Let $V$ be a real $d$-dimensional vector space. Let $\omega \in \bigwedge^kV$ be a fixed non-zero multivector for some $1 < k < d$.
Define $ G_{\omega}=\{ T \in \text{Aut}(V) \, | \, (\bigwedge^k T)(\omega)=\omega\}$ to be the subgroup of linear automorphisms of $V$ which preserve $\omega$.
(Here $\bigwedge^k V$ is the $k$-th exterior power of $V$, and $\bigwedge^k T \in \text{End}(\bigwedge^k V)$ is the exterior power of $T$).
Question: What are the different isomorphism classes of the $\{G_{\omega}\}_{\omega \in \bigwedge^k V}$?
If that is too hard, what are the possible dimensions of these groups?
Commnets:
$G_{\omega}$ is the isotropy group of the action of $\text{GL}(V)$ on $\bigwedge^K V$, defined by $(T,\omega) \to (\bigwedge^k T) \omega$. Thus, for every two elements in the same orbit $\omega,\omega' $, we have $G_{\omega} \simeq G_{\omega'}$.
(Thus it might be helpful to classify the orbits of this action).
In particular, this is true for every two non-zero decomposable elements.
In the case where $\omega$ is decomposable, it is easy to see that $$ \dim(G_{\omega})=d^2-k(d-k)-1. \tag{1}$$
Indeed, suppose that $\omega=v_1 \wedge \dots \wedge v_k$, we can complete $v_1,\dots,v_k$ into a basis $v_1,\dots,v_d$ of $V$. Then we have $$ Tv_1 \wedge \dots \wedge Tv_k=v_1 \wedge \dots \wedge v_k \neq 0,$$
so $\text{span}(Tv_1,\dots,Tv_k)=\text{span}(v_1,\dots,v_k)$. Denote $W=\text{span}(v_1,\dots,v_k)$. Then $T \in G_{\omega}$ implies $T|_{W} \in \text{SL}(W) \simeq \text{SL}(k)$. On a direct summand of $W$, $T$ can do whatever it wants, as long as it stays invertbile. Thus $$ \dim(G_{\omega})=\dim \text{SL}(k)+ (d-k)\cdot d=k^2-1+(d-k)\cdot d. $$
Let us consider for a moment the (simplest?) non-decomposable case:
$\omega = e_1\wedge e_2 + e_3\wedge e_4\in \Lambda^2(\Bbb R^4)$. In that case $G_{\omega}$ clearly contains a copy of $\text{SL}(2) \times \text{SL}(2)$, corresponding to actions on the two planes $\text{span}\{ e_1,e_2\},\text{span}\{ e_3,e_4\}$. Thus, $$ \dim(G_{\omega}) \ge 2\dim \text{SL}(2)=6.$$
Is $\dim(G_{\omega})=6$? (As commented by Ted Shifrin, we can also switch between the two planes, but I don't think this particular option increases the dimension of the group).
Note that for $d=4,k=2$, the formula $(1)$ gives $\dim(G_{\omega})=11$.
