A proximal difference-of-convex algorithm with extrapolation

TL;DR

This paper introduces an accelerated proximal difference-of-convex algorithm with extrapolation, improving convergence speed for a class of DC optimization problems by leveraging extrapolation techniques inspired by FISTA.

Contribution

It proposes a novel accelerated proximal DCA with extrapolation, establishing convergence and demonstrating improved performance over existing methods.

Findings

The algorithm converges to stationary points under general conditions.

It outperforms traditional proximal DCA and iterative shrinkage algorithms in experiments.

The convergence rate is analyzed under the Kurdyka-{ extL}ojasiewicz property.

Abstract

We consider a class of difference-of-convex (DC) optimization problems whose objective is level-bounded and is the sum of a smooth convex function with Lipschitz gradient, a proper closed convex function and a continuous concave function. While this kind of problems can be solved by the classical difference-of-convex algorithm (DCA) [26], the difficulty of the subproblems of this algorithm depends heavily on the choice of DC decomposition. Simpler subproblems can be obtained by using a specific DC decomposition described in [27]. This decomposition has been proposed in numerous work such as [18], and we refer to the resulting DCA as the proximal DCA. Although the subproblems are simpler, the proximal DCA is the same as the proximal gradient algorithm when the concave part of the objective is void, and hence is potentially slow in practice. In this paper, motivated by the extrapolation techniques for accelerating the proximal gradient algorithm in the convex settings, we consider a proximal difference-of-convex algorithm with extrapolation to possibly accelerate the proximal DCA. We show that any cluster point of the sequence generated by our algorithm is a stationary point of the DC optimization problem for a fairly general choice of extrapolation parameters: in particular, the parameters can be chosen as in FISTA with fixed restart [15]. In addition, by assuming the Kurdyka-{\L}ojasiewicz property of the objective and the differentiability of the concave part, we establish global convergence of the sequence generated by our algorithm and analyze its convergence rate. Our numerical experiments on two difference-of-convex regularized least squares models show that our algorithm usually outperforms the proximal DCA and the general iterative shrinkage and thresholding algorithm proposed in [17].