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Main Authors: Herrera, Pablo, Taylor, Jamie M., Uriarte, Carlos, Muga, Ignacio, Pardo, David, van der Zee, Kristoffer G.
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2603.12982
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author Herrera, Pablo
Taylor, Jamie M.
Uriarte, Carlos
Muga, Ignacio
Pardo, David
van der Zee, Kristoffer G.
author_facet Herrera, Pablo
Taylor, Jamie M.
Uriarte, Carlos
Muga, Ignacio
Pardo, David
van der Zee, Kristoffer G.
contents Solving Partial Differential Equations (PDEs) using neural networks presents different challenges, including integration errors and spectral bias, often leading to poor approximations. In addition, standard neural network-based methods, such as Physics-Informed Neural Networks (PINNs), often lack stability when dealing with PDEs characterized by low-regularity solutions. To address these limitations, we introduce the Ritz--Uzawa Neural Networks (RUNNs) framework, an iterative methodology to solve strong, weak, and ultra-weak variational formulations. Rewriting the PDE as a sequence of Ritz-type minimization problems within a Uzawa loop provides an iterative framework that, in specific cases, reduces both bias and variance during training. We demonstrate that the strong formulation offers a passive variance reduction mechanism, whereas variance remains persistent in weak and ultra-weak regimes. Furthermore, we address the spectral bias of standard architectures through a data-driven frequency tuning strategy. By initializing a Sinusoidal Fourier Feature Mapping based on the Normalized Cumulative Power Spectral Density (NCPSD) of previous residuals or their proxies, the network dynamically adapts its bandwidth to capture high-frequency components and severe singularities. Numerical experiments demonstrate the robustness of RUNNs, accurately resolving highly oscillatory solutions and successfully recovering a discontinuous $L^2$ solution from a distributional $H^{-2}$ source -- a scenario where standard energy-based methods fail.
format Preprint
id arxiv_https___arxiv_org_abs_2603_12982
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle RUNNs: Ritz-Uzawa Neural Networks for Solving Variational Problems
Herrera, Pablo
Taylor, Jamie M.
Uriarte, Carlos
Muga, Ignacio
Pardo, David
van der Zee, Kristoffer G.
Numerical Analysis
Solving Partial Differential Equations (PDEs) using neural networks presents different challenges, including integration errors and spectral bias, often leading to poor approximations. In addition, standard neural network-based methods, such as Physics-Informed Neural Networks (PINNs), often lack stability when dealing with PDEs characterized by low-regularity solutions. To address these limitations, we introduce the Ritz--Uzawa Neural Networks (RUNNs) framework, an iterative methodology to solve strong, weak, and ultra-weak variational formulations. Rewriting the PDE as a sequence of Ritz-type minimization problems within a Uzawa loop provides an iterative framework that, in specific cases, reduces both bias and variance during training. We demonstrate that the strong formulation offers a passive variance reduction mechanism, whereas variance remains persistent in weak and ultra-weak regimes. Furthermore, we address the spectral bias of standard architectures through a data-driven frequency tuning strategy. By initializing a Sinusoidal Fourier Feature Mapping based on the Normalized Cumulative Power Spectral Density (NCPSD) of previous residuals or their proxies, the network dynamically adapts its bandwidth to capture high-frequency components and severe singularities. Numerical experiments demonstrate the robustness of RUNNs, accurately resolving highly oscillatory solutions and successfully recovering a discontinuous $L^2$ solution from a distributional $H^{-2}$ source -- a scenario where standard energy-based methods fail.
title RUNNs: Ritz-Uzawa Neural Networks for Solving Variational Problems
topic Numerical Analysis
url https://arxiv.org/abs/2603.12982