The document discusses matchings in graphs and the Erdos-Ko-Rado (EKR) theorem. It introduces Baranyai partitions, which is a decomposition of the edges of a complete bipartite graph K2n into (2n-1) perfect matchings. Considering cyclic permutations of the edges within each perfect matching partition provides a way to set up "Katona-like local environments" to prove bounds on intersecting families of matchings, in analogy to Katona's proof technique for intersecting families of sets.
14. The number of matchings of size r in K2n is:
(
2n
2
)
15. The number of matchings of size r in K2n is:
(
2n
2
)(
2n − 2
2
)
16. The number of matchings of size r in K2n is:
(
2n
2
)(
2n − 2
2
)(
2n − 4
2
)
17. The number of matchings of size r in K2n is:
(
2n
2
)(
2n − 2
2
)(
2n − 4
2
)
· · ·
18. The number of matchings of size r in K2n is:
(
2n
2
)(
2n − 2
2
)(
2n − 4
2
)
· · ·
(
2n − 2(r − 1)
2
)
r choices
19. The number of matchings of size r in K2n is:
(
2n
2
)(
2n − 2
2
)(
2n − 4
2
)
· · ·
(
2n − 2(r − 1)
2
)
r choices
r!
20. The number of matchings of size r in K2n is:
|Mr
n| =
(
2n
2
)(
2n − 2
2
)(
2n − 4
2
)
· · ·
(
2n − 2(r − 1)
2
)
r choices
r!
21. The number of matchings of size r in a star centered at e is:
22. The number of matchings of size r in a star centered at e is:
(
2n − 2
2
)
23. The number of matchings of size r in a star centered at e is:
(
2n − 2
2
)(
2n − 4
2
)
24. The number of matchings of size r in a star centered at e is:
(
2n − 2
2
)(
2n − 4
2
)
· · ·
25. The number of matchings of size r in a star centered at e is:
(
2n − 2
2
)(
2n − 4
2
)
· · ·
(
2n − 2(r − 1)
2
)
(r−1) choices
26. The number of matchings of size r in a star centered at e is:
(
2n − 2
2
)(
2n − 4
2
)
· · ·
(
2n − 2(r − 1)
2
)
(r−1) choices
(r − 1)!
27. The number of matchings of size r in a star centered at e is:
|Mr
n(e)| =
(
2n − 2
2
)(
2n − 4
2
)
· · ·
(
2n − 2(r − 1)
2
)
(r−1) choices
(r − 1)!
33. The EKR Statement for Families of Sets
If A is an intersecting family of r-subsets of [n], then:
|A|
(
n − 1
r − 1
)
,
34. The EKR Statement for Families of Sets
If A is an intersecting family of r-subsets of [n], then:
|A|
(
n − 1
r − 1
)
,
with equality holding if and only if A is a star.
36. Proof by Picture
Katona (1972)
Arrange the elements of the universe on a circle.
Call this arrangement σ.
37. Proof by Picture
Katona (1972)
Arrange the elements of the universe on a circle.
Call this arrangement σ.
Aσ: those sets of A that happen to be intervals on this circular
arrangement.
38. Proof by Picture
Katona (1972)
Arrange the elements of the universe on a circle.
Call this arrangement σ.
Aσ: those sets of A that happen to be intervals on this circular
arrangement.
How big can Aσ be, given that A is intersecting?
49. Proof by Picture
Katona (1972)
Arrange the elements of the universe on a circle.
Call this arrangement σ.
Aσ: those sets of A that happen to be intervals on this circular
arrangement.
How big can Aσ be, given that A is intersecting?
50. Proof by Picture
Katona (1972)
Arrange the elements of the universe on a circle.
Call this arrangement σ.
Aσ: those sets of A that happen to be intervals on this circular
arrangement.
|Aσ| r
58. The Count
Katona (1972)
How many pairs (S, σ) are there,
where S ∈ A, σ is a cyclic permutation of [n], and S occurs as an
interval in σ?
59. The Count
Katona (1972)
How many pairs (S, σ) are there,
where S ∈ A, σ is a cyclic permutation of [n], and S occurs as an
interval in σ?
|A| · r! · (n − r)!
60. The Count
Katona (1972)
How many pairs (S, σ) are there,
where S ∈ A, σ is a cyclic permutation of [n], and S occurs as an
interval in σ?
|A| · r! · (n − r)! (n − 1)!r
61. The Count
Katona (1972)
How many pairs (S, σ) are there,
where S ∈ A, σ is a cyclic permutation of [n], and S occurs as an
interval in σ?
|A| · r! · (n − r)! (n − 1)!r
|A| (n−1)!r
r!(n−r)!
62. The Count
Katona (1972)
How many pairs (S, σ) are there,
where S ∈ A, σ is a cyclic permutation of [n], and S occurs as an
interval in σ?
|A| · r! · (n − r)! (n − 1)!r
|A| (n−1)!r
r!(n−r)! =
(n−1
r−1
)
.
63. Setting Up Katona-Like Local Environments
Our universe is now the set of all edges in K2n.
64. Setting Up Katona-Like Local Environments
Our universe is now the set of all edges in K2n.
We might begin by considering cyclic permutations of these edges.
65. Setting Up Katona-Like Local Environments
Our universe is now the set of all edges in K2n.
We might begin by considering cyclic permutations of these edges.
A direct approach only leads to a weak bound...
66. ...and informally, the bounds are loose because
an interval of an arbitrary permutation of E(K2n)
is not automatically a matching.
67. ...and informally, the bounds are loose because
an interval of an arbitrary permutation of E(K2n)
is not automatically a matching.
Our first goal, therefore, is to come up with a more suitable
selection of cyclic permutations.
92. We have just described one cyclic permutation of E(K2n).
93. We have just described one cyclic permutation of E(K2n).
We can generate other cyclic permutations of E(K2n) using this
method.
94. We have just described one cyclic permutation of E(K2n).
We can generate other cyclic permutations of E(K2n) using this
method.
Let σ be a permutation of [2n].
Start with the following Baranyai Partition...
(illustration for n = 4):
98. The cyclic orders that we have just generated will serve as
wireframes on which we can project elements of A as intervals, a la
Katona’s proof for the classic version of the theorem.
99. The cyclic orders that we have just generated will serve as
wireframes on which we can project elements of A as intervals, a la
Katona’s proof for the classic version of the theorem.
Preliminary Observation.
Every interval of length r is a matching, as long as r < n.
100. The cyclic orders that we have just generated will serve as
wireframes on which we can project elements of A as intervals, a la
Katona’s proof for the classic version of the theorem.
Preliminary Observation.
Every interval of length r is a matching, as long as r < n.
106. Proving the EKR bound
Let A be an intersecting family of r-matchings of K2n, where r < n.
107. Proving the EKR bound
Let A be an intersecting family of r-matchings of K2n, where r < n.
Let σ be a permutation of [2n] - consider the cyclic permutations
of E(K2n) that we generated based on σ - let’s call this χσ.
108. Proving the EKR bound
Let A be an intersecting family of r-matchings of K2n, where r < n.
Let σ be a permutation of [2n] - consider the cyclic permutations
of E(K2n) that we generated based on σ - let’s call this χσ.
Aσ: those sets of A that happen to be intervals on this circular
arrangement.
109. Proving the EKR bound
Let A be an intersecting family of r-matchings of K2n, where r < n.
Let σ be a permutation of [2n] - consider the cyclic permutations
of E(K2n) that we generated based on σ - let’s call this χσ.
Aσ: those sets of A that happen to be intervals on this circular
arrangement.
How big can Aσ be, given that A is intersecting?
110. Proving the EKR bound
Let A be an intersecting family of r-matchings of K2n, where r < n.
Let σ be a permutation of [2n] - consider the cyclic permutations
of E(K2n) that we generated based on σ - let’s call this χσ.
Aσ: those sets of A that happen to be intervals on this circular
arrangement.
|Aσ| r, for the same reasons as before.
111. Proving the EKR bound (contd.)
As before, consider the set of pairs (M, σ), where:
♣ M is a r-matching of K2n,
112. Proving the EKR bound (contd.)
As before, consider the set of pairs (M, σ), where:
♣ M is a r-matching of K2n,
♣ M belongs to A,
113. Proving the EKR bound (contd.)
As before, consider the set of pairs (M, σ), where:
♣ M is a r-matching of K2n,
♣ M belongs to A,
♣ σ is a permutation of [2n],
114. Proving the EKR bound (contd.)
As before, consider the set of pairs (M, σ), where:
♣ M is a r-matching of K2n,
♣ M belongs to A,
♣ σ is a permutation of [2n],
♣ and M occurs as an interval in χσ.
115. Proving the EKR bound (contd.)
As before, consider the set of pairs (M, σ), where:
♣ M is a r-matching of K2n,
♣ M belongs to A,
♣ σ is a permutation of [2n],
♣ and M occurs as an interval in χσ.
Clearly,
#(M, σ) r · (2n)!
116. Now, let us investigate the following question:
In how many cyclic orders χσ can a given matching M occur as an
interval?
117. To address the question, let us recall the cyclic orders χσ.
118. To address the question, let us recall the cyclic orders χσ.
It is useful to think of χσ as being composed of (2n − 1) chunks, as
they arise from the (2n − 1) parts of the Baranyai partitions.
119. To address the question, let us recall the cyclic orders χσ.
It is useful to think of χσ as being composed of (2n − 1) chunks, as
they arise from the (2n − 1) parts of the Baranyai partitions.
In the picture that follows, each row is a “chunk”.
121. Task 1.
Enumerate all σ where
M belongs to χσ as an interval,
and M lies entirely inside one of the chunks of χσ.
122. If M has r edges, then we have r! ways to order the edges of M.
For a fixed ordering p of the edges of M, let us devise a σ such that
χσ will contain M as an interval in its ith chunk, with the edges of
M appearing in the order prescribed by p.
128. We have (n − r) choices to begin the placement of the edges of M.
129. We have (n − r) choices to begin the placement of the edges of M.
The ordering of the vertices that are not incident to M are
immaterial, and there are (2n − 2r)! such orderings.
130. We have (n − r) choices to begin the placement of the edges of M.
The ordering of the vertices that are not incident to M are
immaterial, and there are (2n − 2r)! such orderings.
Finally, for a fixed realization of M respecting the order p, we may
still swap the endpoints of M to get a different permutation with
the same realization.
135. Note that there are 2r choices for swapping the endpoints of the
edges of M.
136. Note that there are 2r choices for swapping the endpoints of the
edges of M.
Putting everything together, we have....
137. These many ways in which
the chunk of σ in which we realize M
can be chosen:
(2n − 1)
138. These many ways in which
the ordering of the edges of M
can be chosen:
(2n − 1) · r!
139. These many ways in which
the starting point of M
can be chosen:
(2n − 1) · r! · (n − r)
140. These many ways in which
the ordering the vertices not incident to M
can be chosen:
(2n − 1) · r! · (n − r) · (2n − 2r)!
141. These many ways in which
“swapped” vertices within edges of M
can be chosen:
(2n − 1) · r! · (n − r) · (2n − 2r)! · 2r
142. These many ways in which
the permutation σ
can be chosen:
(2n − 1) · r! · (n − r) · (2n − 2r)! · 2r
143. Task 2.
Enumerate all σ where
M belongs to χσ as an interval,
and M “splits across” two chunks of χσ.
144. If M has r edges, then we have r! ways to order the edges of M.
For a fixed ordering p of the edges of M, let us devise a σ such that
χσ will contain M as an interval starting in its ith chunk, with the
edges of M appearing in the order prescribed by p,
and spilling over to the (i + 1)th chunk.
149. This time, we have r choices to begin the placement of the edges of
M.
150. This time, we have r choices to begin the placement of the edges of
M.
As before, the ordering of the vertices that are not incident to M
are immaterial, and there are (2n − 2r)! such orderings.
151. This time, we have r choices to begin the placement of the edges of
M.
As before, the ordering of the vertices that are not incident to M
are immaterial, and there are (2n − 2r)! such orderings.
And again, for a fixed realization of M respecting the order p, we
may still swap (in 2r ways) the endpoints of M to get a different
permutation with the same realization.
152. These many ways in which
the chunk of σ in which we realize M
can be chosen:
(2n − 1)
153. These many ways in which
the ordering of the edges of M
can be chosen:
(2n − 1) · r!
154. These many ways in which
the starting point of M
can be chosen:
(2n − 1) · r! · r
155. These many ways in which
the ordering the vertices not incident to M
can be chosen:
(2n − 1) · r! · r · (2n − 2r)!
156. These many ways in which
“swapped” vertices within edges of M
can be chosen:
(2n − 1) · r! · r · (2n − 2r)! · 2r
157. These many ways in which
the permutation σ
can be chosen:
(2n − 1) · r! · r · (2n − 2r)! · 2r
158. We are now in a position to tackle this:
In how many cyclic orders χσ can a given matching M occur as an
interval?
159. We are now in a position to tackle this:
In how many cyclic orders χσ can a given matching M occur as an
interval?
(2n − 1) · r! · r · (2n − 2r)! · 2r
+
(2n − 1) · r! · (n − r) · (2n − 2r)! · 2r
160. We are now in a position to tackle this:
In how many cyclic orders χσ can a given matching M occur as an
interval?
(2n − 1) · r! · r · (2n − 2r)! · 2r
+
(2n − 1) · r! · (n − r) · (2n − 2r)! · 2r
= (2n − 1) · r! · n · (2n − 2r)! · 2r
171. The structural claim
Let A be an extremal intersecting family of r-matchings of K2n.
Then there must be an edge that is common to all matchings in A.
172. High Level Proof Strategy
We know that if A is an extremal intersecting family, then:
|Aσ| = r, for all σ ∈ S2n.
Therefore, the matchings of the subfamily Aσ necessarily have a
common edge...
179. High Level Proof Strategy (Contd.)
Now that we know that every Aσ has a common edge,
it remains to show that the common edge is the same for every σ.
180. High Level Proof Strategy (Contd.)
Now that we know that every Aσ has a common edge,
it remains to show that the common edge is the same for every σ.
Begin by assuming that Aσ is centered at the edge e, where σ is the
identity permutation.
181. High Level Proof Strategy (Contd.)
Now that we know that every Aσ has a common edge,
it remains to show that the common edge is the same for every σ.
Begin by assuming that Aσ is centered at the edge e, where σ is the
identity permutation.
182. High Level Proof Strategy (Contd.)
Let σi be obtained by σ by a transposition of the element at i.
σi(j) =
i + 1 if j = i,
i if j = i + 1,
j otherwise .
183. High Level Proof Strategy (Contd.)
Let σi be obtained by σ by a transposition of the element at i.
σi(j) =
i + 1 if j = i,
i if j = i + 1,
j otherwise .
It suffices to show that, for every 1 i 2n,
Aσi
and Aσ have the same common edge.
184. High Level Proof Strategy (Contd.)
Let σi be obtained by σ by a transposition of the element at i.
σi(j) =
i + 1 if j = i,
i if j = i + 1,
j otherwise .
It suffices to show that, for every 1 i 2n,
Aσi
and Aσ have the same common edge.
185. High Level Proof Strategy (Contd.)
Let σi be obtained by σ by a transposition of the element at i.
σi(j) =
i + 1 if j = i,
i if j = i + 1,
j otherwise .
It suffices to show that, for every 1 i 2n,
Aσi
and Aσ have the same common edge.
The proof follows by an analysis on the structure of χσi
,
based on position of i.