[A long, long time ago I studied this as an undergrad. ]
You need to be clear on the masses. Probably you are assuming equal mass for both balls, as opposed to one being of infinite mass.
The second thing is: Are you interested in considering rolling constraints as well as linear momentum. The treatments you will come across which talk along the lines of a simplistic elastic collision ignore all this. As an example, consider shots in pool/ snooker where you deliberately strike the ball away from the midpoint to generate front or backspin.
Do you want to able to do this?
If so, you need to consider the friction between a spinning ball and the surface.
For example in a "simple" straight-on collision between a rolling ball and a stationary one, if we assume perfectly elastic (again not quite true):
- the initial collision stops the moving ball 'A'
- the stationary ball 'B' starts moving at the impact speed of 'A'
- 'A' still has spin, it grips the surface and picks up some small velocity
- 'B' starts without spin and has to match it to its speed in order to roll. This results in it slowing slightly.
For the simplistic case, the calculation is much easier if you transform to the coordinates of the centre of mass. In that frame, the collision is always a straight-on collision, reversing the direction of the balls. You then just transform back to get the resultants.
Assuming indetical masses and speeds prior to the impact of v1 and w1.
V0 = centre of mass speed = (v1+w1)/2
v1_prime = v of mass_1 in transformed coords = v1 - V0
w1_prime = w1 - V0
Post collision, we have a simple reflection:
v2_prime = -v1_prime (== w1_prime)
w2_prime = -vw_prime (== v1_prime)
v2 = v2_prime + V0
w2 = w2_prime + V0