A two-stage numerical procedure for an inverse scattering problem
Abstract
In this thesis we study a numerical procedure for the solution of the
inverse problem of reconstructing location, shape and material properties
(in particular refractive indices) of scatterers located in a known background
medium. The data consist of time-resolved backscattered radar
signals from a single source position. This relatively small amount of
data and the ill-posed nature of the inversion are the main challenges of
the problem. Mathematically, the problem is formulated as a coefficient
inverse problem for a system of partial differential equations derived from
Maxwell’s equations.
The numerical procedure is divided into two stages. In the first stage,
a good initial approximation for the unknown coefficient is computed by
an approximately globally convergent algorithm. This initial approximation
is refined in the second stage, where an adaptive finite element
method is employed to minimize a Tikhonov functional. An important
tool for the second stage is a posteriori error estimates – estimates in
terms of known (computed) quantities – for the difference between the
computed coefficient and the true minimizing coefficient.
This thesis includes four papers. In the first two, the a posteriori error
analysis required for the adaptive finite element method in the second
stage is extended from the previously existing indirect error estimators
to direct ones. The last two papers concern verification of the two-stage
numerical procedure on experimental data. We find that location and
material properties of scatterers are obtained already in the first stage,
while shapes are significantly improved in the second stage.
Publisher
Chalmers University of Technology and University of Gothenburg
View/ Open
Date
2015Author
Bondestam Malmberg, John
Keywords
coefficient inverse problem
inverse scattering
backscattering data
approximate global convergence
finite element method
adaptivity
a posteriori error analysis
Publication type
licentiate thesis
Language
eng