Proper path‐factors and interval edge‐coloring of (3,4)‐biregular bigraphs

Abstract. A proper edge coloring of a graph with colors 1, 2, 3, . . . is called an interval coloring if the colors on the edges incident to each vertex form an interval of integers. A bipartite graph is (a, b)-biregular if every vertex in one part has degree a and every vertex in the other part has degree b. It has been conjectured that all such graphs have interval colorings. We prove that all (3, 6)-biregular graphs have interval colorings and that all (3, 9)-biregular graphs having a cubic subgraph covering all vertices of degree 9 admit interval colorings. Moreover, we prove that slightly weaker versions of the conjecture hold for (3, 5)-biregular, (4, 6)-biregular and (4, 8)-biregular graphs. All our proofs are constructive and yield polynomial time algorithms for constructing the required colorings.

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“…i to z (1) i and z (2) i by two edges. A schematic of the graph L in the case when k = 3 appears in Figure 4.…”

Section: Appendixmentioning

confidence: 99%

“…Several sufficient conditions for a (3,4)-biregular graph to admit an interval coloring has been obtained [2,7,19,22]. In [6] we give a sufficient condition for a (3, 5)-biregular graph to admit an interval coloring.…”

Section: Introductionmentioning

confidence: 97%

On Interval Edge Colorings of Biregular Bipartite Graphs With Small Vertex Degrees

Casselgren

Toft

2014

Journal of Graph Theory

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“…Nevertheless, trees [11,5], regular and complete bipartite graphs [11,5], grids [9], and simple outerplanar bipartite graphs [10,6] all have interval colorings. 2 A well-known conjecture suggests that all (a, b)-biregular graphs have interval colorings (see e.g. [11,14,19]), where a bipartite graph is (a, b)-biregular if all vertices in one part have degree a and all vertices in the other part have degree b.…”

Section: Introductionmentioning

confidence: 99%

“…By results of [11,13], all (2, b)-biregular graphs admit interval colorings (the latter result was also obtained independently by Kostochka [16] and by Kamalian et al 3 ). Several sufficient conditions for a (3,4)-biregular graph G to admit an interval 6-coloring have been obtained [2,17,20]; however, it is still open whether all (3,4)-biregular graphs have interval colorings. In [8] we proved that every (3,6)-biregular graph has an interval 7-coloring and in [7] it was proved that large families of (3, 5)-biregular graphs admit interval colorings.…”

Section: Introductionmentioning

confidence: 99%

One-sided interval edge-colorings of bipartite graphs

Casselgren

Toft

2016

Discrete Mathematics

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a b s t r a c tLet G be a bipartite graph with bipartition (X, Y ). An X -interval coloring of G is a proper edge-coloring of G by integers such that the colors on the edges incident to any vertex in X form an interval. Denote by χ ′ int (G, X ) the minimum k such that G has an X -interval coloring with k colors. In this paper we give various upper and lower bounds on χ ′ int (G, X ) in terms of the vertex degrees of G. We also determine χ ′ int (G, X ) exactly for some classes of bipartite graphs G. Furthermore, we present upper bounds on χ ′ int (G, X ) for classes of bipartite graphs G with maximum degree ∆(G) at most 9: in particular, if ∆(G) = 4, then

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“…Later the theory of interval colorings was developed in e.g. [3,4,[7][8][9][10][11][12][13][14][15][21][22][23]25,27,30]. Generally, it is an NP-complete problem to determine whether a bipartite graph has an interval coloring [27].…”

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confidence: 99%

Some results on cyclic interval edge colorings of graphs

Asratian

Casselgren

2017

Journal of Graph Theory

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A proper edge coloring of a graph G with colors 1, 2, . . . , t is called a cyclic interval t-coloring if for each vertex v of G the edges incident to v are colored by consecutive colors, under the condition that color 1 is considered as consecutive to color t. We prove that a bipartite graph G of even maximum degree ∆(G) ≥ 4 admits a cyclic intervalWe also prove that every Eulerian bipartite graph G with maximum degree at most 8 has a cyclic interval coloring. Some results are obtained for (a, b)-biregular graphs, that is, bipartite graphs with the vertices in one part all having degree a and the vertices in the other part all having degree b; it has been conjectured that all these have cyclic interval colorings. We show that all (4, 7)-biregular graphs as well as all (2r −2, 2r)-biregular (r ≥ 2) graphs have cyclic interval colorings. Finally, we prove that all complete multipartite graphs admit cyclic interval colorings; this proves a conjecture of Petrosyan and Mkhitaryan.

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Proper path‐factors and interval edge‐coloring of (3,4)‐biregular bigraphs

Cited by 23 publications

References 4 publications

On Interval Edge Colorings of Biregular Bipartite Graphs With Small Vertex Degrees

On Interval Edge Colorings of Biregular Bipartite Graphs With Small Vertex Degrees

One-sided interval edge-colorings of bipartite graphs

Some results on cyclic interval edge colorings of graphs

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