Multilevel fast multipole algorithm for electromagnetic scattering by large complex objects

Song, Jiming; Lu, Cai‐Cheng; Chew, Weng Cho

doi:10.1109/8.633855

Cited by 1,440 publications

(856 citation statements)

References 32 publications

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“…Because of that, many MoM acceleration strategies based on iterative solutions have emerged to reduce the computational complexity. Among these acceleration techniques, it must be pointed out the Fast Multipole Method (FMM) [4] and its multilevel version, the Multilevel Fast Multipole Algorithm (MLFMA) [5][6][7][8], which are extensively used at present. Nevertheless, the FMM and, in general, other methods that tackle the electromagnetic analysis within the framework of iterative schemes usually meet with difficulties when dealing with radiation problems.…”

Section: Introductionmentioning

confidence: 99%

Geometry Based Preconditioner for Radiation Problems Involving Wire and Surface Basis Functions

Araújo¹,

Bertolo

Obelleiro³

et al. 2009

PIER

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Abstract-An innovative preconditioner has been developed in this work. It significantly improves the convergence of the iterative solvers applied to electromagnetic radiation problems by a renormalization of the matrix equation. The preconditioner balances the disparities in terms of magnitude and units caused by the strong self-coupling of the antennas, the non-uniformity of the meshes and also by the coexistence of wire and surface basis functions. It can be easily integrated into different electromagnetic solvers with a negligible impact on the computational cost on account of its simple implementation.

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Section: Introductionmentioning

confidence: 99%

Geometry Based Preconditioner for Radiation Problems Involving Wire and Surface Basis Functions

Araújo¹,

Bertolo

Obelleiro³

et al. 2009

PIER

View full text Add to dashboard Cite

show abstract

“…For the matrix-vector product with N unknowns, the two-level FMM reduces both the memory requirement and numerical complexity from O(N 2 ) to O(N 1.5 ) and the three-level FMM reduces it to O(N 4/3 ) [16][17][18][19]. By using the multilevel fast multipole method (MLFMM), the numerical complexity can be further reduced to O(N log N ) [21][22][23][24].…”

Section: The Fast Multipole Accelerationmentioning

confidence: 99%

“…In (9), L is an infinite number. However, in numerical practice, L must be truncated with the finite number of modes and the relative error is depending on L with the following relationship [18,21]:…”

Section: The Fast Multipole Accelerationmentioning

confidence: 99%

Fast Analysis of Electrically Large Radome in Millimeter Wave Band With Fast Multipole Acceleration

Meng¹,

Dou²

2011

PIER

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Abstract-Radome has strong effects on the radiation performances of the antenna in millimeter wave band. In this paper, the aperture integration-surface integration (AI-SI) method is adopted to analyze the electrically large antenna-radome system. The fast multipole method (FMM) is proposed to accelerate the aperture integration and inner surface integration in the AI-SI method. An electrically large antenna-radome system at W band is analyzed and measured. The radiation patterns of the system calculated using the AI-SI method with and without the fast multipole acceleration and the measured patterns are compared. The calculated patterns agree very well with each other, and both have the same agreement with the experimental results. However, the computational time of the proposed analysis with the fast multipole acceleration is reduced significantly.

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“…Several techniques have been proposed to reduce the memory demands as well as the solution complexity of the conventional MoM. Fast integral equation solvers, such as the multilevel fast multiple method (MLFMM) [4,5], adaptive integral method (AIM) [6,7] and its close counterpart, the precorrected FFT (PC-FFT) [8,9], reach the solution complexity and memory requirement as O(N log(N )). However, when the scatter becomes electrically large, the number of unknowns becomes so large that even the fast integral equation solvers cannot solve it efficiently.…”

Section: Introductionmentioning

confidence: 99%

Higher Order Hierarchical Legendre Basis Functions Application to the Analysis of Scattering by Uniaxial Anisotropic Objects

Lv¹,

Shi²,

Chen³

2010

PIER M

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Abstract-An efficient technique for the analysis of scattering by uniaxial anisotropic objects is presented. The technique is based on the method of higher order MoM of the surface integral equations. This higher order MoM solution uses the higher order hierarchical basis functions which are based on the modified Legendre polynomials. Numerical results are given to demonstrate that the higher order hierarchical basis functions are more accurate and efficient in the calculations of uniaxial anisotropic objects scattering problem than the low-order basis function.

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Multilevel fast multipole algorithm for electromagnetic scattering by large complex objects

Cited by 1,440 publications

References 32 publications

Geometry Based Preconditioner for Radiation Problems Involving Wire and Surface Basis Functions

Geometry Based Preconditioner for Radiation Problems Involving Wire and Surface Basis Functions

Fast Analysis of Electrically Large Radome in Millimeter Wave Band With Fast Multipole Acceleration

Higher Order Hierarchical Legendre Basis Functions Application to the Analysis of Scattering by Uniaxial Anisotropic Objects

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