Electromagnetic FieldsProfessor 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. |
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... numerical analyst, including the popular method of moments • Comprehensive discussion of singularities of sources and fields with delineations of field properties at edges and at sector and cone vertices • Extensive appendices that of ...
... numerical analyst, including the popular method of moments • Comprehensive discussion of singularities of sources and fields with delineations of field properties at edges and at sector and cone vertices • Extensive appendices that of ...
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Page vii
... Numerical Solution of Matrix Problems 69 2.9 Iterative Numerical Solution of Matrix Problems 70 1. Linear Analysis 1.1 Linear Spaces 2 3. Electrostatic Fields in the Presence of Dielectrics 1.2 Linear Transformations 5 1.3 The Inversion ...
... Numerical Solution of Matrix Problems 69 2.9 Iterative Numerical Solution of Matrix Problems 70 1. Linear Analysis 1.1 Linear Spaces 2 3. Electrostatic Fields in the Presence of Dielectrics 1.2 Linear Transformations 5 1.3 The Inversion ...
Page viii
... Numerical Methods: 4.10 Contact Electrodes 153 Integral Equations 251 4.11 Chains of Conductors 158 Finite Elements 6.13 5. Special Geometries for the Electrostatic Field Two-Dimensional Potentials 5.1 in the Plane 167 6.12 Numerical ...
... Numerical Methods: 4.10 Contact Electrodes 153 Integral Equations 251 4.11 Chains of Conductors 158 Finite Elements 6.13 5. Special Geometries for the Electrostatic Field Two-Dimensional Potentials 5.1 in the Plane 167 6.12 Numerical ...
Page ix
... Numerical Procedures 12.5 Integral Equations for Penetrable Bodies 12.6 Absorbing Boundary 633 639 Dipole Problem 448 Conditions 646 9.4 Multilayered Structures 452 12.7 9.5 Periodic Structures 460 9.6 Field Penetration Through Finite ...
... Numerical Procedures 12.5 Integral Equations for Penetrable Bodies 12.6 Absorbing Boundary 633 639 Dipole Problem 448 Conditions 646 9.4 Multilayered Structures 452 12.7 9.5 Periodic Structures 460 9.6 Field Penetration Through Finite ...
Contents
Single Layer of Charge | 23 |
of Dielectrics | 146 |
Contents | 167 |
Special Geometries for | 258 |
221 | 357 |
Plane Boundaries | 423 |
5 | 469 |
696 | 563 |
882 | 972 |
11 | 979 |
Frames | 988 |
Vector Analysis in Three | 1001 |
Vector Operators | 1011 |
Vector Analysis on | 1025 |
Dyadic Analysis | 1035 |
Special Functions | 1043 |
Charged Conductor | 592 |
133 | 660 |
Cylinders | 751 |
Cylinders | 759 |
11 | 786 |
The Conical Waveguide | 918 |
Uniformly in Static Fields | 960 |
Axisymmetric and Conical | 966 |
Complex Integration | 1063 |
Transforms | 1075 |
Distributions | 1089 |
Miscellaneous Data | 1111 |
Bibliography | 1117 |
Mathematical Techniques Specifically | 1123 |
1133 | |
1149 | |
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Common terms and phrases
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