Representing concepts in formal ontologies. Compositionality vs. typicality effects
DOI:
https://doi.org/10.12775/LLP.2012.018Keywords
concept representation, formal ontologies, prototypical effects, compositionalityAbstract
The problem of concept representation is relevant for many subfields of cognitive research, including psychology and philosophy, as well as artificial intelligence. In particular, in recent years it has received a great deal of attention within the field of knowledge representation, due to its relevance for both knowledge engineering as well as ontology-based technologies. However, the notion of a concept itself turns out to be highly disputed and problematic. In our opinion, one of the causes of this state of affairs is that the notion of a concept is, to some extent, heterogeneous, and encompasses different cognitive phenomena. This results in a strain between conflicting requirements, such as compositionality, on the one hand and the need to represent prototypical information on the other. In some ways artificial intelligence research shows traces of this situation. In this paper, we propose an analysis of this current state of affairs. Since it is our opinion that a mature methodology with which to approach knowledge representation and knowledge engineering should also take advantage of the empirical results of cognitive psychology concerning human abilities, we outline some proposals for concept representation in formal ontologies, which take into account suggestions from psychological research. Our basic assumption is that knowledge representation systems whose design takes into account evidence from experimental psychology (and which, therefore, are more similar to the human way of organizing and processing information) may therefore give better results in many applications (e.g. in the fields of information retrieval and semantic web).References
Baader, F., D. Calvanese, D. McGuinness, D. Nardi, and P. Patel-Schneider, 2010, The Description Logic Handbook: Theory, Implementations and Applications, 2ndedition, Cambridge University Press.
Baader, F., and B. Hollunder, 1995, “Embedding defaults into terminological knowledge representation formalisms”, J. Autom. Reasoning 14, 1: 149–180. CrossRef
Barsalou, L.W., 1985, “Continuity of the conceptual system across species”, Trends in Cognitive Science 9, 7: 305–311. CrossRef
Bizer, C., T.Heath, and T. Berners-Lee, 2009, “Linked Data – The Story So Far”, International Journal on Semantic Web and Information System 5, 3: 1–22. CrossRef
Bermudez, J.L., 1995, “Nonconceptual content: From perceptual experience to subpersonal computational states”, Mind and Language 10: 333–369. CrossRef
Bermudez, J. L., and A. Cahen, 2011, “Nonconceptual mental content”, Stanford Encyclopaedia of Philosophy, Link
Bobillo, F., and U. Straccia, 2009, “An OWL Ontology for Fuzzy OWL 2”, Proceedings of the 18th International Symposium on Methodologies for Intelligent Systems (ISMIS-09), Lecture Notes in Computer Science, Springer Verlag.
Bonatti, P.A., C. Lutz, and F. Wolter, F., 2006, “Description logics with circumscription”, pages 400–410 in: Proc. of KR.
Brachman, R., 1985, “I lied about the trees”, The AI Magazine 3, 6: 80–95.
Brachman, R., and J.G. Schmolze, 1985, “An overview of the KL-ONE knowledge representation system”, Cognitive Science 9: 171-216. CrosReff
Brachman, R., and H. Levesque (eds.), 1985, Readings in Knowledge Representation, Morgan Kaufmann, Los Altos, CA.
Brandom, R., 1994, Making it Explicit, Harvard University Press, Cambridge, MA.
Calegari, S., and D. Ciucci, 2007, “Fuzzy Ontology, Fuzzy Description Logics and Fuzzy-OWL”, Proc. WILF 2007, LNCS, volume 4578.
Dell’Anna, A., and M. Frixione, 2010, “On the advantage (if any) and disadvantage of the conceptual/nonconceptual distinction for cognitive science”, Minds & Machines 20: 29–45. WoS
Ding, Z., Y. Peng, and R. Pan, 2006, “BayesOWL: Uncertainty modeling in Semantic Web ontologies”, in: Soft Computing in Ontologies and Semantic Web, Z. Ma (ed.), Studies in Fuzziness and Soft Computing, volume 204, Springer.
Evans, J.S.B.T., and K. Frankish (eds.), 2008, In Two Minds: Dual Processes and Beyond, Oxford UP, New York, NY.
Fodor, J., 1981, “The present status of the innateness controversy”, in: J. Fodor Representations, The MIT Press, Cambridge, MA.
Fodor, J., 1987, Psychosemantics, The MIT Press/A Bradford Book, Cambridge, MA.
Fodor, J., 1998, Concepts: Where Cognitive Science Went Wrong, Oxford, UK: Oxford University Press.
Fodor, J., and Z. Pylyshyn, 1988, “Connectionism and cognitive architecture: A critical analysis”, Cognition 28: 3–71. CrossRef; PubMed
Frixione, M., 2007, “Do concepts exist? A naturalistic point of view”, in: Explaining the Mental, C. Penco, M. Beaney, M. Vignolo (eds.), Cambridge Scholars Publishing, Cambridge, UK.
Gagliardi, F., 2008, “A Prototype-Exemplars Hybrid Cognitive Model of ‘Phenomenon of Typicality’ in Categorization: A Case Study in Biological Classification”, pages 1176–1181 in: Proc. 30th Annual Conf. of the Cognitive Science Society, Austin, TX.
Gagliardi, F. 2010, “Cognitive Models of Typicality in Categorization with Instance-Based Machine Learning”, pages 115–130 in: Practices of Cognition. Recent Researches in Cognitive Science, University of Trento Press.
Gao, M., and C. Liu, 2005, “Extending OWL by fuzzy Description Logic”, Proc. 17th IEEE Int. Conf. on Tools with Artificial Intelligence (ICTAI 2005), IEEE Computer Society, Los Alamitos, pp. 562–567.
Hayes, P., 2001, “Dialogue on rdf-logic. Why must the web be monotonic?. World Wide Web Consortium (W3C)”, Link
Klinov, P., and B.Parsia, 2008, “Optimization and evaluation of reasoning in probabilistic description logic: Towards a systematic approach”, pages 213–228 in: ISWC 2008, A.P. Sheth, S. Staab, M. Dean, M. Paolucci, D. Maynard, T. Finin, and K. Thirunarayan, (eds.), LNCS, volume 5318, Springer, Heidelberg.
Lukasiewicz, Th., and U. Straccia, 2008, “Managing uncertainty and vagueness in description logics for the Semantic Web”, Journal of Web Semantics 6: 291–308. CrossRef; WoS
Machery, E., 2005, “Concepts are not a natural kind”, Philosophy of Science 72: 444–467. CrossRef
Machery, E., 2009, Doing without Concepts Oxford University Press, Oxford, UK.
Medin, D.L., and P.J. Schwanenflugel, 1981, “Linear separability in classification learning”, J. of Exp. Psyc.: Human Learning and Memory 7: 355–368. CrossRef
Minsky, M., 1975, “A framework for representing knowledge”, in: The Psychology of Computer Vision, Patrick H. Winston (ed.), McGraw-Hill, New York (republished: Brachman & Levesque, New York, 1985).
Murphy, G.L., 2002, The Big Book of Concepts, The MIT Press, Cambridge, MA.
Osherson, D.N., and E.E.Smith, 1981, “On the adequacy of prototype theory as a theory of concepts”, Cognition 11: 237–262. CrossRef
Peacocke, C., 1992, A Study of Concepts, The MIT Press, Cambridge, MA.
Rosch, E., 1975, “Cognitive representation of semantic categories”, Journal of Experimental Psychology 104: 573–605.
Spelke, E.S., 1994, “Initial knowledge: six suggestions”, Cognition 50: 431–445. CrossRef; PubMed
Spelke, E.S., and K.D. Kinzler, 2007, “Core knowledge”, Developmental Science 10, 1: 89–96. CrossRef
Stanovich, K.E., and R. West, 2000, “Individual Differences in Reasoning: Implications for the Rationality Debate?”, The Behavioural and Brain Sciences 23, 5: 645–665. CrossRef
Stoilos, G., G. Stamou, V. Tzouvaras, J.Z. Pan, I. Horrocks, 2005, “Fuzzy OWL: Uncertainty and the Semantic Web”, Proc. Workshop on OWL: Experience and Directions (OWLED 2005), CEUR Workshop Proceedings, volume 188.
Straccia, U., 1993, “Default inheritance reasoning in hybrid kl-one-style logics”, Proc. IJCAI, pp. 676–681.
Wittgenstein, L., 1953, Philosophische Untersuchungen, Oxford, Blackwell.
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