Covering a Graph with Cycles of Length at Least 4

Hong Wang

doi:10.37236/4099

On Graphs with Cyclic Defect or Excess

The Electronic Journal of Combinatorics ◽

10.37236/415 ◽

2010 ◽

Vol 17 (1) ◽

Cited By ~ 3

Author(s):

Charles Delorme ◽

Guillermo Pineda-Villavicencio

Keyword(s):

Upper Bound ◽

Adjacency Matrix ◽

Minimum Degree ◽

Integer Coefficients ◽

Disjoint Cycles ◽

The Matrix ◽

Odd Degree ◽

Unexplored Area ◽

Trivial Graph ◽

Vertex Disjoint

The Moore bound constitutes both an upper bound on the order of a graph of maximum degree $d$ and diameter $D=k$ and a lower bound on the order of a graph of minimum degree $d$ and odd girth $g=2k+1$. Graphs missing or exceeding the Moore bound by $\epsilon$ are called graphs with defect or excess $\epsilon$, respectively. While Moore graphs (graphs with $\epsilon=0$) and graphs with defect or excess 1 have been characterized almost completely, graphs with defect or excess 2 represent a wide unexplored area. Graphs with defect (excess) 2 satisfy the equation $G_{d,k}(A) = J_n + B$ ($G_{d,k}(A) = J_n - B$), where $A$ denotes the adjacency matrix of the graph in question, $n$ its order, $J_n$ the $n\times n$ matrix whose entries are all 1's, $B$ the adjacency matrix of a union of vertex-disjoint cycles, and $G_{d,k}(x)$ a polynomial with integer coefficients such that the matrix $G_{d,k}(A)$ gives the number of paths of length at most $k$ joining each pair of vertices in the graph. In particular, if $B$ is the adjacency matrix of a cycle of order $n$ we call the corresponding graphs graphs with cyclic defect or excess; these graphs are the subject of our attention in this paper. We prove the non-existence of infinitely many such graphs. As the highlight of the paper we provide the asymptotic upper bound of $O(\frac{64}3d^{3/2})$ for the number of graphs of odd degree $d\ge3$ and cyclic defect or excess. This bound is in fact quite generous, and as a way of illustration, we show the non-existence of some families of graphs of odd degree $d\ge3$ and cyclic defect or excess. Actually, we conjecture that, apart from the Möbius ladder on 8 vertices, no non-trivial graph of any degree $\ge 3$ and cyclic defect or excess exists.

Disjoint Cycles of Different Lengths in Graphs and Digraphs

The Electronic Journal of Combinatorics ◽

10.37236/6921 ◽

2017 ◽

Vol 24 (4) ◽

Author(s):

Julien Bensmail ◽

Ararat Harutyunyan ◽

Ngoc Khang Le ◽

Binlong Li ◽

Nicolas Lichiardopol

Keyword(s):

Minimum Degree ◽

Directed Graphs ◽

Probabilistic Method ◽

Undirected Graphs ◽

Disjoint Cycles ◽

Vertex Disjoint ◽

Degree Bound ◽

Directed Cycles

In this paper, we study the question of finding a set of $k$ vertex-disjoint cycles (resp. directed cycles) of distinct lengths in a given graph (resp. digraph). In the context of undirected graphs, we prove that, for every $k \geq 1$, every graph with minimum degree at least $\frac{k^2+5k-2}{2}$ has $k$ vertex-disjoint cycles of different lengths, where the degree bound is best possible. We also consider other cases such as when the graph is triangle-free, or the $k$ cycles are required to have different lengths modulo some value $r$. In the context of directed graphs, we consider a conjecture of Lichiardopol concerning the least minimum out-degree required for a digraph to have $k$ vertex-disjoint directed cycles of different lengths. We verify this conjecture for tournaments, and, by using the probabilistic method, for some regular digraphs and digraphs of small order.

A Note on Vertex-Disjoint Cycles

Combinatorics Probability Computing ◽

10.1017/s0963548301004904 ◽

2002 ◽

Vol 11 (1) ◽

pp. 97-102 ◽

Cited By ~ 3

Author(s):

JACQUES VERSTRAËTE

Keyword(s):

Minimum Degree ◽

Quadratic Function ◽

Average Degree ◽

Disjoint Cycles ◽

Vertex Disjoint

Häggkvist and Scott asked whether one can find a quadratic function q(k) such that, if G is a graph of minimum degree at least q(k), then G contains vertex-disjoint cycles of k consecutive even lengths. In this paper, it is shown that if G is a graph of average degree at least k2+19k+10 with sufficiently many vertices, then G contains vertex-disjoint cycles of k consecutive even lengths, answering the above question in the affirmative. The coefficient of k2 cannot be decreased and, in this sense, this result is best possible.

Towards a Weighted Version of the Hajnal–Szemerédi Theorem

Combinatorics Probability Computing ◽

10.1017/s0963548313000059 ◽

2013 ◽

Vol 22 (3) ◽

pp. 346-350 ◽

Cited By ~ 1

Author(s):

JOZSEF BALOGH ◽

GRAEME KEMKES ◽

CHOONGBUM LEE ◽

STEPHEN J. YOUNG

Keyword(s):

Positive Integer ◽

Minimum Degree ◽

Edge Weight ◽

Main Question ◽

Weighted Graphs ◽

Lower And Upper Bounds ◽

Weighted Degree ◽

Weighted Version ◽

Vertex Disjoint ◽

The Given

For a positive integer r ≥ 2, a Kr-factor of a graph is a collection vertex-disjoint copies of Kr which covers all the vertices of the given graph. The celebrated theorem of Hajnal and Szemerédi asserts that every graph on n vertices with minimum degree at least $(1-\frac{1}{r})n contains a Kr-factor. In this note, we propose investigating the relation between minimum degree and existence of perfect Kr-packing for edge-weighted graphs. The main question we study is the following. Suppose that a positive integer r ≥ 2 and a real t ∈ [0, 1] is given. What is the minimum weighted degree of Kn that guarantees the existence of a Kr-factor such that every factor has total edge weight at least $$t\binom{r}{2}$?$ We provide some lower and upper bounds and make a conjecture on the asymptotics of the threshold as n goes to infinity.

Monochromatic Cycle Partitions of $2$-Coloured Graphs with Minimum Degree $3n/4$

The Electronic Journal of Combinatorics ◽

10.37236/7239 ◽

2019 ◽

Vol 26 (1) ◽

Cited By ~ 1

Author(s):

Shoham Letzter

Keyword(s):

Minimum Degree ◽

Disjoint Cycles ◽

Large N ◽

Vertex Set ◽

Vertex Disjoint ◽

Edge Colouring

Balogh, Barát, Gerbner, Gyárfás, and Sárközy made the following conjecture. Let $G$ be a graph on $n$ vertices with minimum degree at least $3n/4$. Then for every $2$-edge-colouring of $G$, the vertex set $V(G)$ may be partitioned into two vertex-disjoint cycles, one of each colour. We prove this conjecture for large $n$, improving approximate results by the aforementioned authors and by DeBiasio and Nelsen.

Remarks on the Local Irregularity Conjecture

Mathematics ◽

10.3390/math9243209 ◽

2021 ◽

Vol 9 (24) ◽

pp. 3209

Author(s):

Jelena Sedlar ◽

Riste Škrekovski

Keyword(s):

Minimum Degree ◽

Edge Coloring ◽

Chromatic Index ◽

Sparse Graphs ◽

Unicyclic Graphs ◽

Disjoint Cycles ◽

Cactus Graph ◽

Colorable Graph ◽

Vertex Disjoint ◽

Local Irregularity

A locally irregular graph is a graph in which the end vertices of every edge have distinct degrees. A locally irregular edge coloring of a graph G is any edge coloring of G such that each of the colors induces a locally irregular subgraph of G. A graph G is colorable if it allows a locally irregular edge coloring. The locally irregular chromatic index of a colorable graph G, denoted by χirr′(G), is the smallest number of colors used by a locally irregular edge coloring of G. The local irregularity conjecture claims that all graphs, except odd-length paths, odd-length cycles and a certain class of cacti are colorable by three colors. As the conjecture is valid for graphs with a large minimum degree and all non-colorable graphs are vertex disjoint cacti, we study rather sparse graphs. In this paper, we give a cactus graph B which contradicts this conjecture, i.e., χirr′(B)=4. Nevertheless, we show that the conjecture holds for unicyclic graphs and cacti with vertex disjoint cycles.

The Order of Monochromatic Subgraphs with a Given Minimum Degree

The Electronic Journal of Combinatorics ◽

10.37236/1725 ◽

2003 ◽

Vol 10 (1) ◽

Author(s):

Yair Caro ◽

Raphael Yuster

Keyword(s):

Positive Integer ◽

Minimum Degree

Let $G$ be a graph. For a given positive integer $d$, let $f_G(d)$ denote the largest integer $t$ such that in every coloring of the edges of $G$ with two colors there is a monochromatic subgraph with minimum degree at least $d$ and order at least $t$. Let $f_G(d)=0$ in case there is a $2$-coloring of the edges of $G$ with no such monochromatic subgraph. Let $f(n,k,d)$ denote the minimum of $f_G(d)$ where $G$ ranges over all graphs with $n$ vertices and minimum degree at least $k$. In this paper we establish $f(n,k,d)$ whenever $k$ or $n-k$ are fixed, and $n$ is sufficiently large. We also consider the case where more than two colors are allowed.

A fast $$(2 + \frac{2}{7})$$-approximation algorithm for capacitated cycle covering

Mathematical Programming ◽

10.1007/s10107-021-01678-3 ◽

2021 ◽

Author(s):

Vera Traub ◽

Thorben Tröbst

Keyword(s):

Vehicle Routing Problem ◽

Covering Problem ◽

Post Processing ◽

Routing Problem ◽

Cycle Cover ◽

Disjoint Cycles ◽

Processing Step ◽

Number Of Cycles ◽

Vertex Disjoint ◽

Capacitated Vehicle

AbstractWe consider the capacitated cycle covering problem: given an undirected, complete graph G with metric edge lengths and demands on the vertices, we want to cover the vertices with vertex-disjoint cycles, each serving a demand of at most one. The objective is to minimize a linear combination of the total length and the number of cycles. This problem is closely related to the capacitated vehicle routing problem (CVRP) and other cycle cover problems such as min-max cycle cover and bounded cycle cover. We show that a greedy algorithm followed by a post-processing step yields a $$(2 + \frac{2}{7})$$ ( 2 + 2 7 ) -approximation for this problem by comparing the solution to a polymatroid relaxation. We also show that the analysis of our algorithm is tight and provide a $$2 + \epsilon $$ 2 + ϵ lower bound for the relaxation.

On Directed Versions of the Hajnal–Szemerédi Theorem

Combinatorics Probability Computing ◽

10.1017/s0963548315000036 ◽

2015 ◽

Vol 24 (6) ◽

pp. 873-928 ◽

Cited By ~ 6

Author(s):

ANDREW TREGLOWN

Keyword(s):

Directed Graph ◽

Minimum Degree ◽

Directed Graphs ◽

Perfect Matchings ◽

Large Order ◽

Vertex Disjoint ◽

Removal Lemma

We say that a (di)graph G has a perfect H-packing if there exists a set of vertex-disjoint copies of H which cover all the vertices in G. The seminal Hajnal–Szemerédi theorem characterizes the minimum degree that ensures a graph G contains a perfect Kr-packing. In this paper we prove the following analogue for directed graphs: Suppose that T is a tournament on r vertices and G is a digraph of sufficiently large order n where r divides n. If G has minimum in- and outdegree at least (1−1/r)n then G contains a perfect T-packing.In the case when T is a cyclic triangle, this result verifies a recent conjecture of Czygrinow, Kierstead and Molla [4] (for large digraphs). Furthermore, in the case when T is transitive we conjecture that it suffices for every vertex in G to have sufficiently large indegree or outdegree. We prove this conjecture for transitive triangles and asymptotically for all r ⩾ 3. Our approach makes use of a result of Keevash and Mycroft [10] concerning almost perfect matchings in hypergraphs as well as the Directed Graph Removal Lemma [1, 6].

Vertex disjoint cycles of different lengths in d-arc-dominated digraphs

Operations Research Letters ◽

10.1016/j.orl.2014.06.004 ◽

2014 ◽

Vol 42 (5) ◽

pp. 351-354 ◽

Cited By ~ 1

Author(s):

Ngo Dac Tan

Keyword(s):

Disjoint Cycles ◽

Vertex Disjoint