It is well known that the convex hull of {(x,y,xy)}, where (x,y) is constrained to lie in a box, is given by the Reformulation-Linearization Technique (RLT) constraints. Belotti et al. (2010) and Miller et al. (2011) showed that if there are additional upper and/or lower bounds on the product z=xy, then the convex hull can be represented by adding an infinite family of inequalities, requiring a separation algorithm to implement. Nguyen et al. (2018) derived convex hulls with bounds on z for the more general case of z=x^{b_1}y^{b_2}, where b_1 >= 1, b_2 >= 1. We focus on the most important case where b_1 = b_2 = 1 and show that the convex hull with either an upper bound or lower bound on the product is given by RLT constraints, the bound on z and a single Second-Order Cone (SOC) constraint. With both upper and lower bounds on the product, the convex hull can be represented using no more than three SOC constraints, each applicable on a subset of (x,y) values. In addition to the convex hull characterizations, volumes of the convex hulls with either an upper or lower bound on z are calculated and compared to the relaxation that imposes only the RLT constraints. As an application of these volume results, we show how spatial branching can be applied to the product variable so as to minimize the sum of the volumes for the two resulting subproblems.
Citation
Dept. of Business Analytics, Tippie College of Business, University of Iowa, Iowa City, IA 52242, April 2020.
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