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Integrating Word Relationships into Language Models

Integrating Word Relationships into Language Models. Guihong Cao , Jian-Yun Nie , Jing Bai D épartment ďInformatique et de Recherche Opérationnelle,Université de Montréal. Presenter : Chia-Hao Lee . Outline. Introduction Previous Work A Dependency Model to Combine WordNet and Co-occurrence

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Integrating Word Relationships into Language Models

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  1. Integrating Word Relationships into Language Models Guihong Cao , Jian-Yun Nie , Jing Bai Départment ďInformatique et de Recherche Opérationnelle,Université de Montréal Presenter : Chia-Hao Lee 

  2. Outline • Introduction • Previous Work • A Dependency Model to Combine WordNet and Co-occurrence • Parameter estimation • Estimating conditional probabilities • Estimating mixture weights • Experiments • Conclusion and feature work

  3. Introduction • In recent years, language models for information retrieval (IR) have increased in popularity. • The basic idea behind is to compute the conditional probability . • In most approaches, the computation is conceptually decomposed into two distinct steps: • (1) Estimating the document model • (2) Computing the query likelihood using the estimated document model

  4. Introduction (cont.) • When estimating the document model, the words in the document are assumed to be independent with respect to one another, leading to the so called “bag-of-word” model. • However, from our own knowledge of natural language, we know that the assumption of term independence is a matter of mathematical convenience rather than a reality. • For example, the words “computer” and “program” are not independent. A query requesting for “computer” might be well satisfied by a document about “program”.

  5. Introduction (cont.) • Some studies have been carried out to relax the independence assumption. • The first one is data-driven, which tries to capture dependency among terms by statistical information derived from the corpus directly. • Another direction is to exploit hand-crafted thesauri, such as WordNet.

  6. Previous Work • In classical language modeling approach to IR, a multinomial model over terms is estimated for each document in the collection to be indexed and searched. • In most cases, each query term is assumed to be independent of the others, the query likelihood is estimated by . • After the specification of a document prior ,the posteriori probability of a document is given by:

  7. Previous Work (cont.) • However the classical language model approach for IR does not address the problem of dependence between words. • The term “dependence” may mean two different things: • Dependence between words within a query or within a document • Dependence between query words and document words • The first meaning, one may try to recognize the relationships between words in sentence. • Under the second meaning, dependence means any relationship that can be exploited during query evaluation.

  8. Previous Work (cont.) • The incorporate term relationships into the document language model, we propose a translation model . • With the translation model, the document-to-query model becomes: • Even though their model is general than other language models, it is different to determine the translation probability in practice. • To solve this problem, we generate an artificial collection of “synthetic” data for training by assuming that a sentence is parallel to the paragraph that contains the sentence.

  9. A Dependency Model to Combine WordNet and Co-occurrence • Given a query q and a document d, the query can be related directly, or they can be related indirectly through some word relationships. • An example of the first case is that the document and the query contain the same words. • In the second case, a document can contain a different word, but synonymous or related to the one in the query.

  10. A Dependency Model to Combine WordNet and Co-occurrence (cont.) • In order to take both cases into our modeling, we assume that there are two sources to generate a term from a document: one from a dependency model and another from a non-dependency model. :the parameter of dependency model :the parameter of non-dependency model

  11. :the probability of unigram model A Dependency Model to Combine WordNet and Co-occurrence (cont.) • The non-dependency model tries to capture the direct generation of the query by the document, we can model it by unigram document model: • Then, we select a term in the document randomly first. • Second, a query term is generated based on the observed term. Therefore we have:

  12. A Dependency Model to Combine WordNet and Co-occurrence (cont.) • As for the translation model, we also have the problem of estimating the dependency between two term, i.e. • To address the problem, we assume that some word relationships have been manually identified and stored in a linguistic resource, and some other relationships have to be found automatically according to co-occurrences.

  13. :the conditional probability of given according to WordNet. :the probability that the link between and is achieved by other means. :the interpolation factor, which can be considered as a two-component model. A Dependency Model to Combine WordNet and Co-occurrence (cont.) • So, this combination can be achieved by a linear interpolation smoothing. Thus: • In our study, we only consider co-occurrence information beside WordNet. • So, is just the co-occurrence model.

  14. A Dependency Model to Combine WordNet and Co-occurrence (cont.) • For the simplicity of expression, we denote probability of link model as , i.e. , and the co-occurrence model as . • Substitute Equations 4 and 5 into 3, we obtain Equation 6:

  15. A Dependency Model to Combine WordNet and Co-occurrence (cont.) + + + + + +

  16. A Dependency Model to Combine WordNet and Co-occurrence (cont.) • The idea can become more obvious if we make some simplification in the formula. • So, we can get: consisting of link model, co-occurrence model and unigram model

  17. A Dependency Model to Combine WordNet and Co-occurrence (cont.) • Let , , denote the respect weights of link model, co-occurrence model, and unigram model. • Then equation 9 can be rewritten as: • For information retrieval, the most important terms are nouns. So, we concentrate on three relations related to nouns: synonym, hypernym, and hyponym. NSLM SLM

  18. :the discount factor :the length of the document :the count of unigram term in the document :the maximum likelihood probability of the word in the collection Parameter estimation • 1.Estimating conditional probabilities • The unigram model ,we use the MLE estimation, smoothed by interpolated absolute discount, that is: (related to D)

  19. Parameter estimation (cont.) • For , it can be approximated by the maximum likelihood probability . • This approximation is motivated by the fact that the word is primarily generated from in a way quite independent from the model . • The estimation of - the probability of link between two words according to WordNet.

  20. and are assumed to have a relationship in WordNet ( ) :the count of co-occurrences of with within the predefined window C w , w W , L i :the number of unique terms which have a relationship with in WordNet and co-occur with it in . Parameter estimation (cont.) • Equation 13 defines our estimation of by interpolated Absolute discount: ?

  21. Parameter estimation (cont.) • The estimation of the components of the co-occurrence model is similar to those of the link model expect that that when counting the co-occurrence frequency, the requirement of having a link in WordNet is removed.

  22. :the number of documents in the dataset :the length of query :the prior probability with which to choose the document to generate the query Parameter estimation (cont.) • 2.Estimating mixture weights We introduce an EM algorithm to estimate the mixture weights in NSLM. Because NSLM is a three-component mixture model, the optimal weights should maximize the likelihood of the queries. Let be the mixture weights, we then have:

  23. smoothing :the weight of the noise :respectively unigram model, link model and co-occurrence model built from the collection Parameter estimation (cont.) • However, some documents having high weights are not truly relevant to the query. They contain noise. • To account for the noise, we further assume that there are two distinctive sources to generate the query. • One is the relevant documents, another is a noisy source, which is approximated by the collection C

  24. Parameter estimation (cont.) • With this setting, the hidden and can be estimated using the EM algorithm. • The update formulas are as follows:

  25. Experiments We evaluated our model described in the previous sections using three different TREC collections – WSJ,AP and SJM

  26. Experiments (cont.)

  27. Conclusion and feature work • In this paper, we integrate word relationships into the language modeling framework. • We used EM algorithm to train the parameters. This method worked well for our experiment.

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