Adaptive algorithms in sampling recovery

Abstract

We study optimal algorithms in adaptive sampling recovery of smooth functions defined on the unit d-cube d:= [0,1]d. The recovery error is measured in the quasi-norm \|·\|q of Lq := Lq(d). For B a subset in Lq, we define a sampling algorithm of recovery with the free choice of sample points and recovering functions from B as follows. For each f from the quasi-normed Besov space Bαp,θ, we choose n sample points. This choice defines n sampled values. Based on these sample points and sampled values, we choose a function from B for recovering f. The choice of n sample points and a recovering function from B for each f ∈ Bαp,θ defines a n-sampling algorithm SnB by functions in B. If = \φk\k ∈ K is a family of elements in Lq, let n() be the non-linear set of linear combinations of n free terms from , that is n():= \\, φ = Σj=1n aj φkj: \ kj ∈ K \, \. Denote by G the set of all families in Lq such that the intersection of with any finite dimensional subspace in Lq is a finite set, and by (Bαp,θ, Lq) the set of all continuous mappings from Bαp,θ into Lq. We define the quantity n(Bαp,θ,Lq) := ∈f ∈ G ∈fSnB ∈ (X, Lq): B= n() \|f\|Bαp,θ 1 \ \|f - SnB(f)\|q. Let 0 < p,q, θ ∞ and α > d/p. Then we prove the asymptotic order n(Bαp,θ,Lq) n- α / d. We also obtained the asymptotic order of quantities of optimal recovery by SnB in terms of best n-term approximation as well of other non-linear n-widths.