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Auteurs principaux: Zhang, Jiahao, Pei, Xiaobing, Zhong, Zhaokun, Hao, Wenqiang, Tang, Zhenghao
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2509.13266
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author Zhang, Jiahao
Pei, Xiaobing
Zhong, Zhaokun
Hao, Wenqiang
Tang, Zhenghao
author_facet Zhang, Jiahao
Pei, Xiaobing
Zhong, Zhaokun
Hao, Wenqiang
Tang, Zhenghao
contents Graph Neural Networks (GNNs) have demonstrated remarkable performance across various applications, yet they are vulnerable to sophisticated adversarial attacks, particularly node injection attacks. The success of such attacks heavily relies on their stealthiness, the ability to blend in with the original graph and evade detection. However, existing methods often achieve stealthiness by relying on indirect proxy metrics, lacking consideration for the fundamental characteristics of the injected content, or focusing only on imitating local structures, which leads to the problem of local myopia. To overcome these limitations, we propose a dual-constraint stealthy node injection framework, called Joint Alignment of Nodal and Universal Structures (JANUS). At the local level, we introduce a local feature manifold alignment strategy to achieve geometric consistency in the feature space. At the global level, we incorporate structured latent variables and maximize the mutual information with the generated structures, ensuring the injected structures are consistent with the semantic patterns of the original graph. We model the injection attack as a sequential decision process, which is optimized by a reinforcement learning agent. Experiments on multiple standard datasets demonstrate that the JANUS framework significantly outperforms existing methods in terms of both attack effectiveness and stealthiness.
format Preprint
id arxiv_https___arxiv_org_abs_2509_13266
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle JANUS: A Dual-Constraint Generative Framework for Stealthy Node Injection Attacks
Zhang, Jiahao
Pei, Xiaobing
Zhong, Zhaokun
Hao, Wenqiang
Tang, Zhenghao
Machine Learning
Artificial Intelligence
Graph Neural Networks (GNNs) have demonstrated remarkable performance across various applications, yet they are vulnerable to sophisticated adversarial attacks, particularly node injection attacks. The success of such attacks heavily relies on their stealthiness, the ability to blend in with the original graph and evade detection. However, existing methods often achieve stealthiness by relying on indirect proxy metrics, lacking consideration for the fundamental characteristics of the injected content, or focusing only on imitating local structures, which leads to the problem of local myopia. To overcome these limitations, we propose a dual-constraint stealthy node injection framework, called Joint Alignment of Nodal and Universal Structures (JANUS). At the local level, we introduce a local feature manifold alignment strategy to achieve geometric consistency in the feature space. At the global level, we incorporate structured latent variables and maximize the mutual information with the generated structures, ensuring the injected structures are consistent with the semantic patterns of the original graph. We model the injection attack as a sequential decision process, which is optimized by a reinforcement learning agent. Experiments on multiple standard datasets demonstrate that the JANUS framework significantly outperforms existing methods in terms of both attack effectiveness and stealthiness.
title JANUS: A Dual-Constraint Generative Framework for Stealthy Node Injection Attacks
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2509.13266