Learning Physics-Consistent Particle Interactions

TL;DR

This paper introduces a physics-consistent graph network approach to accurately learn pairwise interactions in particle systems, outperforming existing methods and ensuring physical law adherence.

Contribution

The authors develop a deterministic operator within a graph network framework that precisely infers pairwise interactions from particle acceleration data, ensuring physical consistency.

Findings

Achieves superior accuracy in inferring pairwise interactions.

Ensures the inferred interactions are consistent with physical laws.

Scalable and transferable to various particle systems.

Abstract

Interacting particle systems play a key role in science and engineering. Access to the governing particle interaction law is fundamental for a complete understanding of such systems. However, the inherent system complexity keeps the particle interaction hidden in many cases. Machine learning methods have the potential to learn the behavior of interacting particle systems by combining experiments with data analysis methods. However, most existing algorithms focus on learning the kinetics at the particle level. Learning pairwise interaction, e.g., pairwise force or pairwise potential energy, remains an open challenge. Here, we propose an algorithm that adapts the Graph Networks framework, which contains an edge part to learn the pairwise interaction and a node part to model the dynamics at particle level. Different from existing approaches that use neural networks in both parts, we design a deterministic operator in the node part that allows to precisely infer the pairwise interactions that are consistent with underlying physical laws by only being trained to predict the particle acceleration. We test the proposed methodology on multiple datasets and demonstrate that it achieves superior performance in inferring correctly the pairwise interactions while also being consistent with the underlying physics on all the datasets. The proposed framework is scalable to larger systems and transferable to any type of particle interactions, contrary to the previously proposed purely data-driven solutions. The developed methodology can support a better understanding and discovery of the underlying particle interaction laws, and hence guide the design of materials with targeted properties.