Cosets/Additive case/Z and vector space/Example

In an (additively written) commutative group like ${\displaystyle {}\mathbb {Z} }$ or a vector space ${\displaystyle {}V}$, and of a given subgroup ${\displaystyle {}H}$, the equivalence relation ${\displaystyle {}x\sim _{H}y}$ means ${\displaystyle {}y-x\in H}$, that is, there exists a ${\displaystyle {}h\in H}$ such that

${\displaystyle {}y=x+h\,.}$

The equivalence classes are of the form ${\displaystyle {}x+H={\left\{x+h\mid h\in H\right\}}}$. In case ${\displaystyle {}H=\mathbb {Z} d\subseteq \mathbb {Z} }$ with a fixed ${\displaystyle {}d}$, the equivalence classes have the form

${\displaystyle H=\mathbb {Z} d,\,1+H=\{\ldots ,1-d,1,1+d,1+2d,\ldots \},\,2+H=\{\ldots ,2-d,2,2+d,2+2d,\ldots \},\ldots .}$

These classes encompass those integer numbers that have, upon division by ${\displaystyle {}d}$, the remainder ${\displaystyle {}0}$, or ${\displaystyle {}1}$, or ${\displaystyle {}2}$, etc. They form a partition of ${\displaystyle {}\mathbb {Z} }$.

If ${\displaystyle {}H=U\subseteq V}$ is a linear subspace, then the equivalence classes have the form ${\displaystyle {}v+U={\left\{v+u\mid u\in U\right\}}}$ for a vector ${\displaystyle {}v\in V}$. This is ther affine space with starting point ${\displaystyle {}v}$ and the translating space ${\displaystyle {}U}$ (in the sense of definition). The equivalence classes form a family of affine subspaces parallel to each other.