Solving multiscale elliptic problems by sparse radial basis function neural networks

TL;DR

This paper introduces a sparse radial basis function neural network approach for efficiently solving multiscale elliptic PDEs, demonstrating high accuracy and scalability in complex, high-dimensional problems.

Contribution

The paper proposes a novel RBF neural network method with regularization for multiscale elliptic PDEs, improving efficiency and accuracy over existing machine learning techniques.

Findings

Achieves accurate solutions for multiscale problems with fewer RBFs.

Scales efficiently with the smallest scale parameter, ε.

Outperforms other machine learning methods in robustness and accuracy.

Abstract

Machine learning has been successfully applied to various fields of scientific computing in recent years. In this work, we propose a sparse radial basis function neural network method to solve elliptic partial differential equations (PDEs) with multiscale coefficients. Inspired by the deep mixed residual method, we rewrite the second-order problem into a first-order system and employ multiple radial basis function neural networks (RBFNNs) to approximate unknown functions in the system. To aviod the overfitting due to the simplicity of RBFNN, an additional regularization is introduced in the loss function. Thus the loss function contains two parts: the $L_2$ loss for the residual of the first-order system and boundary conditions, and the $\ell_1$ regularization term for the weights of radial basis functions (RBFs). An algorithm for optimizing the specific loss function is introduced to accelerate the training process. The accuracy and effectiveness of the proposed method are demonstrated through a collection of multiscale problems with scale separation, discontinuity and multiple scales from one to three dimensions. Notably, the $\ell_1$ regularization can achieve the goal of representing the solution by fewer RBFs. As a consequence, the total number of RBFs scales like $\mathcal{O}(\varepsilon^{-n\tau})$, where $\varepsilon$ is the smallest scale, $n$ is the dimensionality, and $\tau$ is typically smaller than $1$. It is worth mentioning that the proposed method not only has the numerical convergence and thus provides a reliable numerical solution in three dimensions when a classical method is typically not affordable, but also outperforms most other available machine learning methods in terms of accuracy and robustness.