Title :
“Blind” shape reconstruction from experimental data
Author :
Van Den Berg, Peter M. ; Coté, Marc G. ; Kleinman, Ralph E.
Author_Institution :
Lab. of Electromagnetic Res., Delft Univ. of Technol., Netherlands
fDate :
12/1/1995 12:00:00 AM
Abstract :
A method for reconstructing the shape of a bounded impenetrable object from measured scattered field data is presented. The reconstruction algorithm is, in principle, the same as that used before for reconstructing the conductivity of a penetrable object and uses the fact that for high conductivity the skin depth of the scatterer is small, in which case the only meaningful information produced by the algorithm is the boundary of the scatterer. A striking increase in efficiency is achieved by incorporating into the algorithm the fact that for large conductivity, the contrast is dominated by a large positive imaginary part. This fact together with the knowledge that the scatterer is constrained in some test domain constitute the only a priori information about the scatterer that is used. There are no other implicit assumptions about the location, connectivity, convexity, or boundary conditions. The method is shown to successfully reconstruct the shape of an object from experimental scattered field data in a “blind” test
Keywords :
electric field measurement; electromagnetic wave scattering; image reconstruction; inverse problems; magnetic field measurement; blind shape reconstruction; blind test; boundary conditions; bounded impenetrable object; conductivity; efficiency; experimental data; experimental scattered field data; measured scattered field data; modified gradient inverse scattering algorithm; reconstruction algorithm; scatterer; skin depth; Conductivity; Electromagnetic scattering; Image reconstruction; Iterative algorithms; Laboratories; Permittivity; Reconstruction algorithms; Shape measurement; Skin; Testing;
Journal_Title :
Antennas and Propagation, IEEE Transactions on
