Some Computational Aspects of Pocklington's Electric Field Integral Equation for Thin Wires

D. H. Werner; P. L. Wernei; J. K. Breakall

doi:10.1109/8.286230

Some Computational Aspects of Pocklington's Electric Field Integral Equation for Thin Wires

D. H. Werner, P. L. Wernei, J. K. Breakall

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16 Scopus citations

Abstract

A procedure is presented for extracting the singularity from the kernel in Pocklington's electric field integral equation for thin wires. The modified kernel which results may be used to dramatically improve the computational efficiency of certain moment method formulations. A simple example is considered in which pulse basis functions and point matching are used. For this case, a convenient approximation of the self-term is also derived.

Original language	English (US)
Pages (from-to)	561-563
Number of pages	3
Journal	IEEE Transactions on Antennas and Propagation
Volume	42
Issue number	4
DOIs	https://doi.org/10.1109/8.286230
State	Published - Apr 1994

All Science Journal Classification (ASJC) codes

Electrical and Electronic Engineering

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10.1109/8.286230

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title = "Some Computational Aspects of Pocklington's Electric Field Integral Equation for Thin Wires",

abstract = "A procedure is presented for extracting the singularity from the kernel in Pocklington's electric field integral equation for thin wires. The modified kernel which results may be used to dramatically improve the computational efficiency of certain moment method formulations. A simple example is considered in which pulse basis functions and point matching are used. For this case, a convenient approximation of the self-term is also derived.",

author = "Werner, {D. H.} and Wernei, {P. L.} and Breakall, {J. K.}",

note = "Funding Information: Manuscript received March I. 1993; revised October 25, 1993. This work was supported by the Navy Security Group Command, Washington, DC. D. H. Werner is with the Applied Research Laboratory. Pennsylvania State University, State College, PA 16804. P. L. Wemer is with the College of Engineering, Pennsylvania State University, DuBois, PA 15801. J. K. Breakall is with the Department of Electrical and Computer Engineering, Pennsylvania State University, University Park. PA 16802. IEEE Log Number 9400505.",

year = "1994",

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T1 - Some Computational Aspects of Pocklington's Electric Field Integral Equation for Thin Wires

AU - Werner, D. H.

AU - Wernei, P. L.

AU - Breakall, J. K.

N1 - Funding Information: Manuscript received March I. 1993; revised October 25, 1993. This work was supported by the Navy Security Group Command, Washington, DC. D. H. Werner is with the Applied Research Laboratory. Pennsylvania State University, State College, PA 16804. P. L. Wemer is with the College of Engineering, Pennsylvania State University, DuBois, PA 15801. J. K. Breakall is with the Department of Electrical and Computer Engineering, Pennsylvania State University, University Park. PA 16802. IEEE Log Number 9400505.

PY - 1994/4

Y1 - 1994/4

N2 - A procedure is presented for extracting the singularity from the kernel in Pocklington's electric field integral equation for thin wires. The modified kernel which results may be used to dramatically improve the computational efficiency of certain moment method formulations. A simple example is considered in which pulse basis functions and point matching are used. For this case, a convenient approximation of the self-term is also derived.

AB - A procedure is presented for extracting the singularity from the kernel in Pocklington's electric field integral equation for thin wires. The modified kernel which results may be used to dramatically improve the computational efficiency of certain moment method formulations. A simple example is considered in which pulse basis functions and point matching are used. For this case, a convenient approximation of the self-term is also derived.

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Some Computational Aspects of Pocklington's Electric Field Integral Equation for Thin Wires

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