Digitising the industry : : internet of things connecting the physical, digital and virtual worlds / / editors, Ovidiu Vermesan, Peter Friess.
This book provides an overview of the current Internet of Things (IoT) landscape, ranging from the research, innovation and development priorities to enabling technologies in a global context. A successful deployment of IoT technologies requires integration on all layers, be it cognitive and semanti...
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| Superior document: | River Publishers series in communications ; Volume 49 |
|---|---|
| TeilnehmendeR: | |
| Place / Publishing House: | Gistrup, Denmark : : River Publishers,, 2016. ©2016 |
| Year of Publication: | 2016 |
| Edition: | First edition. |
| Language: | English |
| Series: | River Publishers series in communications ;
Volume 49. |
| Physical Description: | 1 online resource (364 p.) |
| Notes: | Description based upon print version of record. |
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Table of Contents:
- Frontcover
- Half Title Page
- River Publishers Series in Communications
- Title Page - Digitising the Industry Internet of Things Connecting the Physical, Digital and Virtual Worlds
- Copyright Page
- Dedication
- Contents
- Preface
- Editors Biography
- List of Figures
- List of Tables
- Chapter 1 - Introduction
- Chapter 2 - IoT Ecosystems Implementing Smart Technologies to Drive Innovation for Future Growth and Development
- 2.1 Introduction
- 2.2 Support for IoT Ecosystem Creation
- 2.3 Spurring Innovation in Lead Markets
- 2.4 Outlook
- Chapter 3 - IoT Digital Value Chain Connecting Research, Innovation and Deployment
- 3.1 Internet of Things Vision
- 3.1.1 IoT Common Definition
- 3.1.2 Artificial Intelligence and Cognitive IoT
- 3.1.3 IoT of Robotic Things
- 3.2 IoT Strategic Research and Innovation Directions
- 3.3 IoT Smart Environments and Applications
- 3.3.1 Wearables
- 3.3.2 Smart Health,Wellness and AgeingWell
- 3.3.3 Smart Clothing
- 3.3.4 Smart Buildings and Architecture
- 3.3.5 Smart Energy
- 3.3.6 Smart Mobility and Transport
- 3.3.7 Industrial IoT and Smart Manufacturing
- 3.3.8 Smart Cities
- 3.3.8.1 Open Data and Ecosystem for Smart Cities
- 3.3.8.2 Citizen Centric Smart Cities IoT Applications and Deployments
- 3.3.9 Smart Farming and Food Security
- 3.3.9.1 Business Models and Innovation Ecosystems
- 3.3.9.2 Societal Aspects
- 3.3.9.3 Coordination among Different DGs, Programmes and Member States
- 3.3.9.4 Policy and Regulations
- 3.4 IoT and Related Future Internet Technologies
- 3.4.1 Cloud Computing
- 3.4.2 Edge Computing
- 3.5 Networks and Communication
- 3.5.1 Network Technology
- 3.5.2 Communication Technology
- 3.6 IoT Standardisation
- 3.7 IoT Security
- 3.7.1 IoT Security Framework based on Artificial Intelligence Concepts.
- 3.7.2 Self-protecting, Self-optimizing and Self-healing IoT Concepts
- 3.7.3 IoT Trust Framework
- 3.8 IoT Enabling the Digital Transformation of Industry
- Chapter 4 - Internet of Food and Farm 2020
- 4.1 Global Food Production - Setting the Scene
- 4.2 Smart Farming and Food: WhereWe Are Right Now
- 4.3 Farming, Food and IoT: WhereWe Are Going
- 4.4 Challenges
- 4.4.1 Technical Dimension
- 4.4.2 Non-Technical Dimension
- 4.5 Conclusions
- Chapter 5 - Internet of Things Applications in Future Manufacturing
- 5.1 Introduction
- 5.2 EU Initiatives and IoT Platforms for Digital Manufacturing
- 5.2.1 Future Manufacturing Value Chains
- 5.2.2 Recent EU Research Initiatives in Virtual Manufacturing
- 5.2.3 Levels of Manufacturing Digitisation
- 5.2.4 Industrie 4.0 Principles for CPS Manufacturing
- 5.2.5 Digital Manufacturing and IoT Platforms
- 5.2.6 Maturity Model for IoT in Manufacturing
- 5.3 Digital Factory Automation
- 5.3.1 Business Drivers
- 5.3.2 IoT Techniques for the Virtualization of Automation Pyramid
- 5.3.3 CPS-based Factory Simulation
- 5.3.4 IoT/CPS Production Workflows - Systems-of-Systems Automation
- 5.4 IoT Applications for Manufacturing
- 5.4.1 Proactive Maintenance
- 5.4.2 Mass Customisation
- 5.4.3 Reshoring
- 5.4.4 Safe HumanWorkplaces and HMIs
- 5.5 Future Outlook and Conclusions
- 5.5.1 Outlook and Directions for Future Research and Pilots
- 5.5.2 Conclusions
- Bibliography
- Chapter 6 - Trusted IoT in the Complex Landscape of Governance, Security, Privacy, Availability and Safety
- 6.1 Introduction
- 6.2 The Need for Evaluating Trust in IoT
- 6.3 Trust Management in IoT
- 6.4 Trust for Devices
- 6.4.1 Communication-based Trust
- 6.4.2 Security-based Trust
- 6.4.3 Data-Reliability based Trust
- 6.4.4 Social Relationship based Trust
- 6.4.5 Reputation based Trust.
- 6.5 Trust for IoT Services
- 6.6 Consent and Trust in Personal Data Sharing
- 6.7 Using Trust in Authorization
- 6.8 Using Trust in an Indoor Positioning Solution
- 6.9 Using Trust in Routing
- 6.10 Conclusions
- Chapter 7 - IoT Societal Impact - Legal Considerations and Perspectives
- 7.1 The Relevance of Hyperconnectivity
- 7.2 Unambiguous Definitions
- 7.3 Converging Markets
- 7.3.1 Things
- 7.3.2 Infrastructure
- 7.3.3 Data
- 7.3.4 Services
- 7.3.5 Connectivity and Interoperability
- 7.4 Relationships and Markets
- 7.5 What Are the Main Challenges
- 7.5.1 Common Understanding
- 7.5.2 Trust
- 7.5.3 Security
- 7.5.4 Personal Data Protection
- 7.5.5 Digital Right Management
- 7.5.6 Data Ownership and Data Access
- 7.5.7 Free Flow of Data
- 7.5.8 Accountability and Liability
- 7.5.9 Too Much Data?
- 7.5.10 Regulation and Standardisation
- 7.6 Multi-Angle Stakeholders IoT Ecosystem
- 7.6.1 Technology and People
- 7.6.2 Ethics and Accountability
- 7.6.3 Regulation and Standardisation
- 7.6.4 Contractual Relationships
- 7.6.5 Risk Allocation
- 7.7 Conclusion and Recommendations
- Chapter 8 - IoT Standards - State-of-the-Art Analysis
- 8.1 Introduction
- 8.2 Analysing the IoT Standards Landscape
- 8.2.1 AIOTI WG03
- 8.2.2 ETSI STF 505
- 8.2.3 UNIFY-IoT CSA
- 8.3 A Framework to Analyse IoT Standardization
- 8.3.1 Horizontal and Vertical Domains
- 8.3.1.1 Vertical Domains
- 8.3.1.2 IoT SDOs and Alliance Landscape
- 8.3.2 Knowledge Areas
- 8.3.3 High Level Architecture (HLA)
- 8.3.3.1 The AIOTI HLA
- 8.3.3.2 Mapping of the HLA:The Example of oneM2M
- 8.3.3.3 The STF 505 Enterprise IoT Framework
- 8.3.4 Status of Standardization in IoT
- 8.3.5 Overview of IoT Standards Landscape
- 8.3.5.1 Generic Cross Domain Standards
- 8.3.5.2 Domain Specific Standards
- 8.3.6 Identifying IoT Standards Gaps.
- 8.3.6.1 Defining Gaps
- 8.3.6.2 Identify Gaps: A User Survey
- 8.3.6.3 Example of Gaps
- 8.3.6.4 Status of Gaps Identification
- 8.3.7 Conclusions and Further Challenges
- Bibliography
- Chapter 9 - IoT Platforms Initiative
- 9.1 Introduction
- 9.1.1 AGILE Project: A Modular Adaptive Gateway for IoT
- 9.1.2 The Challenges
- 9.1.3 The AGILE Solution
- 9.1.4 The AGILE Use Cases
- 9.2 BIG IoT: Bridging the Interoperability Gap of the IoT
- 9.3 bIoTope: Building an IoT Open Innovation Ecosystem for Connected Smart Objects
- 9.3.1 Building Blocks Underlying the bIoTope Project
- 9.3.2 O-MI and O-DF Standards
- 9.3.3 Context-as-a-Service
- 9.3.4 bIoTope Large-Scale Pilots
- 9.4 INTER-IoT: Interoperability of Heterogeneous IoT Platforms
- 9.4.1 Open Interoperability
- 9.4.2 Use-Case Driven
- 9.5 symbIoTe: Symbiosis of Smart Objects Across IoT Environments
- 9.5.1 The Vision
- 9.5.2 The Technical Approach
- 9.5.3 The Use Cases
- 9.6 TagItSmart
- 9.6.1 Vision
- 9.6.2 Objectives
- 9.6.3 The Approach
- 9.6.4 Industry Impact
- 9.6.5 Use Cases
- 9.7 Vicinity
- 9.7.1 Challenges
- 9.7.2 VICINITY Solution
- 9.7.3 Demonstration and Impact
- 9.8 Be-IoT
- 9.9 UNIFY-IoT
- Chapter 10 - European IoT International Cooperation in Research and Innovation
- 10.1 Introduction
- 10.2 IoT in South Korea and Cooperation with EU
- 10.2.1 Open Innovation and Open Platform
- 10.2.2 Large-Scaled IoT Pilot Projects
- 10.2.3 Global Collaboration
- 10.3 Global IoT Challenges Seen from China
- 10.3.1 China Policy on IoT
- 10.3.2 IoT Applications in China
- 10.3.3 IoT Trends and Standards
- 10.3.4 The Internet and the Reconstruction of the Industrial Ecology
- 10.3.5 EU-China Cooperation Proposal in IoT
- 10.3.5.1 Policy Level Cooperation
- 10.3.5.2 Technical Cooperation
- 10.3.5.3 Standards Cooperation
- 10.3.5.4 Market Cooperation.
- 10.4 Adapting IoT to New Needs: Challenges from Brazil
- 10.4.1 IoT RD&
- I Funding in Brazil
- 10.4.2 IoT Success Cases in Brazil
- 10.4.2.1 RFID/IoT Change of Paradigm
- 10.4.2.2 Smart Metering and Smart Grids
- 10.4.3 International Standardisation Related to IoT
- 10.4.4 EU-Brazil Collaboration on IoT
- 10.4.4.1 EU-Brazil Joint Call for IoT Pilots RIAs
- 10.4.4.2 EU-Brazil Mapping and Comparative Study
- 10.4.4.3 The EU-Brazil FUTEBOL Project
- 10.4.4.4 FurtherWork on EU-Brazil Cooperation
- 10.5 Do More with Less: Challenges for Africa. Low-Cost IoT for Sub-Saharan African Applications
- 10.5.1 Lower-Cost, Longer-Range IoT Communications
- 10.5.2 Cost of IoT Hardware and Services
- 10.5.3 Limit Dependency to Proprietary Infrastructures, Provide Local Interaction Models
- 10.5.4 The H2020WAZIUP Project
- 10.6 EU-Japan Collaboration for aWorld Leading Research in IoT
- 10.6.1 ClouT: Cloud of Things for Empowering Citizen ClouT in Smart Cities
- 10.6.2 FESTIVAL Federated Interoperable Smart ICT Services Development and Testing Platform
- 10.6.3 iKaaS - Intelligent Knowledge as a Service
- 10.7 EU-US IoT Cooperation
- 10.7.1 Policy Level Cooperation
- 10.7.2 Technical Cooperation
- 10.7.3 Standards Cooperation
- 10.7.4 Market Cooperation
- 10.8 Conclusions: Cooperation to Balance Globalisationand Differentiation of IoT Solutions Worldwide
- Index
- Backcover.