Applying Physics to Pinball Machines: A Comprehensive Guide

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A user seeks resources on the application of physics in pinball machines for an 11th grade Honors Physics class. Key concepts discussed include Newton's third law, impulse momentum equations, and kinematic equations relevant to the motion of the pinball. Specific equations are suggested for analyzing how the ball interacts with flippers and the trajectory of its movement. The conversation emphasizes the importance of understanding basic physics principles without delving too deeply into complex theories. Overall, the discussion provides a foundation for applying physics concepts to the mechanics of pinball machines.
Shaheemie
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Do any of you know of a good site, or just a general site, where physics is applied to pinball machines? I 'm having trouble finding any, if there are any out there, that is.
 
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What would you like to know? There is a couple of things about pinball machines related to physics (and by a couple of things I mean, well... everything).
 
Well, I don't need it in great depth. I'm in an 11th grade Honors Physics class and there is only so much we can cover and understand. Obviously basics is needed. That would be really helpful, thank you. I trust your judgement. If I have any trouble, I'll just yell. :P
 
I'm guessing you are in Physics C (Mechanics). You should look into Newton's third law (law of conservation). This can represent how the pinball will bounce off of walls. You can also look at impulse momentum equations F/delta t = M /delta V. This can be applied to when the flipper hits the ball. You can then look at d = 1/2gt^2. This equation can (when applied on a tilted axis, because the ball is not dropping straight down) provide a distance that the ball will travel downwards in a given amount of time, or you can use the equation v_f^2 = v_o^2 + 2ad for the velocity of a ball.

Good luck!
 
That's fantastic. That's just what I needed.
Thank you!
 

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