Non-ergodic convergence rate of an inertial accelerated primal-dual algorithm for saddle point problems

Abstract

In this paper, we design an inertial accelerated primal-dual algorithm to address the convex-concave saddle point problem, which is formulated as xy f(x) + Kx, y - g(y). Remarkably, both functions f and g exhibit a composite structure, combining ``nonsmooth'' + ``smooth'' components. Under the assumption of partially strong convexity in the sense that f is convex and g is strongly convex, we introduce a novel inertial accelerated primal-dual algorithm based on Nesterov's extrapolation. This algorithm can be reduced to two classical accelerated forward-backward methods for unconstrained optimization problem. We show that the proposed algorithm achieves a non-ergodic O(1/k2) convergence rate, where k represents the number of iterations. Several numerical experiments validate the efficiency of our proposed algorithm.

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