Semantic e-Science

edited by Huajun Chen, Yimin Wang, Kei-Hoi Cheung

The Semantic Web has been a very important development in how knowledge is disseminated and manipulated on the Web, but it has been of particular importance to the flow of scientific knowledge, and will continue to shape how data is stored and accessed in a broad range of disciplines, including life sciences, earth science, materials science, and the social sciences. After first presenting papers on the foundations of semantic e-science, including papers on scientific knowledge acquisition, data integration, and workflow, this volume looks at the state of the art in each of the above-mentioned disciplines, presenting research on semantic web applications in the life, earth, materials, and social sciences. Drawing papers from three semantic web workshops, as well as papers from several invited contributors, this volume illustrates how far semantic web applications have come in helping to manage scientific information flow.

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Year of publication:	2010
Authors:	Chen, Huajun
Other Persons:	Wang, Yimin (contributor) ; Cheung, Kei-Hoi (contributor)
Publisher:	Boston, MA : Springer Science+Business Media, LLC
Subject:	Semantisches Web \| Semantic web \| Ontologie \| Ontology
Description of contents:	Table of Contents [gbv.de]

Extent:	Online-Ressource v.: digital
Series:	Annals of Information Systems ; 11
Type of publication:	Book / Working Paper
Language:	English
Notes:	Includes bibliographical references Preface; Contents; Contributors; About the Editors; 1 Supporting e-Science Using Semantic Web Technologies The Semantic Grid; 1.1 Introduction; 1.2 The e-Science Vision; 1.3 Semantic Grid: Service-Oriented Science; 1.4 Semantic Web Essentials; 1.5 Achieving the e-Science Vision; 1.5.1 Resource Description, Discovery, and Use; 1.5.2 Process Description and Enactment; 1.5.3 Autonomic Behaviour; 1.5.4 Security and Trust; 1.5.5 Annotation; 1.5.6 Information Integration; 1.5.7 Communities; 1.6 A Semantic Grid Approach to In Silico Bioinformatics; 1.7 A Semantic Datagrid for Chemistry 1.8 Architectures for the Semantic Grid1.8.1 S-OGSAA Reference Architecture for the Semantic Grid; 1.8.2 The Service-Oriented Knowledge Utility; 1.8.3 The Semantic Grid Community; 1.9 Moving Forward; 1.10 Summary; References; 2 Semantic Disclosure in an e-Science Environment; 2.1 Introduction; 2.1.1 Semantic Disclosure; 2.1.2 The Semantic Web; 2.1.3 Making Sense of the Digital Deluge; 2.1.4 Data Integration; 2.1.5 W3C Semantic Web for Health Care and Life Sciences Interest Group; 2.1.6 Semantic Architecture; 2.1.7 The Virtual Laboratory for e-Science Project; 2.2 The AIDA Toolkit 2.2.1 StorageThe Metadata Storage Module2.2.2 Learning -- The Machine Learning Module; 2.2.3 Search -- The Information Retrieval Module; 2.3 Applications of Adaptive Information Disclosure; 2.3.1 Food Informatics -- Adaptive Information Disclosure Collaboration; 2.3.2 A Metadata Management Approach to fMRI Data; 2.3.3 Semantic Disclosure in Support of Biological Experimentation; 2.3.3.1 Application Case 1: Semantic Disclosure of Human Genome Data; 2.3.3.2 Application Case 2: Semantic Disclosure of Biological Knowledge Trapped in Literature 2.3.3.3 An e-Science Approach for Extracting Knowledge from Text2.3.3.4 Conclusion; 2.4 Discussion; References; 3 A Smart e-Science Cyberinfrastructure for Cross-Disciplinary Scientific Collaborations; 3.1 Introduction; 3.2 Background; 3.2.1 Challenges for Smart e-Science; 3.2.2 Enabling Technologies for Smart e-Science; 3.2.2.1 Grid Computing; 3.2.2.2 Service-Oriented Architecture and Web Services; 3.2.2.3 Semantic Web and Ontology; 3.2.3 Contemporary Efforts in e-Science Cyberinfrastructure; 3.2.4 Case Study: Integration of Scientific Infrastructures; 3.3 The Smart e-Science Framework 3.3.1 The e-Science Ontology3.3.2 Grid-Based Service Orientation; 3.3.3 Service Interface; 3.3.4 Semantic Interface; 3.3.5 The Proxy; 3.3.6 Knowledgebase Design; 3.3.7 Data Exchange; 3.4 Implementation; 3.4.1 Ontology Design; 3.4.2 Server-Side Service Implementation; 3.4.3 Client-Side Service Implementation; 3.4.4 Fundamental and Composed Services; 3.4.4.1 Users and Application Services; 3.4.4.2 Sensor Resources Proxy Services; 3.4.4.3 Compute/Data Resources Services; 3.4.5 Conceptual and Semantic Schema; 3.5 Conclusions; References; 4 Developing Ontologies within Decentralised Settings 4.1 Introduction Cover13;Preface -- Contents -- Contributors -- About the Editors -- Chapter 1 Supporting e-Science Using Semantic Web Technologies The Semantic Grid -- 1.1 Introduction -- 1.2 The e-Science Vision -- 1.3 Semantic Grid: Service-Oriented Science -- 1.4 Semantic Web Essentials -- 1.5 Achieving the e-Science Vision -- 1.5.1 Resource Description, Discovery, and Use -- 1.5.2 Process Description and Enactment -- 1.5.3 Autonomic Behaviour -- 1.5.4 Security and Trust -- 1.5.5 Annotation -- 1.5.6 Information Integration -- 1.5.7 Communities -- 1.6 A Semantic Grid Approach to In Silico Bioinformatics -- 1.7 A Semantic Datagrid for Chemistry -- 1.8 Architectures for the Semantic Grid -- 1.8.1 S-OGSA -- A Reference Architecture for the Semantic Grid -- 1.8.2 The Service-Oriented Knowledge Utility -- 1.8.3 The Semantic Grid Community -- 1.9 Moving Forward -- 1.10 Summary -- References -- Chapter 2 Semantic Disclosure in an e-Science Environment -- 2.1 Introduction -- 2.1.1 Semantic Disclosure -- 2.1.2 The Semantic Web -- 2.1.3 Making Sense of the Digital Deluge -- 2.1.4 Data Integration -- 2.1.5 W3C Semantic Web for Health Care and Life Sciences Interest Group -- 2.1.6 Semantic Architecture -- 2.1.7 The Virtual Laboratory for e-Science Project -- 2.2 The AIDA Toolkit -- 2.2.1 Storage -- The Metadata Storage Module -- 2.2.2 Learning -- The Machine Learning Module -- 2.2.3 Search -- The Information Retrieval Module -- 2.3 Applications of Adaptive Information Disclosure -- 2.3.1 Food Informatics -- Adaptive Information Disclosure Collaboration -- 2.3.2 A Metadata Management Approach to fMRI Data -- 2.3.3 Semantic Disclosure in Support of Biological Experimentation -- 2.4 Discussion -- References -- Chapter 3 A Smart e-Science Cyberinfrastructure for Cross-Disciplinary Scientific Collaborations -- 3.1 Introduction -- 3.2 Background -- 3.2.1 Challenges for Smart e-Science -- 3.2.2 Enabling Technologies for Smart e-Science -- 3.2.3 Contemporary Efforts in e-Science Cyberinfrastructure -- 3.2.4 Case Study: Integration of Scientific Infrastructures -- 3.3 The Smart e-Science Framework -- 3.3.1 The e-Science Ontology -- 3.3.2 Grid-Based Service Orientation -- 3.3.3 Service Interface -- 3.3.4 Semantic Interface -- 3.3.5 The Proxy -- 3.3.6 Knowledgebase Design -- 3.3.7 Data Exchange -- 3.4 Implementation -- 3.4.1 Ontology Design -- 3.4.2 Server-Side Service Implementation -- 3.4.3 Client-Side Service Implementation -- 3.4.4 Fundamental and Composed Services -- 3.4.5 Conceptual and Semantic Schema -- 3.5 Conclusions -- References -- Chapter 4 Developing Ontologies within Decentralised Settings -- 4.1 Introduction -- 4.1.1 Decentralised Communities -- 4.1.2 Community-Driven Ontology Engineering -- 4.1.3 Upper Level Ontologies -- 4.1.4 Dynamic Ontologies -- 4.1.5 The Melting Point: A Methodology for Distributed Community-Driven Ontology Engineering -- 4.2 Review of Current Methodologies -- 4.2.1 Criteria for Review -- 4.2.2 Finding the Melting Point -- 4.3 The Melting Point Methodology -- 4.3.1 Definition of Terminology -- 4.3.2 Management Processes -- 4.3.3 Documentation Processes -- 4.3.4 Development-Oriented Processes -- 4.3.5 Evaluation -- 4.4 Discussion -- 4.4.1 Melting Point Evaluated -- 4.4.2 IEEE Standards Compliance -- 4.4.3 Quality Ass. Electronic reproduction; Available via World Wide Web
ISBN:	978-1-4419-5908-9 ; 978-1-4419-5902-7
Other identifiers:	10.1007/978-1-4419-5908-9 [DOI]
Source:	ECONIS - Online Catalogue of the ZBW

Persistent link: https://www.econbiz.de/10014275186