Minimum Empirical Divergence for Sub-Gaussian Linear Bandits
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We propose a novel linear bandit algorithm called LinMED (Linear Minimum Empirical Divergence), which is a linear extension of the MED algorithm that was originally designed for multi-armed bandits. LinMED is a randomized algorithm that admits a closed-form computation of the arm sampling probabilities, unlike the popular randomized algorithm called linear Thompson sampling. Such a feature proves useful for off-policy evaluation where the unbiased evaluation requires accurately computing the sampling probability. We prove that LinMED enjoys a near-optimal regret bound of $d\sqrt{n}$ up to logarithmic factors where $d$ is the dimension and $n$ is the time horizon. We further show that LinMED enjoys a $\frac{d^2}{\Delta}\left(\log^2(n)\right)\log\left(\log(n)\right)$ problem-dependent regret where $\Delta$ is the smallest sub-optimality gap. Our empirical study shows that LinMED has a competitive performance with the state-of-the-art algorithms.
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Bandits for Efficient Experimentation: Adapting to Control Group, Preferences, and Context Drifts
Dri-MED achieves Õ(κ d² log T / Δ̃) regret and Õ(d) constraint violations for drifting contextual bandits with personalized preferences and baseline constraints under practitioner-friendly assumptions.
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