Numerical Performance of Optimized Frolov Lattices in Tensor Product Reproducing Kernel Sobolev Spaces

Christopher Kacwin; Jens Oettershagen; Mario Ullrich; Tino Ullrich

doi:10.1007/s10208-020-09463-y

Numerical Performance of Optimized Frolov Lattices in Tensor Product Reproducing Kernel Sobolev Spaces

Christopher Kacwin
, Jens Oettershagen
, Mario Ullrich
, Tino Ullrich

Research output: Contribution to journal › Article › peer-review

Abstract

In this paper, we deal with several aspects of the universal Frolov cubature method, which is known to achieve optimal asymptotic convergence rates in a broad range of function spaces. Even though every admissible lattice has this favorable asymptotic behavior, there are significant differences concerning the precise numerical behavior of the worst-case error. To this end, we propose new generating polynomials that promise a significant reduction in the integration error compared to the classical polynomials. Moreover, we develop a new algorithm to enumerate the Frolov points from non-orthogonal lattices for numerical cubature in the d-dimensional unit cube [0,1]d. Finally, we study Sobolev spaces with anisotropic mixed smoothness and compact support in [0,1]d and derive explicit formulas for their reproducing kernels. This allows for the simulation of exact worst-case errors which numerically validate our theoretical results.

Original language	English
Pages (from-to)	849–889
Number of pages	41
Journal	Foundations of Computational Mathematics
Volume	21
Issue number	3
DOIs	https://doi.org/10.1007/s10208-020-09463-y
Publication status	Published - Jun 2021

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101002 Analysis
101032 Functional analysis

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abstract = "In this paper, we deal with several aspects of the universal Frolov cubature method, which is known to achieve optimal asymptotic convergence rates in a broad range of function spaces. Even though every admissible lattice has this favorable asymptotic behavior, there are significant differences concerning the precise numerical behavior of the worst-case error. To this end, we propose new generating polynomials that promise a significant reduction in the integration error compared to the classical polynomials. Moreover, we develop a new algorithm to enumerate the Frolov points from non-orthogonal lattices for numerical cubature in the d-dimensional unit cube [0,1]d. Finally, we study Sobolev spaces with anisotropic mixed smoothness and compact support in [0,1]d and derive explicit formulas for their reproducing kernels. This allows for the simulation of exact worst-case errors which numerically validate our theoretical results.",

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PY - 2021/6

Y1 - 2021/6

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AB - In this paper, we deal with several aspects of the universal Frolov cubature method, which is known to achieve optimal asymptotic convergence rates in a broad range of function spaces. Even though every admissible lattice has this favorable asymptotic behavior, there are significant differences concerning the precise numerical behavior of the worst-case error. To this end, we propose new generating polynomials that promise a significant reduction in the integration error compared to the classical polynomials. Moreover, we develop a new algorithm to enumerate the Frolov points from non-orthogonal lattices for numerical cubature in the d-dimensional unit cube [0,1]d. Finally, we study Sobolev spaces with anisotropic mixed smoothness and compact support in [0,1]d and derive explicit formulas for their reproducing kernels. This allows for the simulation of exact worst-case errors which numerically validate our theoretical results.

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ER -

Numerical Performance of Optimized Frolov Lattices in Tensor Product Reproducing Kernel Sobolev Spaces

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