From Python: tf-idf-cosine: to find document similarity , it is possible to calculate document similarity using tf-idf cosine. Without importing external libraries, are that any ways to calculate cosine similarity between 2 strings?

s1 = "This is a foo bar sentence ."
s2 = "This sentence is similar to a foo bar sentence ."
s3 = "What is this string ? Totally not related to the other two lines ."

cosine_sim(s1, s2) # Should give high cosine similarity
cosine_sim(s1, s3) # Shouldn't give high cosine similarity value
cosine_sim(s2, s3) # Shouldn't give high cosine similarity value
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    I don't have the answer, but something like word2vec (code.google.com/p/word2vec) would probably be a good start if you want meaningful results. – static_rtti Sep 19 '15 at 18:53
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    @static_rtti word2vec has got nothing to do with cosine similarity. Thats about embeddings. Here he is giving the two strings from which he wants to calculate cosine similarity. – mithunpaul May 8 at 23:57
up vote 120 down vote accepted

A simple pure-Python implementation would be:

import re, math
from collections import Counter

WORD = re.compile(r'\w+')

def get_cosine(vec1, vec2):
     intersection = set(vec1.keys()) & set(vec2.keys())
     numerator = sum([vec1[x] * vec2[x] for x in intersection])

     sum1 = sum([vec1[x]**2 for x in vec1.keys()])
     sum2 = sum([vec2[x]**2 for x in vec2.keys()])
     denominator = math.sqrt(sum1) * math.sqrt(sum2)

     if not denominator:
        return 0.0
     else:
        return float(numerator) / denominator

def text_to_vector(text):
     words = WORD.findall(text)
     return Counter(words)

text1 = 'This is a foo bar sentence .'
text2 = 'This sentence is similar to a foo bar sentence .'

vector1 = text_to_vector(text1)
vector2 = text_to_vector(text2)

cosine = get_cosine(vector1, vector2)

print 'Cosine:', cosine

Prints:

Cosine: 0.861640436855

The cosine formula used here is described here.

This does not include weighting of the words by tf-idf, but in order to use tf-idf, you need to have a reasonably large corpus from which to estimate tfidf weights.

You can also develop it further, by using a more sophisticated way to extract words from a piece of text, stem or lemmatise it, etc.

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    How about "Felines feed on mice" and "Rodents are often eaten by cats"? You code incorrectly returns 0. – mbatchkarov Mar 3 '13 at 0:47
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    Surely, an SO question is not the place to definitively solve the problem of modelling semantic similarity of sentences. The question is about measuring (surface) similarity between two bits of text, that's what the code does. – vpekar Mar 3 '13 at 14:57
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    The code returns 0, correctly, because it measures surface similarity of two texts, it does not measure meaning as such. – vpekar Mar 3 '13 at 15:06
  • I agree with your first point and disagree with the second. SO is not for long and theoretical scientific discussions, which is why I refrained from talking about the technical side. While your answer is to the point and correct, the question is clearly not about surface similarity. Please have another look at the example sentences in the question. – mbatchkarov Mar 3 '13 at 21:00
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    You asked specifically about cosine. I answered specifically that question. The cosine is implemented as "realistically" as you can possibly get. If you mean to say, "how to do better than cosine to measure similarity", then it's a different question. – vpekar Mar 4 '13 at 13:46

The short answer is "no, it is not possible to do that in a principled way that works even remotely well". It is an unsolved problem in natural language processing research and also happens to be the subject of my doctoral work. I'll very briefly summarize where we are and point you to a few publications:

Meaning of words

The most important assumption here is that it is possible to obtain a vector that represents each word in the sentence in quesion. This vector is usually chosen to capture the contexts the word can appear in. For example, if we only consider the three contexts "eat", "red" and "fluffy", the word "cat" might be represented as [98, 1, 87], because if you were to read a very very long piece of text (a few billion words is not uncommon by today's standard), the word "cat" would appear very often in the context of "fluffy" and "eat", but not that often in the context of "red". In the same way, "dog" might be represented as [87,2,34] and "umbrella" might be [1,13,0]. Imagening these vectors as points in 3D space, "cat" is clearly closer to "dog" than it is to "umbrella", therefore "cat" also means something more similar to "dog" than to an "umbrella".

This line of work has been investigated since the early 90s (e.g. this work by Greffenstette) and has yielded some surprisingly good results. For example, here is a few random entries in a thesaurus I built recently by having my computer read wikipedia:

theory -> analysis, concept, approach, idea, method
voice -> vocal, tone, sound, melody, singing
james -> william, john, thomas, robert, george, charles

These lists of similar words were obtained entirely without human intervention- you feed text in and come back a few hours later.

The problem with phrases

You might ask why we are not doing the same thing for longer phrases, such as "ginger foxes love fruit". It's because we do not have enough text. In order for us to reliably establish what X is similar to, we need to see many examples of X being used in context. When X is a single word like "voice", this is not too hard. However, as X gets longer, the chances of finding natural occurrences of X get exponentially slower. For comparison, Google has about 1B pages containing the word "fox" and not a single page containing "ginger foxes love fruit", despite the fact that it is a perfectly valid English sentence and we all understand what it means.

Composition

To tackle the problem of data sparsity, we want to perform composition, i.e. to take vectors for words, which are easy to obtain from real text, and to put the together in a way that captures their meaning. The bad news is nobody has been able to do that well so far.

The simplest and most obvious way is to add or multiply the individual word vectors together. This leads to undesirable side effect that "cats chase dogs" and "dogs chase cats" would mean the same to your system. Also, if you are multiplying, you have to be extra careful or every sentences will end up represented by [0,0,0,...,0], which defeats the point.

Further reading

I will not discuss the more sophisticated methods for composition that have been proposed so far. I suggest you read Katrin Erk's "Vector space models of word meaning and phrase meaning: a survey". This is a very good high-level survey to get you started. Unfortunately, is not freely available on the publisher's website, email the author directly to get a copy. In that paper you will find references to many more concrete methods. The more comprehensible ones are by Mitchel and Lapata (2008) and Baroni and Zamparelli (2010).


Edit after comment by @vpekar: The bottom line of this answer is to stress the fact that while naive methods do exist (e.g. addition, multiplication, surface similarity, etc), these are fundamentally flawed and in general one should not expect great performance from them.

  • Out of curiosity, what approach did you use to build the thesaurus? – JesseBuesking Jun 18 '13 at 19:33
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    It's a distributional thesaurus, built with Byblo. In this particular instantiation each token has as features the other tokens that occurs in window of 5 words around it in all of Wikipedia, and similarity is calculated based on these features. We've built other thesauri where the features are the other words the target word has grammatical relations with. This generally works better, but requires at least a partial parse of the corpus, which takes a long time. – mbatchkarov Jun 18 '13 at 21:45
  • Why cannot we use RNN to handle composition? This way we'd take into account words order as well as their individual meaning. – Oleg Afanasyev Jun 1 at 19:33
  • Sure, you can. This answer is now over 5 years old. At the time RNNs were just starting to get big (again) and weren't really on my radar – mbatchkarov Jun 2 at 20:43

Thanks @vpekar for your implementation. It helped a lot. I just found that it misses the tf-idf weight while calculating the cosine similarity. The Counter(word) returns a dictionary which has the list of words along with their occurence.

cos(q, d) = sim(q, d) = (q · d)/(|q||d|) = (sum(qi, di)/(sqrt(sum(qi2)))*(sqrt(sum(vi2))) where i = 1 to v)

  • qi is the tf-idf weight of term i in the query.
  • di is the tf-idf
  • weight of term i in the document. |q| and |d| are the lengths of q and d.
  • This is the cosine similarity of q and d . . . . . . or, equivalently, the cosine of the angle between q and d.

Please feel free to view my code here. But first you will have to download the anaconda package. It will automatically set you python path in Windows. Add this python interpreter in Eclipse.

Well, if you are aware of word embeddings like Glove/Word2Vec/Numberbatch, your job is half done. If not let me explain how this can be tackled. Convert each sentence into word tokens, and represent each of these tokens as vectors of high dimension (using the pre-trained word embeddings, or you could train them yourself even!). So, now you just don't capture their surface similarity but rather extract the meaning of each word which comprise the sentence as a whole. After this calculate their cosine similarity and you are set.

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