B-spline quasi-interpolant representations and sampling recovery of functions with mixed smoothness

Abstract

Let = \xj\j=1n be a grid of n points in the d-cube d:=[0,1]d, and = \φj\j =1n a family of n functions on d. We define the linear sampling algorithm Ln(,,·) for an approximate recovery of a continuous function f on d from the sampled values f(x1), ..., f(xn), by Ln(,,f)\ := \ Σj=1n f(xj)φj. For the Besov class Bαp,θ of mixed smoothness α (defined as the unit ball of the Besov space ), to study optimality of Ln(,,·) in Lq(d) we use the quantity rn(Bαp,θ)q \ := \ ∈fH, \ f ∈ Bαp,θ \, \|f - Ln(,xi,f)\|q, where the infimum is taken over all grids = \xj\j=1n and all families = \φj\j=1n in Lq(d). We explicitly constructed linear sampling algorithms Ln(,,·) on the grid = \ Gd(m):= \(2-k1s1,...,2-kdsd) ∈ d : \ k1 + ... + kd m\, with a family of linear combinations of mixed B-splines which are mixed tensor products of either integer or half integer translated dilations of the centered B-spline of order r. The grid Gd(m) is of the size 2m md-1 and sparse in comparing with the generating dyadic coordinate cube grid of the size 2dm. For various 0<p,q,θ ∞ and 1/p < α < r, we proved upper bounds for the worst case error f ∈ Bαp,θ \, \|f - Ln(,,f)\|q which coincide with the asymptotic order of rn(Bαp,θ)q in some cases. A key role in constructing these linear sampling algorithms, plays a quasi-interpolant representation of functions f ∈ Bαp,θ by mixed B-spline series.