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Optimal Transport-Based Coverage Control for Swarm Robot Systems: Generalization of the Voronoi Tessellation-Based Method

Daisuke Inoue, Yuji Ito, Hiroaki Yoshida

2020IEEE Control Systems Letters26 citationsDOIOpen Access PDF

Abstract

Swarm robot systems, which consist of many cooperating mobile robots, have attracted attention for their environmental adaptability and fault tolerance advantages. One of the most important tasks for such systems is coverage control, in which robots autonomously deploy to approximate a given spatial distribution. In this letter, we formulate a coverage control paradigm using the concept of optimal transport and propose a novel control technique, which we have termed the optimal transport-based coverage control (OTCC) method. The proposed OTCC, derived via the gradient flow of the cost function in the Kantorovich dual problem, is shown to cover a widely used existing control method as a special case. We also perform a Lyapunov stability analysis of the controlled system, and provide numerical calculations to show that the OTCC reproduces target distributions with better performance than the existing control method.

Topics & Concepts

Computer scienceGeneralizationAdaptabilityStability (learning theory)Mobile robotRobotMathematical optimizationLyapunov functionControl theory (sociology)Cover (algebra)Optimal controlControl (management)Function (biology)Voronoi diagramDual (grammatical number)Swarm behaviourLyapunov stabilityMathematicsControl systemFault toleranceRoboticsAutomationAdaptive controlDistributed Control Multi-Agent SystemsControl and Dynamics of Mobile RobotsAdvanced Control Systems Optimization
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