DocumentCode
2917290
Title
Self-triggered best-response dynamics for mobile sensor deployment
Author
Cortes, Ana ; Martinez, Sonia
Author_Institution
Dept. of Mech. & Aerosp. Eng., Univ. of California, San Diego, La Jolla, CA, USA
fYear
2013
fDate
17-19 June 2013
Firstpage
6370
Lastpage
6375
Abstract
The coordination of large numbers of autonomous agents has lead to the development of novel theoretical tools for the analysis and design of practical control algorithms with performance guarantees. Aligned with this research, this paper investigates the adaptation of classical best-response dynamics to achieve coverage control by a mobile sensor network subject to communication constraints. To do this, we first formulate a 1-D deployment scenario as a continuous-time-space potential game with a componentwise concave potential function. Making use of the stability theory for non-smooth dynamical systems, we characterize how the set-valued, best-response dynamics can converge to the set of Nash equilibria under some general conditions. This allows us to guarantee that sensor trajectories converge toward positions that maximize the covered area. We then modify the best-response dynamics to account for a self-triggered communication strategy that decreases the multi-agent communication effort while ensuring convergence to the equilibrium set. Finally, we present some simulations that demonstrate the performance of the proposed strategy.
Keywords
continuous time systems; decentralised control; game theory; sensor placement; stability; wireless sensor networks; 1-D deployment scenario; Nash equilibria; autonomous agents; communication constraints; componentwise concave potential function; continuous-time-space potential game; control algorithm analysis; control algorithm design; coverage control; mobile sensor deployment; mobile sensor network; multiagent communication effort; nonsmooth dynamical systems; self-triggered best-response dynamics; self-triggered communication strategy; set-valued best-response dynamics; stability theory; Convergence; Games; Mobile communication; Mobile computing; Monitoring; Trajectory; Upper bound;
fLanguage
English
Publisher
ieee
Conference_Titel
American Control Conference (ACC), 2013
Conference_Location
Washington, DC
ISSN
0743-1619
Print_ISBN
978-1-4799-0177-7
Type
conf
DOI
10.1109/ACC.2013.6580837
Filename
6580837
Link To Document