The integrality gap of the Goemans-Linial SDP relaxation for sparsest cut is at least a constant multiple of √log n

A. Naor, Robert Young
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引用次数: 9

Abstract

We prove that the integrality gap of the Goemans-Linial semidefinite programming relaxation for the Sparsest Cut Problem is Ω(√logn) on inputs with n vertices, thus matching the previously best known upper bound (logn)1/2+o(1) up to lower-order factors. This statement is a consequence of the following new isoperimetric-type inequality. Consider the 8-regular graph whose vertex set is the 5-dimensional integer grid ℤ5 and where each vertex (a,b,c,d,e)∈ ℤ5 is connected to the 8 vertices (a± 1,b,c,d,e), (a,b± 1,c,d,e), (a,b,c± 1,d,e± a), (a,b,c,d± 1,e± b). This graph is known as the Cayley graph of the 5-dimensional discrete Heisenberg group. Given Ω⊆ ℤ5, denote the size of its edge boundary in this graph (a.k.a. the horizontal perimeter of Ω) by |∂hΩ|. For t ϵ ℕ, denote by |∂vtΩ| the number of (a,b,c,d,e)ϵ ℤ5 such that exactly one of the two vectors (a,b,c,d,e),(a,b,c,d,e+t) is in Ω. The vertical perimeter of Ω is defined to be |∂vΩ|= √Σt=1∞|∂vtΩ|2/t2. We show that every subset Ω⊆ ℤ5 satisfies |∂vΩ|=O(|∂hΩ|). This vertical-versus-horizontal isoperimetric inequality yields the above-stated integrality gap for Sparsest Cut and answers several geometric and analytic questions of independent interest. The theorem stated above is the culmination of a program whose aim is to understand the performance of the Goemans-Linial semidefinite program through the embeddability properties of Heisenberg groups. These investigations have mathematical significance even beyond their established relevance to approximation algorithms and combinatorial optimization. In particular they contribute to a range of mathematical disciplines including functional analysis, geometric group theory, harmonic analysis, sub-Riemannian geometry, geometric measure theory, ergodic theory, group representations, and metric differentiation. This article builds on the above cited works, with the "twist" that while those works were equally valid for any finite dimensional Heisenberg group, our result holds for the Heisenberg group of dimension 5 (or higher) but fails for the 3-dimensional Heisenberg group. This insight leads to our core contribution, which is a deduction of an endpoint L1-boundedness of a certain singular integral on ℝ5 from the (local) L2-boundedness of the corresponding singular integral on ℝ3. To do this, we devise a corona-type decomposition of subsets of a Heisenberg group, in the spirit of the construction that David and Semmes performed in ℝn, but with two main conceptual differences (in addition to more technical differences that arise from the peculiarities of the geometry of Heisenberg group). Firstly, the "atoms" of our decomposition are perturbations of intrinsic Lipschitz graphs in the sense of Franchi, Serapioni, and Serra Cassano (plus the requisite "wild" regions that satisfy a Carleson packing condition). Secondly, we control the local overlap of our corona decomposition by using quantitative monotonicity rather than Jones-type β-numbers.
对于最稀疏切割,Goemans-Linial SDP松弛的完整性间隙至少是√log n的常数倍
我们证明了最稀疏切割问题的Goemans-Linial半定规划松弛在有n个顶点的输入上的完整性缺口为Ω(√logn),从而匹配了之前已知的上界(logn)1/2+o(1)直到低阶因子。这个表述是下列新的等周型不等式的结果。考虑一个8正则图,它的顶点集是5维整数网格,其中每个顶点(a,b,c,d,e)∈t5与8个顶点(a±1,b,c,d,e), (a,b±1,c,d,e), (a,b,c, c±1,e±a), (a,b,c,d±1,e±b)相连。这个图被称为5维离散Heisenberg群的Cayley图。给定Ω,其边缘边界的大小(即Ω的水平周长)用|∂hΩ|表示。对于t λ∈,用|∂vtΩ|表示(a,b,c,d,e)的个数,使得两个向量(a,b,c,d,e),(a,b,c,d,e+t)恰好有一个在Ω中。Ω的垂直周长定义为|∂vΩ|=√Σt=1∞|∂vtΩ|2/t2。我们证明了每个子集Ω都满足|∂vΩ|=O(|∂hΩ|)。这个垂直与水平等周不等式产生了上述的稀疏切割的完整性差距,并回答了几个独立感兴趣的几何和分析问题。上述定理是一个程序的高潮,其目的是通过海森堡群的可嵌入性来理解Goemans-Linial半定程序的性能。这些研究具有数学意义,甚至超越了它们与近似算法和组合优化的既定相关性。特别是,他们对一系列数学学科做出了贡献,包括泛函分析、几何群论、调和分析、亚黎曼几何、几何测度理论、遍历理论、群表示和度量微分。这篇文章建立在上述引用的作品的基础上,“扭曲”的是,虽然这些作品对任何有限维的海森堡群都同样有效,但我们的结果适用于5维(或更高)的海森堡群,但不适用于3维的海森堡群。这一洞见引出了我们的核心贡献,即从相应的(局部)l2有界性推导出了某一个在∈5上的奇异积分的端点l1有界性。为了做到这一点,我们设计了一个海森堡群子集的冕型分解,本着David和Semmes在h - n中进行的构造的精神,但有两个主要的概念差异(除了海森堡群的几何特性引起的更多技术差异)。首先,我们分解的“原子”是Franchi, Serapioni和Serra Cassano意义上的本征Lipschitz图的扰动(加上满足Carleson填充条件的必要“野”区域)。其次,我们利用定量单调性而不是琼斯型β数来控制电晕分解的局部重叠。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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