English

Rethinking the Global Convergence of Softmax Policy Gradient with Linear Function Approximation

Machine Learning 2025-05-07 v1

Abstract

Policy gradient (PG) methods have played an essential role in the empirical successes of reinforcement learning. In order to handle large state-action spaces, PG methods are typically used with function approximation. In this setting, the approximation error in modeling problem-dependent quantities is a key notion for characterizing the global convergence of PG methods. We focus on Softmax PG with linear function approximation (referred to as Lin-SPG\texttt{Lin-SPG}) and demonstrate that the approximation error is irrelevant to the algorithm's global convergence even for the stochastic bandit setting. Consequently, we first identify the necessary and sufficient conditions on the feature representation that can guarantee the asymptotic global convergence of Lin-SPG\texttt{Lin-SPG}. Under these feature conditions, we prove that TT iterations of Lin-SPG\texttt{Lin-SPG} with a problem-specific learning rate result in an O(1/T)O(1/T) convergence to the optimal policy. Furthermore, we prove that Lin-SPG\texttt{Lin-SPG} with any arbitrary constant learning rate can ensure asymptotic global convergence to the optimal policy.

Keywords

Cite

@article{arxiv.2505.03155,
  title  = {Rethinking the Global Convergence of Softmax Policy Gradient with Linear Function Approximation},
  author = {Max Qiushi Lin and Jincheng Mei and Matin Aghaei and Michael Lu and Bo Dai and Alekh Agarwal and Dale Schuurmans and Csaba Szepesvari and Sharan Vaswani},
  journal= {arXiv preprint arXiv:2505.03155},
  year   = {2025}
}

Comments

75 pages

R2 v1 2026-06-28T23:22:23.626Z