探索解决边界层问题的物理信息神经网络

Journal of Fundamental Mathematics and Applications (JFMA) Pub Date : 2023-11-27 DOI:10.14710/jfma.v6i2.20084

Muchamad Harry Yudha Pratama, Agus Yodi Gunawan

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摘要

在本文中，我们探索了一种被称为物理信息神经网络（PINN）的尖端技术来解决边界层问题。我们在此研究了二阶 ODE 边界层的四种不同情况：具有常数系数的线性 ODE、具有同质边界条件的非线性 ODE、具有非常数系数的 ODE 和具有多个边界层的 ODE。我们采用 PINN 技术来处理这些问题，结果表明，求解结果的准确性取决于我们在设计 PINN 架构时如何选择最可靠、最稳健的激活函数。此外，通过我们的探索，我们旨在加深对 PINN 技术如何更好地处理边界层问题的理解。特别是在 PINN 中使用 SiLU（Sigmoid-Weighted Linear Unit，西格玛加权线性单元）激活函数，在处理边界层问题时效果尤为显著。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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EXPLORING PHYSICS-INFORMED NEURAL NETWORKS FOR SOLVING BOUNDARY LAYER PROBLEMS

In this paper, we explore a cutting-edge technique called as Physics- Informed Neural Networks (PINN) to tackle boundary layer problems. We here examine four different cases of boundary layers of second-order ODE: a linear ODEwith constant coefficients, a nonlinear ODE with homogeneous boundary conditions, an ODE with non-constant coefficients, and an ODE featuring multiple boundary layers. We adapt the line of PINN technique for handling those problems, and our results show that the accuracy of the resulted solutions depends on how we choose the most reliable and robust activation functions when designing the architecture of the PINN. Beside that, through our explorations, we aim to improve our understanding on how the PINN technique works better for boundary layer problems. Especially, the use of the SiLU (Sigmoid-Weighted Linear Unit) activation function in PINN has proven to be particularly remarkable in handling our boundary layer problems.

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Journal of Fundamental Mathematics and Applications (JFMA)

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