Moment of Inertia and Frequency of Oscillation

AI Thread Summary
To calculate the moment of inertia from the frequency of oscillation, additional information such as the restoring force is necessary. The discussion describes a scenario where a body is pivoted and displaced, leading to simple harmonic motion under the influence of gravity. The relationship between torque and moment of inertia is established through the equation τ = I d²θ/dt². By applying the small angle approximation, the angular frequency ω can be derived, which relates to frequency f as ω = 2πf. This method effectively connects the moment of inertia with oscillation frequency.
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How do you calculate the moment of inertia given frequency of oscillation?
 
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You are going to need more than just the frequency. You will need to know the restoring force.

I think the problem you are describing is a body hung on a pivot through a point on it and the body is displaced by a small angle θ with gravity acting on the centre of mass to restore equilibrium. In the limit of small θ the body executes simple harmonic motion.

For angular displacements the equivalent of F=ma is τ = I d2θ /dt2 where τ is the torque about the pivot of gravity (mg) acting at the centre of mass and I is the moment of inertia about the pivot.

Put this together and use the approximation sin θ ≈ θ for small θ and as you would for a simple pendulum solve to find ω (= dθ/dt)

since ω (= 2 \pi f) you have solved the problem

Hope this makes sense and helps

regards

Sam
 
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