Applied Algebra Seminar/Abstracts F13: Difference between revisions

From UW-Math Wiki
Jump to navigation Jump to search
Line 1: Line 1:
== October 31 ==
== October 31 ==
{| cellpadding="5" width="40%"
{| cellpadding="5" width="70%"
|- valign="top"
|- valign="top"
|Andrew Bridy<br>UW-Madison [[Image:Aasf13 andrewbridy.jpg|right|200px]]
|Andrew Bridy<br>UW-Madison [[Image:Aasf13 andrewbridy.jpg|right|200px]]

Revision as of 16:09, 23 August 2013

October 31

Andrew Bridy
UW-Madison
Aasf13 andrewbridy.jpg
Functional Graphs of Affine-Linear Transformations over Finite Fields
A linear transformation [math]\displaystyle{ A: (\mathbb{F}_q)^n \to (\mathbb{F}_q)^n }[/math] gives rise to a directed graph by regarding the elements of [math]\displaystyle{ (\mathbb{F}_q)^n }[/math] as vertices and drawing an edge from [math]\displaystyle{ v }[/math] to [math]\displaystyle{ w }[/math] if [math]\displaystyle{ Av = w }[/math]. In 1959, Elspas determined the "functional graphs" on [math]\displaystyle{ q^n }[/math] vertices that are realized in this way. In doing so he showed that there are many non-similar linear transformations which have isomorphic functional graphs (and so are conjugate by a non-linear permutation of [math]\displaystyle{ (\mathbb{F}_q)^n) }[/math]. I review some of this work and prove an new upper bound on the number of equivalence classes of affine-linear transformations of [math]\displaystyle{ (F_q)^n }[/math] under the equivalence relation of isomorphism of functional graphs. This bound is significantly smaller than the number of conjugacy classes of [math]\displaystyle{ \operatorname{GL}_n(q) }[/math]. This is joint work with Eric Bach.