We study Concave Constrained Markov Decision Processes (Concave CMDPs) where both the objective and constraints are defined as concave functions of the state-action occupancy measure. We propose the Variance-Reduced Primal-Dual Policy Gradient Algorithm (VR-PDPG), which updates the primal variable via policy gradient ascent and the dual variable via projected sub-gradient descent. Despite the challenges posed by the loss of additivity structure and the nonconcave nature of the problem, we establish the global convergence of VR-PDPG by exploiting a form of hidden concavity. In the exact setting, we prove an O(T−1/3) convergence rate for both the average optimality gap and constraint violation, which further improves to O(T−1/2) under strong concavity of the objective in the occupancy measure. In the sample-based setting, we demonstrate that VR-PDPG achieves an O(ϵ−4) sample complexity for ϵ-global optimality. Moreover, by incorporating a diminishing pessimistic term into the constraint, we show that VR-PDPG can attain a zero constraint violation without compromising the convergence rate of the optimality gap. Finally, we validate the effectiveness of our methods through numerical experiments.
@article{arxiv.2205.10715,
title = {Policy-based Primal-Dual Methods for Concave CMDP with Variance Reduction},
author = {Donghao Ying and Mengzi Amy Guo and Hyunin Lee and Yuhao Ding and Javad Lavaei and Zuo-Jun Max Shen},
journal= {arXiv preprint arXiv:2205.10715},
year = {2024}
}