A comparative investigation of a time-dependent mesh method and physics-informed neural networks to analyze the generalized Kolmogorov–Petrovsky–Piskunov equation

IF 1.7 4区工程技术 Q3 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS International Journal for Numerical Methods in Fluids Pub Date : 2024-01-18 DOI:10.1002/fld.5259

Saad Sultan, Zhengce Zhang

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Abstract

The Kolmogorov–Petrovsky–Piskunov (KPP) partial differential equation (PDE) is solved in this article using the moving mesh finite difference technique (MMFDM) in conjunction with physics-informed neural networks (PINNs). We construct a time-dependent mesh to obtain approximate solutions for the KPP problem. The temporal derivative is discretized using a backward Euler, while the spatial derivatives are discretized using a central implicit difference scheme. Depending on the error measure, several moving mesh partial differential equations (MMPDEs) are employed along the arc-length and curvature mesh density functions (MDF). The proposed strategy has been suggested to yield remarkably precise and consistent results. To find the approximate solution, we additionally employ physics-informed neural networks (PINNs) to compare the outcomes of the adaptive moving mesh approach. It has been observed that solutions obtained using the moving mesh method (MMM) are sufficiently accurate, and the absolute error is also much lower than the PINNs.

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分析广义科尔莫戈罗夫-彼得罗夫斯基-皮斯库诺夫方程的时变网格法和物理信息神经网络的比较研究

本文使用移动网格有限差分技术（MMFDM）结合物理信息神经网络（PINNs）求解了 Kolmogorov-Petrovsky-Piskunov (KPP) 偏微分方程（PDE）。我们构建了一个随时间变化的网格，以获得 KPP 问题的近似解。时间导数采用后向欧拉法离散，空间导数采用中心隐式差分方案离散。根据误差度量，沿着弧长和曲率网格密度函数（MDF）采用了多个移动网格偏微分方程（MMPDE）。研究表明，所提出的策略能产生非常精确和一致的结果。为了找到近似解，我们还采用了物理信息神经网络（PINN）来比较自适应移动网格方法的结果。结果表明，使用移动网格法（MMM）得到的解足够精确，绝对误差也比 PINNs 低得多。

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来源期刊

International Journal for Numerical Methods in Fluids 物理-计算机：跨学科应用

CiteScore

3.70

自引率

5.60%

发文量

111

审稿时长

8 months

期刊介绍： The International Journal for Numerical Methods in Fluids publishes refereed papers describing significant developments in computational methods that are applicable to scientific and engineering problems in fluid mechanics, fluid dynamics, micro and bio fluidics, and fluid-structure interaction. Numerical methods for solving ancillary equations, such as transport and advection and diffusion, are also relevant. The Editors encourage contributions in the areas of multi-physics, multi-disciplinary and multi-scale problems involving fluid subsystems, verification and validation, uncertainty quantification, and model reduction. Numerical examples that illustrate the described methods or their accuracy are in general expected. Discussions of papers already in print are also considered. However, papers dealing strictly with applications of existing methods or dealing with areas of research that are not deemed to be cutting edge by the Editors will not be considered for review. The journal publishes full-length papers, which should normally be less than 25 journal pages in length. Two-part papers are discouraged unless considered necessary by the Editors.