37 research outputs found
Polyhedral Properties of RLT Relaxations of Nonconvex Quadratic Programs and Their Implications on Exact Relaxations
We study linear programming relaxations of nonconvex quadratic programs given
by the reformulation-linearization technique (RLT), referred to as RLT
relaxations. We investigate the relations between the polyhedral properties of
the feasible regions of a quadratic program and its RLT relaxation. We
establish various connections between recession directions, boundedness, and
vertices of the two feasible regions. Using these properties, we present
necessary and sufficient exactness conditions for RLT relaxations. We then give
a thorough discussion of how our results can be converted into simple
algorithmic procedures to construct instances of quadratic programs with exact,
inexact, or unbounded RLT relaxations.Comment: Technical Report, School of Mathematics, The University of Edinburgh,
Edinburgh, EH9 3FD, Scotland, United Kingdo
On Tractable Convex Relaxations of Standard Quadratic Optimization Problems under Sparsity Constraints
Standard quadratic optimization problems (StQPs) provide a versatile
modelling tool in various applications. In this paper, we consider StQPs with a
hard sparsity constraint, referred to as sparse StQPs. We focus on various
tractable convex relaxations of sparse StQPs arising from a mixed-binary
quadratic formulation, namely, the linear optimization relaxation given by the
reformulation-linearization technique, the Shor relaxation, and the relaxation
resulting from their combination. We establish several structural properties of
these relaxations in relation to the corresponding relaxations of StQPs without
any sparsity constraints, and pay particular attention to the rank-one feasible
solutions retained by these relaxations. We then utilize these relations to
establish several results about the quality of the lower bounds arising from
different relaxations. We also present several conditions that ensure the
exactness of each relaxation.Comment: Technical Report, School of Mathematics, The University of Edinburgh,
Edinburgh, EH9 3FD, Scotland, United Kingdo
A unifying optimal partition approach to sensitivity analysis in conic optimization
Abstract We study convex conic optimization problems in which the right-hand side and the cost vectors vary linearly as a function of a scalar parameter. We present a unifying geometric framework that subsumes the concept of the optimal partition in linear programming (LP) and semidefinite programming (SDP) and extends it to conic optimization. Similar to the optimal partition approach to sensitivity analysis in LP and SDP, the range of perturbations for which the optimal partition remains constant can be computed by solving two conic optimization problems. Under a weaker notion of * Revised version of the former technical report "On Sensitivity Analysis in Conic Programming" dated October 22, 2001. ā Department of Applied Mathematics and Statistics, Stony Brook University, Stony Brook, NY 11794-3600, USA. The author is supported in part by NSF through CAREER grant DMI-0237415. ([email protected]) 1 nondegeneracy, this range is simply given by a minimum ratio test. We briefly discuss the properties of the optimal value function under such perturbations
On the minimum volume covering ellipsoid of ellipsoids
We study the problem of computing a (1+É)-approximation to the minimum volume covering ellipsoid of a given set S of the convex hull of m full-dimensional ellipsoids in R n. We extend the first-order algorithm of Kumar and Yıldırım that computes an approximation to the minimum volume covering ellipsoid of a finite set of points in R n, which, in turn, is a modification of Khachiyanās algorithm. For fixed É> 0, we establish a polynomial-time complexity, which is linear in the number of ellipsoids m. In particular, the iteration complexity of our algorithm is identical to that for a set of m points. The main ingredient in our analysis is the extension of polynomialtime complexity of certain subroutines in the algorithm from a set of points to a set of ellipsoids. As a byproduct, our algorithm returns a finite ācore ā set X ā S with the property that the minimum volume covering ellipsoid of X provides a good approximation to that of S. Furthermore, the size of X depends only on the dimension n and É, but not on the number of ellipsoids m. We also discuss the extent to which our algorithm can be used to compute the minimum volume covering ellipsoid of the convex hull of other sets in R n. We adopt the real number model of computation in our analysis