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Radiation and Propagation of Electromagnetic Waves /
Radiation and Propagation of Electromagnetic Waves serves as a text in electrical engineering or electrophysics. The book discusses the electromagnetic theory; plane electromagnetic waves in homogenous isotropic and anisotropic media; and plane electromagnetic waves in inhomogenous stratified media....
| Clasificación: | Libro Electrónico |
|---|---|
| Autor principal: | |
| Formato: | Electrónico eBook |
| Idioma: | Inglés |
| Publicado: |
New York :
Academic Press,
1969.
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| Colección: | Electrical science series.
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| Temas: | |
| Acceso en línea: | Texto completo |
Tabla de Contenidos:
- Front Cover; Radiation and Propagation of Electromagnetic Waves; Copyright Page; Dedication; Table of Contents; PREFACE; ACKNOWLEDGMENTS; CHAPTER 1. ELECTROMAGNETIC THEORY; 1.1 Maxwell's Equations; 1.2 Macroscopic Properties of Matter; 1.3 Energy and Power; 1.4 Boundary Conditions; 1.5 The Wave Equation; 1.6 Electromagnetic Potentials in Homogeneous Isotropic Media; 1.7 Uniqueness Theorem for Electromagnetic Boundary Value Problems; 1.8 The Dirac Delta Function; Problems; References; CHAPTER 2. PLANE WAVES IN HOMOGENEOUS ISOTROPIC MEDIA; 2.1 General Properties of Plane Waves.
- 2.2 Spectral Decomposition2.3 Inhomog�eneo us Plane Waves; 2.4 Reflection and Refraction; 2.5 The Zenneck Surface Wave; 2.6 The Lateral Wave; 2.7 The Impedance Concept and Boundary Conditions; 2.8 System of Parallel Plane Layers; Problems; References; CHAPTER 3. PLANE WAVES IN HOMOGENEOUS ANISOTROPIC MEDIA; 3.1 Electrically Anisotropic Media; 3.2 Magnetically Anisotropic Media; 3.3 Plane Waves in Magnetoplasmas; 3.4 Plane Waves in Magnetized Ferrites; Problems; References; CHAPTER 4. PLANE WAVES IN INHOMOGENEOUS STRATIFIED MEDIA; 4.1 The Characteristic Differential Equations.
- 4.2 General Solution4.3 Specific Inhomogeneity Profiles; 4.4 The WKB Approximation; 4.5 Geometrical Optics Approximation; Problems; References; CHAPTER 5. SPECTRAL REPRESENTATION OF ELEMENTARY SOURCES; 5.1 Integration of the Wave Equation; 5.2 Spectral Representation of Dipoles and Line Sources; 5.3 Asymptotic Evaluation of Integrals; Problems; References; CHAPTER 6. FIELD OF A DIPOLE IN A STRATIFIED MEDIUM; 6.1 Vertical Electric Dipole above an Interface; 6.2 Vertical Electric Dipole above a Conducting Earth (Sommerfeld Problem).
- 6.3 Vertical Electric Dipole above a Slightly Conducting Plasma6.4 Vertical Electric Dipole in a Three-Layer Medium; Problems; References; CHAPTER 7. RADIATION IN ANISOTROPIC PLASMA; 7.1 Electric Dipole in Magnetoplasma; 7.2 Magnetic Line Source in Magnetoplasma; 7.3 Radiation from a Magnetic Current Line Source in the Presence of a Separation Boundary; Problems; References; CHAPTER 8. GREEN'S FUNCTION METHOD OF SOLUTION; 8.1 Self-Adjoint Boundary Value Problems; 8.2 Examples of Eigenfunction Expansion; 8.3 Formal Green's Function Procedure; 8.4 Examples of Green's Function Construction.
- ProblemsReferences; CHAPTER 9. AXIAL CURRENTS AND CYLINDRICAL BOUNDARIES; 9.1 General Considerations; 9.2 Perfectly Conducting Wedge and an Axial Current Distribution; 9.3 Cylindrically Tipped Wedge and an Axial Current Distribution; 9.4 Perfectly Conducting Circular Cylinder and an Axial Current Distribution; 9.5 Dielectric Circular Cylinder and a Line Source; Problems; References; CHAPTER 10. DIFFRACTION BY CYLINDRICAL STRUCTURES; 10.1 Circular Cylinder; 10.2 Cylindrically Tipped Wedge; 10.3 The Wedge; 10.4 The Wiener-Hopf Technique; Problems; References.