A small ball of mass m is released in a smooth circular tube as shown in figure. The minimum height h such that bead can complete the circle is

A bead of mass m is released from height h on smooth thread as shown in figure.The minimum value of h such that bead completes the circular arc is

A ball of mass m=1kg strikes a smooth horizontal floor as shown in figure. The impulse exerted on the floor 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 body of mass m is released from a height h on a smooth inclined plane that is shown in the figure. The following can be true about the velocity of the block knowing that the wedge is fixed. .

A body of mass m is released from a height h on a smooth inclined plane that is shown in the figure. The following can be true about the velocity of the block knowing that the wedge is fixed. .

A block is released from rest at the top of an inclined plane which later curves into a circular track of radius r as shown in figure. Find the minimum height h from where it should be released so that it is able to complete the circle.

A small ball is rolled with speed u from piont A along a smooth circular track as shown in figure. If x=3R , then What is the minimum value of x for which the ball can reach the point of projection after reaching C?

Assertion A small block of mass m is rotating in a circle inside a smooth cone as shown in figure. In this case the normal reaction, N ne "mg cos"theta Reason In this case, acceleraion of the block is not along the surface of cone. It is horizontal.

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 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