PmSPARQL: Extended SPARQL for Multi-paradigm Path Extraction
Authors: Thabet Slimani, Boutheina Ben Yaghlane, Khaled Mellouli
Abstract:
In the last few years, the Semantic Web gained scientific acceptance as a means of relationships identification in knowledge base, widely known by semantic association. Query about complex relationships between entities is a strong requirement for many applications in analytical domains. In bioinformatics for example, it is critical to extract exchanges between proteins. Currently, the widely known result of such queries is to provide paths between connected entities from data graph. However, they do not always give good results while facing the user need by the best association or a set of limited best association, because they only consider all existing paths but ignore the path evaluation. In this paper, we present an approach for supporting association discovery queries. Our proposal includes (i) a query language PmSPRQL which provides a multiparadigm query expressions for association extraction and (ii) some quantification measures making easy the process of association ranking. The originality of our proposal is demonstrated by a performance evaluation of our approach on real world datasets.
Keywords: Association extraction, query Language, relationships, knowledge base, multi-paradigm query.
Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1070527
Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 1451References:
[1] B. Aleman-Meza, C. Halaschek, B. Arpinar, and A. Sheth, Contextaware semantic association ranking. In First International Workshop on Semantic Web and Databases,in First International Workshop on Semantic Web and Databases, Berlin, Germany, September 2003, p. 33-50.
[2] K. Anyanwu, A. Maduko, and A. Sheth, Sem-rank: Ranking complex relationship search results on the semantic web, in International World Wide Web Conference, 14, ACM, Chiba, Japan, 2005, p. 117-127.
[3] B. Aleman-Meza, C. Halaschek-Wiener, I. Budak Arpinar, C. Ramakrishnan, and A. Sheth, Ranking complex relationships on the semantic web, in IEEE Internet Computing, 03, 2005, p. 37-44.
[4] B. Aleman-Meza, P. Burns, M. Eavenson, D. Palaniswami, and A. Sheth, An ontological approach to the document access problem of insider threat. IEEE International Conference on Intelligence and Security Informatics. Atlanta, Georgia, USA, 2005, p. 486-491.
[5] K. Anyanwu and A. Sheth, The rho operator: Computing and ranking semantic associations in the semantic web. SIGMOD Record, 2002.
[6] A. Seaborne, RDQL A Query Language for RDF, WWWConsortium, Member Submission SUBM-RDQL-20040109, 2004.
[7] E. Prud-hommeaux and A. Seaborne, SPARQL:Query Language for RDF, 2005.
[8] A. Kemafor, M. Angela, and S. Amit, SPARQ2L: Towards support for subgraph extraction queries in rdf databases, in WWW 2007, Banff, Alberta, Canada, 2007, p. 797- 806.
[9] J. Krys and Maciej.J, SARQLeR: Extended sparql for semantic association discovery, in 4 th European Semantic Web Conference. Innsbruck, Austria, 2007.
[10] A. Helenius and M. Aebi, Roles of n-linked glycans in the endoplasmic reticulum, in Annual Review of Biochemistry, 73 , 2004, p. 1019-1049.
[11] H. Donninger, T. Bonome, M. Radonovich, Pise-Masison, C. A., J. H. Brady, J.and Shih, J. Barrett, and M. J. Birrer, Whole genome expression profiling of advance stage papillary serous ovarian cancer reveals activated pathways. Oncogene 23, 8065, 8077 (2004).
[12] T. Miki, S. Nomura, and T. Ishida, Semantic web link analysis to discover social relationships in academic communities. Symposium on Applications and the Internet, 2005.
[13] A. Sheth, B. Aleman-Meza, I. Arpinar1, C. Halaschek, C. Ramakrishnan1, C. Bertram, Y. Warke, D. Avant, F. S. Arpinar, K. Anyanwu, and K. K., Semantic association identification and knowledge discovery for national security applications. Special Issue of Journal of Database Management on Database Technology for Enhancing National Security, L. Zhou and W. Kim (Eds.) 16, 33-53 (2005).
[14] S. Mukherjea and B. Bamba, Biopatentminer: An information retrieval system for biomedical patents. Thirtieth International Conference on Very Large Data Bases. VLDB, Toronto, Canada, 2004, p. 1066-1077.
[15] I. Arpinar, A. Sheth, C. Ramakrishnan, E. Usery, M. Azami, and M. Kwan, Geospatial ontology development and semantic analytics, in Handbook of Geographic Information Science., 4, edited by J. P. Wilson and A. S. F. E. vol 10. Blackwell Publishing, 2004.
[16] S. Lin and H. Chalupsky, Unsupervised link discovery in multirelational data via rarity analysis. ICDM 2003, 2003, p. 171-178.
[17] M. Janik and K. Kochut, A work-bench rdf store and high performance memory system for semantic association discovery. 4th International Semantic Web Conference. Galway, Ireland, 2005.
[18] W. Milnor, C. Ramakrishnan, M. Perry, A. Sheth, J. Miller, and K. Kochut, Discovering informative subgraphs in rdf graphs. Technical report, LSDIS Lab, Computer Science,University of Georgia, CS Technical Report 05-001.
[19] V. Paliwal, N. R. Adam, H. Xiong, and C. Bornhovd, Web service discovery via semantic association ranking and hyperclique pattern discovery, in wi, IEEE/WIC/ACM ,IEEE Computer Society, 2006, p. 649-652.
[20] H.-J. Chu and R. Chow, Reaching semantic interoperability through semantic association of domain standards, in 11th IEEE International Workshop on Future Trends of Distributed Computing Systems (FTDCS07), ISSN:1701-0483, 0-7695-2810-4, IEEE Computer Society, Washington, DC, USA, 2007.
[21] I. Cruz, A. Mendelzon, and P. Wood, A graphical query language supporting recursion. in acm sigmod international conference on management of data, in ACM SIGMOD International Conference on Management of Data, San Francisco, California, United States, 1987, p. 323- 330.
[22] I. Cruz, A. Mendelzon, and P. Wood, G+: Recursive queries without recursion. 2nd International Conference on Expert Database Systems, 1988, p. 355-368.
[23] M. Consens and A. Mendelzon, Graphlog: a visual formalism for real life recursion. ACM Symposium On Principles of Database Systems. 1990, p. 404-416.
[24] J. Broekstra and A. Kampman, SERQL: A second generation rdf query language. In SWAD-Europe Workshop on Semantic Web Storage and Retrieval. SWAD-Europe Workshop on Semantic Web Storage and Retrieval, 2003.
[25] M. Sintek and S. Decker, Triple - an rdf query, inference, and transformation language. In Deductive Databases and Knowledge Management. Tokyo, Japan, 2001.
[26] U. Ogbuji, RDF Query using Versa Thinking XML: Basic XML and RDF techniques for knowledge management, Part 6, 10 April 2002.
[27] A.Souzis, RxPath specification proposal. http://rx4rdf. liminalzone. org/RxPathSpec., 2004.
[28] L. Sam, L. yang, L. Jianrong, C. Friedman, and Y. Lussier, Triple - an rdf query, inference, and transformation language. In 12me Pacific Symposium on Biocomputing. 2007, p. 76-87.
[29] T. Samir and I. Budak Arpinar, Ontology evaluation and ranking using ontoqa. The first IEEE International Conference on Semantic Computing. Irvine, California, USA, September 17-19, 2007, p. 185- 192.
[30] C. Gutierrez, C. Hurtado, and A. Mendelzon., Foundations of Semantic Web Databases. Foundations of Semantic Web Databases. In PODS 2004, p. 95106., 2004.
[31] D. Marin, Rdf formalization. Technical report, Santiago de Chile. TR/DCC-2006-8. http://www.dcc.uchile.cl/ cgutierr/ftp/draltan.pdf.
[32] P. Jorge, A. Marcelo, and G. Claudio, Semantics and complexity of sparql. International Semantic Web Conference. Athens, GA, US, 2006.
[33] J. Lim, ADOdb Library for PHP, http://php.weblogs.com/ADODB., 2007.