A small block of mass `m` is released from rest from position A inside a smooth hemispherical bowl of radius R as shown in figure Choose the wrong option.

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 :

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 :

A ball of mass 1 kg is released from position A inside a wedge with a hemispherical cut of radius 0.5 m as shown in figure. The force exerted by the wedge on ball, when the ball is in position B is (neglect friction everywhere) (Take g = 10 m//s^(2) )

A small ball of mass m is released from rest from the position shown . All contact surface are smooth . The speed of the ball when it reaches its lowest position is

A small ball of mass m is released from rest from the position shown . All contact surface are smooth . The speed of the ball when it reaches its lowest position is

A small block of mass m has speed sqrt(gR) /2 at the top most point of a fixed hemisphere of radius R as shown in figure. The angle theta , when block loses the contact with the hemisphere is

A ball of mass m is released from A inside a smooth wedge of mass m as shown in figure. What is the speed of the wedge when the ball reaches point B?

A small block of mass m is placed at the bottom of fixed circular smooth surface of radius R as shown in the figure If a velocity v. 14 gR is given to the block then maximum height from the bottom of circular surface, where block will leave the contact

A block of mass m is moving in a circle of radius R with speed v inside a smooth cone as shown in figure. Choose the wrong options

A small solid sphere of mass m and radius r starting from rest from the rim of a fixed hemispherical bowl of radius R(gt gtr) rolls inside it without sliding. The normal reaction exerted by the sphere on the hemisphere when it reaches the bottom of hemisphere is