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Research PaperResearchia:202607.08076

Physics-Informed Neural Embeddings of PDE Solution Families

Raul Jimenez

Abstract

We introduce a physics-informed framework for learning finite-dimensional embeddings of solution families of partial differential equations. The method uses a multihead Physics-Informed Neural Network in which a shared body learns a latent manifold representing the solution space, while linear heads reconstruct individual solutions associated with different initial conditions. A head-orthogonalization penalty removes degeneracies in the latent representation and stabilizes the principal-componen...

Submitted: July 8, 2026Subjects: Machine Learning; Data Science

Description / Details

We introduce a physics-informed framework for learning finite-dimensional embeddings of solution families of partial differential equations. The method uses a multihead Physics-Informed Neural Network in which a shared body learns a latent manifold representing the solution space, while linear heads reconstruct individual solutions associated with different initial conditions. A head-orthogonalization penalty removes degeneracies in the latent representation and stabilizes the principal-component spectrum across training realizations. Because the initial condition is built into the network output by construction, these principal components measure the additional variability the network learns on top of the initial profile, not the full solution itself. We apply the method to the one-dimensional viscous Burgers equation, with the heat and wave equations as robustness checks. For a latent dimension nb=20n_b=20, the learned manifolds exhibit pronounced effective dimensional reduction: for Burgers dynamics, only 22-44 principal components capture about 95%95\% of the latent-space variance, while 44-77 capture about 99%99\%, depending on the initial-condition family; the same qualitative compression holds for the heat and wave equations. We also split the wavenumber axis into bands (``Fourier shells'') and measure how much each band contributes to every principal component. The resulting frequency profile is invariant under the change-of-basis freedom that the orthogonalization penalty leaves in the latent space, and is therefore reproducible across independent training runs. More broadly, this establishes the learned spectral profiles and principal components as robust observables of solution-manifold geometry.


Source: arXiv:2607.06348v1 - http://arxiv.org/abs/2607.06348v1 PDF: https://arxiv.org/pdf/2607.06348v1 Original Link: http://arxiv.org/abs/2607.06348v1

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Date:
Jul 8, 2026
Topic:
Data Science
Area:
Machine Learning
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