General Linear Group to Determinant is Homomorphism
Theorem
Let $\GL {n, \R}$ be the general linear group over the field of real numbers.
Let $\struct {\R_{\ne 0}, \times}$ denote the multiplicative group of real numbers.
Let $\det: \GL {n, \R} \to \struct {\R_{\ne 0}, \times}$ be the mapping:
- $\mathbf A \mapsto \map \det {\mathbf A}$
where $\map \det {\mathbf A}$ is the determinant of $\mathbf A$.
Then $\det$ is a group homomorphism.
Corollary
The kernel of the $\det$ mapping is the special linear group $\SL {n, \R}$.
Proof
From Determinant of Matrix Product:
- $\map \det {\mathbf A \mathbf B} = \map \det {\mathbf A} \, \map \det {\mathbf B}$
which is seen to be a group homomorphism by definition.
$\blacksquare$