2014
DOI: 10.1002/2013rs005250
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Multiscale electromagnetic computations using a hierarchical multilevel fast multipole algorithm

Abstract: A hierarchical multilevel fast multipole method (H-MLFMM) is proposed herein to accelerate the solutions of surface integral equation methods. The proposed algorithm is particularly suitable for solutions of wideband and multiscale electromagnetic problems. As documented in Zhao and Chew (2000) that the multilevel fast multipole method (MLFMM) achieves O(N log N) computational complexity in the fixed mesh size scenario, hk = cst, where h is the mesh size and k is the corresponding wave number, for problems dis… Show more

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Cited by 28 publications
(7 citation statements)
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“…Apart from the EPA, some other methods based on the hierarchical MLFMA [16], multiresolution basis functions [17], and accelerated Cartesian expansion [18] have also been used to attack multiscale problems. In various advanced computing [19], chemistry [20], biology [21], and physics [22] applications, especially in N-body problems, a modified version of the FMM, namely, the adaptive FMM, has been used.…”
mentioning
confidence: 99%
“…Apart from the EPA, some other methods based on the hierarchical MLFMA [16], multiresolution basis functions [17], and accelerated Cartesian expansion [18] have also been used to attack multiscale problems. In various advanced computing [19], chemistry [20], biology [21], and physics [22] applications, especially in N-body problems, a modified version of the FMM, namely, the adaptive FMM, has been used.…”
mentioning
confidence: 99%
“…It requires that the surface currents in each independent subdomain be radiated to all other subdomains. The computation is accomplished with two mathematical ingredients: (i) a hierarchical multi-level fast multipole method (H-MLFMM) [49,50], which leads to the seamless integration of multi-level skeletonization technique [51] into the FMM framework and results in an effective matrix compression for non-uniform DG discretizations; (ii) a primal-dual octree partitioning algorithm for separable subdomain coupling [52]. Namely, instead of partitioning the entire computational domain into a single octree as in the traditional FMM, we have created independent octrees for all subdomains.…”
Section: Radiation Coupling Among Subdomainsmentioning
confidence: 99%
“…When the variety in the element size is large, conventional implementations often suff er from inaccuracy, instability, and/or ineffi ciency issues due to numerical breakdowns in the context of discretization, expansion, and/or matrix solution. As a natural consequence, there is an enormous collective eff ort in the literature [1][2][3][4][5][6][7][8][9] to develop accurate, stable, and effi cient numerical solvers for multi-scale problems involving nonuniform discretizations.…”
Section: Introductionmentioning
confidence: 99%