On approximating the shape of one dimensional functions
Abstract
Consider an -dimensional function being evaluated at points of a low discrepancy sequence (LDS), where the objective is to approximate the one-dimensional functions that result from integrating out variables. Here, the emphasis is on accurately approximating the shape of such \emph{one-dimensional} functions. Approximating this shape when the function is evaluated on a set of grid points instead is relatively straightforward. However, the number of grid points needed increases exponentially with . LDS are known to be increasingly more efficient at integrating -dimensional functions compared to grids, as increases. Yet, a method to approximate the shape of a one-dimensional function when the function is evaluated using an -dimensional LDS has not been proposed thus far. We propose an approximation method for this problem. This method is based on an -dimensional integration rule together with fitting a polynomial smoothing function. We state and prove results showing conditions under which this polynomial smoothing function will converge to the true one-dimensional function. We also demonstrate the computational efficiency of the new approach compared to a grid based approach.
Cite
@article{arxiv.1911.03045,
title = {On approximating the shape of one dimensional functions},
author = {Chaitanya Joshi and Paul T. Brown and Stephen Joe},
journal= {arXiv preprint arXiv:1911.03045},
year = {2019}
}