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Main Authors: Propp, Adrienne M., Perego, Mauro, Cyr, Eric C., Gruber, Anthony, Howard, Amanda A., Heinlein, Alexander, Stinis, Panos, Tartakovsky, Daniel M.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2512.01888
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author Propp, Adrienne M.
Perego, Mauro
Cyr, Eric C.
Gruber, Anthony
Howard, Amanda A.
Heinlein, Alexander
Stinis, Panos
Tartakovsky, Daniel M.
author_facet Propp, Adrienne M.
Perego, Mauro
Cyr, Eric C.
Gruber, Anthony
Howard, Amanda A.
Heinlein, Alexander
Stinis, Panos
Tartakovsky, Daniel M.
contents Accurate yet efficient surrogate models are essential for large-scale simulations of partial differential equations (PDEs), particularly for uncertainty quantification (UQ) tasks that demand hundreds or thousands of evaluations. We develop a physics-inspired graph neural network (GNN) surrogate that operates directly on unstructured meshes and leverages the flexibility of graph attention. To improve both training efficiency and generalization properties of the model, we introduce a domain decomposition (DD) strategy that partitions the mesh into subdomains, trains local GNN surrogates in parallel, and aggregates their predictions. We then employ transfer learning to fine-tune models across subdomains, accelerating training and improving accuracy in data-limited settings. Applied to ice sheet simulations, our approach accurately predicts full-field velocities on high-resolution meshes, substantially reduces training time relative to training a single global surrogate model, and provides a ripe foundation for UQ objectives. Our results demonstrate that graph-based DD, combined with transfer learning, provides a scalable and reliable pathway for training GNN surrogates on massive PDE-governed systems, with broad potential for application beyond ice sheet dynamics.
format Preprint
id arxiv_https___arxiv_org_abs_2512_01888
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Domain-Decomposed Graph Neural Network Surrogate Modeling for Ice Sheets
Propp, Adrienne M.
Perego, Mauro
Cyr, Eric C.
Gruber, Anthony
Howard, Amanda A.
Heinlein, Alexander
Stinis, Panos
Tartakovsky, Daniel M.
Machine Learning
Numerical Analysis
Mathematical Physics
Computational Physics
Accurate yet efficient surrogate models are essential for large-scale simulations of partial differential equations (PDEs), particularly for uncertainty quantification (UQ) tasks that demand hundreds or thousands of evaluations. We develop a physics-inspired graph neural network (GNN) surrogate that operates directly on unstructured meshes and leverages the flexibility of graph attention. To improve both training efficiency and generalization properties of the model, we introduce a domain decomposition (DD) strategy that partitions the mesh into subdomains, trains local GNN surrogates in parallel, and aggregates their predictions. We then employ transfer learning to fine-tune models across subdomains, accelerating training and improving accuracy in data-limited settings. Applied to ice sheet simulations, our approach accurately predicts full-field velocities on high-resolution meshes, substantially reduces training time relative to training a single global surrogate model, and provides a ripe foundation for UQ objectives. Our results demonstrate that graph-based DD, combined with transfer learning, provides a scalable and reliable pathway for training GNN surrogates on massive PDE-governed systems, with broad potential for application beyond ice sheet dynamics.
title Domain-Decomposed Graph Neural Network Surrogate Modeling for Ice Sheets
topic Machine Learning
Numerical Analysis
Mathematical Physics
Computational Physics
url https://arxiv.org/abs/2512.01888