Symmetric graph

In the mathematical field of graph theory, a graph $G$ is symmetric (or arc-transitive) if, given any two pairs of adjacent vertices $u 1 — v 1$ and $u 2 — v 2$ of $G$ , there is an automorphism

f:V(G)\rightarrow V(G)

such that

f(u_{1})=u_{2}

and

f(v_{1})=v_{2}.

In other words, a graph is symmetric if its automorphism group acts transitively on ordered pairs of adjacent vertices (that is, upon edges considered as having a direction). Such a graph is sometimes also called 1-arc-transitive or flag-transitive.

By definition (ignoring $u 1$ and $u 2$ ), a symmetric graph without isolated vertices must also be vertex-transitive. Since the definition above maps one edge to another, a symmetric graph must also be edge-transitive. However, an edge-transitive graph need not be symmetric, since $a—b$ might map to $c—d$ , but not to $d—c$ . Star graphs are a simple example of being edge-transitive without being vertex-transitive or symmetric. As a further example, semi-symmetric graphs are edge-transitive and regular, but not vertex-transitive.

Every connected symmetric graph must thus be both vertex-transitive and edge-transitive, and the converse is true for graphs of odd degree. However, for even degree, there exist connected graphs which are vertex-transitive and edge-transitive, but not symmetric. Such graphs are called half-transitive. The smallest connected half-transitive graph is Holt's graph, with degree 4 and 27 vertices. Confusingly, some authors use the term "symmetric graph" to mean a graph which is vertex-transitive and edge-transitive, rather than an arc-transitive graph. Such a definition would include half-transitive graphs, which are excluded under the definition above.

A distance-transitive graph is one where instead of considering pairs of adjacent vertices (i.e. vertices a distance of 1 apart), the definition covers two pairs of vertices, each the same distance apart. Such graphs are automatically symmetric, by definition.

A $t$ -arc is defined to be a sequence of $t + 1$ vertices, such that any two consecutive vertices in the sequence are adjacent, and with any repeated vertices being more than 2 steps apart. A $t$ -transitive graph is a graph such that the automorphism group acts transitively on $t$ -arcs, but not on ( $t + 1$ )-arcs. Since 1-arcs are simply edges, every symmetric graph of degree 3 or more must be $t$ -transitive for some $t$ , and the value of $t$ can be used to further classify symmetric graphs. The cube is 2-transitive, for example.

Note that conventionally the term "symmetric graph" is not complementary to the term "asymmetric graph," as the latter refers to a graph that has no nontrivial symmetries at all.

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Graph families defined by their automorphisms
distance-transitive	→	distance-regular	←	strongly regular
↓
symmetric (arc-transitive)	←	t-transitive, $t \geq 2$		skew-symmetric
↓
_{(if connected)} vertex- and edge-transitive	→	edge-transitive and regular	→	edge-transitive
↓		↓		↓
vertex-transitive	→	regular	→	_{(if bipartite)} biregular
↑
Cayley graph	←	zero-symmetric		asymmetric