Solving the Rocking Motion of a Dumbbell

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SUMMARY

The discussion focuses on solving the rocking motion of a dumbbell consisting of two spheres, each with mass \(\frac{m}{2}\), connected by a massless rod of length 2a, in circular orbit at radius \(r_0\) with frequency \(\omega_0\). The stable equilibrium position occurs at an angle \(\phi = \pi\), while the unstable equilibrium is at \(\phi = 0\). The key conclusion is that the angular frequency of the rocking motion about the stable equilibrium is determined to be \(\omega_0 \sqrt{3}\). The participant struggles with setting up the Lagrangian equation correctly, indicating a need for clarity in the application of Lagrangian mechanics.

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Homework Statement



A dumbbell consisting of two spheres of mass [tex]\frac{m}{2}[/tex], and connected by a massless rod of length [tex]2a[/tex] is in circular orbit. The dumbbell is at radius [tex]r_0[/tex] from the planet, and orbits with frequency [tex]\omega_0[/tex]. The angle of the dumbbell to the downward gravitational force is given by [tex]\phi[/tex].

The position of stable equilibrium for the dumbbell is when [tex]\phi=\pi[/tex], and the position of unstable equilibrium is at [tex]\phi=0[/tex].

The dumbbell is rocking back and forth. Show that the angular frequency of the rocking motion about the stable equilibrium is equal to [tex]\omega_0*\sqrt{3}[/tex].

Homework Equations





The Attempt at a Solution



I keep attempting to set up a lagrangian equation to describe the motion of [tex]\phi[/tex], however, my [tex]\omega_0[/tex] term keeps dropping out at the beginning of my calculations, so I know right there that the answer will turn out wrong.

What method am I supposed to use?
 
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