Graph labeling
In the mathematical discipline of graph theory, a graph labeling is the assignment of labels, traditionally represented by integers, to the edges or vertices, or both, of a graph.[1]
Formally, given a graph G = (V, E), a vertex labeling is a function of V to a set of labels. A graph with such a function defined is called a vertex-labeled graph. Likewise, an edge labeling is a function of E to a set of labels. In this case, the graph is called an edge-labeled graph.
When the edge labels are members of an ordered set (e.g., the real numbers), it may be called a weighted graph.
When used without qualification, the term labeled graph generally refers to a vertex-labeled graph with all labels distinct. Such a graph may equivalently be labeled by the consecutive integers {1, …, | V |}, where | V | is the number of vertices in the graph.[1] For many applications, the edges or vertices are given labels that are meaningful in the associated domain. For example, the edges may be assigned weights representing the "cost" of traversing between the incident vertices.[2]
In the above definition a graph is understood to be a finite undirected simple graph. However, the notion of labeling may be applied to all extensions and generalizations of graphs. For example, in automata theory and formal language theory it is convenient to consider labeled multigraphs, i.e., a pair of vertices may be connected by several labeled edges.[3]
History
Most graph labelings trace their origins to labelings presented by Alex Rosa in his 1967 paper.[4] Rosa identified three types of labelings, which he called α-, β-, and ρ-labelings.[5] β-labelings were later renamed graceful by S. W. Golomb and the name has been popular since.
Special cases
Graceful labeling
A graph is known as graceful when its vertices are labeled from 0 to | E |, the size of the graph, and this labeling induces an edge labeling from 1 to | E |. For any edge e, the label of e is the positive difference between the two vertices incident with e. In other words, if e is incident with vertices labeled i and j, e will be labeled | i − j |. Thus, a graph G = (V, E) is graceful if and only if there exists an injection that induces a bijection from E to the positive integers up to | E |.
In his original paper, Rosa proved that all eulerian graphs with size equivalent to 1 or 2 (mod 4) are not graceful. Whether or not certain families of graphs are graceful is an area of graph theory under extensive study. Arguably, the largest unproven conjecture in graph labeling is the Ringel–Kotzig conjecture, which hypothesizes that all trees are graceful. This has been proven for all paths, caterpillars, and many other infinite families of trees. Kotzig himself has called the effort to prove the conjecture a "disease."[6]
Edge-graceful labeling
An edge-graceful labeling on a simple graph (no loops or multiple edges) on p vertices and q edges is a labelling of the edges by distinct integers in {1, …, q} such that the labeling on the vertices induced by labeling a vertex with the sum of the incident edges taken modulo p assigns all values from 0 to p − 1 to the vertices. A graph G is said to be edge-graceful if it admits an edge-graceful labeling.
Edge-graceful labelings were first introduced by S. Lo in 1985.[7]
A necessary condition for a graph to be edge-graceful is Lo's condition:
Harmonious labeling
A harmonious labeling on a graph G is an injection from the vertices of G to the group of integers modulo k, where k is the number of edges of G, that induces a bijection between the edges of G and the numbers modulo k by taking the edge label for an edge (x, y) to be the sum of the labels of the two vertices x, y (mod k). A harmonious graph is one that has a harmonious labeling. Odd cycles are harmonious, as is the Petersen graph. It is conjectured that trees are all harmonious if one vertex label is allowed to be reused.[8] The seven-page book graph K1,7 × K2 provides an example of a graph that is not harmonious.[9]
Graph coloring
A graph coloring is a subclass of graph labelings. A vertex coloring assigns different labels to adjacent vertices; an edge colouring assigns different labels to adjacent edges.
Lucky labeling
A lucky labeling of a graph G is an assignment of positive integers to the vertices of G such that if S(v) denotes the sum of the labels on the neighbours of v, then S is a vertex coloring of G. The lucky number of G is the least k such that G has a lucky labeling with the integers {1, …, k}.[10]
References
- 1 2 Weisstein, Eric W. "Labeled graph". MathWorld.
- ↑ "Different Aspects of Coding Theory", by Robert Calderbank (1995) ISBN 0-8218-0379-4, p. 53"
- ↑ "Developments in Language Theory", Proc. 9th. Internat.Conf., 2005, ISBN 3-540-26546-5, p. 313
- ↑ Gallian, J. "A Dynamic Survey of Graph Labelings, 1996-2005". The Electronic Journal of Combinatorics.
- ↑ Rosa, A. "On certain valuations of vertices in a graph".
- ↑ Vietri, Andrea (2008). "Sailing towards, and then against, the graceful tree conjecture: some promiscuous results". Bull. Inst. Comb. Appl. 53: 31–46. ISSN 1183-1278. Zbl 1163.05007.
- ↑ Lo, Sheng-Ping (1985). "On edge-graceful labelings of graphs". Congressus Numerantium. 50: 231–241. Zbl 0597.05054.
- ↑ Guy (2004) pp.190–191
- ↑ Gallian, Joseph A. (1998), "A dynamic survey of graph labeling", Electronic Journal of Combinatorics, 5: Dynamic Survey 6, MR 1668059.
- ↑ Czerwiński, Sebastian; Grytczuk, Jarosław; Ẓelazny, Wiktor (2009). "Lucky labelings of graphs". Inf. Process. Lett. 109 (18): 1078–1081. Zbl 1197.05125.
- Rosa, A. (1967). On certain valuations of the vertices of a graph. Theory of Graphs, Int. Symp. Rome July 1966. Gordon and Breach. pp. 349–355. Zbl 0193.53204.
- Guy, Richard K. (2004). Unsolved problems in number theory (3rd ed.). Springer-Verlag. C13. ISBN 0-387-20860-7. Zbl 1058.11001.