Title :
On a rigorous inverse scattering model for a three dimensional flaw embedded in anisotropic advanced composite materials
Author :
Barkeshli, S. ; Sabbagh, H.A. ; Radecki, D.J.
Author_Institution :
Sabbagh Associates Inc., Bloomington, IN, USA
Abstract :
Inverse scattering models of the type that are often used to invert eddy current data are inherently nonlinear because they involve the product of two unknowns, the flaw conductivity and the true electric field within the flaw. Computational inverse models, therefore, often linearize the problem by assuming that the electric field within the flaw is known a priori. The authors describe a rigorous formulation of such an inverse scattering model. The model is based on coupled integral equations that are discretized by means of the method of moments. The linearized version of this model is also outlined. The measured data are inverted by means of the conjugate gradient algorithm. An example concerning the reconstruction of a flaw in a graphite-epoxy advanced composite using the linearized model is shown.<>
Keywords :
composite materials; eddy current testing; electromagnetic field theory; electromagnetic wave scattering; flaw detection; integral equations; voids (solid); 3D flow; anisotropic composite materials; conjugate gradient algorithm; coupled integral equations; eddy current data; electric field; flaw conductivity; graphite-epoxy composite; inverse problems; inverse scattering model; linearized model; measured data; method of moments; three dimensional flaw; Anisotropic magnetoresistance; Conductivity; Frequency; Green´s function methods; Integral equations; Inverse problems; Moment methods; Region 1; Region 2; Slabs;
Conference_Titel :
Antennas and Propagation Society International Symposium, 1990. AP-S. Merging Technologies for the 90's. Digest.
Conference_Location :
Dallas, TX, USA
DOI :
10.1109/APS.1990.115363
