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Global Convergence in Training Large-Scale Transformers

Machine Learning 2024-11-01 v1 Machine Learning Statistics Theory Statistics Theory

Abstract

Despite the widespread success of Transformers across various domains, their optimization guarantees in large-scale model settings are not well-understood. This paper rigorously analyzes the convergence properties of gradient flow in training Transformers with weight decay regularization. First, we construct the mean-field limit of large-scale Transformers, showing that as the model width and depth go to infinity, gradient flow converges to the Wasserstein gradient flow, which is represented by a partial differential equation. Then, we demonstrate that the gradient flow reaches a global minimum consistent with the PDE solution when the weight decay regularization parameter is sufficiently small. Our analysis is based on a series of novel mean-field techniques that adapt to Transformers. Compared with existing tools for deep networks (Lu et al., 2020) that demand homogeneity and global Lipschitz smoothness, we utilize a refined analysis assuming only partial homogeneity\textit{partial homogeneity} and local Lipschitz smoothness\textit{local Lipschitz smoothness}. These new techniques may be of independent interest.

Keywords

Cite

@article{arxiv.2410.23610,
  title  = {Global Convergence in Training Large-Scale Transformers},
  author = {Cheng Gao and Yuan Cao and Zihao Li and Yihan He and Mengdi Wang and Han Liu and Jason Matthew Klusowski and Jianqing Fan},
  journal= {arXiv preprint arXiv:2410.23610},
  year   = {2024}
}

Comments

to be published in 38th Conference on Neural Information Processing Systems (NeurIPS 2024)

R2 v1 2026-06-28T19:42:21.839Z