A Benchmark for Component-based Hybrid Systems Safety Verification

Andreas Müller; Stefan Mitsch; Werner Retschitzegger; Wieland Schwinger; Andre Platzer

A Benchmark for Component-based Hybrid Systems Safety Verification

Andreas Müller, Stefan Mitsch, Werner Retschitzegger, Wieland Schwinger, Andre Platzer

Department of Cooperative Information Systems

Research output: Chapter in Book/Report/Conference proceeding › Conference proceedings › peer-review

Abstract

At scale, formal verification of hybrid systems is challenging, but a potential remedy is the observation that systems often come with a number of natural components with certain local responsibilities. Ideally, such a compartmentalization into more manageable components also translates to hybrid systems verification, so that safety properties about the whole system can be derived from local verification results. We propose a benchmark consisting of a sequence of three case studies, where components interact to achieve system safety. The baseline for the benchmark is the verification effort from a monolithic fashion (i.e., the entire system without splitting it into components). We describe how to split the system models used in these case studies into components with local responsibilities, and what is expected about their interaction to guarantee system safety. The benchmark can be used to assess the performance, automation, and verification features of component-based verification approaches.

Original language	English
Title of host publication	ARCH17. 4th International Workshop on Applied Verification of Continuous and Hybrid Systems
Editors	Goran Frehse and Matthias Althoff (editors)
Publisher	EasyChair
Pages	65-74
Number of pages	10
Volume	48
Publication status	Published - 2017

Publication series

Name	EPiC Series in Computing

Fields of science

102 Computer Sciences
102015 Information systems
102027 Web engineering

JKU Focus areas

Computation in Informatics and Mathematics

Cite this

@inproceedings{a867cf5686924014bbdcf64134d5343b,

title = "A Benchmark for Component-based Hybrid Systems Safety Verification",

abstract = "At scale, formal verification of hybrid systems is challenging, but a potential remedy is the observation that systems often come with a number of natural components with certain local responsibilities. Ideally, such a compartmentalization into more manageable components also translates to hybrid systems verification, so that safety properties about the whole system can be derived from local verification results. We propose a benchmark consisting of a sequence of three case studies, where components interact to achieve system safety. The baseline for the benchmark is the verification effort from a monolithic fashion (i.e., the entire system without splitting it into components). We describe how to split the system models used in these case studies into components with local responsibilities, and what is expected about their interaction to guarantee system safety. The benchmark can be used to assess the performance, automation, and verification features of component-based verification approaches.",

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year = "2017",

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series = "EPiC Series in Computing",

publisher = "EasyChair",

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booktitle = "ARCH17. 4th International Workshop on Applied Verification of Continuous and Hybrid Systems",

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A Benchmark for Component-based Hybrid Systems Safety Verification. / Müller, Andreas; Mitsch, Stefan; Retschitzegger, Werner et al.
ARCH17. 4th International Workshop on Applied Verification of Continuous and Hybrid Systems. ed. / Goran Frehse and Matthias Althoff (editors). Vol. 48 EasyChair, 2017. p. 65-74 (EPiC Series in Computing).

Research output: Chapter in Book/Report/Conference proceeding › Conference proceedings › peer-review

TY - GEN

T1 - A Benchmark for Component-based Hybrid Systems Safety Verification

AU - Müller, Andreas

AU - Mitsch, Stefan

AU - Retschitzegger, Werner

AU - Schwinger, Wieland

AU - Platzer, Andre

PY - 2017

Y1 - 2017

N2 - At scale, formal verification of hybrid systems is challenging, but a potential remedy is the observation that systems often come with a number of natural components with certain local responsibilities. Ideally, such a compartmentalization into more manageable components also translates to hybrid systems verification, so that safety properties about the whole system can be derived from local verification results. We propose a benchmark consisting of a sequence of three case studies, where components interact to achieve system safety. The baseline for the benchmark is the verification effort from a monolithic fashion (i.e., the entire system without splitting it into components). We describe how to split the system models used in these case studies into components with local responsibilities, and what is expected about their interaction to guarantee system safety. The benchmark can be used to assess the performance, automation, and verification features of component-based verification approaches.

AB - At scale, formal verification of hybrid systems is challenging, but a potential remedy is the observation that systems often come with a number of natural components with certain local responsibilities. Ideally, such a compartmentalization into more manageable components also translates to hybrid systems verification, so that safety properties about the whole system can be derived from local verification results. We propose a benchmark consisting of a sequence of three case studies, where components interact to achieve system safety. The baseline for the benchmark is the verification effort from a monolithic fashion (i.e., the entire system without splitting it into components). We describe how to split the system models used in these case studies into components with local responsibilities, and what is expected about their interaction to guarantee system safety. The benchmark can be used to assess the performance, automation, and verification features of component-based verification approaches.

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VL - 48

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BT - ARCH17. 4th International Workshop on Applied Verification of Continuous and Hybrid Systems

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