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Random planar maps and graphs with minimum degree two and three

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 Added by Lander Ramos
 Publication date 2014
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and research's language is English




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We find precise asymptotic estimates for the number of planar maps and graphs with a condition on the minimum degree, and properties of random graphs from these classes. In particular we show that the size of the largest tree attached to the core of a random planar graph is of order c log(n) for an explicit constant c. These results provide new information on the structure of random planar graphs.



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The degree-based entropy of a graph is defined as the Shannon entropy based on the information functional that associates the vertices of the graph with the corresponding degrees. In this paper, we study extremal problems of finding the graphs attaining the minimum degree-based graph entropy among graphs and bipartite graphs with a given number of vertices and edges. We characterize the unique extremal graph achieving the minimum value among graphs with a given number of vertices and edges and present a lower bound for the degree-based entropy of bipartite graphs and characterize all the extremal graphs which achieve the lower bound. This implies the known result due to Cao et al. (2014) that the star attains the minimum value of the degree-based entropy among trees with a given number of vertices.
Given a simple graph $G$, denote by $Delta(G)$, $delta(G)$, and $chi(G)$ the maximum degree, the minimum degree, and the chromatic index of $G$, respectively. We say $G$ is emph{$Delta$-critical} if $chi(G)=Delta(G)+1$ and $chi(H)le Delta(G)$ for every proper subgraph $H$ of $G$; and $G$ is emph{overfull} if $|E(G)|>Delta lfloor |V(G)|/2 rfloor$. Since a maximum matching in $G$ can have size at most $lfloor |V(G)|/2 rfloor$, it follows that $chi(G) = Delta(G) +1$ if $G$ is overfull. Conversely, let $G$ be a $Delta$-critical graph. The well known overfull conjecture of Chetwynd and Hilton asserts that $G$ is overfull provided $Delta(G) > |V(G)|/3$. In this paper, we show that any $Delta$-critical graph $G$ is overfull if $Delta(G) - 7delta(G)/4ge(3|V(G)|-17)/4$.
Given a graph $G$, a decomposition of $G$ is a partition of its edges. A graph is $(d, h)$-decomposable if its edge set can be partitioned into a $d$-degenerate graph and a graph with maximum degree at most $h$. For $d le 4$, we are interested in the minimum integer $h_d$ such that every planar graph is $(d,h_d)$-decomposable. It was known that $h_3 le 4$, $h_2le 8$, and $h_1 = infty$. This paper proves that $h_4=1, h_3=2$, and $4 le h_2 le 6$.
Let $G$ be a simple graph with maximum degree $Delta(G)$. A subgraph $H$ of $G$ is overfull if $|E(H)|>Delta(G)lfloor |V(H)|/2 rfloor$. Chetwynd and Hilton in 1985 conjectured that a graph $G$ with $Delta(G)>|V(G)|/3$ has chromatic index $Delta(G)$ if and only if $G$ contains no overfull subgraph. The 1-factorization conjecture is a special case of this overfull conjecture, which states that for even $n$, every regular $n$-vertex graph with degree at least about $n/2$ has a 1-factorization and was confirmed for large graphs in 2014. Supporting the overfull conjecture as well as generalizing the 1-factorization conjecture in an asymptotic way, in this paper, we show that for any given $0<varepsilon <1$, there exists a positive integer $n_0$ such that the following statement holds: if $G$ is a graph on $2nge n_0$ vertices with minimum degree at least $(1+varepsilon)n$, then $G$ has chromatic index $Delta(G)$ if and only if $G$ contains no overfull subgraph.
94 - Vladimir Nikiforov 2016
This paper presents sufficient conditions for Hamiltonian paths and cycles in graphs. Letting $lambdaleft( Gright) $ denote the spectral radius of the adjacency matrix of a graph $G,$ the main results of the paper are: (1) Let $kgeq1,$ $ngeq k^{3}/2+k+4,$ and let $G$ be a graph of order $n$, with minimum degree $deltaleft( Gright) geq k.$ If [ lambdaleft( Gright) geq n-k-1, ] then $G$ has a Hamiltonian cycle, unless $G=K_{1}vee(K_{n-k-1}+K_{k})$ or $G=K_{k}vee(K_{n-2k}+overline{K}_{k})$. (2) Let $kgeq1,$ $ngeq k^{3}/2+k^{2}/2+k+5,$ and let $G$ be a graph of order $n$, with minimum degree $deltaleft( Gright) geq k.$ If [ lambdaleft( Gright) geq n-k-2, ] then $G$ has a Hamiltonian path, unless $G=K_{k}vee(K_{n-2k-1}+overline {K}_{k+1})$ or $G=K_{n-k-1}+K_{k+1}$ In addition, it is shown that in the above statements, the bounds on $n$ are tight within an additive term not exceeding $2$.
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