
　　9-6.1 Smith-Chart Calculations for Lossy Lines
　9-7 Transmission-Line Impedance Matching
　　9-7.1 Impedance Matching by Quarter-Wave Transformer
　　9-7.2 Single-Stub Matching
　　9-7.3 Double-Stub Matching
　Review Questions
　Problems
10 Waveguides and Cavity Resonators
　10-1 Introduction
　10-2 General Wave Behaviors along Uniform Guiding Structures
　　10-2.1 Transverse Electromagnetic Waves
　　10-2.2 Transverse Magnetic Waves
　　10-2.3 Transverse Electric Waves
　10-3 Parallel-Plate Waveguide
　　10-3.1 TM Waves between Parallel Plates
　　10-3.2 TE Waves between Parallel Plates
　　10-3.3 Energy-Transport Velocity
　　10-3.4 Attenuation in Parallel-Plate Waveguides
　10-4 Rectangular Waveguides
　　10-4.1 TM Waves in Rectangular Waveguides
　　10-4.2 TE Waves in Rectangular Waveguides
　　10-4.3 Attenuation in Rectangular Waveguides
　　10-4.4 Discontinuities in Rectangular Waveguides
　10-5 Circular Waveguides
　　10-5.1 Bessel's Differential Equation and Bessel Functions
　　10-5.2 TM Waves in Circular Waveguides
　　10-5.3 TE Waves in Circular Waveguides
　10-6 Dielectric Waveguides
　　10-6.1 TM Waves along a Dielectric Slab
　　10-6.2 TE Waves along a Dielectric Slab
　　10-6.3 Additional Comments on Dielectric Waveguides
　10-7 Cavity Resonators
　　10-7.1 Rectangular Cavity Resonators
　　10-7.2 Quality Factor of Cavity Resonator
　　10-7.3 Circular Cavity Resonator
　Review Questions
　Problems
11 Antennas and Radiating Systems
　11-1 Introduction
　11-2 Radiation Fields of Elemental Dipoles
　　11-2.1 The Elemental Electric Dipole
　　11-2.2 The Elemental Magnetic Dipole
　11-3 Antenna Patterns and Antenna Parameters
　11-4 Thin Linear Antennas
　　11-4.1 The Half-Wave Dipole
　　11-4.2 Effective Antenna Length
　11-5 Antenna Arrays
　　11-5.1 Two-Element Arrays
　　11-5.2 General Uniform Linear Arrays
　11-6 Receiving Antennas
　　11-6.1 Internal Impedance and Directional Pattern
　　11-6.2 Effective Area
　　11-6.3 Backscatter Cross Section
　11-7 Transmit-Receive Systems
　　11-7.1 Friis Transmission Formula and Radar Equation
　　11-7.2 Wave Propagation near Earth's Surface
　11-8 Some Other Antenna Types
　　11-8.1 Traveling-Wave Antennas
　　11-8.2 Helical Antennas
　　11-8.3 Yagi-Uda Antenna
　　11-8.4 Broadband Antennas
　11-9 Aperture Radiators
　　References
　　Review Questions
　　Problems
Appendixes
A Symbols and Units
　A-1 Fundamental SI (Rationalized MKSA) Units
　A-2 Derived Quantities
　A-3 Multiples and Submultiples of Units
B Some Useful Material Constants
　B-1 Constants of Free Space
　B-2 Physical Constants of Electron and Proton
　B-3 Relative Permittivities(Dielectric Constants)
　B-4 Conductivities
　B-5 Relative Permeabilities
C Index of Tables
General Bibliography
Answers to Selected Problems
Index
Some Useful Items
　Some Useful Vector Identities
　Gradient, Divergence, Curl, and Laplacian Operations in Cartesian Coordinates
　Gradient, Divergence, Curl, and Laplacian Operations in Cylindrical and Spherical Coordinates