The linear ordering problem is easy to state: Given a complete weighted directed graph, find an ordering of the vertices that maximizes the weight of the forward edges. Although the problem is NP-hard, it is easy to estimate the optimum to within a factor of 1/2. It is not known whether the maximum can be estimated to a better factor using a polynomial-time algorithm. Recently it was shown [NV01] that widely-studied polyhedral relaxations for this problem cannot be used to approximate the problem to within a factor better than 1/2. This was shown by demonstrating that the integrality gap of these relaxations is 2 on random graphs with uniform edge probability p = 2√log n/n. In this paper, we present a new semidefinite programming relaxation for the linear ordering problem. We then show that if we choose a random graph with uniform edge probability p = d/n, where d = ω(1), then with high probability the gap between our semidefinite relaxation and the integral optimal is at most 1.64. © Springer-Verlag 2004.
CITATION STYLE
Newman, A. (2004). Cuts and orderings: On semidefinite relaxations for the linear ordering problem. Lecture Notes in Computer Science (Including Subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics), 3122, 195–206. https://doi.org/10.1007/978-3-540-27821-4_18
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