Numerical solution of Poisson partial differential equation in high dimension using two-layer neural networks

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2024-05-11 DOI:10.1090/mcom/3971

Mathias Dus, Virginie Ehrlacher

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Abstract

The aim of this article is to analyze numerical schemes using two-layer neural networks with infinite width for the resolution of the high-dimensional Poisson partial differential equation with Neumann boundary condition. Using Barron’s representation of the solution [IEEE Trans. Inform. Theory 39 (1993), pp. 930–945] with a probability measure defined on the set of parameter values, the energy is minimized thanks to a gradient curve dynamic on the 2 2 -Wasserstein space of the set of parameter values defining the neural network. Inspired by the work from Bach and Chizat [On the global convergence of gradient descent for over-parameterized models using optimal transport, 2018; ICM–International Congress of Mathematicians, EMS Press, Berlin, 2023], we prove that if the gradient curve converges, then the represented function is the solution of the elliptic equation considered. Numerical experiments are given to show the potential of the method.

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利用双层神经网络数值求解高维度泊松偏微分方程

本文旨在分析使用无限宽双层神经网络的数值方案，以解决具有诺伊曼边界条件的高维泊松偏微分方程。利用巴伦的求解表示法[IEEE Trans. Inform. Theory 39 (1993), pp.受 Bach 和 Chizat [On the global convergence of gradient descent for over-parameterized models using optimal transport, 2018; ICM-International Congress of Mathematicians, EMS Press, Berlin, 2023] 工作的启发，我们证明，如果梯度曲线收敛，那么所表示的函数就是所考虑的椭圆方程的解。我们给出了数值实验，以展示该方法的潜力。

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