Graph property

While graph drawing and graph representation are valid topics in graph theory, in order to focus only on the abstract structure of graphs, a graph property is defined to be a property preserved under all possible isomorphisms of a graph. In other words, it is a property of the graph itself, not of a specific drawing or representation of the graph. Informally, the term "graph invariant" is used for properties expressed quantitatively, while "property" usually refers to descriptive characterizations of graphs. For example, the statement "graph does not have vertices of degree 1" is a "property" while "the number of vertices of degree 1 in a graph" is an "invariant". More formally, a graph property is a class of graphs with the property that any two isomorphic graphs either both belong to the class, or both do not belong to it. ==Properties of properties==

Many graph properties are well-behaved with respect to certain natural partial orders or preorders defined on graphs: • A graph property P is hereditary if every induced subgraph of a graph with property P also has property P. For instance, being a perfect graph or being a chordal graph are hereditary properties. • A graph property is monotone if every subgraph of a graph with property P also has property P. For instance, being a bipartite graph or being a triangle-free graph is monotone. Every monotone property is hereditary, but not necessarily vice versa; for instance, subgraphs of chordal graphs are not necessarily chordal, so being a chordal graph is not monotone. • A graph property is minor-closed if every graph minor of a graph with property P also has property P. For instance, being a planar graph is minor-closed. Every minor-closed property is monotone, but not necessarily vice versa; for instance, minors of triangle-free graphs are not necessarily themselves triangle-free. These definitions may be extended from properties to numerical invariants of graphs: a graph invariant is hereditary, monotone, or minor-closed if the function formalizing the invariant forms a monotonic function from the corresponding partial order on graphs to the real numbers. Additionally, graph invariants have been studied with respect to their behavior with regard to disjoint unions of graphs: • A graph invariant is additive if, for all two graphs G and H, the value of the invariant on the disjoint union of G and H is the sum of the values on G and on H. For instance, the number of vertices is additive. • A graph invariant is multiplicative if, for all two graphs G and H, the value of the invariant on the disjoint union of G and H is the product of the values on G and on H. For instance, the Hosoya index (number of matchings) is multiplicative. • A graph invariant is maxing if, for all two graphs G and H, the value of the invariant on the disjoint union of G and H is the maximum of the values on G and on H. For instance, the chromatic number is maxing. In addition, graph properties can be classified according to the type of graph they describe: whether the graph is undirected or directed, whether the property applies to multigraphs, etc. ==Values of invariants==

The target set of a function that defines a graph invariant may be one of: • A truth-value, true or false, for the indicator function of a graph property. • An integer, such as the number of vertices or chromatic number of a graph. • A real number, such as the fractional chromatic number of a graph. • A sequence of integers, such as the degree sequence of a graph. • A polynomial, such as the Tutte polynomial of a graph. ==Graph invariants and graph isomorphism==

Easily computable graph invariants are instrumental for fast recognition of graph isomorphism, or rather non-isomorphism, since for any invariant at all, two graphs with different values cannot (by definition) be isomorphic. Two graphs with the same invariants may or may not be isomorphic, however. A graph invariant I(G) is called complete if the identity of the invariants I(G) and I(H) implies the isomorphism of the graphs G and H. Finding an efficiently computable such invariant (the problem of graph canonization) would imply an easy solution to the challenging graph isomorphism problem. However, even polynomial-valued invariants such as the chromatic polynomial are not usually complete. The claw graph and the path graph on 4 vertices both have the same chromatic polynomial, for example. ==Examples==

Properties • Connected graphs • Bipartite graphs • Planar graphs • Triangle-free graphs • Perfect graphs • Eulerian graphs • Hamiltonian graphs Integer invariants • Order, the number of vertices • Size, the number of edges • Number of connected components • Circuit rank, a linear combination of the numbers of edges, vertices, and components • diameter, the longest of the shortest path lengths between pairs of vertices • girth, the length of the shortest cycle • Vertex connectivity, the smallest number of vertices whose removal disconnects the graph • Edge connectivity, the smallest number of edges whose removal disconnects the graph • Chromatic number, the smallest number of colors for the vertices in a proper coloring • Chromatic index, the smallest number of colors for the edges in a proper edge coloring • Choosability (or list chromatic number), the least number k such that G is k-choosable • Independence number, the largest size of an independent set of vertices • Clique number, the largest order of a complete subgraph • Arboricity • Graph genus • Pagenumber • Hosoya index • Wiener index • Colin de Verdière graph invariant • Boxicity Real number invariants • Clustering coefficient • Betweenness centrality • Fractional chromatic number • Algebraic connectivity • Isoperimetric number • Estrada index • Strength Sequences and polynomials • Degree sequence • Graph spectrum • Characteristic polynomial of the adjacency matrix • Chromatic polynomial, the number of k-colorings viewed as a function of k • Tutte polynomial, a bivariate function that encodes much of the graph's connectivity Edge partition • (a, b)-decomposition for any natural a,b ==See also==