On eigenvalues of certain cayley graphs / Terry Lau Shue Chien
Let Sn be the symmetric group on [n] = {1,. . . ,n}. The k-point fixing graph, F(n, k) is defined to be the graph with vertex set Sn and two vertices g and h of F(n, k) are joined if and only if gh−1 fixes exactly k points. F(n, k) is a Cayley graph on Sn generated by S (n, k), the union of the c...
Saved in:
Main Author: | |
---|---|
Format: | Thesis |
Published: |
2016
|
Subjects: | |
Online Access: | http://studentsrepo.um.edu.my/7013/4/terry.pdf http://studentsrepo.um.edu.my/7013/ |
Tags: |
Add Tag
No Tags, Be the first to tag this record!
|
Institution: | Universiti Malaya |
Summary: | Let Sn be the symmetric group on [n] = {1,. . . ,n}. The k-point fixing graph, F(n, k) is
defined to be the graph with vertex set Sn and two vertices g and h of F(n, k) are joined
if and only if gh−1 fixes exactly k points. F(n, k) is a Cayley graph on Sn generated by
S (n, k), the union of the conjugacy classes that fixes exactly k points. A subset I of Sn is
said to be an independent set in F(n, k) if and only if any two vertices in I are not adjacent
to each other. The problem of finding such a set is called the maximum independent set
problem and it is an NP-hard optimization problem. We are going to determine the size
of the largest independent set in F(n, k) for 0 < k << n by using the Delsarte-Hoffman
Bound. In order to do so, eigenvalues of the adjacency matrix of F(n, k) are required in
finding a bound for the size of a largest independent set in F(n, k).
To determine the eigenvalues of the adjacency matrix of F(n, k), we use the representation
theory of symmetric groups. In particular, we use the character theory of symmetric
groups. We apply the branching rule and results from Foulkes to derive a recurrence
formula for eigenvalues of F(n, k). Then we apply our results and some of the results
regarding the eigenvalues and size of largest independent set of F(n,0) to determine
the sign of the eigenvalues of F(n,1). Then, we determine the smallest eigenvalue of
F(n,1) by techniques in extremal combinatorics. We use the largest and smallest eigenvalues
of F(n,1) and apply the Delsarte-Hoffman Bound to determine a bound for the
size of a largest independent set in F(n,1). When 0 < k << n, we determine the smallest
eigenvalues of F(n, k) and the Specht module where it occurs. Similarly, we use the
largest and smallest eigenvalues of F(n, k) and apply the Delsarte-Hoffman Bound to
determine a bound for the size of a largest independent set in F(n, k).
We also consider F(n,0), the derangement graph with generating set Dn, the derangement
set. For any fixed positive integer k ≤ n, the Cayley graph on Sn generated by the
subset of Dn consisting of permutations without any i-cycles for all 1 ≤ i ≤ k is a regular
subgraph of the derangement graph. We determine the smallest eigenvalue of these subgraphs
and show that the set of all largest independent sets in these subgraphs is equal to
the set of all the largest independent sets in F(n,0) provided that k << n.
h |
---|