Title :
A macro-element compression for the moment method
Author :
Poirier, Jean-René ; Bendali, Abderrahmane ; Borderies, Pierre
Author_Institution :
Univ. Paul Sabatier, Toulouse, France
fDate :
10/1/2001 12:00:00 AM
Abstract :
A new approach based on QR compression of the off-diagonal blocks of the impedance matrix arising in integral equations solutions of electromagnetic (EM) scattering problems, previously implemented for finite and irregular gratings, is extended here to an arbitrarily shaped obstacle. The main tool consists in dividing the entire surface scatterer into subdomains and in assembling the global impedance matrix as a combination of the macromatrices associated to each interaction of any patch on the other. The correlation between compression rate and accuracy of field computation is drawn up. An experimental study is performed to optimize the method relatively to the two competing parameters: accuracy and cost. Finally, it is shown that this method works equally well in both the high and the low frequency domain and also with an inclusion of a small detail in a large object
Keywords :
electromagnetic wave scattering; impedance matrix; integral equations; matrix decomposition; method of moments; radar cross-sections; CPU time; EM scattering; HF domain; LF domain; QR compression; RCS; arbitrarily shaped obstacle; correlation; cost; electromagnetic scattering; field computation accuracy; global impedance matrix; high frequency domain; integral equations; low frequency domain; macro-element compression; macromatrices; matrix decomposition; matrix-vector product; moment method; radar cross section; subdomains; surface scatterer; Assembly; Cost function; Electromagnetic scattering; Gratings; Integral equations; Matrix decomposition; Moment methods; Optimization methods; Radar scattering; Surface impedance;
Journal_Title :
Antennas and Propagation, IEEE Transactions on
