# Algorithm to find corner points in a curve

I'm looking for an algoritm to find corners in a list of points/vectors. Is there any good algoritm out there allready I can use or do I have to work this out myself?

Ive done a few tries with min/max of position and angles in a given small range/window around each point. But no matter how I try I cant seem distinguish between an edge and a curve with a small radius very good. Also, when a corner is chamfered by two or more points my method fails.

Do you have any suggestion how I could do this, or point me to a existing algoritm?

Update: The list of points I have is not a polygon, but a curve.

I draw a continuous curve with some circles and some sharp turns, then I want to find out what points in this curve can be considered to be corners. Even though the points in the circles could be pretty tight I dont want them to be detected as corners. Likewise I want points that form wide angles in otherwise pretty straight lines to be detected as corners. It doesnt seem that hard but I cant get it right.

Ive checked out the convex hull and max rect suggestions but I dont see how they could help me here much?

Ive realized that this is depending alot of what I consider to be a corner, because I want the algoritm accept small round or chamfered corners as well.

-
A list of points/vectors does not necessarily make a polygon, are you saying in this case they do? Single polygon or polylines or..? Any point that does not lie on a straight line between the previous/next point could by definition be considered a 'corner'.. can you be more specific? – Kieren Johnstone Oct 23 '11 at 12:40
Look for "maximum rectangle" algorithms. – Gert Arnold Oct 23 '11 at 12:56

You can run from one point to the next, and determine the angle made between vectors `P[n]-P[n-1]` and `P[n-1]-P[n-2]`: i.e. the previous two points vs the latest and previous point. You can do that by normalising both to unit vectors, taking the dot product of the two, then inverse cosine on that, and you have your angle. That's the amount of 'turn' that this point introduced vs the last one. If it's greater than something you specify (say 40 degrees), then you can mark it as a corner.

To rephrase that better: for every sequential set of 3 points (A, B, C), B is a corner if `cos-1(AB.BC)` > 40, or some other angle you specify

Hope that helps.

-
That would give me corners is a tight circle too I think... – Andreas Zita Oct 23 '11 at 13:48
It depends how many points made up the circle, but yes, since you haven't defined what a corner is, I'm suggesting the definition of 'any point that's a turn sharper than N degrees, for example 40'. If you have a different definition, please let me know.. There is no real distinction between a corner and an approximation of a curve mathematically, the curve is a series of corners. – Kieren Johnstone Oct 23 '11 at 13:53
Your right of course, the definition of a corner is everything. I have to try and come up with one that suites my needs. Thanks for your suggestion anyway. Ill try some more. – Andreas Zita Oct 23 '11 at 14:06

I think in your case best algorithm is finding a convex hull, it's fast but implementation is a little tricky. In fact corners are convex hull vertices.

-
As I can see question edit, my point is not nice in this case but variation of this way is good, I think about it and say it with more detail. – Saeed Amiri Oct 23 '11 at 19:22

It depends a lot on the coordinate system that you're using, but basically you have to iterate over all points and find out:

1. The point with the smallest x-coordinate and biggest y-coordinate
2. The point with the biggest x-coordinate and biggest y-coordinate
3. The point with the smallest x-coordinate and smallest y-coordinate
4. The point with the biggest x-coordinate and smallest y-coordinate
-
That finds the bounding rectangle, or the corners of that bounding rectangle. It doesn't sound like that the OP is trying to do that – Kieren Johnstone Oct 23 '11 at 13:20