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# Javascript, Canvas: Calculating the angle from a flying bubble

What I have:

A lot of bubbles. But to make it more simple, let's say I have two. When they meet each other they collide and change the direction.

``````var xVelocityBubble1 = Math.random();
var yVelocityBubble1 = Math.random();

var xVelocityBubble2 = Math.random();
var yVelocityBubble2 = Math.random();

moveBubbles = function() {
xbubble1 += xVelocityBubble1;
ybubble1 += yVelocityBubble1;

xbubble2 -= xVelocityBubble2;
xbubble2 -= yVelocityBubble2;

if (Math.sqrt(Math.pow(xbubble1 - xbubble2, 2) + Math.pow(ybubble1 - ybubble2, 2)) < radius * 2) {
xVelocityBubble1 *= -1;
yVelocityBubble1 *= -1;
xVelocityBubble2 *= -1;
yVelocityBubble2 *= -1;
}
}
``````

What I want:

I do not want the circles to simply change the direction, because that looks strange and boring. So I want to calculate the angle where the circle meet, and from that I need to calculate how much momentum they exchange and how that affects each circle.

My problem:

I really do not know how to calculate the angle and the momentum! Any hints?

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physics.stackexchange.com seems to be a more appropriate place for your question – Asad Saeeduddin Oct 19 '12 at 16:03
One quick hint: You should be able to calculate the angle of the bubble(s) by using `Math.atan2(yVelocity, xVelocity)` – Shmiddty Oct 19 '12 at 16:28

To get the angle between those two bubbles if they collide do as follows:

get the direction vector in which one of those bubbles were moving

``````direction = {x: Math.abs(xVelocityBubble1), y: Math.abs(yVelocityBubble1)};
``````

Then normalize that vector (divide it's x and y components by it's length)

After doing that you'll have the cosine of the angle as the x component and the sine as the y, just use any of them in `Math.acos` or `Math.asin` and you'll have the angle in which they collided.

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This code shows collision of asteroids:

``````            for (var i = 0; i < asteroidsLength; i++) {
var tmpAsteroid = asteroids[i];

for (var j = i + 1; j < asteroidsLength; j++) {
var tmpAsteroidB = asteroids[j];

var dX = tmpAsteroidB.x - tmpAsteroid.x;
var dY = tmpAsteroidB.y - tmpAsteroid.y;
var distance = Math.sqrt((dX * dX) + (dY * dY));

var angle = Math.atan2(dY, dX);
var sine = Math.sin(angle);
var cosine = Math.cos(angle);

// Rotate asteroid position
var x = 0;
var y = 0;

// Rotate asteroidB position
var xB = dX * cosine + dY * sine;
var yB = dY * cosine - dX * sine;

// Rotate asteroid velocity

var vX = tmpAsteroid.vX * cosine + tmpAsteroid.vY * sine;
var vY = tmpAsteroid.vY * cosine - tmpAsteroid.vX * sine;

// Rotate asteroidB velocity
var vXb = tmpAsteroidB.vX * cosine + tmpAsteroidB.vY * sine;
var vYb = tmpAsteroidB.vY * cosine - tmpAsteroidB.vX * sine;

// Conserve momentum
var vTotal = vX - vXb;
vX = ((tmpAsteroid.mass - tmpAsteroidB.mass) * vX + 2 * tmpAsteroidB.mass * vXb) / (tmpAsteroid.mass + tmpAsteroidB.mass);
vXb = vTotal + vX;

// Move asteroids apart

// Rotate asteroid positions back
tmpAsteroid.x = tmpAsteroid.x + (x * cosine - y * sine);
tmpAsteroid.y = tmpAsteroid.y + (y * cosine + x * sine);

tmpAsteroidB.x = tmpAsteroid.x + (xB * cosine - yB * sine);
tmpAsteroidB.y = tmpAsteroid.y + (yB * cosine + xB * sine);

// Rotate asteroid velocities back
tmpAsteroid.vX = vX * cosine - vY * sine;
tmpAsteroid.vY = vY * cosine + vX * sine;

tmpAsteroidB.vX = vXb * cosine - vYb * sine;
tmpAsteroidB.vY = vYb * cosine + vXb * sine;
};

};
``````
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