Integral equation methods for electromagnetics /

This text/reference is a detailed look at the development and use of integral equation methods for electromagnetic analysis, specifically for antennas and radar scattering. Developers and practitioners will appreciate the broad-based approach to understanding and utilizing integral equation methods...

Descripción completa

Detalles Bibliográficos
Clasificación:Libro Electrónico
Autor principal: Volakis, John Leonidas, 1956-
Otros Autores: Sertel, Kubilay
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Raleigh, NC : SciTech Pub., ©2012.
Temas:
Electromagnetic fields > Mathematical models.
Integral equations.
Champs électromagnétiques > Modèles mathématiques.
Équations intégrales.
SCIENCE > Waves & Wave Mechanics.
Electromagnetic fields > Mathematical models
Integral equations
computational electromagnetics.
electromagnetic field theory.
integral equations.
antenna theory.
Acceso en línea:Texto completo
Tabla de Contenidos:
  • 1. Fundamental Concepts and Theorems; 1.1 Maxwell's Equation in Differential Time Domain Form; 1.2 Maxwell's Equations in Integral Form; 1.3 Maxwell's Equations in Phasor Form; 1.4 Natural Boundary Conditions; 1.5 Poynting's Theorem; 1.6 Uniqueness Theorem; 1.7 Superposition Theorem; 1.8 Duality Theorem; 1.9 Volume Equivalence Theorem; 1.10 Surface Equivalence Theorem; 1.11 Reciprocity and Reaction Theorems; 1.12 Approximate Boundary Conditions; Problems; Bibliography; 2. Field Solutions and Representations; 2.1 Field Solutions in Terms of Vector and Hertz Potentials
  • 2.2 Solution for the Vector and Scalar Potentials2.3 Near- and Far-Zone Field Expressions; 2.4 Direct Solution of the Vector Wave Equation; 2.5 Two-Dimensional Fields; 2.6 Spectral Field Representations; 2.7 Radiation over a Dielectric Half Space; Problems; Bibliography; 3. Integral Equations and Other Field Representations; 3.1 Three-Dimensional Integral Equations; 3.2 Two-Dimensional Representations; Problems; Bibliography; 4. Solution of Integral Equations for Wire Radiatorsand Scatterers; 4.1 Formulation; 4.2 Basis Functions; 4.3 Pulse-Basis-Point-Matching Solution; 4.4 Source Modeling
  • 4.5 Calculation of the Far-Zone Field and AntennaCharacteristics4.6 Piecewise Sinusoidal-Basis-Point-Matching Solution; 4.7 Method of Weighted Residuals/Method of Moments; 4.8 Method of Moments for Nonlinear Wires; 4.9 Wires of Finite Conductivity; 4.10 Construction of Integral Equations via the Reaction/Reciprocity Theorem; 4.11 Iterative Solution Methods: The Conjugate Gradient Method Problems; Problems; Bibliography; 5. Two-Dimensional Scattering; 5.1 Flat Resistive Strip; 5.2 Metallic Cylinders; 5.3 H-Polarized (TE) Scattering by Curved Resistive Strips
  • 5.4 Piecewise Homogeneous Dielectric Cylinders5.5 Elimination of Interior Resonances; 5.6 Simulation of Inhomogeneous Dielectric Cylinders; Bibliography; 6. Three-Dimensional Scattering; 6.1 Scattering by Metallic Bodies; 6.2 Curved Triangular and Quadrilateral Elements; 6.3 Evaluation of MoM Matrix Entries; 6.4 Volumetric Modeling; 6.5 Scattering Examples; 6.6 Step by Step Moment Method Example; Bibliography; 7. Fast Multipole Method and Its Multilevel Implementation; 7.1 Fast Multipole Method; 7.2 Multilevel Fast Multipole Method; 7.3 MLFMM Formulation; 7.4 Radiation and Scattering Exa
  • 7.5 MLFMM for Volume Integral EquationsBibliography; Appendix: Integral Equations for Microstrip Antennas; A.1 Dyadic Green's Function for a Grounded Substrate; A.2 Moment Method Formulation; A.3 Far-Zone Field Evaluation; Bibliography; Index

Ejemplares similares