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Main Authors: Ji, Ethan, Chen, Yuanzhou, Ramteke, Arush, Sun, Fang, Yu, Tianrun, Parera, Jai, Wang, Wei, Sun, Yizhou
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2511.22938
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author Ji, Ethan
Chen, Yuanzhou
Ramteke, Arush
Sun, Fang
Yu, Tianrun
Parera, Jai
Wang, Wei
Sun, Yizhou
author_facet Ji, Ethan
Chen, Yuanzhou
Ramteke, Arush
Sun, Fang
Yu, Tianrun
Parera, Jai
Wang, Wei
Sun, Yizhou
contents Partial differential equations (PDEs) are central to dynamical systems modeling, particularly in hydrodynamics, where traditional solvers often struggle with nonlinearity and computational cost. Lagrangian neural surrogates such as GNS and SEGNN have emerged as strong alternatives by learning from particle-based simulations. However, these models typically operate with limited receptive fields, making them inaccurate for capturing the inherently global interactions in fluid flows. Motivated by this observation, we introduce Convolutional Residual Global Interactions (CORGI), a hybrid architecture that augments any GNN-based solver with a lightweight Eulerian component for global context aggregation. By projecting particle features onto a grid, applying convolutional updates, and mapping them back to the particle domain, CORGI captures long-range dependencies without significant overhead. When applied to a GNS backbone, CORGI achieves a 57% improvement in rollout accuracy with only 13% more inference time and 31% more training time. Compared to SEGNN, CORGI improves accuracy by 49% while reducing inference time by 48% and training time by 30%. Even under identical runtime constraints, CORGI outperforms GNS by 47% on average, highlighting its versatility and performance on varied compute budgets.
format Preprint
id arxiv_https___arxiv_org_abs_2511_22938
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle CORGI: GNNs with Convolutional Residual Global Interactions for Lagrangian Simulation
Ji, Ethan
Chen, Yuanzhou
Ramteke, Arush
Sun, Fang
Yu, Tianrun
Parera, Jai
Wang, Wei
Sun, Yizhou
Machine Learning
Partial differential equations (PDEs) are central to dynamical systems modeling, particularly in hydrodynamics, where traditional solvers often struggle with nonlinearity and computational cost. Lagrangian neural surrogates such as GNS and SEGNN have emerged as strong alternatives by learning from particle-based simulations. However, these models typically operate with limited receptive fields, making them inaccurate for capturing the inherently global interactions in fluid flows. Motivated by this observation, we introduce Convolutional Residual Global Interactions (CORGI), a hybrid architecture that augments any GNN-based solver with a lightweight Eulerian component for global context aggregation. By projecting particle features onto a grid, applying convolutional updates, and mapping them back to the particle domain, CORGI captures long-range dependencies without significant overhead. When applied to a GNS backbone, CORGI achieves a 57% improvement in rollout accuracy with only 13% more inference time and 31% more training time. Compared to SEGNN, CORGI improves accuracy by 49% while reducing inference time by 48% and training time by 30%. Even under identical runtime constraints, CORGI outperforms GNS by 47% on average, highlighting its versatility and performance on varied compute budgets.
title CORGI: GNNs with Convolutional Residual Global Interactions for Lagrangian Simulation
topic Machine Learning
url https://arxiv.org/abs/2511.22938