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\centerline{\bf Counting two-graphs related to trees}
\bigskip
\centerline{Peter J. Cameron}
\bigskip
Submitted: October 19, 1994; Accepted: February 8, 1995.
\bigskip
{\bf Abstract.} In an earlier paper, I showed that the classes of
pentagon-free two-graphs and of pentagon-and-hexagon-free two-graphs
could be represented in terms of trees. This paper gives formulae for
the numbers of labelled objects in each of these classes, as well
as the numbers of labelled reduced two-graphs in each class. The proofs use
various enumeration results for trees. At least some of these
results are well-known. To make the paper self-contained,
I have included proofs.
\smallskip
{\bf MOS classification:} Primary 05 C 30; secondary 05 C 05, 05 A 18.

\section 1. Trees and two-graphs

A {\it two-graph} is a pair $(X,V)$, where $X$ is a set of
points, and $V$ a set of 3-subsets of $X$, having the property that any
4-subset of $X$ contains an even number of members of $V$.

Given a graph $G$ on the vertex set $X$, the set of 3-sets carrying an odd
number of edges of $G$ forms a two-graph on $X$. Every two-graph can be
represented in this way; and graphs $G_1$ and $G_2$ represent the same
two-graph if and only if they are related by {\it switching} with respect
to a set $Y$ of vertices. (This operation consists of interchanging
adjacency and non-adjacency between $Y$ and its complement $X\setminus Y$,
while leaving edges within or outside $Y$ unchanged.) When I speak of the
{\it pentagon} and {\it hexagon} two-graphs below, I mean the two-graphs
obtained from the pentagon and hexagon graphs by this procedure.

All this material can be found in Seidel [9].

\medskip

Let $(X,V)$ be a two-graph. Define a relation $\equiv$ on $X$
by setting $x\equiv y$ if either $x=y$ or no member of $V$ contains both
$x$ and $y$. This is an equivalence relation. The two-graph is called
{\it reduced} if the relation just defined is equality. In any two-graph,
the three points of any triple in $V$ belong to different classes; and
replacing a point by an equivalent point does not affect membership in $V$
(that is, $\equiv$ is a {\it congruence}). Thus we have a `canonical
projection' onto a reduced two-graph. The original two-graph is uniquely
determined by this reduced image and the sizes of the equivalence classes.

\medskip

In [2], I gave two constructions leading from trees to two-graphs.

\medskip

\noindent{\sl Construction 1.} Let $T$ be a tree with edge set $X$. Let $V$
be the set of 3-subsets of $X$ not contained in paths in $T$. Then $(X,V)$
is a two-graph.

\proclaim Proposition 1.1. A two-graph arises from a tree by Construction~1
if and only if it contains neither the pentagon nor the hexagon as an
induced substructure. Trees $T_1$ and $T_2$ yield isomorphic two-graphs
if and only if they are themselves isomorphic.

\noindent{\sl Construction 2.} Let $T$ be a series-reduced tree (one with no
divalent vertices). Let $X$ be the set of leaves of $T$. Now $T$, being
bipartite and connected, has exactly two vertex 2-colourings; select one,
and call the colours black and white. Let $V$ consist of all 3-subsets of
$X$ such that the paths joining these vertices meet at a black vertex. Then
$(X,V)$ is a two-graph. (If we use the other colouring, we obtain the
complementary two-graph.)

\proclaim Proposition 1.2. A two-graph arises from a tree by Construction~2
if and only if it doesn't contain the pentagon as an induced substructure.
Coloured trees $T_1$ and $T_2$ yield isomorphic two-graphs if and only if
they are isomorphic (the isomorphism preserving the colours).

I shall call a two-graph {\it 5,6-free} if it arises from Construction~1,
and {\it 5-free} if it arises from Construction~2. The purpose of this
paper is to enumerate these two classes of two-graphs.

\medskip

The first construction has a group-theoretic interpretation. The {\it Coxeter
group} of a graph is defined to have a generator $s_v$ for each vertex $v$
of the graph, with the defining relations $s_v^2=1$, $(s_vs_w)^3=1$ if
$v\sim w$, and $(s_vs_w)^2=1$ if $v\not\sim w$. The set of all products of
even length in the generators forms a normal subgroup of index 2, called the
{\it even part} of the Coxeter group.

Analogously, Tsaranov [12] defined
a group with a generator $t_v$ for each vertex, having relations $t_v^3=1$,
$(t_vt_w^{-1})^2=1$ if $v\sim w$, and $(t_vt_w)^2=1$ if $v\not\sim w$. It is
readily checked that switching a graph with respect to a set of vertices
corresponds to replacing Tsaranov's generators for vertices in this set with
their inverses; so the {\it Tsaranov group} is an invariant of the switching class,
that is, of the two-graph.

Now Seidel and Tsaranov [10] showed that the Tsaranov group of the two-graph
obtained from a tree $T$ by Construction~1 is isomorphic to the even part of
the Coxeter group of $T$.

No similar group-theoretic interpretation of Construction~2 is known.

\medskip

To conclude this section, I consider briefly the enumeration problems.
According to Proposition~2, the number of unlabelled 5,6-free two-graphs is 
equal to the number of trees with $n$ edges (that is, with $n+1$ vertices).
This number was found by Otter [6]; I will not reproduce the formula here.
The sequence is listed as number 299 in Sloane [11].

Cayley's famous theorem [4] shows that the number of labelled trees on $n$
vertices is $n^{n-2}$. It follows that the number of trees with $n$ labelled
edges is $(n+1)^{n-2}$ for $n\ge2$ (this will be proved in the next section).
But this does not solve the counting problem for labelled 5,6-free two-graphs.
For example, a path with $n$ edges can be labelled in $n!/2$ ways, but yields
only one two-graph, the null one. Informally, the two-graph gives no
information about the order of edges on a path.

More precisely, define a relation $\sim$ on the edges of a tree $T$ by
$e\sim f$ if $e$ and $f$ meet at a vertex of valency~2. Let $\equiv$ be the
reflexive and transitive closure of $\sim$. Then an arbitrary permutation
of the labels within any equivalence class of $\equiv$ does not change the
two-graph. So we have to count edge labelled trees up to this relation. 
In fact, this equivalence relation coincides with the relation defined
earlier on any two-graph. Thus, reduced 5,6-free two-graphs correspond to
series-reduced trees.

For 5-free two-graphs, the difficulty is in the other direction.
Proposition~1.2 shows that, for $n\ge3$, the number of labelled 5-free
two-graphs on $n$ points is twice the number of series-reduced trees with
$n$ labelled leaves. The latter sequence is well-known (it is number 1465
in Sloane [11], the solution to Schr\"oder's fourth problem, and has many
other interpretations). I will derive the formula below, since it involves
only a slight detour.

The unlabelled case has an additional complication, since it can happen that 
complementary two-graphs are isomorphic. Such an isomorphism must arise
from an automorphism $\theta$ of the series-reduced tree which interchanges
the bipartite blocks. Since $\theta$ has no fixed points, it must be
bicentral, and $T$ consists of two copies of a rooted series-reduced tree
with ${1\over2}n+1$ leaves (rooted at a leaf) with the edges through the
roots identified in opposite senses.
So, if $a_n$ and $b_n$ are the numbers of unrooted and rooted
series-reduced trees with $n$ leaves (where the root is a leaf), then
the number of 5-free two-graphs is $2a_n$ if $n$ is odd, and $2a_n-b_{1+n/2}$
if $n$ is even.

\section 2. Vertex and edge labellings

I begin with two proofs of the following result. Each proof contributes
something to the subsequent argument.

\proclaim Proposition 2.1. For $n\ge2$, the number of trees with $n$ labelled
edges is $(n+1)^{n-2}$.

\noindent{\sl First proof.} A tree $T$ with $n$ edges has $n+1$ vertices; so
the numbers of vertex and edge labellings of $T$ are respectively
$(n+1)!/|{\rm Aut}(T)|$ and $n!/|{\rm Aut}(T)|$. (Here we use the fact,
derived from Whitney's theorem [13] or easily proved directly, that the
automorphism group acts faithfully on the edge set if $n\ge2$.) Thus the
number of vertex labellings is $n+1$ times the number of edge labellings.
So the same holds for all trees with $n$ edges. By Cayley's theorem, there
are $(n+1)^{n-1}$ such vertex labelled trees.

\medskip

\noindent{\sl Second proof.} We look at Pr\"ufer's proof [7] of Cayley's
theorem. There is a bijection between the vertex labelled trees on $n+1$
vertices and the {\it Pr\"ufer codes}, the $(n-1)$-tuples of labels. We take
the label set to be $\{0, 1, \ldots, n\}$. Let $P$ be a Pr\"ufer code, $S$
the set of labels. Let $p_1$ be the first element of $P$, $s_1$ the smallest
element of $S$ not occurring in $P$. Join $p_1$ to $s_1$, and delete $p_1$
and $s_1$ from $P$ and $S$ respectively. Repeat this operation until $P$ is
empty. Then two labels remain in $S$; join these two vertices.

Note that the valency of a vertex in the tree is one greater than the number
of its occurrences in $P$. In particular, the leaves are the elements of $S$
not occurring in $P$. Now Proposition~2.1 follows from:

\proclaim Lemma 2.2. For $n\ge2$, there is a bijection between edge labelled
trees with label set $\{1, 2, \ldots, n\}$ and vertex labelled trees with
label set $\{0, 1, 2, \ldots, n\}$ in which vertex 0 is a non-leaf joined
to the leaf with smallest label. These trees are precisely those whose
Pr\"ufer codes begin with $0$.

\noindent{\sl Proof.} From the vertex labelling, we obtain an edge labelling
by moving the label on each vertex $v\not=0$ to the edge through $v$ in
the direction of 0. Conversely, given an edge labelling, choose the pendant
edge with smallest label; give the label 0 to its non-leaf, and move the
edge labels to their vertices further from 0. The last statement is
immediate from Pr\"ufer's algorithm.

\medskip

\noindent{\sl Remark.} We can define the {\it edge Pr\"ufer code} of an
edge labelled tree by taking the Pr\"ufer code of the corresponding
vertex labelling and deleting the initial 0. This suggests two problems:

\smallskip

\noindent{\sl Problem 1.} Describe a constructive bijection between
edge labelled trees and edge Pr\"ufer codes, not going via vertex labellings.

\smallskip

\noindent{\sl Problem 2.} Describe the equivalence relation $\equiv$ (see
Section~1) in terms of the edge Pr\"ufer code.

\smallskip

The solution to Problem 1 is not obvious. In the construction of a tree from
its vertex Pr\"ufer code, we usually produce several connected components
which are not joined up until later; so, when an edge appears, it may not be
known which of its vertices is further from 0. Because I could not solve
these problems, I had to proceed another way.

\section 3. The formulae

The {\it Stirling number of the second kind}, $S(n,k)$, is the number of
partitions of an $n$-set into $k$ non-empty parts. Now $k!S(n,k)$ is the
number of surjections from $\{1, \ldots, n\}$ to $\{1, \ldots, k\}$, for
which a standard inclusion-exclusion argument gives the formula
$$k!S(n,k)=\sum_{i=0}^k(-1)^i{k\choose i}(k-i)^n.$$
Let $s(n,k)$ be the signed Stirling number of the first kind: that is,
$(-1)^{n-k}s(n,k)$ is the number of permutations of $\{1, \ldots, n\}$
having $k$ cycles.

\proclaim Proposition 3.1. Let $\cal F$ be a family of reduced two-graphs,
and let $E({\cal F})$ denote the class of two-graphs containing no member
of $\cal F$ as a substructure. If $f_n$ and $g_n$ denote the numbers of
labelled $n$-element two-graphs and reduced two-graphs in $E({\cal F})$
respectively, then
$$f_n=\sum_{k=1}^nS(n,k)g_k,$$
whence
$$g_n=\sum_{k=1}^ns(n,k)f_k.$$

\noindent{\sl Proof.} As in Section~1, a two-graph is uniquely specified by
the classes of the equivalence relation $\equiv$ and the reduced two-graph
on the set of classes. Moreover, since every member of $\cal F$ is reduced,
a two-graph excludes $\cal F$ if and only if its reduced quotient does. The
first equation follows; and the second then holds in view of the well-known
inversion relation between the two kinds of Stirling numbers.

\smallskip

The next result is well-known (see p.~270 of Nijenhuis and Wilf [5],
for example).

\proclaim Proposition 3.2. The number of trees with $n$ labelled leaves and
$k$ non-leaves is $S(n+k-2,k)$.

\noindent{\sl Proof.} If we label the non-leaves as well, we obtain a
vertex labelled tree whose Pr\"ufer code consists exactly of the labels
of the non-leaves, and so defines a surjection from an $(n+k-2)$-set to a
$k$-set. But each labelling of the leaves extends to $k!$ labellings of all
vertices, since no non-trivial automorphism can fix all the leaves.

\medskip

A tree is series-reduced if no number occurs precisely once in its Pr\"ufer
code. If there are $n$ vertices, the number of codes in which at least a
set $J$ of labels with $|J|=j$ occurs precisely once is
$${n-2\choose j}j!(n-j)^{n-2-j},$$
since we must choose $j$ coordinates, write the elements of $J$ in those
coordinates, and use elements not in $J$ for the remaining labels. Thus,
inclusion-exclusion gives the first part of the next result; the second
part follows from the first proof of Proposition~2.1.

\proclaim Proposition 3.3. The number $x_n$ of series-reduced trees
with $n$ labelled vertices is given by $x_1=x_2=1$ and
$$x_n=\sum_{j=0}^{n-2}(-1)^j{n\choose j}{n-2\choose j}j!(n-j)^{n-2-j}$$
for $n\ge3$, while the number $x_n'$ of series-reduced
trees with $n$ labelled edges is $x_n'=x_{n+1}/(n+1)$ for $n\ge2$, with
$x'_1=1$.

The number of reduced 5,6-free two-graphs with $n$ labelled points is also
$x'_n$, by the remarks in Section~1.

\medskip

To count series-reduced trees with $n$ labelled leaves, we have to
combine the two methods.

\proclaim Proposition 3.4. The number $y_n$ of series-reduced trees
with $n$ labelled leaves is
$$y_n=\sum_{k=1}^{n-2}\sum_{j=0}^{k-1}(-1)^j{n+k-2\choose j}S(n+k-j-2,k-j).$$
for $n\ge2$, with $y_1=1$.

\noindent{\sl Proof.} Suppose that such a tree has $k$ non-leaves. Each
non-leaf has valency at least~3, so $n+3k\le2(n+k-1)$, or $k\le n-2$. Consider
trees with fixed $k$, and label the non-leaves as well. These trees have
Pr\"ufer codes of length $n+k-2$, made up of labels from the $k$ non-leaves,
each occurring at least twice. As before, the number of trees in which at
least a set $J$ of $j$ labels occurs only once is
$${n+k-2\choose j}j!(k-j)!S(n+k-j-2,k-j);$$
so the required number of trees is
$$\sum_{j=0}^{k-1}(-1)^j{k\choose j}{n+k-2\choose j}j!(k-j)!S(n+k-j-2,k-j).$$
Dividing by $k!$ and summing over $k$ gives the result.

\medskip

As noted earlier, the number of labelled 5-free two-graphs is given by
$y'_n=2y_n$ for $n\ge3$, with $y_1'=y_2'=1$.

\medskip

Now we can complete the enumeration in all cases, using Proposition~3.1.

\proclaim Proposition 3.5. Let $x'_n$ and $y'_n$ be as defined earlier.
\item{(a)} The number of labelled 5,6-free two-graphs on
$n$ points is
$$\sum_{k=1}^nS(n,k)x'_k.$$
\item{(b)} The number of labelled reduced two-graphs on $n$ points is
$$\sum_{k=1}^ns(n,k)2^{k-1\choose2},$$
and the number of labelled reduced 5-free two-graphs is
$$\sum_{k=1}^ns(n,k)y'_k.$$

\medskip

\noindent{\sl Remark 1.} In the terminology of Bernstein and Sloane [1],
the sequence $(z_n)$ enumerating 5,6-free two-graphs
is the Stirling transform of the sequence $(x'_n)$. It
is curious that the Stirling transform of $(z_n)$ is also of combinatorial
significance. For there is an infinite permutation group $G$ which has $z_n$
orbits on ordered $n$-tuples of distinct elements (Cameron [2]); by Cameron
and Taylor [3], the number of orbits of $G$ on arbitrary $n$-tuples is
$\sum_{k=0}^nS(n,k)z_k$.

\smallskip

\noindent{\sl Remark 2.} The number of labelled two-graphs on $n$ points is
$2^{n-1\choose 2}$. This sequence, and those for 5-free and 5,6-free
two-graphs, begin
\item{} 1, 1, 2, 8, 64, 1024, \dots
\item{} 1, 1, 2, 8, 52, 472, \dots
\item{} 1, 1, 2, 8, 52, 457, \dots

\noindent This is reassuring since

(a) The pentagon has 10 automorphisms and hence 12 labellings, so the first
and second sequences should differ by 12 in the fifth place;

(b) The hexagon has 48 automorphisms (as a two-graph) and hence 15 labellings,
so the second and third sequences should differ by 15 in the sixth place.

\section Appendix: The sequences

Below I give the first twenty terms of each of the one-variable sequences
considered here (except for two-graphs, where the sequence grows so rapidly
that only fifteen terms are given). These sequences have been computed by
{\sf GAP} [8] programs and the output pasted directly into the paper, to reduce
the probability of error.

{\rightskip=0pt plus 2in

Vertex labelled trees:
  1, 1, 3, 16, 125, 1296, 16807, 262144, 4782969, 100000000, 2357947691, 
  61917364224, 1792160394037, 56693912375296, 1946195068359375, 
  72057594037927936, 2862423051509815793, 121439531096594251776, 
  5480386857784802185939, 262144000000000000000000  

Edge labelled trees:
  1, 1, 4, 25, 216, 2401, 32768, 531441, 10000000, 214358881, 5159780352, 
  137858491849, 4049565169664, 129746337890625, 4503599627370496, 
  168377826559400929, 6746640616477458432, 288441413567621167681, 
  13107200000000000000000, 630880792396715529789561  

Vertex labelled series reduced trees:
  1, 1, 0, 4, 5, 96, 427, 6448, 56961, 892720, 11905091, 211153944, 
  3692964145, 75701219608, 1613086090995, 38084386700896, 949168254452993, 
  25524123909350112, 725717102391257347, 21955114496683796680  

Edge labelled series reduced trees:
  1, 0, 1, 1, 16, 61, 806, 6329, 89272, 1082281, 17596162, 284074165, 
  5407229972, 107539072733, 2380274168806, 55833426732529, 1418006883852784, 
  38195636967960913, 1097755724834189834, 33345176998235584301  

Leaf labelled series reduced trees:
  1, 1, 1, 4, 26, 236, 2752, 39208, 660032, 12818912, 282137824, 6939897856, 
  188666182784, 5617349020544, 181790703209728, 6353726042486272, 
  238513970965257728, 9571020586419012608, 408837905660444010496, 
  18522305410364986906624  

Point labelled two-graphs:
  1, 1, 2, 8, 64, 1024, 32768, 2097152, 268435456, 68719476736, 
  35184372088832, 36028797018963968, 73786976294838206464, 
  302231454903657293676544, 2475880078570760549798248448  

Point labelled 5-free two-graphs:
  1, 1, 2, 8, 52, 472, 5504, 78416, 1320064, 25637824, 564275648, 
  13879795712, 377332365568, 11234698041088, 363581406419456, 
  12707452084972544, 477027941930515456, 19142041172838025216, 
  817675811320888020992, 37044610820729973813248  

Point labelled 5,6-free two-graphs:
  1, 1, 2, 8, 52, 457, 4979, 64591, 972906, 16701834, 322063458, 6894918021, 
  162316253829, 4168330738093, 115980086558470, 3476156853885992, 
  111665862911781864, 3827642575341002133, 139457935266705019299, 
  5382149182666970080019  

Point labelled reduced two-graphs:
  1, 0, 1, 1, 28, 448, 18788, 1419852, 207249896, 58206408344, 
  31725488477648, 33830818147141904, 71068681534173472576, 
  295648155633330113713344, 2444510010072634827916776064  

Point labelled reduced 5-free two-graphs:
  1, 0, 1, 1, 16, 76, 1016, 10284, 157340, 2411756, 44953712, 899824256, 
  20283419872, 495216726096, 13202082981712, 378896535199888, 
  11690436112988224, 385173160930360192, 13509981115738946816, 
  502374681770910293568  

Point labelled reduced 5,6-free two-graphs: Same as edge labelled 
series-reduced trees.

}

\section References

\frenchspacing
\hbox{ }

\item{1.} M. Bernstein and N. J. A. Sloane, Some canonical sequences of
integers, to appear in {\it Linear Algebra and Appl.}

\item{2.} P. J. Cameron, Two-graphs and trees, {\it Discrete Math.} {\bf 127}
(1994), 63--74.

\item{3.} P. J. Cameron and D. E. Taylor, Stirling numbers and affine
equivalence, {\it Ars Combinatoria} {\bf 20B} (1985), 3--14.

\item{4.} A. Cayley, A theorem on trees, {\it Quart. J. Pure Appl. Math.}
{\bf 23} (1889), 376--378.

\item{5.} A. Nijenhuis and H. S. Wilf, {\it Combinatorial Algorithms}, second
edition, Academic Press, New York, 1978.

\item{6.} R. Otter, The number of trees, {\it Ann. Math.} (2) {\bf 49}
(1948), 583--599.

\item{7.} H. Pr\"ufer, Neuer Beweis eines Satzes \"uber Permutationen,
{\it Arch. Math. Phys.} (3) {\bf 27} (1918), 142--144.

\item{8.} M. Sch\"onert {\it et al.}, {\sf GAP} --- {\it Groups, Algorithms and
Programming}, fourth edition, Lehrstuhl D f\"ur Mathematik, RWTH Aachen,
1994.

\item{9.} J. J. Seidel, A survey of two-graphs, pp. 481--511 in {\it Proc.
Int. Colloq. Teorie Combinatorie}, Accad. Naz. Lincei, Roma, 1977.

\item{10.} J. J. Seidel and S. V. Tsaranov, Two-graphs, related groups and
root lattices, {\it Bull. Math. Soc. Belg.} {\bf 42} (1990), 695--711.

\item{11.} N. J. A. Sloane, {\it A Handbook of Integer Sequences}, Academic
Press, New York, 1973. (A revised edition, entitled {\it The Encyclopedia
of Integer Sequences}, by N. J. A. Sloane and S. Plouffe, is to be
published shortly by Academic Press.)

\item{12.} S. V. Tsaranov, On a generalization of Coxeter groups, {\it Algebra
Groups Geom.} {\bf 6} (1989), 281--318.

\item{13.} H. Whitney, Congruent graphs and the connectivity of graphs,
{\it Amer. J. Math.} {\bf 54} (1932), 150--168.

\bigskip

{\parskip=0pt \parindent=0pt

School of Mathematical Sciences

Queen Mary and Westfield College

Mile End Road

London E1 4NS

U.K.

\smallskip

{\tt P.J.Cameron@qmw.ac.uk}

\vfill}

\bye