MAX CUT in Weighted Random Intersection Graphs and Discrepancy of Sparse Random Set Systems
Abstract
Let be a set of vertices, a set of labels, and let be an matrix of independent Bernoulli random variables with success probability . A random instance of the weighted random intersection graph model is constructed by drawing an edge with weight between any two vertices for which this weight is larger than 0. In this paper we study the average case analysis of Weighted Max Cut, assuming the input is a weighted random intersection graph, i.e. given we wish to find a partition of into two sets so that the total weight of the edges having one endpoint in each set is maximized. We initially prove concentration of the weight of a maximum cut of around its expected value, and then show that, when the number of labels is much smaller than the number of vertices, a random partition of the vertices achieves asymptotically optimal cut weight with high probability (whp). Furthermore, in the case and constant average degree, we show that whp, a majority type algorithm outputs a cut with weight that is larger than the weight of a random cut by a multiplicative constant strictly larger than 1. Then, we highlight a connection between the computational problem of finding a weighted maximum cut in and the problem of finding a 2-coloring with minimum discrepancy for a set system with incidence matrix . We exploit this connection by proposing a (weak) bipartization algorithm for the case that, when it terminates, its output can be used to find a 2-coloring with minimum discrepancy in . Finally, we prove that, whp this 2-coloring corresponds to a bipartition with maximum cut-weight in .
Keywords
Cite
@article{arxiv.2009.01567,
title = {MAX CUT in Weighted Random Intersection Graphs and Discrepancy of Sparse Random Set Systems},
author = {Sotiris Nikoletseas and Christoforos Raptopoulos and Paul Spirakis},
journal= {arXiv preprint arXiv:2009.01567},
year = {2021}
}
Comments
24 pages