Close evaluation of layer potentials in three dimensions

International audience We present a simple and effective method for evaluating double- and single-layer potentials for Laplace’s equation in three dimensions close to the boundary. The close evaluation of these layer potentials is challenging because they are nearly singular integrals. The method we...

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Bibliographic Details
Main Authors: Khatri, Shilpa, Kim, Arnold, Cortez, Ricardo, Carvalho, Camille
Other Authors: University of California Merced (UC Merced), University of California (UC), Tulane University
Format: Article in Journal/Newspaper
Language:English
Published: HAL CCSD 2020
Subjects:
boundary integral equations
Nearly singular integrals
close evaluation problem
potential theory
numerical quadrature
[MATH]Mathematics [math]
[MATH.MATH-AP]Mathematics [math]/Analysis of PDEs [math.AP]
[MATH.MATH-NA]Mathematics [math]/Numerical Analysis [math.NA]
[MATH.MATH-MP]Mathematics [math]/Mathematical Physics [math-ph]
North Pole
Online Access:https://hal.archives-ouvertes.fr/hal-01832316
https://hal.archives-ouvertes.fr/hal-01832316/document
https://hal.archives-ouvertes.fr/hal-01832316/file/CKK3D-2018.pdf
Description
Summary:International audience We present a simple and effective method for evaluating double- and single-layer potentials for Laplace’s equation in three dimensions close to the boundary. The close evaluation of these layer potentials is challenging because they are nearly singular integrals. The method we propose is based on writing these layer potentials in spherical coordinates where the point at which their kernels are peaked maps to the north pole. An N-point Gauss-Legendre quadrature rule is used for integration with respect to the polar angle rather than the cosine of the polar angle. A 2N-point periodic trapezoid rule is used to compute the integral with respect to the azimuthal angle which acts as a natural and effective averaging operation in this coordinate system. The numerical method resulting from combining these two quadrature rules in this rotated coordinate system yields results that are consistent with asymptotic behaviors of the double- and single-layer potentials at close evaluation distances. In particular, we show that the error in computing the double-layer potential, after applying a subtraction method, is quadratic with respect to the evaluation distance from the boundary, and the error is linear for the single-layer potential. We improve upon the single-layer potential by introducing an alternate approximation based on a perturbation expansion and obtain an error that is quadratic with respect to the evaluation distance from the boundary.

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