Title :
Accelerating fast multipole methods for the Helmholtz equation at low frequencies
Author :
Reengard, Leslieg ; Jingfang Huang ; Khlin, Vladimirro ; Wandzura, Stephen
Author_Institution :
Courant Inst. of Math. Sci., New York, NY, USA
Abstract :
The authors describe a diagonal form for translating far-field expansions to use in low frequency fast multipole methods. Their approach combines evanescent and propagating plane waves to reduce the computational cost of FMM implementation. More specifically, we present the analytic foundations for a new version of the fast multipole method for the scalar Helmholtz equation in the low frequency regime. The computational cost of existing FMM implementations, is dominated by the expense of translating far field partial wave expansions to local ones, requiring 189p4 or 189p3 operations per box, where harmonics up to order p2 have been retained. By developing a new expansion in plane waves, we can diagonalize these translation operators. The new low frequency FMM (LF-FMM) requires 40p2+6p2 operations per box
Keywords :
Fourier transforms; Helmholtz equations; computational complexity; FMM implementation; computational cost; diagonal form; evanescent waves; far field partial wave expansions; far-field expansions; fast multipole method acceleration; low frequencies; low frequency FMM; low frequency fast multipole methods; low frequency regime; propagating plane waves; scalar Helmholtz equation; translation operators; Acoustic propagation; Acoustic waves; Computational efficiency; Electromagnetic modeling; Electromagnetic propagation; Electromagnetic scattering; Frequency; Laplace equations; Large-scale systems; Microwave propagation;
Journal_Title :
Computational Science & Engineering, IEEE
