Last-Iterate Analyses of FTRL with the 1/2-Tsallis Entropy in Stochastic Bandits
Abstract
The convergence analysis of online learning algorithms is central to machine learning theory, where the last-iterate convergence is particularly important, as it captures the learner's actual decisions and describes the evolution of the learning process over time. However, in multi-armed bandits, most existing algorithmic analyses mainly focus on the order of regret, while the last-iterate (simple regret) convergence rate remains less explored -- especially for the widely studied Follow-the-Regularized-Leader (FTRL) algorithms. Recently, FTRL with the 1/2-Tsallis entropy regularizer (p) = -4Σi=1d pi (the 1/2-Tsallis-INF algorithm, by arXiv:1807.07623) was shown to achieve logarithmic regret in stochastic bandits. Nevertheless, its last-iterate convergence rate has not yet been studied. Intuitively, logarithmic regret should correspond to a t-1 last-iterate convergence rate. This paper studies the 1/2-Tsallis-INF algorithm and partially confirms this intuition through theoretical analysis, showing that the Bregman divergence, defined by (p), between the point mass on the optimal arm and the probability distribution over the arm set obtained at iteration t, decays at a rate of t-1/2.
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