Title :
Inverse obstacle scattering for homogeneous dielectric cylinders using a boundary finite-element method
Author :
Bonnard, Stéphane ; Vincent, Patrick ; Saillard, Marc
Author_Institution :
Lab. d´´Opt. Electromagn., CNRS, Marseille, France
fDate :
3/1/2000 12:00:00 AM
Abstract :
A method for reconstructing the shape and the permittivity of a penetrable homogeneous cylinder is described. It is the extension to penetrable cylinders of a previous work dealing with perfectly conducting cylinders. A low-frequency approximation is used to determine an initial guess. Then, a rigorous boundary integral method permits us to reconstruct arbitrary shapes and complex permittivities. It is based on an iterative conjugate gradient algorithm requiring the solving of two direct diffraction problems only. A simple and original regularization scheme is presented, which ensures the robustness of the algorithm. Numerical examples with lossy embedding media and additional random noise for both E|| and H|| polarizations are given
Keywords :
absorbing media; approximation theory; boundary-elements methods; conjugate gradient methods; dielectric bodies; electromagnetic wave diffraction; electromagnetic wave polarisation; electromagnetic wave scattering; finite element analysis; inverse problems; permittivity; random noise; E-polarization; H-polarization; algorithm robustness; boundary finite-element method; complex permittivities; diffraction problems; homogeneous dielectric cylinders; inverse obstacle scattering; iterative conjugate gradient algorithm; lossy embedding media; low-frequency approximation; penetrable homogeneous cylinder; perfectly conducting cylinders; permittivity; random noise; regularization scheme; rigorous boundary integral method; shape reconstruction; Dielectrics; Diffraction; Integral equations; Iterative algorithms; Noise robustness; Noise shaping; Permittivity; Random media; Scattering; Shape;
Journal_Title :
Antennas and Propagation, IEEE Transactions on
