Riemann localisation on the sphere

Abstract

This paper first shows that the Riemann localisation property holds for the Fourier-Laplace series partial sum for sufficiently smooth functions on the two-dimensional sphere, but does not hold for spheres of higher dimension. By Riemann localisation on the sphere Sd⊂Rd+1, d2, we mean that for a suitable subset X of Lp(Sd), 1 p ∞, the Lp-norm of the Fourier local convolution of f∈ X converges to zero as the degree goes to infinity. The Fourier local convolution of f at x∈Sd is the Fourier convolution with a modified version of f obtained by replacing values of f by zero on a neighbourhood of x. The failure of Riemann localisation for d>2 can be overcome by considering a filtered version: we prove that for a sphere of any dimension and sufficiently smooth filter the corresponding local convolution always has the Riemann localisation property. Key tools are asymptotic estimates of the Fourier and filtered kernels.