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Main Authors: Du, Chengze, Xu, Heng, Yu, Zhiwei, Zhou, Ying, Meng, Zili, Li, Jialong
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2508.12852
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author Du, Chengze
Xu, Heng
Yu, Zhiwei
Zhou, Ying
Meng, Zili
Li, Jialong
author_facet Du, Chengze
Xu, Heng
Yu, Zhiwei
Zhou, Ying
Meng, Zili
Li, Jialong
contents Tomography inference attacks aim to reconstruct network topology by analyzing end-to-end probe delays. Existing defenses mitigate these attacks by manipulating probe delays to mislead inference, but rely on two strong assumptions: (i) probe packets can be perfectly detected and altered, and (ii) attackers use known, fixed inference algorithms. These assumptions often break in practice, leading to degraded defense performance under detection errors or adaptive adversaries. We present RoTO, a robust topology obfuscation scheme that eliminates both assumptions by modeling uncertainty in attacker-observed delays through a distributional formulation. RoTO casts the defense objective as a min-max optimization problem that maximizes expected topological distortion across this uncertainty set, without relying on perfect probe control or specific attacker models. To approximate attacker behavior, RoTO leverages graph neural networks for inference simulation and adversarial training. We also derive an upper bound on attacker success probability, and demonstrate that our approach enhances topology obfuscation performance through the optimization of this upper bound. Experimental results show that RoTO outperforms existing defense methods, achieving average improvements of 34% in structural similarity and 42.6% in link distance while maintaining strong robustness and concealment capabilities.
format Preprint
id arxiv_https___arxiv_org_abs_2508_12852
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle RoTO: Robust Topology Obfuscation Against Tomography Inference Attacks
Du, Chengze
Xu, Heng
Yu, Zhiwei
Zhou, Ying
Meng, Zili
Li, Jialong
Networking and Internet Architecture
Tomography inference attacks aim to reconstruct network topology by analyzing end-to-end probe delays. Existing defenses mitigate these attacks by manipulating probe delays to mislead inference, but rely on two strong assumptions: (i) probe packets can be perfectly detected and altered, and (ii) attackers use known, fixed inference algorithms. These assumptions often break in practice, leading to degraded defense performance under detection errors or adaptive adversaries. We present RoTO, a robust topology obfuscation scheme that eliminates both assumptions by modeling uncertainty in attacker-observed delays through a distributional formulation. RoTO casts the defense objective as a min-max optimization problem that maximizes expected topological distortion across this uncertainty set, without relying on perfect probe control or specific attacker models. To approximate attacker behavior, RoTO leverages graph neural networks for inference simulation and adversarial training. We also derive an upper bound on attacker success probability, and demonstrate that our approach enhances topology obfuscation performance through the optimization of this upper bound. Experimental results show that RoTO outperforms existing defense methods, achieving average improvements of 34% in structural similarity and 42.6% in link distance while maintaining strong robustness and concealment capabilities.
title RoTO: Robust Topology Obfuscation Against Tomography Inference Attacks
topic Networking and Internet Architecture
url https://arxiv.org/abs/2508.12852