Litcius/Paper detail

Indirect/Direct Learning Coverage Control for Wireless Sensor and Mobile Robot Networks

Yen‐Chen Liu, Tsen-Chang Lin, Mu-Tai Lin

2021IEEE Transactions on Control Systems Technology20 citationsDOI

Abstract

This article proposes indirect/direct learning control schemes for wireless sensor and mobile robot networks to cover an environment according to the density function, which is the distribution of an important quantity within the environment. When stationary sensors cooperate with mobile robots, the density estimation can be enhanced by using nonstationary basis functions to relax the assumption of matching conditions in the previous approach. To improve the density function estimation, this study employs an expectation–maximization algorithm and log-likelihood, which maximizes the similarity between the proposed normalized density and normalized coverage function. Subsequently, the adaptive weighting algorithm is combined with the proposed indirect coverage control for tunable basis centers and the weighting of the basis functions. For direct coverage control, mobile robots are driven to cover the regions of higher importance while simultaneously estimating the density function utilizing a sensory model function. We prove that the Lloyd algorithm is a special case of the direct method when the density function and Voronoi partitions are available. The efficiency of the proposed methods is confirmed in numerical examples and semiexperiments.

Topics & Concepts

WeightingMobile robotComputer scienceMaximizationProbability density functionVoronoi diagramBasis (linear algebra)Function (biology)Basis functionCover (algebra)Wireless sensor networkDensity estimationMathematical optimizationAlgorithmRobotArtificial intelligenceMathematicsStatisticsEngineeringComputer networkEstimatorRadiologyGeometryMechanical engineeringBiologyMedicineEvolutionary biologyMathematical analysisDistributed Control Multi-Agent SystemsEnergy Efficient Wireless Sensor NetworksStability and Control of Uncertain Systems