Adaptive Extrapolated Proximal Gradient Methods with Variance Reduction for Composite Nonconvex Finite-Sum Minimization
Abstract
This paper proposes AEPG-SPIDER, an Adaptive Extrapolated Proximal Gradient (AEPG) method with variance reduction for minimizing composite nonconvex finite-sum functions. It integrates three acceleration techniques: adaptive stepsizes, Nesterov's extrapolation, and the recursive stochastic path-integrated estimator SPIDER. Unlike existing methods that adjust the stepsize factor using historical gradients, AEPG-SPIDER relies on past iterate differences for its update. While targeting stochastic finite-sum problems, AEPG-SPIDER simplifies to AEPG in the full-batch, non-stochastic setting, which is also of independent interest. To our knowledge, AEPG-SPIDER and AEPG are the first Lipschitz-free methods to achieve optimal iteration complexity for this class of composite minimization problems. Specifically, AEPG achieves the optimal iteration complexity of O(N ε-2), while AEPG-SPIDER achieves O(N + N ε-2) for finding ε-approximate stationary points, where N is the number of component functions. Under the Kurdyka-Lojasiewicz (KL) assumption, we establish non-ergodic convergence rates for both methods. Preliminary experiments on sparse phase retrieval and linear eigenvalue problems demonstrate the superior performance of AEPG-SPIDER and AEPG compared to existing methods.
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