Near-Optimal Sample Complexity for Iterated CVaR Reinforcement Learning with a Generative Model
Abstract
In this work, we study the sample complexity problem of risk-sensitive Reinforcement Learning (RL) with a generative model, where we aim to maximize the Conditional Value at Risk (CVaR) with risk tolerance level τ at each step, a criterion we refer to as Iterated CVaR. We first build a connection between Iterated CVaR RL and (s, a)-rectangular distributional robust RL with a specific uncertainty set for CVaR. We establish nearly matching upper and lower bounds on the sample complexity of this problem. Specifically, we first prove that a value iteration-based algorithm, ICVaR-VI, achieves an ε-optimal policy with at most O (SA(1-γ)4τ2ε2 ) samples, where γ is the discount factor, and S, A are the sizes of the state and action spaces. Furthermore, when τ ≥ γ, the sample complexity improves to O ( SA(1-γ)3ε2 ). We further show a minimax lower bound of O ((1-γ τ)SA(1-γ)4τε2 ). For a fixed risk level τ ∈ (0,1], our upper and lower bounds match, demonstrating the tightness and optimality of our analysis. We also investigate a limiting case with a small risk level τ, called Worst-Path RL, where the objective is to maximize the minimum possible cumulative reward. We develop matching upper and lower bounds of O (SAp ), where p denotes the minimum non-zero reaching probability of the transition kernel.
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