The cofficient of restitution e for a perfectly elastic collision is
(a) 1 (b) zero (c) infinite (d) -1

The coefficient of restitution e for a perfectly elastic collision is

A uniform rod of mass m and length L is hinged at one end and free to rotate in the horizontal plane. All the surface are smooth. A particle of same mass m collides with the rod with a speed V_(0) . The coefficient of restitution for the collision is e=(1)/(2) . If hinge reaction during the collision is zero then the value of x is :

For perfectly inelastic collision cofficient of restitution e is

Derive final velocities V_1 and V_2 after perfectly elastic collision.

A ball of mass 1 kg is dropped from a height of 3.2 m on smooth inclined plane. The coefficient of restitution for the collision is e= 1//2 . The ball's velocity become horizontal after the collision.

Molecular collisions are perfectly elastic.

Three identical blocks A, B and C are placed on horizontal frictionless surface. The blocks B and C are at rest. But A is approaching towards B with a speed of 10 ms^(-1) The coefficient of restitution for all collision is 0.5. The speed of the block C just after collision is

Three identical blocks A, B and C are placed on horizontal frictionless surface. The blocks B and C are at rest. But A is approaching towards B with a speed of 10 ms^(-1) The coefficient of restitution for all collision is 0.5. The speed of the block C just after collision is

Statement-1 : The coefficient of restitution is less than one for all collision studied under Newton's laws of restituation. and Statement-2 : For a perfeclty elastic collision, coefficient of restitution is equal to one .

Consider objects of masses m_(1)and m_(2) moving initially along the same straight line with velocities u_(1)and u_(2) respectively. Considering a perfectly elastic collision (with u_(1)gt u_(2)) derive expressions for their velocities after collision.