Randomized Complexity of Vector-Valued Approximation
Abstract
We study the randomized -th minimal errors (and hence the complexity) of vector valued approximation. In a recent paper by the author [Randomized complexity of parametric integration and the role of adaption I. Finite dimensional case (preprint)] a long-standing problem of Information-Based Complexity was solved: Is there a constant such that for all linear problems the randomized non-adaptive and adaptive -th minimal errors can deviate at most by a factor of ? That is, does the following hold for all linear and \begin{equation*} e_n^{\rm ran-non} (\mathcal{P})\le ce_n^{\rm ran} (\mathcal{P}) \, {\bf ?} \end{equation*} The analysis of vector-valued mean computation showed that the answer is negative. More precisely, there are instances of this problem where the gap between non-adaptive and adaptive randomized minimal errors can be (up to log factors) of the order . This raises the question about the maximal possible deviation. In this paper we show that for certain instances of vector valued approximation the gap is (again, up to log factors).
Cite
@article{arxiv.2306.13697,
title = {Randomized Complexity of Vector-Valued Approximation},
author = {Stefan Heinrich},
journal= {arXiv preprint arXiv:2306.13697},
year = {2023}
}
Comments
14 pages. arXiv admin note: substantial text overlap with arXiv:2306.13471