A stochastic first-order method with multi-extrapolated momentum for highly smooth unconstrained optimization
Abstract
In this paper, we consider an unconstrained stochastic optimization problem where the objective function exhibits high-order smoothness. Specifically, we propose a new stochastic first-order method (SFOM) with multi-extrapolated momentum, in which multiple extrapolations are performed in each iteration, followed by a momentum update based on these extrapolations. We demonstrate that the proposed SFOM can accelerate optimization by exploiting the high-order smoothness of the objective function f. Assuming that the pth-order derivative of f is Lipschitz continuous for some p2, and under additional mild assumptions, we establish that our method achieves a sample complexity of O(ε-(3p+1)/p) for finding a point x such that E[\|∇ f(x)\|]ε. To the best of our knowledge, this is the first SFOM to leverage arbitrary-order smoothness of the objective function for acceleration, resulting in a sample complexity that improves upon the best-known results without assuming the mean-squared smoothness condition. Preliminary numerical experiments validate the practical performance of our method and support our theoretical findings.
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