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Mapped Vector Basis Functions for Electromagnetic Integral Equations

Record Type:	Language materials, printed : Monograph/item
Title/Author:	Mapped Vector Basis Functions for Electromagnetic Integral Equations/ by Andrew F. Peterson.
Author:	Peterson, Andrew F.
Description:	VIII, 115 p.online resource. :
Contained By:	Springer Nature eBook
Subject:	Engineering. -
Online resource:	https://doi.org/10.1007/978-3-031-01686-8
ISBN:	9783031016868

Mapped Vector Basis Functions for Electromagnetic Integral Equations
Peterson, Andrew F.

Mapped Vector Basis Functions for Electromagnetic Integral Equations[electronic resource] /by Andrew F. Peterson. - 1st ed. 2006. - VIII, 115 p.online resource. - Synthesis Lectures on Computational Electromagnetics,1932-1716. - Synthesis Lectures on Computational Electromagnetics,.

Introduction -- The Surface Model -- Divergence-Conforming Basis Functions -- Curl-Conforming Basis Functions -- Transforming Vector Basis Functions to Curved Cells -- Use of Divergence-conforming Basis Functions with the Electric Field Integral Equation -- Use of Curl-conforming Bases with the Magnetic Field Integral Equation.

The method-of-moments solution of the electric field and magnetic field integral equations (EFIE and MFIE) is extended to conducting objects modeled with curved cells. These techniques are important for electromagnetic scattering, antenna, radar signature, and wireless communication applications. Vector basis functions of the divergence-conforming and curl-conforming types are explained, and specific interpolatory and hierarchical basis functions are reviewed. Procedures for mapping these basis functions from a reference domain to a curved cell, while preserving the desired continuity properties on curved cells, are discussed in detail. For illustration, results are presented for examples that employ divergence-conforming basis functions with the EFIE and curl-conforming basis functions with the MFIE. The intended audience includes electromagnetic engineers with some previous familiarity with numerical techniques.

ISBN: 9783031016868

Standard No.: 10.1007/978-3-031-01686-8doiSubjects--Topical Terms:

561152
Engineering.

LC Class. No.: T1-995

Dewey Class. No.: 620

Mapped Vector Basis Functions for Electromagnetic Integral Equations
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520 $a The method-of-moments solution of the electric field and magnetic field integral equations (EFIE and MFIE) is extended to conducting objects modeled with curved cells. These techniques are important for electromagnetic scattering, antenna, radar signature, and wireless communication applications. Vector basis functions of the divergence-conforming and curl-conforming types are explained, and specific interpolatory and hierarchical basis functions are reviewed. Procedures for mapping these basis functions from a reference domain to a curved cell, while preserving the desired continuity properties on curved cells, are discussed in detail. For illustration, results are presented for examples that employ divergence-conforming basis functions with the EFIE and curl-conforming basis functions with the MFIE. The intended audience includes electromagnetic engineers with some previous familiarity with numerical techniques.
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