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I'm trying to make a ball bounce around a window. Depending on how far away the ball hits the wall and at what angle will determine its reflection. You can see in the pic that the black trajectory hits the opposite wall on the inner half... and the gray trajectory represents if it were to reflect and hit the other half... which would decrease the angle of reflection.

I'm not sure if I'm thinking about it correctly... I'm trying to put the coordinates in terms of degrees.

So given the pic... You would take those deltas, then get degrees...

degree = Math.atan2(opposite/adjacent) = (-4/-2)

enter image description here

My code

public class Calculate {

public Calculate() {
    System.out.println(getCalc(7,5,4,0));       
}

public double getCalc(int x1, int x2, int y1, int y2) {
    double deltaX = Math.abs(x2-x1);
    double deltaY = Math.abs(y2-y1);
    double degrees = Math.toDegrees((java.lang.Math.atan2(deltaX, deltaY)));

    return degrees;
}

}

Gives the output: 26.56505117707799

So now I know the ball would reflect off the wall at 26 degrees (since that's the angle of incidence). But I don't want the ball to necessarily reflect uniformly off each wall so it adds variability.

My questions:

  • Am I calculating the angle of the ball correctly?
  • How can I add variability to the bounce based on where it hits on the wall?
  • Once I have the angle in degrees, how can I translate that back to coordinates?

Thank you!

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3 Answers

up vote 2 down vote accepted

Am I calculating the angle of the ball correctly?

Your drawing is not to scale. The 26 degrees is measured from a line perpendicular to the wall.

How can I add variability to the bounce based on where it hits on the wall?

You already suggested a random angle. You can also adjust the angle of reflection based on the distance from the center of the wall.

Put your angle of reflection calculation into its own method. You can adjust the calculation until your calculations give you the "randomness" you're looking for.

Once I have the angle in degrees, how can I translate that back to coordinates?

Convert the degrees to radians, then calculate the SAS of the triangle. Just leave your angles in radians in the model, and convert to degrees in your display / diagnostic methods.

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Thanks for the response Gilbert. I updated my drawing above... is that correct? –  Growler Jul 26 '13 at 15:48
    
@Growler: Yes, theta is the angle you're calculating. –  Gilbert Le Blanc Jul 26 '13 at 15:51
    
I meant, once I have the angle in degrees... I'm looking how to get the new incrementing values that represent that angle (not necessarily the sides as your link shows using SAS). As in.. what is newVal in x += newVal; and y += newVal for x and y increments? –  Growler Jul 26 '13 at 19:16
    
Any thoughts on that Gilbert? –  Growler Jul 29 '13 at 14:27
    
@Growler: I didn't want to argue with you. In your diagram, you calculate theta as the angle of incidence. By some method that you choose, you calculate a new theta for the angle of reflection. You now have a side (the perpendicular line), an angle (the new theta), and a side (the outgoing path, which is the same length as the incoming path). Looks like an SAS calculation to me. –  Gilbert Le Blanc Jul 29 '13 at 14:37
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I think that the distance of the ball from the surface doesn't really have an effect on the angle. The angle of the ball before hitting the surface should be the same (mirror reflected) when it leaves the surface for it to be natural.

You can add some variability by thinking what happens to a rubber ball, since it changes a little on impact depending on the force etc., the reflection is not exactly the same every time. You could simply add or remove a degree or two randomly and see how it goes.

Once you have an angle, its once again down to trigonometry. You have an angle, and you know the hypotenuse (I presume depending on your frame-rate and ball speed the ball would have travelled a certain amount from the surface). So from that you need to get the adjacent and opposite lines of the triangle.

For example:

sin(angle) * hypothenuse = opposite (so Y offset from the surface).

cos(angle) * hypothenuse = adjacent (so X offset from the point of contact).

Just add or remove (depending on the direction) the adjacent and opposite values from the coordinates of the contact point.

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If you want to make it seem a little random, you could model spin somewhat--it doesn't have to be too complicated.

If it was not spinning and hit a wall at a 45 degree angle, it would impart a spin to the ball. When it hit the next wall, the spin would added to the angle and the spin would be increased (or decreased) by the angle. I think the spin/angle combination would also effect the speed at which it came off the wall (Just visualizing real-life situations)

That would make it vary without it being truly random--but I don't know how it would actually look--you may have to apply other restrictions (I think that there must be a way to limit the max spin).

I bet there is a simple physics book around that could give enough to model this without going too deep into the math if you didn't just want to make up rules.

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