论文信息 - Application of adaptive integral method to scattering and radiation analysis of arbitrarily shaped planar structures

Application of adaptive integral method to scattering and radiation analysis of arbitrarily shaped planar structures

The adaptive integral method (AIM) is applied to the scattering and radiation analysis of arbitrarily shaped planar structures. The method extends the well-known conjugate gradient fast Fourier transform (CGFFT) method to the triangular subdomain discretization, which has a much better geometry modeling capability than the rectangular subdomain discretization employed in the traditional CGFFT method. The resulting algorithm has a memory requirement proportional to O(N) and the operation count for the matrix-vector multiplication proportional to O(N log N). Numerical results are presented to demonstrate the efficiency and accuracy of this method.

Jian-Ming Jin | Feng Ling | Chao-Fu Wang

[1] D. Wilton,et al. Electromagnetic scattering by surfaces of arbitrary shape , 1980 .

[2] Jian-Ming Jin,et al. A Biconjugate Gradient FFT Solution for Scattering by Planar Plates , 1992 .

[3] P. M. van den Berg,et al. A weak form of the conjugate gradient FFT method for plate problems , 1991 .

[4] T. Sarkar,et al. Comments on "Application of FFT and the conjugate gradient method for the solution of electromagnetic radiation from electrically large and small conducting bodies" , 1986 .

[5] Jiming Song,et al. Fast multipole method solution using parametric geometry , 1994 .

[6] R. Duhamel,et al. Broadband logarithmically periodic antenna structures , 1957 .

[7] V. Rokhlin. Rapid Solution of Integral Equations of Scattering Theory , 1990 .

[8] Jiming Song,et al. Multilevel fast multipole algorithm for electromagnetic scattering by large complex objects , 1997 .

[9] M. Cátedra,et al. A numerical scheme to obtain the RCS of three-dimensional bodies of resonant size using the conjugate gradient method and the fast Fourier transform , 1989 .

[10] R. Coifman,et al. The fast multipole method for the wave equation: a pedestrian prescription , 1993, IEEE Antennas and Propagation Magazine.

[11] M. Bleszynski,et al. AIM: Adaptive integral method for solving large‐scale electromagnetic scattering and radiation problems , 1996 .