The pulley shown in figure has a moment of inertias I about its xis and mss m. find the tikme period of vertical oscillastion of its centre of mass. The spring has spring constant k and the string does not slip over the pulley.

The pulley shown in figure has a moment of inertia I about it's axis and its radius is R. Find the magnitude of the acceleration of the two blocks. Assume that the string is light and does not slip on the pulley.

Find the time period of oscillation of block of mass m. Spring, and pulley are ideal. Spring constant is k.

Figure shows two blocks of masses m and M connected bky a string pasing over a pulley. The horizontal table over which the mass m slides is smooth. The pulley has a radius r and moment of inertia I about its axis and it can freely rotte about this axis. Find the accelerationof the mass M asuming that the string does not slip on the pulley.

In the situation as shown in figure time period of small vertical oscillation of block will be - (String, springs and pulley are ideal)

An object of mass m, oscillating on the end of a spring with spring constant k has amplitude A. its maximum speed is

The pulley shown in figure has a radius 10 cm and moment of inertia 0.5 kg-m^2 about its axis. Assuming the inclined planes to be frictionless, calculate the acceleration of the 4.0 kg block.

Find the frequency of small oscillations of the arrangement illustrated in figure. The radius of the pulley is R , its moment of inertia relative to the rotation axis is I , the mass of the body is m , and the spring stiffness is x .The mass of the thread and the spring is negligible , the thread does not slide over the pulley, there is no friction in the axis of the pulley

Consider the situation as shown. The pulley has a moment of inertia I, and radius r, the block is in equilibrium. Find the time period of mass m. Assume no slipping.