Analyzing the impact of human errors on interactive service robotic scenarios via formal verification

Developing robotic applications with human–robot interaction for the service sector raises a plethora of challenges. In these settings, human behavior is essentially unconstrained as they can stray from the plan in numerous ways, constituting a critical source of uncertainty for the outcome of the r...

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Bibliographic Details
Published inSoftware and systems modeling Vol. 23; no. 2; pp. 473 - 502
Main Authors Lestingi, Livia, Manglaviti, Andrea, Marinaro, Davide, Marinello, Luca, Askarpour, Mehrnoosh, Bersani, Marcello M., Rossi, Matteo
Format Journal Article
LanguageEnglish
Published Berlin/Heidelberg Springer Berlin Heidelberg 01.04.2024
Springer Nature B.V
Subjects
Compilers
Computer Science
Designers
Human behavior
Human error
Impact analysis
Information Systems Applications (incl.Internet)
Interpreters
IT in Business
Mission planning
Programming Languages
Programming Techniques
Robotics
Robots
Software Engineering
Software Engineering/Programming and Operating Systems
Special Section Paper
Statistical models
Verification
Human errors
Statistical model checking
Stochastic Hybrid Automata
Human–robot interaction
Service robotics
Formal modeling
Formal verification
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Summary:Developing robotic applications with human–robot interaction for the service sector raises a plethora of challenges. In these settings, human behavior is essentially unconstrained as they can stray from the plan in numerous ways, constituting a critical source of uncertainty for the outcome of the robotic mission. Application designers require accessible and reliable frameworks to address this issue at an early development stage. We present a model-driven framework for developing interactive service robotic scenarios, allowing designers to model the interactive scenario, estimate its outcome, deploy the application, and smoothly reconfigure it. This article extends the framework compared to previous works by introducing an analysis of the impact of human errors on the mission’s outcome. The core of the framework is a formal model of the agents at play—the humans and the robots—and the robotic mission under analysis, which is subject to statistical model checking to estimate the mission’s outcome. The formal model incorporates a formalization of different human erroneous behaviors’ phenotypes, whose likelihood can be tuned while configuring the scenario. Through scenarios inspired by the healthcare setting, the evaluation highlights how different configurations of erroneous behavior impact the verification results and guide the designer toward the mission design that best suits their needs.
ISSN:1619-1366
1619-1374
DOI:10.1007/s10270-023-01125-1