Left coset of a subgroup: Difference between revisions

Revision as of 13:02, 22 March 2008

This article is about a basic definition in group theory. The article text may, however, contain advanced material.
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Definition

Definition with symbols

Let $H$ be a subgroup of a group $G$ . Then, a left coset of $H$ is a nonempty set $S$ satisfying the following equivalent properties:

$x^{- 1} y$ is in $H$ for any $x$ and $y$ in $S$ , and any element of $H$ can be written as $x^{- 1} y$ for some $x, y \in S$
There exists an $x$ in $G$ such that $S = x H$
For any $x$ in $S$ , $S = x H$

Equivalence of definitions

For full proof, refer: Equivalence of definitions of left coset

Facts

Left congruence

The left cosets of a subgroup are pairwise disjoint, and hence form a partition of the group. The relation of being in the same left coset is an equivalence relation on the group, and this equivalence relation is termed the left congruence induced by the subgroup.

Relation with right coset

Every subset that occurs as a left coset of a subgroup also occurs as a right coset. In fact, the left coset $x H$ occurs as the right coset $(x H x^{- 1}) x$ with $x H x^{- 1}$ being the new subgroup.

Numerical facts

Size of each left coset

Let $H$ be a subgroup of $G$ and $x$ be any element of $G$ . Then, the map sending $g$ in $H$ to $x g$ is a bijection from $H$ to $x H$ .

For full proof, refer: Left cosets are in bijection via left multiplication

Number of left cosets

The number of left cosets of a subgroup is termed the index of that subgroup.

Since all left cosets have the same size as the subgroup, we have a formula for the index of the subgroup when the whole group is finite: it is the ratio of the order of the group to the order of the subgroup.

This incidentally also proves Lagrange's theorem -- the order of any subgroup of a finite group divides the order of the whole group.

Natural isomorphism of left cosets with right cosets

There is a natural bijection between the set of left cosets of a subgroup and the set of right cosets of that subgroup. This bijection arises from the natural antiautomorphism of a group defined by the map sending each element to its inverse. Further information: Left and right coset spaces are naturally isomorphic

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 Let <math>H</math> be a [[subgroup]] of a [[group]] <math>G</math>. Then, a '''left coset''' of <math>H</math> is a nonempty set <math>S</math> satisfying the following equivalent properties:
-* <math>x^{-1}y</math> is in <math>H</math> for any <math>x</math> and <math>y</math> in <math>S</math>
+* <math>x^{-1}y</math> is in <math>H</math> for any <math>x</math> and <math>y</math> in <math>S</math>, and any element of <math>H</math> can be written as <math>x^{-1}y</math> for some <math>x,y \in S</math>
 * There exists an <math>x</math> in <math>G</math> such that <math>S = xH</math>
 * For any <math>x</math> in <math>S</math>, <math>S = xH</math>