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A rigid rod of mass m with a ball of mas...

A rigid rod of mass m with a ball of mass M attached to the free end is restrained to oscillate in a vertical plane as shown in the figure. Find the natural frequency of oscillation.

Text Solution

Verified by Experts

The correct Answer is:
`(1)/(2 pi) sqrt((3k)/(27 M + 7m))`
At equlibrium position deformation of the spring is `x_(0)`
`kx_(0) = (1)/(4) = Mg ((3)/(4) l) + mg ((1)/(4))`
When the rod is further rotated through an angle `theta` from equlibrium position, the restoring tarque.
`tau = - [k(x+ x_(0)) (1)/(4) cos theta - Mg ((3)/(4)) L cos theta] - mg ((L)/(4)) cos theta`
`= - [k(x+ x_(0)) (1)/(4) - Mg ((3)/(4)) L - mg ((L)/(4))] cos theta`
For small `theta, cos theta ~~ 1`
`tau = - (kl)/(4) x` `implies l alpha = - (kl^(2))/(4) theta`
`l = m ((3)/(4) L) ^(2) + (mL^(2))/(12) + m ((L)/(4))^(2)`
`f = (1)/(2 pi) sqrt((3k)/(27 M + 7m))`
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  • A system of springs with their spring constants are as shown in figure. What is the frequency of oscillations of the mass m ?

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    `1/(2pi)sqrt((k_1k_2(k_3+k_4))/([(k_1+k_2)+(k_3+k_4)+k_1k_4]m))`
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    `1/(2pi)sqrt(((k_1+k_2)(k_3+k_4)+k_1k_2)/(k_1 k_2(k_3+k_4)m)`

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