When does a subgroup of $\operatorname{GL}(n, \mathbb Q)$ have a bounded fundamental domain on $\mathbb R^n$?

Question

$\DeclareMathOperator\GL{GL}$Let $G \subset M_{n\times n~}(\mathbb Z)$ be a finitely generated subgroup of $\GL(n,\mathbb Q)$ (i.e. $g\in G$ is an invertible matrix with entries in $\mathbb Z$). Then $G$ acts on $\mathbb R^n = \mathbb Z^n \otimes_{\mathbb Z} \mathbb R$ through $\GL(n,\mathbb Q)$.

Suppose that there is a rational affine subspace $V \subset \mathbb R^n$ (by this, I mean that there is a sub-lattice $L \subset \mathbb Z^n$ and $a \in \mathbb Z^n$ such that $V = a + (L \otimes_{\mathbb Z} \mathbb R)$), and $V$ is invariant under the action of $G$ (i.e. for any $v\in V, g\in G$, we have $g\cdot v \in V$). Moreover, there exists $v \in L$ (in fact, we can take $v=a$) such that $$G \cdot v = L.$$

Question: is there a bounded subset $P \subset V$ such that $$\bigcup_{g \in G}\ g\cdot P = V \quad ? $$

Any suggestion on relevant questions/references is very welcome! Particularly, I don't know which field studies such problems ….

Edit:

Example. Consider $(0,1)+L:=(\mathbb Z,1) \subset \mathbb Z^2$, and $$G=\{\begin{pmatrix} 1&k\\0&1\end{pmatrix}\mid k\in\mathbb Z\}.$$ For $v=(0,1)$, we have $G \cdot v =(0,1)+L$. In this case, we can take $P$ to be the interval from $(0,1)$ to $(1,1)$.

Answer 1

After reading the comments, I think the underlying algebraic question is: " if $G=U$ is a unipotent linear algebraic group defined over $\mathbb{Q}$, then is the arithmetic unipotent subgroup $U(\mathbb{Z})$ cocompact in $U(\mathbb{R})$? "

The answer to the above question is Yes, as well known to students in geometry of numbers, reduction theory of quadratic forms, and arithmetic groups. For example, a proof is contained in Borel/Harish-Chandra, S 6.10. (See image below).

E.g. the integral Heisenberg group $H(\mathbb{Z})$ is cocompact in $H(\mathbb{R})$.

If the OP does not study the full arithmetic unipotent $U(\mathbb{Z})$, but restricts to a subgroup $G \subset U(\mathbb{Z})$, then the answer to the above question is No unless $G$ is finite index in $U(\mathbb{Z})$. Indeed it's evident that discrete subgroups $L'$ of $\mathbb{Z}^n$ are cocompact in $\mathbb{R}^n$ if and only if $[L':\mathbb{Z}^n]<+\infty$.