Explainable AI Security: Exploring Robustness of Graph Neural Networks to Adversarial Attacks
- URL: http://arxiv.org/abs/2406.13920v1
- Date: Thu, 20 Jun 2024 01:24:18 GMT
- Title: Explainable AI Security: Exploring Robustness of Graph Neural Networks to Adversarial Attacks
- Authors: Tao Wu, Canyixing Cui, Xingping Xian, Shaojie Qiao, Chao Wang, Lin Yuan, Shui Yu,
- Abstract summary: Graph neural networks (GNNs) have achieved tremendous success, but recent studies have shown that GNNs are vulnerable to adversarial attacks.
We investigate the adversarial robustness of GNNs by considering graph data patterns, model-specific factors, and the transferability of adversarial examples.
This work illuminates the vulnerabilities of GNNs and opens many promising avenues for designing robust GNNs.
- Score: 14.89001880258583
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Graph neural networks (GNNs) have achieved tremendous success, but recent studies have shown that GNNs are vulnerable to adversarial attacks, which significantly hinders their use in safety-critical scenarios. Therefore, the design of robust GNNs has attracted increasing attention. However, existing research has mainly been conducted via experimental trial and error, and thus far, there remains a lack of a comprehensive understanding of the vulnerability of GNNs. To address this limitation, we systematically investigate the adversarial robustness of GNNs by considering graph data patterns, model-specific factors, and the transferability of adversarial examples. Through extensive experiments, a set of principled guidelines is obtained for improving the adversarial robustness of GNNs, for example: (i) rather than highly regular graphs, the training graph data with diverse structural patterns is crucial for model robustness, which is consistent with the concept of adversarial training; (ii) the large model capacity of GNNs with sufficient training data has a positive effect on model robustness, and only a small percentage of neurons in GNNs are affected by adversarial attacks; (iii) adversarial transfer is not symmetric and the adversarial examples produced by the small-capacity model have stronger adversarial transferability. This work illuminates the vulnerabilities of GNNs and opens many promising avenues for designing robust GNNs.
Related papers
- Uncertainty in Graph Neural Networks: A Survey [50.63474656037679]
Graph Neural Networks (GNNs) have been extensively used in various real-world applications.
However, the predictive uncertainty of GNNs stemming from diverse sources can lead to unstable and erroneous predictions.
This survey aims to provide a comprehensive overview of the GNNs from the perspective of uncertainty.
arXiv Detail & Related papers (2024-03-11T21:54:52Z) - Securing Graph Neural Networks in MLaaS: A Comprehensive Realization of Query-based Integrity Verification [68.86863899919358]
We introduce a groundbreaking approach to protect GNN models in Machine Learning from model-centric attacks.
Our approach includes a comprehensive verification schema for GNN's integrity, taking into account both transductive and inductive GNNs.
We propose a query-based verification technique, fortified with innovative node fingerprint generation algorithms.
arXiv Detail & Related papers (2023-12-13T03:17:05Z) - Trustworthy Graph Neural Networks: Aspects, Methods and Trends [115.84291569988748]
Graph neural networks (GNNs) have emerged as competent graph learning methods for diverse real-world scenarios.
Performance-oriented GNNs have exhibited potential adverse effects like vulnerability to adversarial attacks.
To avoid these unintentional harms, it is necessary to build competent GNNs characterised by trustworthiness.
arXiv Detail & Related papers (2022-05-16T02:21:09Z) - A Comprehensive Survey on Trustworthy Graph Neural Networks: Privacy,
Robustness, Fairness, and Explainability [59.80140875337769]
Graph Neural Networks (GNNs) have made rapid developments in the recent years.
GNNs can leak private information, are vulnerable to adversarial attacks, can inherit and magnify societal bias from training data.
This paper gives a comprehensive survey of GNNs in the computational aspects of privacy, robustness, fairness, and explainability.
arXiv Detail & Related papers (2022-04-18T21:41:07Z) - CAP: Co-Adversarial Perturbation on Weights and Features for Improving
Generalization of Graph Neural Networks [59.692017490560275]
Adversarial training has been widely demonstrated to improve model's robustness against adversarial attacks.
It remains unclear how the adversarial training could improve the generalization abilities of GNNs in the graph analytics problem.
We construct the co-adversarial perturbation (CAP) optimization problem in terms of weights and features, and design the alternating adversarial perturbation algorithm to flatten the weight and feature loss landscapes alternately.
arXiv Detail & Related papers (2021-10-28T02:28:13Z) - Adversarial Attack on Graph Neural Networks as An Influence Maximization
Problem [12.88476464580968]
Graph neural networks (GNNs) have attracted increasing interests.
There is an urgent need for understanding the robustness of GNNs under adversarial attacks.
arXiv Detail & Related papers (2021-06-21T00:47:44Z) - Uncertainty-Matching Graph Neural Networks to Defend Against Poisoning
Attacks [43.60973654460398]
Graph Neural Networks (GNNs) are generalizations of neural networks to graph-structured data.
GNNs are vulnerable to adversarial attacks, i.e., a small perturbation to the structure can lead to a non-trivial performance degradation.
We propose Uncertainty Matching GNN (UM-GNN), that is aimed at improving the robustness of GNN models.
arXiv Detail & Related papers (2020-09-30T05:29:42Z) - Graph Backdoor [53.70971502299977]
We present GTA, the first backdoor attack on graph neural networks (GNNs)
GTA departs in significant ways: it defines triggers as specific subgraphs, including both topological structures and descriptive features.
It can be instantiated for both transductive (e.g., node classification) and inductive (e.g., graph classification) tasks.
arXiv Detail & Related papers (2020-06-21T19:45:30Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.