I am working on solving the equation of motion for a particular system. It has been a long time since I've worked with matrix equations and need help in simplifying the following:
$\frac{d}{dt}$$(I_G\omega)$ + $\omega \times(I_G\omega)$ + $My\times [(−\dot\omega\times y)$−$\omega \times (\omega \times y)]$ = 0
This equation came from substituting:
$a_G$ = $−\dot\omega \times y$ - $\omega \times (\omega \times y)$ into:
$\frac{d}{dt}(I_G\omega)$ + $\omega \times (I_G\omega)$ + $My \times a_G$ = 0
Any suggestions or references that would help me simplify this equation would be greatly appreciated! :)
$I_G$ is the inertia tensor at the center of gravity of the mean model. $M$ is the mass matrix. There are no external forces or moments. $\omega$ is the angular velocity vector and y is the distance vector $r_{GG}$ (an arbitrary point $P$ is coincident with $O$ and both are defined as $G$ bar from the mean model, but I have to call it $G$ since I can't find the over bar command). $a_G$ is the acceleration vector at the center of gravity of the mean model, therefore it can not be zero. The system is a block that is rotating and translating. The frame is body fixed.
