DC Semidefinite Programming and Cone Constrained DC Optimization: Theory and Local Search Methods

TL;DR

This paper extends DC optimization methods to nonlinear semidefinite and cone constrained problems, analyzing properties, decompositions, and convergence of local search algorithms with applications in variational problems and sphere packing.

Contribution

It introduces new DC decompositions for matrix-valued functions and analyzes convergence of DCA extensions for cone constrained DC problems.

Findings

DC decompositions of maximal eigenvalues enable reformulation as DC constraints

Global convergence of DCA for cone constrained problems is established

Exact penalty DCA effectively solves variational and packing problems

Abstract

In this paper, we study possible extensions of the main ideas and methods of constrained DC optimization to the case of nonlinear semidefinite programming problems and more general nonlinear and nonsmooth cone constrained optimization problems. In the first part of the paper, we analyse two different approaches to the definition of DC matrix-valued functions (namely, order-theoretic and componentwise), study some properties of convex and DC matrix-valued mappings and demonstrate how to compute DC decompositions of some nonlinear semidefinite constraints appearing in applications. We also compute a DC decomposition of the maximal eigenvalue of a DC matrix-valued function. This DC decomposition can be used to reformulate DC semidefinite constraints as DC inequality constrains. Finally, we study local optimality conditions for general cone constrained DC optimization problems. The second part of the paper is devoted to a detailed convergence analysis of two extensions of the well-known DCA method for solving DC (Difference of Convex functions) optimization problems to the case of general cone constrained DC optimization problems. We study the global convergence of the DCA for cone constrained problems and present a comprehensive analysis of a version of the DCA utilizing exact penalty functions. In particular, we study the exactness property of the penalized convex subproblems and provide two types of sufficient conditions for the convergence of the exact penalty method to a feasible and critical point of a cone constrained DC optimization problem from an infeasible starting point. In the numerical section of this work, the exact penalty DCA is applied to the problem of computing compressed modes for variational problems and the sphere packing problem on Grassmannian.