Spelling suggestions: "subject:"ontologybased data access"" "subject:"ontology_based data access""
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Answering Object Queries over Knowledge Bases with Expressive Underlying Description LogicsWu, Jiewen January 2013 (has links)
Many information sources can be viewed as collections of objects and descriptions about objects. The relationship between objects is often characterized by a set of constraints that semantically encode background knowledge of some domain. The most straightforward and fundamental way to access information in these repositories is to search for objects that satisfy certain selection criteria. This work considers a description logics (DL) based representation of such information sources and object queries, which allows for automated reasoning over the constraints accompanying objects. Formally, a knowledge base K=(T, A) captures constraints in the terminology (a TBox) T, and objects with their descriptions in the assertions (an ABox) A, using some DL dialect L. In such a setting, object descriptions are L-concepts and object identifiers correspond to individual names occurring in K. Correspondingly, object queries are the well known problem of instance retrieval in the underlying DL knowledge base K, which returns the identifiers of qualifying objects.
This work generalizes instance retrieval over knowledge bases to provide users with answers in which both identifiers and descriptions of qualifying objects are given. The proposed query paradigm, called assertion retrieval, is favoured over instance retrieval since it provides more informative answers to users. A more compelling reason is related to performance: assertion retrieval enables a transfer of basic relational database techniques, such as caching and query rewriting, in the context of an assertion retrieval algebra.
The main contributions of this work are two-fold: one concerns optimizing the fundamental reasoning task that underlies assertion retrieval, namely, instance checking, and the other establishes a query compilation framework based on the assertion retrieval algebra. The former is necessary because an assertion retrieval query can entail a large volume of instance checking requests in the form of K|= a:C, where "a" is an individual name and "C" is a L-concept. This work thus proposes a novel absorption technique, ABox absorption, to improve instance checking. ABox absorption handles knowledge bases that have an expressive underlying dialect L, for instance, that requires disjunctive knowledge. It works particularly well when knowledge bases contain a large number of concrete domain concepts for object descriptions.
This work further presents a query compilation framework based on the assertion retrieval algebra to make assertion retrieval more practical. In the framework, a suite of rewriting rules is provided to generate a variety of query plans, with a focus on plans that avoid reasoning w.r.t. the background knowledge bases when sufficient cached results of earlier requests exist. ABox absorption and the query compilation framework have been implemented in a prototypical system, dubbed CARE Assertion Retrieval Engine (CARE). CARE also defines a simple yet effective cost model to search for the best plan generated by query rewriting. Empirical studies of CARE have shown that the proposed techniques in this work make assertion retrieval a practical application over a variety of domains.
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Answering Object Queries over Knowledge Bases with Expressive Underlying Description LogicsWu, Jiewen January 2013 (has links)
Many information sources can be viewed as collections of objects and descriptions about objects. The relationship between objects is often characterized by a set of constraints that semantically encode background knowledge of some domain. The most straightforward and fundamental way to access information in these repositories is to search for objects that satisfy certain selection criteria. This work considers a description logics (DL) based representation of such information sources and object queries, which allows for automated reasoning over the constraints accompanying objects. Formally, a knowledge base K=(T, A) captures constraints in the terminology (a TBox) T, and objects with their descriptions in the assertions (an ABox) A, using some DL dialect L. In such a setting, object descriptions are L-concepts and object identifiers correspond to individual names occurring in K. Correspondingly, object queries are the well known problem of instance retrieval in the underlying DL knowledge base K, which returns the identifiers of qualifying objects.
This work generalizes instance retrieval over knowledge bases to provide users with answers in which both identifiers and descriptions of qualifying objects are given. The proposed query paradigm, called assertion retrieval, is favoured over instance retrieval since it provides more informative answers to users. A more compelling reason is related to performance: assertion retrieval enables a transfer of basic relational database techniques, such as caching and query rewriting, in the context of an assertion retrieval algebra.
The main contributions of this work are two-fold: one concerns optimizing the fundamental reasoning task that underlies assertion retrieval, namely, instance checking, and the other establishes a query compilation framework based on the assertion retrieval algebra. The former is necessary because an assertion retrieval query can entail a large volume of instance checking requests in the form of K|= a:C, where "a" is an individual name and "C" is a L-concept. This work thus proposes a novel absorption technique, ABox absorption, to improve instance checking. ABox absorption handles knowledge bases that have an expressive underlying dialect L, for instance, that requires disjunctive knowledge. It works particularly well when knowledge bases contain a large number of concrete domain concepts for object descriptions.
This work further presents a query compilation framework based on the assertion retrieval algebra to make assertion retrieval more practical. In the framework, a suite of rewriting rules is provided to generate a variety of query plans, with a focus on plans that avoid reasoning w.r.t. the background knowledge bases when sufficient cached results of earlier requests exist. ABox absorption and the query compilation framework have been implemented in a prototypical system, dubbed CARE Assertion Retrieval Engine (CARE). CARE also defines a simple yet effective cost model to search for the best plan generated by query rewriting. Empirical studies of CARE have shown that the proposed techniques in this work make assertion retrieval a practical application over a variety of domains.
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Acesso a dados baseado em ontologias com NoSQL / Ontology-based data access with NoSQLBarbara Tieko Agena 27 November 2017 (has links)
O acesso a dados baseado em ontologia (OBDA, de Ontology-Based Data Access) propõe facilitar ao usuário acesso a dados sem o conhecimento específico de como eles estão armazenados em suas fontes. Para isso, faz-se uso de uma ontologia como camada conceitual de alto nível, explorando sua capacidade de descrever o domínio e lidar com a incompletude dos dados. Atualmente, os sistemas NoSQL (Not Only SQL) estão se tornando populares, oferecendo recursos que os sistemas de bancos de dados relacionais não suportam. Desta forma, surgiu a necessidade dos sistemas OBDA se moldarem a estes novos tipos de bancos de dados. O objetivo desta pesquisa é propor uma arquitetura nova para sistemas OBDA possibilitando o acesso a dados em bancos de dados relacionais e bancos de dados NoSQL. Para tal, foi proposta a utilização de um mapeamento mais simples responsável pela comunicação entre ontologia e bancos de dados. Foram construídos dois protótipos de sistemas OBDA para sistemas NoSQL e sistemas de bancos de dados relacional para uma validação empírica da arquitetura proposta neste trabalho. / Ontology-based data access (OBDA) proposes to facilitate user access to data without specific knowledge of how they are stored in their sources. For this, an ontology is used as a high level conceptual layer, exploring its capacity to describe the domain and deal with the incompleteness of the data. Currently, NoSQL (Not Only SQL) systems are becoming popular, offering features that relational database systems do not support. In this way, the need arose for shaping OBDA systems to deal with these new types of databases. The objective of this research is to propose a new architecture for OBDA systems allowing access to data in relational databases and NoSQL databases. For this, we propose the use of a simpler mapping responsible for the communication between ontology and databases. Two OBDA system prototypes were constructed: one for NoSQL systems and one for relational database systems for an empirical validation.
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Acesso a dados baseado em ontologias com NoSQL / Ontology-based data access with NoSQLAgena, Barbara Tieko 27 November 2017 (has links)
O acesso a dados baseado em ontologia (OBDA, de Ontology-Based Data Access) propõe facilitar ao usuário acesso a dados sem o conhecimento específico de como eles estão armazenados em suas fontes. Para isso, faz-se uso de uma ontologia como camada conceitual de alto nível, explorando sua capacidade de descrever o domínio e lidar com a incompletude dos dados. Atualmente, os sistemas NoSQL (Not Only SQL) estão se tornando populares, oferecendo recursos que os sistemas de bancos de dados relacionais não suportam. Desta forma, surgiu a necessidade dos sistemas OBDA se moldarem a estes novos tipos de bancos de dados. O objetivo desta pesquisa é propor uma arquitetura nova para sistemas OBDA possibilitando o acesso a dados em bancos de dados relacionais e bancos de dados NoSQL. Para tal, foi proposta a utilização de um mapeamento mais simples responsável pela comunicação entre ontologia e bancos de dados. Foram construídos dois protótipos de sistemas OBDA para sistemas NoSQL e sistemas de bancos de dados relacional para uma validação empírica da arquitetura proposta neste trabalho. / Ontology-based data access (OBDA) proposes to facilitate user access to data without specific knowledge of how they are stored in their sources. For this, an ontology is used as a high level conceptual layer, exploring its capacity to describe the domain and deal with the incompleteness of the data. Currently, NoSQL (Not Only SQL) systems are becoming popular, offering features that relational database systems do not support. In this way, the need arose for shaping OBDA systems to deal with these new types of databases. The objective of this research is to propose a new architecture for OBDA systems allowing access to data in relational databases and NoSQL databases. For this, we propose the use of a simpler mapping responsible for the communication between ontology and databases. Two OBDA system prototypes were constructed: one for NoSQL systems and one for relational database systems for an empirical validation.
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From Horn-SRIQ to Datalog: A Data-Independent Transformation that Preserves Assertion Entailment: Extended VersionCarral, David, González, Larry, Koopmann, Patrick 20 June 2022 (has links)
Ontology-based access to large data-sets has recently gained a lot of attention. To access data e_ciently, one approach is to rewrite the ontology into Datalog, and then use powerful Datalog engines to compute implicit entailments. Existing rewriting techniques support Description Logics (DLs) from ELH to Horn-SHIQ. We go one step further and present one such data-independent rewriting technique for Horn-SRIQ⊓, the extension of Horn-SHIQ that supports role chain axioms, an expressive feature prominently used in many real-world ontologies. We evaluated our rewriting technique on a large known corpus of ontologies. Our experiments show that the resulting rewritings are of moderate size, and that our approach is more efficient than state-of-the-art DL reasoners when reasoning with data-intensive ontologies. / This is an extended version of the article to appear in the proceedings of AAAI 2019.
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Temporal Query Answering in ELBorgwardt, Stefan, Thost, Veronika 20 June 2022 (has links)
Context-aware systems use data about their environment for adaptation at runtime, e.g., for optimization of power consumption or user experience. Ontology-based data access (OBDA) can be used to support the interpretation of the usually large amounts of data. OBDA augments query answering in databases by dropping the closed-world assumption (i.e., the data is not assumed to be complete any more) and by including domain knowledge provided by an ontology. We focus on a recently proposed temporalized query language that allows to combine conjunctive queries with the operators of the well-known propositional temporal logic LTL. In particular, we investigate temporalized OBDA w.r.t. ontologies in the DL EL, which allows for efficient reasoning and has been successfully applied in practice. We study both data and combined complexity of the query entailment problem.
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On Implementing Temporal Query Answering in DL-LiteThost, Veronika, Holste, Jan, Özçep, Özgür 20 June 2022 (has links)
Ontology-based data access augments classical query answering over fact bases by adopting the open-world assumption and by including domain knowledge provided by an ontology. We implemented temporal query answering w.r.t. ontologies formulated in the Description Logic DL-Lite. Focusing on temporal conjunctive queries (TCQs), which combine conjunctive queries via the operators of propositional linear temporal logic, we regard three approaches for answering them: an iterative algorithm that considers all data available; a window-based algorithm; and a rewriting approach, which translates the TCQs to be answered into SQL queries. Since the relevant ontological knowledge is already encoded into the latter queries, they can be answered by a standard database system. Our evaluation especially shows that implementations of both the iterative and the window-based algorithm answer TCQs within a few milliseconds, and that the former achieves a constant performance, even if data is growing over time.
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Temporal Query Answering w.r.t. DL-Lite-OntologiesBorgwardt, Stefan, Lippmann, Marcel, Thost, Veronika 20 June 2022 (has links)
Ontology-based data access (OBDA) generalizes query answering in relational databases. It allows to query a database by using the language of an ontology, abstracting from the actual relations of the database. For ontologies formulated in Description Logics of the DL-Lite family, OBDA can be realized by rewriting the query into a classical first-order query, e.g. an SQL query, by compiling the information of the ontology into the query. The query is then answered using classical database techniques. In this report, we consider a temporal version of OBDA. We propose a temporal query language that combines a linear temporal logic with queries over DL-Litecore-ontologies. This language is well-suited for expressing temporal properties of dynamical systems and is useful in context-aware applications that need to detect specific situations. Using a first-order rewriting approach, we transform our temporal queries into queries over a temporal database. We then present three approaches to answering the resulting queries, all having different advantages and drawbacks. / This revised version proves that the presented algorithm achieves a bounded history encoding.
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Reasoning with Temporal Properties over Axioms of DL-LiteBorgwardt, Stefan, Lippmann, Marcel, Thost, Veronika 20 June 2022 (has links)
Recently, a lot of research has combined description logics (DLs) of the DL-Lite family with temporal formalisms. Such logics are proposed to be used for situation recognition and temporalized ontology-based data access. In this report, we consider DL-Lite-LTL, in which axioms formulated in a member of the DL-Lite family are combined using the operators of propositional linear-time temporal logic (LTL). We consider the satisfiability problem of this logic in the presence of so-called rigid symbols whose interpretation does not change over time. In contrast to more expressive temporalized DLs, the computational complexity of this problem is the same as for LTL, even w.r.t. rigid symbols.
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On the Complexity of Temporal Query AnsweringBaader, Franz, Borgwardt, Stefan, Lippmann, Marcel 20 June 2022 (has links)
Ontology-based data access (OBDA) generalizes query answering in databases towards deduction since (i) the fact base is not assumed to contain complete knowledge (i.e., there is no closed world assumption), and (ii) the interpretation of the predicates occurring in the queries is constrained by axioms of an ontology. OBDA has been investigated in detail for the case where the ontology is expressed by an appropriate Description Logic (DL) and the queries are conjunctive queries. Motivated by situation awareness applications, we investigate an extension of OBDA to the temporal case. As query language we consider an extension of the well-known propositional temporal logic LTL where conjunctive queries can occur in place of propositional variables, and as ontology language we use the prototypical expressive DL ALC. For the resulting instance of temporalized OBDA, we investigate both data complexity and combined complexity of the query entailment problem.
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