# How to find two most distant points?

This is a question that I was asked on a job interview some time ago. And I still can't figure out sensible answer.

Question is:

you are given set of points (x,y). Find 2 most distant points. Distant from each other.

For example, for points: (0,0), (1,1), (-8, 5) - the most distant are: (1,1) and (-8,5) because the distance between them is larger from both (0,0)-(1,1) and (0,0)-(-8,5).

The obvious approach is to calculate all distances between all points, and find maximum. The problem is that it is O(n^2), which makes it prohibitively expensive for large datasets.

There is approach with first tracking points that are on the boundary, and then calculating distances for them, on the premise that there will be less points on boundary than "inside", but it's still expensive, and will fail in worst case scenario.

Tried to search the web, but didn't find any sensible answer - although this might be simply my lack of search skills.

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Was "some time ago" on the order of one hour? ;-) –  Marcelo Cantos Apr 29 '10 at 9:56
If you can do the sorting in O(nlogn), try to use it. –  Gabriel Ščerbák Apr 29 '10 at 10:01
What do you mean, Gabriel? Sort by what? –  Marcelo Cantos Apr 29 '10 at 10:04
You cannot "sort" a multidimensional space, or more precisely, you can sort it in many different ways –  fortran Apr 29 '10 at 10:06
@Marcelo - no. closer to 3 years. –  user80168 Apr 29 '10 at 10:11

EDIT: One way is to find the convex hull http://en.wikipedia.org/wiki/Convex_hull of the set of points and then the two distant points are vertices of this.

Also:

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That questions is about graph algorithms, not computational geometry, isn't it? –  Pavel Shved Apr 29 '10 at 10:07
you can model the problem as a complete weighted graph –  jk. Apr 29 '10 at 10:22
good answer, I like it. –  ldog Apr 29 '10 at 16:57

Boundary point algorithms abound (look for convex hull algorithms). From there, it should take O(N) time to find the most-distant opposite points.

From the author's comment: first find any pair of opposite points on the hull, and then walk around it in semi-lock-step fashion. Depending on the angles between edges, you will have to advance either one walker or the other, but it will always take O(N) to circumnavigate the hull.

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Now assume all given N points are on the convex hull. Still O(N)? –  Pavel Shved Apr 29 '10 at 10:05
Yes, because you first find any pair of opposite points on the hull, and then walk around it in semi-lock-step fashion. Depending on the angles between vertices, you will have to advance either one walker or the other, but it will always take O(N) to circumnavigate the hull. –  Marcelo Cantos Apr 29 '10 at 10:15
Thanks Pavel! I was not trying to be dismissive, by the way (my last comment reads worse than I intended). It's just a fair bit of fiddly geometry and edge-cases to get it right. –  Marcelo Cantos Apr 29 '10 at 10:45
@Marcelo, oh, saying "complete algorithm" in computational geometry usually means "as complete as possible before it gets boring" :-) –  Pavel Shved Apr 29 '10 at 10:52
This has a name: en.wikipedia.org/wiki/Rotating_calipers –  Rafał Dowgird Apr 30 '10 at 14:37

This question is introduced at Introduction to Algorithm. It mentioned 1) Calculate Convex Hull O(NlgN). 2) If there is M vectex on Convex Hull. Then we need O(M) to find the farthest pair.

I find this helpful links. It includes analysis of algorithm details and program. http://www.seas.gwu.edu/~simhaweb/alg/lectures/module1/module1.html

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Just a few thoughts:

You might look at only the points that define the convex hull of your set of points to reduce the number,... but it still looks a bit "not optimal".

Otherwise there might be a recursive quad/oct-tree approach to rapidly bound some distances between sets of points and eliminate large parts of your data.

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A starting point could be looking at closest-point problems, which have been examined. Wikipedia lists some options:

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

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–  zaf Apr 29 '10 at 10:10
Well, the solutions for closest base on divide and conquer, and I have no idea how to apply it to finding the furthest apart points. –  user80168 Apr 29 '10 at 10:49

A stochastic algorithm to find the most distant pair would be

• Choose a random point
• Get the point most distant to it
• Repeat a few times
• Remove all visited points
• Choose another random point and repeat a few times.

You are in O(n) as long as you predetermine "a few times", but are not guaranteed to actually find the most distant pair. But depending on your set of points the result should be pretty good. =)

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Consider this, and then correct or delete your answer so you don't get downvotes: imagine you have an almost-square set of points, `{A=(0, 0), B=(10, 10), C=(10, 0), D=(0, 11)}`; most distant points are BD (distance = 14.86); but if you try to start at A or B you'll feel tempted to remove C (AC = BC = 10) or D (AD = 11, BD = 10.05) since they're closer to the chosen vertex than the opposite vertex (AC = 14.14), while in reality the longest distance is really 14.86 . –  ANeves Apr 29 '10 at 11:01
@sr pt: In your example, CD are the most distant points, not BD. Starting in A or B one would always choose the other in step 2, so only these two get removed in step 4. –  Jens Apr 29 '10 at 11:34

You are looking for an algorithm to compute the diameter of a set of points, Diam(S). It can be shown that this is the same as the diameter of the convex hull of S, Diam(S) = Diam(CH(S)). So first compute the convex hull of the set.

Now you have to find all the antipodal points on the convex hull and pick the pair with maximum distance. There are O(n) antipodal points on a convex polygon. So this gives a O(n lg n) algorithm for finding the farthest points.

This technique is known as Rotating Calipers. This is what Marcelo Cantos describes in his answer.

If you write the algorithm carefully, you can do without computing angles. For details, check this URL.

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