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D. Egret
CDS, Strasbourg, France, E-mail: egret@astro.u-strasbg.fr
J. Mothe1, T. Dkaki2 and B. Dousset
Research Institute in Computer Sciences, IRIT, SIG, 31062 Toulouse Cedex,
France,
E-mail: {mothe/dkaki/dousset}@irit.fr
1Institut Universitaire de Formation des Maîtres de Toulouse 2IUT Strasbourg-Sud, Université Robert Schuman, France
Electronic publication has become an essential aspect of the distribution of astronomical results (see Heck 1997). The users who want to exploit this information need efficient information retrieval systems in order to retrieve relevant raw information or to extract hidden information and synthesize thematic trends. The tools providing the former functionalities are based on query and document matching (Salton et al. 1983; Frakes et al. 1992; Eichhorn et al. 1997). The latter functionalities (called data mining functionalities) result from data analysis, data evolution analysis and data correlation principles and allow one to discover a priori unknown knowledge or information (Shapiro et al. 1996). We focus on these latter functionalities.
A knowledge discovery process can be broken down into two steps: first, the data or information selection and pre-treatment; second, the mining of these pieces of information in order to extract hidden information. The main objectives of the mining are to achieve classification (i.e., finding a partition of the data, using a rule deduced from the data characteristics), association (one tries to find data correlations) and sequences (the objective is to identify and to find the temporal relationships between the data). The information resulting from an analysis have then to be presented to the user in the most synthetic and expressive way, including graphical representation.
Tetralogie is an information mining tool that has been developed at the Institut de Recherche en Informatique de Toulouse (IRIT). It is used for science and technology monitoring (Dousset et al. 1995; Chrisment et al. 1997) from document collections. In this paper it is not possible to present in detail all the system functionalities. We will rather focus on some key features and on an example of the results that can be obtained from astronomical records.
The information mining process is widely based on statistical methods and more precisely on data analysis methods. First, the raw information have to be selected and pre-treated in order to extract the relevant elements of information and to store them in an appropriate form.
Different kinds of crossing tables can be performed according to the kind of information one wants to discover, for example:
Kind of crossing | Expected discovering |
(authors name, authors name) | Multi-author collaborative work |
(authors name, document topics) | Thematic map of publishing authors |
(document topics, authors affiliation) | Geographic map of the topics |
The different mining functions used are described in Chrisment et al. (1997). They include: Principal component analysis (PCA), Correspondence Factorial Analysis (CFA), Hierarchical Ascendant Classification, Classification by Partition and Procustean Analysis.
In that abstract sample, it is possible to extract about 1600 different authors, and 200 can be selected as the most prolific. Topics of the documents can be extracted either from the title, from the keywords or from the abstract field. Titles have been considered as too short to be really interesting for the study. In addition, the use of keywords was considered too restrictive, as they belong to a controlled set. Indeed, we preferred to automatically extract the different topics from the words or series of words contained in the abstracts.
The first crossing was done using all the authors. A first view is obtained by sorting the author correlations in order to find the strong connexities. The resulting connexity table shows strongly related groups (about 15 groups appear on the diagonal). They are almost all weakly linked via at least one common author (see the several points above and below the diagonal line, linking the blocks). The isolated groups appear on the bottom right corner. This strong connexity is typical of a scientific domain including large international projects and strong cooperative links.
One can go further and study in depth one of these collaborative groups: a CFA of the (main author / author) crossing shows, for instance, some features of the collaborative work around the Hipparcos project in the years 1994-96 (i.e., before the publication of the final catalogues) as can be viewed by grouping together authors having papers co-authored with M. Perryman (Hipparcos project scientist) and L. Lindegren (leader of one of the scientific consortia). The system allows the extraction of 25 main authors (with more than two publications, and at least one with one of the selected central authors) and the cross-referencing of them with all possible co-authors.
For instance, crossing main authors of the `Hipparcos' collaboration with topical key words, allowed us to discover the main keywords of the `peripheral' authors (those who bring specific outside collaborations).
In this paper, we have tried to show the usefulness of the TETRALOGIE system for discovering trends in the astronomical literature. We focused on several functionalities of this tool that allow one to find some hidden information such as the teams (through the multi-author collaborative work) or the topical maps of publishing authors. This tool graphically displays the discovered relationships that may exist among the extracted information.
Schulman et al. 1997, using classical statistical approaches, have extracted significant features from an analysis of subsequent years of astronomy literature. In a forthcoming study, we will show how the Tetralogie system can also be used to discover thematic evolutions in the literature over several years.
The Web version contains additional figures for illustration.
Benzecri, J.P. 1973, L'analyse de données, Tome 1 et 2, Dunod Edition
Chrisment, C., Dkaki, T., Dousset, & B., Mothe, J. 1997, ISI vol. 5, 3, 367 (ISSN 1247-0317)
Dousset, B., Rommens, M., & Sibue, D. 1995, Symposium International, Omega-3, Lipoprotéines et atherosclerose
Eichhorn, G., et al. 1997, in Astronomical Data Analysis Software and Systems VI, ASP Conf. Ser., Vol. 125, eds. Gareth Hunt and H. E. Payne (San Francisco, ASP), 569
Frakes et al. 1992, Information retrieval, Algorithms and structure (ISBN 0-13-463837-9)
Heck, A. 1997, ``Electronic Publishing for Physics and Astronomy'', Astrophys. Space Science 247, Kluwer, Dordrecht (ISBN 0-7923-4820-6)
Murtagh, F., & Heck, A. 1989, Knowledge-based systems in astronomy, Lecture Notes in Physics 329, Springer-Verlag, Heidelberg (ISBN 3-540-51044-3)
Salton, G., et al. 1983, Introduction to modern retrieval, McGraw Hill International (ISBN 0-07-66526-5)
Shapiro et al. 1996, Advances in Knowledge discovery and Data Mining, AAAI Press (ISBN 0-262-56097-6)
Schulman, E., et al. 1997, PASP 109, 741
Next: CDS GLU, a Tool for Managing Heterogeneous Distributed Web Services
Up: Astrostatistics and Databases
Previous: LINNÉ, a Software System for Automatic Classification
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