Let $\Phi: G \times M \rightarrow M$ be a group action on a symplectic manifold $M$ and $G$ be a Lie group. Furthermore, $x$ is a solution of the Hamilton equation $\dot{x}(t) = X_H(x(t))$ and for a any $t$ there is a $g(t) \in G_x:=\{g \in G; Ad^*_h(x)=x\}$ (here $x \in \mathfrak{g}^*$) such that $x(t) = \Phi(g(t),d(t)).$
Now this $d:I \rightarrow M$ is another path in $M$ that is not necessarily Hamiltonian, but can be transformed into one under the group action, where the group elements can be taken from $G_x.$
In this situation I found that $d$ already satisfies the Hamilton equation
$$\dot{d}(t) + Z_{\zeta(t)}(d(t))= X_H(d(t)),$$
where $Z_{\zeta(t)}(p) := \frac{d}{dt}|_{t=0} \Phi(e^{t \zeta(t)},p)$ and $\zeta(t):=dL_{g(t)^{-1}}\dot{g}(t).$
So actually $d$ satisfies a Hamiltonian equation with an additional term. Does anybody know how this result can be derived?
It should not be too hard, as we already have a strong relationship between $x$ and $d$, but I don't really see how we can get the equation modified Hamilton's equation shown above.