Sparsity-Cone SDP Relaxations and Applications to Variable Fixing for Sparse Quadratic Programs

Abstract

Quadratic programs (QPs) with sparsity constraint are generally NP-hard, and their efficient global solution depends crucially on tractable tight convex relaxations. In this paper, we propose a sparsity-cone semidefinite programming (SC-SDP) relaxation for sparse (indefinite) QPs. Unlike standard SDP liftings, such as the SDP--RLT relaxation, which involve a (2n+1)-dimensional semidefinite matrix, the proposed SC-SDP formulation uses only a (n+1)-dimensional matrix together with a single sparsity-cone constraint K to handle the relaxation of the 0-norm constraint. We prove that SC-SDP is equivalent in strength to the SDP--RLT relaxation. We further study the sparsity cone K, deriving structural characterizations and showing that projection onto K can be computed efficiently via a one-dimensional subproblem. Building on the dual of SC-SDP, we derive explicit presolving mechanisms, including a dual-fixing rule for individual variables, a screening-cut rule for excluding larger support patterns, and a dual-refinement step for improving presolving certificates. To solve the resulting relaxation SC-SDP efficiently, we develop a two-phase Riemannian-based augmented Lagrangian method and exploits the structured projection subproblems. Numerical experiments on several classes of sparse QPs show that SC-SDP preserves the bound quality of SDP--RLT while offering substantial computational advantages and practically effective presolving capabilities.