Phase-Space Detection of Cyber Events

Proceedings of the 10th Annual Cyber and Information Security Research Conference Pub Date : 2015-04-07 DOI:10.1145/2746266.2746279

J. M. Hernández, Aaron Ferber, S. Prowell, L. Hively

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引用次数: 13

Abstract

Energy Delivery Systems (EDS) are a network of processes that produce, transfer and distribute energy. EDS are increasingly dependent on networked computing assets, as are many Industrial Control Systems. Consequently, cyber-attacks pose a real and pertinent threat, as evidenced by Stuxnet, Shamoon and Dragonfly. Hence, there is a critical need for novel methods to detect, prevent, and mitigate effects of such attacks. To detect cyber-attacks in EDS, we developed a framework for gathering and analyzing timing data that involves establishing a baseline execution profile and then capturing the effect of perturbations in the state from injecting various malware. The data analysis was based on nonlinear dynamics and graph theory to improve detection of anomalous events in cyber applications. The goal was the extraction of changing dynamics or anomalous activity in the underlying computer system. Takens' theorem in nonlinear dynamics allows reconstruction of topologically invariant, time-delay-embedding states from the computer data in a sufficiently high-dimensional space. The resultant dynamical states were nodes, and the state-to-state transitions were links in a mathematical graph. Alternatively, sequential tabulation of executing instructions provides the nodes with corresponding instruction-to-instruction links. Graph theorems guarantee graph-invariant measures to quantify the dynamical changes in the running applications. Results showed a successful detection of cyber events.

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网络事件的相空间检测

能源输送系统(EDS)是一个生产、传输和分配能源的过程网络。EDS越来越依赖于网络计算资产，正如许多工业控制系统一样。因此，网络攻击构成了真实而相关的威胁，正如震网、Shamoon和蜻蜓所证明的那样。因此，迫切需要新的方法来检测、预防和减轻此类攻击的影响。为了检测EDS中的网络攻击，我们开发了一个用于收集和分析时序数据的框架，该框架涉及建立基线执行概况，然后捕获注入各种恶意软件的状态扰动的影响。数据分析基于非线性动力学和图论，以提高网络应用中异常事件的检测能力。目标是提取底层计算机系统中不断变化的动态或异常活动。非线性动力学中的Takens定理允许从足够高维空间的计算机数据中重建拓扑不变，时延嵌入状态。生成的动态状态是节点，状态到状态的转换是数学图中的链接。或者，执行指令的顺序制表为节点提供相应的指令到指令链接。图定理保证了图不变度量来量化运行中的应用程序中的动态变化。结果显示，该系统成功检测到了网络事件。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Proceedings of the 10th Annual Cyber and Information Security Research Conference

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