Tight Regret Bounds for Noisy Optimization of a Brownian Motion
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We consider the problem of Bayesian optimization of a one-dimensional Brownian motion in which the T adaptively chosen observations are corrupted by Gaussian noise. We show that as the smallest possible expected simple regret and the smallest possible expected cumulative regret scale as Ω(1 / √(T log (T))) ∩O(log T / √(T)) and Ω(√(T / log (T))) ∩O(√(T)·log T) respectively. Thus, our upper and lower bounds are tight up to a factor of O( (log T)^1.5 ). The upper bound uses an algorithm based on confidence bounds and the Markov property of Brownian motion, and the lower bound is based on a reduction to binary hypothesis testing.
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