PGammaL(2,4) is isomorphic to S5: Difference between revisions

Latest revision as of 18:27, 17 November 2011

This article gives a proof/explanation of the equivalence of multiple definitions for the term symmetric group:S4
View a complete list of pages giving proofs of equivalence of definitions

Statement

The projective semilinear group of degree two over field:F4 (the field of four elements) is isomorphic to symmetric group:S5.

In symbols:

$P\Gamma L(2,4)\cong S_{5}$ .

Related facts

Similar facts

Facts used

Proof

Step no.	Assertion/construction	Facts used	Previous steps used	Explanation
1	For any field $k$ , there is a natural faithful group action of $P\Gamma L(2,k)$ on $\mathbb {P} ^{1}(k)$ , the set of lines through the origin in $k^{2}$ , and hence an injective group homomorphism from $P\Gamma L(2,k)$ to the symmetric group on $\mathbb {P} ^{1}(k)$ .			Follows from definitions.
2	For $k$ the field of size $q$ , $\mathbb {P} ^{1}(k)$ has size $q+1$ and thus the symmetric group on it has size $(q+1)!$ .	Fact (1)
3	For $k$ the field of size $q=p^{r}$ with $p$ prime, $P\Gamma L(2,k)=P\Gamma L(2,q)$ has size $r(q^{3}-q)$ .	Fact (2)
4	For $k$ the field of size $q=4$ , $P\Gamma L(2,k)=P\Gamma L(2,4)$ has order $2(4^{3}-3)=2(60)=120$ and $\operatorname {Sym} (\mathbb {P} ^{1}(k))$ is the symmetric group of degree $4+1=5$ and has order $5!=120$ .		Steps (2), (3)	Plug in and evaluate.
5	For $k$ the field of size $q=4$ , the homomorphism of Step (1) gives an isomorphism from $P\Gamma L(2,4)$ to $S_{5}$ .		Steps (1), (4)	By Steps (1) and (4), we get an injective homomorphism from $P\Gamma L(2,4)$ to $S_{5}$ . Again by Step (4), both groups are finite and have the same order, hence the injective homomorphism must be an isomorphism.

@@ Line 4: / Line 4: @@
 The [[fact about::projective semilinear group;3| ]][[projective semilinear group]] of [[fact about::projective semilinear group of degree two;2| ]][[projective semilinear group of degree two|degree two]] over [[field:F4]] (the field of four elements) is isomorphic to [[symmetric group:S5]].
+In symbols:
+<math>P\Gamma L(2,4) \cong S_5</math>.
 ==Related facts==
@@ Line 18: / Line 22: @@
 # [[uses::Equivalence of definitions of size of projective space]]
-# [[uses::Order formulas for linear groups]]
+# [[uses::Order formulas for linear groups of degree two]]
 ==Proof==
@@ Line 24: / Line 29: @@
 ! Step no. !! Assertion/construction !! Facts used !! Previous steps used !! Explanation
 |-
-| 1 || For any field <math>k</math>, there is a natural faithful group action of <math>P\Gamma L(2,k)</math> on <math>\mathbb{P}^1(k)</math>, the set of lines through the origin in <math>k^2</math>, and hence an injective group homomorphism from <math>P\GammaL(2,k)</math> to the symmetric group on <math>\mathbb{P}^1(k)</math>. || || || Follows from definitions.
+| 1 || For any field <math>k</math>, there is a natural faithful group action of <math>P\Gamma L(2,k)</math> on <math>\mathbb{P}^1(k)</math>, the set of lines through the origin in <math>k^2</math>, and hence an injective group homomorphism from <math>P\Gamma L(2,k)</math> to the symmetric group on <math>\mathbb{P}^1(k)</math>. || || || Follows from definitions.
 |-
 | 2 || For <math>k</math> the field of size <math>q</math>, <math>\mathbb{P}^1(k)</math> has size <math>q + 1</math> and thus the symmetric group on it has size <math>(q + 1)!</math>. || Fact (1) || ||