DocumentCode
1252184
Title
Forward and inverse scattering for discrete layered lossy and absorbing media
Author
Frolik, Jeffrey L. ; Yagle, Andrew E.
Author_Institution
Dept. of Electr. Eng. & Comput. Sci., Michigan Univ., Ann Arbor, MI, USA
Volume
44
Issue
9
fYear
1997
fDate
9/1/1997 12:00:00 AM
Firstpage
710
Lastpage
722
Abstract
A complete digital signal processing (DSP) theory is developed for forward and inverse scattering in discrete (piecewise-constant) layered lossy systems, generalizing previous work for discrete lossless systems and continuous lossy systems. This paper is motivated by radar reflections from stratified dielectrics and interchip communication modeled by lossy transmission lines. The DSP formulation allows exact solutions, without discretization approximations, and includes all multiple reflections, transmission scattering losses, and absorption effects. For the forward problem, discrete matrix Green´s functions are derived for the lossy medium, as are fast algorithms for computing impulse reflection and transmission responses for the medium. For the inverse problem, asymmetric Toeplitz systems of equations which function as discrete counterparts to integral equations are derived, as are fast algorithms for reconstructing the medium from its impulse transmission and reflection responses. Data sufficiency and feasibility are discussed. Finally, these results are applied to the LCRG transmission line and layered dielectric medium problems, dispersion effects are discussed, and a numerical example is presented
Keywords
Green´s function methods; Toeplitz matrices; dispersion (wave); electromagnetic wave scattering; integral equations; inverse problems; losses; radar cross-sections; transmission line theory; DSP theory; LCRG transmission line problem; absorbing media; absorption effects; asymmetric Toeplitz systems of equations; digital signal processing theory; discrete layered media; discrete matrix Green functions; dispersion effects; fast algorithms; forward scattering; impulse reflection response; impulse transmission response; integral equations; interchip communication; inverse scattering; layered dielectric medium problem; lossy media; lossy transmission lines; multiple reflections; radar reflections; stratified dielectrics; transmission scattering losses; Dielectric losses; Digital signal processing; Integral equations; Inverse problems; Propagation losses; Radar; Reflection; Signal processing algorithms; Transmission line matrix methods; Transmission line theory;
fLanguage
English
Journal_Title
Circuits and Systems II: Analog and Digital Signal Processing, IEEE Transactions on
Publisher
ieee
ISSN
1057-7130
Type
jour
DOI
10.1109/82.624998
Filename
624998
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