666 research outputs found
Forbidden subgraphs that imply Hamiltonian-connectedness
It is proven that if is a -connected claw-free graph which is also -free (where is a triangle with a path of length attached), -free (where is a path with vertices) or -free (where consists of two disjoint triangles connected by an edge), then is Hamiltonian-connected. Also, examples will be described that determine a finite family of graphs such that if a 3-connected graph being claw-free and -free implies is Hamiltonian-connected, then . \u
Ore- and Fan-type heavy subgraphs for Hamiltonicity of 2-connected graphs
Bedrossian characterized all pairs of forbidden subgraphs for a 2-connected
graph to be Hamiltonian. Instead of forbidding some induced subgraphs, we relax
the conditions for graphs to be Hamiltonian by restricting Ore- and Fan-type
degree conditions on these induced subgraphs. Let be a graph on
vertices and be an induced subgraph of . is called \emph{o}-heavy if
there are two nonadjacent vertices in with degree sum at least , and is
called -heavy if for every two vertices ,
implies that . We say that is -\emph{o}-heavy
(-\emph{f}-heavy) if every induced subgraph of isomorphic to is
\emph{o}-heavy (\emph{f}-heavy). In this paper we characterize all connected
graphs and other than such that every 2-connected
-\emph{f}-heavy and -\emph{f}-heavy (-\emph{o}-heavy and
-\emph{f}-heavy, -\emph{f}-heavy and -free) graph is Hamiltonian. Our
results extend several previous theorems on forbidden subgraph conditions and
heavy subgraph conditions for Hamiltonicity of 2-connected graphs.Comment: 21 pages, 2 figure
Heavy subgraphs, stability and hamiltonicity
Let be a graph. Adopting the terminology of Broersma et al. and \v{C}ada,
respectively, we say that is 2-heavy if every induced claw () of
contains two end-vertices each one has degree at least ; and
is o-heavy if every induced claw of contains two end-vertices with degree
sum at least in . In this paper, we introduce a new concept, and
say that is \emph{-c-heavy} if for a given graph and every induced
subgraph of isomorphic to and every maximal clique of ,
every non-trivial component of contains a vertex of degree at least
in . In terms of this concept, our original motivation that a
theorem of Hu in 1999 can be stated as every 2-connected 2-heavy and
-c-heavy graph is hamiltonian, where is the graph obtained from a
triangle by adding three disjoint pendant edges. In this paper, we will
characterize all connected graphs such that every 2-connected o-heavy and
-c-heavy graph is hamiltonian. Our work results in a different proof of a
stronger version of Hu's theorem. Furthermore, our main result improves or
extends several previous results.Comment: 21 pages, 6 figures, finial version for publication in Discussiones
Mathematicae Graph Theor
On Eulerian subgraphs and hamiltonian line graphs
A graph {\color{black}} is Hamilton-connected if for any pair of distinct vertices {\color{black}}, {\color{black}} has a spanning -path; {\color{black}} is 1-hamiltonian if for any vertex subset with , has a spanning cycle. Let , and denote the minimum degree, the matching number and the line graph of a graph , respectively. The following result is obtained. {\color{black} Let be a simple graph} with . If , then each of the following holds. \\ (i) is Hamilton-connected if and only if . \\ (ii) is 1-hamiltonian if and only if . %==========sp For a graph , an integer and distinct vertices , an -path-system of is a subgraph consisting of internally disjoint -paths. The spanning connectivity is the largest integer such that for any with and for any with , has a spanning -path-system. It is known that , and determining if is an NP-complete problem. A graph is maximally spanning connected if . Let and be the smallest integers and such that is maximally spanning connected and , respectively. We show that every locally-connected line graph with connectivity at least 3 is maximally spanning connected, and that the spanning connectivity of a locally-connected line graph can be polynomially determined. As applications, we also determined best possible upper bounds for and , and characterized the extremal graphs reaching the upper bounds. %==============st For integers and , a graph is -supereulerian if for any disjoint edge sets with and , has a spanning closed trail that contains and avoids . Pulleyblank in [J. Graph Theory, 3 (1979) 309-310] showed that determining whether a graph is -supereulerian, even when restricted to planar graphs, is NP-complete. Settling an open problem of Bauer, Catlin in [J. Graph Theory, 12 (1988) 29-45] showed that every simple graph on vertices with , when is sufficiently large, is -supereulerian or is contractible to . We prove the following for any nonnegative integers and . \\ (i) For any real numbers and with , there exists a family of finitely many graphs \F(a,b;s,t) such that if is a simple graph on vertices with and , then either is -supereulerian, or is contractible to a member in \F(a,b;s,t). \\ (ii) Let denote the connected loopless graph with two vertices and parallel edges. If is a simple graph on vertices with and , then when is sufficiently large, either is -supereulerian, or for some integer with , is contractible to a . %==================index For a hamiltonian property \cp, Clark and Wormold introduced the problem of investigating the value \cp(a,b) = \max\{\min\{n: L^n(G) has property \cp\}: and , and proposed a few problems to determine \cp(a,b) with when \cp is being hamiltonian, edge-hamiltonian and hamiltonian-connected. Zhan in 1986 proved that the line graph of a 4-edge-connected graph is Hamilton-connected, which implies a solution to the unsettled cases of above-mentioned problem. We consider an extended version of the problem. Let denote the essential edge-connectivity of a graph , and define \cp\u27(a,b) = \max\{\min\{n: L^n(G) has property \cp\}: and . We investigate the values of \cp\u27(a,b) when \cp is one of these hamiltonian properties. In particular, we show that for any values of , \cp\u27(4,b) \le 2 and \cp\u27(4,b) = 1 if and only if Thomassen\u27s conjecture that every 4-connected line graph is hamiltonian is valid
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