Title :
Numerical evaluation of dyadic diffraction coefficients and bistatic radar cross sections for a perfectly conducting semi-infinite elliptic cone
Author :
Blume, Siegfried ; Krebs, Volker
Author_Institution :
Dept. of Electr. Eng., Ruhr-Univ., Bochum, Germany
fDate :
3/1/1998 12:00:00 AM
Abstract :
In this paper, the scattering of electromagnetic waves by a perfectly conducting semi-infinite elliptic cone is treated. The exact solution of this boundary value problem in problem-adapted spheroconal coordinates in the form of a spherical multipole expansion is of poor convergence if both the source point and the field point are far away from the cone´s tip. Therefore, an appropriate sequence transformation of these series expansions (we apply the Shanks transformation) is necessary to numerically determine the dyadic diffraction coefficients and bistatic radar cross sections (RCS) for an arbitrary elliptic cone. Our far-field data for an elliptic cone, a circular cone, and a plane angular sector are compared with some other results obtained with the aid of quite different methods
Keywords :
boundary-value problems; electromagnetic wave diffraction; electromagnetic wave scattering; radar cross-sections; sequences; series (mathematics); transforms; Shanks transformation; bistatic radar cross sections; boundary value problem; circular cone; convergence; dyadic diffraction coefficients; electromagnetic wave; far-field data; field point; perfectly conducting semi-infinite elliptic cone; plane angular sector; problem-adapted spheroconal coordinates; scattering; sequence transformation; series expansions; source point; spherical multipole expansion; Acoustic scattering; Bistatic radar; Boundary value problems; Electromagnetic diffraction; Electromagnetic scattering; Legged locomotion; Optical scattering; Radar cross section; Radar scattering; Shape;
Journal_Title :
Antennas and Propagation, IEEE Transactions on
