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Stochastic Linear Bandits with Parameter Noise

Machine Learning 2026-05-26 v2

Abstract

We study the stochastic linear bandits with parameter noise model, in which the reward of action aa is aθa^\top \theta where θ\theta is sampled i.i.d. We show a regret upper bound of O~(dTlog(K/δ)σmax2)\widetilde{O} (\sqrt{d T \log (K/\delta) \sigma^2_{\max})} for a horizon TT, general action set of size KK of dimension dd, and where σmax2\sigma^2_{\max} is the maximal variance of the reward for any action. We further provide a lower bound of Ω~(dTσmax2)\widetilde{\Omega} (d \sqrt{T \sigma^2_{\max}}) which is tight (up to logarithmic factors) whenever log(K)d\log (K) \approx d. For more specific action sets, p\ell_p unit balls with p2p \leq 2 and dual norm qq, we show that the minimax regret is Θ~(dTσq2)\widetilde{\Theta} (\sqrt{dT \sigma^2_q)}, where σq2\sigma^2_q is a variance-dependent quantity that is always at most 44. This is in contrast to the minimax regret attainable for such sets in the classic additive noise model, where the regret is of order dTd \sqrt{T}. Surprisingly, we show that this optimal (up to logarithmic factors) regret bound is attainable using a very simple explore-exploit algorithm.

Keywords

Cite

@article{arxiv.2601.23164,
  title  = {Stochastic Linear Bandits with Parameter Noise},
  author = {Daniel Ezer and Alon Peled-Cohen and Yishay Mansour},
  journal= {arXiv preprint arXiv:2601.23164},
  year   = {2026}
}

Comments

8 pages

R2 v1 2026-07-01T09:28:03.531Z