On filtered polynomial approximation on the sphere

Abstract

This paper considers filtered polynomial approximations on the unit sphere Sd⊂ Rd+1, obtained by truncating smoothly the Fourier series of an integrable function f with the help of a "filter" h, which is a real-valued continuous function on [0,∞) such that h(t)=1 for t∈[0,1] and h(t)=0 for t2. The resulting "filtered polynomial approximation" (a spherical polynomial of degree 2L-1) is then made fully discrete by approximating the inner product integrals by an N-point cubature rule of suitably high polynomial degree of precision, giving an approximation called "filtered hyperinterpolation". In this paper we require that the filter h and all its derivatives up to d-12 are absolutely continuous, while its right and left derivatives of order d+12 exist everywhere and are of bounded variation. Under this assumption we show that for a function f in the Sobolev space Wsp(Sd),\ 1 p ∞, both approximations are of the optimal order L-s, in the first case for s>0 and in the second fully discrete case for s>d/p.