Four identical balls of mass m each are placed as shown. The three balls that lie on the ground are prevented from moving by applying horizontal forces (not shown). The reaction force between the fourth ball (placed above) and any of the other three ball is

Two spherical balls of mass 10 kg each are placed 100 m apart. Find the gravitational force of attraction between them.

Two spherical balls of mass 10 kg each are placed 10 cm apart. Find the gravitational force of attraction between them.

A ball collides elastically with a massive wall moving towards it with a velocity of v as shown. The collision occurs at a height of h above ground level and the velocity of the ball just before collision is 2v in horizontal direction. The distance between the foot of the wall and the point on the ground where the ball lands, at the instant the ball lands, will be :

A ball of mass m kept at the corner as shown in the figure, is acted by a horizontal force F. The correct free body diagram of ball is

A ball of mass 'm' is thrown with a speed v_0 towards a bat. It rebounds along the same speed 2v_0 . The variation of interaction force between the bat and ball is shown The speed of the ball at the instant the force acting on the ball is maximum is

Two identical balls each of mass m interconnected by a small light inextensible string are kept on a smooth horizontal surface. One of the balls is pushed towards the other with a speed v_(0) find the loss of K.E. of the ball. What will be the final velocities of the balls ? (e=1).

A ball of mass 'm' is thrown with a speed v_0 towards a bat. It rebounds along the same speed 2v_0 . The variation of interaction force between the bat and ball is shown Average force exerted by the bat on the ball is

A ball of mass 'm' is thrown with a speed v_0 towards a bat. It rebounds along the same speed 2v_0 . The variation of interaction force between the bat and ball is shown Maximum force exerted by the bat on the ball is

A solid spherical ball of mass m is released from the topmost point of the shown semi - spherical shell. The track is sufficiently rough to enablle to enable pure rolling motion. The normal force between the ball and the shell at the lowest position is

In the arrangement shown in fig., mass of the rod M exceeds the mass m of the ball. The ball has an opening permitting it to slide along the thread with some friction. The mass of the pulley and the friction in its axle are negligible. At the initial moment, the ball was located opposite the lower end of the rod. When set free, both bodies began moving with constant accelerations. Find the friction force between the ball and the thread if t seconds after the beginning of motion, the ball got opposite to the upper end of the rod. The rod length equals l.