Order formulas for linear groups: Difference between revisions

This article gives a list of formulas for the orders of the general linear group of finite degree ${\displaystyle n\geq 1}$ and some other related groups, both for a finite field of size ${\displaystyle q}$ and for related rings.

For a finite field of size ${\displaystyle q}$

Formulas

In the formulas below, the field size is ${\displaystyle q}$ and the degree (order of matrices involved, dimension of vector space being acted upon) is ${\displaystyle n}$. The characteristic of the field is a prime number ${\displaystyle p}$. ${\displaystyle q}$ is a prime power with underlying prime ${\displaystyle p}$. We let ${\displaystyle r=\log _{p}q}$, so ${\displaystyle q=p^{r}}$ and ${\displaystyle r}$ is a nonnegative integer.

In the table below, ${\displaystyle \Phi _{d}(q)}$ stands for the ${\displaystyle d^{th}}$ cyclotomic polynomial evaluated at ${\displaystyle q}$.

Group	Symbolic notation	Order formula	Order formula (powers of ${\displaystyle q}$ taken out)	Order formula (maximally factorized)	Degree as polynomial in ${\displaystyle q}$ (same as algebraic dimension)	Multiplicity of factor ${\displaystyle q}$	Multiplicity of factor ${\displaystyle q-1}$	Quick explanation for order
general linear group	${\displaystyle GL(n,q)}$ or ${\displaystyle GL(n,\mathbb {F} _{q})}$	${\displaystyle \prod _{i=0}^{n-1}(q^{n}-q^{i})}$	${\displaystyle q^{\binom {n}{2}}\prod _{i=0}^{n-1}(q^{n-i}-1)}$	${\displaystyle q^{\binom {n}{2}}\prod _{d=1}^{n}(\Phi _{d}(q))^{\lfloor n/d\rfloor }}$	${\displaystyle n^{2}}$	${\displaystyle {\binom {n}{2}}={\frac {n(n-1)}{2}}}$	${\displaystyle n}$	See full explanation below.
special linear group	${\displaystyle SL(n,q)}$ or ${\displaystyle SL(n,\mathbb {F} _{q})}$	${\displaystyle {\frac {\prod _{i=0}^{n-1}(q^{n}-q^{i})}{q-1}}}$	${\displaystyle q^{\binom {n}{2}}\prod _{i=0}^{n-2}(q^{n-i}-1)}$	${\displaystyle q^{\binom {n}{2}}(q-1)^{n-1}\prod _{d=2}^{n}(\Phi _{d}(q))^{\lfloor n/d\rfloor }}$	${\displaystyle n^{2}-1}$	${\displaystyle {\binom {n}{2}}={\frac {n(n-1)}{2}}}$	${\displaystyle n-1}$	${\displaystyle |GL(n,q)|/|\mathbb {F} _{q}^{\ast }|}$; see full explanation below.
projective general linear group	${\displaystyle PGL(n,q)}$ or ${\displaystyle PGL(n,\mathbb {F} _{q})}$	${\displaystyle {\frac {\prod _{i=0}^{n-1}(q^{n}-q^{i})}{q-1}}}$	${\displaystyle q^{\binom {n}{2}}\prod _{i=0}^{n-2}(q^{n-i}-1)}$	${\displaystyle q^{\binom {n}{2}}(q-1)^{n-1}\prod _{d=2}^{n}(\Phi _{d}(q))^{\lfloor n/d\rfloor }}$	${\displaystyle n^{2}-1}$	${\displaystyle {\binom {n}{2}}={\frac {n(n-1)}{2}}}$	${\displaystyle n-1}$	${\displaystyle |GL(n,q)|/|\mathbb {F} _{q}^{\ast }|}$; see full explanation below.
projective special linear group	${\displaystyle PSL(n,q)}$ or ${\displaystyle PSL(n,\mathbb {F} _{q})}$	${\displaystyle {\frac {\prod _{i=0}^{n-1}(q^{n}-q^{i})}{(q-1)\operatorname {gcd} (n,q-1)}}}$	${\displaystyle q^{\binom {n}{2}}{\frac {\prod _{i=0}^{n-2}(q^{n-i}-1)}{\operatorname {gcd} (n,q-1)}}}$	${\displaystyle q^{\binom {n}{2}}{\frac {(q-1)^{n-1}\prod _{d=2}^{n}(\Phi _{d}(q))^{\lfloor n/d\rfloor }}{\operatorname {gcd} (n,q-1)}}}$	${\displaystyle n^{2}-1}$ (ignoring gcd term)	${\displaystyle {\binom {n}{2}}={\frac {n(n-1)}{2}}}$	${\displaystyle n-1}$ (ignoring gcd term)	${\displaystyle |SL(n,q)|}$ divided by the number of ${\displaystyle n^{th}}$ roots in ${\displaystyle \mathbb {F} _{q}^{\ast }}$; see full explanation below.
general semilinear group	${\displaystyle \Gamma L(n,q)}$ or ${\displaystyle \Gamma L(n,\mathbb {F} _{q})}$	${\displaystyle r\prod _{i=0}^{n-1}(q^{n}-q^{i})}$	${\displaystyle rq^{\binom {n}{2}}\prod _{i=0}^{n-1}(q^{n-i}-1)}$	${\displaystyle rq^{\binom {n}{2}}\prod _{d=1}^{n}(\Phi _{d}(q))^{\lfloor n/d\rfloor }}$	${\displaystyle n^{2}}$	${\displaystyle {\binom {n}{2}}={\frac {n(n-1)}{2}}}$	${\displaystyle n}$	${\displaystyle r}$ times the order of ${\displaystyle GL(n,q)}$; see full explanation below.
outer linear group	${\displaystyle OL(n,q)}$ or ${\displaystyle OL(n,\mathbb {F} _{q})}$	${\displaystyle 2\prod _{i=0}^{n-1}(q^{n}-q^{i})}$	${\displaystyle 2q^{\binom {n}{2}}\prod _{i=0}^{n-1}(q^{n-i}-1)}$	${\displaystyle 2q^{\binom {n}{2}}\prod _{d=1}^{n}(\Phi _{d}(q))^{\lfloor n/d\rfloor }}$	${\displaystyle n^{2}}$	${\displaystyle {\binom {n}{2}}={\frac {n(n-1)}{2}}}$	${\displaystyle n}$	Twice the order of ${\displaystyle GL(n,q)}$; see full explanation below.
outer semilinear group	${\displaystyle O\Gamma L(n,q)}$ or ${\displaystyle O\Gamma L(n,\mathbb {F} _{q})}$	${\displaystyle 2r\prod _{i=0}^{n-1}(q^{n}-q^{i})}$	${\displaystyle 2rq^{\binom {n}{2}}\prod _{i=0}^{n-1}(q^{n-i}-1)}$	${\displaystyle 2rq^{\binom {n}{2}}\prod _{d=1}^{n}(\Phi _{d}(q))^{\lfloor n/d\rfloor }}$	${\displaystyle n^{2}}$	${\displaystyle {\binom {n}{2}}={\frac {n(n-1)}{2}}}$	${\displaystyle n}$	${\displaystyle 2r}$ times the order of ${\displaystyle GL(n,q)}$; see full explanation below.
special semilinear group	?	${\displaystyle r{\frac {\prod _{i=0}^{n-1}(q^{n}-q^{i})}{q-1}}}$	${\displaystyle rq^{\binom {n}{2}}\prod _{i=0}^{n-2}(q^{n-i}-1)}$	${\displaystyle rq^{\binom {n}{2}}(q-1)^{n-1}\prod _{d=2}^{n}(\Phi _{d}(q))^{\lfloor n/d\rfloor }}$	${\displaystyle n^{2}-1}$	${\displaystyle {\binom {n}{2}}={\frac {n(n-1)}{2}}}$	${\displaystyle n-1}$	${\displaystyle r}$ times the order of ${\displaystyle SL(n,q)}$; explanation similar to that for general semilinear group.
projective semilinear group	${\displaystyle P\Gamma L(n,q)}$ or ${\displaystyle P\Gamma L(n,\mathbb {F} _{q})}$	${\displaystyle r{\frac {\prod _{i=0}^{n-1}(q^{n}-q^{i})}{q-1}}}$	${\displaystyle rq^{\binom {n}{2}}\prod _{i=0}^{n-2}(q^{n-i}-1)}$	${\displaystyle rq^{\binom {n}{2}}(q-1)^{n-1}\prod _{d=2}^{n}(\Phi _{d}(q))^{\lfloor n/d\rfloor }}$	${\displaystyle n^{2}-1}$	${\displaystyle {\binom {n}{2}}={\frac {n(n-1)}{2}}}$	${\displaystyle n-1}$	${\displaystyle r}$ times the order of ${\displaystyle PGL(n,q)}$; explanation similar to that for general semilinear group.
projective special semilinear group	?	${\displaystyle r{\frac {\prod _{i=0}^{n-1}(q^{n}-q^{i})}{(q-1)\operatorname {gcd} (n,q-1)}}}$	${\displaystyle rq^{\binom {n}{2}}{\frac {\prod _{i=0}^{n-2}(q^{n-i}-1)}{\operatorname {gcd} (n,q-1)}}}$	${\displaystyle rq^{\binom {n}{2}}{\frac {(q-1)^{n-1}\prod _{d=2}^{n}(\Phi _{d}(q))^{\lfloor n/d\rfloor }}{\operatorname {gcd} (n,q-1)}}}$	${\displaystyle n^{2}-1}$ (ignoring gcd term)	${\displaystyle {\binom {n}{2}}={\frac {n(n-1)}{2}}}$	${\displaystyle n-1}$ (ignoring gcd term)	${\displaystyle r}$ times the order of ${\displaystyle PGL(n,q)}$; explanation similar to that for general semilinear group.
general affine group	${\displaystyle GA(n,q)}$ or ${\displaystyle GA(n,\mathbb {F} _{q})}$	${\displaystyle q^{n}\prod _{i=0}^{n-1}(q^{n}-q^{i})}$	${\displaystyle q^{\binom {n+1}{2}}\prod _{i=0}^{n-1}(q^{n-i}-1)}$	${\displaystyle q^{\binom {n+1}{2}}\prod _{d=1}^{n}(\Phi _{d}(q))^{\lfloor n/d\rfloor }}$	${\displaystyle n(n+1)}$	${\displaystyle {\binom {n+1}{2}}={\frac {n(n+1)}{2}}}$	${\displaystyle n}$	${\displaystyle q^{n}}$ times the order of ${\displaystyle GL(n,q)}$
special affine group	${\displaystyle SA(n,q)}$ or ${\displaystyle SA(n,\mathbb {F} _{q})}$	${\displaystyle q^{n}{\frac {\prod _{i=0}^{n-1}(q^{n}-q^{i})}{q-1}}}$	${\displaystyle q^{\binom {n+1}{2}}\prod _{i=0}^{n-2}(q^{n-i}-1)}$	${\displaystyle q^{\binom {n+1}{2}}(q-1)^{n-1}\prod _{d=2}^{n}(\Phi _{d}(q))^{\lfloor n/d\rfloor }}$	${\displaystyle n^{2}+n-1}$	${\displaystyle {\binom {n+1}{2}}={\frac {n(n-1)}{2}}}$	${\displaystyle n-1}$	${\displaystyle q^{n}}$ times the order of ${\displaystyle GL(n,q)}$
general semiaffine group	${\displaystyle \Gamma A(n,q)}$ or ${\displaystyle \Gamma A(n,\mathbb {F} _{q})}$	${\displaystyle rq^{n}\prod _{i=0}^{n-1}(q^{n}-q^{i})}$	${\displaystyle rq^{\binom {n+1}{2}}\prod _{i=0}^{n-1}(q^{n-i}-1)}$	${\displaystyle rq^{\binom {n+1}{2}}\prod _{d=1}^{n}(\Phi _{d}(q))^{\lfloor n/d\rfloor }}$	${\displaystyle n(n+1)}$	${\displaystyle {\binom {n+1}{2}}={\frac {n(n+1)}{2}}}$	${\displaystyle n}$	${\displaystyle r}$ times the order of ${\displaystyle GA(n,q)}$
special semiaffine group	?	${\displaystyle rq^{n}{\frac {\prod _{i=0}^{n-1}(q^{n}-q^{i})}{q-1}}}$	${\displaystyle rq^{\binom {n+1}{2}}\prod _{i=0}^{n-2}(q^{n-i}-1)}$	${\displaystyle rq^{\binom {n+1}{2}}(q-1)^{n-1}\prod _{d=2}^{n}(\Phi _{d}(q))^{\lfloor n/d\rfloor }}$	${\displaystyle n^{2}+n-1}$	${\displaystyle {\binom {n+1}{2}}={\frac {n(n-1)}{2}}}$	${\displaystyle n-1}$	${\displaystyle r}$ times the order of ${\displaystyle SA(n,q)}$
unitriangular matrix group	${\displaystyle UT(n,q)}$ or ${\displaystyle UT(n,\mathbb {F} _{q})}$	${\displaystyle \prod _{i=0}^{n-1}q^{n-1-i}}$	${\displaystyle q^{\binom {n}{2}}}$	${\displaystyle q^{\binom {n}{2}}}$	${\displaystyle {\binom {n}{2}}={\frac {n(n-1)}{2}}}$	${\displaystyle {\binom {n}{2}}={\frac {n(n-1)}{2}}}$	0	Each of the entries above the diagonal can take any of the values in ${\displaystyle \mathbb {F} _{q}}$; there are ${\displaystyle {\binom {n}{2}}}$ entries to choose.
triangular matrix group (diagonal entries not required to be one); this is an example of a Borel subgroup	?	${\displaystyle \prod _{i=0}^{n-1}(q^{n-1-i}(q-1))}$	${\displaystyle q^{\binom {n}{2}}(q-1)^{n}}$	${\displaystyle q^{\binom {n}{2}}(q-1)^{n}}$	${\displaystyle {\binom {n+1}{2}}={\frac {n(n+1)}{2}}}$	${\displaystyle {\binom {n}{2}}={\frac {n(n-1)}{2}}}$	${\displaystyle n}$	Each of the entries above the diagonal can take any of the values in ${\displaystyle \mathbb {F} _{q}}$; there are ${\displaystyle {\binom {n}{2}}}$ entries to choose. Each of the ${\displaystyle n}$ entries of the diagonal can take any of ${\displaystyle |\mathbb {F} _{q}^{\ast }|=q-1}$ values.

Explanation for order of general linear group over a finite field

We describe here the reasoning behind the formula for the order of the general linear group ${\displaystyle GL(n,q)=GL(n,\mathbb {F} _{q})}$.

The order equals the number of invertible ${\displaystyle n\times n}$ matrices with entries over ${\displaystyle \mathbb {F} _{q}}$. The set of such matrices is in correspondence with the set of ordered bases for ${\displaystyle \mathbb {F} _{q}^{n}}$, the ${\displaystyle n}$-dimensional vector space over ${\displaystyle \mathbb {F} _{q}}$ (for instance, we can identify the columns of the matrix with the vectors in the ordered basis). Thus, it suffices to count the number of possible ordered bases for ${\displaystyle \mathbb {F} _{q}^{n}}$.

For the first vector of the ordered basis, there are ${\displaystyle q^{n}-1}$ possible choices (all nonzero vectors work). For the second vector, there are ${\displaystyle q^{n}-q}$ choices (all vectors that are not in the span of the first vector work). After the first ${\displaystyle i}$ basis vectors are chosen, the number of possibilities for the next basis vector are ${\displaystyle q^{n}-q^{i}}$, because ${\displaystyle q^{i}}$ is the size of the subspace spanned by the first ${\displaystyle i}$ basis vectors. By the product rule in combinatorics, we get that the total number of possibilities is:

${\displaystyle \prod _{i=1}^{n}(q^{n}-q^{i})=(q^{n}-1)(q^{n}-q)\dots (q^{n}-q^{n-1})}$

Explanation for order of special linear group over a finite field

The group ${\displaystyle SL(n,q)}$ is the kernel of the determinant map, a surjective homomorphism from ${\displaystyle GL(n,q)}$ to ${\displaystyle \mathbb {F} _{q}^{\ast }}$. The homomorphism is surjective because for any ${\displaystyle a\in \mathbb {F} _{q}^{\ast }}$, we can construct a diagonal matrix with one diagonal entry ${\displaystyle a}$ and the remaining entries equal to 1, and this maps to ${\displaystyle a}$ under the determinant map.

Essentially by Lagrange's theorem and the first isomorphism theorem, we know that the order of the kernel is the order of the whole group divided by the order of the image. Thus:

${\displaystyle |SL(n,q)|={\frac {|GL(n,q)|}{|\mathbb {F} _{q}^{\ast }|}}}$

We now use the expression obtained for ${\displaystyle |GL(n,q)|}$ and use that ${\displaystyle |\mathbb {F} _{q}^{\ast }|=q-1}$.

Explanation for order of projective general linear group over a finite field

The group ${\displaystyle PGL(n,q)}$ is the quotient of ${\displaystyle GL(n,q)}$ by the center of ${\displaystyle GL(n,q)}$.

The center of ${\displaystyle GL(n,q)}$ is the subgroup of scalar matrices (see center of general linear group is group of scalar matrices over center), and is isomorphic to ${\displaystyle \mathbb {F} _{q}^{\ast }}$.

Thus, by Lagrange's theorem, the order of the quotient ${\displaystyle PGL(n,q)}$ is:

${\displaystyle |PGL(n,q)|={\frac {|GL(n,q)|}{|\mathbb {F} _{q}^{\ast }|}}}$

We now use the expression obtained for ${\displaystyle |GL(n,q)|}$ and use that ${\displaystyle |\mathbb {F} _{q}^{\ast }|=q-1}$.

Explanation for order of projective special linear group over a finite field

The group ${\displaystyle PSL(n,q)}$ is the quotient group of ${\displaystyle SL(n,q)}$ by its intersection with the center of ${\displaystyle GL(n,q)}$.

The intersection of ${\displaystyle SL(n,q)}$ and the center of ${\displaystyle GL(n,q)}$ is the subgroup of scalar matrices of determinant 1. The determinant of a ${\displaystyle n\times n}$ scalar matrix is the ${\displaystyle n^{th}}$ power of the scalar value, so the intersection comprises those scalar matrices whose scalar values are ${\displaystyle n^{th}}$ roots of unity. Since ${\displaystyle \mathbb {F} _{q}^{\ast }}$ is cyclic of order ${\displaystyle q-1}$ (see multiplicative group of a finite field is cyclic), the number of such elements is ${\displaystyle \operatorname {gcd} (n,q-1)}$.

Thus, the kernel of the quotient map from ${\displaystyle SL(n,q)}$ to ${\displaystyle PSL(n,q)}$ has order ${\displaystyle \operatorname {gcd} (n,q-1)}$. We thus get, by Lagrange's theorem:

${\displaystyle |PSL(n,q)|={\frac {|SL(n,q)|}{\operatorname {gcd} (n,q-1)}}}$

Simplifying this gives the expressions in the table above.

Explanation for order of general semilinear group over a finite field

The general semilinear group ${\displaystyle \Gamma L(n,q)}$ is a semidirect product:

${\displaystyle \Gamma L(n,q)=GL(n,q)\rtimes \operatorname {Aut} (\mathbb {F} _{q})}$

Therefore, we have:

${\displaystyle |\Gamma L(n,q)|=|GL(n,q)||\operatorname {Aut} (\mathbb {F} _{q})|}$

Since ${\displaystyle q=p^{r}}$, ${\displaystyle \mathbb {F} _{q}}$ is a degree ${\displaystyle r}$ extension of its prime subfield ${\displaystyle \mathbb {F} _{p}}$. The extension is a Galois extension, and the automorphism group is therefore equal to the Galois group of the extension, and is cyclic of order ${\displaystyle r}$ (it is generated by the Frobenius automorphism ${\displaystyle x\mapsto x^{p}}$). We thus get:

${\displaystyle |\Gamma L(n,q)|=|GL(n,q)|\cdot r}$

We substitute the formulas calculated for ${\displaystyle |GL(n,q)|}$ and obtain the formulas for ${\displaystyle |\Gamma L(n,q)|}$.

Explanation for order of outer linear group over a finite field

The outer linear group ${\displaystyle OL(n,q)}$ is a semidirect product:

${\displaystyle OL(n,q)=GL(n,q)\rtimes \mathbb {Z} /2\mathbb {Z} }$

where the non-identity element of ${\displaystyle \mathbb {Z} /2\mathbb {Z} }$ acts via the transpose-inverse map. Thus:

${\displaystyle |OL(n,q)|=|GL(n,q)|\cdot 2}$

We substitute the formulas calculated for ${\displaystyle |GL(n,q)|}$ and obtain the formulas for ${\displaystyle |OL(n,q)|}$.

Explanation for order of outer semilinear group over a finite field

The outer semilinear group ${\displaystyle O\Gamma L(n,q)}$ is a semidirect product:

${\displaystyle O\Gamma L(n,q)=GL(n,q)\rtimes (\operatorname {Aut} (\mathbb {F} _{q})\times \mathbb {Z} /2\mathbb {Z} )}$

Therefore, we have:

${\displaystyle |O\Gamma L(n,q)|=|GL(n,q)||\operatorname {Aut} (\mathbb {F} _{q})|\cdot 2}$

Since ${\displaystyle q=p^{r}}$, ${\displaystyle \mathbb {F} _{q}}$ is a degree ${\displaystyle r}$ extension of its prime subfield ${\displaystyle \mathbb {F} _{p}}$. The extension is a Galois extension, and the automorphism group is therefore equal to the Galois group of the extension, and is cyclic of order ${\displaystyle r}$ (it is generated by the Frobenius automorphism ${\displaystyle x\mapsto x^{p}}$). We thus get:

${\displaystyle |O\Gamma L(n,q)|=|GL(n,q)||\operatorname {Aut} (\mathbb {F} _{q})|\cdot r\cdot 2}$

We substitute the formulas calculated for ${\displaystyle |GL(n,q)|}$ and obtain the formulas for ${\displaystyle |O\Gamma L(n,q)|}$.

General justification for degree of polynomial describing the order

The degree of the polynomial giving the order of the group can be thought of as corresponding to the algebraic dimension, using, for instance, the Zariski topology. Note that applying the Zariski topology on a finite field won't work, because the topology for a variety over a finite field is discrete. However, we can look at the corresponding concept for an infinite field and then intersect with the points realized over the finite field ${\displaystyle \mathbb {F} _{q}}$. We go over these justifications briefly for the important cases:

Group	Degree of polynomial giving the order	Justification in terms of algebraic dimension
general linear group	${\displaystyle n^{2}}$	Over an infinite field, the general linear group is an open, and hence dense, subset of the ${\displaystyle n^{2}}$-dimensional space of matrices over the field, because it is defined by the determinant (a degree ${\displaystyle n}$ polynomial in the ${\displaystyle n^{2}}$ variables) being nonzero.
special linear group	${\displaystyle n^{2}-1}$	Over an infinite field, the special linear group is a codimension-one closed subset of the ${\displaystyle n^{2}}$-dimensional space of matrices over the field, because it is defined by the determinant (a degree ${\displaystyle n}$ polynomial in the ${\displaystyle n^{2}}$ variables) being exactly one.
projective general linear group	${\displaystyle n^{2}-1}$	Over an infinite field, the projective general linear group is a quotient variety of the general linear group by the equivalence relation of being scalar multiples of each other. It therefore has dimension one less than the general linear group.
general affine group	${\displaystyle n^{2}+n}$	The dimension of this is the sum of the dimension of the vector space (${\displaystyle n}$) and the dimension of the general linear group (${\displaystyle n^{2}}$).
special affine group	${\displaystyle n^{2}+n-1}$	The dimension of this is the sum of the dimension of the vector space (${\displaystyle n}$) and the dimension of the general linear group (${\displaystyle n^{2}-1}$).

General justification for largest power of ${\displaystyle q}$ dividing the order

For all linear groups, the largest power of ${\displaystyle q}$ dividing the order is ${\displaystyle {\binom {n}{2}}}$. All of these factors of ${\displaystyle q}$ are attained in the unitriangular matrix group (the group of upper triangular matrices with 1s on the diagonal).

For affine groups, we get an additional factor of ${\displaystyle q^{n}}$, and thus an addition of ${\displaystyle n}$ to the exponent.

General justification for largest power of ${\displaystyle q-1}$ dividing the order

The largest power of ${\displaystyle q-1}$ dividing the order corresponds to the dimension of the maximal torus (without considering extensions, i.e., the torus realizable over ${\displaystyle \mathbb {F} _{q}}$). We go over the justifications briefly for some important cases:

Group	Power of ${\displaystyle q-1}$ in order	Justification in terms of algebraic dimension of largest torus
general linear group	${\displaystyle n}$	The torus is the group of invertible diagonal matrices. The points in this torus over ${\displaystyle \mathbb {F} _{q}}$ form the group ${\displaystyle (\mathbb {F} _{q}^{\ast })^{n}}$, and the dimension is ${\displaystyle n}$
special linear group	${\displaystyle n-1}$	The torus is the group of invertible diagonal matrices where the product of the diagonal entries is 1. There are ${\displaystyle n-1}$ entries that can be freely chosen from the multiplicative group, and the ${\displaystyle n^{th}}$ entry is constrained by them. The points in this torus over ${\displaystyle \mathbb {F} _{q}}$ form the group ${\displaystyle (\mathbb {F} _{q}^{\ast })^{n-1}}$, and the dimension is ${\displaystyle n-1}$
projective general linear group	${\displaystyle n-1}$	The torus is the group of invertible matrices where the product of the diagonal entries is 1, modulo the scalar matrices. There are ${\displaystyle n-1}$ degrees of freedom, because 1 degree of freedom is taken away by the ability to scale the matrix.

General justification for largest power of other cyclotomic polynomials dividing the order

For any ${\displaystyle d}$ with ${\displaystyle 1\leq d\leq n}$, the exponent for the largest power of the cyclotomic polynomial ${\displaystyle \Phi _{d}(q)}$ dividing the order is ${\displaystyle \lfloor {\frac {n}{d}}\rfloor }$. This can also be justified in terms of a "torus" as follows:

• The field extension ${\displaystyle \mathbb {F} _{q^{d}}}$ can be embedded in the ring of ${\displaystyle d\times d}$ matrices over ${\displaystyle \mathbb {F} _{q}}$ as a subring, through its action on itself as a ${\displaystyle d}$-dimensional vector space over ${\displaystyle \mathbb {F} _{q}}$. With this, ${\displaystyle \mathbb {F} _{q^{d}}^{\ast }}$ gets embedded in ${\displaystyle GL(d,q)}$.
• Inside ${\displaystyle GL(n,q)}$, we can think of ${\displaystyle GL(d,q)}$ as occupying a block of size ${\displaystyle d\times d}$. Thus, a block of size ${\displaystyle d\times d}$ can accommodate ${\displaystyle \mathbb {F} _{q^{d}}^{\ast }}$.
• There is space for ${\displaystyle \lfloor {\frac {n}{d}}\rfloor }$ such blocks, so ${\displaystyle \left(\mathbb {F} _{q^{d}}^{\ast }\right)^{\lfloor {\frac {n}{d}}\rfloor }}$ can be embedded in ${\displaystyle GL(n,q)}$, but no larger power of ${\displaystyle \mathbb {F} _{q^{d}}^{\ast }}$ can.