Weathering Ongoing Uncertainty: Learning and Planning in a Time-Varying Partially Observable Environment
This work addresses decision-making challenges for autonomous systems in dynamic, uncertain environments, representing an incremental advancement by combining existing concepts with partial observability.
The paper tackles the problem of optimal decision-making in uncertain, time-varying, and partially observable environments by introducing Time-Varying Partially Observable Markov Decision Processes (TV-POMDP) and proposing a two-pronged approach for estimation and planning. The results demonstrate superior performance over standard methods in simulations and hardware experiments.
Optimal decision-making presents a significant challenge for autonomous systems operating in uncertain, stochastic and time-varying environments. Environmental variability over time can significantly impact the system's optimal decision making strategy for mission completion. To model such environments, our work combines the previous notion of Time-Varying Markov Decision Processes (TVMDP) with partial observability and introduces Time-Varying Partially Observable Markov Decision Processes (TV-POMDP). We propose a two-pronged approach to accurately estimate and plan within the TV-POMDP: 1) Memory Prioritized State Estimation (MPSE), which leverages weighted memory to provide more accurate time-varying transition estimates; and 2) an MPSE-integrated planning strategy that optimizes long-term rewards while accounting for temporal constraint. We validate the proposed framework and algorithms using simulations and hardware, with robots exploring a partially observable, time-varying environments. Our results demonstrate superior performance over standard methods, highlighting the framework's effectiveness in stochastic, uncertain, time-varying domains.