Exactly conservative physics-informed neural networks and deep operator networks for dynamical systems.

Journal: Neural networks : the official journal of the International Neural Network Society

PMID: 39509811

Abstract

We introduce a method for training exactly conservative physics-informed neural networks and physics-informed deep operator networks for dynamical systems, that is, for ordinary differential equations. The method employs a projection-based technique that maps a candidate solution learned by the neural network solver for any given dynamical system possessing at least one first integral onto an invariant manifold. We illustrate that exactly conservative physics-informed neural network solvers and physics-informed deep operator networks for dynamical systems vastly outperform their non-conservative counterparts for several real-world problems from the mathematical sciences.

Authors

Elsa Cardoso-Bihlo

Department of Mathematics and Statistics Memorial University of Newfoundland St. John's, NL, A1C 5S7, Canada. Electronic address: ecardosobihl@mun.ca.
Alex Bihlo

Department of Mathematics and Statistics, Memorial University of Newfoundland, St. John's (NL), A1C 5S7, Canada. Electronic address: abihlo@mun.ca.

Keywords

Algorithms Deep Learning Neural Networks, Computer Physics

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View on PubMed Access via DOI PubMed (39509811)

Exactly conservative physics-informed neural networks and deep operator networks for dynamical systems.

Abstract

Authors

Keywords

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