How does it work

The word2vec tool takes a text corpus as input and produces the word vectors as output. It first constructs a vocabulary from the training text data and then learns vector representation of words. The resulting word vector file can be used as features in many natural language processing and machine learning applications.

A simple way to investigate the learned representations is to find the closest words for a user-specified word. The distance tool serves that purpose. For example, if you enter 'france', distance will display the most similar words and their distances to 'france', which should look like:

                 Word       Cosine distance
-------------------------------------------
                spain              0.678515
              belgium              0.665923
          netherlands              0.652428
                italy              0.633130
          switzerland              0.622323
           luxembourg              0.610033
             portugal              0.577154
               russia              0.571507
              germany              0.563291
            catalonia              0.534176

There are two main learning algorithms in word2vec : continuous bag-of-words and continuous skip-gram. The switch -cbow allows the user to pick one of these learning algorithms. Both algorithms learn the representation of a word that is useful for prediction of other words in the sentence. These algorithms are described in detail in [1,2].

Interesting properties of the word vectors

It was recently shown that the word vectors capture many linguistic regularities, for example vector operations vector('Paris') - vector('France') + vector('Italy') results in a vector that is very close to vector('Rome'), and vector('king') - vector('man') + vector('woman') is close to vector('queen') [3, 1]. You can try out a simple demo by running demo-analogy.sh.

To observe strong regularities in the word vector space, it is needed to train the models on large data set, with sufficient vector dimensionality as shown in [1]. Using the word2vec tool, it is possible to train models on huge data sets (up to hundreds of billions of words).

From words to phrases and beyond

In certain applications, it is useful to have vector representation of larger pieces of text. For example, it is desirable to have only one vector for representing 'san francisco'. This can be achieved by pre-processing the training data set to form the phrases using the word2phrase tool, as is shown in the example script ./demo-phrases.sh. The example output with the closest tokens to 'san_francisco' looks like:

                 Word       Cosine distance
-------------------------------------------
          los_angeles              0.666175
          golden_gate              0.571522
              oakland              0.557521
           california              0.554623
            san_diego              0.534939
             pasadena              0.519115
              seattle              0.512098
                taiko              0.507570
              houston              0.499762
     chicago_illinois              0.491598

The linearity of the vector operations seems to weakly hold also for the addition of several vectors, so it is possible to add several word or phrase vectors to form representation of short sentences [2].

How to measure quality of the word vectors

Several factors influence the quality of the word vectors:

• amount and quality of the training data
• size of the vectors
• training algorithm

The quality of the vectors is crucial for any application. However, exploration of different hyper-parameter settings for complex tasks might be too time demanding. Thus, we designed simple test sets that can be used to quickly evaluate the word vector quality.

For the word relation test set described in [1], see ./demo-word-accuracy.sh, for the phrase relation test set described in [2], see ./demo-phrase-accuracy.sh. Note that the accuracy depends heavily on the amount of the training data; our best results for both test sets are above 70% accuracy with coverage close to 100%.

Word clustering

The word vectors can be also used for deriving word classes from huge data sets. This is achieved by performing K-means clustering on top of the word vectors. The script that demonstrates this is ./demo-classes.sh. The output is a vocabulary file with words and their corresponding class IDs, such as:

carnivores 234
carnivorous 234
cetaceans 234
cormorant 234
coyotes 234
crocodile 234
crocodiles 234
crustaceans 234
cultivated 234
danios 234
.
.
.
acceptance 412
argue 412
argues 412
arguing 412
argument 412
arguments 412
belief 412
believe 412
challenge 412
claim 412

Performance

The training speed can be significantly improved by using parallel training on multiple-CPU machine (use the switch '-threads N'). The hyper-parameter choice is crucial for performance (both speed and accuracy), however varies for different applications. The main choices to make are:

• architecture: skip-gram (slower, better for infrequent words) vs CBOW (fast)
• the training algorithm: hierarchical softmax (better for infrequent words) vs negative sampling (better for frequent words, better with low dimensional vectors)
• sub-sampling of frequent words: can improve both accuracy and speed for large data sets (useful values are in range 1e-3 to 1e-5)
• dimensionality of the word vectors: usually more is better, but not always
• context (window) size: for skip-gram usually around 10, for CBOW around 5

Where to obtain the training data

The quality of the word vectors increases significantly with amount of the training data. For research purposes, you can consider using data sets that are available on-line:

• First billion characters from wikipedia (use the pre-processing perl script from the bottom of Matt Mahoney's page)
• WMT11 site: large amount of text data for several languages (duplicate sentences should be removed before training the models)

Pre-trained entity vectors with Freebase naming

We are also offering more than 1.4M pre-trained entity vectors with naming from Freebase. This is especially helpful for projects related to knowledge mining.

• Entity vectors trained on 100B words from various news articles: freebase-vectors-skipgram1000.bin.gz
• Entity vectors trained on 100B words from various news articles, using the deprecated /en/ naming (more easily readable); the vectors are sorted by frequency: freebase-vectors-skipgram1000-en.bin.gz

Here is an example output of ./distance freebase-vectors-skipgram1000-en.bin:

Enter word or sentence (EXIT to break): /en/geoffrey_hinton

                        Word       Cosine distance
--------------------------------------------------
           /en/marvin_minsky              0.457204
             /en/paul_corkum              0.443342
 /en/william_richard_peltier              0.432396
           /en/brenda_milner              0.430886
    /en/john_charles_polanyi              0.419538
          /en/leslie_valiant              0.416399
         /en/hava_siegelmann              0.411895
            /en/hans_moravec              0.406726
         /en/david_rumelhart              0.405275
             /en/godel_prize              0.405176

Final words

Thank you for trying out this toolkit, and do not forget to let us know when you obtain some amazing results! We hope that the distributed representations will significantly improve the state of the art in NLP.

References

[1] Tomas Mikolov, Kai Chen, Greg Corrado, and Jeffrey Dean. Efficient Estimation of Word Representations in Vector Space. In Proceedings of Workshop at ICLR, 2013.

[2] Tomas Mikolov, Ilya Sutskever, Kai Chen, Greg Corrado, and Jeffrey Dean. Distributed Representations of Words and Phrases and their Compositionality. Submitted to NIPS 2013.

[3] Tomas Mikolov, Wen-tau Yih, and Geoffrey Zweig. Linguistic Regularities in Continuous Space Word Representations. In Proceedings of NAACL HLT, 2013.

Other useful links

Feel free to send us a link to your project or research paper related to word2vec that you think will be useful or interesting for the others.

Tomas Mikolov, Quoc V. Le and Ilya Sutskever. Exploiting Similarities among Languages for Machine Translation. We show how the word vectors can be applied to machine translation.

Word2vec in Python by Radim Rehurek in gensim.

Demo using word2vec by Christopher Moody: ThisPlusThat.me

Disclaimer

This open source project is NOT a Google product, and is released for research purposes only.