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Auteurs principaux: Liu, Qibang, Zhong, Weiheng, Meidani, Hadi, Abueidda, Diab, Koric, Seid, Geubelle, Philippe
Format: Preprint
Publié: 2025
Sujets:
Accès en ligne:https://arxiv.org/abs/2504.19452
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author Liu, Qibang
Zhong, Weiheng
Meidani, Hadi
Abueidda, Diab
Koric, Seid
Geubelle, Philippe
author_facet Liu, Qibang
Zhong, Weiheng
Meidani, Hadi
Abueidda, Diab
Koric, Seid
Geubelle, Philippe
contents Machine-learning-based surrogate models offer significant computational efficiency and faster simulations compared to traditional numerical methods, especially for problems requiring repeated evaluations of partial differential equations. This work introduces the Geometry-Informed Neural Operator Transformer (GINOT), which integrates the transformer architecture with the neural operator framework to enable forward predictions on arbitrary geometries. GINOT employs a sampling and grouping strategy together with an attention mechanism to encode surface point clouds that are unordered, exhibit non-uniform point densities, and contain varying numbers of points for different geometries. The geometry information is seamlessly integrated with query points in the solution decoder through the attention mechanism. The performance of GINOT is validated on multiple challenging datasets, showcasing its high accuracy and strong generalization capabilities for complex and arbitrary 2D and 3D geometries.
format Preprint
id arxiv_https___arxiv_org_abs_2504_19452
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Geometry-Informed Neural Operator Transformer
Liu, Qibang
Zhong, Weiheng
Meidani, Hadi
Abueidda, Diab
Koric, Seid
Geubelle, Philippe
Machine Learning
Computational Physics
Machine-learning-based surrogate models offer significant computational efficiency and faster simulations compared to traditional numerical methods, especially for problems requiring repeated evaluations of partial differential equations. This work introduces the Geometry-Informed Neural Operator Transformer (GINOT), which integrates the transformer architecture with the neural operator framework to enable forward predictions on arbitrary geometries. GINOT employs a sampling and grouping strategy together with an attention mechanism to encode surface point clouds that are unordered, exhibit non-uniform point densities, and contain varying numbers of points for different geometries. The geometry information is seamlessly integrated with query points in the solution decoder through the attention mechanism. The performance of GINOT is validated on multiple challenging datasets, showcasing its high accuracy and strong generalization capabilities for complex and arbitrary 2D and 3D geometries.
title Geometry-Informed Neural Operator Transformer
topic Machine Learning
Computational Physics
url https://arxiv.org/abs/2504.19452