# find a point non collinear with all other points in a plane

Given a list of N points in the plane in general position (no three are collinear), find a new point p that is not collinear with any pair of the N original points.

We obviously cannot search for every point in the plane, I started with finding the coincidence point of all the lines that can be formed with the given points, or making a circle with them something.. I dont have any clue how to check all the points.

Question found in http://introcs.cs.princeton.edu/java/42sort/

I found this question in a renowned algorithm book that means it is answerable, but I cannot think of an optimal solution, thats why I am posting it here so that if some one knows it he/she can answer it

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So, exactly, what is your point? –  TheTerribleSwiftTomato Apr 8 '12 at 22:23
You keep posting questions with very little (if any) prior research. –  assylias Apr 8 '12 at 22:25
I did search for it, went through some classic geometry questions, studied topcoder tutorials, couldnt find it anything anywhere.. –  learner Apr 8 '12 at 22:26
Then show your work, please. Other people don't have random memory access to your head, they're unable to find out that you did work just by reading a post that contains only a question and a reference. I see you've edited it now to add an assertion of research being done. I believe you, but this is not sufficient - describe your research in detail. What solutions have you tried? Did you hit any snags? If so, what snags? Remember, until this point, to other posters, you're just a random dude on the Internet who says he did work, without showing any of it. –  TheTerribleSwiftTomato Apr 8 '12 at 22:37
any random point has an overwhelming probability of being non-colinear. –  andrew cooke Apr 8 '12 at 23:42
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The best I can come up with is an N^2 algorithm. Here goes:

1. Choose a tolerance e to control how close you're willing to come to a line formed from the points in the set.
2. Compute the convex hull of your set of points.
3. Choose a line L parallel to one of the sides of the convex hull, at a distance 3e outside the hull.
4. Choose a point P on L, so that P is outside the projection of the convex hull on L. The projection of the convex hull on L is an interval of L. P must be placed outside this interval.
5. Test each pair of points in the set. For a particular line M formed by the 2 test points intersects a disc of radius 2e around P, move P out further along L until M no longer intersects the disc. By the construction of L, there can be no line intersecting the disk parallel to L, so this can always be done.
6. If M crosses L beyond P, move P beyond that intersection, again far enough that M doesn't pass through the disc.
7. After all this is done, choose your point at distance e, on the perpendicular to L at P. It can be colinear with no line of the set.

I'll leave the details of how to choose the next position of P along L in step 5 to you,

There are some obvious trivial rejection tests you can do so that you do more expensive checks only with the test line M is "parallel enough" to L.

Finally, I should mention that it is probably possible to push P far enough out that numerical problems occur. In that case the best I can suggest is to try another line outside of the convex hull by a distance of at least 3e.

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