Mathematics Asked by José Luis Camarillo Nava on December 15, 2021
It is well know that the fundamental group of the Klein Bottle $G$ is defined by
$$G=BS(1,-1)=langle a,b: bab^{-1}=a^{-1}rangle.$$
I know, for example that $BS(1,2)$ can be defined as the group
$$BS(1,2)=langle A,Brangle $$
where
$$A=left(
begin{array}{cc}
1 & 1 \
0 & 1 \
end{array}
right), B=left(
begin{array}{cc}
2 & 0 \
0 & 1 \
end{array}
right).$$
These matrices satisfy the equation $BAB^{-1}=A^{2}$ and are free : there is not an integer $k$ such that $A^{k}=I$ or $B^{k}=I$. This implies that we obtain an "explicit description" of $BS(1,2)$ as the group generated by $A$ and $B$.
I know that the matrices
$$a=left(
begin{array}{cc}
1 & 1 \
0 & 1 \
end{array}
right), b=left(
begin{array}{cc}
-1 & 0 \
0 & 1 \
end{array}
right)$$
satisfy the relation $bab^{-1}=a^{-1}$ but $b^{2}=I$. This implies that $BS(1,-1)$ is not generated by $a$ and $b$.
My question is: is there an "explicit description" for $G=BS(1,-1)$ with matrices or maybe another couple of objects?
Finally , $G$ can be described as the group of $2times 2$ matrices generated by two matrix $A,B$ such that $BAB^{-1}=A^{-1}$ and $A^{k}neq I$, $B^{k}neq I$ for all $k$. Let $A=left( begin{array}{cc} a & b \ c & d\ end{array} right)$ and $B=left( begin{array}{cc} lambda & 0 \ 0 & mu \ end{array} right)$ (to simplify computations). Working whith the equation $BAB^{-1}=A^{-1}$ and assuming that $ad-bc=1$ and $b,cneq 0$ we have that
$A=left( begin{array}{cc} a & b \ c & a\ end{array} right)$ and $B=left( begin{array}{cc} lambda & 0 \ 0 & -lambda \ end{array} right)$
This family of matrices satisfy the relation $BAB^{-1}=A^{-1}$.
If $A=left( begin{array}{cc} 2 & 3 \ 1 & 2\ end{array} right)$ and $B=left( begin{array}{cc} 2 & 0 \ 0 & -2 \ end{array} right)$, then $BAB^{-1}=A^{-1}$ and $A^{k}neq I$, $B^{k}neq I$, for all $k$
Hence $Gequiv langle A,Brangle$.
Answered by José Luis Camarillo Nava on December 15, 2021
Starting from the representation described by @PaulPlummer as a group of isometries of $mathbb R^2$, you can obtain a representation as a group of linear transformations of $mathbb R^3$.
To do this, one uses a standard embedding of the isometry group of $mathbb R^2$ as a subgroup of $GL(3,mathbb R)$. Each isometry of $mathbb R^2$ can be written uniquely as $P mapsto MP + Q$ for some $M in O(2,mathbb R)$ and some $Q in mathbb R^2$ (vectors are written in column format). The representing element of $GL(3,mathbb R)$ is the matrix written in block form as $pmatrix{M & Q \ 0 & 1}$. If you then represent a column 2-vector $P$ as a column 3-vector $pmatrix{P \ 1}$ then matrix multiplication gives you $$pmatrix{M & Q \ 0 & 1}pmatrix{P \ 1} = pmatrix{MP+Q \ 1} $$
For the Klein bottle group, the two generators are:
Answered by Lee Mosher on December 15, 2021
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