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Numerical Integration over the Unit Sphere by using spherical t-design

Numerical Analysis 2016-11-10 v1

Abstract

This paper studies numerical integration over the unit sphere S2R3 \mathbb{S}^2 \subset \mathbb{R}^{3} by using spherical tt-design, which is an equal positive weights quadrature rule with polynomial precision tt. We investigate two kinds of spherical tt-designs with tt up to 160. One is well conditioned spherical tt-design(WSTD), which was proposed by [1] with N=(t+1)2 N=(t+1)^{2} . The other is efficient spherical tt-design(ESTD), given by Womersley [2], which is made of roughly of half cardinality of WSTD. Consequently, a series of persuasive numerical evidences indicates that WSTD is better than ESTD in the sense of worst-case error in Sobolev space Hs(S2) \mathbb{H}^{s}(\mathbb{S}^2) . Furthermore, WSTD is employed to approximate integrals of various of functions, especially including integrand has a point singularity over the unit sphere and a given ellipsoid. In particular, to deal with singularity of integrand, Atkinson's transformation [3] and Sidi's transformation [4] are implemented with the choices of `grading parameters' to obtain new integrand which is much smoother. Finally, the paper presents numerical results on uniform errors for approximating representive integrals over sphere with three quadrature rules: Bivariate trapezoidal rule, Equal area points and WSTD.

Keywords

Cite

@article{arxiv.1611.02785,
  title  = {Numerical Integration over the Unit Sphere by using spherical t-design},
  author = {Congpei An and Siyong Chen},
  journal= {arXiv preprint arXiv:1611.02785},
  year   = {2016}
}
R2 v1 2026-06-22T16:46:37.376Z