Bandits with many optimal arms

Abstract

We consider a stochastic bandit problem with a possibly infinite number of arms. We write p* for the proportion of optimal arms and for the minimal mean-gap between optimal and sub-optimal arms. We characterize the optimal learning rates both in the cumulative regret setting, and in the best-arm identification setting in terms of the problem parameters T (the budget), p* and . For the objective of minimizing the cumulative regret, we provide a lower bound of order ((T)/(p*)) and a UCB-style algorithm with matching upper bound up to a factor of (1/). Our algorithm needs p* to calibrate its parameters, and we prove that this knowledge is necessary, since adapting to p* in this setting is impossible. For best-arm identification we also provide a lower bound of order ((-cT2 p*)) on the probability of outputting a sub-optimal arm where c>0 is an absolute constant. We also provide an elimination algorithm with an upper bound matching the lower bound up to a factor of order (T) in the exponential, and that does not need p* or as parameter. Our results apply directly to the three related problems of competing against the j-th best arm, identifying an ε good arm, and finding an arm with mean larger than a quantile of a known order.