A block of mass m slides down a smooth vertical circular track. During the motion, the block is in:

A block of mass m is placed on a vertical fixed circular track and then it is given velocity v along the track at position A on track. The coefficient of friction between the block and the track varies with the angle theta . If the block moves on track with constant speed then the coefficient of friction is

A block of mass m is projected on a smooth horizontal circular track with velocity v what is the average normal force exered by the circular walls on the block during motion A to B?

A block of mass 1 kg slides down a vertical curved track that is one quadrant of a circle of radius 1m. Its speed ast the the bottom si 2 m//s . The work done by frictional force 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 block of mass m slides down along the surface of the bowl from the rim to the bottom as shown in fig. The velocity of the block at the bottom will be-

A block A os mass m slides on a smooth slider in the system as shown. A block c of mass hanging from a pulley pulls block A . When the block A was at position B , the spring was unstretched. Find the speed of the block A when AB = OB = L . .

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 block of mass M slides down a rough inclined surface of inclination theta and reaches the bottom at speed at 'v' . However , if it slides down a smooth inclined surface of same length and same inclination , it reaches the bottom with the speed kv. Coefficient of friction between the block and the rough incline is :

A small block of mass m slides along a smooth frictionless track as shown. (a) If it starts from rest at P , what is the resultant force acting on it at Q ? (b) At what height above the bottom should the block be released so that the force it exerts against the track at the top of the loop equals its weight?