POMDPs under Probabilistic Semantics
This addresses theoretical computational complexity issues in control synthesis for POMDPs, which is incremental as it builds on prior work in decision processes and semantics.
The paper tackles the problem of computing almost-sure winning sets in partially observable Markov decision processes (POMDPs) with limit-average payoff under probabilistic semantics, showing that for qualitative constraints, finite-memory controller existence is EXPTIME-complete and infinite-memory controller existence is undecidable, while for quantitative constraints, finite-memory controller existence is undecidable.
We consider partially observable Markov decision processes (POMDPs) with limit-average payoff, where a reward value in the interval [0,1] is associated to every transition, and the payoff of an infinite path is the long-run average of the rewards. We consider two types of path constraints: (i) quantitative constraint defines the set of paths where the payoff is at least a given threshold lambda_1 in (0,1]; and (ii) qualitative constraint which is a special case of quantitative constraint with lambda_1=1. We consider the computation of the almost-sure winning set, where the controller needs to ensure that the path constraint is satisfied with probability 1. Our main results for qualitative path constraint are as follows: (i) the problem of deciding the existence of a finite-memory controller is EXPTIME-complete; and (ii) the problem of deciding the existence of an infinite-memory controller is undecidable. For quantitative path constraint we show that the problem of deciding the existence of a finite-memory controller is undecidable.