# Algorithm to cover maximal number of points with one circle of given radius

Let's imagine we have a plane with some points on it. We also have a circle of given radius.

I need an algorithm that determines such position of the circle that it covers maximal possible number of points. Of course, there are many such positions, so the algorithm should return one of them.
Precision is not important and the algorithm may do small mistakes.

Here is an example picture:

Input:
int n (n<=50) – number of points;
float x[n] and float y[n] – arrays with points' X and Y coordinates;
float r – radius of the circle.

Output:
float cx and float cy – coordinates of the circle's center

Lightning speed of the algorithm is not required, but it shouldn't be too slow (because I know a few slow solutions for this situation).

C++ code is preferred, but not obligatory.

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You have no restrictions on the distribution of the points? – Pontus Gagge Jul 12 '10 at 14:47
This sounds like a great codegolf – bobobobo Dec 28 '13 at 22:24
@bobobobo I really don't think so. Quite boring, no exact winning conditions... But feel free to create such a question. – Oleh Prypin Dec 28 '13 at 23:00

Edited to better wording, as suggested :

Basic observations :

• I assume the radius is one, since it doesn't change anything.
• given any two points, there exists at most two unit circles on which they lie.
• given a solution circle to your problem, you can move it until it contains two points of your set while keeping the same number of points of your set inside it.

The algorithm is then:

• For each pair of points, if their distance is < 2, compute the two unit circles C1 and C2 that pass through them.
• Compute the number of points of your set inside C1 and C2
• Take the max.
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I like this solution. It may be the one I need... But I'm not sure it's always correct – Oleh Prypin Jul 12 '10 at 15:17
Can you explain the rationale Alex? – Mau Jul 12 '10 at 15:18
It is O(n^3) in the number of points. You can check whether C is inside the circle of radius 1 passing through A and B (with one prescribed orientation) by calculating one determinant I think. But please beware of roundoff errors, they can really spoil this kind of algorithms. – Alexandre C. Jul 12 '10 at 15:19
@ IVlad: For every two points that are < 2r apart, there are two circles of radius r that could pass through these two points. (If two points are exactly 2r apart, there's only one circle.) With regards to the two points, these circles are "optimal": Since the points are on the very border of the circle, the circle covers a maximum of additional space (and, possibly, further points). Iterating over all point pairs gives you all possible circles with >= 2 points in them. Check these circles for the number of points they each contain, and select the one circle with the highest number. – DevSolar Jul 12 '10 at 16:05
@doc: edited, I assumed r = 1 without saying it. – Alexandre C. Jul 12 '10 at 16:43

This is the "disk partial covering problem" in the literature -- that should give you a good place to start googling. Here's a paper covering one possible solution, but it is a little intense mathematically: http://www.utdallas.edu/~edsha/papers/bin/ISPAN04_cover.pdf

As a matter of fact, this falls in the area called computational geometry, which is fascinating but can be hard to get a toehold in. There's a good overview by deBerg on various algorithms related to the subject.

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I don't think the algorithm can be used in this situation, because I have only one circle – Oleh Prypin Jul 12 '10 at 18:08
In your case, the paper's "k" is 1. – Joel Jul 12 '10 at 18:59

If you want something simple, take random position (x,y), calculate number of points inside circle and compare with previous position. Take the maximum. Repeat the operation any times you want.

Why the hell downvote? Ever heard about Monte Carlo methods? Actually for a huge amount of points, deterministic algorithm may not finish in reasonable time.

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Not the downvoter, but OP: "I need an algorithm that determines...." – maxwellb Jul 12 '10 at 16:56
@maxwellb: "Precision is not important and algorithm may do small mistakes" – doc Jul 12 '10 at 16:58
Reasonable time, also, is expressed in terms of a relationship with the number of points given. For example, O(n^3) means that the algorithm finishes in time proportional to the cube of the number of points. Often, "reasonable" time for an algorithm is: polynomial (n^3, n^8, n^k): OK, linear (n, or 3n, (1/9)n, kn, all are n): great, logarithmic: awesome. – maxwellb Jul 12 '10 at 16:59
Fair enough, and I think your point is valid, so I didn't downvote. Cheers. – maxwellb Jul 12 '10 at 17:00
For my situation, this solution isn't too bad – Oleh Prypin Jul 12 '10 at 17:20

The problem reverts back to finding the global optimum of a function f :R x R -> N. The input for f is the center point of the circle, and the value, of course, is the number of included points from the set. The graph of the function will be discontinuous, staircase-like.

You could start by testing the function in each point corresponding to a point in the set, order the points by decreasing values of f, then intensify search around those points (for example moving out along a spiral).

Another option is to consider all intersection points of segments connecting any pairs of points in the set. Your optimal point will be at one of these intersections I think, but their number is probably too big to consider.

You may also hybridise options 1 and 2, and consider intersections of the segments generated from points around 'good set points'.

Anyhow, unless the number of set points is low (allowing you to check all intersections), I don't think you can guarantee to find the optimum (just a good solution).

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I can see the same answer posted three times in total - probably by mistake. Can you delete the two instances of it? – Suma Jul 12 '10 at 15:11
Done. SO technical issues :-) – Mau Jul 12 '10 at 15:13
The number of points is low (I've just edited the question). But I don't understand a few things, like... how can you make a graph of 2-parameter function? – Oleh Prypin Jul 12 '10 at 15:14
minimization of discrete-valued functions is very tough. – Alexandre C. Jul 12 '10 at 15:15
@Philipp Well I think really only linear (non-integer) are tractable in the general case. But we digress :-) – Mau Jul 12 '10 at 18:53

At a first glance, I would say a quad tree solution.

Also, there is an information visualization/Data mining method called K-means which makes clusters of given data. It can be used with added functionality in the end to fit your purpose.

The basic algorithm for K-Means is:

1. Place K points into the space represented by the items that are being clustered - These points represent initial group centroids
2. Assign each data item to the group that has the closest centroid
3. When all items have been assigned, recalculate the positions of the K centroids by calculating the mean position of your dots
4. Repeat Steps 2 and 3 until the centroids no longer move, or move very little

The added functionality would then be:

1. Calculate number of points within your circle positioned at the K centroids
2. Choose the one that suits you the best ;)

Sources:

A quick search on wikipedia and you find source code: en.wikipedia.org/wiki/K-means_clustering

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Here are two ideas: an O(n) approximation algorithm and an O(n^2 log n) exact (non-approximate) algorithm:

Fast approximation

Use locality-sensitive hashing. Basically, hash each point to a hash bucket that contains all nearby points. The buckets are set up so that collisions only happen between nearby points - unlike similarly-named hash tables, collisions are useful here. Keep a running count of the number of collisions in a bucket, and then use the center of that bucket as the center of your circle.

I admit that this is a fast explanation of a concept that is not super-obvious the first time you hear of it. An analogy would be to ask a bunch of people what their zip code is, and use the most common zip code to determine the most populous circle. It's not perfect, but a good fast heuristic.

It's basically linear time in terms of the number of points, and you can update your data set on the fly to incrementally get new answers in constant time per point (constant with respect to n = number of points).

Better-than-brute-force deterministic approach

The idea is: for each point, place the edge of a circle on that point and sweep the circle around to see which direction contains the most points. Do this for all points and we find the global max.

The sweep around a point p can be done in n log n time by: (a) finding the angle interval per other point q such that when we place the circle at angle theta, then it contains q; and (b) sorting the intervals so that we can march/sweep around p in linear time.

So it takes O(n log n) time to find the best circle touching a fixed point p, and then multiply that by O(n) to perform the check for all points. The total time is O(n^2 log n).

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If it is true that precision is not important and algorithm may do small mistakes then I think the following.

Let f(x,y) is a function which has a maximum at the point (0,0) and is only significant at the points inside of circle of radius R. For example, f(x,y) = e^{(x^2 + y^2)/ (2 * R^2)}.

Let (x_i,y_i) are points and E_i(x,y) = f(x - x_i, y - y_i).

Your problem is to find the maximum of \sum_i E_i(x,y) .

You can use a gradient descent starting it from each point.

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I'm 15-year-old kid. I love programming and I don't like Math. So I often don't understand these smart math things :) – Oleh Prypin Jul 12 '10 at 15:28
@BlaXpirit, you can achieve a lot by programming if you don't know math a lot. But to effectively solve--and understand solutions of--tasks like the one you posted you should get better in maths. (By the way, Alexey is also using LaTeX notation of writing mathematical functions, it's not related to maths, but one of those things you'd better learn about) – Pavel Shved Jul 12 '10 at 16:25
@Alexey, it would be absolutely correct if f was 1 inside the circle, and 0 outside. :-) – Pavel Shved Jul 12 '10 at 16:27
@Pavel, gradient descent does not work correctly for the case of your nondifferentiable function. – Alexey Malistov Jul 12 '10 at 19:01
@Pavel, I'm sure too. I started my answer with If it is true that precision is not important.... – Alexey Malistov Jul 13 '10 at 6:37

Might I suggest a density map? Find the min and max bounds for the x and y. Divide the range of the x and y bounds into bins having widths equal to the diameter of your circle. Count the number of points in each bin for the x and y separately. Now find the intersection on your density map between the highest ranked x bin with the highest ranked y bin.

This is a VERY fast algorithm to quickly generalize large data sets but it is not always accurate, to improve accuracy you can slice the bins into smaller and smaller pieces or shift the bin positions to the left or right n times and use a voting system to select the answer that occurs most often between trials.

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"not always accurate": imagebin.org/105002 – maxwellb Jul 12 '10 at 16:55
Instead of large data sets, I have very small data sets. So this is incorrect here – Oleh Prypin Jul 12 '10 at 17:19

You could pixelize the whole area, then go to each point and increase the value of all pixels within the circle of the radius around that point. The pixels with the highest sum are good candidates.

Of course, you might lose some good areas or "hallucinate" good areas due to rounding errors. Perhaps you could try to do a rough pixellation first, then refine the promising areas.

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This is famous K-closest point algorithm. Described here: http://www.cs.ucsb.edu/~suri/cs235/ClosestPair.pdf

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No it's not. You could have a best circle centered on a point that is not part of the set. – Mau Jul 12 '10 at 14:57
This is not the correct answer – Oleh Prypin Jul 12 '10 at 14:58
if it isn't correct downvote it – Jarrod Roberson Jul 12 '10 at 15:09
you do now :-) keep asking interesting questions! – Jarrod Roberson Jul 12 '10 at 15:47
@BlaXpirit if the answer isn't correct then please unselect it as the accepted solution. – chollida Jul 12 '10 at 18:29