A New Approach to Automatic Keyword Generation Using Inverse Vector Space Model

키워드 자동 생성에 대한 새로운 접근법: 역 벡터공간모델을 이용한 키워드 할당 방법

  • Published : 2011.03.31

Abstract

Recently, numerous documents have been made available electronically. Internet search engines and digital libraries commonly return query results containing hundreds or even thousands of documents. In this situation, it is virtually impossible for users to examine complete documents to determine whether they might be useful for them. For this reason, some on-line documents are accompanied by a list of keywords specified by the authors in an effort to guide the users by facilitating the filtering process. In this way, a set of keywords is often considered a condensed version of the whole document and therefore plays an important role for document retrieval, Web page retrieval, document clustering, summarization, text mining, and so on. Since many academic journals ask the authors to provide a list of five or six keywords on the first page of an article, keywords are most familiar in the context of journal articles. However, many other types of documents could not benefit from the use of keywords, including Web pages, email messages, news reports, magazine articles, and business papers. Although the potential benefit is large, the implementation itself is the obstacle; manually assigning keywords to all documents is a daunting task, or even impractical in that it is extremely tedious and time-consuming requiring a certain level of domain knowledge. Therefore, it is highly desirable to automate the keyword generation process. There are mainly two approaches to achieving this aim: keyword assignment approach and keyword extraction approach. Both approaches use machine learning methods and require, for training purposes, a set of documents with keywords already attached. In the former approach, there is a given set of vocabulary, and the aim is to match them to the texts. In other words, the keywords assignment approach seeks to select the words from a controlled vocabulary that best describes a document. Although this approach is domain dependent and is not easy to transfer and expand, it can generate implicit keywords that do not appear in a document. On the other hand, in the latter approach, the aim is to extract keywords with respect to their relevance in the text without prior vocabulary. In this approach, automatic keyword generation is treated as a classification task, and keywords are commonly extracted based on supervised learning techniques. Thus, keyword extraction algorithms classify candidate keywords in a document into positive or negative examples. Several systems such as Extractor and Kea were developed using keyword extraction approach. Most indicative words in a document are selected as keywords for that document and as a result, keywords extraction is limited to terms that appear in the document. Therefore, keywords extraction cannot generate implicit keywords that are not included in a document. According to the experiment results of Turney, about 64% to 90% of keywords assigned by the authors can be found in the full text of an article. Inversely, it also means that 10% to 36% of the keywords assigned by the authors do not appear in the article, which cannot be generated through keyword extraction algorithms. Our preliminary experiment result also shows that 37% of keywords assigned by the authors are not included in the full text. This is the reason why we have decided to adopt the keyword assignment approach. In this paper, we propose a new approach for automatic keyword assignment namely IVSM(Inverse Vector Space Model). The model is based on a vector space model. which is a conventional information retrieval model that represents documents and queries by vectors in a multidimensional space. IVSM generates an appropriate keyword set for a specific document by measuring the distance between the document and the keyword sets. The keyword assignment process of IVSM is as follows: (1) calculating the vector length of each keyword set based on each keyword weight; (2) preprocessing and parsing a target document that does not have keywords; (3) calculating the vector length of the target document based on the term frequency; (4) measuring the cosine similarity between each keyword set and the target document; and (5) generating keywords that have high similarity scores. Two keyword generation systems were implemented applying IVSM: IVSM system for Web-based community service and stand-alone IVSM system. Firstly, the IVSM system is implemented in a community service for sharing knowledge and opinions on current trends such as fashion, movies, social problems, and health information. The stand-alone IVSM system is dedicated to generating keywords for academic papers, and, indeed, it has been tested through a number of academic papers including those published by the Korean Association of Shipping and Logistics, the Korea Research Academy of Distribution Information, the Korea Logistics Society, the Korea Logistics Research Association, and the Korea Port Economic Association. We measured the performance of IVSM by the number of matches between the IVSM-generated keywords and the author-assigned keywords. According to our experiment, the precisions of IVSM applied to Web-based community service and academic journals were 0.75 and 0.71, respectively. The performance of both systems is much better than that of baseline systems that generate keywords based on simple probability. Also, IVSM shows comparable performance to Extractor that is a representative system of keyword extraction approach developed by Turney. As electronic documents increase, we expect that IVSM proposed in this paper can be applied to many electronic documents in Web-based community and digital library.

Keywords

References

  1. Berry, M., Dramc, Z., and Jessup, E., "Matrics, Vector Spaces, and Information Retrieval," SIAM Review, Vol. 41, 1999, pp. 335-362. https://doi.org/10.1137/S0036144598347035
  2. Ercan, G. and Cicekli, I., "Using lexical chain for keyword extraction," Information Processing and Management, Vol. 43, 2007, pp. 1705-1714. https://doi.org/10.1016/j.ipm.2007.01.015
  3. Frank, E., Paynter, W., Witten, I., Gutwin, C., and Nevill-Manning, C., "Domain-specific keyphrase extraction," In: Proceedings of IJCAI'99, 1999.
  4. Kim, P., "A Study on the Performance Improvement of Rocchio Classifier with Term Weighting Methods," Journal of the Korean Society for information Management, Vol. 25, No. 1, 2008, pp. 211-233. https://doi.org/10.3743/KOSIM.2008.25.1.211
  5. Lee, C., Kim, M., Lee, K., Lee, G., and Park, H., "Document Thematic words Extraction using Principal Component Analysis," Journal of Korean Institute of Information Scientists and Engineers, Vol. 29, No. 10, 2002, pp. 747-754.
  6. Lee, M. and Bae, H., "Design of Keyword Extraction System Using TFIDF," Korean journal of cognitive science, Vol. 12, No. 1, 2002, pp. 1-11.
  7. Matsuo, Y. and Ishizuka, M., "Keyword extraction from a single document using word co-occurrence statistical information," International Journal on Artificial Intelligence Tools, Vol. 13, No. 1, 2004, pp. 157-169. https://doi.org/10.1142/S0218213004001466
  8. Salton, G. and McGrill, M., Introduction to modern information retrieval, Mcgraw-Hill, New York, 1983.
  9. Shin, H., Zhang, B., and Kim, Y., "Learning Probabilistic Graph Models for Extracting Topic Words in a Collection of Text Documents," In: Proceedings of Spring Conference on Korean Institute of Information Scientists and Engineers, 2000.
  10. Turney, P., "Extraction of Keyphrase from text: evaluation of four algorithms," National Research Council, Institute for Information Technology, Technical Report ERB-1051, 1997.
  11. Turney, P., "Learning to Extract Keyphrases from Text," National Research Council, Institute for Information Technology, Technical Report ERB-1057, 1999.
  12. Turney, P., "Learning algorithm for keyphrase extraction," Information Retrieval, Vol. 2, No. 3, 2000, pp. 303-336.
  13. Wan, X., "A novel document similarity measure based on earh mover's distance," In_formation Sciences, Vol. 177, 2007, pp. 3718-3730. https://doi.org/10.1016/j.ins.2007.02.045
  14. Witten, I., Paynter, G., Frank, E., Gutwin, C., and Nevill-Manning, C., "KEA: Practical Automatic Keyphrase Extraction," In: Proceedings of DL'99, 1999.
  15. Yang, K. and Huh, S., "Automation of Expert Classification in Knowledge Management Systems Using Text Categorization Technique," Journal of MIS research, Vol. 14, No. 2, 2004, pp. 115-130.
  16. Yoon, A., Hwang, S., Lee, E., and Kwon, H., "Construction of Korean Wordnet KorLex 1.5," Journal of Korean Institute of Information Scientists and Engineers, Vol. 36, No. 1, 2009, pp. 92-108.
  17. Zhang, C. and Xu, H., "Using citation-KNN for automatic keywords assignment," In: proceedings of 2009 International Conference on Electronic Commerce and Business Intelligence, 2009.