High-Order Numerical Methods for Transient Wave Equations

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Scientific Computation

ISBN: 354041598X
ISBN 13: 9783540415985
Autor: Cohen, Gary
Verlag: Springer Verlag GmbH
Umfang: xviii, 349 S., 90 s/w Illustr., 2 farbige Illustr., 349 p. 92 illus., 2 illus. in color.
Erscheinungsdatum: 06.11.2001
Format: 2.5 x 24 x 16.3
Gewicht: 669 g
Produktform: Gebunden/Hardback
Einband: GEB

Solving efficiently the wave equations involved in modeling acoustic, elastic or electromagnetic wave propagation remains a challenge both for research and industry. To attack the problems coming from the propagative character of the solution, the author constructs higher-order numerical methods to reduce the size of the meshes, and consequently the time and space stepping, dramatically improving storage and computing times. This book surveys higher-order finite difference methods and develops various mass-lumped finite (also called spectral) element methods for the transient wave equations, and presents the most efficient methods, respecting both accuracy and stability for each sort of problem. A central role is played by the notion of the dispersion relation for analyzing the methods. The last chapter is devoted to unbounded domains which are modeled using perfectly matched layer (PML) techniques. Numerical examples are given.

Artikelnummer: 665257 Kategorie:

Beschreibung

"To my knowledge [this] is the first book to address specifically the use of high-order discretizations in the time domain to solve wave equations. [.] I recommend the book for its clear and cogent coverage of the material selected by its author." --Physics Today, March 2003

Autorenporträt

InhaltsangabeI. Basic Definitions and Properties.- 1. The Basic Equations.- 2. Functional Issues.- 3. Plane Wave Solutions.- II. Finite Difference Methods.- 4. Construction of the Schemes in Homogeneous Media.- 5. The Dispersion Relation.- 6. Stability of the Schemes.- 7. Numerical Dispersion and Anisotropy.- 8. Construction of the Schemes in Heterogeneous Media.- 9. Stability by Energy Techniques.- 10. Reflection-Transmission Analysis.- III. Finite Element Methods.- 11. Mass-Lumping in 1D.- 12. Spectral Elements.- 13. Mass-Lumped Mixed Formulations and Edge Elements.- 14. Modeling Unbounded Domains.- A.1.1 Notation.- A.2.1 Notation.

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