Escaping From Saddle Points --- Online Stochastic Gradient for Tensor Decomposition
Abstract
We analyze stochastic gradient descent for optimizing non-convex functions. In many cases for non-convex functions the goal is to find a reasonable local minimum, and the main concern is that gradient updates are trapped in saddle points. In this paper we identify strict saddle property for non-convex problem that allows for efficient optimization. Using this property we show that stochastic gradient descent converges to a local minimum in a polynomial number of iterations. To the best of our knowledge this is the first work that gives global convergence guarantees for stochastic gradient descent on non-convex functions with exponentially many local minima and saddle points. Our analysis can be applied to orthogonal tensor decomposition, which is widely used in learning a rich class of latent variable models. We propose a new optimization formulation for the tensor decomposition problem that has strict saddle property. As a result we get the first online algorithm for orthogonal tensor decomposition with global convergence guarantee.
Cite
@article{arxiv.1503.02101,
title = {Escaping From Saddle Points --- Online Stochastic Gradient for Tensor Decomposition},
author = {Rong Ge and Furong Huang and Chi Jin and Yang Yuan},
journal= {arXiv preprint arXiv:1503.02101},
year = {2015}
}