English

On filtered polynomial approximation on the sphere

Classical Analysis and ODEs 2015-09-15 v1

Abstract

This paper considers filtered polynomial approximations on the unit sphere SdRd+1\mathbb{S}^d\subset \mathbb{R}^{d+1}, obtained by truncating smoothly the Fourier series of an integrable function ff with the help of a "filter" hh, which is a real-valued continuous function on [0,)[0,\infty) such that h(t)=1h(t)=1 for t[0,1]t\in[0,1] and h(t)=0h(t)=0 for t2t\ge2. The resulting "filtered polynomial approximation" (a spherical polynomial of degree 2L12L-1) is then made fully discrete by approximating the inner product integrals by an NN-point cubature rule of suitably high polynomial degree of precision, giving an approximation called "filtered hyperinterpolation". In this paper we require that the filter hh and all its derivatives up to d12\lfloor\tfrac{d-1}{2}\rfloor are absolutely continuous, while its right and left derivatives of order d+12\lfloor \tfrac{d+1}{2}\rfloor exist everywhere and are of bounded variation. Under this assumption we show that for a function ff in the Sobolev space Wps(Sd), 1pW^s_p(\mathbb{S}^d),\ 1\le p\le \infty, both approximations are of the optimal order Ls L^{-s}, in the first case for s>0s>0 and in the second fully discrete case for s>d/ps>d/p.

Keywords

Cite

@article{arxiv.1509.03792,
  title  = {On filtered polynomial approximation on the sphere},
  author = {Heping Wang and Ian H. Sloan},
  journal= {arXiv preprint arXiv:1509.03792},
  year   = {2015}
}
R2 v1 2026-06-22T10:55:15.970Z