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Autori principali: Xiao, Jing, Chen, Xinhai, Wang, Qingling, Liu, Jie
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2501.11937
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author Xiao, Jing
Chen, Xinhai
Wang, Qingling
Liu, Jie
author_facet Xiao, Jing
Chen, Xinhai
Wang, Qingling
Liu, Jie
contents Mesh generation plays a crucial role in scientific computing. Traditional mesh generation methods, such as TFI and PDE-based methods, often struggle to achieve a balance between efficiency and mesh quality. To address this challenge, physics-informed intelligent learning methods have recently emerged, significantly improving generation efficiency while maintaining high mesh quality. However, physics-informed methods fail to generalize when applied to previously unseen geometries, as even small changes in the boundary shape necessitate burdensome retraining to adapt to new geometric variations. In this paper, we introduce MeshONet, the first generalizable intelligent learning method for structured mesh generation. The method transforms the mesh generation task into an operator learning problem with multiple input and solution functions. To effectively overcome the multivariable mapping restriction of operator learning methods, we propose a dual-branch, shared-trunk architecture to approximate the mapping between function spaces based on input-output pairs. Experimental results show that MeshONet achieves a speedup of up to four orders of magnitude in generation efficiency over traditional methods. It also enables generalization to different geometries without retraining, greatly enhancing the practicality of intelligent methods.
format Preprint
id arxiv_https___arxiv_org_abs_2501_11937
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle MeshONet: A Generalizable and Efficient Operator Learning Method for Structured Mesh Generation
Xiao, Jing
Chen, Xinhai
Wang, Qingling
Liu, Jie
Machine Learning
Artificial Intelligence
Mesh generation plays a crucial role in scientific computing. Traditional mesh generation methods, such as TFI and PDE-based methods, often struggle to achieve a balance between efficiency and mesh quality. To address this challenge, physics-informed intelligent learning methods have recently emerged, significantly improving generation efficiency while maintaining high mesh quality. However, physics-informed methods fail to generalize when applied to previously unseen geometries, as even small changes in the boundary shape necessitate burdensome retraining to adapt to new geometric variations. In this paper, we introduce MeshONet, the first generalizable intelligent learning method for structured mesh generation. The method transforms the mesh generation task into an operator learning problem with multiple input and solution functions. To effectively overcome the multivariable mapping restriction of operator learning methods, we propose a dual-branch, shared-trunk architecture to approximate the mapping between function spaces based on input-output pairs. Experimental results show that MeshONet achieves a speedup of up to four orders of magnitude in generation efficiency over traditional methods. It also enables generalization to different geometries without retraining, greatly enhancing the practicality of intelligent methods.
title MeshONet: A Generalizable and Efficient Operator Learning Method for Structured Mesh Generation
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2501.11937