English

Algorithms and Complexity for Functions on General Domains

Numerical Analysis 2020-01-15 v2 Computational Complexity Numerical Analysis

Abstract

Error bounds and complexity bounds in numerical analysis and information-based complexity are often proved for functions that are defined on very simple domains, such as a cube, a torus, or a sphere. We study optimal error bounds for the approximation or integration of functions defined on DdRdD_d \subset R^d and only assume that DdD_d is a bounded Lipschitz domain. Some results are even more general. We study three different concepts to measure the complexity: order of convergence, asymptotic constant, and explicit uniform bounds, i.e., bounds that hold for all nn (number of pieces of information) and all (normalized) domains. It is known for many problems that the order of convergence of optimal algorithms does not depend on the domain DdRdD_d \subset R^d. We present examples for which the following statements are true: 1) Also the asymptotic constant does not depend on the shape of DdD_d or the imposed boundary values, it only depends on the volume of the domain. 2) There are explicit and uniform lower (or upper, respectively) bounds for the error that are only slightly smaller (or larger, respectively) than the asymptotic error bound.

Keywords

Cite

@article{arxiv.1908.05943,
  title  = {Algorithms and Complexity for Functions on General Domains},
  author = {Erich Novak},
  journal= {arXiv preprint arXiv:1908.05943},
  year   = {2020}
}

Comments

minor revision; to appear in Journal of Complexity

R2 v1 2026-06-23T10:49:04.294Z