Qualitative Possibilistic Mixed-Observable MDPs
This work addresses the computational complexity problem in decision-making under uncertainty for robotics applications, but it is incremental as it adapts an existing mixed-observable framework to a possibilistic setting.
The paper tackles the intractability of solving possibilistic POMDPs by introducing a possibilistic version of Mixed-Observable MDPs, which reduces complexity when some state variables are fully observable, and shows experimentally that this model outperforms probabilistic POMDPs in a target recognition problem with imprecise observations.
Possibilistic and qualitative POMDPs (pi-POMDPs) are counterparts of POMDPs used to model situations where the agent's initial belief or observation probabilities are imprecise due to lack of past experiences or insufficient data collection. However, like probabilistic POMDPs, optimally solving pi-POMDPs is intractable: the finite belief state space exponentially grows with the number of system's states. In this paper, a possibilistic version of Mixed-Observable MDPs is presented to get around this issue: the complexity of solving pi-POMDPs, some state variables of which are fully observable, can be then dramatically reduced. A value iteration algorithm for this new formulation under infinite horizon is next proposed and the optimality of the returned policy (for a specified criterion) is shown assuming the existence of a "stay" action in some goal states. Experimental work finally shows that this possibilistic model outperforms probabilistic POMDPs commonly used in robotics, for a target recognition problem where the agent's observations are imprecise.