Provable Exactness for Asymmetric Low-Rank SDP Learning

Abstract

Low-rank factorization is a standard way to make structured optimization problems in machine learning more tractable by replacing matrix variables with compact factors. For positive semidefinite (PSD) variables, the symmetric Burer--Monteiro factorization (sBMF) writes Z=XX with a single low-rank factor X. A recent asymmetric alternative (aBMF) writes Z=XY and adds a quadratic penalty (γ/2)\|X-Y\|F2 to encourage symmetry. This split is attractive because it yields a biconvex objective with alternating convex subproblems, but its practical value depends strongly on how the penalty parameter γ is chosen. We study a unified regularized aBMF framework and derive an explicit lower bound on γ that guarantees exactness: under mild assumptions, any γ above this threshold makes aBMF and sBMF share the same critical points. This gives a principled way to use the asymmetric formulation without altering the critical-point structure of the symmetric problem. In particular, it answers the open question of whether an exact penalty exists for asymmetric relaxation.