A system consists of two concentric hoops constrained to rotate about an axis through their centers and perpendicular to their common plane. A torque of 23.5 meter Newtons is applied to the system.
The first hoop has radius 6.48 meters and mass .3 kilograms, while the second has radius 17 meters and mass 9.8 kilograms.
Each mass rotates at a constant distance from the center of rotation.
The acceleration resulting from a torque of 23.5 meter Newtons will therefore be `alpha = `tau /( `Sigma mr ^ 2) = ( 23.5 meter Newtons) / ( 2844.797 kg m^2) = 8.260694E-03 rad/s ^ 2.
If we have point masses m1, m2, ..., mn along a rod at distances r1, r2, ..., rn from the center of rotation, then we have individual moments of inertia m1 r1^2, m2 r2^2, ..., mn rn^2.
- angular acceleration = `tau / I = `tau / [ `sigma (m r^2)] = `tau / [ m1 r1^2 `m2 r2^2 0... `mn rn^2 ].
The figure below shows two masses m1 and m2 along a massless rod which constrains them to rotate about a central axis at respective distances r1 and r2 from the axis.
- Angular acceleration = `alpha = `tau / I = `tau / (m1 r1^2 `m2 r2^2).
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