Presentation is loading. Please wait.

Presentation is loading. Please wait.

Centers and Centralizers

Published byShinta Jayadi Modified over 5 years ago

Similar presentations

Presentation on theme: "Centers and Centralizers"— Presentation transcript:

1 Centers and Centralizers

2 The Center of a group Definition:
Let G be a group. The center of G, denoted Z(G) is the set of group elements that commutes with every element of G. That is,

3 Z(D4) R0 R90 R180 R270 H V D D'

4 Z(D4) contains R0 • R0 R90 R180 R270 H V D D'
R0 commutes with everything.

5 Z(D4) contains R180 R0 R90 R180 R270 H V D D'

6 Z(D4) = {R0, R180} R0 R90 R180 R270 H V D D'

7 Z(G)≤G Proof: We will use the two step test.
ex = xe for all x in G, so Z(G) is not empty. Choose any a and b in Z(G). Then for any x in G, we have (ab)x = a(xb) since b in Z(G) = (xa)b since a in Z(G) = x(ab) So Z(G) is closed.

8 Proof that Z(G) ≤ G (con't)
To show Z(G) is closed under inverses, Choose any a in Z(G). For any x in G, ax = xa. Multiply on both sides by a-1: a-1 (ax)a-1 = a-1(xa)a-1 (a-1 a)(xa-1) = (a-1x)(aa-1) exa-1= a-1xe xa-1= a-1x By the two step test, Z(G) ≤ G

9 Centralizers Definition:
Let a be any element of a group G. The centralizer of a in G, denoted C(a), is the set of elements that commutes with a. That is,

10 C(H) in D4 R0 R90 R180 R270 H V D D' Start with row and column with H. See if Hx = xH

11 In D4, C(H) = {R0, R180, H, V} R0 R90 R180 R270 H V D D'

12 Prove: C(a) ≤ G Proof: Let a be an element of a group G. We will use the one-step test to show that C(a) is a subgroup. ea = ae, so e belongs to C(a). Hence C(a) is nonempty.

13 Show xy-1 in C(a) Choose any x,y in C(a). Then
(xy-1)-1a(xy-1) = (yx -1)a(xy-1) by S&S =yx-1(ax)y-1 = yx-1(xa)y-1 since x in C(a) =yay-1 since x-1x = e =(ay)y-1 since y is in C(a) = a since yy-1=e Multiply both sides on the left by (xy-1) to get: a(xy-1) = (xy-1)a Hence (xy-1) is in C(a) as required.

14 Subgroups of D4 {R0,R90,R180,R270,H,V,D,D'} {R0,R90,R180,R270}
{R0,R180,D,D'} Trivial group Cyclic subgroups; In this case the Center is cyclic Centralizers: One of them is cyclic The whole group {R0, R180} {R0, D} {R0, D'} {R0, V} {R0, H} {R0}

Download ppt "Centers and Centralizers"

Similar presentations

Vector Spaces A set V is called a vector space over a set K denoted V(K) if is an Abelian group, is a field, and For every element vV and K there exists.

Vector Spaces A set V is called a vector space over a set K denoted V(K) if is an Abelian group, is a field, and For every element vV and K there exists.
Cayley Theorem Every group is isomorphic to a permutation group.

Cayley Theorem Every group is isomorphic to a permutation group.
Section 13 Homomorphisms Definition A map  of a group G into a group G’ is a homomorphism if the homomophism property  (ab) =  (a)  (b) Holds for.

Section 13 Homomorphisms Definition A map  of a group G into a group G’ is a homomorphism if the homomophism property  (ab) =  (a)  (b) Holds for.
Cyclic Groups Part 2.

Cyclic Groups Part 2.
1.  Detailed Study of groups is a fundamental concept in the study of abstract algebra. To define the notion of groups,we require the concept of binary.

1.  Detailed Study of groups is a fundamental concept in the study of abstract algebra. To define the notion of groups,we require the concept of binary.
Chapter 3: Finite Groups; Subgroups  Terminology and Notation  Subgroup Tests  Examples of Subgroups.

Chapter 3: Finite Groups; Subgroups  Terminology and Notation  Subgroup Tests  Examples of Subgroups.
2.3 Matrix Inverses. Numerical equivalent How would we solve for x in: ax = b ? –a -1 a x = a -1 b –x=a -1 b since a -1 a = 1 and 1x = x We use the same.

2.3 Matrix Inverses. Numerical equivalent How would we solve for x in: ax = b ? –a -1 a x = a -1 b –x=a -1 b since a -1 a = 1 and 1x = x We use the same.
Binary Operations.

Binary Operations.
Permutations and Inverses. Definition Let A be a set. If f : A  A is a 1-1 correspondence then f is called a permutation of A. Notation: S(A): the set.

Permutations and Inverses. Definition Let A be a set. If f : A  A is a 1-1 correspondence then f is called a permutation of A. Notation: S(A): the set.
How do we start this proof? (a) Assume A n is a subgroup of S n. (b)  (c) Assume o(S n ) = n! (d) Nonempty:

How do we start this proof? (a) Assume A n is a subgroup of S n. (b)  (c) Assume o(S n ) = n! (d) Nonempty:
Find all subgroups of the Klein 4- Group. How many are there? 1 2 3 4 5 6 7 8 9 10.

Find all subgroups of the Klein 4- Group. How many are there?
Cosets.

Cosets.
Matrix Algebra THE INVERSE OF A MATRIX © 2012 Pearson Education, Inc.

Matrix Algebra THE INVERSE OF A MATRIX © 2012 Pearson Education, Inc.
1 Set Theory. Notation S={a, b, c} refers to the set whose elements are a, b and c. a  S means “a is an element of set S”. d  S means “d is not an element.

1 Set Theory. Notation S={a, b, c} refers to the set whose elements are a, b and c. a  S means “a is an element of set S”. d  S means “d is not an element.
7.1 – Multiplying Monomials. x · x = x 1 · x 1 =

7.1 – Multiplying Monomials. x · x = x 1 · x 1 =
A Fast Introduction inverse matrix1 What is a matrix ------ (One Matrix many matrices) Why do they exist Matrix Terminology Elements Rows Columns Square.

A Fast Introduction inverse matrix1 What is a matrix (One Matrix many matrices) Why do they exist Matrix Terminology Elements Rows Columns Square.
EXAMPLE 2 Solve a matrix equation SOLUTION Begin by finding the inverse of A. 4 7 1 2 = Solve the matrix equation AX = B for the 2 × 2 matrix X. 2 –7 –1.

EXAMPLE 2 Solve a matrix equation SOLUTION Begin by finding the inverse of A = Solve the matrix equation AX = B for the 2 × 2 matrix X. 2 –7 –1.
Math 3121 Abstract Algebra I Lecture 3 Sections 2-4: Binary Operations, Definition of Group.

Math 3121 Abstract Algebra I Lecture 3 Sections 2-4: Binary Operations, Definition of Group.
Chap. 2 Matrices 2.1 Operations with Matrices

Chap. 2 Matrices 2.1 Operations with Matrices
Finite Groups & Subgroups. Order of a group Definition: The number of elements of a group (finite or infinite) is called its order. Notation: We will.

Finite Groups & Subgroups. Order of a group Definition: The number of elements of a group (finite or infinite) is called its order. Notation: We will.

Similar presentations

Ads by Google