10-1100/Homework Assignment 2: Difference between revisions

Latest revision as of 12:29, 20 October 2010

#	Week of...	Notes and Links
Additions to the MAT 1100 web site no longer count towards good deed points
1	Sep 13	About This Class, Tuesday - Non Commutative Gaussian Elimination, Thursday
2	Sep 20	Tuesday - Homomorphisms and Normal Groups, Thursday - Isomorphism Theorems
3	Sep 27	Class Photo, HW1, HW1 solution
4	Oct 4
5	Oct 11	HW2, HW2 solution
6	Oct 18
7	Oct 25	Term Test
8	Nov 1	HW3, HW3 solution
9	Nov 8	Monday-Tuesday is Fall Break, One Theorem, Two Corollaries, Four Weeks
10	Nov 15	HW4, HW4 solution
11	Nov 22
12	Nov 29	HW5, HW5 solution
13	Dec 6	Boxing Day Handout, see also December 2010 Schedule. Some Class Notes
F	Dec 13	Final exam, Tuesday December 14 10-1, Bahen 6183
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See Non Commutative Gaussian Elimination

This assignment is due at class time on Thursday, October 21, 2010.

(Selick)
1. What it the least integer $n$ for which the symmetric group $S_{n}$ contains an element of order 18?
2. What is the maximal order of an element in $S_{26}$ ? (That is, of a shuffling of the red cards within a deck of cards?)
(Selick) Let $H$ be a subgroup of index 2 in a group $G$ . Show that $H$ is normal in $G$ .
Let $\sigma \in S_{20}$ be a permutation whose cycle decomposition consists of one 5-cycle, two 3-cycles, and one 2-cycle. What is the order of the centralizer $C_{S_{20}}(\sigma )$ of $\sigma$ ?
(Selick) Let $G$ be a group of odd order. Show that $x$ is not conjugate to $x^{-1}$ unless $x=e$ .
(Dummit and Foote) Show that if $G/Z(G)$ is cyclic then $G$ is Abelian.
(Lang) Prove that if the group of automorphisms of a group $G$ is cyclic, then $G$ is Abelian.
(Lang)
1. Let $G$ be a group and let $H$ be a subgroup of finite index. Prove that there is a normal subgroup $N$ of $G$ , contained in $H$ , so that $(G:N)$ is also finite. (Hint: Let $(G:H)=n$ and find a morphism $G\to S_{n}$ whose kernel is contained in $H$ .)
2. Let $G$ be a group and $H_{1}$ and $H_{2}$ be subgroups of $G$ . Suppose $(G:H_{1})<\infty$ and $(G:H_{2})<\infty$ . Show that $(G:H_{1}\cap H_{2})<\infty$

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 {{10-1100/Navigation}}
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 This assignment is due at class time on Thursday, October 21, 2010.
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 # (Selick)
 ## What it the least integer <math>n</math> for which the symmetric group <math>S_n</math> contains an element of order 18?
-## What is the maximal order of an element in <math>S_{52}</math>? (That is, of a shuffling of a deck of cards?)
+## What is the maximal order of an element in <math>S_{26}</math>? (That is, of a shuffling of the red cards within a deck of cards?)
 # (Selick) Let <math>H</math> be a subgroup of index 2 in a group <math>G</math>. Show that <math>H</math> is normal in <math>G</math>.
 # Let <math>\sigma\in S_{20}</math> be a permutation whose cycle decomposition consists of one 5-cycle, two 3-cycles, and one 2-cycle. What is the order of the centralizer <math>C_{S_{20}}(\sigma)</math> of <math>\sigma</math>?