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Advanced Theoretical and Numerical Electromagnetics: 2 Volume Set [Multiple-component retail product, part(s) enclosed]

  • Formatas: Multiple-component retail product, part(s) enclosed, 1294 pages, aukštis x plotis: 254x203 mm, Contains 2 hardbacks
  • Serija: Electromagnetic Waves
  • Išleidimo metai: 01-Feb-2022
  • Leidėjas: Institution of Engineering and Technology
  • ISBN-10: 1839535709
  • ISBN-13: 9781839535703
Kitos knygos pagal šią temą:
Advanced Theoretical and Numerical Electromagnetics: 2 Volume Set
  • Formatas: Multiple-component retail product, part(s) enclosed, 1294 pages, aukštis x plotis: 254x203 mm, Contains 2 hardbacks
  • Serija: Electromagnetic Waves
  • Išleidimo metai: 01-Feb-2022
  • Leidėjas: Institution of Engineering and Technology
  • ISBN-10: 1839535709
  • ISBN-13: 9781839535703
Kitos knygos pagal šią temą:
This comprehensive and self-contained resource conveniently combines advanced topics in electromagnetic theory, a high level of mathematical detail, and the well-established ubiquitous Method of Moments applied to the solution of practical wave-scattering and antenna problems formulated with surface, volume, and hybrid integral equations. Originating from the graduate-level electrical engineering course that the author taught at the Technical University of Eindhoven (NL) from 2010 to 2017 this well-researched two-volume set is an ideal tool for self-study. The subject matter is presented with clear, engaging prose and explanatory illustrations in logical order. References to specialized texts are meticulously provided for the readers who wish to deepen and expand their mastery of a specific topic. This book will be of great interest to graduate students, doctoral candidates and post-docs in electrical engineering and physics, and to industry professionals working in areas such as design of passive microwave/optical components or antennas, and development of electromagnetic software. Thanks to the detailed mathematical derivations of all the important theoretical results and the numerous worked examples, readers can expect to build a solid and structured knowledge of the physical, mathematical, and computational aspects of classical electromagnetism. Volume 1 covers fundamental notions and theorems, static electric fields, stationary magnetic fields, properties of electromagnetic fields, electromagnetic waves and finishes with time-varying electromagnetic fields. Volume 2 starts with Integral formulas and equivalence principles, the moves to cover spectral representations of electromagnetic fields, wave propagation in dispersive media, integral equations in electromagnetics and finishes with a comprehensive explanation of the Method of Moments.
Volume 1
Chapter 1: Fundamental notions and theorems
Chapter 2: Static electric fields I
Chapter 3: Static electric fields II
Chapter 4: Stationary magnetic fields I
Chapter 5: Stationary magnetic fields II
Chapter 6: Properties of electromagnetic fields
Chapter 7: Electromagnetic waves
Chapter 8: Time-varying electromagnetic fields I
Chapter 9: Time-varying electromagnetic fields II Volume 2
Chapter 10: Integral formulas and equivalence principles
Chapter 11: Spectral representations of electromagnetic fields
Chapter 12: Wave propagation in dispersive media
Chapter 13: Integral equations in electromagnetics
Chapter 14: The Method of Moments I
Chapter 15: The Method of Moments II Appendix A: Vector calculus Appendix B: Complex analysis Appendix C: Dirac delta distributions Appendix D: Functional analysis Appendix E: Dyads and dyadics Appendix F: Properties of smooth surfaces Appendix G: A surface integral involving the time-harmonic scalar Green function Appendix H: Formulas
Vito Lancellotti has worked on and conducted research in theoretical and applied electromagnetics for more than twenty-five years. He has held research and teaching positions at both the Politecnico di Torino (IT) and the Technical University of Eindhoven (NL). His specialties include applied and computational electromagnetics; antennas; plasma sources and antennas; plasma-facing antennas for nuclear fusion; biological effects of electromagnetic field; metallic and dielectric waveguides; spectral methods and the Wiener-Hopf technique.