# Most efficient way to find distance between two circles in java?

So apparently calculating square roots is not very efficient, which leaves me wondering what the best way is to find out the distance (which I've called range below) between two circles is?

So normally I would work out:

``````a^2 + b^2 = c^2
dy^2 + dx^2 = h^2
dy^2 + dx^2 = (r1 + r2 + range)^2
(dy^2 + dx^2)^0.5 = r1 + r2 + range
range = (dy^2 + dx^2)^0.5 - r1 - r2
``````

Trying to avoid the square root works fine when you just look for the situation when "range" is 0 for collisions:

`````` if ( (r1 + r2 + 0 )^2 > (dy^2 + dx^2) )
``````

But if I'm trying to work out that range distance, I end up with some unwieldy equation like:

`````` range(range + 2r1 + 2r2) = dy^2 + dx^2 - (r1^2 + r2^2 + 2r1r2)
``````

which isn't going anywhere. At least I don't know how to solve it for range from here...

The obvious answer then is trignometry and first find theta:

``````  Tan(theta) = dy/dx
theta = dy/dx * Tan^-1
``````

Then the find the hypotemuse Sin(theta) = dy/h h = dy/Sin(theta)

Finally work out the range range + r1 + r2 = dy/Sin(theta) range = dy/Sin(theta) - r1 - r2

So that's what I've done and have got a method that looks like this:

``````private int findRangeToTarget(ShipEntity ship, CircularEntity target){

//get the relevant locations
double shipX = ship.getX();
double shipY = ship.getY();
double targetX =  target.getX();
double targetY =  target.getY();

//get the difference in locations:
double dX = shipX - targetX;
double dY = shipY - targetY;

// find angle
double theta = Math.atan(  ( dY / dX ) );

// find length of line ship centre - target centre
double hypotemuse = dY / Math.sin(theta);

// finally range between ship/target is:

return range;

}
``````

So my question is, is using tan and sin more efficient than finding a square root?

I might be able to refactor some of my code to get the theta value from another method (where I have to work it out) would that be worth doing?

Or is there another way altogether?

Please excuse me if I'm asking the obvious, or making any elementary mistakes, it's been a long time since I've used high school maths to do anything...

*EDIT*

Specifically I'm trying to create a "scanner" device in a game that detects when enemies/obstacles are approaching/ going away etc. The scanner will relay this information via an audio tone or a graphical bar or something. Therefore although I don't need exact numbers, ideally I would like to know:

1. target is closer/further than before
2. target A is closer/further than target B, C, D...
3. A (linear hopefully?) ratio that expresses how far a target is from the ship relative to 0 (collision) and max range (some constant)
4. some targets will be very large (planets?) so I need to take radius into account

I'm hopeful that there is some clever optimisation/approximation possible (dx + dy + (longer of dx, dy?), but with all these requirements, maybe not...

-
I am amused with your hypotenuse! –  Bruno Kim May 19 '12 at 16:01
don't use `toDegrees`: `Math.sin` uses radians (as do all trig functions in Math) –  ratchet freak May 19 '12 at 18:46
Have you profiled your code with `sqrt`? –  siamii May 19 '12 at 19:37
@BrunoKim :D It's not the first time I've spelt it like that either... I think I prefer my version, inspired by my favourite animal, the hypotomus, I mean hippotopamus... hippyhoppytoppamossymus... hmm. I may have mild dyslexia. –  kiman May 20 '12 at 16:01
@ratchetfreak Good point! –  kiman May 20 '12 at 16:02

`Math.hypot` is designed to get faster, more accurate calculations of the form `sqrt(x^2 + y^2)`. So this should be just

``````return Math.hypot(x1 - x2, y1 - y2) - r1 - r2;
``````

I can't imagine any code that would be simpler than this, nor faster.

-
+1, Interesting, I have never noticed that method before! –  Ernest Friedman-Hill May 19 '12 at 17:04
Taking cues from other answers of not worrying too much, I think this seems the most sensible solution for now. If performance becomes a problem in the future I will also look more into approximations and look up tables. –  kiman May 20 '12 at 16:06
Is it really faster? How do you know? –  Inverse May 26 '12 at 0:55
This is basically unambiguously how you're supposed to do it. If the JDK provides you with a built-in method to calculate the hypotenuse of a triangle like this, that's implemented in native code, I feel quite comfortable assuming that that's how you're meant to do it. Is that the reason for the downvote? –  Louis Wasserman May 30 '12 at 22:02

If you really need the accurate distance, then you can't really avoid the square root. Trigonometric functions are at least as bad as square root calculations, if not worse.

But if you need only approximate distances, or if you need only relative distances for various combinations of circles, then there are definitely things you can do. For example, if you need only relative distances, note that squared numbers have the same greater-than relationship as do their square roots. If you're only comparing different pairs, skip the square root step and you'll get the same answer.

If you only need approximate distances, then you might consider that `h` is roughly equal to the longer adjacent side. This approximation is never off by more than a factor of two. Or you could use lookup tables for the trigonometric functions -- which are more practical than lookup tables for arbitrary square roots.

-
Thanks Ernest, there are some useful pointers there. I'm wondering if something like adding dx + dy (minus the radii) and the longer of the two sides, might give some kind of decent approximation that would fulfill most of my conditions (I just added them to my post). I think the big problem is that I would like a smooth representation of this data to output to the user... Anyway if I can't come up with anything better over the next day or so, I'll mark this answer as correct. –  kiman May 19 '12 at 15:14

I tired working out whether firstly the answers when we use tan, sine is same as when we use sqrt functions.

``````public static void main(String[] args) throws Exception {
// TODO Auto-generated method stub
double shipX = 5;
double shipY = 5;
double targetX =  1;
double targetY =  1;

//get the difference in locations:
double dX = shipX - targetX;
double dY = shipY - targetY;

// find angle
double theta = Math.toDegrees(Math.atan(  ( dY / dX ) ));

// find length of line ship centre - target centre
double hypotemuse = dY / Math.sin(theta);
System.out.println(hypotemuse);
// finally range between ship/target is:
System.out.println(range);

hypotemuse = Math.sqrt(Math.pow(dX,2) + Math.pow(dY,2));
System.out.println(hypotemuse);
System.out.println(range);
}
``````

The answer which i got was : 4.700885452542996

1.7008854

5.656854249492381

2.6568542

Now there seems a difference between the value with sqrt ones being more correct.

1. talking abt the performance : Consider your code snippet :

i calculated the time of performance- which comes out as:

``````    public static void main(String[] args) throws Exception {
// TODO Auto-generated method stub
long lStartTime = new Date().getTime(); //start time
double shipX = 555;
double shipY = 555;
double targetX =  11;
double targetY =  11;

//get the difference in locations:
double dX = shipX - targetX;
double dY = shipY - targetY;

// find angle
double theta = Math.toDegrees(Math.atan(  ( dY / dX ) ));

// find length of line ship centre - target centre
double hypotemuse = dY / Math.sin(theta);
System.out.println(hypotemuse);
// finally range between ship/target is:
System.out.println(range);

long lEndTime = new Date().getTime(); //end time

long difference = lEndTime - lStartTime; //check different

System.out.println("Elapsed milliseconds: " + difference);
}
``````

Answer - 639.3204215458475, 610.32043, Elapsed milliseconds: 2

And when we try out with sqrt root one:

``````public static void main(String[] args) throws Exception {
// TODO Auto-generated method stub
long lStartTime = new Date().getTime(); //start time
double shipX = 555;
double shipY = 555;
double targetX =  11;
double targetY =  11;

//get the difference in locations:
double dX = shipX - targetX;
double dY = shipY - targetY;

// find angle
double theta = Math.toDegrees(Math.atan(  ( dY / dX ) ));

// find length of line ship centre - target centre

double hypotemuse = Math.sqrt(Math.pow(dX,2) + Math.pow(dY,2));
System.out.println(hypotemuse);
System.out.println(range);

long lEndTime = new Date().getTime(); //end time

long difference = lEndTime - lStartTime; //check different

System.out.println("Elapsed milliseconds: " + difference);
}
``````

Answer - 769.3321779309637, 740.33215, Elapsed milliseconds: 1

Now if we check for the difference the difference between the two answer is also huge.

hence i would say that if you making a game more accurate the data would be more fun it shall be for the user.

-
Thanks for the testing, interesting to see the difference in the answers. Accuracy is not so important for me as opposed to precision. (I think I got them the right way round) In any case I will keep it in mind for future reference. –  kiman May 20 '12 at 16:08

The problem usually brought up with `sqrt` in "hard" geometry software is not its performance, but the loss of precision that comes with it. In your case, `sqrt` fits the bill nicely.

If you find that `sqrt` really brings performance penalties - you know, optimize only when needed - you can try with a linear approximation.

``````f(x) ~ f(X0) + f'(x0) * (x - x0)
sqrt(x) ~ sqrt(x0) + 1/(2*sqrt(x0)) * (x - x0)
``````

So, you compute a lookup table (LUT) for `sqrt` and, given `x`, uses the nearest `x0`. Of course, that limits your possible ranges, when you should fallback to regular computing. Now, some code.

``````class MyMath{
private static double[] lut;
private static final LUT_SIZE = 101;
static {
lut = new double[LUT_SIZE];
for (int i=0; i < LUT_SIZE; i++){
lut[i] = Math.sqrt(i);
}
}
public static double sqrt(final double x){
int i = Math.round(x);
if (i < 0)
throw new ArithmeticException("Invalid argument for sqrt: x < 0");
else if (i >= LUT_SIZE)
return Math.sqrt(x);
else
return lut[i] + 1.0/(2*lut[i]) * (x - i);
}
}
``````

(I didn't test this code, please forgive and correct any errors)

Also, after writing this all, probably there is already some approximate, efficient, alternative Math library out there. You should look for it, but only if you find that performance is really necessary.

-
Hm, it will provide an answer if `x < 0` but `Math.round(x) >= 0`. –  Bruno Kim May 19 '12 at 16:28
I think I will follow your advice and not worry too much about optimizing yet. I want to port my game to phones eventually, so I guess I'll have to optimize then. At that point linear approximation and look up tables will probably be the answer. –  kiman May 20 '12 at 16:09