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Information-Theoretic Generalization Bounds for Sequential Decision Making

Machine Learning 2026-05-13 v1 Machine Learning

Abstract

Information-theoretic generalization bounds based on the supersample construction are a central tool for algorithm-dependent generalization analysis in the batch i.i.d.~setting. However, existing supersample conditional mutual information (CMI) bounds do not directly apply to sequential decision-making problems such as online learning, streaming active learning, and bandits, where data are revealed adaptively and the learner evolves along a causal trajectory. To address this limitation, we develop a sequential supersample framework that separates the learner filtration from a proof-side enlargement used for ghost-coordinate comparisons. Under a row-wise exchangeability assumption, the sequential generalization gap is controlled by sequential CMI, a sum of roundwise selector--loss information terms. We also establish a Bernstein-type refinement that yields faster rates under suitable variance conditions. The selector-SCMI proof strategy applies to online learning, streaming active learning with importance weighting, and stochastic multi-armed bandits.

Keywords

Cite

@article{arxiv.2605.12190,
  title  = {Information-Theoretic Generalization Bounds for Sequential Decision Making},
  author = {Futoshi Futami and Masahiro Fujisawa},
  journal= {arXiv preprint arXiv:2605.12190},
  year   = {2026}
}