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Data-Importance Aware User Scheduling for Communication-Efficient Edge Machine Learning

Networking and Internet Architecture 2019-10-08 v1 Information Theory math.IT

Abstract

With the prevalence of intelligent mobile applications, edge learning is emerging as a promising technology for powering fast intelligence acquisition for edge devices from distributed data generated at the network edge. One critical task of edge learning is to efficiently utilize the limited radio resource to acquire data samples for model training at an edge server. In this paper, we develop a novel user scheduling algorithm for data acquisition in edge learning, called (data) importance-aware scheduling. A key feature of this scheduling algorithm is that it takes into account the informativeness of data samples, besides communication reliability. Specifically, the scheduling decision is based on a data importance indicator (DII), elegantly incorporating two "important" metrics from communication and learning perspectives, i.e., the signal-to-noise ratio (SNR) and data uncertainty. We first derive an explicit expression for this indicator targeting the classic classifier of support vector machine (SVM), where the uncertainty of a data sample is measured by its distance to the decision boundary. Then, the result is extended to convolutional neural networks (CNN) by replacing the distance based uncertainty measure with the entropy. As demonstrated via experiments using real datasets, the proposed importance-aware scheduling can exploit the two-fold multi-user diversity, namely the diversity in both the multiuser channels and the distributed data samples. This leads to faster model convergence than the conventional scheduling schemes that exploit only a single type of diversity.

Keywords

Cite

@article{arxiv.1910.02214,
  title  = {Data-Importance Aware User Scheduling for Communication-Efficient Edge Machine Learning},
  author = {Dongzhu Liu and Guangxu Zhu and Jun Zhang and Kaibin Huang},
  journal= {arXiv preprint arXiv:1910.02214},
  year   = {2019}
}

Comments

30 pages

R2 v1 2026-06-23T11:35:11.123Z