Difference between revisions of "Abelian group"

(removed stub)
 
(3 intermediate revisions by one other user not shown)
Line 1: Line 1:
An '''abelian group''' is a [[group]] in which the group [[operation]] is [[commutative]].
+
An '''abelian group''' is a [[group]] in which the group [[operation]] is [[commutative]]. They are named after Norwegian mathematician Niels Abel.  
 
For a [[group]] to be considered '''abelian''', it must meet several requirements.
 
For a [[group]] to be considered '''abelian''', it must meet several requirements.
  
Line 27: Line 27:
  
 
Seeing as <math>\mathbb{Z}</math> meets all of these requirements under addition, we can say that <math>\mathbb{Z}</math> is abelian under addition.
 
Seeing as <math>\mathbb{Z}</math> meets all of these requirements under addition, we can say that <math>\mathbb{Z}</math> is abelian under addition.
 +
==Examples==
 +
Notable examples of abelian groups include the integers under addition, the real numbers under addition, the integers modulo <math>n</math> under addition, the multiplicative group of integers modulo <math>n</math>, and the additive group of any ring. Many matrix groups are ''not'' abelian because matrix multiplication is associative and not commutative. The smallest finite non-abelian group is the dihedral group of order 6.
  
{{stub}}
 
  
 
[[Category:Definition]]
 
[[Category:Definition]]
 
[[Category:Group theory]]
 
[[Category:Group theory]]

Latest revision as of 17:30, 14 June 2020

An abelian group is a group in which the group operation is commutative. They are named after Norwegian mathematician Niels Abel. For a group to be considered abelian, it must meet several requirements.

Closure

         For all $a,b$ $\in$ $S$, and for all operations $\bullet$, $a\bullet b \in S$.

Associativity

         For all $a,b,c$ $\in$ $S$ and all operations $\bullet$, $(a\bullet b)\bullet c=a\bullet(b\bullet c)$.

Identity Element

         There exists some $e \in S$ such that $a \bullet e = e \bullet a = a$.

Inverse Element

         For all $a \in S$, there exists some $a^{-1}$ such that $a \bullet a^{-1} = e$

Commutativity

         For all $a,b \in S$, $a \bullet b = b \bullet a$.

A simple example of an abelian group is $\mathbb{Z}$ under addition. It is simple to show that it meets all the requirements.

Closure

         For all $a,b \in \mathbb{Z} , a+b \in \mathbb{Z}$.

Associativity

         For all $a,b,c \in \mathbb{Z} , (a+b)+c = a+(b+c)$.

Identity Element

         For all $a \in \mathbb{Z} , a+0 = 0+a = a$.

Inverse Element

         For all $a \in \mathbb{Z} , a+ -a = 0$.

Commutativity

         For all $a,b \in \mathbb{Z} , a+b = b+a$.

Seeing as $\mathbb{Z}$ meets all of these requirements under addition, we can say that $\mathbb{Z}$ is abelian under addition.

Examples

Notable examples of abelian groups include the integers under addition, the real numbers under addition, the integers modulo $n$ under addition, the multiplicative group of integers modulo $n$, and the additive group of any ring. Many matrix groups are not abelian because matrix multiplication is associative and not commutative. The smallest finite non-abelian group is the dihedral group of order 6.