English

Synthesizing POMDP Policies: Sampling Meets Model-checking via Learning

Artificial Intelligence 2026-05-15 v1 Formal Languages and Automata Theory Logic in Computer Science

Abstract

Partially Observable Markov Decision Processes (POMDPs) are the standard framework for decision-making under uncertainty. While sampling-based methods scale well, they lack formal correctness guarantees, making them unsuitable for safety-critical applications. Conversely, formal synthesis techniques provide correctness-by-construction but often struggle with scalability, as general POMDP synthesis is undecidable. To bridge this gap, we propose a synthesis framework that integrates sampling, automata learning, and model-checking. Inspired by Angluin's LL^* algorithm, our approach utilizes sampling as a membership oracle and model-checking as an equivalence oracle. This enables the synthesis of finite-state controllers with formal guarantees, provided the sampling-induced policy is regular. We establish a relative completeness result for this framework. Experimental results from our prototypical implementation demonstrate that this method successfully solves threshold-safety problems that remain challenging for existing formal synthesis tools. We believe our algorithm serves as a valuable component in a portfolio approach to tackling the inherent difficulty of POMDP synthesis problems.

Keywords

Cite

@article{arxiv.2605.14440,
  title  = {Synthesizing POMDP Policies: Sampling Meets Model-checking via Learning},
  author = {Debraj Chakraborty and Anirban Majumdar and Prince Mathew and Sayan Mukherjee and Jean-François Raskin},
  journal= {arXiv preprint arXiv:2605.14440},
  year   = {2026}
}

Comments

Paper accepted at 38th International Conference on Computer Aided Verification (CAV 2026), Lisbon, Portugal, July 2026