Optimal Learning Rate Scaling Depends on Data in Deep Scalar Linear Networks

Abstract

In this short note we consider the gradient descent dynamics of deep scalar linear networks, f(x) = Πl=1L wl x, which enjoy exact time-course solutions for any integer depth. We show that even in this minimal model, the optimal depth-wise learning rate scaling depends on data, whereas data-agnostic scaling rules fail to transfer across depths. Under the data-dependent optimal scaling, the learning dynamics is independent of data and weakly dependent on depth, resulting in a constant linear convergence rate across all depths including infinity. We further show similar data-dependent effects in deep scalar linear networks with residual connections.

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