Simulation of a Bio-Inspired Flocking-Based Aggregation Behaviour in Swarm Robotics

Simulation of a Bio-Inspired Flocking-Based Aggregation Behaviour in Swarm Robotics

This paper presents a biologically inspired flocking-based aggregation behaviour of a swarm of mobile robots. Aggregation behaviour is essential to many swarm systems, such as swarm robotics systems, in order to accomplish complex tasks that are impossible for a single agent. In this work, we develo...

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Bibliographic Details
Main Authors: Samira Rasouli, Kerstin Dautenhahn, Chrystopher L. Nehaniv
Format: Article
Language:English
Published: MDPI AG 2024-11-01
Series:Biomimetics
Subjects:
swarm robotics
Reynolds’ rules
aggregation behaviour
K-means
Online Access:https://www.mdpi.com/2313-7673/9/11/668
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Summary:This paper presents a biologically inspired flocking-based aggregation behaviour of a swarm of mobile robots. Aggregation behaviour is essential to many swarm systems, such as swarm robotics systems, in order to accomplish complex tasks that are impossible for a single agent. In this work, we developed a robot controller using Reynolds’ flocking rules to coordinate the movements of multiple e-puck robots during the aggregation process. To improve aggregation behaviour among these robots and address the scalability issues in current flocking-based aggregation approaches, we proposed using a K-means algorithm to identify clusters of agents. Using the developed controller, we simulated the aggregation behaviour among the swarm of robots. Five experiments were conducted using Webots simulation software. The performance of the developed system was evaluated under a variety of environments and conditions, such as various obstacles, agent failure, different numbers of robots, and arena sizes. The results of the experiments demonstrated that the proposed algorithm is robust and scalable. Moreover, we compared our proposed algorithm with another implementation of the flocking-based self-organizing aggregation behaviour based on Reynolds’ rules in a swarm of e-puck robots. Our algorithm outperformed this method in terms of cohesion performance and aggregation completion time.
ISSN:2313-7673

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