Riemann Tensor Neural Networks: Learning Conservative Systems with Physics-Constrained Networks

IRIS

Divergence-free symmetric tensors (DFSTs) are fundamental in continuum mechanics, encoding conservation laws such as mass and momentum conservation. We introduce Riemann Tensor Neural Networks (RTNNs), a novel neural architecture that inherently satisfies the DFST condition to machine precision, providing a strong inductive bias for enforcing these conservation laws. We prove that RTNNs can approximate any sufficiently smooth DFST with arbitrary precision and demonstrate their effectiveness as surrogates for conservative PDEs, achieving improved accuracy across benchmarks. This work is the first to use DFSTs as an inductive bias in neural PDE surrogates and to explicitly enforce the conservation of both mass and momentum within a physicsconstrained neural architecture.

Riemann Tensor Neural Networks: Learning Conservative Systems with Physics-Constrained Networks / Jnini, A.; Breschi, L.; Vella, F.. - 267:(2025), pp. 28304-28326. ( 42nd International Conference on Machine Learning, ICML 2025 Vancouver, Canada 2025).

Riemann Tensor Neural Networks: Learning Conservative Systems with Physics-Constrained Networks

Jnini A.^Primo;Breschi L.;Vella F.^Ultimo

2025-01-01

Abstract

Divergence-free symmetric tensors (DFSTs) are fundamental in continuum mechanics, encoding conservation laws such as mass and momentum conservation. We introduce Riemann Tensor Neural Networks (RTNNs), a novel neural architecture that inherently satisfies the DFST condition to machine precision, providing a strong inductive bias for enforcing these conservation laws. We prove that RTNNs can approximate any sufficiently smooth DFST with arbitrary precision and demonstrate their effectiveness as surrogates for conservative PDEs, achieving improved accuracy across benchmarks. This work is the first to use DFSTs as an inductive bias in neural PDE surrogates and to explicitly enforce the conservation of both mass and momentum within a physicsconstrained neural architecture.

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	Anno di pubblicazione (Date of publication)
	
				2025
			
	Titolo del volume (Proceedings title)
	
				Proceedings of Machine Learning Research
			
	Luogo di edizione (Place of publication)
	
				Vancouver Canada
			
	Casa editrice (Publisher)
	
				ML Research Press
			
	Settori scientifico-disciplinari (validi fino a 24/06/2024) - Reference SSD (valid until 24/06/2024)
	
				Settore ING-INF/05 - Sistemi di Elaborazione delle Informazioni
Settore ING-IND/06 - Fluidodinamica
			
	Settori scientifico-disciplinari (validi dal 09/05/2024) - Reference SSD (valid from 09/05/2024)
	
				Settore IINF-05/A - Sistemi di elaborazione delle informazioni
			
	Codice Scopus (Scopus Identifier)
	
				2-s2.0-105023822096
			
	Tutti gli autori
	
						Jnini, A.; Breschi, L.; Vella, F.
					
	Citazione
	
				Riemann Tensor Neural Networks: Learning Conservative Systems with Physics-Constrained Networks / Jnini, A.; Breschi, L.; Vella, F.. - 267:(2025), pp. 28304-28326. ( 42nd International Conference on Machine Learning, ICML 2025 Vancouver, Canada 2025).
			
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				04.1 Saggio in atti di convegno (Paper in Proceedings)

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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11572/474131

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