Quaternionic vector space

Since quaternion algebra is division ring, then module over quaternion algebra is called vector space. Because quaternion algebra is non-commutative, we distinguish left and right vector spaces. In left vector space, linear composition of vectors ${\displaystyle v}$ and ${\displaystyle w}$ has form ${\displaystyle av+bw}$ where ${\displaystyle a}$, ${\displaystyle b\in H}$. In right vector space, linear composition of vectors ${\displaystyle v}$ and ${\displaystyle w}$ has form ${\displaystyle va+wb}$.

If quaternionic vector space has finite dimension ${\displaystyle n}$, then it is isomorphic to direct sum ${\displaystyle H^n}$ of ${\displaystyle n}$ copies of quaternion algebra ${\displaystyle H}$. In such case we can use basis which has form

${\displaystyle e_1=(1,0,\dots ,0)}$

${\displaystyle \dots }$

${\displaystyle e_n=(0,\dots ,0,1)}$

In left quaternionic vector space ${\displaystyle H^n}$ we use componentwise sum of vectors and product of vector over scalar

${\displaystyle (p_1,\dots ,p_n)+(r_1,\dots ,r_n)=(p_1+r_1,\dots ,p_n+r_n)}$

${\displaystyle q(r_1,\dots ,r_n)=(q{r}_1,\dots ,q{r}_n)}$

In right quaternionic vector space ${\displaystyle H^n}$ we use componentwise sum of vectors and product of vector over scalar

${\displaystyle (p_1,\dots ,p_n)+(r_1,\dots ,r_n)=(p_1+r_1,\dots ,p_n+r_n)}$

${\displaystyle (r_1,\dots ,r_n)q=(r_{1}q,\dots ,r_{n}q)}$

• Vector space
• General linear group
• Special linear group
• SL(n,H)
• Symplectic group

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