In graph theory, a strongly regular graph (SRG) is a regular graph G = (V, E) with v vertices and degree k such that for some given integers
Such a strongly regular graph is denoted by srg(v, k, λ, μ); its "parameters" are the numbers in (v, k, λ, μ). Its complement graph is also strongly regular: it is an srg(v, v − k − 1, v − 2 − 2k + μ, v − 2k + λ).
A strongly regular graph is a distance-regular graph with diameter 2 whenever μ is non-zero. It is a locally linear graph whenever λ = 1.
A strongly regular graph is denoted as an srg(v, k, λ, μ) in the literature. By convention, graphs which satisfy the definition trivially are excluded from detailed studies and lists of strongly regular graphs. These include the disjoint union of one or more equal-sized complete graphs,[1][2] and their complements, the complete multipartite graphs with equal-sized independent sets.
Andries Brouwer and Hendrik van Maldeghem (see #References) use an alternate but fully equivalent definition of a strongly regular graph based on spectral graph theory: a strongly regular graph is a finite regular graph that has exactly three eigenvalues, only one of which is equal to the degree k, of multiplicity 1. This automatically rules out fully connected graphs (which have only two distinct eigenvalues, not three) and disconnected graphs (for which the multiplicity of the degree k is equal to the number of different connected components, which would therefore exceed one). Much of the literature, including Brouwer, refers to the larger eigenvalue as r (with multiplicity f) and the smaller one as s (with multiplicity g).
Strongly regular graphs were introduced by R.C. Bose in 1963.[3] They built upon earlier work in the 1950s in the then-new field of spectral graph theory.
A strongly regular graph is called primitive if both the graph and its complement are connected. All the above graphs are primitive, as otherwise μ = 0 or λ = k.
Conway's 99-graph problem asks for the construction of an srg(99, 14, 1, 2). It is unknown whether a graph with these parameters exists, and John Horton Conway offered a $1000 prize for the solution to this problem.[5]
The strongly regular graphs with λ = 0 are triangle free. Apart from the complete graphs on fewer than 3 vertices and all complete bipartite graphs, the seven listed earlier (pentagon, Petersen, Clebsch, Hoffman-Singleton, Gewirtz, Mesner-M22, and Higman-Sims) are the only known ones.
Every strongly regular graph with is a geodetic graph, a graph in which every two vertices have a unique unweighted shortest path.[6] The only known strongly regular graphs with are those where is 0, therefore triangle-free as well. These are called the Moore graphs and are explored below in more detail. Other combinations of parameters such as (400, 21, 2, 1) have not yet been ruled out. Despite ongoing research on the properties that a strongly regular graph with would have,[7][8] it is not known whether any more exist or even whether their number is finite.[6] Only the elementary result is known, that cannot be 1 for such a graph.
The four parameters in an srg(v, k, λ, μ) are not independent. They must obey the following relation:
The above relation is derived through a counting argument as follows:
Let I denote the identity matrix and let J denote the matrix of ones, both matrices of order v. The adjacency matrix A of a strongly regular graph satisfies two equations.
First:
which is a restatement of the regularity requirement. This shows that k is an eigenvalue of the adjacency matrix with the all-ones eigenvector.
Second:
which expresses strong regularity. The ij-th element of the left hand side gives the number of two-step paths from i to j. The first term of the right hand side gives the number of two-step paths from i back to i, namely k edges out and back in. The second term gives the number of two-step paths when i and j are directly connected. The third term gives the corresponding value when i and j are not connected. Since the three cases are mutually exclusive and collectively exhaustive, the simple additive equality follows.
Conversely, a graph whose adjacency matrix satisfies both of the above conditions and which is not a complete or null graph is a strongly regular graph.[9]
Since the adjacency matrix A is symmetric, it follows that its eigenvectors are orthogonal. We already observed one eigenvector above which is made of all ones, corresponding to the eigenvalue k. Therefore the other eigenvectors x must all satisfy where J is the all-ones matrix as before. Take the previously established equation:
and multiply the above equation by eigenvector x:
Call the corresponding eigenvalue p (not to be confused with the graph parameter) and substitute , and :
Eliminate x and rearrange to get a quadratic:
This gives the two additional eigenvalues . There are thus exactly three eigenvalues for a strongly regular matrix.
Conversely, a connected regular graph with only three eigenvalues is strongly regular.[10]
Following the terminology in much of the strongly regular graph literature, the larger eigenvalue is called r with multiplicity f and the smaller one is called s with multiplicity g.
Since the sum of all the eigenvalues is the trace of the adjacency matrix, which is zero in this case, the respective multiplicities f and g can be calculated:
As the multiplicities must be integers, their expressions provide further constraints on the values of v, k, μ, and λ.
Strongly regular graphs for which have integer eigenvalues with unequal multiplicities.
Strongly regular graphs for which are called conference graphs because of their connection with symmetric conference matrices. Their parameters reduce to
Their eigenvalues are and , both of whose multiplicities are equal to . Further, in this case, v must equal the sum of two squares, related to the Bruck–Ryser–Chowla theorem.
Further properties of the eigenvalues and their multiplicities are:
If the above condition(s) are violated for any set of parameters, then there exists no strongly regular graph for those parameters. Brouwer has compiled such lists of existence or non-existence here with reasons for non-existence if any.
As noted above, the multiplicities of the eigenvalues are given by
which must be integers.
In 1960, Alan Hoffman and Robert Singleton examined those expressions when applied on Moore graphs that have λ = 0 and μ = 1. Such graphs are free of triangles (otherwise λ would exceed zero) and quadrilaterals (otherwise μ would exceed 1), hence they have a girth (smallest cycle length) of 5. Substituting the values of λ and μ in the equation , it can be seen that , and the eigenvalue multiplicities reduce to
For the multiplicities to be integers, the quantity must be rational, therefore either the numerator is zero or the denominator is an integer.
If the numerator is zero, the possibilities are:
If the denominator is an integer t, then is a perfect square , so . Substituting:
Since both sides are integers, must be an integer, therefore t is a factor of 15, namely , therefore . In turn:
The Hoffman-Singleton theorem states that there are no strongly regular girth-5 Moore graphs except the ones listed above.