A body of mass m is moving with speed v makes a one-dimensional collision with a stationary body of same mass on a horizontal table . They are in connect for the a very small time interval `Deltat`. The contact force between them varies varies as shown in the graph. ( Neglect friction)

The coefficient of restitution for the collision will be

A body of mass 2 m moving with velocity v makes a head - on elastic collision with another body of mass m which is initially at rest. Loss of kinetic energy of the colliding body (mass 2 m) is

A particle of mass m moving with velocity u makes an elastic one-dimensional collision with a stationary particle of mass m . They come in contact for a very small time t_0 . Their force of interaction increases from zero to F_0 linearly in time 0.5t_0 , and decreases linearly to zero in further time 0.5t_0 as shown in figure. The magnitude of F_0 is

A particle of mass m moving with velocity u makes an elastic one-dimentional collision with a stationary particle of mass m . They come in contact for a very small time t_0 . Their force of interaction increases from zero to F_0 linearly in time 0.5t_0 , and decreases linearly to zero in further time 0.5t_0 as shown in figure. The magnitude of F_0 is

A body of mass m moving with a constant velocity collides head on with another stationary body of same mass if the coefficient of restitution between the bodies is (1)/(2) then ratio of velocities of two bodies after collision with be

A ball of mass m moving at a speed v makes a head on inelastic collision with an identical ball at rest. The kinetic energy of the balls after the collision is 3/4th of the original. Find the coefficient of restitution.

A particle of mass m_1 , makes a head on elastic collision with another stationary body of mass m_2 If m_1 , rebounds with half of its original speed then (m_1/m_2) is

A small ball of mass m moving with speed v ( gt sqrt(2gL)) undergoes an elastic head on collision with a stationary bon of identical mass of a simple pendulum of length L. The maximum height h, from the equilibrium position, to which the bob rises after collision is

A ball of mass m moving at a speed v makes a head-on collision with an identical ball at rest. The kinetic energy of the balls after the collision is three fourths of the original. Find the coefficient of restitution.

A particle of mass m moving with a velocity u makes an elastic one-dimensional collision with a stationary particle of mass m establishing a contact with it for extermely small time. T . Their force of contact increases from zero to F_0 linearly in time T//4 , remains constant for a further time T//2 and decreases linearly from F_0 to zero in further time T//4 as shown. The magnitude possessed by F_0 is. .

A particle of mass m moving with a velocity u makes an elastic one-dimensional collision with a stationary particle of mass m establishing a contact with it for extermely small time. T . Their force of contact increases from zero to F_0 linearly in time T//4 , remains constant for a further time T//2 and decreases linearly from F_0 to zero in further time T//4 as shown. The magnitude possessed by F_0 is. .