Convexification of a Separable Function over a Polyhedral Ground Set

Abstract

In this paper, we study the set S = \ (x,y)∈G×Rn : yj = xj , j=1,…,n\, where > 1 and the ground set G is a nonempty polytope contained in [0,1]n. This nonconvex set is closely related to separable standard quadratic programming and appears as a substructure in potential-based network flow problems from gas and water networks. Our aim is to obtain the convex hull of S or its tight outer-approximation for the special case when the ground set G is the standard simplex. We propose power cone, second-order cone and semidefinite programming relaxations for this purpose, which are further strengthened by the Reformulation-Linearization Technique and the Reformulation-Perspectification Technique. For =2, we obtain the convex hull of S in the low-dimensional setting. For general , we give approximation guarantees for the power cone representable relaxation, the weakest relaxation we consider. We prove that this weakest relaxation is tight with probability one as n∞ when a uniformly generated linear objective is optimized over it. Finally, we provide the results of our extensive computational experiments comparing the empirical strength of several conic programming relaxations that we propose.

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