# What is the fastest way to find the center of an irregularly shaped polygon?

I need to find a point that is a visual center of an irregularly shaped polygon. By visual center, I mean a point that appears to be in the center of a large area of the polygon visually. The application is to put a label inside the polygon.

Here is a solution that uses inside buffering:

http://proceedings.esri.com/library/userconf/proc01/professional/papers/pap388/p388.htm

If this is to be used, what is an effective and fast way to find the buffer? If any other way is to be used, which is that way?

A good example of really tough polygons is a giant thick U (written in Arial Black or Impact or some such font).

Thanks, M

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What if the set defined by the polygon is (highly) non-convex (en.wikipedia.org/wiki/Convex_set); is it allowed to have the center outside the polygon? –  Pukku Jul 29 '09 at 21:35
Yes, but for the purpose of labeling, we would need to find a point inside. –  Mikhil Jul 29 '09 at 21:40
@Mikhil: to expand on @Pukku's comment, could you please post a "hard" aspect of this problem, i.e. a shape that would be difficult to label given "naive" answers such as center-of-mass? The ones I can think of easily are a giant U or the state of Florida (center of mass of these shapes are outside the boundary) –  Jason S Jul 29 '09 at 21:41
Jason, the examples you state are good ones! Thanks! –  Mikhil Jul 29 '09 at 21:45
I guess a small "U" would be nearly as hard a testcase ;) –  Flo Ledermann Oct 15 '14 at 9:48

If you can convert the polygon into a binary image, then you can use the foundation that exists in the field of image processing, e.g.: A Fast Skeleton Algorithm on Block Represented Binary Images.

But this is not really reasonable in the general case, because of discretization errors and extra work.

However, maybe you find these useful:

EDIT: Maybe you want to look for the point that is the center of the largest circle contained in the polygon. It is not necessarily always in the observed centre, but most of the time would probably give the expected result, and only in slightly pathological cases something that is totally off.

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–  Oren Trutner Jul 29 '09 at 21:57
I think these are your best bets by far. You could adapt the above by vertically stretching the polygon by a factor of 2 or 3, then searching for the largest circle contained in the stretched polygon. This will give you the largest ellipse contained within the polygon, which will give you the best spot to put your label. –  jprete Jul 29 '09 at 22:08

Have you looked into using the centroid formula?

http://en.wikipedia.org/wiki/Centroid

http://en.wikipedia.org/wiki/K-means_algorithm

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Centroid == Center of Mass at Uniform Density –  Janie Jul 29 '09 at 21:54

How about finding the "incircle" of the polygon (the largest circle that fits inside it), and then centering the label at the center of that? Here are a couple of links to get you started:

This won't work perfectly on every polygon, most likely; a polygon that looked like a C would have the label at a somewhat unpredictable spot. But the advantage would be that the label would always overlap a solid part of the polygon.

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Won't this be slow if a polygon has several triangulations? –  Mikhil Jul 29 '09 at 22:05
I don't know; will it? –  Kyralessa Jul 29 '09 at 23:13

I am not saying that this is the fastest, but it will give you a point inside the polygon. Calculate the Straight Skeleton. The point you are looking for is on this skeleton. You could pick the one with the shortest normal distance to the center of the bounding box for example.

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Centroid method has already been suggested multiple times. I think this is an excellent resource that describes the process (and many other useful tricks with polygons) very intuitively:

http://paulbourke.net/geometry/polygonmesh/centroid.pdf

Also, for placing a simple UI label, it might be sufficient to just calculate the bounding box of the polygon (a rectangle defined by the lowest and highest x and y coordinates of any vertex in the polygon), and getting its center at:

``````{
x = min_x + (max_x - min_x)/2,
y = min_y + (max_y - min_y)/2
}
``````

This is a bit faster than calculating the centroid, which might be significant for a real-time or embedded application.

Also notice, that if your polygons are static (they don't change form), you could optimize by saving the result of the BB center / center of mass calculation (relative to e.g. the first vertex of the polygon) to the data structure of the polygon.

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Compute the centre position (x,y) of each edge of the polygon. You can do this by finding the difference between the positions of the ends of each edge. Take the average of each centre in each dimension. This will be the centre of the polygon.

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I think this suffers the same problem as my solution when it comes to highly non-convex shapes... –  Janie Jul 29 '09 at 21:38
Yep, and without taking a weighted average it also over-emphasizes short edges, even if the polygon is convex. –  Pukku Jul 29 '09 at 21:43

If I understand the point of the paper you linked to (quite an interesting problem, btw), this "inside buffering" technique is somewhat analogous to modeling the shape in question out of a piece of sugar that's being dissolved by acid from the edges in. (e.g. as the buffer distance increases, less of the original shape remains) The last bit remaining is the ideal spot to place a label.

How to accomplish this in an algorithm unfortunately isn't very clear to me....

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GIS softwares like PostGIS have functions like ST_Buffer that do this. I don't know how, so quickly. –  Mikhil Jul 29 '09 at 21:44

This problem would probably be analogous to finding the "center of mass" assuming a uniform density.

EDIT: This method won't work if the polygon has "holes"

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No. See the figure #4 in the ESRI paper that the OP linked to. –  Jason S Jul 29 '09 at 21:31
It seems that my assumption is what they used in #2; the only time it breaks down is under this condition: "However, this method provides an incorrect result if a polygon has holes" –  Janie Jul 29 '09 at 21:34
No. Imagine a giant U. There are no holes, and the center of mass is not inside the boundary of the polygon. I think your answer is correct only for convex polygons. –  Jason S Jul 29 '09 at 21:36
I see, thank you for the clarification. –  Janie Jul 29 '09 at 21:37
You're welcome. I like to criticize rather than downvote :-) –  Jason S Jul 29 '09 at 21:39

I think if you broke the polygon back into it's vertices, and then applied a function to find the largest convex hull , and then find the center off that convex hull, it would match closely with the "apparent" center.

Finding the largest convex hull given the vertices: Look under the Simple Polygon paragraph.

Average the vertices of the convex hull to find the center.

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I wonder. What would happen, if my polygon was a giant 'U'? –  Mikhil Jul 29 '09 at 21:42
It would select one of the sides. What is the desired behavior in that situation? –  CookieOfFortune Jul 29 '09 at 21:46
For a giant U, an acceptable solution is the middle of the lower thick section. –  Mikhil Jul 29 '09 at 21:50
If the lower thick section is the largest convex hull, then it would be selected. Is there some type of criteria for selected convex hull to be more of a square? –  CookieOfFortune Jul 29 '09 at 21:52
Wont the largest convex hull cover the entire U and be a rectangle? –  Mikhil Jul 29 '09 at 22:01

Could you place the label at the naive center (of the bounding box, perhaps), and then move it based on the intersections of the local polygon edges and the label's BB? Move along the intersecting edges' normals, and if multiple edges intersect, sum their normals for movement?

Just guessing here; in this sort of problem I would probably try to solve iteratively as long as performance isn't too much of a concern.

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Not much time to elaborate or test this right now, but I'll try to do more when I get a chance.

Use centroids as your primary method. Test to see if the centroid is within the polygon; if not, draw a line through the nearest point and on to the other side of the polygon. At the midpoint of the section of that line that is within the polygon, place your label.

Because the point that is nearest to the centroid is likely to bound a fairly large area, I think this might give results similar to Kyralessa's incircles. Of course, this might go berserk if you had a polygon with holes. In that case, the incircles would probably fair much better. On the other hand, it defaults to the (quick?) centroid method for the typical cases.

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Pathological test case #3: a symmetrical barbell-like shape with a thin rectangle and two big octagons on the ends. Centroid is within the polygon but the rectangle is a bad place to label since it may not fit. –  Jason S Jul 30 '09 at 13:38

you can use Center of Mass (or Center of Gravity) method which is used in civil engineering, here is a useful link from wikipedia:

http://en.wikipedia.org/wiki/Center_of_mass

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