Explicit families of functions on the sphere with exactly known Sobolev space smoothness

We analyze explicit trial functions defined on the unit sphere S_d in the Euclidean space ℝ^d+1, d ≥ 1, that are integrable in the L_p-sense, p ε [1,∞). These functions depend on two free parameters: one determines the support and one, a critical exponent, controls the behavior near the boundary of the support. Three noteworthy features are: (1) they are simple to implement and capture typical behavior of functions in applications, (2) their integrals with respect to the uniform measure on the sphere are given by explicit formulas and, thus, their numerical values can be computed to arbitrary precision, and (3) their smoothness can be defined a priori, that is to say, they belong to Sobolev spaces H^s(S^d) up to a specified index Ns determined by the parameters of the function.Considered are zonal functions g(x) = h(x · p), where p is some fixed pole on S^d. The function h(t) is of the type [max(t, T)]^α or a variation of a truncated power function x (mapping) (x)^α ₊ C (which assumes 0 if x ≤ 0 and is the power x^α if x > 0) that reduces to [max(t - T,0)]α, [max(t² - T², 0)]^α, and [max(T² - t₂, 0)]^α if α > 0. These types of trial functions have as support the whole sphere, a spherical cap centered at p, a bi-cap centered at the antipodes p, -p, or an equatorial belt. We give inclusion theorems that identify the critical smoothness s = s(T, α) and explicit formulas for the integral over the sphere. We obtain explicit formulas for the coefficients in the Laplace- Fourier expansion of these trial functions and provide the leading order term in the asymptotics for large index of the coefficients.