An application of the first (group) isomorphism theorem Announcing the arrival of Valued Associate #679: Cesar Manara Planned maintenance scheduled April 23, 2019 at 23:30 UTC (7:30pm US/Eastern)The natural projection mapping $pi : G to G/N$ defined by $pi(x) = xN$, for all $x$ in $G$, is a homomorphism, and $ker(pi) = N$.Question about normal subgroup and isomorphism relationInterpretation of Second isomorphism theoremGeneralized Isomorphism Theorem for GroupsIntuition about the first isomorphism theoremApplication of first isomorphism theoremTwo normal subgroups and isomorphism theoremFinding all groups H (up to isomorphism) such that there is a surjective homomorphism from D8 to HFind isomorphism between $S_4/H$ and $S_3$ where $H=e,(12)(34),(13)(24),(14)(23)$ using isomorphism theoremFinding the kernel of $phi$ of applying the First Isomorphism TheoremApplication of first isomorphism question.
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An application of the first (group) isomorphism theorem
Announcing the arrival of Valued Associate #679: Cesar Manara
Planned maintenance scheduled April 23, 2019 at 23:30 UTC (7:30pm US/Eastern)The natural projection mapping $pi : G to G/N$ defined by $pi(x) = xN$, for all $x$ in $G$, is a homomorphism, and $ker(pi) = N$.Question about normal subgroup and isomorphism relationInterpretation of Second isomorphism theoremGeneralized Isomorphism Theorem for GroupsIntuition about the first isomorphism theoremApplication of first isomorphism theoremTwo normal subgroups and isomorphism theoremFinding all groups H (up to isomorphism) such that there is a surjective homomorphism from D8 to HFind isomorphism between $S_4/H$ and $S_3$ where $H=e,(12)(34),(13)(24),(14)(23)$ using isomorphism theoremFinding the kernel of $phi$ of applying the First Isomorphism TheoremApplication of first isomorphism question.
$begingroup$
Suppose that $G$ is a group and $N$ is a normal subgroup of $G$. How do we find out what $G/N$ is isomorphic to? For example, $C_m$ is a normal subgroup of $D_2n$ generated by a rotation of angle $2pi/m$. We can partiotion the group $D_2n$ using the normal subgrouop $C_m$. We want to find a surjective homomorphism $phi: Gto G'$ such that $ker(phi) = C_m$? What surjective homomorphism $phi: Gto G'$ should we have so that $D_2n/C_m$ is isomorphic to $G'$?
abstract-algebra group-theory normal-subgroups group-homomorphism
asked Apr 2 at 16:05
user546106user546106
1748
$endgroup$
add a comment |
$begingroup$
Suppose that $G$ is a group and $N$ is a normal subgroup of $G$. How do we find out what $G/N$ is isomorphic to? For example, $C_m$ is a normal subgroup of $D_2n$ generated by a rotation of angle $2pi/m$. We can partiotion the group $D_2n$ using the normal subgrouop $C_m$. We want to find a surjective homomorphism $phi: Gto G'$ such that $ker(phi) = C_m$? What surjective homomorphism $phi: Gto G'$ should we have so that $D_2n/C_m$ is isomorphic to $G'$?
abstract-algebra group-theory normal-subgroups group-homomorphism
asked Apr 2 at 16:05
user546106user546106
1748
$endgroup$
1
$begingroup$
Its difficult to work out what your question is. So far as I can tell, any answer is just going to re-state the first isomorphism theorem (and the current two answers do this).
$endgroup$
– user1729
Apr 2 at 16:37
$begingroup$
(On the other hand, the answer to the abstract question "how do we find out what $G/N$ is isomorphic to?" does have a concrete answer. The answer is: "you don't; in fact you can't even determine if $G/N$ is the trivial group".)
$endgroup$
– user1729
Apr 2 at 16:41
add a comment |
$begingroup$
Suppose that $G$ is a group and $N$ is a normal subgroup of $G$. How do we find out what $G/N$ is isomorphic to? For example, $C_m$ is a normal subgroup of $D_2n$ generated by a rotation of angle $2pi/m$. We can partiotion the group $D_2n$ using the normal subgrouop $C_m$. We want to find a surjective homomorphism $phi: Gto G'$ such that $ker(phi) = C_m$? What surjective homomorphism $phi: Gto G'$ should we have so that $D_2n/C_m$ is isomorphic to $G'$?
abstract-algebra group-theory normal-subgroups group-homomorphism
asked Apr 2 at 16:05
user546106user546106
1748
$endgroup$
Suppose that $G$ is a group and $N$ is a normal subgroup of $G$. How do we find out what $G/N$ is isomorphic to? For example, $C_m$ is a normal subgroup of $D_2n$ generated by a rotation of angle $2pi/m$. We can partiotion the group $D_2n$ using the normal subgrouop $C_m$. We want to find a surjective homomorphism $phi: Gto G'$ such that $ker(phi) = C_m$? What surjective homomorphism $phi: Gto G'$ should we have so that $D_2n/C_m$ is isomorphic to $G'$?
abstract-algebra group-theory normal-subgroups group-homomorphism
abstract-algebra group-theory normal-subgroups group-homomorphism
asked Apr 2 at 16:05
user546106user546106
1748
asked Apr 2 at 16:05
user546106user546106
1748
edited Apr 2 at 16:26
user546106
asked Apr 2 at 16:05
user546106user546106
1748
asked Apr 2 at 16:05
user546106user546106
1748
asked Apr 2 at 16:05
user546106user546106
1748
1748
1
$begingroup$
Its difficult to work out what your question is. So far as I can tell, any answer is just going to re-state the first isomorphism theorem (and the current two answers do this).
$endgroup$
– user1729
Apr 2 at 16:37
$begingroup$
(On the other hand, the answer to the abstract question "how do we find out what $G/N$ is isomorphic to?" does have a concrete answer. The answer is: "you don't; in fact you can't even determine if $G/N$ is the trivial group".)
$endgroup$
– user1729
Apr 2 at 16:41
add a comment |
1
$begingroup$
Its difficult to work out what your question is. So far as I can tell, any answer is just going to re-state the first isomorphism theorem (and the current two answers do this).
$endgroup$
– user1729
Apr 2 at 16:37
$begingroup$
(On the other hand, the answer to the abstract question "how do we find out what $G/N$ is isomorphic to?" does have a concrete answer. The answer is: "you don't; in fact you can't even determine if $G/N$ is the trivial group".)
$endgroup$
– user1729
Apr 2 at 16:41
1
1
$begingroup$
Its difficult to work out what your question is. So far as I can tell, any answer is just going to re-state the first isomorphism theorem (and the current two answers do this).
$endgroup$
– user1729
Apr 2 at 16:37
$begingroup$
Its difficult to work out what your question is. So far as I can tell, any answer is just going to re-state the first isomorphism theorem (and the current two answers do this).
$endgroup$
– user1729
Apr 2 at 16:37
$begingroup$
(On the other hand, the answer to the abstract question "how do we find out what $G/N$ is isomorphic to?" does have a concrete answer. The answer is: "you don't; in fact you can't even determine if $G/N$ is the trivial group".)
$endgroup$
– user1729
Apr 2 at 16:41
$begingroup$
(On the other hand, the answer to the abstract question "how do we find out what $G/N$ is isomorphic to?" does have a concrete answer. The answer is: "you don't; in fact you can't even determine if $G/N$ is the trivial group".)
$endgroup$
– user1729
Apr 2 at 16:41
add a comment |
3 Answers
3
active
oldest
votes
$begingroup$
I assume $m|n$, so $n=md$ and $C_mconglangle r^drangle$. In this case, $|D_2n/C_m|=2d$. Working with cosets you can check that the quotient is generated by $[r]=rC_m$ and $[j]=jC_m$ satisfying the relations $[r]^d=[1]=C_m$, $[j]^2=[1]=C_m$ and $[j][r]=[r^-1][j]$. The correct guess is that $$D_2n/C_mcong D_2d=langle R,Jmid R^d=J^2=1,JR=R^-1Jrangle.$$
Now, define a homomorphism $phi:D_2nto D_2d$ by $phi(r)=R$ and $phi(j)=J$ (and extend multiplicatively). Check that this map is well defined (this involves the fact that $d|n$) and surjective. By the first isomorphism theorem $$D_2n/kerphicong D_2d.$$ Finally, check that $kerphi=langle r^drangle$.
answered Apr 2 at 16:34
David HillDavid Hill
9,6561619
$endgroup$
$begingroup$
Is it possible that $D_2n/C_m cong$ some cyclic group?
$endgroup$
– user546106
Apr 2 at 16:49
$begingroup$
When $m=n$, it is isomorphic to $D_2=C_2$. Otherwise, the quotient is non-abelian.
$endgroup$
– David Hill
Apr 2 at 16:50
$begingroup$
Why is it a natural choice to pick $[r]=rC_m$ as a generator? What about $r^2C_m$?
$endgroup$
– user546106
Apr 2 at 17:04
$begingroup$
Because $r$ is a generator of $D_2n$ while $r^2$ is not, in general.
$endgroup$
– David Hill
Apr 2 at 17:08
add a comment |
$begingroup$
Define the natural homomorphism $gamma: G to G/N$ by $g mapsto gN.$ Then $N$ is the kernel of $gamma$ and we have $$G/Ncong operatornameIm(gamma).$$
See Theorem 10.4 of Gallian's "Contemporary Abstract Algebra."
answered Apr 2 at 16:19
ShaunShaun
11.1k113688
$endgroup$
$begingroup$
Are you not saying something like $G/Ncong G/N$? I think $operatornameIm(gamma) = G/N$
$endgroup$
– user546106
Apr 2 at 16:28
$begingroup$
No, since I'm applying the first isomorphism theorem, @user546106.
$endgroup$
– Shaun
Apr 2 at 16:29
1
$begingroup$
Your $gamma$ is the same as the $pi$ in my picture. How do you define $varphi$ and $G'$?
$endgroup$
– user546106
Apr 2 at 16:30
$begingroup$
I've taken the liberty of having $G'=operatornameIm(gamma)$, @user546106. It's probably best if you work on what $phi$ is yourself.
$endgroup$
– Shaun
Apr 2 at 16:34
add a comment |
$begingroup$
Usually, the first isomorphism theorem is easily satisfied by the projection map $pi:Gto G/N$ defined by $$ pi (g) = gN $$ for example see this question. Then in your specific dihedral group example, you can explicitly calculate $pi(G)$ and get that $$G/N = G/ker(pi)congpi(G) $$
edited Apr 2 at 16:30
Shaun
11.1k113688
answered Apr 2 at 16:22
NazimJNazimJ
890110
$endgroup$
$begingroup$
I think your answer and Shaun's just restate the first isomorphism theorem.
$endgroup$
– user546106
Apr 2 at 16:25
1
$begingroup$
Well to answer your question "How to find out what $G/N$ is isomorphic to?", it is equivalent to answer "how do you compute the right hand side of the first isomorphism theorem?". And we both suggest that you can compute the image of $G$ under the projection map to answer your question. Is this clearer?
$endgroup$
– NazimJ
Apr 2 at 16:30
add a comment |
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3 Answers
3
active
oldest
votes
3 Answers
3
active
oldest
votes
active
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votes
active
oldest
votes
$begingroup$
I assume $m|n$, so $n=md$ and $C_mconglangle r^drangle$. In this case, $|D_2n/C_m|=2d$. Working with cosets you can check that the quotient is generated by $[r]=rC_m$ and $[j]=jC_m$ satisfying the relations $[r]^d=[1]=C_m$, $[j]^2=[1]=C_m$ and $[j][r]=[r^-1][j]$. The correct guess is that $$D_2n/C_mcong D_2d=langle R,Jmid R^d=J^2=1,JR=R^-1Jrangle.$$
Now, define a homomorphism $phi:D_2nto D_2d$ by $phi(r)=R$ and $phi(j)=J$ (and extend multiplicatively). Check that this map is well defined (this involves the fact that $d|n$) and surjective. By the first isomorphism theorem $$D_2n/kerphicong D_2d.$$ Finally, check that $kerphi=langle r^drangle$.
answered Apr 2 at 16:34
David HillDavid Hill
9,6561619
$endgroup$
$begingroup$
Is it possible that $D_2n/C_m cong$ some cyclic group?
$endgroup$
– user546106
Apr 2 at 16:49
$begingroup$
When $m=n$, it is isomorphic to $D_2=C_2$. Otherwise, the quotient is non-abelian.
$endgroup$
– David Hill
Apr 2 at 16:50
$begingroup$
Why is it a natural choice to pick $[r]=rC_m$ as a generator? What about $r^2C_m$?
$endgroup$
– user546106
Apr 2 at 17:04
$begingroup$
Because $r$ is a generator of $D_2n$ while $r^2$ is not, in general.
$endgroup$
– David Hill
Apr 2 at 17:08
add a comment |
$begingroup$
I assume $m|n$, so $n=md$ and $C_mconglangle r^drangle$. In this case, $|D_2n/C_m|=2d$. Working with cosets you can check that the quotient is generated by $[r]=rC_m$ and $[j]=jC_m$ satisfying the relations $[r]^d=[1]=C_m$, $[j]^2=[1]=C_m$ and $[j][r]=[r^-1][j]$. The correct guess is that $$D_2n/C_mcong D_2d=langle R,Jmid R^d=J^2=1,JR=R^-1Jrangle.$$
Now, define a homomorphism $phi:D_2nto D_2d$ by $phi(r)=R$ and $phi(j)=J$ (and extend multiplicatively). Check that this map is well defined (this involves the fact that $d|n$) and surjective. By the first isomorphism theorem $$D_2n/kerphicong D_2d.$$ Finally, check that $kerphi=langle r^drangle$.
answered Apr 2 at 16:34
David HillDavid Hill
9,6561619
$endgroup$
$begingroup$
Is it possible that $D_2n/C_m cong$ some cyclic group?
$endgroup$
– user546106
Apr 2 at 16:49
$begingroup$
When $m=n$, it is isomorphic to $D_2=C_2$. Otherwise, the quotient is non-abelian.
$endgroup$
– David Hill
Apr 2 at 16:50
$begingroup$
Why is it a natural choice to pick $[r]=rC_m$ as a generator? What about $r^2C_m$?
$endgroup$
– user546106
Apr 2 at 17:04
$begingroup$
Because $r$ is a generator of $D_2n$ while $r^2$ is not, in general.
$endgroup$
– David Hill
Apr 2 at 17:08
add a comment |
$begingroup$
I assume $m|n$, so $n=md$ and $C_mconglangle r^drangle$. In this case, $|D_2n/C_m|=2d$. Working with cosets you can check that the quotient is generated by $[r]=rC_m$ and $[j]=jC_m$ satisfying the relations $[r]^d=[1]=C_m$, $[j]^2=[1]=C_m$ and $[j][r]=[r^-1][j]$. The correct guess is that $$D_2n/C_mcong D_2d=langle R,Jmid R^d=J^2=1,JR=R^-1Jrangle.$$
Now, define a homomorphism $phi:D_2nto D_2d$ by $phi(r)=R$ and $phi(j)=J$ (and extend multiplicatively). Check that this map is well defined (this involves the fact that $d|n$) and surjective. By the first isomorphism theorem $$D_2n/kerphicong D_2d.$$ Finally, check that $kerphi=langle r^drangle$.
answered Apr 2 at 16:34
David HillDavid Hill
9,6561619
$endgroup$
I assume $m|n$, so $n=md$ and $C_mconglangle r^drangle$. In this case, $|D_2n/C_m|=2d$. Working with cosets you can check that the quotient is generated by $[r]=rC_m$ and $[j]=jC_m$ satisfying the relations $[r]^d=[1]=C_m$, $[j]^2=[1]=C_m$ and $[j][r]=[r^-1][j]$. The correct guess is that $$D_2n/C_mcong D_2d=langle R,Jmid R^d=J^2=1,JR=R^-1Jrangle.$$
Now, define a homomorphism $phi:D_2nto D_2d$ by $phi(r)=R$ and $phi(j)=J$ (and extend multiplicatively). Check that this map is well defined (this involves the fact that $d|n$) and surjective. By the first isomorphism theorem $$D_2n/kerphicong D_2d.$$ Finally, check that $kerphi=langle r^drangle$.
answered Apr 2 at 16:34
David HillDavid Hill
9,6561619
edited Apr 2 at 16:43
answered Apr 2 at 16:34
David HillDavid Hill
9,6561619
answered Apr 2 at 16:34
David HillDavid Hill
9,6561619
answered Apr 2 at 16:34
David HillDavid Hill
9,6561619
9,6561619
$begingroup$
Is it possible that $D_2n/C_m cong$ some cyclic group?
$endgroup$
– user546106
Apr 2 at 16:49
$begingroup$
When $m=n$, it is isomorphic to $D_2=C_2$. Otherwise, the quotient is non-abelian.
$endgroup$
– David Hill
Apr 2 at 16:50
$begingroup$
Why is it a natural choice to pick $[r]=rC_m$ as a generator? What about $r^2C_m$?
$endgroup$
– user546106
Apr 2 at 17:04
$begingroup$
Because $r$ is a generator of $D_2n$ while $r^2$ is not, in general.
$endgroup$
– David Hill
Apr 2 at 17:08
add a comment |
$begingroup$
Is it possible that $D_2n/C_m cong$ some cyclic group?
$endgroup$
– user546106
Apr 2 at 16:49
$begingroup$
When $m=n$, it is isomorphic to $D_2=C_2$. Otherwise, the quotient is non-abelian.
$endgroup$
– David Hill
Apr 2 at 16:50
$begingroup$
Why is it a natural choice to pick $[r]=rC_m$ as a generator? What about $r^2C_m$?
$endgroup$
– user546106
Apr 2 at 17:04
$begingroup$
Because $r$ is a generator of $D_2n$ while $r^2$ is not, in general.
$endgroup$
– David Hill
Apr 2 at 17:08
$begingroup$
Is it possible that $D_2n/C_m cong$ some cyclic group?
$endgroup$
– user546106
Apr 2 at 16:49
$begingroup$
Is it possible that $D_2n/C_m cong$ some cyclic group?
$endgroup$
– user546106
Apr 2 at 16:49
$begingroup$
When $m=n$, it is isomorphic to $D_2=C_2$. Otherwise, the quotient is non-abelian.
$endgroup$
– David Hill
Apr 2 at 16:50
$begingroup$
When $m=n$, it is isomorphic to $D_2=C_2$. Otherwise, the quotient is non-abelian.
$endgroup$
– David Hill
Apr 2 at 16:50
$begingroup$
Why is it a natural choice to pick $[r]=rC_m$ as a generator? What about $r^2C_m$?
$endgroup$
– user546106
Apr 2 at 17:04
$begingroup$
Why is it a natural choice to pick $[r]=rC_m$ as a generator? What about $r^2C_m$?
$endgroup$
– user546106
Apr 2 at 17:04
$begingroup$
Because $r$ is a generator of $D_2n$ while $r^2$ is not, in general.
$endgroup$
– David Hill
Apr 2 at 17:08
$begingroup$
Because $r$ is a generator of $D_2n$ while $r^2$ is not, in general.
$endgroup$
– David Hill
Apr 2 at 17:08
add a comment |
$begingroup$
Define the natural homomorphism $gamma: G to G/N$ by $g mapsto gN.$ Then $N$ is the kernel of $gamma$ and we have $$G/Ncong operatornameIm(gamma).$$
See Theorem 10.4 of Gallian's "Contemporary Abstract Algebra."
answered Apr 2 at 16:19
ShaunShaun
11.1k113688
$endgroup$
$begingroup$
Are you not saying something like $G/Ncong G/N$? I think $operatornameIm(gamma) = G/N$
$endgroup$
– user546106
Apr 2 at 16:28
$begingroup$
No, since I'm applying the first isomorphism theorem, @user546106.
$endgroup$
– Shaun
Apr 2 at 16:29
1
$begingroup$
Your $gamma$ is the same as the $pi$ in my picture. How do you define $varphi$ and $G'$?
$endgroup$
– user546106
Apr 2 at 16:30
$begingroup$
I've taken the liberty of having $G'=operatornameIm(gamma)$, @user546106. It's probably best if you work on what $phi$ is yourself.
$endgroup$
– Shaun
Apr 2 at 16:34
add a comment |
$begingroup$
Define the natural homomorphism $gamma: G to G/N$ by $g mapsto gN.$ Then $N$ is the kernel of $gamma$ and we have $$G/Ncong operatornameIm(gamma).$$
See Theorem 10.4 of Gallian's "Contemporary Abstract Algebra."
answered Apr 2 at 16:19
ShaunShaun
11.1k113688
$endgroup$
$begingroup$
Are you not saying something like $G/Ncong G/N$? I think $operatornameIm(gamma) = G/N$
$endgroup$
– user546106
Apr 2 at 16:28
$begingroup$
No, since I'm applying the first isomorphism theorem, @user546106.
$endgroup$
– Shaun
Apr 2 at 16:29
1
$begingroup$
Your $gamma$ is the same as the $pi$ in my picture. How do you define $varphi$ and $G'$?
$endgroup$
– user546106
Apr 2 at 16:30
$begingroup$
I've taken the liberty of having $G'=operatornameIm(gamma)$, @user546106. It's probably best if you work on what $phi$ is yourself.
$endgroup$
– Shaun
Apr 2 at 16:34
add a comment |
$begingroup$
Define the natural homomorphism $gamma: G to G/N$ by $g mapsto gN.$ Then $N$ is the kernel of $gamma$ and we have $$G/Ncong operatornameIm(gamma).$$
See Theorem 10.4 of Gallian's "Contemporary Abstract Algebra."
answered Apr 2 at 16:19
ShaunShaun
11.1k113688
$endgroup$
Define the natural homomorphism $gamma: G to G/N$ by $g mapsto gN.$ Then $N$ is the kernel of $gamma$ and we have $$G/Ncong operatornameIm(gamma).$$
See Theorem 10.4 of Gallian's "Contemporary Abstract Algebra."
answered Apr 2 at 16:19
ShaunShaun
11.1k113688
edited Apr 2 at 16:28
answered Apr 2 at 16:19
ShaunShaun
11.1k113688
answered Apr 2 at 16:19
ShaunShaun
11.1k113688
answered Apr 2 at 16:19
ShaunShaun
11.1k113688
11.1k113688
$begingroup$
Are you not saying something like $G/Ncong G/N$? I think $operatornameIm(gamma) = G/N$
$endgroup$
– user546106
Apr 2 at 16:28
$begingroup$
No, since I'm applying the first isomorphism theorem, @user546106.
$endgroup$
– Shaun
Apr 2 at 16:29
1
$begingroup$
Your $gamma$ is the same as the $pi$ in my picture. How do you define $varphi$ and $G'$?
$endgroup$
– user546106
Apr 2 at 16:30
$begingroup$
I've taken the liberty of having $G'=operatornameIm(gamma)$, @user546106. It's probably best if you work on what $phi$ is yourself.
$endgroup$
– Shaun
Apr 2 at 16:34
add a comment |
$begingroup$
Are you not saying something like $G/Ncong G/N$? I think $operatornameIm(gamma) = G/N$
$endgroup$
– user546106
Apr 2 at 16:28
$begingroup$
No, since I'm applying the first isomorphism theorem, @user546106.
$endgroup$
– Shaun
Apr 2 at 16:29
1
$begingroup$
Your $gamma$ is the same as the $pi$ in my picture. How do you define $varphi$ and $G'$?
$endgroup$
– user546106
Apr 2 at 16:30
$begingroup$
I've taken the liberty of having $G'=operatornameIm(gamma)$, @user546106. It's probably best if you work on what $phi$ is yourself.
$endgroup$
– Shaun
Apr 2 at 16:34
$begingroup$
Are you not saying something like $G/Ncong G/N$? I think $operatornameIm(gamma) = G/N$
$endgroup$
– user546106
Apr 2 at 16:28
$begingroup$
Are you not saying something like $G/Ncong G/N$? I think $operatornameIm(gamma) = G/N$
$endgroup$
– user546106
Apr 2 at 16:28
$begingroup$
No, since I'm applying the first isomorphism theorem, @user546106.
$endgroup$
– Shaun
Apr 2 at 16:29
$begingroup$
No, since I'm applying the first isomorphism theorem, @user546106.
$endgroup$
– Shaun
Apr 2 at 16:29
1
1
$begingroup$
Your $gamma$ is the same as the $pi$ in my picture. How do you define $varphi$ and $G'$?
$endgroup$
– user546106
Apr 2 at 16:30
$begingroup$
Your $gamma$ is the same as the $pi$ in my picture. How do you define $varphi$ and $G'$?
$endgroup$
– user546106
Apr 2 at 16:30
$begingroup$
I've taken the liberty of having $G'=operatornameIm(gamma)$, @user546106. It's probably best if you work on what $phi$ is yourself.
$endgroup$
– Shaun
Apr 2 at 16:34
$begingroup$
I've taken the liberty of having $G'=operatornameIm(gamma)$, @user546106. It's probably best if you work on what $phi$ is yourself.
$endgroup$
– Shaun
Apr 2 at 16:34
add a comment |
$begingroup$
Usually, the first isomorphism theorem is easily satisfied by the projection map $pi:Gto G/N$ defined by $$ pi (g) = gN $$ for example see this question. Then in your specific dihedral group example, you can explicitly calculate $pi(G)$ and get that $$G/N = G/ker(pi)congpi(G) $$
edited Apr 2 at 16:30
Shaun
11.1k113688
answered Apr 2 at 16:22
NazimJNazimJ
890110
$endgroup$
$begingroup$
I think your answer and Shaun's just restate the first isomorphism theorem.
$endgroup$
– user546106
Apr 2 at 16:25
1
$begingroup$
Well to answer your question "How to find out what $G/N$ is isomorphic to?", it is equivalent to answer "how do you compute the right hand side of the first isomorphism theorem?". And we both suggest that you can compute the image of $G$ under the projection map to answer your question. Is this clearer?
$endgroup$
– NazimJ
Apr 2 at 16:30
add a comment |
$begingroup$
Usually, the first isomorphism theorem is easily satisfied by the projection map $pi:Gto G/N$ defined by $$ pi (g) = gN $$ for example see this question. Then in your specific dihedral group example, you can explicitly calculate $pi(G)$ and get that $$G/N = G/ker(pi)congpi(G) $$
edited Apr 2 at 16:30
Shaun
11.1k113688
answered Apr 2 at 16:22
NazimJNazimJ
890110
$endgroup$
$begingroup$
I think your answer and Shaun's just restate the first isomorphism theorem.
$endgroup$
– user546106
Apr 2 at 16:25
1
$begingroup$
Well to answer your question "How to find out what $G/N$ is isomorphic to?", it is equivalent to answer "how do you compute the right hand side of the first isomorphism theorem?". And we both suggest that you can compute the image of $G$ under the projection map to answer your question. Is this clearer?
$endgroup$
– NazimJ
Apr 2 at 16:30
add a comment |
$begingroup$
Usually, the first isomorphism theorem is easily satisfied by the projection map $pi:Gto G/N$ defined by $$ pi (g) = gN $$ for example see this question. Then in your specific dihedral group example, you can explicitly calculate $pi(G)$ and get that $$G/N = G/ker(pi)congpi(G) $$
edited Apr 2 at 16:30
Shaun
11.1k113688
answered Apr 2 at 16:22
NazimJNazimJ
890110
$endgroup$
Usually, the first isomorphism theorem is easily satisfied by the projection map $pi:Gto G/N$ defined by $$ pi (g) = gN $$ for example see this question. Then in your specific dihedral group example, you can explicitly calculate $pi(G)$ and get that $$G/N = G/ker(pi)congpi(G) $$
edited Apr 2 at 16:30
Shaun
11.1k113688
answered Apr 2 at 16:22
NazimJNazimJ
890110
edited Apr 2 at 16:30
Shaun
11.1k113688
edited Apr 2 at 16:30
Shaun
11.1k113688
edited Apr 2 at 16:30
Shaun
11.1k113688
11.1k113688
answered Apr 2 at 16:22
NazimJNazimJ
890110
answered Apr 2 at 16:22
NazimJNazimJ
890110
answered Apr 2 at 16:22
NazimJNazimJ
890110
890110
$begingroup$
I think your answer and Shaun's just restate the first isomorphism theorem.
$endgroup$
– user546106
Apr 2 at 16:25
1
$begingroup$
Well to answer your question "How to find out what $G/N$ is isomorphic to?", it is equivalent to answer "how do you compute the right hand side of the first isomorphism theorem?". And we both suggest that you can compute the image of $G$ under the projection map to answer your question. Is this clearer?
$endgroup$
– NazimJ
Apr 2 at 16:30
add a comment |
$begingroup$
I think your answer and Shaun's just restate the first isomorphism theorem.
$endgroup$
– user546106
Apr 2 at 16:25
1
$begingroup$
Well to answer your question "How to find out what $G/N$ is isomorphic to?", it is equivalent to answer "how do you compute the right hand side of the first isomorphism theorem?". And we both suggest that you can compute the image of $G$ under the projection map to answer your question. Is this clearer?
$endgroup$
– NazimJ
Apr 2 at 16:30
$begingroup$
I think your answer and Shaun's just restate the first isomorphism theorem.
$endgroup$
– user546106
Apr 2 at 16:25
$begingroup$
I think your answer and Shaun's just restate the first isomorphism theorem.
$endgroup$
– user546106
Apr 2 at 16:25
1
1
$begingroup$
Well to answer your question "How to find out what $G/N$ is isomorphic to?", it is equivalent to answer "how do you compute the right hand side of the first isomorphism theorem?". And we both suggest that you can compute the image of $G$ under the projection map to answer your question. Is this clearer?
$endgroup$
– NazimJ
Apr 2 at 16:30
$begingroup$
Well to answer your question "How to find out what $G/N$ is isomorphic to?", it is equivalent to answer "how do you compute the right hand side of the first isomorphism theorem?". And we both suggest that you can compute the image of $G$ under the projection map to answer your question. Is this clearer?
$endgroup$
– NazimJ
Apr 2 at 16:30
add a comment |
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$begingroup$
Its difficult to work out what your question is. So far as I can tell, any answer is just going to re-state the first isomorphism theorem (and the current two answers do this).
$endgroup$
– user1729
Apr 2 at 16:37
$begingroup$
(On the other hand, the answer to the abstract question "how do we find out what $G/N$ is isomorphic to?" does have a concrete answer. The answer is: "you don't; in fact you can't even determine if $G/N$ is the trivial group".)
$endgroup$
– user1729
Apr 2 at 16:41