Elastic Collisions: Difference between revisions
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===A Computational Model=== | ===A Computational Model=== | ||
The link below demonstrates a basic car crash elastic collision using MATLAB. Take note of the changes in displacement and the time. | |||
[https://www.youtube.com/watch?v=AfCfCS6O2VM Elastic Collision MATLAB model] | [https://www.youtube.com/watch?v=AfCfCS6O2VM Elastic Collision MATLAB model] |
Revision as of 17:10, 5 December 2015
CLAIMED BY KINGRAM7
The Main Idea
So what exactly is an elastic collision? I know you’re thinking, “Oh I know all about elasticity,” but LOL this is not bubble gum or rubber bands guys!
An elastic collision is a collision between two or more objects in which there is no loss in kinetic energy before and after the collision. If we assume that the colliding objects are part of the system and that there is no force from the surroundings, the final kinetic energy is still in the same form as it was initially. To keep it simple, this means that kinetic energy in= kinetic energy out. Remember how your parents always told you what goes in must come out? They were talking about elastic collisions... probably.
Additionally, elastic collisions are a wonderful representation of the conservation of momentum which states that the momentum of an isolated system is constant. For an isolated system undergoing an elastic collision momentum in = momentum out.
And I love playing pool because every time a ball hits another and they bounce off one another I’m witnessing an elastic collision so basically I’m a physicist in the lab. The image below demonstrates the main idea of an elastic collision. Boing!!
A Mathematical Model
Let’s take what we know about elastic collisions and translate them into that weird language called math. We know that there is no loss in kinetic energy before and after an elastic collision. So,
(Initial kinetic energy = final kinetic energy)
This simple principal can be expanded into:
Starting from the left side we have m1 and m2 which are the masses of object 1 and 2 respectively, and v1i and v2i represent their initial velocities respectively. On the right side of the equation, the final kinetic energy, it’s the same equation just different numbers! For the final kinetic energy, unless stuff is breaking or its otherwise stated in the problem, you can assume the masses won’t change BUT the velocities may. Imagine if you toss a pool ball towards another one that is initially at rest. The one that is at rest will move after it is hit, so there is a change in velocity! However, please remember that there is no overall change in kinetic energy. Let’s say the mass of our pool balls are 2 kilograms and I will make up some speeds. Applying the formula from above we get:
As you see the final velocities changed. One ball was initially at rest but it wasn't after the collision because it was struck by a ball that was already moving...But there was no change in kinetic energy because 32=32 yay! Put it in your calculator and see for yourself.
A Computational Model
The link below demonstrates a basic car crash elastic collision using MATLAB. Take note of the changes in displacement and the time.
Elastic Collision MATLAB model
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