A ball of radius r fits tightly inside a tube attached to a container. There is no friction between the tube wall and the ball. Volume of air inside the container is `V_(0)` when the ball is in equilibrium. Density of the material of the ball is d and atmospheric pressure is `P_(0)`. If the ball is displaced a little from its equilibrium position and released, find time period of its oscillation. Assume that temperature in the container remains constant and that air is an ideal gas.

A ball of radius r fits tightly inside a tube attached to a container.

1.	A ball of radius r fits tightly inside a tube attached to a container. There is no friction between the tube wall and the ball. Volume of air inside the container is `V_(0)` when the ball is in equilibrium. Density of the material of the ball is d and atmospheric pressure is `P_(0)`. If the ball is displaced a little from its equilibrium position and released, find time period of its oscillation. Assume that temperature in the container remains constant and that air is an ideal gas.
Answer» Correct Answer - `T=4sqrt((piV_(0)d)/(3P_(0)r))`

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