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As something more concrete now, which is a must-know, let us try to compute the dihedral group. This is a famous group, constructed as follows:


{{defncard|label=|id=|The dihedral group <math>D_N</math> is the symmetry group of
<math display="block">
\xymatrix@R=12pt@C=12pt{
&\bullet\ar@{-}[r]\ar@{-}[dl]&\bullet\ar@{-}[dr]\\
\bullet\ar@{-}[d]&&&\bullet\ar@{-}[d]\\
\bullet\ar@{-}[dr]&&&\bullet\ar@{-}[dl]\\
&\bullet\ar@{-}[r]&\bullet}
</math>
that is, of the regular polygon having <math>N</math> vertices.}}
In order to understand how this works, here are the basic examples of regular <math>N</math>-gons, at small values of the parameter <math>N\in\mathbb N</math>, along with their symmetry groups:
\underline{<math>N=2</math>}. Here the <math>N</math>-gon is just a segment, and its symmetries are obviously the identity <math>id</math>, plus the symmetry <math>\tau</math> with respect to the middle of the segment:
<math display="block">
\xymatrix@R=10pt@C=20pt{
&\ar@{.}[dd]\\
\bullet\ar@{-}[rr]&&\bullet\\
&}
</math>
Thus we have <math>D_2=\{id,\tau\}</math>, which in group theory terms means <math>D_2=\mathbb Z_2</math>.
\underline{<math>N=3</math>}. Here the <math>N</math>-gon is an equilateral triangle, and we have 6 symmetries, the rotations of angles <math>0^\circ</math>, <math>120^\circ</math>, <math>240^\circ</math>, and the symmetries with respect to the altitudes:
<math display="block">
\xymatrix@R=13pt@C=28pt{
&\bullet\ar@{-}[dddr]\ar@{-}[dddl]\ar@{.}[dddd]\\
\ar@{.}[ddrr]&&\ar@{.}[ddll]\\
\\
\bullet\ar@{-}[rr]&&\bullet\\
&
}
</math>
Alternatively, we can say that the symmetries are all the <math>3!=6</math> possible permutations of the vertices, and so that in group theory terms, we have <math>D_3=S_3</math>.
\underline{<math>N=4</math>}. Here the <math>N</math>-gon is a square, and as symmetries we have 4 rotations, of angles <math>0^\circ,90^\circ,180^\circ,270^\circ</math>, as well as 4 symmetries, with respect to the 4 symmetry axes, which are the 2 diagonals, and the 2 segments joining the midpoints of opposite sides:
<math display="block">
\xymatrix@R=26pt@C=26pt{
\bullet\ar@{-}[dd]\ar@{.}[ddrr]\ar@{-}[rr]&\ar@{.}[dd]&\bullet\ar@{-}[dd]\ar@{.}[ddll]\\
\ar@{.}[rr]&&\\
\bullet\ar@{-}[rr]&&\bullet
}
</math>
Thus, we obtain as symmetry group some sort of product between <math>\mathbb Z_4</math> and <math>\mathbb Z_2</math>. Observe however that this product is not the usual one, our group being not abelian.
\underline{<math>N=5</math>}. Here the <math>N</math>-gon is a regular pentagon, and as symmetries we have 5 rotations, of angles <math>0^\circ,72^\circ,144^\circ,216^\circ,288^\circ</math>, as well as 5 symmetries, with respect to the 5 symmetry axes, which join the vertices to the midpoints of the opposite sides:
<math display="block">
\xymatrix@R=13pt@C=11pt{
&&\bullet\ar@{-}[ddrr]\ar@{-}[ddll]\ar@{.}[dddd]\\
&&&&\\
\bullet\ar@{-}[ddr]\ar@{.}[drrrr]&&&&\bullet\ar@{-}[ddl]\ar@{.}[dllll]\\
&&&&\\
&\bullet\ar@{-}[rr]\ar@{.}[uuurr]&&\bullet\ar@{.}[uuull]&&
}
</math>
\underline{<math>N=6</math>}. Here the <math>N</math>-gon is a regular hexagon, and we have 6 rotations, of angles <math>0^\circ,60^\circ,120^\circ,180^\circ,240^\circ,300^\circ</math>, and 6 symmetries, with respect to the 6 symmetry axes, which are the 3 diagonals, and the 3 segments joining the midpoints of opposite sides:
<math display="block">
\xymatrix@R=4pt@C=14pt{
&&\bullet\ar@{-}[ddrr]\ar@{-}[ddll]\ar@{.}[dddddddd]\\
&\ar@{.}[ddddddrr]&&\ar@{.}[ddddddll]\\
\bullet\ar@{-}[dddd]\ar@{.}[ddddrrrr]&&&&\bullet\ar@{-}[dddd]\ar@{.}[ddddllll]\\
&&&&\\
\ar@{.}[rrrr]&&&&\\
&&&&\\
\bullet\ar@{-}[ddrr]&&&&\bullet\ar@{-}[ddll]\\
&&&&\\
&&\bullet
}
</math>
We can see from the above that the various dihedral groups <math>D_N</math> have many common features, and that there are some differences as well. In general, we have:
{{proofcard|Proposition|proposition-1|The dihedral group <math>D_N</math> has <math>2N</math> elements, as follows:
<ul><li> We have <math>N</math> rotations <math>R_1,\ldots,R_N</math>, with <math>R_k</math> being the rotation of angle <math>2k\pi/N</math>. When labelling the vertices <math>1,\ldots,N</math>, the formula is <math>R_k:i\to k+i</math>.
</li>
<li> We have <math>N</math> symmetries <math>S_1,\ldots,S_N</math>, with <math>S_k</math> being the symmetry with respect to the <math>Ox</math> axis rotated by <math>k\pi/N</math>. The symmetry formula is <math>S_k:i\to k-i</math>.
</li>
</ul>
|Our group is indeed formed of <math>N</math> rotations, of angles <math>2k\pi/N</math> with <math>k=1,\ldots,N</math>, and then of the <math>N</math> symmetries with respect to the <math>N</math> possible symmetry axes, which are the <math>N</math> medians of the <math>N</math>-gon when <math>N</math> is odd, and are the <math>N/2</math> diagonals plus the <math>N/2</math> lines connecting the midpoints of opposite edges, when <math>N</math> is even.}}
With the above result in hand, we can talk about <math>D_N</math> abstractly, as follows:
{{proofcard|Theorem|theorem-1|The dihedral group <math>D_N</math> is the group having <math>2N</math> elements, <math>R_1,\ldots,R_N</math> and <math>S_1,\ldots,S_N</math>, called rotations and symmetries, which multiply as follows,
<math display="block">
R_kR_l=R_{k+l}\quad,\quad
R_kS_l=S_{k+l}
</math>
<math display="block">
S_kR_l=S_{k-l}\quad,\quad
S_kS_l=R_{k-l}
</math>
with all the indices being taken modulo <math>N</math>.
|With notations from Proposition 4.24, the various compositions between rotations and symmetries can be computed as follows:
<math display="block">
R_kR_l\ :\ i\to l+i\to k+l+i\quad,\quad
R_kS_l\ :\ i\to l-i\to k+l-i
</math>
<math display="block">
S_kR_l\ :\ i\to l+i\to k-l-i\quad,\quad
S_kS_l\ :\ i\to l-i\to k-l+i
</math>
But these are exactly the formulae for <math>R_{k+l},S_{k+l},S_{k-l},R_{k-l}</math>, as stated. Now since a group is uniquely determined by its multiplication rules, this gives the result.}}
Observe that <math>D_N</math> has the same cardinality as <math>E_N=\mathbb Z_N\times\mathbb Z_2</math>. We obviously don't have <math>D_N\simeq E_N</math>, because <math>D_N</math> is not abelian, while <math>E_N</math> is. So, our next goal will be that of proving that <math>D_N</math> appears by “twisting” <math>E_N</math>. In order to do this, let us start with:
{{proofcard|Proposition|proposition-2|The group <math>E_N=\mathbb Z_N\times\mathbb Z_2</math> is the group having <math>2N</math> elements, <math>r_1,\ldots,r_N</math> and <math>s_1,\ldots,s_N</math>, which multiply according to the following rules,
<math display="block">
r_kr_l=r_{k+l}\quad,\quad
r_ks_l=s_{k+l}
</math>
<math display="block">
s_kr_l=s_{k+l}\quad,\quad
s_ks_l=r_{k+l}
</math>
with all the indices being taken modulo <math>N</math>.
|With the notation <math>\mathbb Z_2=\{1,\tau\}</math>, the elements of the product group <math>E_N=\mathbb Z_N\times\mathbb Z_2</math> can be labelled <math>r_1,\ldots,r_N</math> and <math>s_1,\ldots,s_N</math>, as follows:
<math display="block">
r_k=(k,1)\quad,\quad
s_k=(k,\tau)
</math>
These elements multiply then according to the formulae in the statement. Now since a group is uniquely determined by its multiplication rules, this gives the result.}}
Let us compare now Theorem 4.25 and Proposition 4.26. In order to formally obtain <math>D_N</math> from <math>E_N</math>, we must twist some of the multiplication rules of <math>E_N</math>, namely:
<math display="block">
s_kr_l=s_{k+l}\to s_{k-l}\quad,\quad
s_ks_l=r_{k+l}\to r_{k-l}
</math>
Informally, this amounts in following the rule “<math>\tau</math> switches the sign of what comes afterwards”, and we are led in this way to the following definition:
{{defncard|label=|id=|Given two groups <math>A,G</math>, with an action <math>A\curvearrowright G</math>, the crossed product
<math display="block">
P=G\rtimes A
</math>
is the set <math>G\times A</math>, with multiplication <math>(g,a)(h,b)=(gh^a,ab)</math>.}}
Now with this technology in hand, by getting back to the dihedral group <math>D_N</math>, we can improve Theorem 4.25, into a final result on the subject, as follows:
{{proofcard|Theorem|theorem-2|We have a crossed product decomposition as follows,
<math display="block">
D_N=\mathbb Z_N\rtimes\mathbb Z_2
</math>
with <math>\mathbb Z_2=\{1,\tau\}</math> acting on <math>\mathbb Z_N</math> via switching signs, <math>k^\tau=-k</math>.
|We have an action <math>\mathbb Z_2\curvearrowright\mathbb Z_N</math> given by the formula in the statement, namely <math>k^\tau=-k</math>, so we can consider the corresponding crossed product group:
<math display="block">
P_N=\mathbb Z_N\rtimes\mathbb Z_2
</math>
In order to understand the structure of <math>P_N</math>, we follow Proposition 4.26. The elements of <math>P_N</math> can indeed be labelled <math>\rho_1,\ldots,\rho_N</math> and <math>\sigma_1,\ldots,\sigma_N</math>, as follows:
<math display="block">
\rho_k=(k,1)\quad,\quad
\sigma_k=(k,\tau)
</math>
Now when computing the products of such elements, we basically obtain the formulae in Proposition 4.26, perturbed as in Definition 4.27. To be more precise, we have:
<math display="block">
\rho_k\rho_l=\rho_{k+l}\quad,\quad
\rho_k\sigma_l=\sigma_{k+l}
</math>
<math display="block">
\sigma_k\rho_l=\sigma_{k+l}\quad,\quad
\sigma_k\sigma_l=\rho_{k+l}
</math>
But these are exactly the multiplication formulae for <math>D_N</math>, from Theorem 4.25. Thus, we have an isomorphism <math>D_N\simeq P_N</math> given by <math>R_k\to\rho_k</math> and <math>S_k\to\sigma_k</math>, as desired.}}
==General references==
{{cite arXiv|last1=Banica|first1=Teo|year=2024|title=Graphs and their symmetries|eprint=2406.03664|class=math.CO}}

Latest revision as of 21:16, 21 April 2025

[math] \newcommand{\mathds}{\mathbb}[/math]

This article was automatically generated from a tex file and may contain conversion errors. If permitted, you may login and edit this article to improve the conversion.

As something more concrete now, which is a must-know, let us try to compute the dihedral group. This is a famous group, constructed as follows:

Definition

The dihedral group [math]D_N[/math] is the symmetry group of

[[math]] \xymatrix@R=12pt@C=12pt{ &\bullet\ar@{-}[r]\ar@{-}[dl]&\bullet\ar@{-}[dr]\\ \bullet\ar@{-}[d]&&&\bullet\ar@{-}[d]\\ \bullet\ar@{-}[dr]&&&\bullet\ar@{-}[dl]\\ &\bullet\ar@{-}[r]&\bullet} [[/math]]
that is, of the regular polygon having [math]N[/math] vertices.

In order to understand how this works, here are the basic examples of regular [math]N[/math]-gons, at small values of the parameter [math]N\in\mathbb N[/math], along with their symmetry groups:


\underline{[math]N=2[/math]}. Here the [math]N[/math]-gon is just a segment, and its symmetries are obviously the identity [math]id[/math], plus the symmetry [math]\tau[/math] with respect to the middle of the segment:

[[math]] \xymatrix@R=10pt@C=20pt{ &\ar@{.}[dd]\\ \bullet\ar@{-}[rr]&&\bullet\\ &} [[/math]]


Thus we have [math]D_2=\{id,\tau\}[/math], which in group theory terms means [math]D_2=\mathbb Z_2[/math].


\underline{[math]N=3[/math]}. Here the [math]N[/math]-gon is an equilateral triangle, and we have 6 symmetries, the rotations of angles [math]0^\circ[/math], [math]120^\circ[/math], [math]240^\circ[/math], and the symmetries with respect to the altitudes:

[[math]] \xymatrix@R=13pt@C=28pt{ &\bullet\ar@{-}[dddr]\ar@{-}[dddl]\ar@{.}[dddd]\\ \ar@{.}[ddrr]&&\ar@{.}[ddll]\\ \\ \bullet\ar@{-}[rr]&&\bullet\\ & } [[/math]]


Alternatively, we can say that the symmetries are all the [math]3!=6[/math] possible permutations of the vertices, and so that in group theory terms, we have [math]D_3=S_3[/math].


\underline{[math]N=4[/math]}. Here the [math]N[/math]-gon is a square, and as symmetries we have 4 rotations, of angles [math]0^\circ,90^\circ,180^\circ,270^\circ[/math], as well as 4 symmetries, with respect to the 4 symmetry axes, which are the 2 diagonals, and the 2 segments joining the midpoints of opposite sides:

[[math]] \xymatrix@R=26pt@C=26pt{ \bullet\ar@{-}[dd]\ar@{.}[ddrr]\ar@{-}[rr]&\ar@{.}[dd]&\bullet\ar@{-}[dd]\ar@{.}[ddll]\\ \ar@{.}[rr]&&\\ \bullet\ar@{-}[rr]&&\bullet } [[/math]]


Thus, we obtain as symmetry group some sort of product between [math]\mathbb Z_4[/math] and [math]\mathbb Z_2[/math]. Observe however that this product is not the usual one, our group being not abelian.


\underline{[math]N=5[/math]}. Here the [math]N[/math]-gon is a regular pentagon, and as symmetries we have 5 rotations, of angles [math]0^\circ,72^\circ,144^\circ,216^\circ,288^\circ[/math], as well as 5 symmetries, with respect to the 5 symmetry axes, which join the vertices to the midpoints of the opposite sides:

[[math]] \xymatrix@R=13pt@C=11pt{ &&\bullet\ar@{-}[ddrr]\ar@{-}[ddll]\ar@{.}[dddd]\\ &&&&\\ \bullet\ar@{-}[ddr]\ar@{.}[drrrr]&&&&\bullet\ar@{-}[ddl]\ar@{.}[dllll]\\ &&&&\\ &\bullet\ar@{-}[rr]\ar@{.}[uuurr]&&\bullet\ar@{.}[uuull]&& } [[/math]]


\underline{[math]N=6[/math]}. Here the [math]N[/math]-gon is a regular hexagon, and we have 6 rotations, of angles [math]0^\circ,60^\circ,120^\circ,180^\circ,240^\circ,300^\circ[/math], and 6 symmetries, with respect to the 6 symmetry axes, which are the 3 diagonals, and the 3 segments joining the midpoints of opposite sides:

[[math]] \xymatrix@R=4pt@C=14pt{ &&\bullet\ar@{-}[ddrr]\ar@{-}[ddll]\ar@{.}[dddddddd]\\ &\ar@{.}[ddddddrr]&&\ar@{.}[ddddddll]\\ \bullet\ar@{-}[dddd]\ar@{.}[ddddrrrr]&&&&\bullet\ar@{-}[dddd]\ar@{.}[ddddllll]\\ &&&&\\ \ar@{.}[rrrr]&&&&\\ &&&&\\ \bullet\ar@{-}[ddrr]&&&&\bullet\ar@{-}[ddll]\\ &&&&\\ &&\bullet } [[/math]]


We can see from the above that the various dihedral groups [math]D_N[/math] have many common features, and that there are some differences as well. In general, we have:

Proposition

The dihedral group [math]D_N[/math] has [math]2N[/math] elements, as follows:

  • We have [math]N[/math] rotations [math]R_1,\ldots,R_N[/math], with [math]R_k[/math] being the rotation of angle [math]2k\pi/N[/math]. When labelling the vertices [math]1,\ldots,N[/math], the formula is [math]R_k:i\to k+i[/math].
  • We have [math]N[/math] symmetries [math]S_1,\ldots,S_N[/math], with [math]S_k[/math] being the symmetry with respect to the [math]Ox[/math] axis rotated by [math]k\pi/N[/math]. The symmetry formula is [math]S_k:i\to k-i[/math].


Show Proof

Our group is indeed formed of [math]N[/math] rotations, of angles [math]2k\pi/N[/math] with [math]k=1,\ldots,N[/math], and then of the [math]N[/math] symmetries with respect to the [math]N[/math] possible symmetry axes, which are the [math]N[/math] medians of the [math]N[/math]-gon when [math]N[/math] is odd, and are the [math]N/2[/math] diagonals plus the [math]N/2[/math] lines connecting the midpoints of opposite edges, when [math]N[/math] is even.

With the above result in hand, we can talk about [math]D_N[/math] abstractly, as follows:

Theorem

The dihedral group [math]D_N[/math] is the group having [math]2N[/math] elements, [math]R_1,\ldots,R_N[/math] and [math]S_1,\ldots,S_N[/math], called rotations and symmetries, which multiply as follows,

[[math]] R_kR_l=R_{k+l}\quad,\quad R_kS_l=S_{k+l} [[/math]]

[[math]] S_kR_l=S_{k-l}\quad,\quad S_kS_l=R_{k-l} [[/math]]
with all the indices being taken modulo [math]N[/math].


Show Proof

With notations from Proposition 4.24, the various compositions between rotations and symmetries can be computed as follows:

[[math]] R_kR_l\ :\ i\to l+i\to k+l+i\quad,\quad R_kS_l\ :\ i\to l-i\to k+l-i [[/math]]

[[math]] S_kR_l\ :\ i\to l+i\to k-l-i\quad,\quad S_kS_l\ :\ i\to l-i\to k-l+i [[/math]]


But these are exactly the formulae for [math]R_{k+l},S_{k+l},S_{k-l},R_{k-l}[/math], as stated. Now since a group is uniquely determined by its multiplication rules, this gives the result.

Observe that [math]D_N[/math] has the same cardinality as [math]E_N=\mathbb Z_N\times\mathbb Z_2[/math]. We obviously don't have [math]D_N\simeq E_N[/math], because [math]D_N[/math] is not abelian, while [math]E_N[/math] is. So, our next goal will be that of proving that [math]D_N[/math] appears by “twisting” [math]E_N[/math]. In order to do this, let us start with:

Proposition

The group [math]E_N=\mathbb Z_N\times\mathbb Z_2[/math] is the group having [math]2N[/math] elements, [math]r_1,\ldots,r_N[/math] and [math]s_1,\ldots,s_N[/math], which multiply according to the following rules,

[[math]] r_kr_l=r_{k+l}\quad,\quad r_ks_l=s_{k+l} [[/math]]

[[math]] s_kr_l=s_{k+l}\quad,\quad s_ks_l=r_{k+l} [[/math]]
with all the indices being taken modulo [math]N[/math].


Show Proof

With the notation [math]\mathbb Z_2=\{1,\tau\}[/math], the elements of the product group [math]E_N=\mathbb Z_N\times\mathbb Z_2[/math] can be labelled [math]r_1,\ldots,r_N[/math] and [math]s_1,\ldots,s_N[/math], as follows:

[[math]] r_k=(k,1)\quad,\quad s_k=(k,\tau) [[/math]]


These elements multiply then according to the formulae in the statement. Now since a group is uniquely determined by its multiplication rules, this gives the result.

Let us compare now Theorem 4.25 and Proposition 4.26. In order to formally obtain [math]D_N[/math] from [math]E_N[/math], we must twist some of the multiplication rules of [math]E_N[/math], namely:

[[math]] s_kr_l=s_{k+l}\to s_{k-l}\quad,\quad s_ks_l=r_{k+l}\to r_{k-l} [[/math]]


Informally, this amounts in following the rule “[math]\tau[/math] switches the sign of what comes afterwards”, and we are led in this way to the following definition:

Definition

Given two groups [math]A,G[/math], with an action [math]A\curvearrowright G[/math], the crossed product

[[math]] P=G\rtimes A [[/math]]
is the set [math]G\times A[/math], with multiplication [math](g,a)(h,b)=(gh^a,ab)[/math].

Now with this technology in hand, by getting back to the dihedral group [math]D_N[/math], we can improve Theorem 4.25, into a final result on the subject, as follows:

Theorem

We have a crossed product decomposition as follows,

[[math]] D_N=\mathbb Z_N\rtimes\mathbb Z_2 [[/math]]
with [math]\mathbb Z_2=\{1,\tau\}[/math] acting on [math]\mathbb Z_N[/math] via switching signs, [math]k^\tau=-k[/math].


Show Proof

We have an action [math]\mathbb Z_2\curvearrowright\mathbb Z_N[/math] given by the formula in the statement, namely [math]k^\tau=-k[/math], so we can consider the corresponding crossed product group:

[[math]] P_N=\mathbb Z_N\rtimes\mathbb Z_2 [[/math]]


In order to understand the structure of [math]P_N[/math], we follow Proposition 4.26. The elements of [math]P_N[/math] can indeed be labelled [math]\rho_1,\ldots,\rho_N[/math] and [math]\sigma_1,\ldots,\sigma_N[/math], as follows:

[[math]] \rho_k=(k,1)\quad,\quad \sigma_k=(k,\tau) [[/math]]


Now when computing the products of such elements, we basically obtain the formulae in Proposition 4.26, perturbed as in Definition 4.27. To be more precise, we have:

[[math]] \rho_k\rho_l=\rho_{k+l}\quad,\quad \rho_k\sigma_l=\sigma_{k+l} [[/math]]

[[math]] \sigma_k\rho_l=\sigma_{k+l}\quad,\quad \sigma_k\sigma_l=\rho_{k+l} [[/math]]


But these are exactly the multiplication formulae for [math]D_N[/math], from Theorem 4.25. Thus, we have an isomorphism [math]D_N\simeq P_N[/math] given by [math]R_k\to\rho_k[/math] and [math]S_k\to\sigma_k[/math], as desired.

General references

Banica, Teo (2024). "Graphs and their symmetries". arXiv:2406.03664 [math.CO].

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