针对非线性两点边值问题的 GPINN 与神经切线核技术

IF 2.6 4区 计算机科学 Q3 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE
Navnit Jha, Ekansh Mallik
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引用次数: 0

摘要

作为微分方程求解器的神经网络是一种很好的数值技术选择,因为其求解速度快,而且能解决传统数值求解器面临的一些经典问题。在本文中,我们将探讨著名的梯度下降优化技术,该技术通过更新参数来训练网络,从而使损失函数最小化。我们将研究梯度下降的理论部分,以了解为什么该网络对损失函数的某些项效果很好,而对其他项效果不佳。这里考虑的损失函数的构建方式包含了微分方程以及微分方程的导数。全连接前馈网络的设计方式是,无需在边界点进行训练,它就能自动满足边界条件。本研究对梯度增强物理信息神经网络的神经正切核进行了研究,并演示了如何利用它生成核函数的闭式表达式。我们还提供了数值实验,证明了新方法对若干两点边界值问题的有效性。我们的结果表明,基于神经正切核的方法可以显著提高梯度增强物理信息神经网络的计算精度,同时降低训练这些模型的计算成本。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

GPINN with Neural Tangent Kernel Technique for Nonlinear Two Point Boundary Value Problems

GPINN with Neural Tangent Kernel Technique for Nonlinear Two Point Boundary Value Problems

Neural networks as differential equation solvers are a good choice of numerical technique because of their fast solutions and their nature in tackling some classical problems which traditional numerical solvers faced. In this article, we look at the famous gradient descent optimization technique, which trains the network by updating parameters which minimizes the loss function. We look at the theoretical part of gradient descent to understand why the network works great for some terms of the loss function and not so much for other terms. The loss function considered here is built in such a way that it incorporates the differential equation as well as the derivative of the differential equation. The fully connected feed-forward network is designed in such a way that, without training at boundary points, it automatically satisfies the boundary conditions. The neural tangent kernel for gradient enhanced physics informed neural networks is examined in this work, and we demonstrate how it may be used to generate a closed-form expression for the kernel function. We also provide numerical experiments demonstrating the effectiveness of the new approach for several two point boundary value problems. Our results suggest that the neural tangent kernel based approach can significantly improve the computational accuracy of the gradient enhanced physics informed neural network while reducing the computational cost of training these models.

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来源期刊
Neural Processing Letters
Neural Processing Letters 工程技术-计算机:人工智能
CiteScore
4.90
自引率
12.90%
发文量
392
审稿时长
2.8 months
期刊介绍: Neural Processing Letters is an international journal publishing research results and innovative ideas on all aspects of artificial neural networks. Coverage includes theoretical developments, biological models, new formal modes, learning, applications, software and hardware developments, and prospective researches. The journal promotes fast exchange of information in the community of neural network researchers and users. The resurgence of interest in the field of artificial neural networks since the beginning of the 1980s is coupled to tremendous research activity in specialized or multidisciplinary groups. Research, however, is not possible without good communication between people and the exchange of information, especially in a field covering such different areas; fast communication is also a key aspect, and this is the reason for Neural Processing Letters
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