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BIT Numerical Mathematics

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06.11.2017

Ubiquitous evaluation of layer potentials using Quadrature by Kernel-Independent Expansion

verfasst von: Abtin Rahimian, Alex Barnett, Denis Zorin

Erschienen in: BIT Numerical Mathematics | Ausgabe 2/2018

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Abstract

We introduce a quadrature scheme—QBKIX —for the ubiquitous high-order accurate evaluation of singular layer potentials associated with general elliptic PDEs, i.e., a scheme that yields high accuracy at all distances to the domain boundary as well as on the boundary itself. Relying solely on point evaluations of the underlying kernel, our scheme is essentially PDE-independent; in particular, no analytic expansion nor addition theorem is required. Moreover, it applies to boundary integrals with singular, weakly singular, and hypersingular kernels. Our work builds upon quadrature by expansion, which approximates the potential by an analytic expansion in the neighborhood of each expansion center. In contrast, we use a sum of fundamental solutions lying on a ring enclosing the neighborhood, and solve a small dense linear system for their coefficients to match the potential on a smaller concentric ring. We test the new method with Laplace, Helmholtz, Yukawa, Stokes, and Navier (elastostatic) kernels in two dimensions (2D) using adaptive, panel-based boundary quadratures on smooth and corner domains. Advantages of the algorithm include its relative simplicity of implementation, immediate extension to new kernels, dimension-independence (allowing simple generalization to 3D), and compatibility with fast algorithms such as the kernel-independent FMM.

Vorheriger Artikel Composite symmetric general linear methods (COSY-GLMs) for the long-time integration of reversible Hamiltonian systems

Nächster Artikel Lagrangian and Hamiltonian Taylor variational integrators

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Titel: Ubiquitous evaluation of layer potentials using Quadrature by Kernel-Independent Expansion
verfasst von: Abtin Rahimian
Alex Barnett
Denis Zorin
Publikationsdatum: 06.11.2017
Verlag: Springer Netherlands
Erschienen in: BIT Numerical Mathematics / Ausgabe 2/2018
Print ISSN: 0006-3835
Elektronische ISSN: 1572-9125
DOI: https://doi.org/10.1007/s10543-017-0689-2

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