Internet of things - from research and innovation to market deployment / / editors, Dr. Ovidiu Vermesan, Dr. Peter Friess.
The book aims to provide a broad overview of various topics of Internet of Things from the research, innovation and development priorities to enabling technologies, nanoelectronics, cyber physical systems, architecture, interoperability and industrial applications. It is intended to be a standalone...
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| Superior document: | River Publishers Series in Communications |
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| Place / Publishing House: | Aalborg, Denmark : : River Publishers,, 2014. ©2014 |
| Year of Publication: | 2014 |
| Edition: | 1st ed. |
| Language: | English |
| Series: | River Publishers series in communications.
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| Physical Description: | 1 online resource (373 pages) :; color illustrations, charts. |
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Vermesan, Ovidiu edt Internet of things - from research and innovation to market deployment / editors, Dr. Ovidiu Vermesan, Dr. Peter Friess. 1st ed. Taylor & Francis 2014 Aalborg, Denmark : River Publishers, 2014. ©2014 1 online resource (373 pages) : color illustrations, charts. text rdacontent computer rdamedia online resource rdacarrier River Publishers Series in Communications Includes bibliographical references at the end of each chapters and index. Description based on online resource; title from PDF title page (ebrary, viewed August 27, 2016). The book aims to provide a broad overview of various topics of Internet of Things from the research, innovation and development priorities to enabling technologies, nanoelectronics, cyber physical systems, architecture, interoperability and industrial applications. It is intended to be a standalone book in a series that covers the Internet of Things activities of the IERC – Internet of Things European Research Cluster from technology to international cooperation and the global "state of play".The book builds on the ideas put forward by the European research Cluster on the Internet of Things Strategic Research Agenda and presents global views and state of the art results on the challenges facing the research, development and deployment of IoT at the global level. Internet of Things is creating a revolutionary new paradigm, with opportunities in every industry from Health Care, Pharmaceuticals, Food and Beverage, Agriculture, Computer, Electronics Telecommunications, Automotive, Aeronautics, Transportation Energy and Retail to apply the massive potential of the IoT to achieving real-world solutions. The beneficiaries will include as well semiconductor companies, device and product companies, infrastructure software companies, application software companies, consulting companies, telecommunication and cloud service providers. IoT will create new revenues annually for these stakeholders, and potentially create substantial market share shakeups due to increased technology competition. The IoT will fuel technology innovation by creating the means for machines to communicate many different types of information with one another while contributing in the increased value of information created by the number of interconnections among things and the transformation of the processed information into knowledge shared into the Internet of Everything. The success of IoT depends strongly on enabling technology development, market acceptance and standardization, which provides interoperability, compatibility, reliability, and effective operations on a global scale. The connected devices are part of ecosystems connecting people, processes, data, and things which are communicating in the cloud using the increased storage and computing power and pushing for standardization of communication and metadata. In this context security, privacy, safety, trust have to be address by the product manufacturers through the life cycle of their products from design to the support processes. The IoT developments address the whole IoT spectrum - from devices at the edge to cloud and datacentres on the backend and everything in between, through ecosystems are created by industry, research and application stakeholders that enable real-world use cases to accelerate the Internet of Things and establish open interoperability standards and common architectures for IoT solutions. Enabling technologies such as nanoelectronics, sensors/actuators, cyber-physical systems, intelligent device management, smart gateways, telematics, smart network infrastructure, cloud computing and software technologies will create new products, new services, new interfaces by creating smart environments and smart spaces with applications ranging from Smart Cities, smart transport, buildings, energy, grid, to smart health and life. Technical topics discussed in the book include: • Introduction• Internet of Things Strategic Research and Innovation Agenda• Internet of Things in the industrial context: Time for deployment.• Integration of heterogeneous smart objects, applications and services• Evolution from device to semantic and business interoperability• Software define and virtualization of network resources• Innovation through interoperability and standardisation when everything is connected anytime at anyplace• Dynamic context-aware scalable and trust-based IoT Security, Privacy framework• Federated Cloud service management and the Internet of Things• Internet of Things Applications English European Commission cover -- RIVER PUBLISHERS SERIES IN COMMUNICATIONS -- Tittle - Internet of Things From Research and Innovation to Market Deployment -- Copyright -- Dedication -- Acknowledgement -- Contents -- Preface -- Shaping the Future of Internet of Things Applications -- Editors Biography -- 1 Introduction -- 2 Putting the Internet of Things Forwardto the Next Nevel -- 2.1 The Internet of Things Today -- 2.2 The Internet of Things Tomorrow -- 2.3 Potential Success Factors -- References -- 3 Internet of Things Strategic Research and Innovation Agenda -- 3.1 Internet of Things Vision -- 3.1.1 Internet of Things Common Definition -- 3.2 IoT Strategic Research and Innovation Directions -- 3.2.1 IoT Applications and Use Case Scenarios -- 3.2.2 IoT Functional View -- 3.2.3 Application Areas -- 3.3 IoT Smart-X Applications -- 3.3.1 Smart Cities -- 3.3.2 Smart Energy and the Smart GridThere is increasing public awareness about the -- 3.3.3 Smart Mobility and Transport -- 3.3.4 Smart Home, Smart Buildings and Infrastructure -- 3.3.5 Smart Factory and Smart Manufacturing -- 3.3.6 Smart Health -- 3.3.7 Food andWater Tracking and Security -- 3.3.8 Participatory Sensing -- 3.3.9 Smart Logistics and Retail -- 3.4 Internet of Things and Related Future Internet Technologies -- 3.4.1 Cloud Computing -- 3.4.2 IoT and Semantic Technologies -- 3.5 Networks and Communication -- 3.5.1 Networking Technology -- 3.5.2 Communication Technology -- 3.5.2.1 Unfolding the potential of communication technologies -- 3.5.2.2 Correctness of construction -- 3.5.2.3 An unified theoretical framework for communication -- 3.5.2.4 Energy-limited Internet of Things devices and their communication -- 3.5.2.5 Challenge the trend to complexity -- 3.5.2.6 Disruptive approaches -- 3.5.1.1 Complexity of the networks of the future -- 3.5.1.2 Growth of wireless networks -- 3.5.1.3 Mobile networks. 3.5.1.4 Expanding current networks to future networks -- 3.5.1.5 Overlay networks -- 3.5.1.6 Network self-organization -- 3.5.1.7 IPv6, IoT and Scalability -- 3.5.1.8 Green networking technology -- 3.6 Processes -- 3.6.1 Adaptive and Event-Driven Processes -- 3.6.2 Processes Dealing with Unreliable Data -- 3.6.3 Processes dealing with unreliable resources -- 3.6.4 Highly Distributed Processes -- 3.7 Data Management -- 3.7.1 Data Collection and Analysis (DCA) -- 3.7.2 Big Data -- 3.7.3 Semantic Sensor Networks and Semantic Annotation of data -- 3.7.4 Virtual Sensors -- 3.8 Security, Privacy & -- Trust -- 3.8.1 Trust for IoT -- 3.8.2 Security for IoT -- 3.8.3 Privacy for IoT -- 3.9 Device Level Energy Issues -- 3.9.1 Low Power Communication -- 3.9.2 Energy Harvesting -- 3.9.3 Future Trends and Recommendations -- 3.10 IoT Related Standardization -- 3.10.1 The Role of Standardization Activities -- 3.10.2 Current Situation -- 3.10.3 Areas for Additional Consideration -- 3.10.4 Interoperability in the Internet-of-Things -- 3.10.4.1 IoT Interoperability necessary framework -- 3.10.4.2 Technical IoT Interoperability -- 3.11 IoT Protocols Convergence -- 3.11.1 Message Queue Telemetry Transport (MQTT) -- 3.11.2 Constrained Applications Protocol (CoAP) -- 3.11.3 Advanced Message Queuing Protocol (AMQP) -- 3.11.4 Java Message Service API (JMS) -- 3.11.5 Data Distribution Service (DDS) -- 3.11.6 Representational State Transfer (REST) -- 3.11.7 Extensible Messaging and Presence Protocol (XMPP) -- 3.12 Discussion -- Acknowledgments -- List of Contributors -- List of Abbreviations and Acronyms -- 4 Internet of Things Global Standardisation - State of Play -- 4.1 Introduction -- 4.1.1 General -- 4.2 IoT Vision -- 4.2.1 IoT Drivers -- 4.2.2 IoT Definition -- 4.3 IoT Standardisation Landscape -- 4.3.1 CEN/ISO and CENELEC/IEC -- 4.3.1.1 CEN/CENELEC overview. 4.3.1.2 CEN technical bodies -- 4.3.1.3 European standards -- 4.3.1.4 Technical specifications -- 4.3.1.6 CENELEC workshop agreements (CWA) -- 4.3.1.7 CEN members -- 4.3.1.8 CEN/TC 225 -- 4.3.1.9 CENELEC -- 4.3.1.10 Smart grids: EC Mandate M/490 -- 4.3.1.11 ISO/IEC JTC 1/SWG 05 on the Internet of Things (IoT) -- 4.3.1.12 ISO/IEC JTC 1/WG 7 Sensor Networks -- 4.3.1.13 ISO/IEC JTC 1/SC 31 Automatic identification and data capture techniques -- 4.3.2 ETSI -- 4.3.3 IEEE -- 4.3.3.1 Overview -- 4.3.3.2 Cloud Computing -- 4.3.3.3 eHealth -- 4.3.3.4 eLearning -- 4.3.3.5 Intelligent Transportation Systems (ITS) -- 4.3.3.6 Network and Information Security (NIS) -- 4.3.3.7 Smart Grid -- 4.3.4 IETF -- 4.3.5 ITU-T -- 4.3.6 OASIS -- 4.3.6.1 Transactional Reliability -- 4.3.6.2 Modularity, reusability, and devices in the cloud -- 4.3.6.3 All that big data from all those things: access control, cybersecurity and privacy -- 4.3.6.4 Access control -- 4.3.6.5 Encryption and cybersecurity -- 4.3.6.6 Privacy -- 4.3.7 OGC -- 4.3.8 oneM2M -- 4.3.9 GS1 -- 4.3.9.1 The Role of Standards -- 4.3.9.2 GS1 Standards: Identify, Capture, Share -- 4.3.9.3 Looking forward -- 4.4 IERC Research Projects Positions -- 4.4.1 BETaaS Advisory Board Experts Position -- 4.4.2 IoT6 Position -- 4.5 Conclusions -- References -- 5 Dynamic Context-Aware Scalable and Trust-based IoT Security, Privacy Framework -- 5.1 Introduction -- 5.2 BackgroundWork -- 5.3 Main Concepts and Motivation of the Framework -- 5.3.1 Identity Management -- 5.3.2 Size and Heterogeneity of the System -- 5.3.3 Anonymization of User Data and Metadata -- 5.3.4 Action's Control -- 5.3.5 Privacy by Design -- 5.3.6 Context Awareness -- 5.3.7 Summary -- 5.4 A Policy-based Framework for Security and Privacy in Internet of Things -- 5.4.1 Deployment in a Scenario -- 5.4.2 Policies and Context Switching. 5.4.3 Framework Architecture and Enforcement -- 5.5 Conclusion and Future Developments -- 5.6 Acknowledgments -- References -- 6 Scalable Integration Framework for Heterogeneous Smart Objects, Applications and Services -- 6.1 Introduction -- 6.2 IPv6 Potential -- 6.3 IoT6 -- 6.4 IPv6 for IoT -- 6.5 Adapting IPv6 to IoT Requirements -- 6.6 IoT6 Architecture -- 6.7 DigCovery -- 6.8 IoT6 Integration with the Cloud and EPICS -- 6.9 Enabling Heterogeneous Integration -- 6.10 IoT6 Smart Office Use-case -- 6.11 Scalability Perspective -- 6.12 Conclusions -- References -- 7 Internet of Things Applications - From Research and Innovation to Market Deployment -- 7.1 Introduction -- 7.2 OpenIoT -- 7.2.1 Project Design and Implementation -- 7.2.2 Execution and Implementation Issues -- 7.2.3 Project Results -- 7.2.4 Acceptance and Sustainability -- 7.2.5 Discussion -- 7.3 iCORE -- 7.3.1 Design -- 7.3.1.1 Smart home and assisted living -- 7.3.1.2 Smart business and logistics -- 7.3.1.3 Smart-city - transportation -- 7.3.1.4 Smart meeting -- 7.3.1.5 Rationale for chosen use cases -- 7.3.2 Project Execution -- 7.3.3 Results Achieved -- 7.3.3.1 Smart tourism trial -- 7.3.3.2 Smart urban security trial -- 7.3.3.3 Smart asset management trial -- 7.3.3.4 Smart amusement park trial -- 7.4 COMPOSE -- 7.4.1 Project Design and Implementation -- 7.4.2 The IoT Communication Technologies -- 7.4.3.1 The COMPOSE services -- 7.4.3.2 The back-end technologies -- 7.4.3 Execution and Implementation Issues -- 7.4.4 Expected Project results -- 7.4.4.1 Smart Spaces -- 7.4.4.2 Smart City -- 7.4.4.3 Smart territory -- 7.5 SmartSantander -- 7.5.1 How SmartSantander Facility has Become a Reality? -- 7.5.2 Massive Experimentation Facility: A Fire Perspective -- 7.5.3 City Services Implementation:The Smart City Paradigm -- 7.5.3.1 Parking service management. 7.5.3.2 Traffic intensity monitoring -- 7.5.3.3 Environmental monitoring -- 7.5.3.4 Parks and gardens irrigation -- 7.5.3.5 Citizens apps -- 7.5.4 Sustainability Plan -- 7.6 FITMAN -- 7.6.1 The "IoT for Manufacturing"Trials in FITMAN -- 7.6.2 FITMAN Trials' Requirements to "IoT for Manufacturing" -- 7.6.3 The TRW and Whirlpool Smart Factory Trial -- 7.6.4 FITMAN Trials' Exploitation Plans & -- Business Opportunities -- 7.6.5 Conclusions and Future Outlook -- 7.7 OSMOSE -- 7.7.1 The AW and EPC "IoT for Manufacturing"Test Cases -- 7.7.2 OSMOSE Use Cases' Requirements to "IoT for Manufacturing" -- 7.7.3 OSMOSE Use Cases' Exploitation Plans & -- Business Opportunities -- 7.7.4 Conclusions and Future Outlook -- Acknowledgments -- List of Contributors -- Contributing Projects and Initiatives -- References -- 8 Bringing IP to Low-power Smart Objects: The Smart Parking Case in the CALIPSO Project -- Abstract -- 8.1 Introduction -- 8.1.1 Bringing IP to Energy-Constrained Devices -- 8.1.2 The CALIPSO Project -- 8.2 Smart Parking -- 8.3 CALIPSO Architecture -- 8.3.1 CALIPSO Communication Modules -- 8.3.1.1 MAC layer -- 8.3.1.2 Routing layer -- 8.3.1.3 Application layer -- 8.3.2 CALIPSO Security Modules -- 8.4 Calipso Implementation and Experimentation with Smart Parking -- 8.4.1 Implementation of Calipso Modules -- 8.4.2 Experimentation Plan for Smart Parking -- 8.4.2.1 Prototype description -- 8.4.2.2 Description of the scenario -- 8.4.2.3 Performance indicators -- 8.5 Concluding Remarks -- Acknowledgements -- References -- 9 Insights on Federated Cloud Service Management and the Internet of Things -- Abstract -- 9.1 Introduction -- 9.2 Federated Cloud Services Management -- 9.2.1 Cloud Data Management -- 9.2.2 Cloud Data Monitoring -- 9.2.3 Cloud Data Exchange -- 9.2.4 Infrastructure Configuration and re-Configuration. 9.3 Federated Management Service Life Cycle. Internet. Communications engineering / telecommunications Vermesan, Ovidiu, editor. Friess, Peter, editor. 87-93102-94-1 River Publishers series in communications. |
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Vermesan, Ovidiu, Friess, Peter, |
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| title |
Internet of things - from research and innovation to market deployment / |
| spellingShingle |
Internet of things - from research and innovation to market deployment / River Publishers Series in Communications cover -- RIVER PUBLISHERS SERIES IN COMMUNICATIONS -- Tittle - Internet of Things From Research and Innovation to Market Deployment -- Copyright -- Dedication -- Acknowledgement -- Contents -- Preface -- Shaping the Future of Internet of Things Applications -- Editors Biography -- 1 Introduction -- 2 Putting the Internet of Things Forwardto the Next Nevel -- 2.1 The Internet of Things Today -- 2.2 The Internet of Things Tomorrow -- 2.3 Potential Success Factors -- References -- 3 Internet of Things Strategic Research and Innovation Agenda -- 3.1 Internet of Things Vision -- 3.1.1 Internet of Things Common Definition -- 3.2 IoT Strategic Research and Innovation Directions -- 3.2.1 IoT Applications and Use Case Scenarios -- 3.2.2 IoT Functional View -- 3.2.3 Application Areas -- 3.3 IoT Smart-X Applications -- 3.3.1 Smart Cities -- 3.3.2 Smart Energy and the Smart GridThere is increasing public awareness about the -- 3.3.3 Smart Mobility and Transport -- 3.3.4 Smart Home, Smart Buildings and Infrastructure -- 3.3.5 Smart Factory and Smart Manufacturing -- 3.3.6 Smart Health -- 3.3.7 Food andWater Tracking and Security -- 3.3.8 Participatory Sensing -- 3.3.9 Smart Logistics and Retail -- 3.4 Internet of Things and Related Future Internet Technologies -- 3.4.1 Cloud Computing -- 3.4.2 IoT and Semantic Technologies -- 3.5 Networks and Communication -- 3.5.1 Networking Technology -- 3.5.2 Communication Technology -- 3.5.2.1 Unfolding the potential of communication technologies -- 3.5.2.2 Correctness of construction -- 3.5.2.3 An unified theoretical framework for communication -- 3.5.2.4 Energy-limited Internet of Things devices and their communication -- 3.5.2.5 Challenge the trend to complexity -- 3.5.2.6 Disruptive approaches -- 3.5.1.1 Complexity of the networks of the future -- 3.5.1.2 Growth of wireless networks -- 3.5.1.3 Mobile networks. 3.5.1.4 Expanding current networks to future networks -- 3.5.1.5 Overlay networks -- 3.5.1.6 Network self-organization -- 3.5.1.7 IPv6, IoT and Scalability -- 3.5.1.8 Green networking technology -- 3.6 Processes -- 3.6.1 Adaptive and Event-Driven Processes -- 3.6.2 Processes Dealing with Unreliable Data -- 3.6.3 Processes dealing with unreliable resources -- 3.6.4 Highly Distributed Processes -- 3.7 Data Management -- 3.7.1 Data Collection and Analysis (DCA) -- 3.7.2 Big Data -- 3.7.3 Semantic Sensor Networks and Semantic Annotation of data -- 3.7.4 Virtual Sensors -- 3.8 Security, Privacy & -- Trust -- 3.8.1 Trust for IoT -- 3.8.2 Security for IoT -- 3.8.3 Privacy for IoT -- 3.9 Device Level Energy Issues -- 3.9.1 Low Power Communication -- 3.9.2 Energy Harvesting -- 3.9.3 Future Trends and Recommendations -- 3.10 IoT Related Standardization -- 3.10.1 The Role of Standardization Activities -- 3.10.2 Current Situation -- 3.10.3 Areas for Additional Consideration -- 3.10.4 Interoperability in the Internet-of-Things -- 3.10.4.1 IoT Interoperability necessary framework -- 3.10.4.2 Technical IoT Interoperability -- 3.11 IoT Protocols Convergence -- 3.11.1 Message Queue Telemetry Transport (MQTT) -- 3.11.2 Constrained Applications Protocol (CoAP) -- 3.11.3 Advanced Message Queuing Protocol (AMQP) -- 3.11.4 Java Message Service API (JMS) -- 3.11.5 Data Distribution Service (DDS) -- 3.11.6 Representational State Transfer (REST) -- 3.11.7 Extensible Messaging and Presence Protocol (XMPP) -- 3.12 Discussion -- Acknowledgments -- List of Contributors -- List of Abbreviations and Acronyms -- 4 Internet of Things Global Standardisation - State of Play -- 4.1 Introduction -- 4.1.1 General -- 4.2 IoT Vision -- 4.2.1 IoT Drivers -- 4.2.2 IoT Definition -- 4.3 IoT Standardisation Landscape -- 4.3.1 CEN/ISO and CENELEC/IEC -- 4.3.1.1 CEN/CENELEC overview. 4.3.1.2 CEN technical bodies -- 4.3.1.3 European standards -- 4.3.1.4 Technical specifications -- 4.3.1.6 CENELEC workshop agreements (CWA) -- 4.3.1.7 CEN members -- 4.3.1.8 CEN/TC 225 -- 4.3.1.9 CENELEC -- 4.3.1.10 Smart grids: EC Mandate M/490 -- 4.3.1.11 ISO/IEC JTC 1/SWG 05 on the Internet of Things (IoT) -- 4.3.1.12 ISO/IEC JTC 1/WG 7 Sensor Networks -- 4.3.1.13 ISO/IEC JTC 1/SC 31 Automatic identification and data capture techniques -- 4.3.2 ETSI -- 4.3.3 IEEE -- 4.3.3.1 Overview -- 4.3.3.2 Cloud Computing -- 4.3.3.3 eHealth -- 4.3.3.4 eLearning -- 4.3.3.5 Intelligent Transportation Systems (ITS) -- 4.3.3.6 Network and Information Security (NIS) -- 4.3.3.7 Smart Grid -- 4.3.4 IETF -- 4.3.5 ITU-T -- 4.3.6 OASIS -- 4.3.6.1 Transactional Reliability -- 4.3.6.2 Modularity, reusability, and devices in the cloud -- 4.3.6.3 All that big data from all those things: access control, cybersecurity and privacy -- 4.3.6.4 Access control -- 4.3.6.5 Encryption and cybersecurity -- 4.3.6.6 Privacy -- 4.3.7 OGC -- 4.3.8 oneM2M -- 4.3.9 GS1 -- 4.3.9.1 The Role of Standards -- 4.3.9.2 GS1 Standards: Identify, Capture, Share -- 4.3.9.3 Looking forward -- 4.4 IERC Research Projects Positions -- 4.4.1 BETaaS Advisory Board Experts Position -- 4.4.2 IoT6 Position -- 4.5 Conclusions -- References -- 5 Dynamic Context-Aware Scalable and Trust-based IoT Security, Privacy Framework -- 5.1 Introduction -- 5.2 BackgroundWork -- 5.3 Main Concepts and Motivation of the Framework -- 5.3.1 Identity Management -- 5.3.2 Size and Heterogeneity of the System -- 5.3.3 Anonymization of User Data and Metadata -- 5.3.4 Action's Control -- 5.3.5 Privacy by Design -- 5.3.6 Context Awareness -- 5.3.7 Summary -- 5.4 A Policy-based Framework for Security and Privacy in Internet of Things -- 5.4.1 Deployment in a Scenario -- 5.4.2 Policies and Context Switching. 5.4.3 Framework Architecture and Enforcement -- 5.5 Conclusion and Future Developments -- 5.6 Acknowledgments -- References -- 6 Scalable Integration Framework for Heterogeneous Smart Objects, Applications and Services -- 6.1 Introduction -- 6.2 IPv6 Potential -- 6.3 IoT6 -- 6.4 IPv6 for IoT -- 6.5 Adapting IPv6 to IoT Requirements -- 6.6 IoT6 Architecture -- 6.7 DigCovery -- 6.8 IoT6 Integration with the Cloud and EPICS -- 6.9 Enabling Heterogeneous Integration -- 6.10 IoT6 Smart Office Use-case -- 6.11 Scalability Perspective -- 6.12 Conclusions -- References -- 7 Internet of Things Applications - From Research and Innovation to Market Deployment -- 7.1 Introduction -- 7.2 OpenIoT -- 7.2.1 Project Design and Implementation -- 7.2.2 Execution and Implementation Issues -- 7.2.3 Project Results -- 7.2.4 Acceptance and Sustainability -- 7.2.5 Discussion -- 7.3 iCORE -- 7.3.1 Design -- 7.3.1.1 Smart home and assisted living -- 7.3.1.2 Smart business and logistics -- 7.3.1.3 Smart-city - transportation -- 7.3.1.4 Smart meeting -- 7.3.1.5 Rationale for chosen use cases -- 7.3.2 Project Execution -- 7.3.3 Results Achieved -- 7.3.3.1 Smart tourism trial -- 7.3.3.2 Smart urban security trial -- 7.3.3.3 Smart asset management trial -- 7.3.3.4 Smart amusement park trial -- 7.4 COMPOSE -- 7.4.1 Project Design and Implementation -- 7.4.2 The IoT Communication Technologies -- 7.4.3.1 The COMPOSE services -- 7.4.3.2 The back-end technologies -- 7.4.3 Execution and Implementation Issues -- 7.4.4 Expected Project results -- 7.4.4.1 Smart Spaces -- 7.4.4.2 Smart City -- 7.4.4.3 Smart territory -- 7.5 SmartSantander -- 7.5.1 How SmartSantander Facility has Become a Reality? -- 7.5.2 Massive Experimentation Facility: A Fire Perspective -- 7.5.3 City Services Implementation:The Smart City Paradigm -- 7.5.3.1 Parking service management. 7.5.3.2 Traffic intensity monitoring -- 7.5.3.3 Environmental monitoring -- 7.5.3.4 Parks and gardens irrigation -- 7.5.3.5 Citizens apps -- 7.5.4 Sustainability Plan -- 7.6 FITMAN -- 7.6.1 The "IoT for Manufacturing"Trials in FITMAN -- 7.6.2 FITMAN Trials' Requirements to "IoT for Manufacturing" -- 7.6.3 The TRW and Whirlpool Smart Factory Trial -- 7.6.4 FITMAN Trials' Exploitation Plans & -- Business Opportunities -- 7.6.5 Conclusions and Future Outlook -- 7.7 OSMOSE -- 7.7.1 The AW and EPC "IoT for Manufacturing"Test Cases -- 7.7.2 OSMOSE Use Cases' Requirements to "IoT for Manufacturing" -- 7.7.3 OSMOSE Use Cases' Exploitation Plans & -- Business Opportunities -- 7.7.4 Conclusions and Future Outlook -- Acknowledgments -- List of Contributors -- Contributing Projects and Initiatives -- References -- 8 Bringing IP to Low-power Smart Objects: The Smart Parking Case in the CALIPSO Project -- Abstract -- 8.1 Introduction -- 8.1.1 Bringing IP to Energy-Constrained Devices -- 8.1.2 The CALIPSO Project -- 8.2 Smart Parking -- 8.3 CALIPSO Architecture -- 8.3.1 CALIPSO Communication Modules -- 8.3.1.1 MAC layer -- 8.3.1.2 Routing layer -- 8.3.1.3 Application layer -- 8.3.2 CALIPSO Security Modules -- 8.4 Calipso Implementation and Experimentation with Smart Parking -- 8.4.1 Implementation of Calipso Modules -- 8.4.2 Experimentation Plan for Smart Parking -- 8.4.2.1 Prototype description -- 8.4.2.2 Description of the scenario -- 8.4.2.3 Performance indicators -- 8.5 Concluding Remarks -- Acknowledgements -- References -- 9 Insights on Federated Cloud Service Management and the Internet of Things -- Abstract -- 9.1 Introduction -- 9.2 Federated Cloud Services Management -- 9.2.1 Cloud Data Management -- 9.2.2 Cloud Data Monitoring -- 9.2.3 Cloud Data Exchange -- 9.2.4 Infrastructure Configuration and re-Configuration. 9.3 Federated Management Service Life Cycle. |
| title_full |
Internet of things - from research and innovation to market deployment / editors, Dr. Ovidiu Vermesan, Dr. Peter Friess. |
| title_fullStr |
Internet of things - from research and innovation to market deployment / editors, Dr. Ovidiu Vermesan, Dr. Peter Friess. |
| title_full_unstemmed |
Internet of things - from research and innovation to market deployment / editors, Dr. Ovidiu Vermesan, Dr. Peter Friess. |
| title_auth |
Internet of things - from research and innovation to market deployment / |
| title_new |
Internet of things - from research and innovation to market deployment / |
| title_sort |
internet of things - from research and innovation to market deployment / |
| series |
River Publishers Series in Communications |
| series2 |
River Publishers Series in Communications |
| publisher |
Taylor & Francis River Publishers, |
| publishDate |
2014 |
| physical |
1 online resource (373 pages) : color illustrations, charts. |
| edition |
1st ed. |
| contents |
cover -- RIVER PUBLISHERS SERIES IN COMMUNICATIONS -- Tittle - Internet of Things From Research and Innovation to Market Deployment -- Copyright -- Dedication -- Acknowledgement -- Contents -- Preface -- Shaping the Future of Internet of Things Applications -- Editors Biography -- 1 Introduction -- 2 Putting the Internet of Things Forwardto the Next Nevel -- 2.1 The Internet of Things Today -- 2.2 The Internet of Things Tomorrow -- 2.3 Potential Success Factors -- References -- 3 Internet of Things Strategic Research and Innovation Agenda -- 3.1 Internet of Things Vision -- 3.1.1 Internet of Things Common Definition -- 3.2 IoT Strategic Research and Innovation Directions -- 3.2.1 IoT Applications and Use Case Scenarios -- 3.2.2 IoT Functional View -- 3.2.3 Application Areas -- 3.3 IoT Smart-X Applications -- 3.3.1 Smart Cities -- 3.3.2 Smart Energy and the Smart GridThere is increasing public awareness about the -- 3.3.3 Smart Mobility and Transport -- 3.3.4 Smart Home, Smart Buildings and Infrastructure -- 3.3.5 Smart Factory and Smart Manufacturing -- 3.3.6 Smart Health -- 3.3.7 Food andWater Tracking and Security -- 3.3.8 Participatory Sensing -- 3.3.9 Smart Logistics and Retail -- 3.4 Internet of Things and Related Future Internet Technologies -- 3.4.1 Cloud Computing -- 3.4.2 IoT and Semantic Technologies -- 3.5 Networks and Communication -- 3.5.1 Networking Technology -- 3.5.2 Communication Technology -- 3.5.2.1 Unfolding the potential of communication technologies -- 3.5.2.2 Correctness of construction -- 3.5.2.3 An unified theoretical framework for communication -- 3.5.2.4 Energy-limited Internet of Things devices and their communication -- 3.5.2.5 Challenge the trend to complexity -- 3.5.2.6 Disruptive approaches -- 3.5.1.1 Complexity of the networks of the future -- 3.5.1.2 Growth of wireless networks -- 3.5.1.3 Mobile networks. 3.5.1.4 Expanding current networks to future networks -- 3.5.1.5 Overlay networks -- 3.5.1.6 Network self-organization -- 3.5.1.7 IPv6, IoT and Scalability -- 3.5.1.8 Green networking technology -- 3.6 Processes -- 3.6.1 Adaptive and Event-Driven Processes -- 3.6.2 Processes Dealing with Unreliable Data -- 3.6.3 Processes dealing with unreliable resources -- 3.6.4 Highly Distributed Processes -- 3.7 Data Management -- 3.7.1 Data Collection and Analysis (DCA) -- 3.7.2 Big Data -- 3.7.3 Semantic Sensor Networks and Semantic Annotation of data -- 3.7.4 Virtual Sensors -- 3.8 Security, Privacy & -- Trust -- 3.8.1 Trust for IoT -- 3.8.2 Security for IoT -- 3.8.3 Privacy for IoT -- 3.9 Device Level Energy Issues -- 3.9.1 Low Power Communication -- 3.9.2 Energy Harvesting -- 3.9.3 Future Trends and Recommendations -- 3.10 IoT Related Standardization -- 3.10.1 The Role of Standardization Activities -- 3.10.2 Current Situation -- 3.10.3 Areas for Additional Consideration -- 3.10.4 Interoperability in the Internet-of-Things -- 3.10.4.1 IoT Interoperability necessary framework -- 3.10.4.2 Technical IoT Interoperability -- 3.11 IoT Protocols Convergence -- 3.11.1 Message Queue Telemetry Transport (MQTT) -- 3.11.2 Constrained Applications Protocol (CoAP) -- 3.11.3 Advanced Message Queuing Protocol (AMQP) -- 3.11.4 Java Message Service API (JMS) -- 3.11.5 Data Distribution Service (DDS) -- 3.11.6 Representational State Transfer (REST) -- 3.11.7 Extensible Messaging and Presence Protocol (XMPP) -- 3.12 Discussion -- Acknowledgments -- List of Contributors -- List of Abbreviations and Acronyms -- 4 Internet of Things Global Standardisation - State of Play -- 4.1 Introduction -- 4.1.1 General -- 4.2 IoT Vision -- 4.2.1 IoT Drivers -- 4.2.2 IoT Definition -- 4.3 IoT Standardisation Landscape -- 4.3.1 CEN/ISO and CENELEC/IEC -- 4.3.1.1 CEN/CENELEC overview. 4.3.1.2 CEN technical bodies -- 4.3.1.3 European standards -- 4.3.1.4 Technical specifications -- 4.3.1.6 CENELEC workshop agreements (CWA) -- 4.3.1.7 CEN members -- 4.3.1.8 CEN/TC 225 -- 4.3.1.9 CENELEC -- 4.3.1.10 Smart grids: EC Mandate M/490 -- 4.3.1.11 ISO/IEC JTC 1/SWG 05 on the Internet of Things (IoT) -- 4.3.1.12 ISO/IEC JTC 1/WG 7 Sensor Networks -- 4.3.1.13 ISO/IEC JTC 1/SC 31 Automatic identification and data capture techniques -- 4.3.2 ETSI -- 4.3.3 IEEE -- 4.3.3.1 Overview -- 4.3.3.2 Cloud Computing -- 4.3.3.3 eHealth -- 4.3.3.4 eLearning -- 4.3.3.5 Intelligent Transportation Systems (ITS) -- 4.3.3.6 Network and Information Security (NIS) -- 4.3.3.7 Smart Grid -- 4.3.4 IETF -- 4.3.5 ITU-T -- 4.3.6 OASIS -- 4.3.6.1 Transactional Reliability -- 4.3.6.2 Modularity, reusability, and devices in the cloud -- 4.3.6.3 All that big data from all those things: access control, cybersecurity and privacy -- 4.3.6.4 Access control -- 4.3.6.5 Encryption and cybersecurity -- 4.3.6.6 Privacy -- 4.3.7 OGC -- 4.3.8 oneM2M -- 4.3.9 GS1 -- 4.3.9.1 The Role of Standards -- 4.3.9.2 GS1 Standards: Identify, Capture, Share -- 4.3.9.3 Looking forward -- 4.4 IERC Research Projects Positions -- 4.4.1 BETaaS Advisory Board Experts Position -- 4.4.2 IoT6 Position -- 4.5 Conclusions -- References -- 5 Dynamic Context-Aware Scalable and Trust-based IoT Security, Privacy Framework -- 5.1 Introduction -- 5.2 BackgroundWork -- 5.3 Main Concepts and Motivation of the Framework -- 5.3.1 Identity Management -- 5.3.2 Size and Heterogeneity of the System -- 5.3.3 Anonymization of User Data and Metadata -- 5.3.4 Action's Control -- 5.3.5 Privacy by Design -- 5.3.6 Context Awareness -- 5.3.7 Summary -- 5.4 A Policy-based Framework for Security and Privacy in Internet of Things -- 5.4.1 Deployment in a Scenario -- 5.4.2 Policies and Context Switching. 5.4.3 Framework Architecture and Enforcement -- 5.5 Conclusion and Future Developments -- 5.6 Acknowledgments -- References -- 6 Scalable Integration Framework for Heterogeneous Smart Objects, Applications and Services -- 6.1 Introduction -- 6.2 IPv6 Potential -- 6.3 IoT6 -- 6.4 IPv6 for IoT -- 6.5 Adapting IPv6 to IoT Requirements -- 6.6 IoT6 Architecture -- 6.7 DigCovery -- 6.8 IoT6 Integration with the Cloud and EPICS -- 6.9 Enabling Heterogeneous Integration -- 6.10 IoT6 Smart Office Use-case -- 6.11 Scalability Perspective -- 6.12 Conclusions -- References -- 7 Internet of Things Applications - From Research and Innovation to Market Deployment -- 7.1 Introduction -- 7.2 OpenIoT -- 7.2.1 Project Design and Implementation -- 7.2.2 Execution and Implementation Issues -- 7.2.3 Project Results -- 7.2.4 Acceptance and Sustainability -- 7.2.5 Discussion -- 7.3 iCORE -- 7.3.1 Design -- 7.3.1.1 Smart home and assisted living -- 7.3.1.2 Smart business and logistics -- 7.3.1.3 Smart-city - transportation -- 7.3.1.4 Smart meeting -- 7.3.1.5 Rationale for chosen use cases -- 7.3.2 Project Execution -- 7.3.3 Results Achieved -- 7.3.3.1 Smart tourism trial -- 7.3.3.2 Smart urban security trial -- 7.3.3.3 Smart asset management trial -- 7.3.3.4 Smart amusement park trial -- 7.4 COMPOSE -- 7.4.1 Project Design and Implementation -- 7.4.2 The IoT Communication Technologies -- 7.4.3.1 The COMPOSE services -- 7.4.3.2 The back-end technologies -- 7.4.3 Execution and Implementation Issues -- 7.4.4 Expected Project results -- 7.4.4.1 Smart Spaces -- 7.4.4.2 Smart City -- 7.4.4.3 Smart territory -- 7.5 SmartSantander -- 7.5.1 How SmartSantander Facility has Become a Reality? -- 7.5.2 Massive Experimentation Facility: A Fire Perspective -- 7.5.3 City Services Implementation:The Smart City Paradigm -- 7.5.3.1 Parking service management. 7.5.3.2 Traffic intensity monitoring -- 7.5.3.3 Environmental monitoring -- 7.5.3.4 Parks and gardens irrigation -- 7.5.3.5 Citizens apps -- 7.5.4 Sustainability Plan -- 7.6 FITMAN -- 7.6.1 The "IoT for Manufacturing"Trials in FITMAN -- 7.6.2 FITMAN Trials' Requirements to "IoT for Manufacturing" -- 7.6.3 The TRW and Whirlpool Smart Factory Trial -- 7.6.4 FITMAN Trials' Exploitation Plans & -- Business Opportunities -- 7.6.5 Conclusions and Future Outlook -- 7.7 OSMOSE -- 7.7.1 The AW and EPC "IoT for Manufacturing"Test Cases -- 7.7.2 OSMOSE Use Cases' Requirements to "IoT for Manufacturing" -- 7.7.3 OSMOSE Use Cases' Exploitation Plans & -- Business Opportunities -- 7.7.4 Conclusions and Future Outlook -- Acknowledgments -- List of Contributors -- Contributing Projects and Initiatives -- References -- 8 Bringing IP to Low-power Smart Objects: The Smart Parking Case in the CALIPSO Project -- Abstract -- 8.1 Introduction -- 8.1.1 Bringing IP to Energy-Constrained Devices -- 8.1.2 The CALIPSO Project -- 8.2 Smart Parking -- 8.3 CALIPSO Architecture -- 8.3.1 CALIPSO Communication Modules -- 8.3.1.1 MAC layer -- 8.3.1.2 Routing layer -- 8.3.1.3 Application layer -- 8.3.2 CALIPSO Security Modules -- 8.4 Calipso Implementation and Experimentation with Smart Parking -- 8.4.1 Implementation of Calipso Modules -- 8.4.2 Experimentation Plan for Smart Parking -- 8.4.2.1 Prototype description -- 8.4.2.2 Description of the scenario -- 8.4.2.3 Performance indicators -- 8.5 Concluding Remarks -- Acknowledgements -- References -- 9 Insights on Federated Cloud Service Management and the Internet of Things -- Abstract -- 9.1 Introduction -- 9.2 Federated Cloud Services Management -- 9.2.1 Cloud Data Management -- 9.2.2 Cloud Data Monitoring -- 9.2.3 Cloud Data Exchange -- 9.2.4 Infrastructure Configuration and re-Configuration. 9.3 Federated Management Service Life Cycle. |
| isbn |
1-000-79736-8 1-00-333862-3 1-003-33862-3 87-93102-95-X 87-93102-94-1 |
| callnumber-first |
T - Technology |
| callnumber-subject |
TK - Electrical and Nuclear Engineering |
| callnumber-label |
TK5105 |
| callnumber-sort |
TK 45105.875 I57 I584 42014 |
| illustrated |
Illustrated |
| dewey-hundreds |
000 - Computer science, information & general works |
| dewey-tens |
000 - Computer science, knowledge & systems |
| dewey-ones |
004 - Data processing & computer science |
| dewey-full |
004.678 |
| dewey-sort |
14.678 |
| dewey-raw |
004.678 |
| dewey-search |
004.678 |
| oclc_num |
957125786 |
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AT vermesanovidiu internetofthingsfromresearchandinnovationtomarketdeployment AT friesspeter internetofthingsfromresearchandinnovationtomarketdeployment |
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n |
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It is intended to be a standalone book in a series that covers the Internet of Things activities of the IERC – Internet of Things European Research Cluster from technology to international cooperation and the global "state of play".The book builds on the ideas put forward by the European research Cluster on the Internet of Things Strategic Research Agenda and presents global views and state of the art results on the challenges facing the research, development and deployment of IoT at the global level. Internet of Things is creating a revolutionary new paradigm, with opportunities in every industry from Health Care, Pharmaceuticals, Food and Beverage, Agriculture, Computer, Electronics Telecommunications, Automotive, Aeronautics, Transportation Energy and Retail to apply the massive potential of the IoT to achieving real-world solutions. The beneficiaries will include as well semiconductor companies, device and product companies, infrastructure software companies, application software companies, consulting companies, telecommunication and cloud service providers. IoT will create new revenues annually for these stakeholders, and potentially create substantial market share shakeups due to increased technology competition. The IoT will fuel technology innovation by creating the means for machines to communicate many different types of information with one another while contributing in the increased value of information created by the number of interconnections among things and the transformation of the processed information into knowledge shared into the Internet of Everything. The success of IoT depends strongly on enabling technology development, market acceptance and standardization, which provides interoperability, compatibility, reliability, and effective operations on a global scale. The connected devices are part of ecosystems connecting people, processes, data, and things which are communicating in the cloud using the increased storage and computing power and pushing for standardization of communication and metadata. In this context security, privacy, safety, trust have to be address by the product manufacturers through the life cycle of their products from design to the support processes. The IoT developments address the whole IoT spectrum - from devices at the edge to cloud and datacentres on the backend and everything in between, through ecosystems are created by industry, research and application stakeholders that enable real-world use cases to accelerate the Internet of Things and establish open interoperability standards and common architectures for IoT solutions. Enabling technologies such as nanoelectronics, sensors/actuators, cyber-physical systems, intelligent device management, smart gateways, telematics, smart network infrastructure, cloud computing and software technologies will create new products, new services, new interfaces by creating smart environments and smart spaces with applications ranging from Smart Cities, smart transport, buildings, energy, grid, to smart health and life. Technical topics discussed in the book include: • Introduction• Internet of Things Strategic Research and Innovation Agenda• Internet of Things in the industrial context: Time for deployment.• Integration of heterogeneous smart objects, applications and services• Evolution from device to semantic and business interoperability• Software define and virtualization of network resources• Innovation through interoperability and standardisation when everything is connected anytime at anyplace• Dynamic context-aware scalable and trust-based IoT Security, Privacy framework• Federated Cloud service management and the Internet of Things• Internet of Things Applications</subfield></datafield><datafield tag="546" ind1=" " ind2=" "><subfield code="a">English</subfield></datafield><datafield tag="536" ind1=" " ind2=" "><subfield code="a">European Commission</subfield></datafield><datafield tag="505" ind1="0" ind2=" "><subfield code="a">cover -- RIVER PUBLISHERS SERIES IN COMMUNICATIONS -- Tittle - Internet of Things From Research and Innovation to Market Deployment -- Copyright -- Dedication -- Acknowledgement -- Contents -- Preface -- Shaping the Future of Internet of Things Applications -- Editors Biography -- 1 Introduction -- 2 Putting the Internet of Things Forwardto the Next Nevel -- 2.1 The Internet of Things Today -- 2.2 The Internet of Things Tomorrow -- 2.3 Potential Success Factors -- References -- 3 Internet of Things Strategic Research and Innovation Agenda -- 3.1 Internet of Things Vision -- 3.1.1 Internet of Things Common Definition -- 3.2 IoT Strategic Research and Innovation Directions -- 3.2.1 IoT Applications and Use Case Scenarios -- 3.2.2 IoT Functional View -- 3.2.3 Application Areas -- 3.3 IoT Smart-X Applications -- 3.3.1 Smart Cities -- 3.3.2 Smart Energy and the Smart GridThere is increasing public awareness about the -- 3.3.3 Smart Mobility and Transport -- 3.3.4 Smart Home, Smart Buildings and Infrastructure -- 3.3.5 Smart Factory and Smart Manufacturing -- 3.3.6 Smart Health -- 3.3.7 Food andWater Tracking and Security -- 3.3.8 Participatory Sensing -- 3.3.9 Smart Logistics and Retail -- 3.4 Internet of Things and Related Future Internet Technologies -- 3.4.1 Cloud Computing -- 3.4.2 IoT and Semantic Technologies -- 3.5 Networks and Communication -- 3.5.1 Networking Technology -- 3.5.2 Communication Technology -- 3.5.2.1 Unfolding the potential of communication technologies -- 3.5.2.2 Correctness of construction -- 3.5.2.3 An unified theoretical framework for communication -- 3.5.2.4 Energy-limited Internet of Things devices and their communication -- 3.5.2.5 Challenge the trend to complexity -- 3.5.2.6 Disruptive approaches -- 3.5.1.1 Complexity of the networks of the future -- 3.5.1.2 Growth of wireless networks -- 3.5.1.3 Mobile networks.</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">3.5.1.4 Expanding current networks to future networks -- 3.5.1.5 Overlay networks -- 3.5.1.6 Network self-organization -- 3.5.1.7 IPv6, IoT and Scalability -- 3.5.1.8 Green networking technology -- 3.6 Processes -- 3.6.1 Adaptive and Event-Driven Processes -- 3.6.2 Processes Dealing with Unreliable Data -- 3.6.3 Processes dealing with unreliable resources -- 3.6.4 Highly Distributed Processes -- 3.7 Data Management -- 3.7.1 Data Collection and Analysis (DCA) -- 3.7.2 Big Data -- 3.7.3 Semantic Sensor Networks and Semantic Annotation of data -- 3.7.4 Virtual Sensors -- 3.8 Security, Privacy &amp -- Trust -- 3.8.1 Trust for IoT -- 3.8.2 Security for IoT -- 3.8.3 Privacy for IoT -- 3.9 Device Level Energy Issues -- 3.9.1 Low Power Communication -- 3.9.2 Energy Harvesting -- 3.9.3 Future Trends and Recommendations -- 3.10 IoT Related Standardization -- 3.10.1 The Role of Standardization Activities -- 3.10.2 Current Situation -- 3.10.3 Areas for Additional Consideration -- 3.10.4 Interoperability in the Internet-of-Things -- 3.10.4.1 IoT Interoperability necessary framework -- 3.10.4.2 Technical IoT Interoperability -- 3.11 IoT Protocols Convergence -- 3.11.1 Message Queue Telemetry Transport (MQTT) -- 3.11.2 Constrained Applications Protocol (CoAP) -- 3.11.3 Advanced Message Queuing Protocol (AMQP) -- 3.11.4 Java Message Service API (JMS) -- 3.11.5 Data Distribution Service (DDS) -- 3.11.6 Representational State Transfer (REST) -- 3.11.7 Extensible Messaging and Presence Protocol (XMPP) -- 3.12 Discussion -- Acknowledgments -- List of Contributors -- List of Abbreviations and Acronyms -- 4 Internet of Things Global Standardisation - State of Play -- 4.1 Introduction -- 4.1.1 General -- 4.2 IoT Vision -- 4.2.1 IoT Drivers -- 4.2.2 IoT Definition -- 4.3 IoT Standardisation Landscape -- 4.3.1 CEN/ISO and CENELEC/IEC -- 4.3.1.1 CEN/CENELEC overview.</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">4.3.1.2 CEN technical bodies -- 4.3.1.3 European standards -- 4.3.1.4 Technical specifications -- 4.3.1.6 CENELEC workshop agreements (CWA) -- 4.3.1.7 CEN members -- 4.3.1.8 CEN/TC 225 -- 4.3.1.9 CENELEC -- 4.3.1.10 Smart grids: EC Mandate M/490 -- 4.3.1.11 ISO/IEC JTC 1/SWG 05 on the Internet of Things (IoT) -- 4.3.1.12 ISO/IEC JTC 1/WG 7 Sensor Networks -- 4.3.1.13 ISO/IEC JTC 1/SC 31 Automatic identification and data capture techniques -- 4.3.2 ETSI -- 4.3.3 IEEE -- 4.3.3.1 Overview -- 4.3.3.2 Cloud Computing -- 4.3.3.3 eHealth -- 4.3.3.4 eLearning -- 4.3.3.5 Intelligent Transportation Systems (ITS) -- 4.3.3.6 Network and Information Security (NIS) -- 4.3.3.7 Smart Grid -- 4.3.4 IETF -- 4.3.5 ITU-T -- 4.3.6 OASIS -- 4.3.6.1 Transactional Reliability -- 4.3.6.2 Modularity, reusability, and devices in the cloud -- 4.3.6.3 All that big data from all those things: access control, cybersecurity and privacy -- 4.3.6.4 Access control -- 4.3.6.5 Encryption and cybersecurity -- 4.3.6.6 Privacy -- 4.3.7 OGC -- 4.3.8 oneM2M -- 4.3.9 GS1 -- 4.3.9.1 The Role of Standards -- 4.3.9.2 GS1 Standards: Identify, Capture, Share -- 4.3.9.3 Looking forward -- 4.4 IERC Research Projects Positions -- 4.4.1 BETaaS Advisory Board Experts Position -- 4.4.2 IoT6 Position -- 4.5 Conclusions -- References -- 5 Dynamic Context-Aware Scalable and Trust-based IoT Security, Privacy Framework -- 5.1 Introduction -- 5.2 BackgroundWork -- 5.3 Main Concepts and Motivation of the Framework -- 5.3.1 Identity Management -- 5.3.2 Size and Heterogeneity of the System -- 5.3.3 Anonymization of User Data and Metadata -- 5.3.4 Action's Control -- 5.3.5 Privacy by Design -- 5.3.6 Context Awareness -- 5.3.7 Summary -- 5.4 A Policy-based Framework for Security and Privacy in Internet of Things -- 5.4.1 Deployment in a Scenario -- 5.4.2 Policies and Context Switching.</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">5.4.3 Framework Architecture and Enforcement -- 5.5 Conclusion and Future Developments -- 5.6 Acknowledgments -- References -- 6 Scalable Integration Framework for Heterogeneous Smart Objects, Applications and Services -- 6.1 Introduction -- 6.2 IPv6 Potential -- 6.3 IoT6 -- 6.4 IPv6 for IoT -- 6.5 Adapting IPv6 to IoT Requirements -- 6.6 IoT6 Architecture -- 6.7 DigCovery -- 6.8 IoT6 Integration with the Cloud and EPICS -- 6.9 Enabling Heterogeneous Integration -- 6.10 IoT6 Smart Office Use-case -- 6.11 Scalability Perspective -- 6.12 Conclusions -- References -- 7 Internet of Things Applications - From Research and Innovation to Market Deployment -- 7.1 Introduction -- 7.2 OpenIoT -- 7.2.1 Project Design and Implementation -- 7.2.2 Execution and Implementation Issues -- 7.2.3 Project Results -- 7.2.4 Acceptance and Sustainability -- 7.2.5 Discussion -- 7.3 iCORE -- 7.3.1 Design -- 7.3.1.1 Smart home and assisted living -- 7.3.1.2 Smart business and logistics -- 7.3.1.3 Smart-city - transportation -- 7.3.1.4 Smart meeting -- 7.3.1.5 Rationale for chosen use cases -- 7.3.2 Project Execution -- 7.3.3 Results Achieved -- 7.3.3.1 Smart tourism trial -- 7.3.3.2 Smart urban security trial -- 7.3.3.3 Smart asset management trial -- 7.3.3.4 Smart amusement park trial -- 7.4 COMPOSE -- 7.4.1 Project Design and Implementation -- 7.4.2 The IoT Communication Technologies -- 7.4.3.1 The COMPOSE services -- 7.4.3.2 The back-end technologies -- 7.4.3 Execution and Implementation Issues -- 7.4.4 Expected Project results -- 7.4.4.1 Smart Spaces -- 7.4.4.2 Smart City -- 7.4.4.3 Smart territory -- 7.5 SmartSantander -- 7.5.1 How SmartSantander Facility has Become a Reality? -- 7.5.2 Massive Experimentation Facility: A Fire Perspective -- 7.5.3 City Services Implementation:The Smart City Paradigm -- 7.5.3.1 Parking service management.</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">7.5.3.2 Traffic intensity monitoring -- 7.5.3.3 Environmental monitoring -- 7.5.3.4 Parks and gardens irrigation -- 7.5.3.5 Citizens apps -- 7.5.4 Sustainability Plan -- 7.6 FITMAN -- 7.6.1 The "IoT for Manufacturing"Trials in FITMAN -- 7.6.2 FITMAN Trials' Requirements to "IoT for Manufacturing" -- 7.6.3 The TRW and Whirlpool Smart Factory Trial -- 7.6.4 FITMAN Trials' Exploitation Plans &amp -- Business Opportunities -- 7.6.5 Conclusions and Future Outlook -- 7.7 OSMOSE -- 7.7.1 The AW and EPC "IoT for Manufacturing"Test Cases -- 7.7.2 OSMOSE Use Cases' Requirements to "IoT for Manufacturing" -- 7.7.3 OSMOSE Use Cases' Exploitation Plans &amp -- Business Opportunities -- 7.7.4 Conclusions and Future Outlook -- Acknowledgments -- List of Contributors -- Contributing Projects and Initiatives -- References -- 8 Bringing IP to Low-power Smart Objects: The Smart Parking Case in the CALIPSO Project -- Abstract -- 8.1 Introduction -- 8.1.1 Bringing IP to Energy-Constrained Devices -- 8.1.2 The CALIPSO Project -- 8.2 Smart Parking -- 8.3 CALIPSO Architecture -- 8.3.1 CALIPSO Communication Modules -- 8.3.1.1 MAC layer -- 8.3.1.2 Routing layer -- 8.3.1.3 Application layer -- 8.3.2 CALIPSO Security Modules -- 8.4 Calipso Implementation and Experimentation with Smart Parking -- 8.4.1 Implementation of Calipso Modules -- 8.4.2 Experimentation Plan for Smart Parking -- 8.4.2.1 Prototype description -- 8.4.2.2 Description of the scenario -- 8.4.2.3 Performance indicators -- 8.5 Concluding Remarks -- Acknowledgements -- References -- 9 Insights on Federated Cloud Service Management and the Internet of Things -- Abstract -- 9.1 Introduction -- 9.2 Federated Cloud Services Management -- 9.2.1 Cloud Data Management -- 9.2.2 Cloud Data Monitoring -- 9.2.3 Cloud Data Exchange -- 9.2.4 Infrastructure Configuration and re-Configuration.</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">9.3 Federated Management Service Life Cycle.</subfield></datafield><datafield tag="650" ind1=" " ind2="0"><subfield code="a">Internet.</subfield></datafield><datafield tag="653" ind1=" " ind2=" "><subfield code="a">Communications engineering / telecommunications</subfield></datafield><datafield tag="700" ind1="1" ind2=" "><subfield code="a">Vermesan, Ovidiu,</subfield><subfield code="e">editor.</subfield></datafield><datafield tag="700" ind1="1" ind2=" "><subfield code="a">Friess, Peter,</subfield><subfield code="e">editor.</subfield></datafield><datafield tag="776" ind1=" " ind2=" "><subfield code="z">87-93102-94-1</subfield></datafield><datafield tag="830" ind1=" " ind2="0"><subfield code="a">River Publishers series in communications.</subfield></datafield><datafield tag="906" ind1=" " ind2=" "><subfield code="a">BOOK</subfield></datafield><datafield tag="ADM" ind1=" " ind2=" "><subfield code="b">2024-05-03 00:54:33 Europe/Vienna</subfield><subfield code="f">system</subfield><subfield code="c">marc21</subfield><subfield code="a">2016-09-03 17:09:02 Europe/Vienna</subfield><subfield code="g">false</subfield></datafield><datafield tag="AVE" ind1=" " ind2=" "><subfield code="i">DOAB Directory of Open Access Books</subfield><subfield code="P">DOAB Directory of Open Access Books</subfield><subfield code="x">https://eu02.alma.exlibrisgroup.com/view/uresolver/43ACC_OEAW/openurl?u.ignore_date_coverage=true&portfolio_pid=5341443090004498&Force_direct=true</subfield><subfield code="Z">5341443090004498</subfield><subfield code="b">Available</subfield><subfield code="8">5341443090004498</subfield></datafield></record></collection> |