As far as I can tell, Taylor & Drummond (2011) do not purport to give an O(*n*) algorithm for *finding* the pair of bitstrings in an array with the largest number of common set bits. They sketch an argument that a record of the best such pairs can be *updated* in O(*n*) after a new bitstring has been added to the array (and two old bitstrings removed).

Certainly the explanation of the algorithm on page 252 is not very clear, and I think their sketch argument that the record can be updated in O(*n*) is incomplete at best, so I can see why you are confused.

Anyway, here's my best attempt to explain Algorithm 1 from the paper.

### Algorithm

The algorithm takes an array of bitstrings and constructs a *lookup tree*. A lookup tree is a binary forest (set of binary trees) whose leaves are the original bitstrings from the array, whose internal nodes are new bitstrings, and where if node A is a parent of node B, then A & B = A (that is, all the set bits in A are also set in B).

For example, if the input is this array of bitstrings:

then the output is the lookup tree:

The algorithm as described in the paper proceeds as follows:

Let *R* be the initial set of bitstrings (the *root set*).

For each bitstring *f1* in *R* that has no partner in *R*, find and record its *partner* (the bitstring *f2* in *R* − {*f1*} which has the largest number of set bits in common with *f1*) and record the number of bits they have in common.

If there is no pair of bitstrings in *R* with any common set bits, stop.

Let *f1* and *f2* be the pair of bitstrings in *R* with the largest number of common set bits.

Let *p* = *f1* & *f2* be the *parent* of *f1* and *f2*.

Remove *f1* and *f2* from *R*; add *p* to *R*.

Go to step 2.

### Analysis

Suppose that the array contains *n* bitstrings of fixed length. Then the algorithm as described is O(*n*^{3}) because step 2 is O(*n*^{2}), and there are O(*n*) iterations, because at each iteration we remove two bitstrings from *R* and add one.

The paper contains an argument that step 2 is Ω(*n*^{2}) only on the first time around the loop, and on other iterations it is O(*n*) because we only have to find the partner of *p* "and any other bitstrings in *R* whose partner was one of the two selected for combination." However, this argument is not convincing to me: it is not clear that there are only O(1) other such bitstrings. (Maybe there's a better argument?)

We could bring the algorithm down to O(*n*^{2}) by storing the number of common set bits between every pair of bitstrings. This requires O(*n*^{2}) extra space.

### Reference

- S. Taylor & T. Drummond (2011). "Binary Histogrammed Intensity Patches for Efficient and Robust Matching".
*Int. J. Comput. Vis.* 94:241–265.

in each iteration(and by "O" they seem to mean "Ω") — so I think their algorithm is Ω(n²) overall. – Gareth Rees Aug 26 '12 at 12:07lowerbounds on the asymptotic performance of algorithms (big-O notation is forupperbounds). To be precise, they ought to write "Ω" in these places instead of "O". But this a very common kind of sloppiness and it's clear in practice what they mean, so it's not worth making a big fuss about it. – Gareth Rees Aug 26 '12 at 21:02