Design your own universe: a physics-informed agnostic method for enhancing graph neural networks

IF 3.1 3区计算机科学 Q2 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

International Journal of Machine Learning and Cybernetics Pub Date : 2024-09-02 DOI:10.1007/s13042-024-02326-w

Dai Shi, Andi Han, Lequan Lin, Yi Guo, Zhiyong Wang, Junbin Gao

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Abstract

Physics-informed Graph Neural Networks have achieved remarkable performance in learning through graph-structured data by mitigating common GNN challenges such as over-smoothing, over-squashing, and heterophily adaption. Despite these advancements, the development of a simple yet effective paradigm that appropriately integrates previous methods for handling all these challenges is still underway. In this paper, we draw an analogy between the propagation of GNNs and particle systems in physics, proposing a model-agnostic enhancement framework. This framework enriches the graph structure by introducing additional nodes and rewiring connections with both positive and negative weights, guided by node labeling information. We theoretically verify that GNNs enhanced through our approach can effectively circumvent the over-smoothing issue and exhibit robustness against over-squashing. Moreover, we conduct a spectral analysis on the rewired graph to demonstrate that the corresponding GNNs can fit both homophilic and heterophilic graphs. Empirical validations on benchmarks for homophilic, heterophilic graphs, and long-term graph datasets show that GNNs enhanced by our method significantly outperform their original counterparts.

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设计自己的宇宙：增强图神经网络的物理信息不可知方法

物理信息图神经网络（Graph Neural Networks）在通过图结构数据进行学习方面取得了令人瞩目的成绩，缓解了常见的图神经网络难题，如过度平滑、过度扭曲和异相适应。尽管取得了这些进步，但目前仍在开发一种简单而有效的范式，将以前处理所有这些挑战的方法进行适当整合。在本文中，我们将 GNN 的传播与物理学中的粒子系统进行类比，提出了一种与模型无关的增强框架。该框架通过引入额外的节点，并在节点标签信息的引导下重新连接正负权重，从而丰富图结构。我们从理论上验证了通过我们的方法增强的 GNN 可以有效规避过度平滑问题，并对过度挤压表现出鲁棒性。此外，我们还对重新布线的图进行了频谱分析，证明相应的 GNN 既适合同亲图，也适合异亲图。在同嗜图、异嗜图和长期图数据集的基准上进行的经验验证表明，用我们的方法增强的 GNN 明显优于其原始对应物。

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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来源期刊

International Journal of Machine Learning and Cybernetics COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE-

CiteScore

7.90

自引率

10.70%

发文量

225

期刊介绍： Cybernetics is concerned with describing complex interactions and interrelationships between systems which are omnipresent in our daily life. Machine Learning discovers fundamental functional relationships between variables and ensembles of variables in systems. The merging of the disciplines of Machine Learning and Cybernetics is aimed at the discovery of various forms of interaction between systems through diverse mechanisms of learning from data. The International Journal of Machine Learning and Cybernetics (IJMLC) focuses on the key research problems emerging at the junction of machine learning and cybernetics and serves as a broad forum for rapid dissemination of the latest advancements in the area. The emphasis of IJMLC is on the hybrid development of machine learning and cybernetics schemes inspired by different contributing disciplines such as engineering, mathematics, cognitive sciences, and applications. New ideas, design alternatives, implementations and case studies pertaining to all the aspects of machine learning and cybernetics fall within the scope of the IJMLC. Key research areas to be covered by the journal include: Machine Learning for modeling interactions between systems Pattern Recognition technology to support discovery of system-environment interaction Control of system-environment interactions Biochemical interaction in biological and biologically-inspired systems Learning for improvement of communication schemes between systems