Learning elliptic partial differential equations with randomized linear algebra

Abstract

Given input-output pairs of an elliptic partial differential equation (PDE) in three dimensions, we derive the first theoretically-rigorous scheme for learning the associated Green's function G. By exploiting the hierarchical low-rank structure of G, we show that one can construct an approximant to G that converges almost surely and achieves a relative error of O(ε-1/23(1/ε)ε) using at most O(ε-64(1/ε)) input-output training pairs with high probability, for any 0<ε<1. The quantity 0<ε≤ 1 characterizes the quality of the training dataset. Along the way, we extend the randomized singular value decomposition algorithm for learning matrices to Hilbert--Schmidt operators and characterize the quality of covariance kernels for PDE learning.

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