English

Improved Information Theoretic Generalization Bounds for Distributed and Federated Learning

Information Theory 2024-01-17 v2 Machine Learning math.IT

Abstract

We consider information-theoretic bounds on expected generalization error for statistical learning problems in a networked setting. In this setting, there are KK nodes, each with its own independent dataset, and the models from each node have to be aggregated into a final centralized model. We consider both simple averaging of the models as well as more complicated multi-round algorithms. We give upper bounds on the expected generalization error for a variety of problems, such as those with Bregman divergence or Lipschitz continuous losses, that demonstrate an improved dependence of 1/K1/K on the number of nodes. These "per node" bounds are in terms of the mutual information between the training dataset and the trained weights at each node, and are therefore useful in describing the generalization properties inherent to having communication or privacy constraints at each node.

Keywords

Cite

@article{arxiv.2202.02423,
  title  = {Improved Information Theoretic Generalization Bounds for Distributed and Federated Learning},
  author = {L. P. Barnes and Alex Dytso and H. V. Poor},
  journal= {arXiv preprint arXiv:2202.02423},
  year   = {2024}
}

Comments

This version of the paper adds an assumption that was missing from Theorem 4 for loss functions of type (i). Thanks to Peyman Gholami for spotting this bug

R2 v1 2026-06-24T09:21:10.147Z