Neural PDE Solvers for Irregular Domains

IF 4.3 3区材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC ACS Applied Electronic Materials Pub Date : 2024-04-14 DOI:10.1016/j.cad.2024.103709

Biswajit Khara , Ethan Herron , Aditya Balu , Dhruv Gamdha , Chih-Hsuan Yang , Kumar Saurabh , Anushrut Jignasu , Zhanhong Jiang , Soumik Sarkar , Chinmay Hegde , Baskar Ganapathysubramanian , Adarsh Krishnamurthy

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Abstract

Neural network-based approaches for solving partial differential equations (PDEs) have recently received special attention. However, most neural PDE solvers only apply to rectilinear domains and do not systematically address the imposition of boundary conditions over irregular domain boundaries. In this paper, we present a neural framework to solve partial differential equations over domains with irregularly shaped (non-rectilinear) geometric boundaries. Given the shape of the domain as an input (represented as a binary mask), our network is able to predict the solution field, and can generalize to novel (unseen) irregular domains; the key technical ingredient to realizing this model is a physics-informed loss function that directly incorporates the interior-exterior information of the geometry. We also perform a careful error analysis which reveals theoretical insights into several sources of error incurred in the model-building process. Finally, we showcase various applications in 2D and 3D, along with favorable comparisons with ground truth solutions.

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不规则域的神经 PDE 求解器

基于神经网络的偏微分方程（PDE）求解方法最近受到了特别关注。然而，大多数神经偏微分方程求解器只适用于直线域，并没有系统地解决在不规则域边界上施加边界条件的问题。在本文中，我们提出了一个神经框架，用于求解具有不规则形状（非直线）几何边界的域上的偏微分方程。给定域的形状作为输入（以二进制掩码表示），我们的网络就能预测解场，并能泛化到新的（未见过的）不规则域；实现这一模型的关键技术要素是一个物理信息损失函数，它直接包含了几何体的内部-外部信息。我们还进行了细致的误差分析，从理论上揭示了模型建立过程中产生误差的几个来源。最后，我们展示了二维和三维中的各种应用，以及与地面实况解决方案的有利比较。

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