Paley graph

Definition

Suppose ${\displaystyle q}$ is a prime power such that ${\displaystyle q\equiv 1{\pmod {4}}}$. The Paley graph on ${\displaystyle q}$ vertices, denoted ${\displaystyle P_{q}}$ or ${\displaystyle QR(q)}$, is defined as follows:

1. The vertex set is identified with the elements of the field ${\displaystyle \mathbb {F} _{q}}$ of ${\displaystyle q}$ elements. This field is unique up to field isomorphism.
2. Given any two distinct vertices ${\displaystyle a,b\in \mathbb {F} _{q}}$, ${\displaystyle a}$ and ${\displaystyle b}$ are defined to be adjacent if and only if ${\displaystyle a-b}$ is a square in ${\displaystyle \mathbb {F} _{q}^{*}}$.

The significance of ${\displaystyle q\equiv 1{\pmod {4}}}$ is that this forces -1 to be a square, hence ${\displaystyle a-b}$ is a square if and only if ${\displaystyle b-a}$ is a square. This is necessary because we want the definition of adjacency to be symmetric in the two vertices.

For a prime power ${\displaystyle q\equiv 3{\pmod {4}}}$, we can consider instead the Paley digraph.

Arithmetic functions

Size measures

Function	Value	Explanation
size of vertex set	${\displaystyle q}$	By definition, the vertex set is the underlying set of a field of size ${\displaystyle q}$
size of edge set	${\displaystyle q(q-1)/4}$	The number of quadratic residues is ${\displaystyle (q-1)/2}$, hence this is the degree of each vertex. We now use the handshaking lemma.

Numerical invariants associated with vertices

Since the graph is a vertex-transitive graph, any numerical invariant associated to a vertex must be equal on all vertices of the graph. Below are listed some of these invariants:

Function	Value	Explanation
degree of a vertex	${\displaystyle (q-1)/2}$	This equals the number of quadratic residues in ${\displaystyle \mathbb {F} _{q}^{\ast }}$, which is the size of the image of the square map ${\displaystyle x\mapsto x^{2}}$, whose domain has size ${\displaystyle q-1}$ and kernel has size 2. The image thus has size ${\displaystyle (q-1)/2}$. Note that we are using that ${\displaystyle q}$ is odd.
eccentricity of a vertex	2	Follows from every element of a finite field is expressible as a sum of two squares

Other numerical invariants

Function	Value	Explanation
clique number	no easy formula, but generally grows with ${\displaystyle q}$	Note that ${\displaystyle q=5}$ is the only case where the clique number is 2; for ${\displaystyle q\geq 9}$, the clique number is at least 3 because of the presence of adjacent quadratic residues -- the number of adjacent quadratic residues is ${\displaystyle (q-5)/4}$. ${\displaystyle q=17}$ is the largest value for which the clique number is 3. By Ramsey theory, we know that if ${\displaystyle q\geq R(m,m)}$, then the clique number is at least ${\displaystyle m}$.
independence number	same as clique number	The two numbers are equal because the Paley graph is a self-complementary graph and independence number equals clique number of complement
chromatic number	Fill this in later	Fill this in later
radius of a graph	2	Due to vertex-transitivity, the radius equals the eccentricity of any vertex, which has been computed above.
diameter of a graph	2	Due to vertex-transitivity, the diameter equals the eccentricity of any vertex, which has been computed above.
girth of a graph	3 (except the case of ${\displaystyle P_{5}}$)	The girth of ${\displaystyle P_{5}}$ is 5. Note that for all higher ${\displaystyle q}$, the girth of the graph is 3, due to the fact that there are ${\displaystyle (q-5)/4}$ pairs of nonzero quadratic residues that differ by 1, and this number is positive whenever ${\displaystyle q>5}$.
circuit rank	${\displaystyle q(q-5)/4+1}$ ${\displaystyle =(q-1)(q-4)/4}$	The circuit rank is number of edges - number of vertices + number of connected components. This becomes ${\displaystyle q(q-1)/4-q+1}$ which simplifies to ${\displaystyle q(q-5)/4+1}$.