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Tail-Aware Information-Theoretic Generalization for RLHF and SGLD

Machine Learning 2026-04-14 v1 Artificial Intelligence Machine Learning Probability Statistics Theory Statistics Theory

Abstract

Classical information-theoretic generalization bounds typically control the generalization gap through KL-based mutual information and therefore rely on boundedness or sub-Gaussian tails via the moment generating function (MGF). In many modern pipelines, such as robust learning, RLHF, and stochastic optimization, losses and rewards can be heavy-tailed, and MGFs may not exist, rendering KL-based tools ineffective. We develop a tail-dependent information-theoretic framework for sub-Weibull data, where the tail parameter θ\theta controls the tail heaviness: θ=2\theta=2 corresponds to sub-Gaussian, θ=1\theta=1 to sub-exponential, and 0<θ<10<\theta<1 to genuinely heavy tails. Our key technical ingredient is a decorrelation lemma that bounds change-of-measure expectations using a shifted-log fθf_\theta-divergence, which admits explicit comparisons to R\'enyi divergence without MGF arguments. On the empirical-process side, we establish sharp maximal inequalities and a Dudley-type chaining bound for sub-Weibull processes with tail index θ\theta, with complexity scaling as log1/θ\log^{1/\theta} and entropy1/θ^{1/\theta}. These tools yield expected and high-probability PAC-Bayes generalization bounds, as well as an information-theoretic chaining inequality based on multiscale R\'enyi mutual information. We illustrate the consequences in R\'enyi-regularized RLHF under heavy-tailed rewards and in stochastic gradient Langevin dynamics with heavy-tailed gradient noise.

Keywords

Cite

@article{arxiv.2604.10727,
  title  = {Tail-Aware Information-Theoretic Generalization for RLHF and SGLD},
  author = {Huiming Zhang and Binghan Li and Wan Tian and Qiang Sun},
  journal= {arXiv preprint arXiv:2604.10727},
  year   = {2026}
}

Comments

65 pages, 9 figures

R2 v1 2026-07-01T12:05:10.956Z