General affine group of degree one: Difference between revisions

Definition

For a field

For a field ${\displaystyle F}$, the general affine group of degree one over ${\displaystyle F}$ is defined as the general affine group over ${\displaystyle F}$ of degree one. Equivalently, it is the external semidirect product of the additive group of ${\displaystyle F}$ by the multiplicative group of ${\displaystyle F}$, where the latter acts naturally on the former by field multiplication.

For a finite number

Let ${\displaystyle p}$ be a prime number and ${\displaystyle q=p^{r}}$ be a power of ${\displaystyle p}$. The general affine group or collineation group ${\displaystyle GA(1,q)}$ is defined as follows. Let ${\displaystyle \mathbb {F} _{q}}$ denote the field with ${\displaystyle q}$ elements. Then ${\displaystyle GA(1,q)}$ is the semidirect product of the additive group of ${\displaystyle \mathbb {F} _{q}}$ with its multiplicative group.

Equivalently it is the general affine group of degree ${\displaystyle 1}$ over the field of ${\displaystyle q}$ elements.

Particular cases

${\displaystyle q}$ (field size)	${\displaystyle p}$ (underlying prime, field characteristic)	${\displaystyle GA(1,q)}$	Order	Second part of GAP ID
2	2	cyclic group:Z2	2	1
3	3	symmetric group:S3	6	1
4	2	alternating group:A4	12	3
5	5	general affine group:GA(1,5)	20	3
7	7	general affine group:GA(1,7)	42	1
8	2	general affine group:GA(1,8)	56	11
9	3	general affine group:GA(1,9)	72	39

Arithmetic functions

Below, ${\displaystyle q}$ is the size of the field and ${\displaystyle p}$ is the underlying prime (the characteristic of the field). We have ${\displaystyle q=p^{r}}$ where ${\displaystyle r}$ is a positive integer.

Function	Value	Explanation
order	${\displaystyle q(q-1)=q^{2}-q}$	order of semidirect product is product of orders: The group is a semidirect product of the additive group of ${\displaystyle \mathbb {F} _{q}}$, which has order ${\displaystyle q}$, and the multiplicative group of ${\displaystyle \mathbb {F} _{q}}$, which has order ${\displaystyle q-1}$ (because it comprises all the non-identity elements).
exponent	${\displaystyle p(q-1)}$	Non-identity elements in the additive group have order ${\displaystyle p}$ and elements in the multiplicative group have order ${\displaystyle q-1}$.
derived length	2	The derived subgroup is the additive group. The exception is the case ${\displaystyle q=2}$, where the group is abelian and has derived length 1.
Fitting length	2	The Fitting subgroup is the additive group of the field, and the quotient is an abelian group.
Frattini length	1	For ${\displaystyle q>2}$, we can find two maximal subgroups of order ${\displaystyle q-1}$ with trivial intersection. Note that this also follows from it being a Frobenius group.

Group properties

Property	Satisfied?	Explanation	Corollary properties satisfied/dissatisfied
Frobenius group	Yes	The additive subgroup ${\displaystyle \mathbb {F} _{q}}$ is a Frobenius kernel and the multiplicative subgroup is a Frobenius complement. (note: the case ${\displaystyle q=2}$ is an exception, where it fails to be a Frobenius group on account of the multiplicative group being trivial).
abelian group	No	Except the ${\displaystyle q=2}$ case, where we get cyclic group:Z2
nilpotent group	No	Except the ${\displaystyle q=2}$ case, where we get cyclic group:Z2
metabelian group	Yes	The derived subgroup is the additive group of the field (when ${\displaystyle q>2}$).	Satisfies: solvable group
supersolvable group	Sometimes	The group is supersolvable if and only if the field is a prime field, i.e., if and only if ${\displaystyle q}$ is a prime number rather than a strict prime power.