I know the complexity is O(nlog(n)). But why? How do you come to this answer?
Any help would be much appreciated, I'm very interested to know!
I know the complexity is O(nlog(n)). But why? How do you come to this answer?
Any help would be much appreciated, I'm very interested to know!
Its average case complexity is considered to be O(n log(n))
, whereas in the worst case it takes O(n^2)
(quadratic).
Consider the following pseudo-code:
QuickHull (S, l, r)
if S={ } then return ()
else if S={l, r} then return (l, r) // a single convex hull edge
else
z = index of a point that is furthest (max distance) from xy.
Let A be the set containing points strictly right of (x, z)
Let B be the set containing points strictly right of (z, y)
return {QuickHull (A, x, z) U (z) U QuickHull (B, z, y)}
The partition is determined by the line passing through two distinct extreme points: the rightmost lowest r
and the leftmost highest points l
. Finding the extremes require O(n)
time.
For the recursive function, it takes n
steps to determine the extreme point z
, but the cost of recursive calls depends on the sizes of set A
and set B
.
Best case. Consider the best possible case, when each partition is almost balanced. Then we have
T(n) = 2 T(n/2) + O(n)
.
This is a familiar recurrence relation, whose solution is
T(n) = O(n log(n))
.
This would occur with randomly distributed points.
Worst case. The worst case occurs when each partition is an extremely unbalanced. In that case the recurrence relation is
T(n) = T(n-1) + O(n)
= T(n-1) + cn
Repeated expansion shows this is O(n^2)
. Therefore, in the worst case the QuickHull is quadratic.
http://www.personal.kent.edu/~rmuhamma/Compgeometry/MyCG/ConvexHull/quickHull.htm