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Bibliographic Details
Main Authors: Dahlinger, Philipp, Gyenes, Balázs, Freymuth, Niklas, Geminiani, Luca, Würth, Tobias, Mitsch, Johannes, Klein, Nadja, Kärger, Luise, Neumann, Gerhard
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.20978
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author Dahlinger, Philipp
Gyenes, Balázs
Freymuth, Niklas
Geminiani, Luca
Würth, Tobias
Mitsch, Johannes
Klein, Nadja
Kärger, Luise
Neumann, Gerhard
author_facet Dahlinger, Philipp
Gyenes, Balázs
Freymuth, Niklas
Geminiani, Luca
Würth, Tobias
Mitsch, Johannes
Klein, Nadja
Kärger, Luise
Neumann, Gerhard
contents Graph Network Simulators (GNSs) have emerged as powerful surrogates for complex physics-based simulation, offering inherent differentiability and orders-of-magnitude speedups over traditional solvers. However, GNSs typically assume access to the underlying material parameters, such as stiffness or viscosity, severely limiting their utility in realistic experimental settings. While recent meta-learning approaches address the parameter dependency by inferring properties from mesh trajectories, reconstructing a mesh from an observed scene is challenging. In this work, we introduce Point Cloud Encoding for Accurate Context Handling (PEACH), a novel framework that applies in-context learning on point clouds to adapt a learned simulator to unseen physical properties during inference. Our approach relies on a novel spatio-temporal point cloud sequence encoder, as well as two forms of auxiliary supervision to help improve simulation fidelity. We demonstrate that PEACH is capable of accurate zero-shot sim-to-real transfer on a challenging, dynamic scene. Experiments on simulation scenes show that PEACH even outperforms mesh-based baselines on prediction accuracy, while being much more practical for real-world deployment.
format Preprint
id arxiv_https___arxiv_org_abs_2605_20978
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Point Cloud Sequence Encoding for Material-conditioned Graph Network Simulators
Dahlinger, Philipp
Gyenes, Balázs
Freymuth, Niklas
Geminiani, Luca
Würth, Tobias
Mitsch, Johannes
Klein, Nadja
Kärger, Luise
Neumann, Gerhard
Machine Learning
Graph Network Simulators (GNSs) have emerged as powerful surrogates for complex physics-based simulation, offering inherent differentiability and orders-of-magnitude speedups over traditional solvers. However, GNSs typically assume access to the underlying material parameters, such as stiffness or viscosity, severely limiting their utility in realistic experimental settings. While recent meta-learning approaches address the parameter dependency by inferring properties from mesh trajectories, reconstructing a mesh from an observed scene is challenging. In this work, we introduce Point Cloud Encoding for Accurate Context Handling (PEACH), a novel framework that applies in-context learning on point clouds to adapt a learned simulator to unseen physical properties during inference. Our approach relies on a novel spatio-temporal point cloud sequence encoder, as well as two forms of auxiliary supervision to help improve simulation fidelity. We demonstrate that PEACH is capable of accurate zero-shot sim-to-real transfer on a challenging, dynamic scene. Experiments on simulation scenes show that PEACH even outperforms mesh-based baselines on prediction accuracy, while being much more practical for real-world deployment.
title Point Cloud Sequence Encoding for Material-conditioned Graph Network Simulators
topic Machine Learning
url https://arxiv.org/abs/2605.20978