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Linear bandits with polylogarithmic minimax regret

Machine Learning 2025-10-28 v2 Artificial Intelligence Machine Learning

Abstract

We study a noise model for linear stochastic bandits for which the subgaussian noise parameter vanishes linearly as we select actions on the unit sphere closer and closer to the unknown vector. We introduce an algorithm for this problem that exhibits a minimax regret scaling as log3(T)\log^3(T) in the time horizon TT, in stark contrast the square root scaling of this regret for typical bandit algorithms. Our strategy, based on weighted least-squares estimation, achieves the eigenvalue relation λmin(Vt)=Ω(λmax(Vt))\lambda_{\min} ( V_t ) = \Omega (\sqrt{\lambda_{\max}(V_t ) }) for the design matrix VtV_t at each time step tt through geometrical arguments that are independent of the noise model and might be of independent interest. This allows us to tightly control the expected regret in each time step to be of the order O(1t)O(\frac1{t}), leading to the logarithmic scaling of the cumulative regret.

Keywords

Cite

@article{arxiv.2402.12042,
  title  = {Linear bandits with polylogarithmic minimax regret},
  author = {Josep Lumbreras and Marco Tomamichel},
  journal= {arXiv preprint arXiv:2402.12042},
  year   = {2025}
}

Comments

39 pages, 3 figures

R2 v1 2026-06-28T14:52:59.473Z