# FInding a lower bound for a nlogn algorithm

The original problem was discussed in here: Algorithm to find special point k in O(n log n) time

Simply we have an algorithm that finds whether a set of points in the plane has a center of symmetry or not.

I wonder is there a way to prove a lower bound (nlogn) to this algorithm? I guess we need to use this algorithm to solve a simplier problem, such as sorting, element uniqueness, or set uniqueness, therefore we can conclude that if we can solve e.g. element uniqueness by using this algorithm, it can be at least nlogn.

It seems like the solution is something to do with element uniqueness, but i couldn't figure out a way to manipulate this into center of symmetry algorithm.

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Check this paper

The idea is if we can reduce problem A to problem B, then B is no harder than A.

That said, if problem B has lower bound Ω（nlogn）, then problem A is guaranteed the same lower bound.

In the paper, the author picked the following relatively approachable problem to be B: given two sets of n real numbers, we wish to decide whether or not they are identical.

It's obvious that this introduced problem has lower bound Ω（nlogn）. Here's how the author reduced our problem at hand to the introduced problem (A, B denote the two real sets in the following context):

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While this may theoretically answer the question, it would be preferable to include the essential parts of the answer here, and provide the link for reference. –  Bill the Lizard Oct 6 '11 at 0:44
@BilltheLizard Thanks for reminding me. –  Terry Li Oct 6 '11 at 1:56

First observe that that your magical point k must be in the center.

• build a lookup data structure indexed by vector position (O(nlog n))
• calculate the centroid of the set of points (O(n))
• for each point, calculate the vector position of its opposite and check for its existence in the lookup structure (O(log n) * n)

Appropriate lookup data structures can include basically anything that allows you to look something up efficiently by content, including balanced trees, oct-trees, hash tables, etc.

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For this problem oct-tree of boundary box has k as split point in root node. All of these tests can be done while building oct-tree, so there is no need for final oct-tree data structure at all :-) –  Ante Oct 5 '11 at 8:01
Strictly speaking, the lower bound is not O(nlogn), because a hash table can be O(n). –  mpm Oct 7 '11 at 0:18
Ante: you're incorrect. You must build a lookup structure so that when you're testing whether the millionth entry has an opposite, you can do it in one lookup rather than 999999. If you're clever, you can find k first, then delete pairs when you find them while build the table. If the table is empty at the end, you win. But the table can still grow to size N/2 in the middle. It doesn't matter whether the oct-tree is centered on k, what matters is that lookup is O(log(n)), not O(n). –  mpm Oct 7 '11 at 0:22