1‐independent percolation on ℤ2×Kn

IF 0.9 3区数学 Q4 COMPUTER SCIENCE, SOFTWARE ENGINEERING Random Structures & Algorithms Pub Date : 2022-12-21 DOI:10.1002/rsa.21129

Victor Falgas‐Ravry, Vincent Pfenninger

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引用次数: 3

Abstract

A random graph model on a host graph H$$ H $$ is said to be 1‐independent if for every pair of vertex‐disjoint subsets A,B$$ A,B $$ of E(H)$$ E(H) $$ , the state of edges (absent or present) in A$$ A $$ is independent of the state of edges in B$$ B $$ . For an infinite connected graph H$$ H $$ , the 1‐independent critical percolation probability p1,c(H)$$ {p}_{1,c}(H) $$ is the infimum of the p∈[0,1]$$ p\in \left[0,1\right] $$ such that every 1‐independent random graph model on H$$ H $$ in which each edge is present with probability at least p$$ p $$ almost surely contains an infinite connected component. Balister and Bollobás observed in 2012 that p1,c(ℤd)$$ {p}_{1,c}\left({\mathbb{Z}}^d\right) $$ tends to a limit in [12,1]$$ \left[\frac{1}{2},1\right] $$ as d→∞$$ d\to \infty $$ , and they asked for the value of this limit. We make progress on a related problem by showing that limn→∞p1,c(ℤ2×Kn)=4−23=0.5358….$$ \underset{n\to \infty }{\lim }{p}_{1,c}\left({\mathbb{Z}}^2\times {K}_n\right)=4-2\sqrt{3}=0.5358\dots . $$In fact, we show that the equality above remains true if the sequence of complete graphs Kn$$ {K}_n $$ is replaced by a sequence of weakly pseudorandom graphs on n$$ n $$ vertices with average degree ω(logn)$$ \omega \left(\log n\right) $$ . We conjecture the answer to Balister and Bollobás's question is also 4−23$$ 4-2\sqrt{3} $$ .

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1‐独立的渗流作用在0 2×Kn上

如果对于E(H) $$ E(H) $$的每一对顶点不相交的子集A,B $$ A,B $$, A $$ A $$中的边的状态(不存在或存在)与B $$ B $$中的边的状态无关，则表示主机图H $$ H $$上的随机图模型是1独立的。对于无限连通图H $$ H $$,1独立的临界渗透概率p1,c(H) $$ {p}_{1,c}(H) $$是p∈[0,1]$$ p\in \left[0,1\right] $$的下限值，使得H $$ H $$上每条边至少以p $$ p $$的概率出现的每一个1独立随机图模型几乎肯定包含一个无限连通分量。Balister和Bollobás在2012年观察到，当d→∞$$ d\to \infty $$时，p1,c(lgd) $$ {p}_{1,c}\left({\mathbb{Z}}^d\right) $$趋向于[12,1]$$ \left[\frac{1}{2},1\right] $$中的一个极限，他们要求这个极限的值。通过证明limn→∞p1,c(0 2×Kn)=4−23=0.5358....，我们在一个相关问题上取得了进展$$ \underset{n\to \infty }{\lim }{p}_{1,c}\left({\mathbb{Z}}^2\times {K}_n\right)=4-2\sqrt{3}=0.5358\dots . $$事实上，我们证明了如果完全图序列Kn $$ {K}_n $$被n个$$ n $$顶点上的平均度为ω(logn) $$ \omega \left(\log n\right) $$的弱伪随机图序列所取代，上面的等式仍然成立。我们推测Balister和Bollobás的问题的答案也是4−23 $$ 4-2\sqrt{3} $$。

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来源期刊

Random Structures & Algorithms 数学-计算机：软件工程

CiteScore

2.50

自引率

10.00%

发文量

审稿时长

>12 weeks

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