Abstract
Information gathering (IG) algorithms aim to intelligently select a mobile sensor actions required to efficiently obtain an accurate reconstruction of a physical process, such as an occupancy map, or a magnetic field. Many recent works have proposed algorithms for IG that employ Gaussian processes (GPs) as underlying model of the process. However, most algorithms discretize the state space, which makes them computationally intractable for robotic systems with complex dynamics. Moreover, they are not suited for online information gathering tasks as they assume prior knowledge about GP parameters. This paper presents a novel approach that tackles the two aforementioned issues. Specifically, our approach includes two intertwined steps: (i) a Rapidly-Exploring Random Tree (RRT) search that allows a robot to identify unvisited locations, and to learn the GP parameters, and (ii) an RRT*-based informative path planning that guides the robot towards those locations by maximizing the information gathered while minimizing path cost. The combination of the two steps allows an online realization of the algorithm, while eliminating the need for discretization. We demonstrate that our proposed algorithm outperforms state-of-the-art both in simulations, and in a lab experiment in which a ground-based robot explores the magnetic field intensity within an indoor environment populated with obstacles.
Highlights
Information gathering (IG) is a fundamental task in a wide range of robotic applications such as environmental monitoring [1], or magnetic field intensity mapping [2]
Our work addresses a similar problem as Ref. [25] but it differs in two principal aspects: (i) our algorithm does not require prior information of the physical process, which, in contrast to Ref. [25], allows an online realization of the algorithm; (ii) our algorithm introduces a trade-off between information gathering and a cost of a particular selected path
We show the estimation of the process, the entropy of the process model, and the tree that was produced by the robot to plan a path toward the station
Summary
Information gathering (IG) is a fundamental task in a wide range of robotic applications such as environmental monitoring [1], or magnetic field intensity mapping [2]. The objective is to collect information efficiently by deciding on the actions of a robot—a mobile sensor, while optimizing the resources employed, e.g., available energy or time. This may be economically advantageous or even life-critical in search and rescue missions. An underlying model of the physical process under study is employed. By modeling spatial variations of the physical process, we can fill spatial gaps between measurements using interpolation or extrapolation [3]. The stronger the correlations and the better they are represented in a model, the fewer measurements are needed to achieve a certain reconstruction accuracy. The use of a model together with some information metric (e.g., expected uncertainty reduction or future information gain) allows a robot to predict the impact of certain robot
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