Formal Verification in the Loop to Enhance Verification of Safety-Critical Cyber-physical Systems

Electron. Commun. Eur. Assoc. Softw. Sci. Technol. Pub Date : 2019-10-21 DOI:10.14279/tuj.eceasst.77.1106

C. Bernardeschi, A. Domenici, S. Saponara

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引用次数: 3

Abstract

Formal verification may play a central role in the development of safe controllers, such as those found in electric drives or (semi-)autonomous vehicles, whose complexity arises from the coexistence of mechanical and electrical subsystems with sophisticated electronic controllers that must implement high-level control policies according to different driving modes, while optimizing several objectives, such as safety first and foremost, efficiency, and performance among others. Model-driven development resorts to simulation to assess how well the various requirements and constraints are satisfied, but there is a growing awareness that more rigorous methods are needed to achieve the required levels of safety. This paper proposes a conceptual framework for the development of complex systems based on (i) higher-order logic specification, (ii) verification by theorem proving, and (iii) tight integration of verification with model-driven development and simulation. This framework addresses both digital and analog systems, as illustrated with some examples in different fields including implantable biomedical systems, autonomous vehicles, and electric valve actuation.

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在循环中正式验证以加强安全关键信息物理系统的验证

正式验证可能在安全控制器的开发中发挥核心作用，例如在电力驱动或(半)自动驾驶汽车中发现的那些，其复杂性源于机械和电气子系统与复杂的电子控制器的共存，这些电子控制器必须根据不同的驾驶模式实施高级控制策略，同时优化几个目标，例如安全第一，效率和性能等。模型驱动的开发依靠模拟来评估各种需求和约束的满足程度，但是越来越多的人意识到需要更严格的方法来实现所需的安全级别。本文提出了一个基于(i)高阶逻辑规范、(ii)定理证明验证和(iii)验证与模型驱动开发和仿真紧密集成的复杂系统开发的概念框架。该框架涉及数字和模拟系统，如在不同领域的一些例子所示，包括植入式生物医学系统、自动驾驶汽车和电动阀门驱动。

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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Electron. Commun. Eur. Assoc. Softw. Sci. Technol.

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