Title :
Using CGM and FDFD Techniques to Investigate the Radar Detection of Two-Dimensional Airplanes in Random Media for Beam Wave Incidence
Author :
El-Ocla, H. ; Al Sharkawy, M.
Author_Institution :
Dept. of Comput. Sci., Lakehead Univ., Thunder Bay, ON, Canada
Abstract :
A previous study proved that the radar cross sections (RCS) of targets differ greatly with the illumination region curvature, assuming a plane wave incidence. In this work, we present numerical results to investigate the effect of target configuration on the backscattering enhancement in the laser radar cross section (LRCS), aiming to enhance the efficiency of the radar detection of objects in a random medium. Two different techniques - the Current Generator Method (CGM) and the Finite-Difference Frequency-Domain (FDFD) Method - are used to illustrate and verify the calculated results. The target configuration includes the illumination region and the target´s complexity with E-wave incidence. We consider concave and convex illumination regions of partially convex targets with a large size.
Keywords :
electromagnetic wave scattering; finite difference methods; frequency-domain analysis; lighting; object detection; optical radar; radar cross-sections; radar detection; random media; CGM technique; E-wave incidence; FDFD technique; LRCS; backscattering enhancement; beam wave incidence; concave illumination; convex illumination; current generator method; finite difference frequency domain method; illumination region curvature; laser radar cross section; object radar detection; partially convex target; plane wave incidence; random media; target complexity; targets RCS; two-dimensional airplane radar detection; Convex functions; Finite difference methods; Laser radar; Lighting; Mathematical model; Radar cross-sections; Scattering; Surface waves; Beam; FDFD; concave; convex; double passage; radar cross section; random medium; scattering;
Journal_Title :
Antennas and Propagation Magazine, IEEE
DOI :
10.1109/MAP.2014.6971920
