English

Exact SDP relaxations of quadratically constrained quadratic programs with forest structures

Optimization and Control 2020-09-22 v2

Abstract

We study the exactness of the semidefinite programming (SDP) relaxation of quadratically constrained quadratic programs (QCQPs). With the aggregate sparsity matrix from the data matrices of a QCQP with nn variables, the rank and positive semidefiniteness of the matrix are examined. We prove that if the rank of the aggregate sparsity matrix is not less than n1n-1 and the matrix remains positive semidefinite after replacing some off-diagonal nonzero elements with zeros, then the standard SDP relaxation provides an exact optimal solution for the QCQP under feasibility assumptions. In particular, we demonstrate that QCQPs with forest-structured aggregate sparsity matrix, such as the tridiagonal or arrow-type matrix, satisfy the exactness condition on the rank. The exactness is attained by considering the feasibility of the dual SDP relaxation, the strong duality of SDPs, and a sequence of QCQPs with perturbed objective functions, under the assumption that the feasible region is compact. We generalize our result for a wider class of QCQPs by applying simultaneous tridiagonalization on the data matrices. Moreover, simultaneous tridiagonalization is applied to a matrix pencil so that QCQPs with two constraints can be solved exactly by the SDP relaxation.

Keywords

Cite

@article{arxiv.2009.02638,
  title  = {Exact SDP relaxations of quadratically constrained quadratic programs with forest structures},
  author = {Godai Azuma and Mituhiro Fukuda and Sunyoung Kim and Makoto Yamashita},
  journal= {arXiv preprint arXiv:2009.02638},
  year   = {2020}
}
R2 v1 2026-06-23T18:20:22.515Z