Acyclic edge colourings of graphs with large girth

An edge colouring of a graph G is called acyclic if it is proper and every cycle contains at least three colours. We show that for every , there exists a such that if G has maximum degree Δ and girth at least g then G admits an acyclic edge colouring with colours. © 2016 Wiley Periodicals, Inc. Random Struct. Alg., 50, 511–533, 2017     

Edge coloring by total labelings of outerplanar graphs

An edge coloring totalk-labeling is a labeling of the vertices and the edges of a graph G with labels{1,2,...,k}such that the weights of the edges defne a proper edge coloring of G.Here the weight of an edge is the sum of its label and the labels of its two end vertices.This concept was introduce by Brandt et al.They defnedχt(G)to be the smallest integer k for which G has an edge coloring total k-labeling and proposed a question:Is there a constant K withχt(G)≤Δ(G)+12+K for all graphs G of maximum degreeΔ(G)?In this paper,we give a positive answer for outerplanar graphs by showing thatχt(G)≤Δ(G)+12+1 for each outerplanar graph G with maximum degreeΔ(G).     

Boundary Chromatic Polynomial

We consider proper colorings of planar graphs embedded in the annulus, such that vertices on one rim can take Q _s colors, while all remaining vertices can take Q colors. The corresponding chromatic polynomial is related to the partition function of a boundary loop model. Using results for the latter, the phase diagram of the coloring problem (with real Q and Q _s) is inferred, in the limits of two-dimensional or quasi one-dimensional infinite graphs. We find in particular that the special role played by Beraha numbers for the usual chromatic polynomial does not extend to the case Q≠Q _s. The agreement with (scarce) existing numerical results is perfect; further numerical checks are presented here.     

Oriented list colorings of graphs

A 2‐assignment on a graph G = (V,E) is a collection of pairs L(v) of allowed colors specified for all vertices v ∈V. The graph G (with at least one edge) is said to have oriented choice number 2 if it admits an orientation which satisfies the following property: For every 2‐assignment there exists a choice c(v)∈L(v) for all v ∈V such that (i) if c(v) = c(w), then vw ∉ E, and (ii) for every ordered pair (a,b) of colors, if some edge oriented from color a to color b occurs, then no edge is oriented from color b to color a. In this paper we characterize the following subclasses of graphs of oriented choice number 2: matchings; connected graphs; graphs containing at least one cycle. In particular, the first result (which implies that the matching with 11 edges has oriented choice number 2) proves a conjecture of Sali and Simonyi. © 2001 John Wiley & Sons, Inc. J Graph Theory 36: 217–229, 2001     

Some new bounds for the maximum number of vertex colorings of a (v,e)-graph

Let f(v, e, λ) denote the maximum number of proper vertex colorings of a graph with v vertices and e edges in λ colors. In this paper we present some new upper bounds for f(v, e, λ). In particular, a new notion of pseudo-proper colorings of a graph is given, which allows us to significantly improve the upper bounds for f(v, e, 3) given by Lazebnik and Liu in the case where e > v²/4. © 1998 John Wiley & Sons, Inc. J. Graph Theory 28: 115–128, 1998     

Almost nonpreemptive schedules

Graph-theoretical models are described for solving preemptive and nonpreemptive scheduling problems with renewable resources. Conditions are obtained for nonpreemptive schedules to exist. These results may be applied for reducing the preemptions in the schedules obtained by the two-phase method developed for preemptive scheduling on unrelated processors.     

3‐colorability of 4‐regular hamiltonian graphs

On the model of the cycle‐plus‐triangles theorem, we consider the problem of 3‐colorability of those 4‐regular hamiltonian graphs for which the components of the edge‐complement of a given hamiltonian cycle are non‐selfcrossing cycles of constant length ≥ 4. We show that this problem is NP‐complete. © 2002 Wiley Periodicals, Inc. J Graph Theory 42: 125–140, 2003     

Acyclic systems of representatives and acyclic colorings of digraphs

A natural digraph analog of the graph theoretic concept of “an independent set” is that of “an acyclic set of vertices,” namely a set not spanning a directed cycle. By this token, an analog of the notion of coloring of a graph is that of decomposition of a digraph into acyclic sets. We extend some known results on independent sets and colorings in graphs to acyclic sets and acyclic colorings of digraphs. In particular, we prove bounds on the topological connectivity of the complex of acyclic sets, and using them we prove sufficient conditions for the existence of acyclic systems of representatives of a system of sets of vertices. These bounds generalize a result of Tardos and Szabó. We prove a fractional version of a strong‐acyclic‐coloring conjecture for digraphs. © 2008 Wiley Periodicals, Inc. J Graph Theory 59: 177–189, 2008     

Limits of Near‐Coloring of Sparse Graphs

Let be nonnegative integers. A graph G is ‐colorable if its vertex set can be partitioned into sets such that the graph induced by has maximum degree at most d for , while the graph induced by is an edgeless graph for . In this article, we give two real‐valued functions and such that any graph with maximum average degree at most is ‐colorable, and there exist non‐‐colorable graphs with average degree at most . Both these functions converge (from below) to when d tends to infinity. This implies that allowing a color to be d‐improper (i.e., of type ) even for a large degree d increases the maximum average degree that guarantees the existence of a valid coloring only by 1. Using a color of type (even with a very large degree d) is somehow less powerful than using two colors of type (two stable sets).