Synchronization Approach to Formation Control of Mobile Robots from the Cluster Space Perspective

Synchronization Approach to Formation Control of Mobile Robots from the Cluster Space Perspective

In this paper, a synchronization approach to solve the formation control problem for three differential-drive wheeled mobile robots from a cluster space perspective is studied. In order to solve the individual trajectory tracking task of each mobile robot while maintaining a desired formation, besid...

Full description

Saved in:
Bibliographic Details
Published in:Journal of intelligent & robotic systems Vol. 103; no. 3
Main Authors: Mauricio, Arteaga-Escamilla C, Castro-Linares, Rafael, Álvarez-Gallegos, Jaime
Format: Journal Article
Language:English
Published: Dordrecht Springer Netherlands 01-11-2021
Springer
Springer Nature B.V
Subjects:
Artificial Intelligence
Asymptotic properties
Clusters
Control
Control theory
Controllers
Convergence
Electrical Engineering
Engineering
Mechanical Engineering
Mechatronics
Perturbation
Robot control
Robotics
Robotics industry
Robots
Short Paper
Synchronism
Topical collection on Unmanned Systems
Tracking errors
Synchronization approach
Formation control
Cluster space control
Differential-drive wheeled mobile robots
Tracking control
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:In this paper, a synchronization approach to solve the formation control problem for three differential-drive wheeled mobile robots from a cluster space perspective is studied. In order to solve the individual trajectory tracking task of each mobile robot while maintaining a desired formation, besides the controller at cluster level, another inner robot controller is implemented. With this, the robustness of formation keeping to perturbations is increased and motions of all mobile robots are synchronized. Based on Lyapunov theory, it is demonstrated that the proposed synchronization strategy guarantees that both the tracking errors and the synchronization errors of all mobile robots asymptotically converge to the origin. Achieving this, the cluster errors asymptotically converge to zero as well. Furthermore, the robots orientation errors exponentially converge to the origin. The control laws are experimentally validated, using a set of TurtleBot3 mobile robots; these results show the efficiency of the proposed scheme.
ISSN:0921-0296
1573-0409
DOI:10.1007/s10846-021-01495-y