RoboWorld: Verification of Robotic Systems with Environment in the Loop-Reference-Cited by-同舟云学术

RoboWorld: Verification of Robotic Systems with Environment in the Loop

Published:2023-11-20 Issue:4 Volume:35 Page:1-46
ISSN:0934-5043
Container-title:Formal Aspects of Computing
language:en
Short-container-title:Form. Asp. Comput.

Author:

Baxter James¹^ORCID,Carvalho Gustavo²^ORCID,Cavalcanti Ana¹^ORCID,Júnior Francisco Rodrigues²^ORCID

Affiliation:

1. University of York, UK

2. Universidade Federal de Pernambuco, Brazil

Abstract

A robot affects and is affected by its environment, so that typically its behaviour depends on properties of that environment. For verification, we need to formalise those properties. Modelling the environment is very challenging, if not impossible, but we can capture assumptions. Here, we present RoboWorld, a domain-specific controlled natural language with a process algebraic semantics that can be used to define (a) operational requirements, and (b) environment interactions of a robot. RoboWorld is part of the RoboStar framework for verification of robotic systems. In this article, we define RoboWorld’s syntax and hybrid semantics, and illustrate its use for capturing operational requirements, for automatic test generation, and for proof. We also present a tool that supports the writing of RoboWorld documents. Since RoboWorld is a controlled natural language, it complements the other RoboStar notations in being accessible to roboticists, while at the same time benefitting from a formal semantics to support rigorous verification (via testing and proof).

Funder

Royal Academy of Engineering

UK EPSRC

UKRI TAS Verifiability Node

CNPq

CAPES

FACEPE

PRONEX

Publisher

Association for Computing Machinery (ACM)

Subject

Theoretical Computer Science,Software

Link

https://dl.acm.org/doi/pdf/10.1145/3625563

Reference49 articles.

1. A. V. Aho, M. S. Lam, R. Sethi, and J. D. Ullman. 2007. Compilers: Principles, Techniques, and Tools. Addison-Wesley.

2. EPiC Series in Computing;Althoff M.,2015

3. Formally-based model-driven development of collaborative robotic applications;Askarpour M.;Journal of Intelligent and Robotic Systems,2021

4. J. Baxter, A. L. C. Cavalcanti, G. Carvalho, and F. Rodrigues Jr.2022a. RoboWorld Reference Manual. Technical Report. RoboStar Centre on Software Engineering for Robotics. Retrieved from robostar.cs.york.ac.uk/publications/techreports/reports/roboworld-reference.pdf

5. J. Baxter, A. L. C. Cavalcanti, M. Gazda, and R. Hierons. 2022b. Testing using CSP Models: Time, Inputs, and Outputs – Extended Version. Technical Report. RoboStar Centre on Software Engineering for Robotics. Retrieved from robostar.cs.york.ac.uk/publications/reports/BCGH22.pdf