Difference and Wavelet Characterizations of Distances from Functions in Lipschitz Spaces to Their Subspaces

Abstract

Let s denote the Lipschitz space of order s∈(0,∞) on Rn, which consists of all f∈C L∞ such that, for some constant L∈(0,∞) and some integer r∈(s,∞), equation* 0-1r f(x,y): =|h|≤ y |hr f(x)|≤ L ys, \ x∈Rn, \ y ∈(0, 1]. equation* Here (and throughout the article) C refers to continuous functions, and hr is the usual r-th order difference operator with step h∈Rn. For each f∈ s and ∈(0,L), let S(f,):= \ (x,y)∈Rn× [0,1]: r f(x,y)ys>\, and let μ: B(R+n+1) [0,∞] be a suitably defined nonnegative extended real-valued function on the Borel σ-algebra of subsets of R+n+1. Let (f) be the infimum of all ∈(0,∞) such that μ(S(f,))<∞. The main target of this article is to characterize the distance from f to a subspace V s of s for various function spaces V (including Sobolev, Besov--Triebel--Lizorkin, and Besov--Triebel--Lizorkin-type spaces) in terms of (f), showing that equation* (f) dist (f, V s)_s: = ∈fg∈ s V \|f-g\|_s.equation* Moreover, we present our results in a general framework based on quasi-normed lattices of function sequences X and Daubechies s-Lipschitz X-based spaces.