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I am making an air hockey game where the user can control a mallet using the mouse and the computer can control another mallet. I want to handle a collision between the puck and the mallet so the puck can change direction and speed (or velocity) based on the speed and angle of the mallet when they collided without changing the speed of the mallet. I prefer a solution that is not necessarily 100% correct in physics because I don't want to change the whole game but I want it to work and make sense. I am making this is Java but I don't mind an answer in pseudo-code or another language so that others can benefit from this post. Here is my code for the Update method in my game:

    public void update(long tP) {
    if (!getPause() && getGameMode()!="menu") {
        player.update(player.getDistanceX(), player.getDistanceY(), getFps());
        computer.update(puck.getX(), puck.getY());
        puck.update();
        if (puck.circleCollide(player)||puck.circleCollide(computer)) {
            puck.setSpeedX((int)(-5*getScaleFactor()));

        }

        if (puck.rectCollide(myGoal) || puck.rectCollide(computerGoal)) {
            String scorer = puck.rectCollide(myGoal) ? "Computer" : "Player";
            puck.setSpeedX(0);
            puck.setSpeedY(0);
            puck.setX(s.getWidth()/2);
            puck.setY(s.getHeight()/2);
            if (scorer=="Computer") {
                computer.addGoal();
            } else if (scorer=="Player") {
                player.addGoal();
            }
        }
    }
}

At the moment the puck just moves to the left at a certain speed. This is where I want to make it do something else. All the other posts assume that both the circles can move after colliding and do not take into account the angle of collision.

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    Note: you probably don't want to compare a String with !=. Do !getGameMode().equals("menu")
    – TameHog
    Jun 27, 2015 at 18:34
  • Did you make the the classes of puck, player, and computer? If so, their code may be useful.
    – ricky3350
    Jun 27, 2015 at 18:36
  • True, I should have thought about that. To not compare references but value. Jun 27, 2015 at 18:36
  • @ricky3350 Yes, they all extend the class circle so I can include that code. Player is from class mallet and computer is from compmallet which extends mallet. Some of the methods are overridden. Jun 27, 2015 at 18:37
  • The puck class just has the collision detection methods and the circle class has the basic things that would be found in a sprite class such as getter and setter methods for positions and speeds. Jun 27, 2015 at 18:42

1 Answer 1

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I think that what you want is not an elastic collision in the physical sense, since the paddle is controlled by the player and therefore the paddle + puck system is not closed (that is, the total momentum and energy are not constant). Instead, I think you're looking to model the force of the paddle on the puck in a collision so that you can update the velocity of the puck accordingly.

When two circles collide the force of each on the other is directed along the line connecting their centers. So in your case the force of the paddle on the puck is in the direction of the vector difference between the center of the paddle (black) to the center of the puck (blue):

direction of force of the paddle (black) on puck (blue)

To implement this in your update, you can do something like

if (puck.circleCollide(player)) {
    double dx, dy, norm, fx, fy;

    dx = puck.getX() - player.getX(); // distance between centers in x
    dy = puck.getY() - player.getY(); // distance between centers in y

    // define unit-length vector (fx, fy) in direction of the force
    dist = Math.sqrt(dx*dx + dy*dy); // norm of (dx, dy)
    fx = dx/dist;
    fy = dy/dist;

    // may need to cast arguments to int, depending on your interface...
    puck.setSpeedX(puck.getSpeedX() + fmag(dist)*fx);
    puck.setSpeedY(puck.getSpeedY() + fmag(dist)*fy);
}

(and similarly for the computer player's paddle).

Now, how to decide the magnitude of the force (the function fmag(dist) in the example)? One simple way is to just make it a constant (independent of dist), for example:

double fmag(double dist) { return 10.0; }

(Of course this is equivalent to replacing fmag(dist) by 10 in the example). This means that whenever the paddle and puck overlap, the puck will accelerate away from the center of the paddle at a constant rate. This isn't the most physically realistic method but is the simplest to implement.

A more realistic method is to make the magnitude of the force proportional to the amount of overlap between the paddle and the puck, for example

double fmag(double dist) { return 10.0*((rPaddle + rPuck) - dist); }

where rPaddle and rPuck are the radii of the paddle and the puck respectively. This is the physics you would get if the paddle and puck behaved as perfect springs, with spring constant equal to 10 in the example.

You can play with the functional form of fmag(dist) and the constant value to get the behavior you're happy with.

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  • This sounds good and I might test it but the problem is that it doesn't take in enough factors and is therefore not precise enough. What I mean is that what I want is the user to be able to control where the puck will move and at which angle based on not only the magnitude of the mallet and puck's velocities but also the angle they collide. For example-if it was a head on collision there should be a different response to a glancing collision with the same velocities. However, what is good about this is that there will be a response even if one of the circles is not moving. Jun 28, 2015 at 22:33

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