Tractable Optimality in Episodic Latent MABs
This work addresses the problem of efficient reinforcement learning in partially observable environments for researchers and practitioners, offering a novel theoretical and practical advancement over prior exponential bounds.
The paper tackles the challenge of learning near-optimal policies in episodic latent multi-armed bandits with partial observability, achieving polynomial sample complexity in the number of actions and demonstrating significant practical performance improvements over existing methods.
We consider a multi-armed bandit problem with $M$ latent contexts, where an agent interacts with the environment for an episode of $H$ time steps. Depending on the length of the episode, the learner may not be able to estimate accurately the latent context. The resulting partial observation of the environment makes the learning task significantly more challenging. Without any additional structural assumptions, existing techniques to tackle partially observed settings imply the decision maker can learn a near-optimal policy with $O(A)^H$ episodes, but do not promise more. In this work, we show that learning with {\em polynomial} samples in $A$ is possible. We achieve this by using techniques from experiment design. Then, through a method-of-moments approach, we design a procedure that provably learns a near-optimal policy with $O(\texttt{poly}(A) + \texttt{poly}(M,H)^{\min(M,H)})$ interactions. In practice, we show that we can formulate the moment-matching via maximum likelihood estimation. In our experiments, this significantly outperforms the worst-case guarantees, as well as existing practical methods.