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Let $G$ be a group and $H$ a subgroup of $G\text{.}$ Define a of $H$ with $g \in G$ to be the set
can be defined similarly by
If left and right cosets coincide or if it is clear from the context to which type of coset that we are referring, we will use the word coset without specifying left or right.
Let $H$ be the subgroup of ${\mathbb Z}_6$ consisting of the elements 0 and 3. The cosets are
We will always write the cosets of subgroups of ${\mathbb Z}$ and ${\mathbb Z}_n$ with the additive notation we have used for cosets here. In a commutative group, left and right cosets are always identical.
Let $H$ be the subgroup of $S_3$ defined by the permutations $\{(1), (123), (132) \}\text{.}$ The left cosets of $H$ are
The right cosets of $H$ are exactly the same as the left cosets:
It is not always the case that a left coset is the same as a right coset. Let $K$ be the subgroup of $S_3$ defined by the permutations $\{(1), (1 2)\}\text{.}$ Then the left cosets of $K$ are
however, the right cosets of $K$ are
The following lemma is quite useful when dealing with cosets. (We leave its proof as an exercise.)
Let $H$ be a subgroup of a group $G$ and suppose that $g_1, g_2 \in G\text{.}$ The following conditions are equivalent.
$g_1 H = g_2 H\text{;}$
$H g_1^{-1} = H g_2^{-1}\text{;}$
$g_1 H \subset g_2 H\text{;}$
$g_2 \in g_1 H\text{;}$
$g_1^{-1} g_2 \in H\text{.}$
In all of our examples the cosets of a subgroup $H$ partition the larger group $G\text{.}$ The following theorem proclaims that this will always be the case.
Let $H$ be a subgroup of a group $G\text{.}$ Then the left cosets of $H$ in $G$ partition $G\text{.}$ That is, the group $G$ is the disjoint union of the left cosets of $H$ in $G\text{.}$
Let $g_1 H$ and $g_2 H$ be two cosets of $H$ in $G\text{.}$ We must show that either $g_1 H \cap g_2 H = \emptyset$ or $g_1 H = g_2 H\text{.}$ Suppose that $g_1 H \cap g_2 H \neq \emptyset$ and $a \in g_1 H \cap g_2 H\text{.}$ Then by the definition of a left coset, $a = g_1 h_1 = g_2 h_2$ for some elements $h_1$ and $h_2$ in $H\text{.}$ Hence, $g_1 = g_2 h_2 h_1^{-1}$ or $g_1 \in g_2 H\text{.}$ By Lemma 6.3, $g_1 H = g_2 H\text{.}$
There is nothing special in this theorem about left cosets. Right cosets also partition $G\text{;}$ the proof of this fact is exactly the same as the proof for left cosets except that all group multiplications are done on the opposite side of $H\text{.}$
Let $G$ be a group and $H$ be a subgroup of $G\text{.}$ Define the of $H$ in $G$ to be the number of left cosets of $H$ in $G\text{.}$ We will denote the index by $[G:H]\text{.}$
Let $G= {\mathbb Z}_6$ and $H = \{ 0, 3 \}\text{.}$ Then $[G:H] = 3\text{.}$
Suppose that $G= S_3\text{,}$ $H = \{ (1),(123), (132) \}\text{,}$ and $K= \{ (1), (12) \}\text{.}$ Then $[G:H] = 2$ and $[G:K] = 3\text{.}$
Let $H$ be a subgroup of a group $G\text{.}$ The number of left cosets of $H$ in $G$ is the same as the number of right cosets of $H$ in $G\text{.}$
Let ${\mathcal L}_H$ and ${\mathcal R}_H$ denote the set of left and right cosets of $H$ in $G\text{,}$ respectively. If we can define a bijective map $\phi : {\mathcal L}_H \rightarrow {\mathcal R}_H\text{,}$ then the theorem will be proved. If $gH \in {\mathcal L}_H\text{,}$ let $\phi( gH ) = Hg^{-1}\text{.}$ By Lemma 6.3, the map $\phi$ is well-defined; that is, if $g_1 H = g_2 H\text{,}$ then $H g_1^{-1} = H g_2^{-1}\text{.}$ To show that $\phi$ is one-to-one, suppose that
Again by Lemma 6.3, $g_1 H = g_2 H\text{.}$ The map $\phi$ is onto since $\phi(g^{-1} H ) = H g\text{.}$