Safe Performance of an Industrial Autonomous Ground Vehicle in the Supervisory Control Framework

A Cyberphysical system, being an autonomous guided vehicle (AGV) and having diverse applications such as thematic parks and product transfer in manufacturing units, is modeled and controlled. The models of all subsystems of the AGV are provided in discrete event systems (DES) form following the Rama...

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Veröffentlicht in:	Electronics (Basel) 2023-12, Vol.12 (24), p.5035
Hauptverfasser:	Koumboulis, Fotis N., Fragkoulis, Dimitrios G., Panagiotakis, George E., Mavroeidis, Efthimios
Format:	Artikel
Sprache:	eng
Schlagworte:	Amusement parks Control theory Cyber-physical systems Design Discrete event systems Languages Manufacturing Mathematical models Sensors Subsystems Supervisors Supervisory control Unmanned ground vehicles Vehicles
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container_title	Electronics (Basel)
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creator	Koumboulis, Fotis N. Fragkoulis, Dimitrios G. Panagiotakis, George E. Mavroeidis, Efthimios
description	A Cyberphysical system, being an autonomous guided vehicle (AGV) and having diverse applications such as thematic parks and product transfer in manufacturing units, is modeled and controlled. The models of all subsystems of the AGV are provided in discrete event systems (DES) form following the Ramadge–Wonham (R–W) framework. The safe performance of the AGV, being the desired behavior of the system, is presented in the form of desired rules and translated into a set of regular languages. Then, the regular languages are realized as supervisory automata in the framework of Supervisory Control Theory (SCT). To ease implementation and coordination of the control architecture, the supervisors are designed to be in two-state automata forms. The controllability of the regular languages, regarding the AGV, will be proved, using the physical realizability (PR) of the synchronous product of the automata of the system and the supervisors. Also, the nonblocking property of all the controlled automata will be proven to be satisfied. Simulation of the controlled AGV will validate the proposed method.
doi_str_mv	10.3390/electronics12245035
format	Article
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source	Elektronische Zeitschriftenbibliothek - Frei zugängliche E-Journals; MDPI - Multidisciplinary Digital Publishing Institute
subjects	Amusement parks Control theory Cyber-physical systems Design Discrete event systems Languages Manufacturing Mathematical models Sensors Subsystems Supervisors Supervisory control Unmanned ground vehicles Vehicles
title	Safe Performance of an Industrial Autonomous Ground Vehicle in the Supervisory Control Framework
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