From the figure, it is observed that the linear momentum is conserved in all the cases. For an elastic collision, kinetic energy is also conserved.

Let us assume that the mass of each ball is m.

Total kinetic energy before collision,

K_i = (1/2)mV² + (1/2)m(0)² + (1/2)m(0)²

⇒ K_i = (1/2)mV²

Case (i):

Total kinetic energy after collision,

K_f = (1/2)m(0)² + (1/2)m(V/2)² + (1/2)m(V/2)²

⇒ K_f = (1/8)mV² + (1/8)mV²

⇒ K_f = (1/4)mV²

The total kinetic energy of the system before collision is not equal to the total kinetic energy after collision in this case. The total kinetic energy is not conserved. Hence, the collision is not elastic.

Case (ii):

Total kinetic energy after collision,

K_f = (1/2)m(0)² + (1/2)m(0)² + (1/2)mV²

⇒ K_f = (1/2)mV²

The total kinetic energy of the system before collision is equal to the total kinetic energy after collision in this case. The total kinetic energy is conserved. Hence, the collision is elastic.

Case (iii):

Total kinetic energy after collision,

K_f = (1/2)m(V/3)² + (1/2)m(V/3)² + (1/2)m(V/3)²

⇒ K_f = (1/18)mV² + (1/18)mV² + (1/18)mV²

⇒ K_f = (1/6)mV²

The total kinetic energy of the system before collision is not equal to the total kinetic energy after collision in this case. The total kinetic energy is not conserved. Hence, the collision is not elastic.

Thus, only case (ii) is an elastic collision.