Bootstrap percolation in inhomogeneous random graphs

Pub Date : 2023-08-07 DOI:10.1017/apr.2023.21

Hamed Amini, Nikolaos Fountoulakis, Konstantinos Panagiotou

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引用次数: 1

Abstract

Abstract A bootstrap percolation process on a graph with n vertices is an ‘infection’ process evolving in rounds. Let $r \ge 2$ be fixed. Initially, there is a subset of infected vertices. In each subsequent round, every uninfected vertex that has at least r infected neighbors becomes infected as well and remains so forever. We consider this process in the case where the underlying graph is an inhomogeneous random graph whose kernel is of rank one. Assuming that initially every vertex is infected independently with probability $p \in (0,1]$ , we provide a law of large numbers for the size of the set of vertices that are infected by the end of the process. Moreover, we investigate the case $p = p(n) = o(1)$ , and we focus on the important case of inhomogeneous random graphs exhibiting a power-law degree distribution with exponent $\beta \in (2,3)$ . The first two authors have shown in this setting the existence of a critical $p_c =o(1)$ such that, with high probability, if $p =o(p_c)$ , then the process does not evolve at all, whereas if $p = \omega(p_c)$ , then the final set of infected vertices has size $\Omega(n)$ . In this work we determine the asymptotic fraction of vertices that will eventually be infected and show that it also satisfies a law of large numbers.

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非齐次随机图中的自举渗流

具有n个顶点的图上的自举渗透过程是一个以轮为单位演化的“感染”过程。让$r \ge 2$固定下来。最初，有一个受感染顶点的子集。在随后的每一轮中，每个至少有r个被感染邻居的未感染顶点也会被感染，并永远保持这种状态。我们考虑下面的图是一个核为秩1的非齐次随机图的情况。假设最初每个顶点都以$p \in (0,1]$的概率独立感染，我们提供了一个大数定律，用于表示在过程结束时被感染的顶点集的大小。此外，我们研究了$p = p(n) = o(1)$的情况，并重点研究了指数为$\beta \in (2,3)$的幂律度分布的非齐次随机图的重要情况。在这种情况下，前两位作者已经证明了一个临界$p_c =o(1)$的存在，这样，在高概率下，如果$p =o(p_c)$，则该过程根本不会进化，而如果$p = \omega(p_c)$，则最终受感染顶点集的大小为$\Omega(n)$。在这项工作中，我们确定了最终将被感染的顶点的渐近分数，并表明它也满足大数定律。

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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