Inexact Proximal-Point Penalty Methods for Constrained Non-Convex Optimization
Abstract
In this paper, an inexact proximal-point penalty method is studied for constrained optimization problems, where the objective function is non-convex, and the constraint functions can also be non-convex. The proposed method approximately solves a sequence of subproblems, each of which is formed by adding to the original objective function a proximal term and quadratic penalty terms associated to the constraint functions. Under a weak-convexity assumption, each subproblem is made strongly convex and can be solved effectively to a required accuracy by an optimal gradient-based method. The computational complexity of the proposed method is analyzed separately for the cases of convex constraint and non-convex constraint. For both cases, the complexity results are established in terms of the number of proximal gradient steps needed to find an -stationary point. When the constraint functions are convex, we show a complexity result of to produce an -stationary point under the Slater's condition. When the constraint functions are non-convex, the complexity becomes if a non-singularity condition holds on constraints and otherwise if a feasible initial solution is available.
Cite
@article{arxiv.1908.11518,
title = {Inexact Proximal-Point Penalty Methods for Constrained Non-Convex Optimization},
author = {Qihang Lin and Runchao Ma and Yangyang Xu},
journal= {arXiv preprint arXiv:1908.11518},
year = {2020}
}
Comments
submitted to journal; corrected a few ? in references