Yuvaraj Selvaraj , Jonas Krook , Wolfgang Ahrendt , Martin Fabian
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引用次数: 0
摘要
网络物理系统通常是安全关键型系统,其正确性至关重要,例如自动驾驶系统。使用正规数学方法是保证正确性和提高安全性的一种方法。虽然这些方法已显示出其有用性,但必须小心谨慎,因为建模错误可能导致证明有问题的控制器是安全的,这在实践中可能是灾难性的。本文讨论了微分动态逻辑中的两个建模错误,微分动态逻辑是一种用于混合系统的形式化规范和验证语言,是网络物理系统的数学模型。本文的主要贡献在于提供了这两种建模错误不会导致错误控制器被证明安全的条件,并展示了如何在交互式定理证明器 KeYmaera X 的帮助下证明这些条件。本文通过一个自动驾驶安全控制器的实际例子来说明这些问题,结果表明所制定的条件对错误和正确的控制器都有预期的效果。同时还说明了所制定的条件如何帮助找到环路不变的候选者,以证明具有反馈环路的混合系统的特性。此外,还讨论了这种环路不变量与最大控制不变量集特征之间的关系。
On proving that an unsafe controller is not proven safe
Cyber-physical systems are often safety-critical and their correctness is crucial, such as in the case of automated driving. Using formal mathematical methods is one way to guarantee correctness and improve safety. Although these methods have shown their usefulness, care must be taken because modelling errors might result in proving a faulty controller safe, which is potentially catastrophic in practice. This paper deals with two such modelling errors in differential dynamic logic, a formal specification and verification language for hybrid systems, which are mathematical models of cyber-physical systems. The main contributions are to provide conditions under which these two modelling errors cannot cause a faulty controller to be proven safe, and to show how these conditions can be proven with help of the interactive theorem prover KeYmaera X. The problems are illustrated with a real world example of a safety controller for automated driving, and it is shown that the formulated conditions have the intended effect both for a faulty and a correct controller. It is also shown how the formulated conditions aid in finding a loop invariant candidate to prove properties of hybrid systems with feedback loops. Furthermore, the relation between such a loop invariant and the characterisation of the maximal control invariant set is discussed.
期刊介绍:
The Journal of Logical and Algebraic Methods in Programming is an international journal whose aim is to publish high quality, original research papers, survey and review articles, tutorial expositions, and historical studies in the areas of logical and algebraic methods and techniques for guaranteeing correctness and performability of programs and in general of computing systems. All aspects will be covered, especially theory and foundations, implementation issues, and applications involving novel ideas.
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