基于次采样数据的多尺度椭圆PDE上尺度与函数逼近

Yifan Chen, T. Hou
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引用次数: 2

摘要

. 多尺度偏微分方程的数值上尺度与异构函数的分散数据近似之间存在密切联系:选择用于推导上尺度方程的粗变量(在前者中)对应于用于近似的采样信息(在后者中)。因此,这两个问题都可以被认为是基于一些粗糙数据恢复目标函数,这些粗糙数据要么是由升级算法人为选择的,要么是由某些物理测量过程确定的。本文的目的是研究,在这样的设置下,对于一个特定的椭圆问题,在有限的计算预算下,粗数据的长度尺度(我们称之为下采样长度尺度)如何影响恢复的准确性。我们的分析和实验表明,减少子采样长度尺度可以提高精度,这意味着在这种计算受限的情况下,粗粒度或数据采集的指导标准,特别是导致对数值均匀化文献中Gamblets方法实现的直接见解。此外,如果目标函数没有足够的规律性,将长度尺度减小到零可能会导致近似误差的放大,这表明需要对拟近似的目标函数进行更强的先验假设。我们从理论上和数值上引入奇异权函数来处理它。这项工作揭示了粗数据的长度尺度、计算成本、目标函数的规律性以及近似和数值模拟的准确性之间的相互作用。
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Multiscale Elliptic PDE Upscaling and Function Approximation via Subsampled Data
. There is an intimate connection between numerical upscaling of multiscale PDEs and scattered data approximation of heterogeneous functions: the coarse variables selected for deriving an upscaled equation (in the former) correspond to the sampled information used for approximation (in the latter). As such, both problems can be thought of as recovering a target function based on some coarse data that are either artificially chosen by an upscaling algorithm or determined by some physical measurement process. The purpose of this paper is then to study, under such a setup and for a specific elliptic problem, how the lengthscale of the coarse data, which we refer to as the subsampled lengthscale, influences the accuracy of recovery, given limited computational budgets. Our analysis and experiments identify that reducing the subsampling lengthscale may improve the accuracy, implying a guiding criterion for coarse-graining or data acquisition in this computationally constrained scenario, especially leading to direct insights for the implementation of the Gamblets method in the numerical homogenization literature. Moreover, reducing the lengthscale to zero may lead to a blow-up of approximation error if the target function does not have enough regularity, suggesting the need for a stronger prior assumption on the target function to be approximated. We introduce a singular weight function to deal with it, both theoretically and numerically. This work sheds light on the interplay of the lengthscale of coarse data, the computational costs, the regularity of the target function, and the accuracy of approximations and numerical simulations.
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