BACKWARD MOTION PLANNING AND CONTROL OF MULTIPLE MOBILE ROBOTS MOVING  IN TIGHTLY COUPLED FORMATIONS

Kuppan Chetty RAMANATHAN; Manju MOHAN; Joshuva AROCKIA DHANRAJ

doi:10.23743/acs-2021-21

Applied Computer Science (Sep 2021)

BACKWARD MOTION PLANNING AND CONTROL OF MULTIPLE MOBILE ROBOTS MOVING IN TIGHTLY COUPLED FORMATIONS

Kuppan Chetty RAMANATHAN,
Manju MOHAN,
Joshuva AROCKIA DHANRAJ

Affiliations

Kuppan Chetty RAMANATHAN: ORCiD; Hindustan Institute of Technology and Science, Centre for Automation and Robotics, School of Mechanical Sciences, OMR, Rajiv Gandhi Salai, Padur, Chennai - 603103, India, [email protected].
Manju MOHAN: ORCiD; Hindustan Institute of Technology and Science, Centre for Automation and Robotics, School of Mechanical Sciences, OMR, Rajiv Gandhi Salai, Padur, Chennai - 603103, India
Joshuva AROCKIA DHANRAJ: ORCiD; Hindustan Institute of Technology and Science, Centre for Automation and Robotics, School of Mechanical Sciences, OMR, Rajiv Gandhi Salai, Padur, Chennai - 603103, India

DOI: https://doi.org/10.23743/acs-2021-21
Journal volume & issue: Vol. 17, no. 3
pp. 60 – 72

Abstract

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This work addresses the development of a distributed switching control strategy to drive the group of mobile robots in both backward and forward motion in a tightly coupled geometric pattern, as a solution for the deadlock situation that arises while navigating the unknown environment. A generalized closed-loop tracking controller considering the leader referenced model is used for the robots to remain in the formation while navigating the environment. A tracking controller using the simple geometric approach and the Instantaneous Centre of Radius (ICR), to drive the robot in the backward motion during deadlock situation is developed and presented. State-Based Modelling is used to model the behaviors/motion states of the proposed approach in MATLAB/STATEFLOW environment. Simulation studies are carried out to test the performance and error dynamics of the proposed approach combining the formation, navigation, and backward motion of the robots in all geometric patterns of formation, and the results are discussed.

Published in Applied Computer Science

ISSN: 1895-3735 (Print); 2353-6977 (Online)
Publisher: Polish Association for Knowledge Promotion
Country of publisher: Poland
LCC subjects: Technology: Technology (General): Industrial engineering. Management engineering: Information technology; Science: Mathematics: Instruments and machines: Electronic computers. Computer science
Website: http://www.acs.pollub.pl/

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