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Information Theoretic Limits of Data Shuffling for Distributed Learning

Information Theory 2016-09-19 v1 Distributed, Parallel, and Cluster Computing Machine Learning math.IT

Abstract

Data shuffling is one of the fundamental building blocks for distributed learning algorithms, that increases the statistical gain for each step of the learning process. In each iteration, different shuffled data points are assigned by a central node to a distributed set of workers to perform local computations, which leads to communication bottlenecks. The focus of this paper is on formalizing and understanding the fundamental information-theoretic trade-off between storage (per worker) and the worst-case communication overhead for the data shuffling problem. We completely characterize the information theoretic trade-off for K=2K=2, and K=3K=3 workers, for any value of storage capacity, and show that increasing the storage across workers can reduce the communication overhead by leveraging coding. We propose a novel and systematic data delivery and storage update strategy for each data shuffle iteration, which preserves the structural properties of the storage across the workers, and aids in minimizing the communication overhead in subsequent data shuffling iterations.

Keywords

Cite

@article{arxiv.1609.05181,
  title  = {Information Theoretic Limits of Data Shuffling for Distributed Learning},
  author = {Mohamed Attia and Ravi Tandon},
  journal= {arXiv preprint arXiv:1609.05181},
  year   = {2016}
}

Comments

To be presented at IEEE GLOBECOM, December 2016

R2 v1 2026-06-22T15:52:24.543Z