Sharp Optimal Algorithm for Derivative-Free Stochastic Convex Optimization in One Dimension
Abstract
Stochastic convex optimization is a classical problem with well-understood guarantees under first-order feedback. In contrast, for zero-order optimization with noisy function evaluations, a logarithmic gap has persisted between known upper bounds and the Ω(1/T) lower bound, even in the one-dimensional case. In this work, we study the problem of minimizing a convex function f : [0,1] [0,1] using a zero-order oracle with subGaussian noise. We propose a computationally efficient algorithm that achieves the optimal O(1/T) convergence rate, matching the lower bound. The result closes the existing gap in one dimension, providing the first sharp rate guarantee in this setting.
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