Safety assurance of an industrial robotic control system using hardware/software co-verification

•Co-verification framework where HW and SW models are coupled via platform mappings.•Verification results are transferred between tools to verify system-level properties.•Formal verification of a safety-critical system in an ABB industrial paint robot.•Use of the two tools Simulink Design Verifier a...

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Bibliographic Details
Published in:Science of computer programming 2022-04, Vol.216, p.102766, Article 102766
Main Authors: Murray, Yvonne, Sirevåg, Martin, Ribeiro, Pedro, Anisi, David A., Mossige, Morten
Format: Article
Language:English
Subjects:
Co-verification
Cyber-physical systems (CPS)
Formal verification
Model checking
Robots
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Summary:•Co-verification framework where HW and SW models are coupled via platform mappings.•Verification results are transferred between tools to verify system-level properties.•Formal verification of a safety-critical system in an ABB industrial paint robot.•Use of the two tools Simulink Design Verifier and RoboTool. As a general trend in industrial robotics, an increasing number of safety functions are being developed or re-engineered to be handled in software rather than by physical hardware such as safety relays or interlock circuits. This trend reinforces the importance of supplementing traditional, input-based testing and quality procedures which are widely used in industry today, with formal verification and model-checking methods. To this end, this paper focuses on a representative safety-critical system in an ABB industrial paint robot, namely the High-Voltage electrostatic Control system (HVC). The practical convergence of the high-voltage produced by the HVC, essential for safe operation, is formally verified using a novel and general co-verification framework where hardware and software models are related via platform mappings. This approach enables the pragmatic combination of highly diverse and specialised tools. The paper's main contribution includes details on how hardware abstraction and verification results can be transferred between tools in order to verify system-level safety properties. It is noteworthy that the HVC application considered in this paper has a rather generic form of a feedback controller. Hence, the co-verification framework and experiences reported here are also highly relevant for any cyber-physical system tracking a setpoint reference.
ISSN:0167-6423
1872-7964
DOI:10.1016/j.scico.2021.102766