Finite Element Method Electromagnetics: Antennas, Microwave Circuits, and Scattering Applications

Electrical Engineering Finite Element Method for Electromagnetics Antennas, Microwave Circuits, and Scattering Applications A volume in the IEEE/OUP Series on Electromagnetic Wave Theory Donald G. Dudley, Series Editor Employed in a large number of commercial electromagnetic simulation packages, the finite element method is one of the most popular and well–established numerical techniques in engineering. This book covers the theory, development, implementation, and application of the finite element method and its hybrid versions to electromagnetics. Finite Element Method for Electromagnetics begins with a step–by–step presentation of the finite element method and its variations, and then provides up–to–date coverage of three–dimensional formulations and modern applications to open– and closed–domain problems. Topics covered include:Galerkin’s and Ritz methodsOne– and two–dimensional theory and applicationsThree–dimensional development of the method using edge elements and applicationsMesh truncation schemesMatlab sample codesEfficient implementation of the finite element method, sparse matrix storage schemes, popular iterative solvers, eigenvalue solutionsExperiences on code porting to parallel computersIntegral algorithms for fast implementation of the boundary integral matrix–vector products. Written by experts who have extensive experience in both teaching and implementing this method to many applications, Finite Element Method for Electromagnetics a can be used as a textbook for first–year graduate students, as well as a handy reference for engineers and scientists interested in computational electromagnetics. About the IEEE/OUP Series on Electromagnetic Wave Theory Formerly the IEEE Press Series on Electromagnetic Waves, this joint series between IEEE Press and Oxford University Press offers outstanding coverage of the field, with new titles as well as reprintings and revisions of recognized classics that maintain long–term archival significance in electromagnetic waves and applications. Designed specifically for graduate students, practicing engineers, and researchers, this series provides affordable volumes that explore electromagnetic waves and applications beyond the undergraduate level.

Spis treści:
Preface.
Acknowledgments.
Fundamental Concepts.
Shape Functions for Scalar and Vector Finite Elements.
Overview of the Finite Element Method: One–Dimensional Examples.
Two–Dimensional Applications.
Three–Dimensional Problems: Closed Domain.
Three–Dimensional Problems: Radiation and Scattering.
Three–Dimensional FE–BI Method.
Fast Integral Methods (S. Bindiganavale and J.L. Volakis).
Numerical Issues.
Index.
About the Authors.

Nota biograficzna:
About the Authors John L. Volakis is professor at the Department of Electrical Engineering and Computer Science at the University of Michigan. He has published more than 140 refereed journal articles and more than 140 conference papers on numerical and analytical techniques in electromagnetics. Dr. Volakis is also coauthor of Approximate Boundary Conditions in Electromagnetics (IEE Press, 1995) and several book chapters.
Arindam Chaterjee has developed three–dimensional computer simulation of electromagnetic fields for scattering and microwave circuits, and is currently a member of the finite element development group for the HFSS finite element commercial package at Hewlett–Packard.
Leo C. Kempel developed three–dimensional antenna simulation packages using the finite element–boundary integral method and has extensive experience with all popular numerical techniques in electromagnetics. He is currently at Mission Research Corporation, Florida, conducting research and development on all aspects of electromagnetics.

Okładka tylna:
Electrical Engineering Finite Element Method for Electromagnetics Antennas, Microwave Circuits, and Scattering Applications A volume in the IEEE/OUP Series on Electromagnetic Wave Theory Donald G. Dudley, Series Editor Employed in a large number of commercial electromagnetic simulation packages, the finite element method is one of the most popular and well–established numerical techniques in engineering. This book covers the theory, development, implementation, and application of the finite element method and its hybrid versions to electromagnetics. Finite Element Method for Electromagnetics begins with a step–by–step presentation of the finite element method and its variations, and then provides up–to–date coverage of three–dimensional formulations and modern applications to open– and closed–domain problems. Topics covered include:Galerkin’s and Ritz methodsOne– and two–dimensional theory and applicationsThree–dimensional development of the method using edge elements and applicationsMesh truncation schemesMatlab sample codesEfficient implementation of the finite element method, sparse matrix storage schemes, popular iterative solvers, eigenvalue solutionsExperiences on code porting to parallel computersIntegral algorithms for fast implementation of the boundary integral matrix–vector products. Written by experts who have extensive experience in both teaching and implementing this method to many applications, Finite Element Method for Electromagnetics a can be used as a textbook for first–year graduate students, as well as a handy reference for engineers and scientists interested in computational electromagnetics. About the IEEE/OUP Series on Electromagnetic Wave Theory Formerly the IEEE Press Series on Electromagnetic Waves, this joint series between IEEE Press and Oxford University Press offers outstanding cove rage of the field, with new titles as well as reprintings and revisions of recognized classics that maintain long–term archival significance in electromagnetic waves and applications. Designed specifically for graduate students, practicing engineers, and researchers, this series provides affordable volumes that explore electromagnetic waves and applications beyond the undergraduate level.