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Currently I'm studying how to find a nearest neighbor using Locality-sensitive hashing. However while I'm reading papers and searching the web I found two algorithms for doing this:

1- Use L number of hash tables with L number of random LSH functions, thus increasing the chance that two documents that are similar to get the same signature. For example if two documents are 80% similar, then there's an 80% chance that they will get the same signature from one LSH function. However if we use multiple LSH functions, then there's a higher chance to get the same signature for the documents from one of the LSH functions. This method is explained in wikipedia and I hope my understanding is correct:

http://en.wikipedia.org/wiki/Locality-sensitive_hashing#LSH_algorithm_for_nearest_neighbor_search

2- The other algorithm uses a method from a paper (section 5) called: Similarity Estimation Techniques from Rounding Algorithms by Moses S. Charikar. It's based on using one LSH function to generate the signature and then apply P permutations on it and then sort the list. Actually I don't understand the method very well and I hope if someone could clarify it.

My main question is: why would anyone use the second method rather than the first method? As I find it's easier and faster.

I really hope someone can help!!!

EDIT: Actually I'm not sure if @Raff.Edward were mixing between the "first" and the "second". Because only the second method uses a radius and the first just uses a new hash family g composed of the hash family F. Please check the wikipedia link. They just used many g functions to generate different signatures and then for each g function it has a corresponding hash table. In order to find the nearest neighbor of a point you just let the point go through the g functions and check the corresponding hash tables for collisions. Thus how I understood it as more function ... more chance for collisions.

I didn't find any mentioning about radius for the first method.

For the second method they generate only one signature for each feature vector and then apply P permutations on them. Now we have P lists of permutations where each contains n signatures. Now they then sort each list from P. After that given a query point q, they generate the signature for it and then apply the P permutations on it and then use binary search on each permuted and sorted P list to find the most similar signature to the query q. I concluded this after reading many papers about it, but I still don't understand why would anyone use such a method because it doesn't seem fast in finding the hamming distance!!!!

For me I would simply do the following to find the nearest neighbor for a query point q. Given a list of signatures N, I would generate the signature for the query point q and then scan the list N and compute the hamming distance between each element in N and the signature of q. Thus I would end up with the nearest neighbor for q. And it takes O(N)!!!

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1 Answer 1

Your understanding of the first one is a little off. The probability of a collision occurring is not proportional to the similarity, but whether or not it is less than the pre-defined radius. The goal is that anything within the radius will have a high chance of colliding, and anything outside the radius * (1+eps) will have a low chance of colliding (and the area in-between is a little murky).

The first algorithm is actually fairly difficult to implement well, but can get good results. In particular, the first algorithm is for the L1 and L2 (and technically a few more) metrics.

The second algorithm is very simple to implement, though a naive implementation may use up too much memory to be useful depending on your problem size. In this case, the probability of collision is proportional to the similarity of the inputs. However, it only works for the Cosine Similarity (or distance metrics based on a transform of the similarity.)

So which one you would use is based primarily on which distance metric you are using for Nearest Neighbor (or whatever other application).

The second one is actually much easier to understand and implement than the first one, the paper is just very wordy.

The short version: Take a random vector V and give each index a independent random unit normal value. Create as many vectors as you want the signature length to be. The signature is the signs of each index when you do a Matrix Vector product. Now the hamming distance between any two signatures is related to the cosine similarity between the respective data points.

Because you can encode the signature into an int array and use an XOR with a bit count instruction to get the hamming distance very quickly, you can get approximate cosine similarity scores very quickly.

LSH algorithms doesn't have a lot of standardization, and the two papers (and others) use different definitions, so its all a bit confusing at times. I only recently implemented both of these algorithms in JSAT, and am still working on fully understanding them both.

EDIT: Replying to your edit. The wikipedia article is not great for LSH. If you read the original paper, the first method you are talking about only works for a fixed radius. The hash functions are then created based on that radius, and concatenated to increase the probability of getting near by points in a collision. They then construct a system for doing k-NN on-top of this by determine the maximum value of k they wan, and then finding the largest reasonable distance they would find the k'th nearest neighbor in. In this way, a radius search will very likely return the set of k-NNs. To speed this up, they also create a few extra small radius since the density is often not uniform, and the smaller radius you use, the faster the results.

The wikipedia section you linked is taken from the paper description for the "Stable Distribution" section, which presents the hash function for a search of radius r=1.

For the second paper, the "sorting" you describe is not part of the hashing, but part of one-scheme for searching the hamming space more quickly. I as I mentioned, I recently implemented this, and you can see a quick benchmark I did using a brute force search is still much faster than the naive method of NN. Again, you would also pick this method if you need the cosine similarity over the L2 or L1 distance. You will find many other papers proposing different schemes for searching the hamming space created by the signatures.

If you need help convincing yourself fit can be faster even if you were still doing brute force - just look at it this way: Lets say that the average sparse document has 40 common words with another document (a very conservative number in my experience). You have n documents to compare against. Brute force cosine similarity would then involve about 40*n floating point multiplications (and some extra work). If you have a 1024 bit signature, thats only 32 integers. That means we could do a brute force LSH search in 32*n integer operations, which are considerably faster then floating point operations.

There are also other factors at play here as well. For a sparse data set we have to keep both the doubles and integer indices to represent the non zero indexes, so the sparse dot product is doing a lot of additional integer operations to see which indices they have in common. LSH also allows us to save memory, because we don't need to store all of these integers and doubles for each vector, instead we can just keep its hash around - which is only a few bytes. Reduced memory use can help us better exploit the CPU cache.

Your O(n) is the naive way I have used in my blog post. And it is fast. However, if you sort the bits before hand, you can do the binary search in O(log(n)). Even if you have L of these lists, L << n, and so it should be faster. The only issue is it gets you approximate hamming NN which are already approximating the cosine similarity, so the results can become a bit worse. It depends on what you need.

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could you please read the edited version of the post? –  Jack Twain Jun 24 '13 at 7:23
    
I've replied to your edit. I was not confused, the wiki article is not well organized to explain what is happening. –  Raff.Edward Jun 24 '13 at 20:50

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