Width Provably Matters in Optimization for Deep Linear Neural Networks

Abstract

We prove that for an L-layer fully-connected linear neural network, if the width of every hidden layer is (L · r · dout · 3 ), where r and are the rank and the condition number of the input data, and dout is the output dimension, then gradient descent with Gaussian random initialization converges to a global minimum at a linear rate. The number of iterations to find an ε-suboptimal solution is O( (1ε)). Our polynomial upper bound on the total running time for wide deep linear networks and the ((L)) lower bound for narrow deep linear neural networks [Shamir, 2018] together demonstrate that wide layers are necessary for optimizing deep models.