Dynamic Sketching for Graph Optimization Problems with Applications to Cut-Preserving Sketches

Foundations of Software Technology and Theoretical Computer Science Pub Date : 2015-10-12 DOI:10.4230/LIPIcs.FSTTCS.2015.52

Sepehr Assadi, S. Khanna, Yang Li, V. Tannen

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引用次数: 7

Abstract

In this paper, we introduce a new model for sublinear algorithms called \emph{dynamic sketching}. In this model, the underlying data is partitioned into a large \emph{static} part and a small \emph{dynamic} part and the goal is to compute a summary of the static part (i.e, a \emph{sketch}) such that given any \emph{update} for the dynamic part, one can combine it with the sketch to compute a given function. We say that a sketch is \emph{compact} if its size is bounded by a polynomial function of the length of the dynamic data, (essentially) independent of the size of the static part. A graph optimization problem $P$ in this model is defined as follows. The input is a graph $G(V,E)$ and a set $T \subseteq V$ of $k$ terminals; the edges between the terminals are the dynamic part and the other edges in $G$ are the static part. The goal is to summarize the graph $G$ into a compact sketch (of size poly$(k)$) such that given any set $Q$ of edges between the terminals, one can answer the problem $P$ for the graph obtained by inserting all edges in $Q$ to $G$, using only the sketch. We study the fundamental problem of computing a maximum matching and prove tight bounds on the sketch size. In particular, we show that there exists a (compact) dynamic sketch of size $O(k^2)$ for the matching problem and any such sketch has to be of size $\Omega(k^2)$. Our sketch for matchings can be further used to derive compact dynamic sketches for other fundamental graph problems involving cuts and connectivities. Interestingly, our sketch for matchings can also be used to give an elementary construction of a \emph{cut-preserving vertex sparsifier} with space $O(kC^2)$ for $k$-terminal graphs; here $C$ is the total capacity of the edges incident on the terminals. Additionally, we give an improved lower bound (in terms of $C$) of $\Omega(C/\log{C})$ on size of cut-preserving vertex sparsifiers.

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图优化问题的动态绘制及其在保切图中的应用

在本文中，我们引入了一种新的亚线性算法模型，称为\emph{动态草图}。在这个模型中，底层数据被划分为大的\emph{静态}部分和小的\emph{动态}部分，目标是计算静态部分(即\emph{草图})的摘要，以便给定动态部分的任何\emph{更新}，可以将其与草图结合起来计算给定的函数。我们说一个草图是\emph{紧凑}的，如果它的大小是由一个多项式函数的长度的动态数据，(本质上)独立于静态部分的大小。本模型中的图优化问题$P$定义如下:输入是一个图形$G(V,E)$和一组$T \subseteq V$的$k$终端;端子之间的边为动态部分，$G$中其他边为静态部分。我们的目标是将图$G$总结成一个紧凑的草图(尺寸为poly $(k)$)，这样，给定终端之间的任何一组$Q$边，就可以回答通过将所有边插入$Q$到$G$而获得的图的问题$P$，只使用草图。我们研究了计算最大匹配的基本问题，并证明了草图尺寸的紧边界。特别地，我们证明了匹配问题存在一个大小为$O(k^2)$的(紧凑的)动态草图，任何这样的草图必须是$\Omega(k^2)$。我们的匹配草图可以进一步用于导出其他涉及切和连通性的基本图问题的紧凑动态草图。有趣的是，我们的匹配草图也可以用来给出$k$ -终端图的具有空间$O(kC^2)$的\emph{保切顶点稀疏器}的初等构造;这里$C$是终端上的边的总容量。此外，我们给出了一个改进的$\Omega(C/\log{C})$的下界(以$C$的形式)关于保持切割的顶点稀疏化器的大小。

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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Foundations of Software Technology and Theoretical Computer Science

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