Edge-Disjoint Hamilton Cycles in Regular Graphs of Large Degree

We study the number of edge-disjoint Hamilton cycles one can guarantee in a sufficiently large graph G on n vertices with minimum degree δ=(1/2+α)n. For any constant α>0, we give an optimal answer in the following sense: let regeven(n,δ) denote the degree of the largest even-regular spanning subgraph one can guarantee in a graph on n vertices with minimum degree δ. Then the number of edge-disjoint Hamilton cycles we find equals regeven(n,δ)/2. The value of regeven(n,δ) is known for infinitely many values of n and δ. We also extend our results to graphs G of minimum degree δ ≥ n/2, unless G is close to the extremal constructions for Dirac's theorem. Our proof relies on a recent and very general result of Kühn and Osthus on Hamilton decomposition of robustly expanding regular graphs.

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Can Colour-Blind Distinguish Colour Palettes?

The Electronic Journal of Combinatorics ◽

10.37236/2319 ◽

2013 ◽

Vol 20 (3) ◽

Cited By ~ 1

Author(s):

Rafał Kalinowski ◽

Monika Pilśniak ◽

Jakub Przybyło ◽

Mariusz Woźniak

Keyword(s):

Large Degree ◽

Bipartite Graphs ◽

Complete Graphs ◽

Regular Graphs ◽

Lovász Local Lemma ◽

Local Lemma ◽

Comprehensive Information ◽

Lovasz Local Lemma ◽

Delta G ◽

Irregular Graphs

Let $c:E(G)\rightarrow [k]$ be a colouring, not necessarily proper, of edges of a graph $G$. For a vertex $v\in V$, let $\overline{c}(v)=(a_1,\ldots,a_k)$, where $ a_i =|\{u:uv\in E(G),\;c(uv)=i\}|$, for $i\in [k].$ If we re-order the sequence $\overline{c}(v)$ non-decreasingly, we obtain a sequence $c^*(v)=(d_1,\ldots,d_k)$, called a palette of a vertex $v$. This can be viewed as the most comprehensive information about colours incident with $v$ which can be delivered by a person who is unable to name colours but distinguishes one from another. The smallest $k$ such that $c^*$ is a proper colouring of vertices of $G$ is called the colour-blind index of a graph $G$, and is denoted by dal$(G)$. We conjecture that there is a constant $K$ such that dal$(G)\leq K$ for every graph $G$ for which the parameter is well defined. As our main result we prove that $K\leq 6$ for regular graphs of sufficiently large degree, and for irregular graphs with $\delta (G)$ and $\Delta(G)$ satisfying certain conditions. The proofs are based on the Lopsided Lovász Local Lemma. We also show that $K=3$ for all regular bipartite graphs, and for complete graphs of order $n\geq 8$.

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An approximate version of Jackson’s conjecture

Combinatorics Probability Computing ◽

10.1017/s0963548320000152 ◽

2020 ◽

Vol 29 (6) ◽

pp. 886-899

Author(s):

Anita Liebenau ◽

Yanitsa Pehova

Keyword(s):

Bipartite Graph ◽

Small Proportion ◽

Complete Bipartite Graph ◽

Hamilton Cycle ◽

Hamilton Cycles ◽

Edge Disjoint ◽

Bipartite Digraph ◽

Bipartite Tournament ◽

Approximate Version

AbstractA diregular bipartite tournament is a balanced complete bipartite graph whose edges are oriented so that every vertex has the same in- and out-degree. In 1981 Jackson showed that a diregular bipartite tournament contains a Hamilton cycle, and conjectured that in fact its edge set can be partitioned into Hamilton cycles. We prove an approximate version of this conjecture: for every ε > 0 there exists n0 such that every diregular bipartite tournament on 2n ≥ n0 vertices contains a collection of (1/2–ε)n cycles of length at least (2–ε)n. Increasing the degree by a small proportion allows us to prove the existence of many Hamilton cycles: for every c > 1/2 and ε > 0 there exists n0 such that every cn-regular bipartite digraph on 2n ≥ n0 vertices contains (1−ε)cn edge-disjoint Hamilton cycles.

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Optimal Construction of Edge-Disjoint Paths in Random Regular Graphs

Combinatorics Probability Computing ◽

10.1017/s0963548300004284 ◽

2000 ◽

Vol 9 (3) ◽

pp. 241-263 ◽

Cited By ~ 9

Author(s):

ALAN M. FRIEZE ◽

LEI ZHAO

Keyword(s):

Polynomial Time ◽

Regular Graph ◽

Randomized Algorithm ◽

Constant Factor ◽

Disjoint Paths ◽

Regular Graphs ◽

Edge Disjoint ◽

Random Regular Graph ◽

Arbitrary Graphs ◽

Optimal Construction

Given a graph G = (V, E) and a set of κ pairs of vertices in V, we are interested in finding, for each pair (ai, bi), a path connecting ai to bi such that the set of κ paths so found is edge-disjoint. (For arbitrary graphs the problem is [Nscr ][Pscr ]-complete, although it is in [Pscr ] if κ is fixed.)We present a polynomial time randomized algorithm for finding edge-disjoint paths in the random regular graph Gn,r, for sufficiently large r. (The graph is chosen first, then an adversary chooses the pairs of end-points.) We show that almost every Gn,r is such that all sets of κ = Ω(n/log n) pairs of vertices can be joined. This is within a constant factor of the optimum.

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On packing Hamilton cycles in ε-regular graphs

Journal of Combinatorial Theory Series B ◽

10.1016/j.jctb.2004.12.003 ◽

2005 ◽

Vol 94 (1) ◽

pp. 159-172 ◽

Cited By ~ 32

Author(s):

Alan Frieze ◽

Michael Krivelevich

Keyword(s):

Regular Graphs ◽

Hamilton Cycles

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Packing Hamilton Cycles Online

Combinatorics Probability Computing ◽

10.1017/s0963548318000159 ◽

2018 ◽

Vol 27 (4) ◽

pp. 475-495

Author(s):

JOSEPH BRIGGS ◽

ALAN FRIEZE ◽

MICHAEL KRIVELEVICH ◽

PO-SHEN LOH ◽

BENNY SUDAKOV

Keyword(s):

Random Graph ◽

Minimum Degree ◽

Hitting Time ◽

Online Version ◽

Hamilton Cycles ◽

Fixed Integer ◽

Edge Disjoint ◽

Colour Class

It is known that w.h.p. the hitting time τ2σ for the random graph process to have minimum degree 2σ coincides with the hitting time for σ edge-disjoint Hamilton cycles [4, 9, 13]. In this paper we prove an online version of this property. We show that, for a fixed integer σ ⩾ 2, if random edges of Kn are presented one by one then w.h.p. it is possible to colour the edges online with σ colours so that at time τ2σ each colour class is Hamiltonian.

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Edge disjoint Hamilton cycles in graphs

Journal of Graph Theory ◽

10.1002/1097-0118(200009)35:1<8::aid-jgt2>3.0.co;2-k ◽

2000 ◽

Vol 35 (1) ◽

pp. 8-20 ◽

Cited By ~ 3

Author(s):

Guojun Li

Keyword(s):

Hamilton Cycles ◽

Edge Disjoint

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Edge Disjoint Hamilton Cycles in Knödel Graphs

Discrete Mathematics & Theoretical Computer Science ◽

10.46298/dmtcs.2148 ◽

2016 ◽

Vol Vol. 17 no. 3 (Graph Theory) ◽

Author(s):

Palanivel Subramania Nadar Paulraja ◽

S Sampath Kumar

Keyword(s):

Maximum Degree ◽

Hamilton Cycle ◽

Hamilton Cycles ◽

Cycle Decomposition ◽

Edge Disjoint ◽

International Audience ◽

Appl Math

International audience The vertices of the Knödel graph $W_{\Delta, n}$ on $n \geq 2$ vertices, $n$ even, and of maximum degree $\Delta, 1 \leq \Delta \leq \lfloor log_2(n) \rfloor$, are the pairs $(i,j)$ with $i=1,2$ and $0 \leq j \leq \frac{n}{2} -1$. For $0 \leq j \leq \frac{n}{2} -1$, there is an edge between vertex $(1,j)$ and every vertex $(2,j + 2^k - 1 (mod \frac{n}{2}))$, for $k=0,1,2, \ldots , \Delta -1$. Existence of a Hamilton cycle decomposition of $W_{k, 2k}, k \geq 6$ is not yet known, see Discrete Appl. Math. 137 (2004) 173-195. In this paper, it is shown that the $k$-regular Knödel graph $W_{k,2k}, k \geq 6$ has $ \lfloor \frac{k}{2} \rfloor - 1$ edge disjoint Hamilton cycles.

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