Risk-Sensitive Reinforcement Learning: Near-Optimal Risk-Sample Tradeoff in Regret

We study risk-sensitive reinforcement learning in episodic Markov decision processes with unknown transition kernels, where the goal is to optimize the total reward under the risk measure of exponential utility. We propose two provably efficient model-free algorithms, Risk-Sensitive Value Iteration (RSVI) and Risk-Sensitive Q-learning (RSQ). These algorithms implement a form of risk-sensitive optimism in the face of uncertainty, which adapts to both risk-seeking and risk-averse modes of exploration. In the above, \beta is the risk parameter of the exponential utility function, S the number of states, A the number of actions, T the total number of timesteps, and H the episode length. On the flip side, we establish a regret lower bound showing that the exponential dependence on \beta and H is unavoidable for any algorithm with an \tilde{O}(\sqrt{T}) regret (even when the risk objective is on the same scale as the original reward), thus certifying the near-optimality of the proposed algorithms.