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Parallel Momentum Methods Under Biased Gradient Estimations

Machine Learning 2025-01-14 v3

Abstract

Parallel stochastic gradient methods are gaining prominence in solving large-scale machine learning problems that involve data distributed across multiple nodes. However, obtaining unbiased stochastic gradients, which have been the focus of most theoretical research, is challenging in many distributed machine learning applications. The gradient estimations easily become biased, for example, when gradients are compressed or clipped, when data is shuffled, and in meta-learning and reinforcement learning. In this work, we establish worst-case bounds on parallel momentum methods under biased gradient estimation on both general non-convex and μ\mu-PL problems. Our analysis covers general distributed optimization problems, and we work out the implications for special cases where gradient estimates are biased, i.e. in meta-learning and when the gradients are compressed or clipped. Our numerical experiments verify our theoretical findings and show faster convergence performance of momentum methods than traditional biased gradient descent.

Keywords

Cite

@article{arxiv.2403.00853,
  title  = {Parallel Momentum Methods Under Biased Gradient Estimations},
  author = {Ali Beikmohammadi and Sarit Khirirat and Sindri Magnússon},
  journal= {arXiv preprint arXiv:2403.00853},
  year   = {2025}
}

Comments

12 pages

R2 v1 2026-06-28T15:06:29.945Z