Framelet perturbation and application to nouniform sampling approximation for Sobolev space

Abstract

The Sobolev space Hs(Rd), where s > d/2, is an important function space that has many applications in various areas of research. Attributed to the inertia of a measuring instrument, it is desirable in sampling theory to reconstruct a function by its nonuniform samples. In the present paper, we investigate the problem of constructing the approximation to all the functions in Hs(Rd) with nonuniform samples by utilizing dual framelet systems for the Sobolev space pair (Hs(Rd), H-s(Rd)). We first establish the convergence rates of the framelet series in (Hs(Rd), H-s(Rd)), and then construct the framelet approximation operator holding for the entire space Hs(Rd). Using the approximation operator, any function in Hs(Rd) can be approximated at the exponential rate with respect to the scale level. We examine the stability property for the perturbations of the framelet approximation operator with respect to shift parameters, and obtain an estimate bound for the perturbation error. Our result shows that under the condition s > d/2, the approximation operator is robust to the shift perturbation. These results are used to establish the nonuniform sampling approximation for every function in Hs(Rd). In particular, the new nonuniform sampling approximation error is robust to the jittering of the samples.