The Abstract Expressive Power of First-Order and Description Logics with Concrete Domains
Pages 754 - 761
Abstract
Concrete domains have been introduced in description logic (DL) to enable reference to concrete objects (such as numbers) and predefined predicates on these objects (such as numerical comparisons) when defining concepts. The primary research goal in this context was to find restrictions on the concrete domain such that its integration into certain DLs preserves decidability or tractability. In this paper, we investigate the abstract expressive power of both first-order and description logics extended with concrete domains, i.e., we analyze which classes of first-order interpretations can be expressed using these logics, compared to what first-order logic without concrete domains can express. We demonstrate that, under natural conditions on the concrete domain D (which also play a role for decidability), extensions of first-order logic (FOL) or the well-known DL ALC with D share important formal characteristics with FOL, such as the compactness and the Löwenheim-Skolem properties. Nevertheless, their abstract expressive power need not be contained in that of FOL, though in some cases it is. To be more precise, we show, on the one hand, that unary concrete domains leave the abstract expressive power within FOL if we are allowed to introduce auxiliary predicates. On the other hand, we exhibit a class of concrete domains that push the abstract expressive power beyond that of FOL. As a by-product of these investigations, we obtain (semi-)decidability results for some of the logics with concrete domains considered in this paper.
References
[1]
James F. Allen. 1983. Maintaining Knowledge about Temporal Intervals. Commun. ACM 26, 11 (1983), 832--843.
[2]
Hajnal Andréka, István Németi, and Johan van Benthem. 1998. Modal Languages and Bounded Fragments of Predicate Logic. J. Philos. Log. 27, 3 (1998), 217--274.
[3]
Alessandro Artale, Vladislav Ryzhikov, and Roman Kontchakov. 2012. DL-Lite with Attributes and Datatypes. In ECAI 2012 - 20th European Conference on Artificial Intelligence, Luc De Raedt, Christian Bessiere, Didier Dubois, Patrick Doherty, Paolo Frasconi, Fredrik Heintz, and Peter J. F. Lucas (Eds.). IOS Press, 61--66.
[4]
Franz Baader. 1996. A Formal Definition for the Expressive Power of Terminological Knowledge Representation Languages. J. of Logic and Computation 6 (1996), 33--54.
[5]
Franz Baader and Filippo De Bortoli. 2019. On the Expressive Power of Description Logics with Cardinality Constraints on Finite and Infinite Sets. In Proc. of the 12th Int. Symposium on Frontiers of Combining Systems (FroCoS'19) (Lecture Notes in Computer Science, Vol. 11715), Andreas Herzig and Andrei Popescu (Eds.). Springer-Verlag, 203--219.
[6]
Franz Baader and Philipp Hanschke. 1991. A Scheme for Integrating Concrete Domains into Concept Languages. In Proceedings of the 12th International Joint Conference on Artificial Intelligence. Sydney, Australia, August 24--30, 1991, John Mylopoulos and Raymond Reiter (Eds.). Morgan Kaufmann, 452--457. http://ijcai.org/Proceedings/91-1/Papers/070.pdf
[7]
Franz Baader and Philipp Hanschke. 1992. Extensions of Concept Languages for a Mechanical Engineering Application. In GWAI-92: Advances in Artificial Intelligence, 16th German Conference on Artificial Intelligence (Lecture Notes in Computer Science, Vol. 671), Hans Jürgen Ohlbach (Ed.). Springer, 132--143.
[8]
Franz Baader, Ian Horrocks, Carsten Lutz, and Ulrike Sattler. 2017. An Introduction to Description Logic. Cambridge University Press.
[9]
Franz Baader and Jakub Rydval. 2020. Description Logics with Concrete Domains and General Concept Inclusions Revisited. In Automated Reasoning (Lecture Notes in Computer Science), Nicolas Peltier and Viorica Sofronie-Stokkermans (Eds.). Springer International Publishing, Cham, 413--431.
[10]
Franz Baader and Jakub Rydval. 2022. Using Model Theory to Find Decidable and Tractable Description Logics with Concrete Domains. Journal of Automated Reasoning 66, 3 (Aug. 2022), 357--407.
[11]
Patrick Blackburn, Maarten de Rijke, and Yde Venema. 2001. Modal Logic. Cambridge Tracts in Theoretical Computer Science, Vol. 53. Cambridge University Press.
[12]
Heinz-Dieter Ebbinghaus, Jörg Flum, and Wolfgang Thomas. 1994. Mathematical Logic (second ed.). Springer, New York, NY.
[13]
Ronald Fagin. 1976. Probabilities on Finite Models. Journal of Symbolic Logic 41, 1 (1976), 50--58.
[14]
Melvin Fitting. 1996. First-Order Logic and Automated Theorem Proving (2. ed ed.). Springer Science+Business Media, New York.
[15]
Erich Grädel, Martin Otto, and Eric Rosen. 1997. Two-Variable Logic with Counting is Decidable. In Proceedings, 12th Annual IEEE Symposium on Logic in Computer Science, Warsaw, Poland, June 29 - July 2, 1997. IEEE Computer Society, 306--317.
[16]
Ian Horrocks and Ulrike Sattler. 2001. Ontology Reasoning in the SHOQ(D) Description Logic. In Proceedings of the Seventeenth International Joint Conference on Artificial Intelligence, IJCAI 2001, Bernhard Nebel (Ed.). Morgan Kaufmann, 199--204.
[17]
Natasha Kurtonina and Maarten de Rijke. 1999. Expressiveness of Concept Expressions in First-Order Description Logics. Artificial Intelligence 107, 2 (1999), 303--333.
[18]
Carsten Lutz. 2002. Description Logics with Concrete Domains---A Survey. In Advances in Modal Logic 4, Philippe Balbiani, Nobu-Yuki Suzuki, Frank Wolter, and Michael Zakharyaschev (Eds.). King's College Publications, 265--296.
[19]
Carsten Lutz. 2004. NEXP TIME-complete description logics with concrete domains. ACM Transactions on Computational Logic (TOCL) 5, 4 (2004), 669--705.
[20]
Carsten Lutz and Maja Miličić. 2007. A Tableau Algorithm for Description Logics with Concrete Domains and General TBoxes. Journal of Automated Reasoning 38, 1 (April 2007), 227--259.
[21]
Roger Lyndon. 1959. An Interpolation Theorem in the Predicate Calculus. Pacific J. Math. 9, 1 (March 1959), 129--142. https://msp.org/pjm/1959/9-1/p12.xhtml
[22]
Leszek Pacholski, Wieslaw Szwast, and Lidia Tendera. 1997. Complexity of Two-Variable Logic with Counting. In Proceedings, 12th Annual IEEE Symposium on Logic in Computer Science. IEEE Computer Society, 318--327.
[23]
Ian Pratt-Hartmann. 2005. Complexity of the Two-Variable Fragment with Counting Quantifiers. J. Log. Lang. Inf. 14, 3 (2005), 369--395.
[24]
David A. Randell, Zhan Cui, and Anthony G. Cohn. 1992. A Spatial Logic based on Regions and Connection. In Proceedings of the 3rd International Conference on Principles of Knowledge Representation and Reasoning (KR'92), Bernhard Nebel, Charles Rich, and William R. Swartout (Eds.). Morgan Kaufmann, 165--176.
[25]
Ognjen Savkovic and Diego Calvanese. 2012. Introducing Datatypes in DL-Lite. In ECAI 2012 - 20th European Conference on Artificial Intelligence, Luc De Raedt, Christian Bessiere, Didier Dubois, Patrick Doherty, Paolo Frasconi, Fredrik Heintz, and Peter J. F. Lucas (Eds.). IOS Press, 720--725.
[26]
Manfred Schmidt-Schauß and Gert Smolka. 1991. Attributive Concept Descriptions with Complements. Artif. Intell. 48, 1 (1991), 1--26.
Index Terms
- The Abstract Expressive Power of First-Order and Description Logics with Concrete Domains
Recommendations
Logics with Concrete Domains: First-Order Properties, Abstract Expressive Power, and (Un)Decidability
Concrete domains have been introduced in description logic (DL) to enable reference to concrete objects (such as numbers) and predefined predicates on these objects (such as numerical comparisons) when defining concepts. The primary research goal in this ...
Expressiveness of concept expressions in first-order description logics
We introduce a method for characterizing the expressive power of concept expressions in first-order description logics. The method is essentially model-theoretic in nature in that it gives preservation results uniquely identifying a wide range of ...
A Tableau Algorithm for Description Logics with Concrete Domains and General TBoxes
In order to use description logics (DLs) in an application, it is crucial to identify a DL that is sufficiently expressive to represent the relevant notions of the application domain, but for which reasoning is still decidable. Two means of expressivity ...
Comments
Information & Contributors
Information
Published In
April 2024
1898 pages
This work is licensed under a Creative Commons Attribution International 4.0 License.
Sponsors
Publisher
Association for Computing Machinery
New York, NY, United States
Publication History
Published: 21 May 2024
Check for updates
Author Tags
Qualifiers
- Research-article
Funding Sources
Conference
SAC '24
Sponsor:
Acceptance Rates
Overall Acceptance Rate 1,650 of 6,669 submissions, 25%
Upcoming Conference
SAC '25
- Sponsor:
- sigapp
Contributors
Other Metrics
Bibliometrics & Citations
Bibliometrics
Article Metrics
- 0Total Citations
- 181Total Downloads
- Downloads (Last 12 months)181
- Downloads (Last 6 weeks)34
Reflects downloads up to 08 Feb 2025
Other Metrics
Citations
Cited By
View allView Options
Login options
Check if you have access through your login credentials or your institution to get full access on this article.
Sign in