# algorithm to detect if a Circles intersect with any other circle in the same plane

I'm looking for an algorithm to detect if a Circles intersect with any other circle in the same plane , given that there can be more than one circle in a plane .

The standard method i have found is to do the separating axis test (did google search on that).

It says:

``````Two objects don't intersect if you can find a line that separates
the two objects. e.g. the objects / all points of an object are on
different sides of the line.
``````

but I dont know how to apply it with the circle.

can anybody help me out here?

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Are you looking for two circle intersection or one circle with many others at the same time ? –  parapura rajkumar Dec 3 '11 at 12:11
one circle with many others at same time –  Jean-Luc Godard Dec 3 '11 at 12:20

Two circles intersect if, and only if, the distance between their centers is between the sum and the difference of their radii. Given two circles (x0,y0,R0) and (x1,y1,R1), the formula is as follows:

``````ABS(R0-R1) <= SQRT((x0-x1)^2+(y0-y1)^2) <= (R0+R1)
``````

Squaring both sides lets you avoid the slow SQRT, and stay with ints if your inputs are integer:

``````(R0-R1)^2 <= (x0-x1)^2+(y0-y1)^2 <= (R0+R1)^2
``````

Since you need only a yes/no test, this check is faster than calculating the exact intersection points.

Edit: corrected for the "one circle inside the other" case.

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A circle totally inside another doesn't intersect but satisfies your condition –  parapura rajkumar Dec 3 '11 at 12:14
@parapurarajkumar Thanks for pointing this out! I corrected the answer to account for that condition. –  dasblinkenlight Dec 3 '11 at 12:24
@dashlinkenlight... I think the OP is looking for a 1 to many intersection –  parapura rajkumar Dec 3 '11 at 12:25
@parapurarajkumar A pair of nested loops and a check for `i != j` should easily deal with that, right? –  dasblinkenlight Dec 3 '11 at 12:27
That is perfectly fine for 2 given circles, but applying this to all pairs of circles in straightforward manner would lead to O(n^2) algorithm. One should first filter out pair that cannot possibly intersect. IMO the preferred way is to consider bounding boxes of the circles, build a quadtree, and then check for intersections only the circles that have possibly intersecting bounding boxes. That would lead to an algorithm with O(n*log(n)) average case complexity. –  Michael Jul 29 at 17:21

I tried the formula given here that is a supposed answer and everyone voted way up although it's seriously flawed. I wrote a program in JavaFX to allow the user to test whether two circles intersect by changing each circles centerX, centerY, and Radius values and this formula absolutely does not work except one way...I can't figure out why but when I move circle 2 near circle 1 it works but when I move circle 1 to the other side near circle 2 it doesn't work.....????? that's a bit odd...figured the formula needed to be tested the opposite way as well so tried that and it doesn't work

``````if (Math.abs(circle1Radius - circle2Radius) <=
Math.sqrt(Math.pow((circle1X - circle2X), 2)
+ Math.pow((circle1Y - circle2Y), 2)) &&
Math.sqrt(Math.pow((circle1X - circle2X), 2)
+ Math.pow((circle1X - circle2Y), 2)) <=
return true;
} else {
return false;
}
``````

This works:

``````    // dx and dy are the vertical and horizontal distances
double dx = circle2X - circle1X;
double dy = circle2Y - circle1Y;

// Determine the straight-line distance between centers.
double d = Math.sqrt((dy * dy) + (dx * dx));

// Check Intersections
// No Solution. Circles do not intersect
return false;
// No Solution. one circle is contained in the other
return false;
} else {
return true;
}
``````

Go here for the formula Intersection of two circles

The formula used is not my formula all credit goes to Paul Bourke(April 1997)

`````` First calculate the distance d between the center of the circles. d = ||P1 - P0||.

If d > r0 + r1 then there are no solutions, the circles are separate.

If d < |r0 - r1| then there are no solutions because one circle is contained within the other.

If d = 0 and r0 = r1 then the circles are coincident and there are an infinite number of solutions.

Considering the two triangles P0P2P3 and P1P2P3 we can write

a2 + h2 = r02 and b2 + h2 = r12

Using d = a + b we can solve for a,

a = (r02 - r12 + d2 ) / (2 d)

It can be readily shown that this reduces to r0 when the two circles touch at one point, ie: d = r0 + r1

Solve for h by substituting a into the first equation, h2 = r02 - a2
So

P2 = P0 + a ( P1 - P0 ) / d

And finally, P3 = (x3,y3) in terms of P0 = (x0,y0), P1 = (x1,y1) and P2 = (x2,y2), is

x3 = x2 +- h ( y1 - y0 ) / d

y3 = y2 -+ h ( x1 - x0 ) / d
``````
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Also I want to thank lorenzo-s for providing me with the link to this page. –  John Conner Jul 29 at 17:03

This solution in Java used the mathematical expresion which was described above:

``````/**
*
* @param values
*            { x0, y0, r0, x1, y1, r1 }
* @return true if circles is intersected
*
*         Check if circle is intersect to another circle
*/
public static boolean isCircleIntersect(double... values) {
/*
* check using mathematical relation: ABS(R0-R1) <=
* SQRT((x0-x1)^2+(y0-y1)^2) <= (R0+R1)
*/
if (values.length == 6) {
/* get values from first circle */
double x0 = values[0];
double y0 = values[1];
double r0 = values[2];
/* get values from second circle */
double x1 = values[3];
double y1 = values[4];
double r1 = values[5];
/* returun result */
return (Math.abs(r0 - r1) <= Math.sqrt(Math.pow((x0 - x1), 2)
+ Math.pow((y0 - y1), 2)))
&& (Math.sqrt(Math.pow((x0 - x1), 2)
+ Math.pow((y0 - y1), 2)) <= (r0 + r1));
} else {
/* return default result */
return false;
}
}
``````
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Rather than just providing a link, it would be preferable to include the essential parts of the answer here, and just provide the link for additional reference. If you're not up to this task, you should consider simply leaving a comment on the question instead of posting an answer. But since this is (presumably) really just an implementation of the accepted answer, and the question makes no mention of Java, I don't find this all that useful. –  Dukeling Feb 18 at 18:27
I fixed your post, what you did was not according to the standards we impose upon ourselves. I strongly encourage you to add some form of code markup to your website (I'm assuming it's yours) so it's actually readable. Not only that but also make sure nothing fancy is going on with the font: I had to replace all the minus signs and the triple dots because they simply weren't valid characters in Eclipse. Read through the links provided by Dukeling to avoid this in future posts. –  Jeroen Vannevel Feb 18 at 20:29

If the distance between the centers of two circles is at most the sum of their radii, but at least the absolute value of the difference between the radii, then the circles themselves intersect at some point.

The "at least the difference" part applies if you care only about the circles themselves, and not their inner areas. If you care whether the circles or the areas they enclose share any points -- that is, if one circle totally inside the other counts as "intersecting" to you -- then you can drop the "at least the difference" check.

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Maybe http://paulbourke.net/geometry/2circle/ ? It uses an "algorithm approach", so it will be easy to write down the code...

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