Difference between revisions of "Cosets and Lagrange’s Theorem"

Left and Right Cosets of Subgroups

Definition: Let ${\displaystyle (G,\cdot )}$ be a group and let ${\displaystyle (H,\cdot )}$ be a subgroup. Let ${\displaystyle g\in G}$. Then the Left Coset of ${\displaystyle H}$ with Representative ${\displaystyle g}$ is the set ${\displaystyle gH=\{gh:h\in H\}}$. The Right Coset of ${\displaystyle H}$ with Representative ${\displaystyle g}$ is the set ${\displaystyle Hg=\{hg:h\in H\}}$.

When the operation symbol “${\displaystyle +}$” is used instead of ${\displaystyle \cdot }$ we often denote the left and right cosets of ${\displaystyle H}$ with representation ${\displaystyle g}$ with the notation ${\displaystyle g+H}$ and ${\displaystyle H+g}$ respectively.

For example, consider the group ${\displaystyle (\mathbb {Z} ,+)}$ and the subgroup ${\displaystyle (3\mathbb {Z} ,+)}$. Consider the element ${\displaystyle 2\in \mathbb {Z} }$. Then the left coset of ${\displaystyle 3\mathbb {Z} }$ with representative ${\displaystyle 2}$ is:

${\displaystyle {\begin{aligned}\quad 2+3\mathbb {Z} =\{2+h:h\in 3\mathbb {Z} \}=\{...,-1,2,5,...\}\end{aligned}}}$

And the right coset of ${\displaystyle 3\mathbb {Z} }$ with representative ${\displaystyle 2}$ is:

${\displaystyle {\begin{aligned}\quad 3\mathbb {Z} +2=\{h+2:h\in 3\mathbb {Z} \}=\{...,-1,2,5,...\}\end{aligned}}}$

In this particular example we see that ${\displaystyle 2+3\mathbb {Z} =3\mathbb {Z} +2}$. But in general, is ${\displaystyle gH=Hg}$ for a given subgroup ${\displaystyle (H,\cdot )}$ of ${\displaystyle (G,\cdot )}$ and for ${\displaystyle g\in G}$? The answer is NO. There are many examples when left cosets are not equal to corresponding right cosets.

To illustrate this, consider the symmetric group ${\displaystyle (S_{3},\circ )}$. Let ${\displaystyle G=\{\epsilon ,(12)\}}$. Then ${\displaystyle (G,\circ )}$ is a subgroup of ${\displaystyle (S_{3},\circ )}$ since ${\displaystyle G\subset S_{3}}$, ${\displaystyle G}$ is closed under ${\displaystyle \circ }$, and ${\displaystyle \epsilon ^{-1}=\epsilon }$, ${\displaystyle (12)^{-1}=(12)}$ (since ${\displaystyle (12)}$ is a transposition). Now consider the element ${\displaystyle (13)\in S_{3}}$. Then the left coset of ${\displaystyle G}$ with representative ${\displaystyle (13)}$ is:

${\displaystyle {\begin{aligned}\quad (13)G=\{(13)\circ h:h\in G\}=\{(13)\circ \epsilon ,(13)\circ (12)\}=\{(13),(123)\}\end{aligned}}}$

And the right coset of ${\displaystyle G}$ with representative ${\displaystyle (13)}$ is:

${\displaystyle {\begin{aligned}\quad G(13)=\{h\circ (13):h\in G\}=\{\epsilon \circ (13),(12)\circ (13)\}=\{(13),(132)\}\end{aligned}}}$

We note that ${\displaystyle (123)\neq (132)}$ and so ${\displaystyle (13)G\neq G(13)}$!

So, when exactly are the left and right cosets of a subgroup with representative ${\displaystyle g}$ equal? The following theorem gives us a simple criterion for a large class of groups.

Proposition 1: Let ${\displaystyle (G,\cdot )}$ be a group and let ${\displaystyle (H,\cdot )}$ be a subgroup. If ${\displaystyle (G,\cdot )}$ is abelian then for all ${\displaystyle g\in G}$, ${\displaystyle gH=Hg}$.

• Proof: Let ${\displaystyle g\in G}$. If ${\displaystyle G}$ is abelian then for all ${\displaystyle h\in G}$ (and hence for all ${\displaystyle h\in H}$) we have that ${\displaystyle g\cdot h=h\cdot g}$. So:

${\displaystyle {\begin{aligned}\quad gH=\{g\cdot h:h\in H\}=\{h\cdot g:h\in H\}=Hg\quad \blacksquare \end{aligned}}}$

Proposition 2: Let ${\displaystyle (G,\cdot )}$ be a group, ${\displaystyle (H,\cdot )}$ a subgroup, and ${\displaystyle g_{1},g_{2}\in G}$. Then the following statements are equivalent:

a) ${\displaystyle g_{1}H=g_{2}H}$.
b) ${\displaystyle Hg_{1}^{-1}=Hg_{2}^{-1}}$.
c) ${\displaystyle g_{1}H\subseteq g_{2}H}$.
d) ${\displaystyle g_{1}\in g_{2}H}$.

e) ${\displaystyle g_{1}^{-1}g_{2}\in H}$.

The Set of Left (Right) Cosets of a Subgroup Partitions the Whole Group

Recall that if ${\displaystyle (G,\cdot )}$ is a group, ${\displaystyle (H,\cdot )}$ is a subgroup, and ${\displaystyle g\in G}$ then the left coset of ${\displaystyle H}$ with representative ${\displaystyle g}$ is the set:

${\displaystyle {\begin{aligned}\quad gH=\{gh:h\in H\}\end{aligned}}}$

The right coset of ${\displaystyle H}$ with representative ${\displaystyle g}$ is the set:

${\displaystyle {\begin{aligned}\quad Hg=\{hg:h\in H\}\end{aligned}}}$

We will now look at a nice theorem which tells us that the set of all left cosets of a subgroup ${\displaystyle (H,\cdot )}$ actually partitions ${\displaystyle (G,\cdot )}$. The proof below can be mirrored to analogously show that the set of all right cosets of a subgroup ${\displaystyle (H,\cdot )}$ also partitions ${\displaystyle (G,\cdot )}$.

Theorem 1: Let ${\displaystyle (G,\cdot )}$ be a group and let ${\displaystyle (H,\cdot )}$ a subgroup. Then the set of all left cosets of ${\displaystyle (H,\cdot )}$ partitions ${\displaystyle (G,\cdot )}$.

Recall that a partition of a set ${\displaystyle A}$ is a collection of nonempty subsets of ${\displaystyle A}$ that are pairwise disjoint and whose union is all of ${\displaystyle A}$.

• Proof: We first show that any two distinct left cosets of ${\displaystyle H}$ are disjoint. Let ${\displaystyle g_{1},g_{2}\in G}$, ${\displaystyle g_{1}\neq g_{2}}$ and assume the left cosets ${\displaystyle g_{1}H}$ and ${\displaystyle g_{2}H}$ are distinct. Suppose that ${\displaystyle g_{1}H\cap g_{2}H\neq \emptyset }$. Then there exists an ${\displaystyle x\in g_{1}H\cap g_{2}H}$. So ${\displaystyle x\in g_{1}H}$ and ${\displaystyle x\in g_{2}H}$ and there exists ${\displaystyle h_{1},h_{2}\in H}$ such that:

${\displaystyle {\begin{aligned}\quad x=g_{1}h_{1}\quad (*)\end{aligned}}}$

${\displaystyle {\begin{aligned}\quad x=g_{2}h_{2}\quad (**)\end{aligned}}}$

• So using ${\displaystyle (*)}$ and ${\displaystyle (**)}$ we see that ${\displaystyle g_{1}h_{1}=g_{2}h_{2}}$. So ${\displaystyle g_{1}=g_{2}h_{2}h_{1}^{-1}}$. But ${\displaystyle h_{2}h_{1}^{-1}\in H}$ since ${\displaystyle (H,\cdot )}$ is a group and is hence closed under ${\displaystyle \cdot }$. So ${\displaystyle g_{1}\in g_{2}H}$. But this means that ${\displaystyle g_{1}H=g_{2}H}$, a contradiction since ${\displaystyle g_{1}H}$ and ${\displaystyle g_{2}H}$ distinct. So the assumption that ${\displaystyle g_{1}H\cap g_{2}H\neq \emptyset }$ was false. So:

${\displaystyle {\begin{aligned}\quad g_{1}H\cap g_{2}H=\emptyset \end{aligned}}}$

• Now if ${\displaystyle i}$ is the identity element for ${\displaystyle (G,\cdot )}$ then ${\displaystyle i\in H}$ since ${\displaystyle (H,\cdot )}$ is a subgroup and must contain the identity element. So ${\displaystyle g=gi\in gH}$ for all ${\displaystyle g\in G}$. So:

${\displaystyle {\begin{aligned}\quad G=\bigcup _{g\in G}gH\end{aligned}}}$

• Therefore the left cosets of ${\displaystyle (H,\cdot )}$ partition ${\displaystyle (G,\cdot )}$.

The Number of Elements in a Left (Right) Coset

Recall that if ${\displaystyle (G,\cdot )}$ is a group, ${\displaystyle (H,\cdot )}$ is a subgroup, and ${\displaystyle g\in G}$ then the left coset of ${\displaystyle H}$ with representative ${\displaystyle g}$ is defined as:

${\displaystyle {\begin{aligned}\quad gH=\{gh:h\in H\}\end{aligned}}}$

The right coset of ${\displaystyle H}$ with representative ${\displaystyle g}$ is defined as:

${\displaystyle {\begin{aligned}\quad Hg=\{hg:h\in H\}\end{aligned}}}$

We will now look at a rather simple theorem which will tell us that the number of elements in a left (or right coset) will equal to the number of elements in ${\displaystyle H}$. This seems rather obvious since ${\displaystyle gH}$ contains elements of the form ${\displaystyle gh}$ where we range through all of ${\displaystyle h}$. So ${\displaystyle gH}$ has at most the same number of elements in ${\displaystyle H}$. Of course, ${\displaystyle gH}$ may have less elements if ${\displaystyle gh_{1}=gh_{2}}$ for distinct ${\displaystyle h_{1},h_{2}\in H}$. Of course this cannot be since by cancellation we would then have that ${\displaystyle h_{1}=h_{2}}$. We make this argument more rigorous below.

Theorem 1: Let ${\displaystyle (G,\cdot )}$ be a group, ${\displaystyle (H,\cdot )}$ a subgroup, and let ${\displaystyle g\in G}$. Then the number of elements in ${\displaystyle gH}$ equals the number of elements in ${\displaystyle H}$, i.e., ${\displaystyle \mid gH\mid =\mid H\mid }$. Similarly, ${\displaystyle \mid Hg\mid =\mid H\mid }$.

We only prove the case of this theorem for left cosets. The case for right cosets is analogous.

• Proof: Define a function ${\displaystyle f:H\to gH}$ for all ${\displaystyle h\in H}$ by:

${\displaystyle {\begin{aligned}\quad f(h)=gh\end{aligned}}}$

• We will show that ${\displaystyle f}$ is bijective. First we show that ${\displaystyle f}$ is injective. Let ${\displaystyle h_{1},h_{2}\in H}$ and assume that ${\displaystyle f(h_{1})=f(h_{2})}$. Then we have that:

${\displaystyle {\begin{aligned}\quad gh_{1}=gh_{2}\end{aligned}}}$

• By left cancellation this implies that ${\displaystyle h_{1}=h_{2}}$ and so ${\displaystyle f}$ is injective. We now show that ${\displaystyle f}$ is surjective. Let ${\displaystyle gh\in gH}$. Then ${\displaystyle f(h)=gh}$ (somewhat trivially) so ${\displaystyle f}$ is surjective.

• Since ${\displaystyle f}$ is bijective we have that ${\displaystyle \mid H\mid =\mid gH\mid }$ so the number of elements in the left coset ${\displaystyle gH}$ is equal to the number of elements in ${\displaystyle H}$. ${\displaystyle \blacksquare }$

The Index of a Subgroup

If ${\displaystyle (G,\cdot )}$ is a group and ${\displaystyle (H,\cdot )}$ is a subgroup then we might want to know the number of left cosets and the number of right cosets of ${\displaystyle H}$. As the following theorem will show - the number of left cosets of ${\displaystyle H}$ will always equal the number of right cosets of ${\displaystyle H}$.

Theorem 1: Let ${\displaystyle (G,\cdot )}$ be a group and let ${\displaystyle (H,\cdot )}$ be a subgroup. Then the number of left cosets of ${\displaystyle H}$ equals the number of right cosets of ${\displaystyle H}$.

• Proof: Let ${\displaystyle L_{H}}$ denote the set of all left cosets of ${\displaystyle H}$ and let ${\displaystyle R_{H}}$ denote the set of all right cosets of ${\displaystyle H}$. Define a function ${\displaystyle f:L_{H}\to R_{H}}$ for all ${\displaystyle gH\in L_{H}}$ by

${\displaystyle {\begin{aligned}\quad f(gH)=Hg^{-1}\end{aligned}}}$

• If we can show that ${\displaystyle f}$ is bijective then ${\displaystyle \mid L_{H}\mid =\mid R_{H}}$. We first show that ${\displaystyle f}$ is injective. Let ${\displaystyle g_{1}H,g_{2}H\in L_{H}}$ and suppose that ${\displaystyle f(g_{1}H)=f(g_{2}H)}$. Then:

${\displaystyle {\begin{aligned}\quad Hg_{1}^{-1}=Hg_{2}^{-1}\end{aligned}}}$

• But then by the theorem of equivalent statements presented on the <a href="/left-and-right-cosets-of-subgroups">Left and Right Cosets of Subgroups</a> page we must have that:

${\displaystyle {\begin{aligned}\quad g_{1}H=g_{2}H\end{aligned}}}$

• Hence ${\displaystyle f}$ is injective. We now show that ${\displaystyle f}$ is surjective. Let ${\displaystyle Hg\in R_{H}}$. Then we have that for ${\displaystyle g^{-1}H\in L_{H}}$ that:

${\displaystyle {\begin{aligned}\quad f(g^{-1}H)=H(g^{-1})^{-1}=Hg\end{aligned}}}$

• So ${\displaystyle f}$ is indeed surjective. Since ${\displaystyle f}$ is a function from a finite set to a finite set that is bijective we must have that ${\displaystyle \mid L_{H}\mid =\mid R_{H}\mid }$, i.e., the number of left cosets of ${\displaystyle H}$ equals the number of right cosets of ${\displaystyle H}$. ${\displaystyle \blacksquare }$

With the result above, we can unambiguously define the index of subgroup ${\displaystyle (H,\cdot )}$ in a group ${\displaystyle (G,\cdot )}$.

Definition: Let ${\displaystyle (G,\cdot )}$ be a group and let ${\displaystyle (H,\cdot )}$ be a subgroup. The Index of ${\displaystyle H}$ in ${\displaystyle G}$ denoted ${\displaystyle [G:H]}$ is defined as the number of left (or right) cosets of ${\displaystyle H}$.

For example, consider the symmetric group ${\displaystyle (S_{3},\circ )}$ and let ${\displaystyle H=\{\epsilon ,(12)\}}$. Let's find the index ${\displaystyle S_{3}:H]}$. Note that ${\displaystyle S_{3}=\{\epsilon ,(12),(13),(23),(123),(132)\}}$. So the left cosets of ${\displaystyle H}$ in ${\displaystyle S_{3}}$ are:

${\displaystyle {\begin{aligned}\quad \epsilon H=\{\epsilon \circ \epsilon ,\epsilon \circ (12)\}=\{\epsilon ,(12)\}\\\end{aligned}}}$

${\displaystyle {\begin{aligned}\quad (12)H=\{(12)\circ \epsilon ,(12)\circ (12)\}=\{(12),\epsilon \}\end{aligned}}}$

${\displaystyle {\begin{aligned}\quad (13)H=\{(13)\circ \epsilon ,(13)\circ (12)\}=\{(13),(123)\}\end{aligned}}}$

${\displaystyle {\begin{aligned}\quad (23)H=\{(23)\circ \epsilon ,(23)\circ (12)\}=\{(23),(132)\}\end{aligned}}}$

${\displaystyle {\begin{aligned}\quad (123)H=\{(123)\circ \epsilon ,(123)\circ (12)\}=\{(123),(13)\}\end{aligned}}}$

${\displaystyle {\begin{aligned}\quad (132)H=\{(132)\circ \epsilon ,(132)\circ (12)\}=\{(132),(23)\}\end{aligned}}}$

So the set of left cosets of ${\displaystyle H}$ is:

${\displaystyle {\begin{aligned}\quad \{\{\epsilon ,(12)\},\{(13),(123)\},\{(23),(132)\}\}\end{aligned}}}$

There are three such cosets so ${\displaystyle [S_{3}:H]=3}$.

For another example, consider the group ${\displaystyle (\mathbb {Z} ,+)}$ and the subgroup ${\displaystyle (3\mathbb {Z} ,+)}$. Then the left cosets of ${\displaystyle (3\mathbb {Z} ,+)}$ are:

${\displaystyle {\begin{aligned}\quad 0+3\mathbb {Z} =\{...,-3,0,3,...\}\end{aligned}}}$

${\displaystyle {\begin{aligned}\quad 1+3\mathbb {Z} =\{...,-2,1,4,...\}\end{aligned}}}$

${\displaystyle {\begin{aligned}\quad 2+3\mathbb {Z} =\{...,-1,2,5,...\}\end{aligned}}}$

Note that if ${\displaystyle m\equiv n{\pmod {3}}}$ then ${\displaystyle m+3\mathbb {Z} =n+3\mathbb {Z} }$. So in this example we have that ${\displaystyle [\mathbb {Z} :3\mathbb {Z} ]=3}$.

Lagrange's Theorem

We now have all of the tools to prove a very important and astonishing theorem regarding subgroups. This theorem is known as Lagrange's theorem and will tell us that the number of elements in a subgroup of a larger group must divide the number of elements in the larger group.

Theorem 1 (Lagrange's Theorem): Let ${\displaystyle (G,\cdot )}$ be a finite group and let ${\displaystyle (H,\cdot )}$ be a subgroup. Then the number of elements in ${\displaystyle H}$ must divide the number of elements in ${\displaystyle G}$.

• Proof:The set of left cosets of ${\displaystyle H}$ partition ${\displaystyle G}$, that is for all ${\displaystyle g_{1},g_{2}\in G}$ with ${\displaystyle g_{1}\neq g_{2}}$ we have that, ${\displaystyle g_{1}H\cap g_{2}H=\emptyset }$ and:

${\displaystyle {\begin{aligned}\quad G=\bigcup _{g\in G}gH\end{aligned}}}$

• The number of left cosets of ${\displaystyle H}$ is the index ${\displaystyle [G:H]}$ and the number of elements in ${\displaystyle gH}$ is equal to the number of elements in ${\displaystyle H}$. So:

${\displaystyle {\begin{aligned}\quad \mid G\mid =[G:H]\mid H\mid \end{aligned}}}$

• Therefore ${\displaystyle \mid H\mid }$ divides ${\displaystyle \mid G\mid }$, i.e., the number of elements in any subgroup ${\displaystyle (H,\cdot )}$ of a finite group ${\displaystyle (G,\cdot )}$ must divide the number of elements in ${\displaystyle (G,\cdot )}$. ${\displaystyle \blacksquare }$

Corollaries to Lagrange's Theorem

Recall that if ${\displaystyle (G,\cdot )}$ is a finite group and ${\displaystyle (H,\cdot )}$ is a subgroup then the number of elements in ${\displaystyle H}$ must divide the number of elements in ${\displaystyle G}$ and moreover:

${\displaystyle {\begin{aligned}\quad \mid G\mid =[G:H]\mid H\mid \end{aligned}}}$

We will now prove some amazing corollaries relating to Lagrange's theorem.

Corollary 1: Let ${\displaystyle (G,\cdot )}$ be a finite group and let ${\displaystyle (H,\cdot )}$ be a subgroup. Then the index of ${\displaystyle H}$ is ${\displaystyle G}$ is given by ${\displaystyle \displaystyle {[G:H]={\frac {\mid G\mid }{\mid H\mid }}}}$.

• Proof: Rearrange the formula in the proof of Lagrange's theorem. ${\displaystyle \blacksquare }$

Corollary 2: Let ${\displaystyle (G,\cdot )}$ be a finite group and let ${\displaystyle g\in G}$. Then the order of the element ${\displaystyle g}$ must divide ${\displaystyle \mid G\mid }$.

The order of an element ${\displaystyle g}$ is the smallest positive integer ${\displaystyle n}$ such that ${\displaystyle g^{n}=e}$ (where of course, ${\displaystyle e}$ is the identity element for the group.

• Proof: The order of the element ${\displaystyle g}$ is the smallest positive integer ${\displaystyle n}$ such that ${\displaystyle g^{n}=e}$. The generated subgroup ${\displaystyle (<g>,\cdot )}$ is such that ${\displaystyle \mid <g>\mid =n}$. So by Lagrange's theorem ${\displaystyle n=\mid <g>\mid }$ must divide ${\displaystyle \mid G\mid }$, i.e., the order of ${\displaystyle g}$ must divide ${\displaystyle \mid G\mid }$.

Corollary 3: Let ${\displaystyle (G,\cdot )}$ be a finite group of order ${\displaystyle \mid G\mid =p}$ where ${\displaystyle p}$ is a prime number. Then ${\displaystyle G}$ is a cyclic group.

• Proof: Let ${\displaystyle g\in G}$ be any non-identity element in ${\displaystyle G}$ (which exists since ${\displaystyle p\geq 2}$). By Lagrange's Theorem, the subgroup ${\displaystyle (<g>,\cdot )}$ must be such that ${\displaystyle \mid <g>\mid }$ divides ${\displaystyle \mid G\mid =p}$. But the only positive divisors of ${\displaystyle p}$ are ${\displaystyle 1}$ and ${\displaystyle p}$.

• So if ${\displaystyle \mid <g>\mid =1}$ then ${\displaystyle g=e}$ which is a contradiction since we assumed that ${\displaystyle g}$ is not the identity for the group. So ${\displaystyle \mid <g>\mid =p}$, i.e., ${\displaystyle G=<g>}$. So ${\displaystyle G}$ is a cyclic group.

Corollary 4: Let ${\displaystyle (G,\cdot )}$ be a finite group and let ${\displaystyle (H,\cdot )}$ and ${\displaystyle (I,\cdot )}$ be subgroups of ${\displaystyle G}$ such that ${\displaystyle I\subseteq H\subseteq G}$. Then ${\displaystyle [G:I]=[G:H][H:I]}$.

• Proof: By Lagrange's theorem we have that:

${\displaystyle {\begin{aligned}\quad [G:I]&={\frac {\mid G\mid }{\mid I\mid }}={\frac {\mid G\mid }{\mid H\mid }}\cdot {\frac {\mid H\mid }{\mid I\mid }}=[G:H][H:I]\quad \blacksquare \end{aligned}}}$

Licensing

Content obtained and/or adapted from:

• Left and Right Cosets of Subgroups, mathonline.wikidot.com under a CC BY-SA license
• The Set of Left (Right) Cosets of a Subgroup Partitions the Whole Group, mathonline.wikidot.com under a CC BY-SA license
• The Number of Elements in a Left (Right) Coset, mathonline.wikidot.com under a CC BY-SA license
• The Index of a Subgroup, mathonline.wikidot.com under a CC BY-SA license
• Lagrange's Theorem, mathonline.wikidot.com under a CC BY-SA license
• Corollaries to Lagrange's Theorem, mathonline.wikidot.com under a CC BY-SA license