A Superlinear Convergence Framework for Kurdyka-ojasiewicz Optimization

Abstract

This work extends the iterative framework proposed by Attouch et al. (in Math. Program. 137: 91-129, 2013) for minimizing a nonconvex and nonsmooth function so that the generated sequence possesses a Q-superlinear convergence rate. This framework consists of a monotone decrease condition, a relative error condition and a continuity condition, and the first two conditions both involve a parameter p\!>0. We justify that any sequence conforming to this framework is globally convergent when is a Kurdyka-ojasiewicz (KL) function, and the convergence has a Q-superlinear rate of order pθ(1+p) when is a KL function of exponent θ∈(0,pp+1). Then, we illustrate that the iterate sequence generated by an inexact q∈[2,3]-order regularization method for composite optimization problems with a nonconvex and nonsmooth term belongs to this framework, and consequently, first achieve the Q-superlinear convergence rate of order 4/3 for an inexact cubic regularization method to solve this class of composite problems with KL property of exponent 1/2.