用于识别高维哈密顿系统和节点分类的辛图神经网络

IF 6 1区计算机科学 Q1 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

Neural Networks Pub Date : 2025-03-22 DOI:10.1016/j.neunet.2025.107397

Alan John Varghese , Zhen Zhang , George Em Karniadakis

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引用次数: 0

摘要

现有的学习哈密顿系统的神经网络模型，如SympNets，虽然在低维上是准确的，但在高维多体系统上却很难学习正确的动力学。在此，我们引入了辛图神经网络（sympgnn），它可以有效地处理高维哈密顿系统中的系统识别和节点分类。sympgnn结合了辛映射和置换等方差，这是图神经网络的一个性质。具体来说，我们提出了两种不同的sympgnn变体：(i) G-SympGNN和（ii） LA-SympGNN，它们由不同的动能和势能参数化产生。我们在两个物理例子上展示了SympGNN的能力：一个40粒子耦合谐振子，以及一个二维Lennard-Jones势中的2000粒子分子动力学模拟。此外，我们展示了SympGNN在节点分类任务中的性能，实现了与最先进的精度相当的精度。我们还通过经验证明，SympGNN可以克服图神经网络领域的两个关键挑战——过平滑和异质性问题。

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SympGNNs: Symplectic Graph Neural Networks for identifying high-dimensional Hamiltonian systems and node classification

Existing neural network models to learn Hamiltonian systems, such as SympNets, although accurate in low-dimensions, struggle to learn the correct dynamics for high-dimensional many-body systems. Herein, we introduce Symplectic Graph Neural Networks (SympGNNs) that can effectively handle system identification in high-dimensional Hamiltonian systems, as well as node classification. SympGNNs combine symplectic maps with permutation equivariance, a property of graph neural networks. Specifically, we propose two variants of SympGNNs: (i) G-SympGNN and (ii) LA-SympGNN, arising from different parameterizations of the kinetic and potential energy. We demonstrate the capabilities of SympGNN on two physical examples: a 40-particle coupled Harmonic oscillator, and a 2000-particle molecular dynamics simulation in a two-dimensional Lennard-Jones potential. Furthermore, we demonstrate the performance of SympGNN in the node classification task, achieving accuracy comparable to the state-of-the-art. We also empirically show that SympGNN can overcome the oversmoothing and heterophily problems, two key challenges in the field of graph neural networks.

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来源期刊

Neural Networks 工程技术-计算机：人工智能

CiteScore

13.90

自引率

7.70%

发文量

425

审稿时长

67 days

期刊介绍： Neural Networks is a platform that aims to foster an international community of scholars and practitioners interested in neural networks, deep learning, and other approaches to artificial intelligence and machine learning. Our journal invites submissions covering various aspects of neural networks research, from computational neuroscience and cognitive modeling to mathematical analyses and engineering applications. By providing a forum for interdisciplinary discussions between biology and technology, we aim to encourage the development of biologically-inspired artificial intelligence.