Litcius/Paper detail

Sampling-based incremental information gathering with applications to robotic exploration and environmental monitoring

Maani Ghaffari, Jaime Valls Miró, Gamini Dissanayake

2020UTS ePRESS (University of Technology Sydney)55 citationsOpen Access PDF

Abstract

© The Author(s) 2019. We propose a sampling-based motion-planning algorithm equipped with an information-theoretic convergence criterion for incremental informative motion planning. The proposed approach allows dense map representations and incorporates the full state uncertainty into the planning process. The problem is formulated as a constrained maximization problem. Our approach is built on rapidly exploring information-gathering algorithms and benefits from the advantages of sampling-based optimal motion-planning algorithms. We propose two information functions and their variants for fast and online computations. We prove an information-theoretic convergence for an entire exploration and information-gathering mission based on the least upper bound of the average map entropy. A natural automatic stopping criterion for information-driven motion control results from the convergence analysis. We demonstrate the performance of the proposed algorithms using three scenarios: comparison of the proposed information functions and sensor configuration selection, robotic exploration in unknown environments, and a wireless signal strength monitoring task in a lake from a publicly available dataset collected using an autonomous surface vehicle.

Topics & Concepts

Computer scienceMotion planningConvergence (economics)Sampling (signal processing)Mutual informationEntropy (arrow of time)MaximizationArtificial intelligenceInformation theoryMathematical optimizationData miningMachine learningRobotComputer visionMathematicsPhysicsEconomic growthEconomicsQuantum mechanicsStatisticsFilter (signal processing)Robotic Path Planning AlgorithmsDistributed Control Multi-Agent SystemsUnderwater Vehicles and Communication Systems
Sampling-based incremental information gathering with applications to robotic exploration and environmental monitoring | Litcius