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Autori principali: Jo, Su Yeong, Park, Sanghyeon, Ko, Seungchan, Park, Jongcheon, Kim, Hosung, Lee, Sangseung, Jeon, Joongoo
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2505.12389
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author Jo, Su Yeong
Park, Sanghyeon
Ko, Seungchan
Park, Jongcheon
Kim, Hosung
Lee, Sangseung
Jeon, Joongoo
author_facet Jo, Su Yeong
Park, Sanghyeon
Ko, Seungchan
Park, Jongcheon
Kim, Hosung
Lee, Sangseung
Jeon, Joongoo
contents The Saint-Venant torsion theory is a classical theory for analyzing the torsional behavior of structural components, and it remains critically important in modern computational design workflows. Conventional numerical methods, including the finite element method (FEM), typically rely on mesh-based approaches to obtain approximate solutions. However, these methods often require complex and computationally intensive techniques to overcome the limitations of approximation, leading to significant increases in computational cost. The objective of this study is to develop a series of novel numerical methods based on physics-informed neural networks (PINN) for solving the Saint-Venant torsion equations. Utilizing the expressive power and the automatic differentiation capability of neural networks, the PINN can solve partial differential equations (PDEs) along with boundary conditions without the need for intricate computational techniques. First, a PINN solver was developed to compute the torsional constant for bars with arbitrary cross-sectional geometries. This was followed by the development of a solver capable of handling cases with sharp geometric transitions; variable-scaling PINN (VS-PINN). Finally, a parametric PINN was constructed to address the limitations of conventional single-instance PINN. The results from all three solvers showed good agreement with reference solutions, demonstrating their accuracy and robustness. Each solver can be selectively utilized depending on the specific requirements of torsional behavior analysis.
format Preprint
id arxiv_https___arxiv_org_abs_2505_12389
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Engineering application of physics-informed neural networks for Saint-Venant torsion
Jo, Su Yeong
Park, Sanghyeon
Ko, Seungchan
Park, Jongcheon
Kim, Hosung
Lee, Sangseung
Jeon, Joongoo
Machine Learning
The Saint-Venant torsion theory is a classical theory for analyzing the torsional behavior of structural components, and it remains critically important in modern computational design workflows. Conventional numerical methods, including the finite element method (FEM), typically rely on mesh-based approaches to obtain approximate solutions. However, these methods often require complex and computationally intensive techniques to overcome the limitations of approximation, leading to significant increases in computational cost. The objective of this study is to develop a series of novel numerical methods based on physics-informed neural networks (PINN) for solving the Saint-Venant torsion equations. Utilizing the expressive power and the automatic differentiation capability of neural networks, the PINN can solve partial differential equations (PDEs) along with boundary conditions without the need for intricate computational techniques. First, a PINN solver was developed to compute the torsional constant for bars with arbitrary cross-sectional geometries. This was followed by the development of a solver capable of handling cases with sharp geometric transitions; variable-scaling PINN (VS-PINN). Finally, a parametric PINN was constructed to address the limitations of conventional single-instance PINN. The results from all three solvers showed good agreement with reference solutions, demonstrating their accuracy and robustness. Each solver can be selectively utilized depending on the specific requirements of torsional behavior analysis.
title Engineering application of physics-informed neural networks for Saint-Venant torsion
topic Machine Learning
url https://arxiv.org/abs/2505.12389