Title :
3D nonlinear electromagnetic inversion for buried objects in layered media
Author :
Song, Lin-Ping ; Liu, Qing H. ; Li, Fenghua
Author_Institution :
Electr. & Comput. Eng. Dept., Duke Univ., Durham, NC, USA
Abstract :
Electromagnetic (EM) inverse scattering in ground penetrating radar (GPR) is complicated and doubly challenging: one is that EM wave propagation is essentially a 3D wave phenomena and waves interact in a complex way with ground surface, subsurface layers, and objects; the other is that this class of nonlinear and ill-posed inverse problem involves intensive computation. In the practical use of GPR, the shallow earth may be necessarily modeled by one or more overburden layers. Thus, it is necessary to extend the existing inverse scattering methods developed for a homogeneous background or half-space to a multilayered medium. In this regard, here we deal with such a 3D EM nonlinear inverse scattering problem in multilayered media as a new step toward 3D image reconstruction of buried objects.
Keywords :
buried object detection; electromagnetic wave scattering; ground penetrating radar; inhomogeneous media; inverse problems; multilayers; radar imaging; 3D image reconstruction; 3D nonlinear electromagnetic inversion; EM inverse scattering; EM wave propagation; GPR; buried objects; ground penetrating radar; layered media; multilayered medium; nonlinear inverse problem; shallow earth overburden layers; Buried object detection; Electromagnetic scattering; Ground penetrating radar; Integral equations; Inverse problems; Magnetic field measurement; Nonhomogeneous media; Q measurement; Radar scattering; Surface waves;
Conference_Titel :
Antennas and Propagation Society International Symposium, 2004. IEEE
Print_ISBN :
0-7803-8302-8
DOI :
10.1109/APS.2004.1329593
