Secure Autonomous Cyber-Physical Systems Through Verifiable Information Flow Control

Proceedings of the 2018 Workshop on Cyber-Physical Systems Security and PrivaCy Pub Date : 2018-01-15 DOI:10.1145/3264888.3264889

Jed Liu

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引用次数: 4

Abstract

Modern cyber-physical systems are complex networked computing systems that electronically control physical systems. Autonomous road vehicles are an important and increasingly ubiquitous instance. Unfortunately, their increasing complexity often leads to security vulnerabilities. Network connectivity exposes these vulnerable systems to remote software attacks that can result in real-world physical damage, including vehicle crashes and loss of control authority. We introduce an integrated architecture to provide provable security and safety assurance for cyber-physical systems by ensuring that safety-critical operations and control cannot be unintentionally affected by potentially malicious parts of the system. Fine-grained information flow control is used to design both hardware and software, determining how low-integrity information can affect high-integrity control decisions. This security assurance is used to improve end-to-end security across the entire cyber-physical system. We demonstrate this integrated approach by developing a mobile robotic testbed modeling a self-driving system and testing it with a malicious attack.

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通过可验证的信息流控制来保护自主网络物理系统

现代信息物理系统是复杂的网络计算系统，以电子方式控制物理系统。自动驾驶汽车是一个重要且越来越普遍的例子。不幸的是，它们日益增加的复杂性常常导致安全漏洞。网络连接使这些易受攻击的系统暴露在远程软件攻击之下，从而导致现实世界的物理损坏，包括车辆碰撞和失去控制权。我们引入了一个集成架构，通过确保安全关键操作和控制不会无意中受到系统潜在恶意部分的影响，为网络物理系统提供可证明的安全性和安全保障。细粒度信息流控制用于设计硬件和软件，确定低完整性信息如何影响高完整性控制决策。这种安全保证用于提高整个网络物理系统的端到端安全性。我们通过开发一个移动机器人测试平台来演示这种集成方法，该平台对自动驾驶系统进行建模，并对其进行恶意攻击测试。

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 2018 Workshop on Cyber-Physical Systems Security and PrivaCy

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