2016
DOI: 10.1007/s10107-016-0989-3
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Average case polyhedral complexity of the maximum stable set problem

Abstract: We study the minimum number of constraints needed to formulate random instances of the maximum stable set problem via linear programs (LPs), in two distinct models. In the uniform model, the constraints of the LP are not allowed to depend on the input graph, which should be encoded solely in the objective function. There we prove a $2^{\Omega(n/ \log n)}$ lower bound with probability at least $1 - 2^{-2^n}$ for every LP that is exact for a randomly selected set of instances; each graph on at most n vertices be… Show more

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Cited by 11 publications
(29 citation statements)
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“…The linear program is constructed from scratch using a matrix factorization. This also extends [7], by allowing affine functions, and using a modification of nonnegative rank, to show that formulation complexity depends only on the slack matrix. Let P * = (P, F * ) be an approximation problem with an optimization problem P = (S, F).…”
Section: Factorization Theorem and The Slack Matrixmentioning
confidence: 96%
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“…The linear program is constructed from scratch using a matrix factorization. This also extends [7], by allowing affine functions, and using a modification of nonnegative rank, to show that formulation complexity depends only on the slack matrix. Let P * = (P, F * ) be an approximation problem with an optimization problem P = (S, F).…”
Section: Factorization Theorem and The Slack Matrixmentioning
confidence: 96%
“…In particular, we answer an open question regarding the inapproximability of VertexCover (see [12]) and we answer a weak version of our sparse graph conjecture posed in [6].…”
Section: Contributionmentioning
confidence: 97%
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