Infinite-dimensional integration and the multivariate decomposition method
Abstract
We further develop the \emph{Multivariate Decomposition Method} (MDM) for the Lebesgue integration of functions of infinitely many variables with respect to a corresponding product of a one dimensional probability measure. Although a number of concepts of infinite-dimensional integrals have been used in the literature, questions of uniqueness and compatibility have mostly not been studied. We show that, under appropriate convergence conditions, the Lebesgue integral equals the `anchored' integral, independently of the anchor. The MDM assumes that point values of are available for important subsets , at some known cost. In this paper we introduce a new setting, in which it is assumed that each belongs to a normed space , and that bounds on are known. This contrasts with the assumption in many papers that weights , appearing in the norm of the infinite-dimensional function space, are somehow known. Often such weights were determined by minimizing an error bound depending on the , the \emph{and} the chosen algorithm, resulting in weights that depend on the algorithm. In contrast, in this paper only the bounds are assumed known. We give two examples in which we specialize the MDM: in the first case is the -fold tensor product of an anchored reproducing kernel Hilbert space, and in the second case it is a particular non-Hilbert space for integration over an unbounded domain.
Cite
@article{arxiv.1501.05445,
title = {Infinite-dimensional integration and the multivariate decomposition method},
author = {Frances Y. Kuo and Dirk Nuyens and Leszek Plaskota and Ian H. Sloan and Grzegorz W. Wasilkowski},
journal= {arXiv preprint arXiv:1501.05445},
year = {2016}
}