Physics-consistent machine learning: output projection onto physical manifolds

TL;DR

This paper introduces a projection-based machine learning method that enforces physical law compliance by projecting outputs onto physical manifolds, enhancing reliability and interpretability of models in physics-related applications.

Contribution

The authors propose a novel projection technique that guarantees physical law adherence in machine learning outputs, improving over existing penalization and invariant-based methods.

Findings

Reduces errors in physical law compliance

Improves predictive accuracy of physical quantities

Outperforms existing methods with limited data

Abstract

Data-driven machine learning models often require extensive datasets, which can be costly or inaccessible, and their predictions may fail to comply with established physical laws. Current approaches for incorporating physical priors mitigate these issues by penalizing deviations from known physical laws, as in physics-informed neural networks, or by designing architectures that automatically satisfy specific invariants. However, penalization approaches do not guarantee compliance with physical constraints for unseen inputs, and invariant-based methods lack flexibility and generality. We propose a novel physics-consistent machine learning method that directly enforces compliance with physical principles by projecting model outputs onto the manifold defined by these laws. This procedure ensures that predictions inherently adhere to the chosen physical constraints, improving reliability and interpretability. Our method is demonstrated on two systems: a spring-mass system and a low-temperature reactive plasma. Compared to purely data-driven models, our approach significantly reduces errors in physical law compliance, enhances predictive accuracy of physical quantities, and outperforms alternatives when working with simpler models or limited datasets. The proposed projection-based technique is versatile and can function independently or in conjunction with existing physics-informed neural networks, offering a powerful, general, and scalable solution for developing fast and reliable surrogate models of complex physical systems, particularly in resource-constrained scenarios.