# Algorithm: Calculate pseudo-random point inside an ellipse

For a simple particle system I'm making, I need to, given an ellipse with width and height, calculate a random point X, Y which lies in that ellipse.

Now I'm not the best at maths, so I wanted to ask here if anybody could point me in the right direction.

Maybe the right way is to choose a random float in the range of the width, take it for X and from it calculate the Y value?

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Most of the answers given find points that lie within the ellipse. But your final sentence makes me wonder whether you're wanting only points which lie on the ellipse (since otherwise, it would be unclear how you could "calculate the Y value" given an X value (and ignoring that there would be two Y values)). Could you clarify. –  Damien_The_Unbeliever Apr 4 '11 at 7:32

1. Generate a random point inside a circle of radius 1. This can be done by taking a random angle `phi` in the interval `[0, 2*pi)` and a random value `rho` in the interval `[0, 1)` and compute

``````x = sqrt(rho) * cos(phi)
y = sqrt(rho) * sin(phi)
``````

The square root in the formula ensures a uniform distribution inside the circle.

2. Scale `x` and `y` to the dimensions of the ellipse

``````x = x * width/2.0
y = y * height/2.0
``````
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Most of your points will hang out in the middle: hardly random pattern. Also (assuming you solve problem #1), stretching the circle doesn't preserve 'randomness' either. –  Nikita Rybak Apr 3 '11 at 11:24
@Nikita As the circle area goes with r^2, taking Sqrt gives you a uniform distribution. –  belisarius Apr 3 '11 at 11:36
@belisarius You're right sorry for that. –  Nikita Rybak Apr 3 '11 at 11:42
@Nikita: I had the same reaction. However, the distribution is really uniform (dxdy = rho drho dphi, so when you integrate the right hand side and invert it, you get sqrt(rho), as asserted). –  Alexandre C. Apr 3 '11 at 12:30

Use rejection sampling: choose a random point in the rectangle around the ellipse. Test whether the point is inside the ellipse by checking the sign of (x-x0)^2/a^2+(y-y0)^2/b^2-1. Repeat if the point is not inside. (This assumes that the ellipse is aligned with the coordinate axes. A similar solution works in the general case but is more complicated, of course.)

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+1. Or sample the unit disc with this very method, and transform it to your ellipse afterwards. –  Alexandre C. Apr 4 '11 at 13:54

You can use polar to cartesian coordinate conversion:

``````x = cos(angle) * radius
``````

which a slight modification

``````x = cos(angle) * width
y = sin(angle) * height
``````

You didn't specify a language, but here's a quick demo using Processing:

``````float ellipseWidth = 150,ellipseHeight = 100;
void setup(){
size(400,400);
smooth();
noStroke();
ellipseMode(CENTER);
background(0);
fill(255);
}

void draw(){
//choose a random angle on the ellipse
angle = random(TWO_PI);
//convert from polar to cartesian, using both width and height as radii
x = cos(angle) * ellipseWidth;
y = sin(angle) * random(ellipseHeight);//random 'lengths' vertically
//draw
translate(200,200);//move to centre
ellipse(x,y,5,5);
}
``````

You can see it run here

HTH

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It doesn't look evenly distributed :) –  Snowbear Apr 3 '11 at 11:15
This is not uniform. Either do rejection, or uses @Sven's answer. –  Alexandre C. Apr 3 '11 at 11:17
Even distribution wasn't requested by the OP. For particle systems, this stuff is usually good enough. Also, neither Sven's or lhf's solution are evenly distributed (at least not over their area). –  ltjax Apr 3 '11 at 11:25
@ltjax What's the problem with lhf's solution? –  Nikita Rybak Apr 3 '11 at 11:35
@Nikita: Oh well - I guess it's a small detail, but the original distribution in the "rectangle" needs to be uniform for that to work, and you usually only get that in a "square" - unless you do rejection from a square to a rectangle first. –  ltjax Apr 3 '11 at 11:39

I'd suggest a very simple method:

1. Choose a random X
2. Calculate upper and lower bounds of Y for that particular X
3. Randomize Y within calculated bounds

Bounds formula (courtesy of Wikipedia):

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you'd unduly weight those x values that have fewer y values. –  Martin DeMello Apr 3 '11 at 11:58
It won't be a good distribution, you will get more points near the left and right side of the ellipse. The picture will be the same as in George's answer. You cannot use regular random to calculate X. –  Snowbear Apr 3 '11 at 11:58
@Snowbear JIM-compiler: Yup, I started to think about that after posting. The probability of having a particular X should correspond to the magnitude of bounds of Y for that X. All X-s shouldn't have equal probability - midpoint should have it highest and endpoints lowest. –  Saul Apr 3 '11 at 12:14
Yes, and unfurtunately the formula to get such distribution for X is complicated and I could not find a solution. –  Snowbear Apr 3 '11 at 12:17