Variance-Aware Sparse Linear Bandits
Abstract
It is well-known that for sparse linear bandits, when ignoring the dependency on sparsity which is much smaller than the ambient dimension, the worst-case minimax regret is (dT) where d is the ambient dimension and T is the number of rounds. On the other hand, in the benign setting where there is no noise and the action set is the unit sphere, one can use divide-and-conquer to achieve O(1) regret, which is (nearly) independent of d and T. In this paper, we present the first variance-aware regret guarantee for sparse linear bandits: O(dΣt=1T σt2 + 1), where σt2 is the variance of the noise at the t-th round. This bound naturally interpolates the regret bounds for the worst-case constant-variance regime (i.e., σt (1)) and the benign deterministic regimes (i.e., σt 0). To achieve this variance-aware regret guarantee, we develop a general framework that converts any variance-aware linear bandit algorithm to a variance-aware algorithm for sparse linear bandits in a "black-box" manner. Specifically, we take two recent algorithms as black boxes to illustrate that the claimed bounds indeed hold, where the first algorithm can handle unknown-variance cases and the second one is more efficient.
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