A bead of mass m is released from rest at A to move along the fixed smooth circular track as shown in figure. The ratio of magnitudes of centripetal force and normal reaction by the track on the bead at any point `P_0` described by the angle `theta(!=0)` would

A small block of mass m is released from rest from point A inside a smooth hemisphere bowl of radius R , which is fixed on group such that OA is horizontal. The ratio (x) of magnitude of centripetal force and normal reaction on the block at any point B varies with theta as :

In the shown figure, a small mass m starts sliding down a smooth and stationary circular track. Which of the following graph best represents the variation of magnitude of the force applied by the track on the mass and the angle theta ?

A smooth block of mass m is held stationary on a smooth wedge of mass M and inclination theta as shown in figure .If the system is released from rest , then the normal reaction between the block and the wedge is

A small block of mass m slides along a smooth frictional track as shown in the figure. If it starts from rest at P, what is the resultant force acting on it at Q?

A particle moves from A to B in a circular path of radius R covering an angle theta as shown in figure. Find the ratio of magnitude of distance and magnitude of displacement of the particle.

A block is released from rest from top of a rough curved track as shown in figure. It comes to rest at some point on the horizontal part. If its mass is 200 gm, calculate work by friction is joules

A cube of mass M starts of rest from point 1 at a height 4R, where R is the radius of the circular track. The cube slides down the frictionless track and around the loop. The force which the track exerts on the cube at point 2 is :

A bead of mass 1/2 kg starts from rest from A to move in a vertical place along a smooth fixed quarter ring of radius 5 m , under the action of a constant horizontal force f=5 N as shown. The speed of bead as it reaches the point (B) is [Take g=10 ms^(-2) ]