GCRL:用于网络连接鲁棒性学习的图神经网络框架

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Yu Zhang, Haowei Chen, Qiyu Chen, Jie Ding, Xiang Li
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引用次数: 0

摘要

复杂网络的复原力和适应性对于确保其功能不受干扰至关重要。特别是,在各种攻击情况下保持网络连接是这种复原力的一个关键方面。网络连通性是指网络内节点相互连接并能交换信息或资源的程度。其鲁棒性反映了网络在各种攻击下保持连接的能力。这种能力具有深远的物理意义,可确保现实世界系统的稳定性和可靠性。目前,连接鲁棒性评估主要依赖于非常耗时的攻击模拟。本文介绍了一种用于网络连接鲁棒性学习(GCRL)的图神经网络框架,以推进网络连接鲁棒性的研究。GCRL 将初始度分布和网络拓扑结构转化为信息嵌入向量,然后由主要由多层感知器组成的鲁棒性学习模块进行处理,实现了高速和高精度。我们的大量实验证明,与现有方法相比,GCRL 能在更短的时间内获得更优越的性能,尤其是在测试数据分布与训练集存在显著差异的困难情况下。该框架还显示出对不同规模网络的适应性,使其成为复杂网络鲁棒性学习的通用解决方案。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
GCRL: a graph neural network framework for network connectivity robustness learning
The resilience and adaptability of complex networks is crucial in ensuring their functionality against disruptions. Particularly, maintaining network connectivity under various attack scenarios is a key aspect of such resilience. Network connectivity refers to the degree to which nodes within a network are interconnected and able to exchange information or resources. Its robustness reflects the ability of a network to maintain connectivity under various attacks. Such ability has profound physical significance, ensuring the stability and reliability of real-world systems. Currently, connectivity robustness assessments rely heavily on very time-consuming attack simulations. This paper introduces a graph neural network framework for network connectivity robustness learning (GCRL) to advance the study of network connectivity robustness. GCRL transforms initial degree distributions and network topology into informative embedding vectors, which are then processed by a robustness learning module mainly composed of multi-layer perceptron, achieving both high speed and precision. Our extensive experiments demonstrate the superior performance of GCRL obtained in less time compared to existing methods, especially in tough scenarios where test data distributions significantly differ from the training set. The framework also shows adaptability to networks of different sizes, making it a more generalized solution for complex network robustness learning.
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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