Partitioning complete multipartite graphs by monochromatic trees

The tree partition number of an r‐edge‐colored graph G, denoted by t_r(G), is the minimum number k such that whenever the edges of G are colored with r colors, the vertices of G can be covered by at most k vertex‐disjoint monochromatic trees. We determine t₂(K(n₁, n₂,…, n_k)) of the complete k‐partite graph K(n₁, n₂,…, n_k). In particular, we prove that t₂(K(n, m)) = ? (m‐2)/2ⁿ? + 2, where 1 ≤ n ≤ m. © 2004 Wiley Periodicals, Inc. J Graph Theory 48: 133–141, 2005     

Partitioning edge-coloured complete graphs into monochromatic cycles

A conjecture of Erdös, Gyárfás, and Pyber says that in any edge-colouring of a complete graph with r colours, it is possible to cover all the vertices with r vertex-disjoint monochromatic cycles. So far, this conjecture has been proven only for $r=2$. In this note we show that in fact this conjecture is false for all $r⩾3$. We also discuss some weakenings of this conjecture which may still be true.     

Partitioning edge-coloured complete symmetric digraphs into monochromatic complete subgraphs

Let ${\overrightarrow{K}}_{\mathbb{N}}$ be the complete symmetric digraph on the positive integers. Answering a question of DeBiasio and McKenney, we construct a 2-colouring of the edges of ${\overrightarrow{K}}_{\mathbb{N}}$ in which every monochromatic path has density 0.However, if we restrict the length of monochromatic paths in one colour, then no example as above can exist: We show that every $(r+1)$-edge-coloured complete symmetric digraph (of arbitrary infinite cardinality) containing no directed paths of edge-length ${?}_i$ for any colour $i\le r$ can be covered by ${\prod }_{i\in \left[r\right]}{?}_i$ pairwise disjoint monochromatic complete symmetric digraphs in colour $r+1$.Furthermore, we present a stability version for the countable case of the latter result: We prove that the edge-colouring is uniquely determined on a large subgraph, as soon as the upper density of monochromatic paths in colour $r+1$ is bounded by ${\prod }_{i\in \left[r\right]}\frac{1}{{?}_i}$.     

Long cycles and paths in distance graphs

For n∈N and D⊆N, the distance graph has vertex set {0,1,…,n−1} and edge set {ij∣0≤i,j≤n−1,|j−i|∈D}. Note that the important and very well-studied circulant graphs coincide with the regular distance graphs.A fundamental result concerning circulant graphs is that for these graphs, a simple greatest common divisor condition, their connectivity, and the existence of a Hamiltonian cycle are all equivalent. Our main result suitably extends this equivalence to distance graphs. We prove that for a finite set D of order at least 2, there is a constant c_D such that the greatest common divisor of the integers in D is 1 if and only if for every n, has a component of order at least n−c_D if and only if for every n≥c_D+3, has a cycle of order at least n−c_D. Furthermore, we discuss some consequences and variants of this result.     

Partitioning 2-edge-colored graphs by monochromatic paths and cycles

We present results on partitioning the vertices of 2-edge-colored graphs into monochromatic paths and cycles. We prove asymptotically the two-color case of a conjecture of Sárközy: the vertex set of every 2-edge-colored graph can be partitioned into at most 2α(G) monochromatic cycles, where α(G) denotes the independence number of G. Another direction, emerged recently from a conjecture of Schelp, is to consider colorings of graphs with given minimum degree. We prove that apart from o(|V (G)|) vertices, the vertex set of any 2-edge-colored graph G with minimum degree at least \(\tfrac{{(1 + \varepsilon )3|V(G)|}} {4}\) can be covered by the vertices of two vertex disjoint monochromatic cycles of distinct colors. Finally, under the assumption that \(\bar G\) does not contain a fixed bipartite graph H, we show that in every 2-edge-coloring of G, |V (G)| ? c(H) vertices can be covered by two vertex disjoint paths of different colors, where c(H) is a constant depending only on H. In particular, we prove that c(C ₄)=1, which is best possible.     

Decomposing complete equipartite graphs into short even cycles

In this article we find necessary and sufficient conditions to decompose a complete equipartite graph into cycles of uniform length, in the case that the length is both even and short relative to the number of parts. © 2010 Wiley Periodicals, Inc. J Combin Designs 19:131‐143, 2011     

赋权图中的路和圈

本文研究了赋权图中的最长路和最长圈,将关于非赋权图中最长路和最长圈的一些结果推广到赋权图上.     

Infinite paths in planar graphs IV,dividing cycles

Nash‐Williams conjectured that a 4‐connected infinite planar graph contains a spanning 2‐way infinite path if, and only if, the deletion of any finite set of vertices results in at most two infinite components. In this article, we prove this conjecture for graphs with no dividing cycles and for graphs with infinitely many vertex disjoint dividing cycles. A cycle in an infinite plane graph is called dividing if both regions of the plane bounded by this cycle contain infinitely many vertices of the graph. © 2006 Wiley Periodicals, Inc. J Graph Theory 53: 173–195, 2006     

不含三角形图的正常染色路和正常染色圈

图G为边染色图,对G中的任一顶点v,定义v的色度dc（v）：G中与顶点v相关联的边中不同染色的数目.用δc（G）表示图G的最小色度,即δc（G）=min{dc（v）：v∈G}.若图G为不含三角形的边染色图,且δc（G）≥2,则G含长为4d-2的正常染色路或长至少为2d-2的正常染色圈.     

Partitioning complete graphs by heterochromatic trees

A heterochromatic tree is an edge-colored tree in which any two edges have different colors. The heterochromatic tree partition number of an r-edge-colored graph G, denoted by t _r (G), is the minimum positive integer p such that whenever the edges of the graph G are colored with r colors, the vertices of G can be covered by at most p vertex-disjoint heterochromatic trees. In this paper we determine the heterochromatic tree partition number of r-edge-colored complete graphs. We also find at most t _r (K _n ) vertex-disjoint heterochromatic trees to cover all the vertices in polynomial time for a given r-edge-coloring of K _n .     

Planar graph colorings without short monochromatic cycles

It is well known that every planar graph G is 2‐colorable in such a way that no 3‐cycle of G is monochromatic. In this paper, we prove that G has a 2‐coloring such that no cycle of length 3 or 4 is monochromatic. The complete graph K₅ does not admit such a coloring. On the other hand, we extend the result to K₅‐minor‐free graphs. There are planar graphs with the property that each of their 2‐colorings has a monochromatic cycle of length 3, 4, or 5. In this sense, our result is best possible. © 2004 Wiley Periodicals, Inc. J Graph Theory 46: 25–38, 2004     

Decompositions of complete graphs into triangles and Hamilton cycles

For all odd integers n ≥ 1, let G_n denote the complete graph of order n, and for all even integers n ≥ 2 let G_n denote the complete graph of order n with the edges of a 1‐factor removed. It is shown that for all non‐negative integers h and t and all positive integers n, G_n can be decomposed into h Hamilton cycles and t triangles if and only if nh + 3t is the number of edges in G_n. © 2004 Wiley Periodicals, Inc.     

Decomposition of complete equipartite graphs into paths and cycles of length 2p

Let $P_k$ and $C_k$ respectively denote a path and a cycle on k vertices. In this paper, we give necessary and sufficient conditions for the existence of a complete $\{P_{2p+1},C_{2p}\}$-decomposition of even regular complete equipartite graphs for all prime p.     

Maximal sets of hamilton cycles in complete multipartite graphs

A set S of edge‐disjoint hamilton cycles in a graph G is said to be maximal if the edges in the hamilton cycles in S induce a subgraph H of G such that G ? E(H) contains no hamilton cycles. In this context, the spectrum S(G) of a graph G is the set of integers m such that G contains a maximal set of m edge‐disjoint hamilton cycles. This spectrum has previously been determined for all complete graphs and for all complete bipartite graphs. In this paper, we extend these results to the complete multipartite graphs. © 2003 Wiley Periodicals, Inc. J Graph Theory 43: 49–66, 2003     

Line graphs of complete multipartite graphs have small cycle double covers

It has been shown by MacGillivray and Seyffarth (Austral. J. Combin. 24 (2001) 91) that bridgeless line graphs of complete graphs, complete bipartite graphs, and planar graphs have small cycle double covers. In this paper, we extend the result for complete bipartite graphs, and show that the line graph of any complete multipartite graph (other than K_1,2) has a small cycle double cover.     

Decompositions of complete multipartite graphs

This paper answers a recent question of Dobson and Maruši? by partitioning the edge set of a complete bipartite graph into two parts, both of which are edge sets of arc-transitive graphs, one primitive and the other imprimitive. The first member of the infinite family is the one constructed by Dobson and Maruši?.     

Factorizations of complete multipartite graphs into generalized cubes

For a positive integer d, the usual d‐dimensional cube Q_d is defined to be the graph (K₂)^d, the Cartesian product of d copies of K₂. We define the generalized cube Q(K_k, d) to be the graph (K_k)^d for positive integers d and k. We investigate the decomposition of the complete multipartite graph K into factors that are vertex‐disjoint unions of generalized cubes Q(K_k, d_i), where k is a power of a prime, n and j are positive integers with j ≤ n, and the d_i may be different in different factors. We also use these results to partially settle a problem of Kotzig on Q_d‐factorizations of K_n. © 2000 John Wiley & Sons, Inc. J Graph Theory 33: 144–150, 2000