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Efficient implementations of the Multivariate Decomposition Method for approximating infinite-variate integrals

Numerical Analysis 2018-08-06 v3 Numerical Analysis

Abstract

In this paper we focus on efficient implementations of the Multivariate Decomposition Method (MDM) for approximating integrals of \infty-variate functions. Such \infty-variate integrals occur for example as expectations in uncertainty quantification. Starting with the anchored decomposition f=uNfuf = \sum_{\mathfrak{u}\subset\mathbb{N}} f_\mathfrak{u}, where the sum is over all finite subsets of N\mathbb{N} and each fuf_\mathfrak{u} depends only on the variables xjx_j with juj\in\mathfrak{u}, our MDM algorithm approximates the integral of ff by first truncating the sum to some `active set' and then approximating the integral of the remaining functions fuf_\mathfrak{u} term-by-term using Smolyak or (randomized) quasi-Monte Carlo (QMC) quadratures. The anchored decomposition allows us to compute fuf_\mathfrak{u} explicitly by function evaluations of ff. Given the specification of the active set and theoretically derived parameters of the quadrature rules, we exploit structures in both the formula for computing fuf_\mathfrak{u} and the quadrature rules to develop computationally efficient strategies to implement the MDM in various scenarios. In particular, we avoid repeated function evaluations at the same point. We provide numerical results for a test function to demonstrate the effectiveness of the algorithm.

Keywords

Cite

@article{arxiv.1712.06782,
  title  = {Efficient implementations of the Multivariate Decomposition Method for approximating infinite-variate integrals},
  author = {Alexander D. Gilbert and Frances Y. Kuo and Dirk Nuyens and Grzegorz W. Wasilkowski},
  journal= {arXiv preprint arXiv:1712.06782},
  year   = {2018}
}
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