An important question for the upcoming Semantic Web is how to best combine open world ontology languages, such as the OWL-based ones, with closed world rule-based languages. One of the most mature proposals for this combination is known as hybrid MKNF knowledge bases [52], and it is based on an adaptation of the Stable Model Semantics to knowledge bases consisting of ontology axioms and rules. In this paper we propose a well-founded semantics for nondisjunctive hybrid MKNF knowledge bases that promises to provide better efficiency of reasoning, and that is compatible with both the OWL-based semantics and the traditional Well-Founded Semantics for logic programs. Moreover, our proposal allows for the detection of inconsistencies, possibly occurring in tightly integrated ontology axioms and rules, with only little additional effort. We also identify tractable fragments of the resulting language.

VL - 175 UR - http://dx.doi.org/10.1016/j.artint.2011.01.007 IS - 9-10 ER - TY - JOUR T1 - Computational Complexity and Anytime Algorithm for Inconsistency Measurement JF - International Journal of Software and Informatics Y1 - 2010 A1 - Yue Ma A1 - Guilin Qi A1 - Guohui Xiao A1 - Pascal Hitzler A1 - Zuoquan Lin KW - algorithm KW - computational complexity KW - inconsistency measurement KW - Knowledge representation KW - multi-valued logic AB -Measuring inconsistency degrees of inconsistent knowledge bases is an important problem as it provides context information for facilitating inconsistency handling. Many methods have been proposed to solve this problem and a main class of them is based on some kind of paraconsistent semantics. In this paper, we consider the computational aspects of inconsistency degrees of propositional knowledge bases under 4-valued semantics. We first give a complete analysis of the computational complexity of computing inconsistency degrees. As it turns out that computing the exact inconsistency degree is intractable, we then propose an anytime algorithm that provides tractable approximations of the inconsistency degree from above and below. We show that our algorithm satisfies some desirable properties and give experimental results of our implementation of the algorithm

VL - 4 UR - http://www.ijsi.org/ch/reader/view_abstract.aspx?file_no=i41&flag=1 ER - TY - JOUR T1 - A Reasonable Semantic Web JF - Semantic Web Y1 - 2010 A1 - Pascal Hitzler A1 - Frank van Harmelen KW - Automated Reasoning KW - Formal Semantics KW - Knowledge representation KW - Linked Open Data KW - Semantic Web AB -The realization of Semantic Web reasoning is central to substantiating the Semantic Web vision. However, current mainstream research on this topic faces serious challenges, which forces us to question established lines of research and to rethink the underlying approaches. We argue that reasoning for the Semantic Web should be understood as "shared inference," which is not necessarily based on deductive methods. Model-theoretic semantics (and sound and complete reasoning based on it) functions as a gold standard, but applications dealing with large-scale and noisy data usually cannot afford the required runtimes. Approximate methods, including deductive ones, but also approaches based on entirely different methods like machine learning or natureinspired computing need to be investigated, while quality assurance needs to be done in terms of precision and recall values (as in information retrieval) and not necessarily in terms of soundness and completeness of the underlying algorithms.

VL - 1 UR - http://dx.doi.org/10.3233/SW-2010-0010 ER -