English

A new upper bound for sampling numbers

Numerical Analysis 2021-02-11 v2 Numerical Analysis

Abstract

We provide a new upper bound for sampling numbers (gn)nN(g_n)_{n\in \mathbb{N}} associated to the compact embedding of a separable reproducing kernel Hilbert space into the space of square integrable functions. There are universal constants C,c>0C,c>0 (which are specified in the paper) such that gn2Clog(n)nkcnσk2,n2, g^2_n \leq \frac{C\log(n)}{n}\sum\limits_{k\geq \lfloor cn \rfloor} \sigma_k^2\quad,\quad n\geq 2\,, where (σk)kN(\sigma_k)_{k\in \mathbb{N}} is the sequence of singular numbers (approximation numbers) of the Hilbert-Schmidt embedding Id:H(K)L2(D,ϱD)\text{Id}:H(K) \to L_2(D,\varrho_D). 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 Hmixs(Td)H^s_{\text{mix}}(\mathbb{T}^d) in L2(Td)L_2(\mathbb{T}^d) with s>1/2s>1/2. We obtain the asymptotic bound gnCs,dnslog(n)(d1)s+1/2, g_n \leq C_{s,d}n^{-s}\log(n)^{(d-1)s+1/2}\,, which improves on very recent results by shortening the gap between upper and lower bound to log(n)\sqrt{\log(n)}.

Keywords

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}
}
R2 v1 2026-06-23T18:55:58.427Z