Litcius/Paper detail

PLGRIM: Hierarchical Value Learning for Large-scale Exploration in Unknown Environments

Sung-Kyun Kim, Amanda Bouman, Gautam Salhotra, David D. Fan, Kyohei Otsu, Joel W. Burdick, Ali–akbar Agha–mohammadi

2021Proceedings of the International Conference on Automated Planning and Scheduling46 citationsDOIOpen Access PDF

Abstract

In order for an autonomous robot to efficiently explore an unknown environment, it must account for uncertainty in sensor measurements, hazard assessment, localization, and motion execution. Making decisions for maximal reward in a stochastic setting requires value learning and policy construction over a belief space, i.e., probability distribution over all possible robot-world states. However, belief space planning in a large spatial environment over long temporal horizons suffers from severe computational challenges. Moreover, constructed policies must safely adapt to unexpected changes in the belief at runtime. This work proposes a scalable value learning framework, PLGRIM (Probabilistic Local and Global Reasoning on Information roadMaps), that bridges the gap between (i) local, risk-aware resiliency and (ii) global, reward-seeking mission objectives. Leveraging hierarchical belief space planners with information-rich graph structures, PLGRIM addresses large-scale exploration problems while providing locally near-optimal coverage plans. We validate our proposed framework with high-fidelity dynamic simulations in diverse environments and on physical robots in Martian-analog lava tubes.

Topics & Concepts

Computer scienceScalabilityProbabilistic roadmapProbabilistic logicRobotFidelityArtificial intelligenceValue of informationMotion planningDistributed computingDatabaseTelecommunicationsDistributed systems and fault toleranceReinforcement Learning in RoboticsBayesian Modeling and Causal Inference