采用信任区域顺序二次编程的物理信息神经网络

Xiaoran Cheng, Sen Na
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摘要

物理信息神经网络(PINNs)是科学机器学习(SciML)的一大进步,它将物理领域的知识整合到经验损失函数中作为软约束,并应用现有的机器学习方法来训练模型。然而,最近的研究指出,PINNs 可能无法学习相对复杂的偏微分方程(PDE)。本文引入了一种新颖的硬约束深度学习方法--信任区域连续二次编程(trust-regionSequential Quadratic Programming,trSQP-PINN),从而解决了PINN的失败模式。与在 PINNs 中直接训练受惩罚的软约束损失不同,我们的方法对硬约束损失进行线性二次逼近,同时利用软约束损失自适应地调整信任区域半径。我们只信任我们的模型近似值,并在信任区域内进行更新,这样的更新方式可以克服 PINN 的条件不良问题。我们还通过对二阶信息进行准牛顿更新,解决了二阶 SQP 方法的计算瓶颈问题,更重要的是,我们引入了一个简单的预训练步骤,进一步提高了方法的训练效率。我们通过大量实验证明了 trSQP-PINN 的有效性。与现有的硬约束 PINN 方法(如penalty 方法和增强拉格朗日方法)相比,trSQP-PINN 显著提高了所学 PDE 解的准确性,误差降低了 1-3 个数量级。此外,我们的预训练步骤对其他硬约束方法也普遍有效,实验表明我们的方法对特定问题参数和算法调整参数都具有稳健性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Physics-Informed Neural Networks with Trust-Region Sequential Quadratic Programming
Physics-Informed Neural Networks (PINNs) represent a significant advancement in Scientific Machine Learning (SciML), which integrate physical domain knowledge into an empirical loss function as soft constraints and apply existing machine learning methods to train the model. However, recent research has noted that PINNs may fail to learn relatively complex Partial Differential Equations (PDEs). This paper addresses the failure modes of PINNs by introducing a novel, hard-constrained deep learning method -- trust-region Sequential Quadratic Programming (trSQP-PINN). In contrast to directly training the penalized soft-constrained loss as in PINNs, our method performs a linear-quadratic approximation of the hard-constrained loss, while leveraging the soft-constrained loss to adaptively adjust the trust-region radius. We only trust our model approximations and make updates within the trust region, and such an updating manner can overcome the ill-conditioning issue of PINNs. We also address the computational bottleneck of second-order SQP methods by employing quasi-Newton updates for second-order information, and importantly, we introduce a simple pretraining step to further enhance training efficiency of our method. We demonstrate the effectiveness of trSQP-PINN through extensive experiments. Compared to existing hard-constrained methods for PINNs, such as penalty methods and augmented Lagrangian methods, trSQP-PINN significantly improves the accuracy of the learned PDE solutions, achieving up to 1-3 orders of magnitude lower errors. Additionally, our pretraining step is generally effective for other hard-constrained methods, and experiments have shown the robustness of our method against both problem-specific parameters and algorithm tuning parameters.
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