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Main Authors: Yuan, Bintao, Tang, Mingsheng, Ge, Binbin, Luo, Hongbin, Yan, Zijie
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2602.06612
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author Yuan, Bintao
Tang, Mingsheng
Ge, Binbin
Luo, Hongbin
Yan, Zijie
author_facet Yuan, Bintao
Tang, Mingsheng
Ge, Binbin
Luo, Hongbin
Yan, Zijie
contents As Low Earth Orbit (LEO) become mega-constellations critical infrastructure, attacks targeting them have grown in number and range. The security analysis of LEO constellations faces a fundamental paradigm gap: traditional topology-centric methods fail to capture systemic risks arising from dynamic load imbalances and high-order dependencies, which can transform localized failures into network-wide cascades. To address this, we propose HYDRA, a hypergraph-based dynamic risk analysis framework. Its core is a novel metric, Hyper-Bridge Centrality (HBC), which quantifies node criticality via a load-to-redundancy ratio within dependency structures. A primary challenge to resilience: the most critical vulnerabilities are not in the densely connected satellite core, but in the seemingly marginal ground-space interfaces. These are the system's "Black Swan" nodes--topologically peripheral yet structurally lethal. We validate this through extensive simulations using realistic StarLink TLE data and population-based gravity model. Experiments demonstrate that HBC consistently outperforms traditional metrics, identifying critical failure points that surpass the structural damage potential of even betweenness centrality. This work shifts the security paradigm from connectivity to structural stress, demonstrating that securing the network edge is paramount and necessitates a fundamental redesign of redundancy strategies.
format Preprint
id arxiv_https___arxiv_org_abs_2602_06612
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle HYDRA: Unearthing "Black Swan" Vulnerabilities in LEO Satellite Networks
Yuan, Bintao
Tang, Mingsheng
Ge, Binbin
Luo, Hongbin
Yan, Zijie
Cryptography and Security
As Low Earth Orbit (LEO) become mega-constellations critical infrastructure, attacks targeting them have grown in number and range. The security analysis of LEO constellations faces a fundamental paradigm gap: traditional topology-centric methods fail to capture systemic risks arising from dynamic load imbalances and high-order dependencies, which can transform localized failures into network-wide cascades. To address this, we propose HYDRA, a hypergraph-based dynamic risk analysis framework. Its core is a novel metric, Hyper-Bridge Centrality (HBC), which quantifies node criticality via a load-to-redundancy ratio within dependency structures. A primary challenge to resilience: the most critical vulnerabilities are not in the densely connected satellite core, but in the seemingly marginal ground-space interfaces. These are the system's "Black Swan" nodes--topologically peripheral yet structurally lethal. We validate this through extensive simulations using realistic StarLink TLE data and population-based gravity model. Experiments demonstrate that HBC consistently outperforms traditional metrics, identifying critical failure points that surpass the structural damage potential of even betweenness centrality. This work shifts the security paradigm from connectivity to structural stress, demonstrating that securing the network edge is paramount and necessitates a fundamental redesign of redundancy strategies.
title HYDRA: Unearthing "Black Swan" Vulnerabilities in LEO Satellite Networks
topic Cryptography and Security
url https://arxiv.org/abs/2602.06612