Cubic Regularized Newton Method with Variance Reduction for Finite-sum Non-convex Problems

Abstract

We study finite-sum non-convex optimization x∈Rd F(x) \;=\; 1nΣi=1n fi(x) and analyze a variance-reduced cubic Newton method based on EMA-smoothed SARAH estimators for both gradient and Hessian information. The method combines a coarse stochastic backbone with a terminal homotopy refinement: once the iterates enter a certified small-step regime, the algorithm decreases the regularization level geometrically, shortens the stage length, and increases the mini-batch size at the reciprocal rate while restarting exact finite-sum snapshots at each stage. We work under average squared gradient smoothness and average mean-cubed Hessian smoothness, thereby avoiding the trajectory-wise Hessian boundedness assumption that is often used in related analyses. Under these assumptions and a standard inexact cubic-subproblem certificate, we establish that the method returns an (,L2)-second-order stationary point with total finite-sum oracle complexity n+ O\!(n1/2-3/2). The analysis separates into a coarse progress phase, which yields the n1/2-scaled stochastic backbone, and a terminal local bootstrap, which supplies the pointwise accuracy needed to turn the model step certificate into a true second-order certificate.

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