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A Deterministic Gradient-Based Approach to Avoid Saddle Points

Machine Learning 2020-09-29 v2 Numerical Analysis Dynamical Systems Numerical Analysis Machine Learning

Abstract

Loss functions with a large number of saddle points are one of the major obstacles for training modern machine learning models efficiently. First-order methods such as gradient descent are usually the methods of choice for training machine learning models. However, these methods converge to saddle points for certain choices of initial guesses. In this paper, we propose a modification of the recently proposed Laplacian smoothing gradient descent [Osher et al., arXiv:1806.06317], called modified Laplacian smoothing gradient descent (mLSGD), and demonstrate its potential to avoid saddle points without sacrificing the convergence rate. Our analysis is based on the attraction region, formed by all starting points for which the considered numerical scheme converges to a saddle point. We investigate the attraction region's dimension both analytically and numerically. For a canonical class of quadratic functions, we show that the dimension of the attraction region for mLSGD is floor((n-1)/2), and hence it is significantly smaller than that of the gradient descent whose dimension is n-1.

Keywords

Cite

@article{arxiv.1901.06827,
  title  = {A Deterministic Gradient-Based Approach to Avoid Saddle Points},
  author = {Lisa Maria Kreusser and Stanley J. Osher and Bao Wang},
  journal= {arXiv preprint arXiv:1901.06827},
  year   = {2020}
}
R2 v1 2026-06-23T07:17:18.944Z