Bayesian optimisation to select Rössler system parameters used in Chaotic Ant Colony Optimisation for Coverage

Bayesian optimisation to select Rössler system parameters used in Chaotic Ant Colony Optimisation for Coverage

•The performance of the CACOC (Chaotic Ant Colony Optimisation for Coverage) mobility model for UAV swarms depends on its chaotic system parameters.•Bayesian optimisation permits to focus on promising chaotic regions of a bifurcation diagram.•Bayesian optimisation permits to improve the area coverag...

Full description

Saved in:
Bibliographic Details
Published in:Journal of computational science Vol. 41; p. 101047
Main Authors: Rosalie, Martin, Kieffer, Emmanuel, Brust, Matthias R., Danoy, Grégoire, Bouvry, Pascal
Format: Journal Article
Language:English
Published: Elsevier B.V 01-03-2020
Elsevier
Subjects:
Bayesian optimisation
Chaotic Dynamics
Chaotic system
Dynamical Systems
Mathematics
Nonlinear Sciences
UAV swarm
Bayesian optimisation
Chaotic system
UAV swarm
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:•The performance of the CACOC (Chaotic Ant Colony Optimisation for Coverage) mobility model for UAV swarms depends on its chaotic system parameters.•Bayesian optimisation permits to focus on promising chaotic regions of a bifurcation diagram.•Bayesian optimisation permits to improve the area coverage performance of a swarm of UAVs. The CACOC (Chaotic Ant Colony Optimisation for Coverage) algorithm has been developed to manage the mobility of a swarm of Unmanned Aerial Vehicles (UAVs). Using a specific chaotic dynamic obtained from the Rössler system, CACOC provides waypoints for UAVs that aim to optimise the coverage of an unknown area while having unpredictable trajectories. Since the chaotic dynamics are obtained from a three differential equations system with parameters, it is possible to tune one parameter to obtain another chaotic dynamic, which will result in different UAV mobility behaviours. This work aims at optimising this parameter of the Rössler chaotic system to improve the coverage performance of CACOC. Since each evaluation of a solution requires a full simulation, global optimisation techniques (e.g., population-based heuristics) would be very time-consuming. We therefore considered a surrogate-based method to efficiently explore the parameter space of the Rössler system for CACOC, i.e., Bayesian optimisation. Experimental results demonstrate that this approach permits to improve the speed of coverage of the UAV swarm. In addition an analysis of the dynamical properties of the obtained chaotic system is provided.
ISSN:1877-7503
1877-7511
DOI:10.1016/j.jocs.2019.101047