FIG-OP: Exploring Large-Scale Unknown Environments on a Fixed Time Budget
Abstract
We present a method for autonomous exploration of large-scale unknown environments under mission time constraints. We start by proposing the Frontloaded Information Gain Orienteering Problem (FIG-OP) -- a generalization of the traditional orienteering problem where the assumption of a reliable environmental model no longer holds. The FIG-OP addresses model uncertainty by frontloading expected information gain through the addition of a greedy incentive, effectively expediting the moment in which new area is uncovered. In order to reason across multi-kilometre environments, we solve FIG-OP over an information-efficient world representation, constructed through the aggregation of information from a topological and metric map. Our method was extensively tested and field-hardened across various complex environments, ranging from subway systems to mines. In comparative simulations, we observe that the FIG-OP solution exhibits improved coverage efficiency over solutions generated by greedy and traditional orienteering-based approaches (i.e. severe and minimal model uncertainty assumptions, respectively).
Cite
@article{arxiv.2203.06316,
title = {FIG-OP: Exploring Large-Scale Unknown Environments on a Fixed Time Budget},
author = {Oriana Peltzer and Amanda Bouman and Sung-Kyun Kim and Ransalu Senanayake and Joshua Ott and Harrison Delecki and Mamoru Sobue and Mykel Kochenderfer and Mac Schwager and Joel Burdick and Ali-akbar Agha-mohammadi},
journal= {arXiv preprint arXiv:2203.06316},
year = {2022}
}
Comments
9 pages, 8 figures, 1 table