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arxiv: 2111.11798 · v2 · pith:PKDBVGRX · submitted 2021-11-23 · cs.LG

Composing Partial Differential Equations with Physics-Aware Neural Networks

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classification cs.LG
keywords finnlearningneuralphysics-awareabilitiescompositionaldifferentialdiffusion-sorption
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We introduce a compositional physics-aware FInite volume Neural Network (FINN) for learning spatiotemporal advection-diffusion processes. FINN implements a new way of combining the learning abilities of artificial neural networks with physical and structural knowledge from numerical simulation by modeling the constituents of partial differential equations (PDEs) in a compositional manner. Results on both one- and two-dimensional PDEs (Burgers', diffusion-sorption, diffusion-reaction, Allen--Cahn) demonstrate FINN's superior modeling accuracy and excellent out-of-distribution generalization ability beyond initial and boundary conditions. With only one tenth of the number of parameters on average, FINN outperforms pure machine learning and other state-of-the-art physics-aware models in all cases -- often even by multiple orders of magnitude. Moreover, FINN outperforms a calibrated physical model when approximating sparse real-world data in a diffusion-sorption scenario, confirming its generalization abilities and showing explanatory potential by revealing the unknown retardation factor of the observed process.

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  1. Mass-Conserving Physics-Informed Neural Networks For The One-Dimensional Advection-Diffusion Equation

    physics.comp-ph 2026-07 conditional novelty 3.0

    Adding a soft mass-conservation penalty to PINNs for the 1D advection-diffusion equation reduces long-term relative L2 error by 9–67× and mass error by 15–215× compared to vanilla PINNs across Peclet numbers 0.01–20.