اشترك بالحزمة الذهبية واحصل على وصول غير محدود شمرا أكاديميا
تسجيل مستخدم جديدThe maximum number of 10- and 12-cycles in a planar graph
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For a fixed planar graph $H$, let $operatorname{mathbf{N}}_{mathcal{P}}(n,H)$ denote the maximum number of copies of $H$ in an $n$-vertex planar graph. In the case when $H$ is a cycle, the asymptotic value of $operatorname{mathbf{N}}_{mathcal{P}}(n,C_m)$ is currently known for $min{3,4,5,6,8}$. In this note, we extend this list by establishing $operatorname{mathbf{N}}_{mathcal{P}}(n,C_{10})sim(n/5)^5$ and $operatorname{mathbf{N}}_{mathcal{P}}(n,C_{12})sim(n/6)^6$. We prove this by answering the following question for $min{5,6}$, which is interesting in its own right: which probability mass $mu$ on the edges of some clique maximizes the probability that $m$ independent samples from $mu$ form an $m$-cycle?
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Finding the maximum number of induced cycles of length $k$ in a graph on $n$ vertices has been one of the most intriguing open problems of Extremal Graph Theory. Recently Balogh, Hu, Lidick{y} and Pfender answered the question in the case $k=5$. In t
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Whitney proved in 1931 that 4-connected planar triangulations are Hamiltonian. Hakimi, Schmeichel, and Thomassen conjectured in 1979 that if $G$ is a 4-connected planar triangulation with $n$ vertices then $G$ contains at least $2(n-2)(n-4)$ Hamilton
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