Dependable Spanners via Unreliable Edges

arXiv - CS - Computational Geometry Pub Date : 2024-07-01 DOI:arxiv-2407.01466

Sariel Har-Peled, Maria C. Lusardi

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Abstract

Let $P$ be a set of $n$ points in $\mathbb{R}^d$, and let $\varepsilon,\psi \in (0,1)$ be parameters. Here, we consider the task of constructing a $(1+\varepsilon)$-spanner for $P$, where every edge might fail (independently) with probability $1-\psi$. For example, for $\psi=0.1$, about $90\%$ of the edges of the graph fail. Nevertheless, we show how to construct a spanner that survives such a catastrophe with near linear number of edges. The measure of reliability of the graph constructed is how many pairs of vertices lose $(1+\varepsilon)$-connectivity. Surprisingly, despite the spanner constructed being of near linear size, the number of failed pairs is close to the number of failed pairs if the underlying graph was a clique. Specifically, we show how to construct such an exact dependable spanner in one dimension of size $O(\tfrac{n}{\psi} \log n)$, which is optimal. Next, we build an $(1+\varepsilon)$-spanners for a set $P \subseteq \mathbb{R}^d$ of $n$ points, of size $O( C n \log n )$, where $C \approx 1/\bigl(\varepsilon^{d} \psi^{4/3}\bigr)$. Surprisingly, these new spanners also have the property that almost all pairs of vertices have a $\leq 4$-hop paths between them realizing this short path.

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可靠的扳手通过不可靠的边缘

让 $P$ 是 $mathbb{R}^d$ 中 $n$ 点的集合，让 $\varepsilon,\psi\in (0,1)$ 是参数。在这里，我们考虑的任务是为 $P$ 构造一个 $(1+\varepsilon)$扫描器，其中每条边都可能以 1-\psi$ 的概率（独立）失败。例如，当 $\psi=0.1$ 时，图中约有 90% 的边会失败。尽管如此，我们还是展示了如何构建一个能以近乎线性的边数经受住这种灾难的扳手。衡量所建图形可靠性的标准是有多少对边失去了 $(1+\varepsilon)$ 连接性。令人惊讶的是，尽管所构建的拼接图的大小接近线性，但失效对的数量却接近于底层图是一个簇时的失效对数量。具体地说，我们展示了如何在一个维度上构建这样一个大小为$O(\tfrac{n}{\psi} \log n)$的精确可依赖生成器，它是最优的。接下来，我们为一个由$n$点组成的集合$P \subseteq \mathbb{R}^d$ 构建了一个大小为$O( C n \log n )$的$(1+\varepsilon)$跨度，其中$C \approx 1/\bigl(\varepsilon^{d}\psi^{4/3}\bigr)$ 。令人惊讶的是，这些新的spanners还具有这样一个特性，即几乎所有的顶点对之间都有一条$\leq 4$-hop的路径来实现这条短路径。

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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arXiv - CS - Computational Geometry

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