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Autori principali: Wu, Yulun, Aguiar, Miguel, Johansson, Karl H., Barreau, Matthieu
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2510.19399
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author Wu, Yulun
Aguiar, Miguel
Johansson, Karl H.
Barreau, Matthieu
author_facet Wu, Yulun
Aguiar, Miguel
Johansson, Karl H.
Barreau, Matthieu
contents Spectral bias, the tendency of neural networks to learn low-frequency features first, is a well-known issue with many training algorithms for physics-informed neural networks (PINNs). To overcome this issue, we propose IFeF-PINN, an algorithm for iterative training of PINNs with Fourier-enhanced features. The key idea is to enrich the latent space using high-frequency components through Random Fourier Features. This creates a two-stage training problem: (i) estimate a basis in the feature space, and (ii) perform regression to determine the coefficients of the enhanced basis functions. For an underlying linear model, it is shown that the latter problem is convex, and we prove that the iterative training scheme converges. Furthermore, we empirically establish that Random Fourier Features enhance the expressive capacity of the network, enabling accurate approximation of high-frequency PDEs. Through extensive numerical evaluation on classical benchmark problems, the superior performance of our method over state-of-the-art algorithms is shown, and the improved approximation across the frequency domain is illustrated.
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publishDate 2025
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spellingShingle Iterative Training of Physics-Informed Neural Networks with Fourier-enhanced Features
Wu, Yulun
Aguiar, Miguel
Johansson, Karl H.
Barreau, Matthieu
Machine Learning
Spectral bias, the tendency of neural networks to learn low-frequency features first, is a well-known issue with many training algorithms for physics-informed neural networks (PINNs). To overcome this issue, we propose IFeF-PINN, an algorithm for iterative training of PINNs with Fourier-enhanced features. The key idea is to enrich the latent space using high-frequency components through Random Fourier Features. This creates a two-stage training problem: (i) estimate a basis in the feature space, and (ii) perform regression to determine the coefficients of the enhanced basis functions. For an underlying linear model, it is shown that the latter problem is convex, and we prove that the iterative training scheme converges. Furthermore, we empirically establish that Random Fourier Features enhance the expressive capacity of the network, enabling accurate approximation of high-frequency PDEs. Through extensive numerical evaluation on classical benchmark problems, the superior performance of our method over state-of-the-art algorithms is shown, and the improved approximation across the frequency domain is illustrated.
title Iterative Training of Physics-Informed Neural Networks with Fourier-enhanced Features
topic Machine Learning
url https://arxiv.org/abs/2510.19399