Building the future internet through FIRE : 2016 FIRE book : : a research and experiment based approach / / Martin Serrano [and five others], editors.
The Internet as we know it today is the result of a continuous activity for improving network communications, end user services, computational processes and also information technology infrastructures. The Internet has become a critical infrastructure for the human-being by offering complex networki...
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| Superior document: | River Publishers series in information science and technology |
|---|---|
| TeilnehmendeR: | |
| Place / Publishing House: | Gistrup, Denmark ; Delft, the Netherlands : : River Publishers,, 2017. ©2017 |
| Year of Publication: | 2017 |
| Edition: | First edition. |
| Language: | English |
| Series: | River Publishers series in information science and technology.
|
| Physical Description: | 1 online resource (794 pages) :; illustrations, tables. |
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Table of Contents:
- Front Cover
- Half Title Page
- RIVER PUBLISHERS SERIES IN INFORMATION SCIENCE AND TECHNOLOGY
- Title Page - Building the Future Internet through FIRE 2016 FIRE Book: A Research and Experiment based Approach
- Copyright Page
- Contents
- Dedications
- Acknowledgements
- Editors Biography
- Foreword
- List of Figures
- List of Tables
- PART I - The Next Generation Internet with FIRE
- Chapter 1 - European Challenges for Experimental Facilities
- 1.1 Evolution of Experimentation Facilities into Open Innovation Ecosystems for the Future Internet
- 1.2 Support, Continuity and Sustainability:The NITOS Testbed Example
- 1.2.1 NITOS Future Internet Facility Overview
- 1.2.2 NITOS Evolution and Growth
- 1.2.3 Facilitating User's Experience
- 1.2.4 Exploitation of NITOS and Users Statistics
- 1.2.5 References
- 1.3 Experimentation: Vision and Roadmap
- 1.3.1 Envisioning Evolution of Experimentation Facilities into the Future
- 1.3.2 Vision and Opportunities of OMA LwM2M/oneM2M and Its Role in the Monitoring and Deployment of Large Scale Unmanned Networks
- 1.3.3 Large Deployments with Low-power, Long-range, Low-cost
- 1.3.3.1 LoRa technology
- 1.3.3.2 LoRaWAN
- 1.3.3.3 Simplified deployment scenarios
- 1.4 Conclusions
- References
- Chapter 2 - Next Generation Internet Research and Experimentation
- 2.1 Experimentation Facilities in H2020: Strategic Research and Innovation Agenda Contributions
- 2.1.1 European Ecosystem Experimentation Impacts
- 2.1.2 Drivers Transforming the Next Generation Internet Experimentation
- 2.1.2.1 Intelligent spaces
- 2.1.2.2 Cooperative autonomous machines
- 2.1.2.3 Collective human experience
- 2.1.2.4 Key networking technologies
- 2.2 Policy Recommendations for Next Generation Internet Experimentation
- 2.3 References.
- 2.4 Experimentation Facilities Evolution towards Ecosystems for Open Innovation in the Internet of Future
- 2.4.1 Changes in the FIRE Portfolio
- 2.4.2 Technological Innovation and Demand Pull
- 2.4.3 Positioning of FIRE
- 2.4.4 Bridging the Gaps between Demands and Service Offer
- 2.4.5 Testbed-as-a-Service
- 2.4.6 Future Scenarios for FIRE
- 2.5 FIRE Vision and Mission in H2020
- 2.6 From Vision to Strategic Objectives
- 2.6.1 Strategic Objectives
- 2.6.2 FIRE's Enablers
- 2.7 FIRE Roadmap towards 2020
- 2.7.1 Milestones
- 2.7.2 Towards Implementation - Resolving the Gaps
- 2.8 Main Conclusions and Recommendations
- 2.8.1 FIRE Vision and Positioning
- 2.8.2 Strategic Challenges for Evolution of FIRE
- 2.8.3 Action Plans to Realize the Strategic Directions
- 2.9 Final Remarks
- References to AmpliFIRE Reports and White Papers
- PART II - Experimentation FACILITIES Best Practices and Flagship Projects
- Chapter 3 - Fed4FIRE - The Largest Federation of Testbeds in Europe
- 3.1 Introduction
- 3.2 Federated Experimentation Facilities
- 3.2.1 Requirements from Industry and Research
- 3.2.2 Establishing Fed4FIRE Federation of Testbesd
- 3.2.3 Experimentation Facilities in Fed4FIRE
- 3.3 Framework for Large-scale Federation of Testbeds
- 3.3.1 Framework Architecture and Tools
- 3.3.1.1 Experiment lifecycle
- 3.3.1.2 Resource discovery, specification, reservation and provisioning
- 3.3.1.2.1 Architectural components
- 3.3.1.3 Other functionality
- 3.3.2 Federating Experimentation Facilities
- 3.3.2.1 Classes of testbeds
- 3.3.2.2 Types of federation
- 3.3.2.3 Workflow for federation
- 3.3.3 Federation Tools
- 3.3.3.1 Portal
- 3.3.3.2 jFed
- 3.3.3.3 NEPI
- 3.3.3.4 YourEPM
- 3.4 Federated Testing in Fed4FIRE
- 3.4.1 Overview of Experiments on Fed4FIRE
- 3.4.2 Complexity of the Fed4FIRE Experiments.
- 3.4.3 Value to the Experimenter
- 3.4.4 Support Provided by the Federation to SMEs
- 3.4.5 Added Value of the Federation
- 3.5 Operating the Federation
- 3.5.1 Federation Model, Structure and Roles
- 3.5.2 Financial Approach of the Federation
- 3.5.3 Organization of the Federation
- 3.6 Summary
- Chapter 4 - A Platform for 4G/5G Wireless Networking Research,Targeting the Experimentally-Driven Research Approach - FLEX -
- 4.1 Introduction
- 4.2 Problem Statement
- 4.2.1 FLEX Testbeds
- 4.2.1.1 NITOS testbed
- 4.2.1.2 w-iLab.t testbed
- 4.2.1.3 OpenAirInterface testbed
- 4.2.1.4 PerformNetworks testbed
- 4.2.1.5 FUSECO playground
- 4.3 Background and State-of-the-Art on Control and Management of Testbeds
- 4.3.1 Slice-based Federation Architecture (SFA)
- 4.3.2 cOntrol and Management Framework (OMF)
- 4.3.3 OML
- 4.4 Approach
- 4.5 Technical Work
- 4.5.1 Control Plane Tools
- 4.5.1.1 NITOS Scheduler
- 4.5.1.2 jFed
- 4.5.1.3 NITOS brokering
- 4.5.2 Experimental Plane Tools
- 4.5.2.1 The FLEX LTErf service
- 4.5.2.2 OMF extensions
- 4.5.3 Monitoring Applications
- 4.5.3.1 FLEX QoE tool
- 4.5.3.2 FLEX problems
- 4.5.3.3 FLEX netchanges
- 4.5.4 Handover Toolkit
- 4.5.4.1 S1-based handovers
- 4.5.4.2 X2-based handovers
- 4.5.4.3 Cross-technology Inter-RAT SDN based handovers
- 4.5.5 Mobility Emulation Platforms
- 4.5.6 Functional Federation
- 4.6 Results and/or Achievements
- 4.6.1 Semantic Based Coordination for LTE in Unlicensed Bands
- 4.6.2 FLOW LTE to Wi-Fi Offloading Experiments
- Discussion
- Conclusions
- References
- Chapter 5 - MONROE: Measuring Mobile Broadband Networks in Europe
- 5.1 Introduction
- 5.2 Background and State of the Art
- 5.3 MONROE Approach and Key Features
- 5.4 MONROE System Design
- 5.5 Experiment Deployment
- 5.5.1 MONROE as a Fed4FIRE Federated Project.
- 5.5.2 User Authentication
- 5.5.3 The Experimenters Portal (MONROE User Access Client)
- 5.5.4 MONROE Scheduler
- 5.6 Network Measurements and Analytics with MONROE
- 5.6.1 MONROE Monitoring Experiments
- 5.6.2 Network Analytics with MONROE
- 5.7 User Experiments
- 5.8 Conclusions
- References
- Chapter 6 - Perform Networks: A Testbed for Exhaustive Interoperability and Performance Analysis for Mobile Networks
- 6.1 Introduction
- 6.2 Problem Statement
- 6.3 Background and State of the Art
- 6.3.1 Research Tools for Wireless Communications
- 6.3.2 Wireless Testbed Platforms
- 6.4 Approach
- 6.5 TechnicalWork
- 6.5.1 T2010 Standard S1 Interface Extension
- 6.5.2 Fleximon
- 6.5.3 TestelDroid
- 6.5.4 FIRE Technology
- 6.6 Results and Achievements
- 6.6.1 SME Experiments
- 6.6.2 FIRE Projects
- 6.6.3 Research Activities
- 6.7 Discussion
- 6.8 Conclusion
- References
- Chapter 7 - Large Scale Testbed for Intercontinental Smart City Experiments and Pilots - Results and Experiences
- 7.1 Introduction
- 7.2 TRESCIMO Architecture
- 7.2.1 Smart Environmental Monitoring Trial
- 7.2.2 Smart Energy Trial
- 7.3 Trial Results
- 7.3.1 Smart Environmental Monitoring Trial
- 7.3.1.1 Scenario and experiments
- 7.3.1.2 Evaluation results
- 7.3.1.2.1 Visualisation and monitoring of the data transmitted by the sensor devices
- 7.3.1.2.2 Performance of the DTN and wake-up system
- 7.3.1.2.3 Consumption of the wake-up sensor devices
- 7.3.1.2.4 Performance of the data collection process and device update capabilities
- 7.3.2 Smart Energy Trial
- 7.3.2.1 Scenario and experiments
- 7.3.2.2 Evaluation results
- 7.3.2.2.1 Energy consumption awareness
- 7.3.2.2.2 Behavioural change
- 7.3.2.2.3 Mobile app
- 7.3.2.2.4 Technology performance metrics
- 7.4 Discussion
- 7.4.1 Smart Environmental Monitoring Trial Observations.
- 7.4.2 Smart Energy Trial Observations
- 7.4.3 General Observation
- 7.5 Conclusion
- Acknowledgments
- References
- Chapter 8 - BonFIRE: A Multi-Cloud Experimentation-as-a-Service Ecosystem
- 8.1 Introduction
- 8.2 A Cloud and Services Experimentation Service
- 8.3 Technical Approach
- 8.4 Federation of Heterogeneous Cloud and Networking Testbeds
- 8.5 Federation within the Broader FIRE Ecosystem
- 8.6 Pioneering Open Access Experimentation and Sustainability
- 8.7 Conclusions and Outlook
- Acknowledgements
- Chapter 9 - EXPERIMEDIA - A Multi-Venue Experimentation Service Supporting Technology Innovation through New Forms of Social Interaction and User Experience
- 9.1 Introduction
- 9.2 Networked Multimedia Systems
- 9.3 A Multi-Venue Media Experimentation Service
- 9.4 Smart Venues and Experiments
- 9.5 Users at the Heart of the System
- 9.6 Making a Difference in the Real-World
- 9.7 Real-Time Interactive and Immersive Media
- 9.8 Economic and Social Viability of Data Value Chains
- 9.9 Innovation whilst Respecting Privacy
- 9.10 Conclusions
- Acknowledgements
- References
- Chapter 10 - Cross-Domain Interoperability Using Federated Interoperable SemanticIoT/C loud Testbeds and Applications: The FIESTA-IoT Approach
- 10.1 Introduction
- 10.2 Federated IoT Testbeds and Deployment of Experimental Facilities
- 10.3 Cross-Domain Interoperability
- 10.4 Experimentation as a Service
- 10.5 IoT Data Marketplace
- 10.6 FIESTA Platform Services and Tools
- 10.6.1 FIESTA Approach on Global Market Confidence Programme on Interoperability Service
- 10.6.2 FIESTA Approach on Linking and Reasoning over IoT Data Streams Services
- 10.6.3 FIESTA Approach on Federating IoT Stream Data Management Services
- 10.6.4 FIESTA Approach on Semantic Interoperability for IoT/Cloud Data Streams Tools.
- 10.6.5 FIESTA Approach on Semantic Interoperability for IoT/Cloud Resources Tools.