Discrete-time Physics-Informed Neural Networks for Two-Phase Flow Interface Capturing
Authors: 
Sen Zhang, Yanxu Zhong, Xi Yang, Wei Wang, Zhuo Zhang, Xiao-Wei Guo, Canqun YangAuthors Info & Claims
Sen Zhang, Yanxu Zhong, Xi Yang, Wei Wang, Zhuo Zhang, Xiao-Wei Guo, Canqun YangAuthors Info & ClaimsPages 24 - 30
Abstract
In two-phase flow, accurately capturing sharp interfaces is essential. Physics-Informed Neural Networks (PINNs) provide a new way to capture interfaces. This paper introduces a new framework that uses Discrete-time Physics-Informed Neural Networks (DtPINNs) to solve the volume of fluid (VOF) advection equation, offering a new approach to interface capturing in two-phase flows. With this framework, we propose an adaptive collocation-point refinement algorithm, which improves the precision of capturing sharp interfaces, reducing errors and diffusion. Experiments, including cases with translation and deformation, show that the DtPINNs method maintains sharp interfaces, outperforming traditional numerical methods. In a 2D single-vortex deformation case, DtPINNs achieved a relative \({L}_2\) error of 0.0760, much lower than the 5th-order WENO-JS scheme (0.5534) and the 1st-order Upwind scheme (0.8879). This shows that DtPINNs are better at capturing complex interface shapes while keeping accuracy and minimizing numerical diffusion.
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November 2024
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Published: 20 January 2025
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- National Key Research and Development Program of China
- scientific research program funded by Haihe Lab of ITAI
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CSAE 2024
CSAE 2024: The 8th International Conference on Computer Science and Application Engineering
November 28 - 29, 2024
Jiangsu, Shanghai, China
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