An automated system repair framework with signal temporal logic

IF 0.4 4区计算机科学 Q4 COMPUTER SCIENCE, INFORMATION SYSTEMS Acta Informatica Pub Date : 2021-06-17 DOI:10.1007/s00236-021-00403-z

Mert Ergurtuna, Beyazit Yalcinkaya, Ebru Aydin Gol

引用次数: 6

Abstract

We present an automated system repair framework for cyber-physical systems. The proposed framework consists of three main steps: (1) system simulation and fault detection to generate a labeled dataset, (2) identification of the repairable temporal properties leading to the faulty behavior and (3) repairing the system to avoid the occurrence of the cause identified in the second step. We express the cause as a past time signal temporal logic (ptSTL) formula and present an efficient monotonicity-based method to synthesize a ptSTL formula from a labeled dataset. Then, in the third step, we modify the faulty system by removing all behaviors that satisfy the ptSTL formula representing the cause of the fault. We apply the framework to two rich modeling formalisms: discrete-time dynamical systems and timed automata. For both of them, we define repairable formulae, the corresponding repair procedures, and illustrate them over case studies.

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具有信号时序逻辑的自动系统修复框架

我们提出了一个用于网络物理系统的自动系统修复框架。提出的框架包括三个主要步骤:(1)系统仿真和故障检测以生成标记数据集;(2)识别导致故障行为的可修复时间属性;(3)修复系统以避免第二步中识别的原因的发生。我们将其表示为过去时间信号时间逻辑(ptSTL)公式，并提出了一种基于单调性的有效方法来从标记数据集合成ptSTL公式。然后，在第三步中，我们通过删除所有满足表示故障原因的ptSTL公式的行为来修改故障系统。我们将该框架应用于两种丰富的建模形式:离散时间动力系统和时间自动机。对于这两种情况，我们定义了可修复公式和相应的修复过程，并通过案例研究说明了它们。

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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来源期刊

Acta Informatica 工程技术-计算机：信息系统

CiteScore

2.40

自引率

16.70%

发文量

审稿时长

>12 weeks

期刊介绍： Acta Informatica provides international dissemination of articles on formal methods for the design and analysis of programs, computing systems and information structures, as well as related fields of Theoretical Computer Science such as Automata Theory, Logic in Computer Science, and Algorithmics. Topics of interest include: • semantics of programming languages • models and modeling languages for concurrent, distributed, reactive and mobile systems • models and modeling languages for timed, hybrid and probabilistic systems • specification, program analysis and verification • model checking and theorem proving • modal, temporal, first- and higher-order logics, and their variants • constraint logic, SAT/SMT-solving techniques • theoretical aspects of databases, semi-structured data and finite model theory • theoretical aspects of artificial intelligence, knowledge representation, description logic • automata theory, formal languages, term and graph rewriting • game-based models, synthesis • type theory, typed calculi • algebraic, coalgebraic and categorical methods • formal aspects of performance, dependability and reliability analysis • foundations of information and network security • parallel, distributed and randomized algorithms • design and analysis of algorithms • foundations of network and communication protocols.