植团的平方和下界

R. Meka, Aaron Potechin, A. Wigderson
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引用次数: 104

摘要

在随机图中寻找团和密切相关的“种植”团变体,其中大小为k的团被种植在随机G(n,1/2)图中,一直是算法设计中大量研究的重点。尽管付出了很多努力,但最著名的多项式时间算法只能解决k = Θ(√n)的问题。本文研究了平方和层次算法下种植团问题的复杂性。我们证明了该模型的第一个平均情况下界:对于G(n,1/2)中的几乎所有图,除非k≥(√n/log n)1/rCr,否则SOS层次的r轮不能找到一个种植的k-团。因此,对于任意常数轮,这类强大的算法都不能找到大小为no(1)的种植团。这是通过SOS和Lasserre层次的随机图上最大团问题的自然表述的可积性间隙来显示的,这反过来又遵循positiveellensatz证明系统的度下界。我们按照通常的方法来证明。首先,我们引入一个自然的“双重证明”(也称为“向量解”或“伪期望”),用于表示每个固定输入图的问题的给定多项式方程系统。然后,我们证明了与此双证书相关的矩阵是PSD(正半确定),在输入图的选择上具有高概率。这需要使用某些工具。一个是关联方案的理论,特别是Johnson方案的特征空间和特征值。另一种是我们开发的组合方法,用于计算(通过迹)某些随机矩阵的范数界,其条目是高度相关的;我们希望这种方法对其他地方有用。
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Sum-of-squares Lower Bounds for Planted Clique
Finding cliques in random graphs and the closely related "planted" clique variant, where a clique of size k is planted in a random G(n,1/2) graph, have been the focus of substantial study in algorithm design. Despite much effort, the best known polynomial-time algorithms only solve the problem for k = Θ(√n). In this paper we study the complexity of the planted clique problem under algorithms from the Sum-Of-Squares hierarchy. We prove the first average case lower bound for this model: for almost all graphs in G(n,1/2), r rounds of the SOS hierarchy cannot find a planted k-clique unless k ≥ (√n/log n)1/rCr. Thus, for any constant number of rounds planted cliques of size no(1) cannot be found by this powerful class of algorithms. This is shown via an integrability gap for the natural formulation of maximum clique problem on random graphs for SOS and Lasserre hierarchies, which in turn follow from degree lower bounds for the Positivestellensatz proof system. We follow the usual recipe for such proofs. First, we introduce a natural "dual certificate" (also known as a "vector-solution" or "pseudo-expectation") for the given system of polynomial equations representing the problem for every fixed input graph. Then we show that the matrix associated with this dual certificate is PSD (positive semi-definite) with high probability over the choice of the input graph.This requires the use of certain tools. One is the theory of association schemes, and in particular the eigenspaces and eigenvalues of the Johnson scheme. Another is a combinatorial method we develop to compute (via traces) norm bounds for certain random matrices whose entries are highly dependent; we hope this method will be useful elsewhere.
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