Arc-Transitive Graph
An arc-transitive graph, sometimes also called a flag-transitive graph, is a graph whose graph automorphism group acts transitively on its graph arcs (Godsil and Royle 2001, p. 59).
More generally, a graph π G
is called π s
-arc-transitive (or simply "π s
-transitive") with π s>=1
if it has an s-route
and if there is always a graph automorphism
of π G
sending each s-route onto any other π s
-s-route (Harary 1994, p. 173).
In other words, a graph is π s
-transitive if its automorphism
group acts transitively on all the s-routes
(Holton and Sheehan 1993, p. 203). Note that various authors prefer symbols
other than π s
,
for example π n
(Harary 1994, p. 173) or π t
.
Arc-transitivity is an even stronger property than edge-transitivity or vertex-transitivity, so arc-transitive graphs have a very high degree of symmetry.
A 0-transitive graph is vertex-transitive. A 1-transitive graph is simply called an "arc-transitive graph" or even
a "transitive graph." More confusingly still, arc-transitive graphs (and
therefore in fact π s
-transitive
graphs for π s>=1
)
are sometimes called symmetric graphs (Godsil
and Royle 2001, p. 59). This terminology conflict is particularly confusing
since, as first shown by Bouwer (1970), graphs exist that are symmetric
(in the sense of both edge- and vertex-transitive) but not arc-transitive, the smallest
known example being the Doyle graph.
Symmetric non-arc-transitive graphs were first considered by Tutte (1966), who showed that any such graph must be regular
of even degree. The first examples were given by Bouwer (1970), who gave a constructive
proof for a connected π 2n
-regular symmetric arc-intransitive graphs for all integers
π n>=2
.
The smallest such Bouwer graph has 54 vertices and
is quartic. Another example of a symmetric
non-arc-transitive graph is the 6-regular nonplanar diameter-3 graph on 111 vertices
discovered by G. Exoo (E. Weisstein, Jul. 16, 2018).
A connected graph π G
with no endpoints (i.e., with minimum vertex degree
π delta(G)>=2
)
is said to be strictly π s
-transitive (with π s>=1
) if π G
is π s
-transitive but not π (s+1)
-transitive (Holton and Sheehan 1993, p. 206). Such
graphs have also been called π s
-regular (Tutte 1947, Coxeter 1950, Frucht 1952) and π s
-unitransitive (Harary 1994, p. 174). A strictly π s
-transitive graph π G
has exactly one automorphism π alpha
such that π alphaW_1=W_2
for any two π s
-routes π W_1
and π W_2
of π G
(Harary 1994, p. 174).
The cycle graph π C_n
(for π n>=3
) is π s
-transitive for all π s>=0
, as is π kC_n
for any positive integer π k
(Holton and Sheehan 1993, p. 204).
The numbers of arc-transitive graphs on π n=1
, 2, ... vertices are 0, 1, 1, 3, 2, 6, 2, 8, 5, ... (OEIS
A180240), as summarized in the table below,
where π P_n
denotes a path graph, π C_n
a cycle graph, π nP_2
is a ladder rung graph,
π K_n
a complete graph, π K_(m,n)
a complete bipartite
graph, π K_(m,n,p)
a complete tripartite graph, π Q_n
a hypercube graph, π Ci_n(k_1,...,k_m)
a circulant
graph, and π kG
a graph union of π k
copies of π G
.
The numbers of connected arc-transitive graphs on π n=1
, 2, ... vertices are 0, 1, 1, 2, 2, 4, 2, 5, 4, 8, ... (OEIS
A286280).
A tree may be π s
-transitive yet not π (s-1)
-transitive. For example, the star
graph π S_n
with π n>=2
is edge-transitive and 2-transitive, but not 1-transitive. However, an π s
-transitive graph that is not a tree is
also π k
-transitive
for all π 0<=k<s
(Holton and Sheehan 1993, p. 204), and so is most clearly termed "strictly
π s
-transitive."
The path graph π P_(s+1)
is π s
-transitive (Holton and Sheehan 1993, p. 203), and a cycle graph π C_n
(π n>=3
) is π infty
-transitive (Holton and Sheehan 1993, pp. 204 and
209, Exercise 6).
If π G
is an π s
-transitive
graph, then π nG
is also π s
-transitive
for any π n>=1
(Holton and Sheehan 1993, p. 204). But if π G
is disconnected and not the union of π n
copies of a single type of graph, then it is not vertex-transitive
and hence not arc-transitive. Disconnected graphs therefore either have the same
π s
-transitivity
as their identical connected components, or are not arc-transitive (if their components
are not identical). The π s
-transitivity of disconnected graphs is therefore trivial.
In 1947, Tutte showed that for any strictly π s
-transitive connected cubic graph,
π s<=5
(Holton and Sheehan 1993, p. 207; Harary 1994, p. 175; Godsil and Royle
2001, p. 63). Weiss (1974) subsequently established the very deep
result that for any regular connected strictly π s
-transitive graph of degree π r>=3
, π s<=5
or π s=7
(Holton and Sheehan 1993, p. 208; Godsil and Royle
2001, p. 63).
If π X
is a vertex-transitive cubic
graph on π n
vertices and π G
is its automorphism group, then if 3 divides
the order of the stabilizer π G_u
of a vertex π u
, then π X
is arc-transitive (Godsil and Royle 2001, p. 75).
Because there are no π s
-transitive cubic graphs for
π s>5
,
there are also no strictly π s
-transitive ones (Harary 1994, p. 175). The 3-cages are
strictly π s
-transitive
for π 3<=s<=7
(Harary 1994, p. 175), but there also exist strictly π s
-transitive graphs for π s<=5
which are not cage graphs
(Harary 1994, p. 175). These include the strictly 1-transitive graph of girth
12 on 432 nodes discovered by Frucht (1952) constructed as the Cayley
graph of the permutations (2, 1, 5, 8, 3, 6, 7, 4, 9), (3, 6, 1, 4, 9, 2, 7,
8, 5), and (4, 3, 2, 1, 5, 7, 6, 8, 9) and now more commonly known as the cubic
symmetric graph π F_(432)C
; the strictly 2-transitive cubical,
dodecahedral graphs, MΓΆbius-Kantor
graph π GP(8,3)
,
and Nauru graph; and the strictly 3-transitive Desargues graph π GP(10,3)
(Coxeter 1950). Some strictly π s
-transitive graphs are illustrated above and summarized in
the table below (partially based on the tables given by Coxeter 1950 and Harary 1994,
p. 175).
| π s | π V | π d | graph |
| 1 | 432 | 3 | cubic
symmetric graph π F_(432)C |
| 2 | 4 | 3 | tetrahedral
graph π K_4 |
| 2 | 8 | 3 | cubical graph π Q_3 |
| 2 | 16 | 3 | MΓΆbius-Kantor graph |
| 2 | 16 | 4 | tesseract graph π Q_4 |
| 2 | 20 | 3 | dodecahedral graph |
| 2 | 24 | 3 | Nauru graph |
| 2 | 32 | 5 | 5-hypercube graph π Q_5 |
| 2 | 32 | 6 | Kummer graph |
| 2 | 64 | 6 | 6-hypercube graph π Q_6 |
| 2 | 128 | 7 | 7-hypercube graph π Q_7 |
| 2 | 256 | 8 | 8-hypercube
graph π Q_8 |
| 3 | 6 | 3 | utility graph π K_(3,3) |
| 3 | 20 | 3 | Desargues graph |
| 4 | 14 | 3 | Heawood graph |
| 5 | 30 | 3 | Tutte 8-cage |
See also
Bouwer Graph, Cubic Symmetric Graph, Doyle Graph, Edge-Transitive Graph, Graph Arc, Group Orbit, k-Transitive Group, s-Route, Symmetric Graph, Transitive, Transitive Closure, Transitive Digraph, Transitive Group, Vertex-Transitive GraphExplore with Wolfram|Alpha
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References
Bouwer, Z. "Vertex and Edge Transitive, But Not 1-Transitive Graphs." Canad. Math. Bull. 13, 231-237, 1970.Conder, M. and Nedela, R. "Symmetric Cubic Graphs of Small Girth." J. Combin. Th. Ser. B 97, 757-768, 2007.Conder, M. "All Symmetric Graphs of Order 2 to 30." Apr. 2014. https://www.math.auckland.ac.nz/~conder/symmetricgraphs-orderupto30.txt.Coxeter, H. S. M. "Self-Dual Configurations and Regular Graphs." Bull. Amer. Math. Soc. 56, 413-455, 1950.Doyle, P. G. On Transitive Graphs. Senior Thesis. Cambridge, MA, Harvard College, April 1976.Doyle, P. "A 27-Vertex Graph That Is Vertex-Transitive and Edge-Transitive But Not L-Transitive." October 1998. http://hilbert.dartmouth.edu/~doyle/docs/bouwer/bouwer/bouwer.html.Frucht, R. "A One-Regular Graph of Degree Three." Canad. J. Math. 4, 240-247, 1952.Gardiner, A. "Arc Transitivity in Graphs." Quart. J. Math. 24, 399-407, 1973.Gardiner, A. "Arc Transitivity in Graphs II." Quart. J. Math. 25, 163-167, 1974.Gardiner, A. "Arc Transitivity in Graphs III." Quart. J. Math. 27, 313-323, 1976.Godsil, C. and Royle, G. "Arc-Transitive Graphs." Ch. 4 in Algebraic Graph Theory. New York: Springer-Verlag, pp. 59-76, 2001.Harary, F. Graph Theory. Reading, MA: Addison-Wesley, pp. 174-175 and 200, 1994.Holt, D. F. "A Graph Which Is Edge Transitive But Not Arc Transitive." J. Graph Th. 5, 201-204, 1981.Holton, D. A. and Sheehan, J. The Petersen Graph. Cambridge, England: Cambridge University Press, pp. 202-210, 1993.Lauri, J. and Scapellato, R. Topics in Graph Automorphisms and Reconstruction. Cambridge, England: Cambridge University Press, 2003.Skiena, S. Implementing Discrete Mathematics: Combinatorics and Graph Theory with Mathematica. Reading, MA: Addison-Wesley, pp. 162 and 174, 1990.Sloane, N. J. A. Sequences A180240 and A286280 in "The On-Line Encyclopedia of Integer Sequences."Tutte, W. T. "A Family of Cubical Graphs." Proc. Cambridge Philos. Soc. 43, 459-474, 1947.Tutte, W. T. Connectivity in Graphs. Toronto, CA: University of Toronto Press, 1966.Weiss, R. M. "Γber π s
-regulΓ€re Graphen." J. Combin. Th. Ser. B 16, 229-233, 1974.
Referenced on Wolfram|Alpha
Arc-Transitive GraphCite this as:
Weisstein, Eric W. "Arc-Transitive Graph." From MathWorld--A Wolfram Resource. https://mathworld.wolfram.com/Arc-TransitiveGraph.html