The
Mathematical Theory of Time-Harmonic Maxwell's Equations
Expansion-, Integral-, and Variational Methods
Kirsch, Andreas.
creator
author.
Hettlich, Frank.
author.
SpringerLink (Online service)
text
gw
2015
monographic
eng
access
XIII, 337 p. 3 illus., 1 illus. in color. online resource.
This book gives a concise introduction to the basic techniques needed for the theoretical analysis of the Maxwell Equations, and filters in an elegant way the essential parts, e.g., concerning the various function spaces needed to rigorously investigate the boundary integral equations and variational equations. The book arose from lectures taught by the authors over many years and can be helpful in designing graduate courses for mathematically orientated students on electromagnetic wave propagation problems. The students should have some knowledge on vector analysis (curves, surfaces, divergence theorem) and functional analysis (normed spaces, Hilbert spaces, linear and bounded operators, dual space). Written in an accessible manner, topics are first approached with simpler scale Helmholtz Equations before turning to Maxwell Equations. There are examples and exercises throughout the book. It will be useful for graduate students and researchers in applied mathematics and engineers working in the theoretical approach to electromagnetic wave propagation.
Introduction -- Expansion into Wave Functions -- Scattering From a Perfect Conductor -- The Variational Approach to the Cavity Problem -- Boundary Integral Equation Methods for Lipschitz Domains -- Appendix -- References -- Index.
by Andreas Kirsch, Frank Hettlich.
Mathematics
Functional analysis
Partial differential equations
Numerical analysis
Applied mathematics
Engineering mathematics
Mathematics
Partial Differential Equations
Functional Analysis
Appl.Mathematics/Computational Methods of Engineering
Numerical Analysis
QA370-380
515.353
Springer eBooks
Applied Mathematical Sciences, 190
9783319110868
http://dx.doi.org/10.1007/978-3-319-11086-8
http://dx.doi.org/10.1007/978-3-319-11086-8
141119
20180115171621.0
978-3-319-11086-8