LEADER 06637oam 2200673I 450 001 9910800163203321 005 20200520144314.0 010 $a0-429-10589-4 010 $a1-4398-3868-2 024 7 $a10.1201/b11793 035 $a(CKB)3710000000391171 035 $a(EBL)1446466 035 $a(SSID)ssj0001458562 035 $a(PQKBManifestationID)12540702 035 $a(PQKBTitleCode)TC0001458562 035 $a(PQKBWorkID)11450737 035 $a(PQKB)11296725 035 $a(MiAaPQ)EBC1446466 035 $a(Au-PeEL)EBL1446466 035 $a(CaPaEBR)ebr11166026 035 $a(OCoLC)908077530 035 $a(OCoLC)1030941246 035 $a(OCoLC-P)1030941246 035 $a(CaSebORM)9781439838686 035 $a(EXLCZ)993710000000391171 100 $a20180706d2012 uy 0 101 0 $aeng 135 $aur|n|---||||| 181 $ctxt 182 $cc 183 $acr 200 10$aElectromagnetic waves, materials, and computation with MATLAB /$fDikshitulu K. Kalluri 210 1$aBoca Raton, Fla. :$cCRC Press,$d2012. 215 $a1 online resource (862 p.) 300 $aDescription based upon print version of record. 311 $a1-4398-3867-4 320 $aIncludes bibliographical references at the end of each chapters. 327 $aFront 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 327 $aChapter 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 327 $aChapter 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 ? Is Comparable to the Radius a of the Wire 327 $aAppendix 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 327 $aAppendix 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 327 $aAppendix 14A: Electromagnetic Wave Interaction with Moving Bounded Plasmas 330 $a"Preface The subject of electromagnetics is still a core subject of the undergraduate electrical engineering (EE) curriculum; however, at most of the universities in United States, the time allotted to teach it is cut into half (one 3-credit course instead of two). The present graduates with BS degree in EE being rushed through the same curriculum content in a shorter time often miss the concepts and depend on a lot of formulas which they use as a recipe for some calculations based on an example worked out in the book. Some of them are fortunate to take a follow-up special elective course in microwaves or RF design or antennas or fiber optics, and so on, thus partly reinforcing one application area. Readily available commercial software allows them to do routine calculations and design without having a conceptual understanding of the expected solution. The commercial software is so user-friendly that we usually get a beautiful colored visualization of the solution, even if it is a wrong simulation of the physical problem. After getting one or two mild reprimands from the boss in his new employment after graduation, the new graduate realizes that he needs to have a fairly good idea of what is the appropriate model to be simulated and what qualitative result is to be expected. Though the software is very useful, it is not a substitute for a conceptual understanding of the steps involved in solving the problem. Fortunately, for him, there is probably a university which offers graduate courses and there is an instructor/professor who understands that these bright students recruited by some of the top companies are not less smart than the employees recruited by the company, say a decade or two ago"--$cProvided by publisher. 606 $aElectromagnetism$xMathematical models 606 $aElectromagnetic waves$xComputer simulation 606 $aMaterials$xElectric properties 615 0$aElectromagnetism$xMathematical models. 615 0$aElectromagnetic waves$xComputer simulation. 615 0$aMaterials$xElectric properties. 676 $a537.028553 686 $aTEC019000$aTEC024000$aTEC061000$2bisacsh 700 $aKalluri$b Dikshitulu K$0846944 801 0$bFlBoTFG 801 1$bFlBoTFG 906 $aBOOK 912 $a9910800163203321 996 $aElectromagnetic waves, materials, and computation with MATLAB$93877017 997 $aUNINA