Build an undirected weighted graph by matching N vertices

Problem:
I want to suggest the top 10 most compatible matches for a particular user, by comparing his/her 'interests' with interests of all others. I'm building an undirected weighted graph between users, where the weight = match score between the two users.

I already have a set of N users: S. For any user U in S, I have a set of interests I. After a long time (a week?) I create a new user U with a set of interests and add it to S. To generate a graph for this new user, I'm comparing interest set I of the new user with the interest sets of all the users in S, iteratively. The problem is with this "all the users" part.

Let's talk about the function for comparing interests. An interest in a set of interests I is a string. I'm comparing two strings/interests using WikipediaMiner (it uses Wikipedia links to infer how closely related two strings are. eg. Billy Jean & Thriller ==> high match, Brad Pitt & Jamaica ==> low match blah blah). I've asked a question about this too (to see if there's a better solution than the one I'm currently using.

So, the above function takes non-negligible time, and in total, it'll take a HUGE time when we compare thousands (maybe millions?) of users and their hundreds of interests. For 100,000 users, I can't afford to make 100,000 user comparisons in a small time (<30sec) in this way. But, I have to give the top 10 recommendations within 30 secs, possibly a preliminary recommendation, and then improve on it in the next 1 min or so, calculate improved recommendations. Simply comparing 1 user vs the N users sequentially is too slow.

Question:
Please suggest an algorithm, method or tool using which I can improve my situation or solve my problem.

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I could think of only an approach to solve the problem, since the outcomes of below stuff depend on the nature of inter-relation between interests.

=>step:1 As your title says.Build an undirected weighted graph with interests as vertices and the weighted match between them as edges.

=>step:2 - cluster the interests. (Most complex)

Kmeans is a commonly used clustering algo, but works on based on K-Dimensional vector space.refer wiki to see how K-means works. it minimizes the sum of (sum of distance^2 for each point and say the center of the cluster) for all clusters. In your case, there are no dimensions available. so try if you can apply the minimizing logic applied there by creating some kind of rule, for distance between two vertices, higher match => lesser distance and vice versa (what are the different matching levels provided by wiki-miner?). chose the Mean of cluster as say the most connected vertex in the chosen set, page ranking sounds to be a good option for "figuring the most connected vertex ".

"Pair-counting F-Measure" sounds like it suit's your need (weighted graph), check for other options available.

(Note: keep modifying this step untill a right clustering algo is found and the right calibration for distance rule, no of clusters etc are found. )

=>Step:3 - Evaluate the clusters

from here on its like calibrating a couple things to fit your need. Examine the clusters, reevaluate : the number of clusters , inter-cluster distance, distance between vertices inside clusters, size of clusters, time\precision trade-off (compare final - match results without any clustring) goto: step-2 untill this evaluation is satisfactory.

=>step:4 - Examinie new inerest

iterate thru all clusters, calculate conectivity in each cluster, sort clusters based on high connectivity, for the top x% of sorted clusters sort and filter out the highly connected interests.

=>step:5 - Match User

reverse look up set of all users using the interests obtained out of step-4, compare all interests for both users, generate a score.

=>step:6 - Apart form the above you can distribute the load (multiple machines can be used for clusters machine-n clusters) to multiple systems\processors, based on the traffic and stuff.

what is the application for this problem, whats the expected traffic?

Another solution to find the connectivity between the new interest and "set of interests in Cluster" C. Wiki-Miner runs on a set of wiki documents, let me call it the UNIVERSE.

1:for each cluster fetch and maintain(index, lucene might be handy) the "set of high relevent docs"(I am calling it HRDC) out of the UNIVERSE. so you have 'N' HRDC's if you got 'N' clusters.

2:when a new interest comes find "Conectivity with Cluster" = "Hit ratio of interest in HRDC/Hit ratio of interest in UNIVERSE" for each HRDC.

3:Sort "Conectivity with Cluster"'s and choose the Highly connected clusters.

4:Either compare all the vertices in the cluster with the new interest or the highly connected vertices (using Page Ranking), depending on the time\Precision trade off , that suits you.

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Ah! Simplifying what you said, the whole set is clustered, and when a new user comes in, rather than comparing his/her interests with every other interest in the main set, I calculate how well it matches with each cluster, iterating through them. Once I find the one having the best connectivity, I reverse look up the users having interests in that cluster. ==> Lesser comparisons. But, the part I couldn't figure out - "calculate conectivity in each cluster" - how do I do that? Do I need to "label" each cluster with a tag, and then compare the interest string with that tag? –  Nilesh Jan 11 '13 at 6:46
for each cluster have a "set of vertices with high connectivity" HCI, say X% of vertices in each cluster. Compare the new interest with all these vertices. How do you obtain HCI? -> apply Page Ranking within the cluster to select HCI. –  karthitoo Jan 11 '13 at 7:26
Probably wise to use the inverse of the result of the interest comparison between them as the distance. –  Nuclearman Jan 11 '13 at 22:13
yes , 1/X could be one, (C - X) can be another, depends on range of MATCH values provided by Wiki-Minor and at some point we might want to say 2 vertices are not at all connected, we don't want a graph with all vertices connected to every other vertex. for a start we can choose inverse, with limiting condition, if (Match > LOWEST_MATCH) { distance = 1/Match; } else { distance = infinity; } but for this problem i feel the algo will get modified(a lot) based on the nature of connectivity, and clusters that's obtained. ...a really interesting problem to think\talk about. –  karthitoo Jan 14 '13 at 14:28

One flaw is that your basing your algorithms complexity on the wrong thing. The real issue is that you have to compare each unique interest against every other unique interest (and that interest against itself).

If all of the interests are unique, then there is probably nothing you can do. However, if you have a lot of duplicate interests you can perhaps speed up the algorithm this way by the following.

1. Create a graph that associates each interest with the users that have that interest. In such a way that allows for fast look-ups.

2. Create a graph that shows how each interest relates to each other interest, also in such a way that allows for fast look-ups.

Therefore, when a new user is added, their interests are compared to all other interest and stored in a graph. You can then use that information to build to build a list of users with similar interests. That list of users will then need to be filtered somehow to bring it down to the top 10.

Finally, add that user and their interests to the graph of users and interests. This is done last so that the user with the most closely matched interests isn't the user themselves.

Note: There might be some statistical short cuts that you could do something like this: A is related to B, B is related to C, C is related to D, therefore A is related to B, C, and D. However, to use those kinds of short cuts likely requires a much better understanding of how your comparison function works, which is a bit beyond my expertise.

Approximate solution:

I forgot to mention it earlier, but what your looking when comparing users or interests is a "Nearest neighbor search" in higher dimensions. Meaning, that for exact solutions, a linear search generally works better than data structures. So approximation is probably the best way to go if you need it faster.

To obtain a quick approximate solution (without guarantees as to how close it is), you'll need a data structure that allows for quickly being able to determine which users are likely to be similar to a new user.

One way to build that structure:

1. Pick 300 random users. These will be the seed users for 300 clusters. Ideally, you'd use the 300 users that are least closely related, but that's probably not practical, still might be wise to ensure that the no seed user is too closely related to the other users (as a sum or average of it's comparison's to other users).
2. The clusters are then filled by each user joining the cluster whose representative user most closely matches it.
3. The top ton can then be determined by picking the top 10 users most closely related users from that cluster.

If you ensure that the number of clusters and the users per cluster is always fairly close to sqrt(number of users), then you obtain a fair approximation in O(sqrt(N)) by only checking the points within the cluster. You can improve that approximation by including users in additional clusters and checking the representative users for each cluster. The more clusters you check, the closer you get towards O(N) and an exact solution. Although, there's probably no way to say how close the current solution is to the exact solution. Chances are you start to hit dimishing returns after checking more than a total of log(sqrt(N)) clusters total. Which would put you at O(sqrt(N) log(sqrt(N))).

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Thank you, I had already thought about both the points you mentioned. About the interests - there will probably be 70 repetitions per 1000 interests. Do you think it'll be wise to go with the graph idea for a ratio like this? (Consider we have a million interests) –  Nilesh Jan 9 '13 at 12:28
Well a million squared is 10^12, if 7 percent of those are repetitions, then you can bring it down to 8.649^11. So something like a 13.5% drop in run time. It'll be a less due to making the graphs, but probably still in that range. Either way, it's not going to affect the overall run-time much, although perhaps that's enough to be worth the trouble. That decision is up to you. –  Nuclearman Jan 9 '13 at 20:11
Your only other possibility is that you might be able to create some sort of data structure that groups "similar" interests together. However, in that case, you're probably looking actually duplicating interest by a lot. However, if you could get it to work. Then you get A related to B, C, D effect I mentioned. That's probably you're only real chance at an algorithm better than O(N^2) at this point. Probably worth asking this question on Cross Validated, or re-ask this question in terms of a data structure to organize the interests. –  Nuclearman Jan 9 '13 at 20:17
Oh wait, one more thing. Do you need an exact algorithm or an approximate one? As if you allow for some approximation, you should be able to get a linear result. The only issue being if the approximation is good enough. –  Nuclearman Jan 9 '13 at 20:19
'some sort of data structure that groups "similar" interests together' --> I see, I'll think about this. :/ An approximate one will work, I don't need anything exact or perfect, but of course, preserving a certain quality of matches. –  Nilesh Jan 10 '13 at 12:29