Asymptotically tight MILP approximations for a nonconvex QCP

Abstract

Nonconvex quadratically constrained programs (QCPs) are generally NP-hard and challenging problems. In this paper, we propose two novel mixed-integer linear programming (MILP) approximations for a nonconvex QCP. Our method begins by utilizing an eigenvalue-based decomposition to express the nonconvex quadratic function as the difference of two convex functions. We then introduce an additional variable to partition each nonconvex constraint into a second-order cone (SOC) constraint and the complement of an SOC constraint. We employ two polyhedral approximation approaches to approximate the SOC constraint. The complement of an SOC constraint is approximated using a combination of linear and complementarity constraints. As a result, we approximate the nonconvex QCP with two linear programs with complementarity constraints (LPCCs). More importantly, we prove that the optimal values of the LPCCs asymptotically converge to that of the original nonconvex QCP. By proving the boundedness of the LPCCs, we further reformulate the LPCCs as MILPs. We demonstrate the effectiveness of our approaches via numerical experiments by applying our proposed approximations to randomly generated instances and two application problems: the joint decision and estimation problem and the two-trust-region subproblem. The numerical results show significant advantages of our approaches in terms of solution quality and computational time compared with existing benchmark approaches.