A new upper bound for sampling numbers
Abstract
We provide a new upper bound for sampling numbers associated to the compact embedding of a separable reproducing kernel Hilbert space into the space of square integrable functions. There are universal constants (which are specified in the paper) such that where is the sequence of singular numbers (approximation numbers) of the Hilbert-Schmidt embedding . The algorithm which realizes the bound is a least squares algorithm based on a specific set of sampling nodes. These are constructed out of a random draw in combination with a down-sampling procedure coming from the celebrated proof of Weaver's conjecture, which was shown to be equivalent to the Kadison-Singer problem. Our result is non-constructive since we only show the existence of a linear sampling operator realizing the above bound. The general result can for instance be applied to the well-known situation of in with . We obtain the asymptotic bound which improves on very recent results by shortening the gap between upper and lower bound to .
Cite
@article{arxiv.2010.00327,
title = {A new upper bound for sampling numbers},
author = {Nicolas Nagel and Martin Schäfer and Tino Ullrich},
journal= {arXiv preprint arXiv:2010.00327},
year = {2021}
}