Finite-Sum Smooth Optimization with SARAH

Abstract

The total complexity (measured as the total number of gradient computations) of a stochastic first-order optimization algorithm that finds a first-order stationary point of a finite-sum smooth nonconvex objective function F(w)=1n Σi=1n fi(w) has been proven to be at least (n/ε) for n ≤ O(ε-2) where ε denotes the attained accuracy E[ \|∇ F(w)\|2] ≤ ε for the outputted approximation w (Fang et al., 2018). In this paper, we provide a convergence analysis for a slightly modified version of the SARAH algorithm (Nguyen et al., 2017a;b) and achieve total complexity that matches the lower-bound worst case complexity in (Fang et al., 2018) up to a constant factor when n ≤ O(ε-2) for nonconvex problems. For convex optimization, we propose SARAH++ with sublinear convergence for general convex and linear convergence for strongly convex problems; and we provide a practical version for which numerical experiments on various datasets show an improved performance.