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Efficient Shallow Ritz Method For 1D Diffusion-Reaction Problems

Numerical Analysis 2025-10-24 v4 Machine Learning Numerical Analysis

Abstract

This paper studies the shallow Ritz method for solving one-dimensional diffusion-reaction problems. The method is capable of improving the order of approximation for non-smooth problems. By following a similar approach to the one presented in [9], we present a damped block Newton (dBN) method to achieve nearly optimal order of approximation. The dBN method optimizes the Ritz functional by alternating between the linear and non-linear parameters of the shallow ReLU neural network (NN). For diffusion-reaction problems, new difficulties arise: (1) for the linear parameters, the mass matrix is dense and even more ill-conditioned than the stiffness matrix, and (2) for the non-linear parameters, the Hessian matrix is dense and may be singular. This paper addresses these challenges, resulting in a dBN method with computational cost of O(n){\cal O}(n). The ideas presented for diffusion-reaction problems can also be applied to least-squares approximation problems. For both applications, starting with the non-linear parameters as a uniform partition, numerical experiments show that the dBN method moves the mesh points to nearly optimal locations.

Keywords

Cite

@article{arxiv.2407.01496,
  title  = {Efficient Shallow Ritz Method For 1D Diffusion-Reaction Problems},
  author = {Zhiqiang Cai and Anastassia Doktorova and Robert D. Falgout and César Herrera},
  journal= {arXiv preprint arXiv:2407.01496},
  year   = {2025}
}
R2 v1 2026-06-28T17:25:17.975Z