An implementation of king's green functions in thin wire scattering problems

No Thumbnail Available

Date

2011-12

Journal Title

Journal ISSN

Volume Title

Publisher

Applied Computational Electromagnetics

Abstract

We investigate electromagnetic scattering from metallic thin wire structures located over planar and spherical lossy dielectric half-spaces by applying Green's function formulation and method of moments in the resonance region and under "high contrast approximation" (HCA). For this purpose, in the calculations of the impedance matrix and the potential column of the moment system, we employ the Green functions of King valid for arbitrary range under HCA and the asymptotic (far field) Green functions for planar and spherical impedance surfaces delivered by Norton and Wait, respectively. For a verification of the developed codes, the current distributions obtained under plane wave illumination on the arms of a cross shaped thin wire structure are compared to the same results obtained by the commercial software SNECTM. Various illustrations for the scattered electrical field from a thin wire plate located over planar and spherical half-spaces are also presented.

Description

Keywords

Engineering, Telecommunications, Electromagnetic scattering, Method of moments, Sommerfeld problem, Thin wires, Vertical electric-dipole, Radio-wave propagation, Electromagnetic-field, Inhomogeneous earth, Conducting bodies, Dielectric layer, Grid model, Half-space, Radiation, Surface, Dielectric materials, Electromagnetic wave scattering, Method of moments, Spheres, Verification, Commercial software, Current distribution, Electrical field, Electromagnetic scattering, Far field, Green function, Half spaces, High contrast, Impedance matrices, Impedance surface, Lossy dielectrics, Metallic thin wires, Plane wave illumination, Resonance region, Scattering problems, Sommerfeld problem, Thin wires, Wire

Citation

Zor, Ö. ve Polat, B. (2011). "An implementation of king's green functions in thin wire scattering problems". Applied Computational Electromagnetics Society Journal, 26(12), Special Issue, 1024-1038.