In graph theory, the act of coloring generally implies the assignment of labels to vertices, edges or faces in a graph. The incidence coloring is a special graph labeling where each incidence of an edge with a vertex is assigned a color under certain constraints.
Below G denotes a simple graph with non-empty vertex set (non-empty) V(G), edge set E(G) and maximum degree Δ(G).
Definition. An incidence is defined as a pair (v, e) where
v\inV(G)
e\inE(G).
c:I(G)\to\N
\chii(G).
The concept of incidence coloring was introduced by Brualdi and Massey in 1993 who bounded it in terms of Δ(G). Initially, the incidence chromatic number of trees, complete bipartite graphs and complete graphs was found out. They also conjectured that all graphs can have an incidence coloring using Δ(G) + 2 colors (Incidence coloring conjecture - ICC). This conjecture was disproved by Guiduli, who showed that incidence coloring concept is a directed star arboricity case,[1] introduced by Alon and Algor. His counter example showed that incidence chromatic number is at most Δ(G) + O(log Δ(G)).[2]
Chen et al. found the incidence chromatic number of paths, fans, cycles, wheels, complete tripartite graph and adding edge wheels. Few years later, Shiu et al. showed that this conjecture is true for certain cubic graphs such as cubic Hamiltonian graphs. He showed that in case of outerplanar graph of maximum degree 4, the incidence chromatic number is not 5. The bounds for incidence chromatic number of various graph classes is found out now.
Proposition.
\chii(G)\ge\Delta(G)+1.
Proof. Let v be the vertex with maximum degree Δ in G. Let
e1,e2,\ldots,e\Delta
e1=\{v,w\}.
(v,e1),(v,e2),\ldots,(v,e\Delta),(w,e1)
The bound is attained by trees and complete graphs:
\chii(G)=\Delta(G)+1.
\chii(G)=\Delta(G)+1.
The main results were proved by Brualdi and Massey (1993). Shiu, Sun and Wu have proposed certain necessary conditions for graph satisfying
\chii(G)=\Delta(G)+1.
\chii(G)\le2\Delta(G).
Km,n
\chii(Cn)\le4
\chii(C3n)=3.
Several algorithms are introduced to provide incidence coloring of meshes[3] like square meshes, honeycomb meshes and hexagonal meshes. These algorithms are optimal. For each mesh, the incidence colors can be made in the linear time with the fewest colors. It is found out that ∆(G) + 1 colors are required for incidence coloring of square meshes, honeycomb meshes and hexagonal meshes.
Chen, Wang and Pang proved that if G is a Halin graph with ∆(G) > 4 then
\chii(G)=\Delta(G)+1.
\chii(G)
Shiu and Sun proved every cubic Halin graph other than
K4
If the Halin graph G contains a tree T, then
| 2) | |
| \chi | |
| i(G |
\le\Delta(T2)+\Delta(T)+8.
D.L. Chen, P.C.B. Lam and W.C. Shiu had conjectured that the incidence chromatic number of a cubic graph G is at most ∆(G) + 2. They proved this for certain cubic graphs such as Hamiltonian cubic graphs. Based on these results, M. H. Dolama, E. Sopena and X. Zhu (2004) studied the graph classes for which
\chii(G)
Consider an outerplanar graph G with cut vertex v such that G – v is the union of
H1
H2
G1
G2
H1
H2
\chii(G)
\chii(G1),\chii(G2)
1+dG(v)
dG(v)
The incidence chromatic number of an outerplanar graph G is at most ∆(G) + 2. In case of outerplanar graphs with ∆(G) > 3 the incidence chromatic number is ∆(G) + 1.
Since outerplanar graphs are K4-minor-free graphs, they accept a (Δ + 2, 2)–incidence coloring.[6] The solution for incidence chromatic number of the outerplanar graph G having Δ(G) = 3 and 2-connected outerplanar graph is still an open question.
Chordal rings are variations of ring networks. The use of chordal rings in communication is very extensive due to its advantages over the interconnection networks with ring topology and other analysed structures such as meshes, hypercubes, Cayley's graphs, etc. Arden and Lee[7] first proposed the chordal ring of degree 3, that is, the ring structured network in which every node has an extra link known as chord, to some other node in the network. Distributed loop networks are chordal rings of degree 4 which is constructed by adding 2 extra chords at every vertex in a ring network.
The chordal ring on N nodes and chord length d, denoted by CR(N,d), is a graph defined as:
\begin{align}V(G)&=\{v0,v1,\ldots,vN-1\}\\ E(G)&=\{vivj:i-j\equiv1,d\bmodN\} \end{align}
These graphs are studied due to their application in communication. Kung-Fu Ding, Kung-Jui Pai and Ro-Yu Wu studied the incidence coloring of chordal rings.[8] Several algorithms are formulated to find the incidence chromatic number of chordal rings. The major findings are:
\begin{align} \chii(CR(N,2))&=\begin{cases}5&5|N\ 6&otherwise\end{cases}\\ \chii(CR(N,3))&=\begin{cases}5&5|N\ 6&N\equiv2\bmod5\end{cases} \end{align}
Keaitsuda Nakprasit and Kittikorn Nakprasit studied the incidence coloring of powers of cycles,
| k. | |
| C | |
| n |
| k | |
| C | |
| n |
=Kn
n=(2k+1)t+r, 1\leqt, 0\leqr\leq2k.
Their results can be summarized as follows:[9]
\begin{align} \chii(C
| k) | |
| n |
&=\begin{cases}2k+1&r=0\ 2k+2&1\leqr\leqtorr=2k\end{cases}&&k\geq3\\ \chii(C
| 2) | |
| n |
&=\begin{cases}5&5|n\ 6&otherwise\end{cases} \end{align}
The relation to incidence coloring conjecture is given by the observation that
| k) | |
| \Delta(C | |
| n |
=2k.
Proposition.[10] Let G be a simple connected graph of order n, size m and domination number
\gamma.
\chii(G)\ge\tfrac{2m}{n-\gamma}.
Proof. Form a digraph D(G) from graph G by dividing each edge of G into 2 arcs in opposite directions. We can see that the total number of arcs in D(G) is 2m. According to Guiduli, the incidence coloring of G is equivalent to proper coloring of the digraph D(G), where 2 distinct arcs
\overrightarrow{uv}
\overrightarrow{xy}
\tfrac{2m}{n-\gamma}
This relation has been widely used in the characterization of (r + 1)-incidence colorable r-regular graphs. The major result on incidence coloring of r-regular graphs is: If graph G is r-regular graph, then
\chii(G)=\chii(G2)=r+1
Definition. A finite subset
A\subset\N
Definition. Let c to be an incidence coloring of G and define
Ac(v)=\{c(v,e):(v,e)\inI(G)\}.
An interval incidence coloring of G is an incidence coloring c such that for each vertex v of G the set
Ac(v)
\chiii.
\chii(G)\le\chiii(G).
\chiii
The concept of interval incidence coloring was introduced by A. Malafiejska, R. Janczewski and M. Malafiejski. They proved
\chiii(G)\le\Delta(G)
The fractional version of the incidence coloring was first introduced by Yang in 2007. An r-tuple incidence k-coloring of a graph G is the assignment of r colors to each incidence of graph G from a set of k colors such that the adjacent incidences are given disjoint sets of colors.[14] By definition, it is obvious that 1-tuple incidence k-coloring is an incidence k-coloring too.
The fractional incidence chromatic number of graph G is the infimum of the fractions
\tfrac{k}{r}
Let G be a graph with n vertices such that
G ≠ Kn,\overline{Kn}
\overline{G}
n+2\leq\chii(G)+\chii(\overline{G})\leq2n-1.
Incidence coloring game was first introduced by S. D. Andres.[15] It is the incidence version of the vertex coloring game, in which the incidences of a graph are colored instead of vertices. Incidence game chromatic number is the new parameter defined as a game-theoretic analogous of the incidence chromatic number.
The game is that two players, Alice and Bob construct a proper incidence coloring. The rules are stated below:
The incidence game chromatic number of a graph G, denoted by
ig(G)
ig(G)