English

GINNs: Graph-Informed Neural Networks for Multiscale Physics

Computational Physics 2021-03-17 v1 Numerical Analysis Numerical Analysis Machine Learning

Abstract

We introduce the concept of a Graph-Informed Neural Network (GINN), a hybrid approach combining deep learning with probabilistic graphical models (PGMs) that acts as a surrogate for physics-based representations of multiscale and multiphysics systems. GINNs address the twin challenges of removing intrinsic computational bottlenecks in physics-based models and generating large data sets for estimating probability distributions of quantities of interest (QoIs) with a high degree of confidence. Both the selection of the complex physics learned by the NN and its supervised learning/prediction are informed by the PGM, which includes the formulation of structured priors for tunable control variables (CVs) to account for their mutual correlations and ensure physically sound CV and QoI distributions. GINNs accelerate the prediction of QoIs essential for simulation-based decision-making where generating sufficient sample data using physics-based models alone is often prohibitively expensive. Using a real-world application grounded in supercapacitor-based energy storage, we describe the construction of GINNs from a Bayesian network-embedded homogenized model for supercapacitor dynamics, and demonstrate their ability to produce kernel density estimates of relevant non-Gaussian, skewed QoIs with tight confidence intervals.

Keywords

Cite

@article{arxiv.2006.14807,
  title  = {GINNs: Graph-Informed Neural Networks for Multiscale Physics},
  author = {Eric J. Hall and Søren Taverniers and Markos A. Katsoulakis and Daniel M. Tartakovsky},
  journal= {arXiv preprint arXiv:2006.14807},
  year   = {2021}
}

Comments

20 pages, 8 figures

R2 v1 2026-06-23T16:38:34.832Z