Title :
Forward-backward iterative physical optics algorithm for computing the RCS of open-ended cavities
Author :
Burkholder, Robert J. ; Lundin, Tomas
Author_Institution :
Dept. of Electr. & Comput. Eng., Ohio State Univ., Columbus, OH, USA
Abstract :
The forward-backward methodology is combined with the iterative physical optics (IPO) algorithm to improve convergence for cavity scattering problems. Wave propagation inside elongated cavities, such as jet engine inlet ducts, follows a predominant down-and-back path. The forward-backward method allows the IPO currents on the cavity walls to be updated sequentially (forward) and reverse-sequentially (backward) along the waveguide axis. A relaxation parameter is introduced to help control the convergence characteristics, making the new algorithm mathematically equivalent to the classical iterative method of symmetric successive over-relaxation. The fast far-field approximation (FaFFA) accelerates the matrix-vector products in the IPO formulation, and an equivalent surface impedance is used to characterize thin material linings in the cavity.
Keywords :
convergence; electromagnetic wave propagation; electromagnetic wave scattering; iterative methods; matrix algebra; physical optics; radar cross-sections; surface impedance; vectors; FaFFA; IPO current; RCS; convergence improvement; electromagnetic wave scattering; equivalent surface impedance; far-field approximation; forward-backward method; iterative physical optics; matrix-vector product; open-ended waveguide cavity; radar cross section; symmetric successive over-relaxation; wave propagation; Convergence; Iterative algorithms; Iterative methods; Jet engines; Optical computing; Optical propagation; Optical scattering; Optical waveguides; Physical optics; Physics computing;
Journal_Title :
Antennas and Propagation, IEEE Transactions on
DOI :
10.1109/TAP.2004.841317
