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Weak Correlations as the Underlying Principle for Linearization of Gradient-Based Learning Systems

Machine Learning 2024-01-09 v1 Statistical Mechanics High Energy Physics - Theory Probability Machine Learning

Abstract

Deep learning models, such as wide neural networks, can be conceptualized as nonlinear dynamical physical systems characterized by a multitude of interacting degrees of freedom. Such systems in the infinite limit, tend to exhibit simplified dynamics. This paper delves into gradient descent-based learning algorithms, that display a linear structure in their parameter dynamics, reminiscent of the neural tangent kernel. We establish this apparent linearity arises due to weak correlations between the first and higher-order derivatives of the hypothesis function, concerning the parameters, taken around their initial values. This insight suggests that these weak correlations could be the underlying reason for the observed linearization in such systems. As a case in point, we showcase this weak correlations structure within neural networks in the large width limit. Exploiting the relationship between linearity and weak correlations, we derive a bound on deviations from linearity observed during the training trajectory of stochastic gradient descent. To facilitate our proof, we introduce a novel method to characterise the asymptotic behavior of random tensors.

Keywords

Cite

@article{arxiv.2401.04013,
  title  = {Weak Correlations as the Underlying Principle for Linearization of Gradient-Based Learning Systems},
  author = {Ori Shem-Ur and Yaron Oz},
  journal= {arXiv preprint arXiv:2401.04013},
  year   = {2024}
}

Comments

41 pages; 10 pages main tex; 0 figures

R2 v1 2026-06-28T14:11:25.105Z