Electromagnetic waves, materials, and computation with MATLAB
"Preface The subject of electromagnetics is still a core subject of the undergraduate electrical engineering (EE) curriculum; however, at most of the universities in United States, the time allotted to teach it is cut into half (one 3-credit course instead of two). The present graduates with BS...
| Autor principal: | |
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| Formato: | Libro electrónico |
| Idioma: | Inglés |
| Publicado: |
Boca Raton, Fla. :
CRC Press
2012.
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| Edición: | 1st ed |
| Materias: | |
| Ver en Biblioteca Universitat Ramon Llull: | https://discovery.url.edu/permalink/34CSUC_URL/1im36ta/alma991009755213706719 |
Tabla de Contenidos:
- Front Cover; Contents; Preface; Acknowledgments; Author; Selected List of Symbols; List of Book Sources; Chapter 1 - Electromagnetics of Simple Media; Chapter 2 - Electromagnetics of Simple Media:: One-Dimensional Solution; Chapter 3 - Two-Dimensional Problems and Waveguides; Chapter 4 - Three-Dimensional Solutions; Chapter 5 - Spherical Waves and Applications; Chapter 6 - Laplace Equation: Static and: Low-Frequency Approximations; Chapter 7 - Miscellaneous Topics on Waves; Chapter 8 - Electromagnetic Modeling of Complex Materials; Chapter 9 - Artificial Electromagnetic Materials
- Chapter 10 - Waves in Isotropic Cold Plasma: Dispersive MediumChapter 11 - Spatial Dispersion and Warm Plasma; Chapter 12 - Wave in Anisotropic Media and Magnetoplasma; Chapter 13 - Optical Waves in Anisotropic Crystals; Chapter 14 - Electromagnetics of Moving Media; Chapter 15 - Introduction and One-Dimensional Problems; Chapter 16 - Two-Dimensional Problem; Chapter 17 - Advanced Topics on Finite-Element Method; Chapter 18 - Case Study Ridged Waveguide : with Many Elements; Chapter 19 - Finite-Difference Time-Domain Method
- Chapter 20 - Finite-Difference Time-Domain Method Simulation of Electromagnetic Pulse Interaction with a Switched Plasma SlabChapter 21 - Approximate Analytical Methods Based on Perturbation and Variational Techniques; 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 δ Is Comparable to the Radius a of the Wire
- Appendix 2B: Transmission Lines: Power CalculationAppendix 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 9A: Experimental Simulation of a Warm-Plasma Medium; Appendix 9B: Wave Propagation in Chiral Media; Appendix 10A: Backscatter from a Plasma Plume due to Excitation of Surface Waves
- Appendix 10B: Classical Photon Theory of Electromagnetic RadiationAppendix 10C: Photon Acceleration in a Time-Varying Medium; Appendix 11A: Thin Film Reflection Properties of a Warm Isotropic Plasma Slab between Two Half-Space Dielectric Media; Appendix 11B: The First-Order Coupled Differential Equations for Waves in Inhomogeneous Warm Magnetoplasmas; Appendix 11C: Waveguide Modes of a Warm Drifting Uniaxial Electron Plasma; Appendix 12A: Faraday Rotation versus Natural Rotation; Appendix 12B: Ferrites and Permeability Tensor
- Appendix 14A: Electromagnetic Wave Interaction with Moving Bounded Plasmas
