# 2D Elastic Ball Collision Physics

I am making a program that involves elastic ball physics. I have worked out all of the maths for collision against walls and stationary objects, but I cannot figure out what happens when two moving balls collide. I have mass and velocity (x and y velocity to be exact, but velocity of each ball and their direction will do) and would like the formulae for those. Remember - this is a perfectly elastic collision - so no spinning balls, etc.

This wikipedia article provides a formula to compute velocities after collision between two particles :

$\mathbf{v'_1}=\mathbf{v_1}-\frac{2m_2}{m_1+m_2}\frac{\left&space;\langle&space;\mathbf{v_1}-\mathbf{v_2}|&space;\mathbf{x_1}-\mathbf{x_2}\right&space;\rangle&space;}{{\left&space;\|&space;\mathbf{x_1}-\mathbf{x_2}&space;\right&space;\|}^{2}}&space;(\mathbf{x_1}-\mathbf{x_2})$

$\mathbf{v'_2}=\mathbf{v_2}-\frac{2m_1}{m_1+m_2}\frac{\left&space;\langle&space;\mathbf{v_2}-\mathbf{v_1}|&space;\mathbf{x_2}-\mathbf{x_1}\right&space;\rangle&space;}{{\left&space;\|&space;\mathbf{x_2}-\mathbf{x_1}&space;\right&space;\|}^{2}}&space;(\mathbf{x_2}-\mathbf{x_1})$

There are many reasons to use this formula :

• you just need the velocity vectors of your balls before collision, their mass and their position,
• you don't need to define angles of deviation,
• the operations are simple (just dot product required),
• the vectors can be expressed in any coordinates system.

There is no proof in the wikipedia article so I provide it below.

Definition of the problem

For each ball we define :

• mi the mass
• vi the vector of velocity before collision
• v'i the vector of velocity after collision
• Oi the point of center
• xi the vector of Oi position

The unit vector n is normal to the surfaces of balls at the point of contact.

$\mathbf{n}=\frac{\mathbf{O_1O_2}}{\left&space;\|&space;\mathbf{O_1O_2}\right&space;\|}=\frac{\mathbf{x_2&space;-&space;x_1}}{\left&space;\|&space;\mathbf{x_2&space;-&space;x_1}\right&space;\|}$

The unit vector t is tangent to the surfaces of balls at the point of contact.

Physics law to use

The conservation of the total momentum is expressed by :

$m_1\mathbf{v'_1}+m_2\mathbf{v'_2}=m_1\mathbf{v_1}+m_2\mathbf{v_2}$

The conservation of total kinetic energy is expressed by :

$\frac{m_1&space;{v'}_1^{2}}{2}+\frac{m_2&space;{v'}_2^{2}}{2}=\frac{m_1&space;v_1^{2}}{2}+\frac{m_2&space;v_2^{2}}{2}$

As there is no force applied in the tangential direction, the tangential components of velocities are unchanged after collision :

$\left\{\begin{matrix}&space;\left&space;\langle&space;\mathbf{v'_1}|\mathbf{t}&space;\right&space;\rangle=\left&space;\langle&space;\mathbf{v_1}|\mathbf{t}&space;\right&space;\rangle&space;\\&space;\left&space;\langle&space;\mathbf{v'_2}|\mathbf{t}&space;\right&space;\rangle=\left&space;\langle&space;\mathbf{v_2}|\mathbf{t}&space;\right&space;\rangle&space;\end{matrix}\right.$

Proof

The tangential components of velocities are unchanged. So we can rewrite the conservation laws with normal components and we have a 1D problem now :

$\left\{\begin{matrix}&space;m_1&space;{\left&space;\langle&space;\mathbf{v'_1}|\mathbf{n}&space;\right&space;\rangle}+m_2&space;{\left&space;\langle&space;\mathbf{v'_2}|\mathbf{n}&space;\right&space;\rangle}&space;=m_1&space;{\left&space;\langle&space;\mathbf{v_1}|\mathbf{n}&space;\right&space;\rangle}+m_2&space;{\left&space;\langle&space;\mathbf{v_2}|\mathbf{n}&space;\right&space;\rangle}&space;\\&space;m_1&space;{\left&space;\langle&space;\mathbf{v'_1}|\mathbf{n}&space;\right&space;\rangle}^{2}+m_2&space;{\left&space;\langle&space;\mathbf{v'_2}|\mathbf{n}&space;\right&space;\rangle}^{2}=m_1&space;{\left&space;\langle&space;\mathbf{v_1}|\mathbf{n}&space;\right&space;\rangle}^{2}+m_2&space;{\left&space;\langle&space;\mathbf{v_2}|\mathbf{n}&space;\right&space;\rangle}^{2}&space;\end{matrix}\right.$

The conservation of kinetic energy can be factorized then simplified with the conservation of momentum :

$m_1&space;{\left&space;\langle&space;\mathbf{v'_1}|\mathbf{n}&space;\right&space;\rangle}^{2}-m_1&space;{\left&space;\langle&space;\mathbf{v_1}|\mathbf{n}&space;\right&space;\rangle}^{2}=m_2&space;{\left&space;\langle&space;\mathbf{v_2}|\mathbf{n}&space;\right&space;\rangle}^{2}-m_2&space;{\left&space;\langle&space;\mathbf{v'_2}|\mathbf{n}&space;\right&space;\rangle}^{2}$

$\Rightarrow&space;{\left&space;\langle&space;\mathbf{v'_1}|\mathbf{n}&space;\right&space;\rangle}+{\left&space;\langle&space;\mathbf{v_1}|\mathbf{n}&space;\right&space;\rangle}={\left&space;\langle&space;\mathbf{v_2}|\mathbf{n}&space;\right&space;\rangle}+{\left&space;\langle&space;\mathbf{v'_2}|\mathbf{n}&space;\right&space;\rangle}$

We combine this last expression with the conservation of momentum and we get the normal component of v'1 :

$\left&space;\langle&space;\mathbf{v'_1}|&space;\mathbf{n}\right&space;\rangle=\frac{(m_1-m_2)\left&space;\langle&space;\mathbf{v_1}|&space;\mathbf{n}\right&space;\rangle&space;+&space;2&space;m_2\left&space;\langle&space;\mathbf{v_2}|&space;\mathbf{n}\right&space;\rangle}{m_1+m_2}&space;=\left&space;\langle&space;\mathbf{v_1}|&space;\mathbf{n}\right&space;\rangle-\frac{&space;2&space;m_2\left&space;\langle&space;\mathbf{v_1-v_2}|&space;\mathbf{n}\right&space;\rangle}{m_1+m_2}$

Finally, we find the formula of the wikipedia article for v'1 :

$\mathbf{v'_1}=\left&space;\langle&space;\mathbf{v'_1}|&space;\mathbf{n}\right&space;\rangle\mathbf{n}+\left&space;\langle&space;\mathbf{v'_1}|&space;\mathbf{t}\right&space;\rangle\mathbf{t}=\mathbf{v_1}-\frac{2m_2}{m_1+m_2}\frac{\left&space;\langle&space;\mathbf{v_1}-\mathbf{v_2}|&space;\mathbf{x_1}-\mathbf{x_2}\right&space;\rangle&space;}{{\left&space;\|&space;\mathbf{x_1}-\mathbf{x_2}&space;\right&space;\|}^{2}}&space;(\mathbf{x_1}-\mathbf{x_2})$

The formula of v'2 is symmetrical.