English

Verifiable Reinforcement Learning Systems via Compositionality

Systems and Control 2023-09-13 v1 Artificial Intelligence Machine Learning Systems and Control

Abstract

We propose a framework for verifiable and compositional reinforcement learning (RL) in which a collection of RL subsystems, each of which learns to accomplish a separate subtask, are composed to achieve an overall task. The framework consists of a high-level model, represented as a parametric Markov decision process, which is used to plan and analyze compositions of subsystems, and of the collection of low-level subsystems themselves. The subsystems are implemented as deep RL agents operating under partial observability. By defining interfaces between the subsystems, the framework enables automatic decompositions of task specifications, e.g., reach a target set of states with a probability of at least 0.95, into individual subtask specifications, i.e. achieve the subsystem's exit conditions with at least some minimum probability, given that its entry conditions are met. This in turn allows for the independent training and testing of the subsystems. We present theoretical results guaranteeing that if each subsystem learns a policy satisfying its subtask specification, then their composition is guaranteed to satisfy the overall task specification. Conversely, if the subtask specifications cannot all be satisfied by the learned policies, we present a method, formulated as the problem of finding an optimal set of parameters in the high-level model, to automatically update the subtask specifications to account for the observed shortcomings. The result is an iterative procedure for defining subtask specifications, and for training the subsystems to meet them. Experimental results demonstrate the presented framework's novel capabilities in environments with both full and partial observability, discrete and continuous state and action spaces, as well as deterministic and stochastic dynamics.

Keywords

Cite

@article{arxiv.2309.06420,
  title  = {Verifiable Reinforcement Learning Systems via Compositionality},
  author = {Cyrus Neary and Aryaman Singh Samyal and Christos Verginis and Murat Cubuktepe and Ufuk Topcu},
  journal= {arXiv preprint arXiv:2309.06420},
  year   = {2023}
}

Comments

arXiv admin note: substantial text overlap with arXiv:2106.05864

R2 v1 2026-06-28T12:19:31.209Z