Electromagnetic fields

Professor Jean Van Bladel, an eminent researcher and educator in fundamental electromagnetic theory and its application in electrical engineering, has updated and expanded his definitive text and reference on electromagnetic fields to twice its original content. This new edition incorporates the latest methods, theory, formulations, and applications that relate to today's technologies. With an emphasis on basic principles and a focus on electromagnetic formulation and analysis, Electromagnetic Fields, Second Edition includes detailed discussions of electrostatic fields, potential theory, propagation in waveguides and unbounded space, scattering by obstacles, penetration through apertures, and field behavior at high and low frequencies.

Preface xiii 1. Linear Analysis 1 1.1 Linear Spaces 2 1.2 Linear Transformations 5 1.3 The Inversion Problem 8 1.4 Green's Functions 11 1.5 Reciprocity 14 1.6 Green's Dyadics 17 1.7 Convergence of a Series 19 1.8 Eigenfunctions 20 1.9 Integral Operators 23 1.10 Eigenfunction Expansions 26 1.11 Discretization 30 1.12 Matrices 33 1.13 Solution of Matrix Equations: Stability 36 1.14 Finite Differences 38 1.15 Perturbations 43 2. Variational Techniques 51 2.1 Stationary functionals 52 2.2 A Suitable Functional for the String Problem 53 2.3 Functionals for the General l Transformation 55 2.4 Euler's Equations of Some Important Functionals 58 2.5 Discretization of the Trial Functions 60 2.6 Simple Finite Elements for Planar Problems 62 2.7 More Finite Elements 65 2.8 Direct Numerical Solution of Matrix Problems 69 2.9 Iterative Numerical Solution of Matrix Problems 70 3. Electrostatic Fields in the Presence of Dielectrics 77 3.1 Volume Charges in Vacuum 77 3.2 Green's Function for Infinite Space 80 3.3 Multipole Expansion 83 3.4 Potential Generated by a Single Layer of Charge 86 3.5 Potential Generated by a Double Layer of Charge 91 3.6 Potential Generated by a Linear Charge 94 3.7 Spherical Harmonics 98 3.8 Dielectric Materials 102 3.9 Cavity Fields 105 3.10 Dielectric Sphere in an External Field 108 3.11 Dielectric Spheroid in an Incident Field 111 3.12 Numerical Methods 115 4. Electrostatic Fields in the Presence of Conductors 125 4.1 Conductivity 125 4.2 Potential Outside a Charged Conductor 127 4.3 Capacitance Matrix 133 4.4 The Dirichlet Problem 134 4.5 The Neumann Problem 137 4.6 Numerical Solution of the Charge Density Problem 139 4.7 Conductor in an External Field 142 4.8 Conductors in the Presence of Dielectrics 146 4.9 Current Injection into a Conducting Volume 148 4.10 Contact Electrodes 153 4.11 Chains of Conductors 158 5. Special Geometries for the Electrostatic Field 167 5.1 Two-Dimensional Potentials in the Plane 167 5.2 Field Behavior at a Conducting Wedge 171 5.3 Field Behavior at a Dielectric Wedge 175 5.4 Separation of Variables in Two Dimensions 177 5.5 Two-Dimensional Integral Equations 181 5.6 Finite Methods in Two Dimensions 185 5.7 Infinite Computational Domains 188 5.8 More Two-Dimensional Techniques 192 5.9 Layered Media 196 5.10 Apertures 199 5.11 Axisymmetric Geometries 203 5.12 Conical Boundaries 207 6. Magnetostatic Fields 221 6.1 Magnetic Fields in Free Space: Vector Potential 221 6.2 Fields Generated by Linear Currents 224 6.3 Fields Generated by Surface Currents 227 6.4 Fields at Large Distances from the Sources 229 6.5 Scalar Potential in Vacuum 232 6.6 Magnetic Materials 234 6.7 Permanent Magnets 236 6.8 The Limit of Infinite Permeability 239 6.9 Two-Dimensional Fields in the Plane 244 6.10 Axisymmetric Geometries 249 6.11 Numerical Methods: Integral Equations 251 6.12 Numerical Methods: Finite Elements 253 6.13 Nonlinear Materials 258 6.14 Strong Magnetic Fields and Force-Free Currents 260 7. Radiation in Free Space 277 7.1 Maxwell's Equations 277 7.2 The Wave Equation 280 7.3 Potentials 282 7.4 Sinusoidal Time Dependence: Polarization 286 7.5 Partially Polarized Fields 290 7.6 The Radiation Condition 293 7.7 Time-Harmonic Potentials 296 7.8 Radiation Patterns 300 7.9 Green's Dyadics 303 7.10 Multipole Expansion 307 7.11 Spherical Harmonics 313 7.12 Equivalent Sources 320 7.13 Linear Wire Antennas 327 7.14 Curved Wire Antennas: Radiation 333 7.15 Transient Sources 337 8. Radiation in a Material Medium 357 8.1 Constitutive Equations 357 8.2 Plane Waves 370 8.3 Ray Methods 377 8.4 Beamlike Propagation 388 8.5 Green's Dyadics 392 8.6 Reciprocity 397 8.7 Equivalent Circuit of an Antenna 402 8.8 Effective Antenna Area 409 9. Plane Boundaries 423 9.1 Plane Wave Incident on a Plane Boundary 423 9.2 Propagation Through a Layered Medium 442 9.3 The Sommerfeld Dipole Problem 448 9.4 Multilayered Structures 452 9.5 Periodic Structures 460 9.6 Field Penetration Through Apertures 478 9.7 Edge Diffraction 490 10. Resonators 509 10.1 Eigenvectors for an Enclosed Volume 509 10.2 Excitation of a Cavity 514 10.3 Determination of the Eigenvectors 517 10.4 Resonances 525 10.5 Open Resonators: Dielectric Resonances 529 10.6 Aperture Coupling 540 10.7 Green's Dyadics 544 11. Scattering: Generalities 563 11.1 The Scattering Matrix 563 11.2 Cross Sections 568 11.3 Scattering by a Sphere 574 11.4 Resonant Scattering 582 11.5 The Singularity Expansion Method 586 11.6 Impedance Boundary Conditions 598 11.7 Thin Layers 601 11.8 Characteristic Modes 604 12. Scattering: Numerical Methods 617 12.1 The Electric Field Integral Equation 617 12.2 The Magnetic Field Integral Equation 624 12.3 The T-Matrix 629 12.4 Numerical Procedures 633 12.5 Integral Equations for Penetrable Bodies 639 12.6 Absorbing Boundary Conditions 646 12.7 Finite Elements 651 12.8 Finite Differences in the Time Domain 654 13. High- and Low-Frequency Fields 671 13.1 Physical Optics 671 13.2 Geometrical Optics 676 13.3 Geometric Theory of Diffraction 681 13.4 Edge Currents and Equivalent Currents 689 13.5 Hybrid Methods 692 13.6 Low-Frequency Fields: The Rayleigh Region 695 13.7 Non-Conducting Scatterers at Low Frequencies 696 13.8 Perfectly Conducting Scatterers at Low Frequencies 699 13.9 Good Conductors 707 13.10 Stevenson's Method Applied to Good Conductors 711 13.11 Circuit Parameters 715 13.12 Transient Eddy Currents 719 14. Two-Dimensional Problems 733 14.1 E and H Waves 733 14.2 Scattering by Perfectly Conducting Cylinders 738 14.3 Scattering by Penetrable Circular Cylinders 743 14.4 Scattering by Elliptic Cylinders 746 14.5 Scattering by Wedges 749 14.6 Integral Equations for Perfectly Conducting Cylinders 751 14.7 Scattering by Penetrable Cylinders 759 14.8 Low-Frequency Scattering by Cylinders 764 14.9 Slots in a Planar Screen 770 14.10 More Slot Couplings 778 14.11 Termination of a Truncated Domain 786 14.12 Line Methods 792 16.2 Scattering by Bodies of Revolution: Integral Equations 908 16.3 Scattering by Bodies of Revolution: Finite Methods 912 16.4 Apertures in Axisymmetric Surfaces 915 16.5 The Conical Waveguide 918 16.6 Singularities at the Tip of a Cone 926 16.7 Radiation and Scattering from Cones 930 15. Cylindrical Waveguides 813 15.1 Field Expansions in a Closed Waveguide 814 15.2 Determination of the Eigenvectors 818 15.3 Propagation in a Closed Waveguide 822 15.4 Waveguide Losses 832 15.5 Waveguide Networks 837 15.6 Aperture Excitation and Coupling 844 15.7 Guided Waves in General Media 859 15.8 Orthogonality and Normalization 865 15.9 Dielectric Waveguides 873 15.10 Other Examples of Waveguides 882 16. Axisymmetric and Conical Boundaries 905 16.1 Field Expansions for Axisymmetric Geometries 905 17. Electrodynamics of Moving Bodies 943 17.1 Fields Generated by a Moving Charge 943 17.2 The Lorentz Transformation 946 17.3 Transformation of Fields and Currents 950 17.4 Radiation from Sources: the Doppler Effect 955 17.5 Constitutive Equations and Boundary Conditions 958 17.6 Material Bodies Moving Uniformly in Static Fields 960 17.7 Magnetic Levitation 962 17.8 Scatterers in Uniform Motion 966 17.9 Material Bodies in Nonuniform Motion 972 17.10 Rotating Bodies of Revolution 974 17.11 Motional Eddy Currents 979 17.12 Accelerated Frames of Reference 984 17.13 Rotating Comoving Frames 988 Appendix 1. Vector Analysis in Three Dimensions 1001 Appendix 9. Some Eigenfunctions and Eigenvectors 1105 Appendix 2. Vector Operators in Several Coordinate Systems 1011 Appendix 10. Miscellaneous Data 1111 Appendix 3. Vector Analysis on a Surface 1025 Appendix 4. Dyadic Analysis 1035 Appendix 5. Special Functions 1043 Appendix 6. Complex Integration 1063 Appendix 7. Transforms 1075 Appendix 8. Distributions 1089 Bibliography 1117 General Texts on Electromagnetic Theory 1117 Texts that Discuss Particular Areas of Electromagnetic Theory 1118 General Mathematical Background 1122 Mathematical Techniques Specifically Applied to Electromagnetic Theory 1123 Acronyms and Symbols 1127 Author Index 1133 Subject Index 1149