Principles of Electromagnetic Waves and Materials

Principles of Electromagnetic Waves and Materials

  • Producent: CRC Press Inc.
  • Rok produkcji: 2013
  • ISBN: 9781466593725
  • Ilość stron: 462
  • Oprawa: Twarda
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Opis: Principles of Electromagnetic Waves and Materials - Dikshitulu K. Kalluri

Principles of Electromagnetic Waves and Materials is a condensed version of the author's previously published textbook, Electromagnetic Waves, Materials, and Computation with MATLAB(R). This book focuses on lower-level courses, primarily senior undergraduate and graduate students in electromagnetic waves and materials courses. It takes an integrative approach to the subject of electromagnetics by supplementing quintessential "old-school" information and methods with the appropriate amount of material on plasmas for exposing the students to the broad area of Plasmonics and by striking a balance between theoretical and practical aspects. Ancillary materials are available upon qualifying course adoption.Electromagnetics of Bounded Simple Media Electromagnetics of Simple Media Introduction Simple Medium Time-Domain Electromagnetics Time-Harmonic Fields Quasistatic and Static Approximations Maxwell's Equations in Integral Form and Circuit Parameters References Electromagnetics of Simple Media: One-Dimensional Solution Uniform Plane Waves in Sourceless Medium (rhoV = 0, Jsource = 0) Good Conductor Approximation Uniform Plane Wave in a Good Conductor: Skin Effect Boundary Conditions at the Interface of a Perfect Electric Conductor with a Dielectric AC Resistance AC Resistance of Round Wires Voltage and Current Harmonic Waves: Transmission Lines Bounded Transmission Line Electromagnetic Wave Polarization Arbitrary Direction of Propagation Wave Reflection Incidence of p Wave: Parallel-Polarized Incidence of s Wave: Perpendicular-Polarized Critical Angle and Surface Wave One-Dimensional Cylindrical Wave and Bessel Functions References Two-Dimensional Problems and Waveguides Two-Dimensional Solutions in Cartesian Coordinates TMmn Modes in a Rectangular Waveguide TEmn Modes in a Rectangular Waveguide Dominant Mode in a Rectangular Waveguide: TE10 Mode Power Flow in a Waveguide: TE10 Mode Attenuation of TE10 Mode due to Imperfect Conductors and Dielectric Medium Cylindrical Waveguide: TM Modes Cylindrical Waveguide: TE Modes Sector Waveguide Dielectric Cylindrical Waveguide-Optical Fiber References Three-Dimensional Solutions Rectangular Cavity with PEC Boundaries: TM Modes Rectangular Cavity with PEC Boundaries: TE Modes Q of a Cavity Reference Spherical Waves and Applications Half-Integral Bessel Functions Solutions of Scalar Helmholtz Equation Vector Helmholtz Equation TMr Modes TEr Modes Spherical Cavity Laplace Equation: Static and Low-Frequency Approximations One-Dimensional Solutions Two-Dimensional Solutions Three-Dimensional Solution References Miscellaneous Topics on Waves Group Velocity vg Green's Function Network Formulation Stop Bands of a Periodic Media Radiation Scattering\ Diffraction References Electromagnetic Equations of Complex Media Electromagnetic Modeling of Complex Materials Volume of Electric Dipoles Frequency-Dependent Dielectric Constant Modeling of Metals Plasma Medium Polarizability of Dielectrics Mixing Formula Good Conductors and Semiconductors Perfect Conductors and Superconductors Magnetic Materials Chiral Medium Plasmonics and Metamaterials References Waves in Isotropic Cold Plasma: Dispersive Medium Basic Equations Dielectric-Dielectric Spatial Boundary Reflection by a Plasma Half-Space Reflection by a Plasma Slab Tunneling of Power through a Plasma Slab Inhomogeneous Slab Problem Periodic Layers of Plasma Surface Waves Transient Response of a Plasma Half-Space Solitons References Spatial Dispersion and Warm Plasma Waves in a Compressible Gas Waves in Warm Plasma Constitutive Relation for a Lossy Warm Plasma Dielectric Model of Warm Loss-Free Plasma Conductor Model of Warm Lossy Plasma Spatial Dispersion and Nonlocal Metal Optics Technical Definition of Plasma State References Wave in Anisotropic Media and Magnetoplasma Introduction Basic Field Equations for a Cold Anisotropic Plasma Medium One-Dimensional Equations: Longitudinal Propagation and L and R Waves One-Dimensional Equations: Transverse Propagation: O Wave One-Dimensional Solution: Transverse Propagation: X Wave Dielectric Tensor of a Lossy Magnetoplasma Medium Periodic Layers of Magnetoplasma Surface Magnetoplasmons Surface Magnetoplasmons in Periodic Media Permeability Tensor References Optical Waves in Anisotropic Crystals Wave Propagation in a Biaxial Crystal along the Principal Axes Propagation in an Arbitrary Direction Propagation in an Arbitrary Direction: Uniaxial Crystal k-Surface Group Velocity as a Function of Polar Angle Reflection by an Anisotropic Half-Space References Appendices Appendix 1A: Vector Formulas and Coordinate Systems Appendix 1B: Retarded Potentials and Review of Potentials for the Static Cases Appendix 1C: Poynting Theorem Appendix 1D: Low-Frequency Approximation of Maxwell's Equations R, L, C, and Memristor M Appendix 2A: AC Resistance of a Round Wire When the Skin Depth delta Is Comparable to the Radius a of the Wire Appendix 2B: Transmission Lines: Power Calculation Appendix 2C: Introduction to the Smith Chart Appendix 2D: Nonuniform Transmission Lines Appendix 4A: Calculation of Losses in a Good Conductor at High Frequencies: Surface Resistance RS Appendix 6A: On Restricted Fourier Series Expansion Appendix 7A: Two- and Three-Dimensional Green's Functions Appendix 8A: Wave Propagation in Chiral Media Appendix 8B: Left-Handed Materials and Transmission Line Analogies Appendix 9A: Backscatter from a Plasma Plume due to Excitation of Surface Waves Appendix 10A: Thin Film Reflection Properties of a Warm Isotropic Plasma Slab between Two Half-Space Dielectric Media Appendix 10B: First-Order Coupled Differential Equations for Waves in Inhomogeneous Warm Magnetoplasmas Appendix 10C: Waveguide Modes of a Warm Drifting Uniaxial Electron Plasma Appendix 11A: Faraday Rotation versus Natural Rotation Appendix 11B: Ferrites and Permeability Tensor Chapter Problems Problems Index


Szczegóły: Principles of Electromagnetic Waves and Materials - Dikshitulu K. Kalluri

Tytuł: Principles of Electromagnetic Waves and Materials
Autor: Dikshitulu K. Kalluri
Producent: CRC Press Inc.
ISBN: 9781466593725
Rok produkcji: 2013
Ilość stron: 462
Oprawa: Twarda
Waga: 1.01 kg


Recenzje: Principles of Electromagnetic Waves and Materials - Dikshitulu K. Kalluri

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