Knowledge Representation and Rule Mining in Entity-Centric Knowledge Bases

The paper illustrates a system that implements a framework, which is oriented to the development of a modular knowledge base for a conversational agent. This solution improves the flexibility of intelligent conversational agents in managing conversations. The modularity of the system grants a concurrent and synergic use of different knowledge representation techniques. According to this choice, it is possible to use the most adequate methodology for managing a conversation for a specific domain, taking into account particular features of the dialogue or the user behavior. We illustrate the implementation of a proof-of-concept prototype: a set of modules exploiting different knowledge representation methodologies and capable of managing different conversation features has been developed. Each module is automatically triggered through a component, named corpus callosum, that selects in real time the most adequate chatbot knowledge module to activate.

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Web knowledge

Agency and the Semantic Web ◽

10.1093/oso/9780199292486.003.0008 ◽

2006 ◽

Author(s):

Christopher Walton

Keyword(s):

Semantic Web ◽

Knowledge Representation ◽

Knowledge Base ◽

Web Applications ◽

Semantic Network ◽

Knowledge Bases ◽

Web Standards ◽

Description Framework ◽

The Web

In the introductory chapter of this book, we discussed the means by which knowledge can be made available on the Web. That is, the representation of the knowledge in a form by which it can be automatically processed by a computer. To recap, we identified two essential steps that were deemed necessary to achieve this task: 1. We discussed the need to agree on a suitable structure for the knowledge that we wish to represent. This is achieved through the construction of a semantic network, which defines the main concepts of the knowledge, and the relationships between these concepts. We presented an example network that contained the main concepts to differentiate between kinds of cameras. Our network is a conceptualization, or an abstract view of a small part of the world. A conceptualization is defined formally in an ontology, which is in essence a vocabulary for knowledge representation. 2. We discussed the construction of a knowledge base, which is a store of knowledge about a domain in machine-processable form; essentially a database of knowledge. A knowledge base is constructed through the classification of a body of information according to an ontology. The result will be a store of facts and rules that describe the domain. Our example described the classification of different camera features to form a knowledge base. The knowledge base is expressed formally in the language of the ontology over which it is defined. In this chapter we elaborate on these two steps to show how we can define ontologies and knowledge bases specifically for the Web. This will enable us to construct Semantic Web applications that make use of this knowledge. The chapter is devoted to a detailed explanation of the syntax and pragmatics of the RDF, RDFS, and OWL Semantic Web standards. The resource description framework (RDF) is an established standard for knowledge representation on the Web. Taken together with the associated RDF Schema (RDFS) standard, we have a language for representing simple ontologies and knowledge bases on the Web.

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Efficient Results in Semantic Interoperability for Health Care

Yearbook of Medical Informatics ◽

10.15265/iy-2016-051 ◽

2016 ◽

Vol 25 (01) ◽

pp. 184-187

Author(s):

J. Charlet ◽

L. F. Soualmia ◽

Keyword(s):

Health Care ◽

Semantic Web ◽

Knowledge Representation ◽

Large Scale ◽

Recommendation System ◽

Clinical Care ◽

Knowledge Bases ◽

Semantic Interoperability ◽

The Third ◽

Research Activities

Summary Objectives: To summarize excellent current research in the field of Knowledge Representation and Management (KRM) within the health and medical care domain. Method: We provide a synopsis of the 2016 IMIA selected articles as well as a related synthetic overview of the current and future field activities. A first step of the selection was performed through MEDLINE querying with a list of MeSH descriptors completed by a list of terms adapted to the KRM section. The second step of the selection was completed by the two section editors who separately evaluated the set of 1,432 articles. The third step of the selection consisted of a collective work that merged the evaluation results to retain 15 articles for peer-review. Results: The selection and evaluation process of this Yearbook’s section on Knowledge Representation and Management has yielded four excellent and interesting articles regarding semantic interoperability for health care by gathering heterogeneous sources (knowledge and data) and auditing ontologies. In the first article, the authors present a solution based on standards and Semantic Web technologies to access distributed and heterogeneous datasets in the domain of breast cancer clinical trials. The second article describes a knowledge-based recommendation system that relies on ontologies and Semantic Web rules in the context of chronic diseases dietary. The third article is related to concept-recognition and text-mining to derive common human diseases model and a phenotypic network of common diseases. In the fourth article, the authors highlight the need for auditing the SNOMED CT. They propose to use a crowd-based method for ontology engineering. Conclusions: The current research activities further illustrate the continuous convergence of Knowledge Representation and Medical Informatics, with a focus this year on dedicated tools and methods to advance clinical care by proposing solutions to cope with the problem of semantic interoperability. Indeed, there is a need for powerful tools able to manage and interpret complex, large-scale and distributed datasets and knowledge bases, but also a need for user-friendly tools developed for the clinicians in their daily practice.

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COMBINING DEFAULT LOGIC DATABASES

International Journal of Cooperative Information Systems ◽

10.1142/s0218215794000181 ◽

1994 ◽

Vol 03 (03) ◽

pp. 319-348 ◽

Cited By ~ 4

Author(s):

CHITTA BARAL ◽

SARIT KRAUS ◽

JACK MINKER ◽

V. S. SUBRAHMANIAN

Keyword(s):

Knowledge Representation ◽

Knowledge Base ◽

Large Scale ◽

Future Generation ◽

Knowledge Bases ◽

Default Logic ◽

Integrity Constraints ◽

Specialized Knowledge ◽

The Past ◽

The Future

During the past decade, it has become increasingly clear that the future generation of large-scale knowledge bases will consist, not of one single isolated knowledge base, but a multiplicity of specialized knowledge bases that contain knowledge about different domains of expertise. These knowledge bases will work cooperatively, pooling together their varied bodies of knowledge, so as to be able to solve complex problems that no single knowledge base, by itself, would have been able to address successfully. In any such situation, inconsistencies are bound to arise. In this paper, we address the question: "Suppose we have a set of knowledge bases, KB1, …, KBn, each of which uses default logic as the formalism for knowledge representation, and a set of integrity constraints IC. What knowledge base constitutes an acceptable combination of KB1, …, KBn?"

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A hybrid knowledge representation approach to reusability of legal knowledge bases

Proceedings of the fifth international conference on Artificial intelligence and law - ICAIL '95 ◽

10.1145/222092.222249 ◽

1995 ◽

Cited By ~ 1

Author(s):

Ulrich Reimer ◽

Andreas Margelisch

Keyword(s):

Knowledge Representation ◽

Knowledge Bases ◽

Legal Knowledge ◽

Hybrid Knowledge

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A Framework for Reasoning about Dynamic Axioms in Description Logics

Proceedings of the Twenty-Ninth International Joint Conference on Artificial Intelligence ◽

10.24963/ijcai.2020/233 ◽

2020 ◽

Author(s):

Bartosz Bednarczyk ◽

Stephane Demri ◽

Alessio Mansutti

Keyword(s):

Knowledge Representation ◽

Knowledge Base ◽

Data Structures ◽

Description Logics ◽

Knowledge Bases ◽

Dynamic Data Structures ◽

Dynamic Data ◽

Logical Connectives ◽

Consistency Problem ◽

Natural Means

Description logics are well-known logical formalisms for knowledge representation. We propose to enrich knowledge bases (KBs) with dynamic axioms that specify how the satisfaction of statements from the KBs evolves when the interpretation is decomposed or recomposed, providing a natural means to predict the evolution of interpretations. Our dynamic axioms borrow logical connectives from separation logics, well-known specification languages to verify programs with dynamic data structures. In the paper, we focus on ALC and EL augmented with dynamic axioms, or to their subclass of positive dynamic axioms. The knowledge base consistency problem in the presence of dynamic axioms is investigated, leading to interesting complexity results, among which the problem for EL with positive dynamic axioms is tractable, whereas EL with dynamic axioms is undecidable.

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Knowledge Extraction from Domain-Specific Documents

Pattern and Data Analysis in Healthcare Settings - Advances in Medical Technologies and Clinical Practice ◽

10.4018/978-1-5225-0536-5.ch006 ◽

2017 ◽

pp. 106-123

Author(s):

Ram Kumar ◽

Shailesh Jaloree ◽

R. S. Thakur

Keyword(s):

Knowledge Representation ◽

Knowledge Base ◽

Knowledge Bases ◽

Domain Ontology ◽

Knowledge Based Systems ◽

Domain Specific ◽

Knowledge Based ◽

Representation Systems ◽

Terminological Confusion ◽

Knowledge Representation Systems

Knowledge-based systems have become widespread in modern years. Knowledge-base developers need to be able to share and reuse knowledge bases that they build. As a result, interoperability among different knowledge-representation systems is essential. Domain ontology seeks to reduce conceptual and terminological confusion among users who need to share various kind of information. This paper shows how these structures make it possible to bridge the gap between standard objects and Knowledge-based Systems.

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Commonsense Knowledge Representation II

Encyclopedia of Artificial Intelligence ◽

10.4018/978-1-59904-849-9.ch051 ◽

2011 ◽

pp. 334-336

Author(s):

Phillip Ein-Dor

Keyword(s):

Knowledge Representation ◽

Physical World ◽

Knowledge Bases ◽

Real Problem ◽

Commonsense Knowledge ◽

The Everyday ◽

Naive Physics ◽

Artificial World ◽

Representation Formalism ◽

Order Predicate Calculus

Early attempts to implement systems that understand commonsense knowledge did so for very restricted domains. For example, the Planes system [Waltz, 1978] knew real world facts about a fleet of airplanes and could answer questions about them put to it in English. It had, however, no behaviors, could not interpret the facts, draw inferences from them or solve problems, other than those that have to do with understanding the questions. At the other extreme, SHRDLU (Winograd, 1973) understood situations in its domain of discourse (which it perceived visually), accepted commands in natural language to perform behaviors in that domain and solved problems arising in execution of the commands; all these capabilities were restricted, however, to SHRDLU’s artificial world of colored toy blocks. Thus, in implemented systems it appears that there may be a trade off between the degree of realism of the domain and the number of capabilities that can be implemented. In the frames versus logic debate (see Commonsense Knowledge Representation I - Formalisms in this Encyclopedia), the real problem, in Israel’s (1983) opinion, is not the representation formalism itself, but rather that the facts of the commonsense world have not been formulated, and this is more critical than choice of a particular formalism. A notable attempt to formulate the “facts of the commonsense world” is that of Hayes [1978a, 1978b, 1979] under the heading of naïve physics. This work employs first-order predicate calculus to represent commonsense knowledge of the everyday physical world. The author of this survey has undertaken a similar effort with respect to commonsense business knowledge (Ein-Dor and Ginzberg 1989). Some broader attempts to formulate commonsense knowledge bases are cited in the section Commonsense Knowledge Bases.

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An Implemented Representation and Reasoning Systems for Creating and Exploiting Large Knowledge Bases of Narrative Information

Intelligent Databases ◽

10.4018/978-1-59904-120-9.ch007 ◽

2011 ◽

pp. 137-166

Author(s):

Gian Piero Zarri

Keyword(s):

Knowledge Representation ◽

Physical Object ◽

Knowledge Bases ◽

Hierarchical Organization ◽

Indirect Speech ◽

Reasoning Systems ◽

Knowledge Representation Language ◽

Representation Language ◽

Inference Techniques ◽

Information Link

In this chapter, we evoke first the ubiquity and the importance of the so-called ‘narrative’ information, showing that the usual ontological tools are unable to offer complete and reliable solutions for representing and exploiting this type of information. We then supply some details about NKRL (Narrative Knowledge Representation Language), a fully implemented knowledge representation and inferencing environment especially created for an ‘intelligent’ exploitation of narrative knowledge. The main innovation of NKRL consists in associating with the traditional ontologies of concepts an ‘ontology of events’, in other words, a new sort of hierarchical organization where the nodes correspond to n-ary structures representing formally generic classes of elementary events like ‘move a physical object’, ‘be present in a place’, or ‘send/receive a message’. More complex, second order tools based on the ‘reification’ principle allow one to encode the ‘connectivity phenomena’ like causality, goal, indirect speech, coordination, and subordination that, in narrative information, link together ‘elementary events’. The chapter includes a description of the inference techniques proper to NKRL, and some information about the last developments of this language.

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Artificial Intelligence-Based Knowledge Representation and Reasoning

Impact of AI Technologies on Teaching, Learning, and Research in Higher Education - Advances in Educational Technologies and Instructional Design ◽

10.4018/978-1-7998-4763-2.ch008 ◽

2021 ◽

pp. 134-149

Author(s):

Dimpal Tomar ◽

Pradeep Tomar

Keyword(s):

Artificial Intelligence ◽

Higher Education ◽

Knowledge Representation ◽

Knowledge Bases ◽

Knowledge Representation And Reasoning ◽

Artificial Intelligent ◽

Logical Interpretation ◽

Quality Of Higher Education ◽

The Right

The quality of higher education can be enhanced only by upgrading the content and skills towards knowledge. Hence, knowledge representation and reasoning play a chief role to represent the facts, beliefs, and information, and inferring the logical interpretation of represented knowledge stored in the knowledge bases. This chapter provide a broad overview of knowledge, representation, and reasoning along with the related art of study in the field of higher education. Various artificial intelligent-based knowledge representation and reasoning techniques and schemes are provided for better representation of facts, beliefs, and information. Various reasoning types are discussed in order to infer the right meaning of the knowledge followed by various issues of knowledge representation and reasoning. .

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