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I have a what I think is a simple machine learning question.

Here is the basic problem: I am repeatedly given a new object and a list of descriptions about the object. For example: new_object: 'bob' new_object_descriptions: ['tall','old','funny']. I then have to use some kind of machine learning to find previously handled objects that have the 10 or less most similar descriptions, for example, past_similar_objects: ['frank','steve','joe']. Next, I have an algorithm that can directly measure whether these objects are indeed similar to bob, for example, correct_objects: ['steve','joe']. The classifier is then given this feedback training of successful matches. Then this loop repeats with a new object. a Here's the pseudo-code:


while True:
    new_object,new_object_descriptions = get_new_object_and_descriptions()
    past_similar_objects = Classifier.classify(new_object,new_object_descriptions)
    correct_objects = calc_successful_matches(new_object,past_similar_objects)

But, there are some stipulations that may limit what classifier can be used:

  • There will be millions of objects put into this classifier so classification and training needs to scale well to millions of object types and still be fast. I believe this disqualifies something like a spam classifier that is optimal for just two types: spam or not spam. (Update: I could probably narrow this to thousands of objects instead of millions, if that is a problem.)

  • Again, I prefer speed when millions of objects are being classified, over accuracy.

  • Update: The classifier should return the 10 (or fewer) most similar objects, based on feedback from past training. Without this limit, an obvious cheat would be for the classifier could just return all past objects :)

What are decent, fast machine learning algorithms for this purpose?

Note: The calc_successful_matches distance metric is extremely expensive to calculate and that's why I'm using a fast machine learning algorithm to try to guess which objects will be close before I actually do the expensive calculation.

share|improve this question
A word of caution: as you describe your algorithm, you're failing to provide feedback on items that were omitted. I.e., perhaps correct_objects equaled ['steve', 'joe', 'dan'] in the example you provided. Perhaps this is necessary due to computational constraints, but make sure it is intentional. – Ben Hocking Mar 25 '10 at 23:43
I am specifically limiting the calc_successful_matches to checking if any of past_similar_objects are similar enough to new_object. If none of them are, the list returned will be empty. – user213060 Mar 26 '10 at 1:19

An algorithm that seems to meet your requirements (and is perhaps similar to what John the Statistician is suggesting) is Semantic Hashing. The basic idea is that it trains a deep belief network (a type of neural network that some have called 'neural networks 2.0' and is a very active area of research right now) to create a hash of the list of descriptions of an object into binary number such that the Hamming distance between the numbers correspond to similar objects. Since this just requires bitwise operations it can be pretty fast, and since you can use it to create a nearest neighbor-style algorithm it naturally generalizes to a very large number of classes. This is very good state of the art stuff. Downside: it's not trivial to understand and implement, and requires some parameter tuning. The author provides some Matlab code here. A somewhat easier algorithm to implement and is closely related to this one is Locality Sensitive Hashing.

Now that you say that you have an expensive distance function you want to approximate quickly, I'm reminded of another very interesting algorithm that does this, Boostmap. This one uses boosting to create a fast metric which approximates an expensive to calculate metric. In a certain sense it's similar to the above idea but the algorithms used are different. The authors of this paper have several papers on related techniques, all pretty good quality (published in top conferences) that you might want to check out.

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The good thing about semantic hashing is that it will also learn if attributes are similar. So if "tall" and "heavy" correlate, the network will actually notice. It is also extremly fast because its basically only matrix multiplications and element wise function application. – bayer Mar 26 '10 at 8:24
Yeah, it's definitely one of those "I wish I would have thought of that" ideas. – dimatura Mar 26 '10 at 16:01
I did also think about recommending semantic hashing, or something similar that also involves restricted Boltzman machines. The thing is, I wasn't sure when I would stop having to add nodes for similar people, and a vector space model would let me add people in a scalable way without having to represent them explicitly. Nonetheless, I give you a point, although I would still do it my way. – John with waffle Mar 28 '10 at 5:28
Actually, if you read the semantic hashing paper, something they are a little sneaky about is they do some preprocessing to limit the number of tags they are hashing to about the 1000 most important words. If you have to continue to learn "on the fly", you may have unexpected problems. – John with waffle Mar 28 '10 at 6:04
Yes, as usual in academic papers some details (that might be important for real world applications) are glossed over. But it's an interesting starting point. – dimatura Mar 28 '10 at 18:26

You could use the vector space model ( I think what you are trying to learn is how to weight terms in considering how close two object description vectors are to each other, say for example in terms of a simplified mutual information. This could be very efficient as you could hash from terms to vectors, which means you wouldn't have to compare objects without shared features. The naive model would then have an adjustable weight per term (this could either be per term per vector, per term overall, or both), as well as a threshold. The vector space model is a widely used technique (for example, in Apache Lucene, which you might be able to use for this problem), so you'll be able to find out a lot about it through further searches.

Let me give a very simple formulation of this in terms of your example. Given bob: ['tall','old','funny'], I retrieve

frank: ['young','short,'funny'] steve: ['tall','old','grumpy'] joe: ['tall','old']

as I am maintaining a hash from funny->{frank,...}, tall->{steve, joe,...}, and old->{steve, joe,...}

I calculate something like the overall mutual information: weight of shared tags/weight of bob's tags. If that weight is over the threshold, I include them in the list.

When training, if I make a mistake I modify the shared tags. If my error was including frank, I reduce the weight for funny, while if I make a mistake by not including Steve or Joe, I increase the weight for tall and old.

You can make this as sophisticated as you'd like, for example by including weights for conjunctions of terms.

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SVM is pretty fast. LIBSVM for Python, in particular, provides a very decent implementation of Support Vector Machine for classification.

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+1 for SVM suggestion. – Peter K. Mar 26 '10 at 1:32
The problem with SVM is that it in its most basic form it is a binary classifier. To make it multiclass is not trivial; a one versus all approach would require one SVM per class, which is unfeasible for a large number of classes. A possible solution is to use Error Correcting Output Coding (ECOC), but that still requires approximately log(number of classes) SVM classifiers. – dimatura Mar 26 '10 at 2:34
SVM would be inappropriate. His outlined procedure appears to require online/incremental training. As far as I know, all SVM implementations only support offline/batch mode training. – Cerin Mar 26 '10 at 12:21

do you really need a machine learning algorithm for this? What is your metric for similarity? You've mentioned the dimensionality of the number of objects, what about the size of the trait set for each person? Are there a maximum number of trait types? I might try something like this:

1) Have a dictionary mapping trait to a list of names named map

for each person p

for each trait t in p


2) then when I want to find the closest person, I'd take my dictionary and create a new temp one:

dictionary mapping name to count called cnt

for each trait t in my person of interest

for each person p in map[t]


then the entry with the highest count is closest

The benefit here is the map is only created once. if the traits per person is small, and the types of available traits are large, then the algorithm should be fast.

share|improve this answer
This is essentially the easiest implementation of the vector-space approach. Congratulations, you now know machine learning. – John with waffle Mar 26 '10 at 1:12
interesting, didn't know that counted. :) – tbischel Mar 26 '10 at 1:26
The actual distance metric is extremely expensive to calculate and that's why I'm using a machine learning algorithm to first try to guess what objects are likely to be close before calculating it directly. – user213060 Mar 26 '10 at 1:28
isn't this also called an inverse index ? and the second step is a basic scalar product (counting common binary dimensions of your vectors), if you could normalize that, you could call it a cosine similarity – bendaizer Feb 28 '13 at 16:30

This project departs from typical classification applications in two notable ways:

  • Rather than outputting the class which the new object is thought to belong to (or possibly outputting an array of these classes, each with probability / confidence level), the "classifier" provides a list of "neighbors" which are "close enough" to the new object.
  • With each new classification, an objective function, independent from the classifier, provides the list of the correct "neighbors"; in turn the corrected list (a subset of the list provided by the classifier ?) is then used to train the classifier

The idea behind the second point is probably that future objects submitted to the classifier and with similar to the current object should get better "classified" (be associated with a more correct set of previously seen objects) since the on-going training re-enforces connections to positive (correct) matches, while weakening the connection to objects which the classifier initially got wrong.

These two characteristics introduce distinct problems.
- The fact that the output is a list of objects rather than a "prototype" (or category identifier of sorts) make it difficult to scale as the number of objects seen so far grows toward the millions of instances as suggested in the question.
- The fact that the training is done on the basis of a subset of the matches found by the classifier, may introduce over-fitting, whereby the classifier could become "blind" to features (dimensions) which it, accidentally, didn't weight as important/relevant, in the early parts of the training. (I may be assuming too much with regards to the objective function in charge of producing the list of "correct" objects)

Possibly, the scaling concern could be handled by having a two-step process, with a first classifier, based the K-Means algorithm or something similar, which would produce a subset of the overall object collection (of objects previously seen) as plausible matches for the current object (effectively filtering out say 70% or more of collection). These possible matches would then be evaluated on the basis of Vector Space Model (particularly relevant if the feature dimensions are based on factors rather than values) or some other models. The underlying assumption for this two-step process is that the object collection will effectively expose clusters (it may just be relatively evenly distributed along the various dimensions).

Another way to further limit the number of candidates to evaluate, as the size of the previously seen objects grows, is to remove near duplicates and to only compare with one of these (but to supply the full duplicate list in the result, assuming that if the new object is close to the "representative" of this near duplicate class, all members of the class would also match)

The issue of over-fitting is trickier to handle. A possible approach would be to [sometimes] randomly add objects to the matching list which the classifier would not normally include. The extra objects could be added on the basis of their distance relative distance to the new object (i.e. making it a bit more probable that a relatively close object be added)

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This reiterates some of the parts of the problem that I was trying to explain very well. Thanks. Yes, I understand that a fast classification will be prone to overfitting and likely to arrive at a suboptimal solution. This is a tradeoff I am willing to accept. – user213060 Mar 26 '10 at 1:37
@user213060: overfitting is not so much due to the choice of a fast classifier, but to the on-going training with potentially biased "training data" (if as I think, the calc_successful_matches function produces a subset of the matches returned by the classifier). – mjv Mar 26 '10 at 1:58

What you describe is somewhat similar to the Locally Weighted Learning algorithm, which given a query instance, it trains a model locally around the neighboring instances weighted by their distances to the query one.

Weka (Java) has an implementation of this in weka.classifiers.lazy.LWL

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The problem with this approach is that it would be extremely slow, because of all the model building required. The local model adds accuracy, but the OP favors a faster classifier even if less accurate. – dimatura Mar 26 '10 at 3:05

deep learning can be used. just go through this link

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