Cross 5G PPP Initiative Documents
5G PPP Project Papers
Title |
Reference Information |
|
| 5G-CARMEN | “LightEdge: Mapping the Evolution of Multi-access Edge Computing in Cellular Networks” | IEEE Communications Magazine, to appear |
| 5G-CARMEN | “Enabling Computation Offloading for Autonomous and Assisted Driving in 5G Networks” | Proc. of IEEE Globecom 2019, Waikoloa, HI, USA |
| 5G CLARITY | D2.1 Use-Case Specifications and Requirements | https://www.5gclarity.com/wp-content/uploads/2020/06/5G-CLARITY_D2.1.pdf |
| 5G CLARITY | D3.1 – State-of-the-Art Review and Initial Design of the Integrated 5GNR/Wi-Fi/LiFi Network Frameworks on Coexistence, Multi-Connectivity, Resource Management and Positioning | https://www.5gclarity.com/wp-content/uploads/2020/09/5G-CLARITY_D3.1.pdf |
| 5G CLARITY | D2.2 – Primary System Architecture | https://www.5gclarity.com/wp-content/uploads/2020/12/5G-CLARITY_D22.pdf |
| 5G CLARITY | D4.1 – Initial Design of the SDN/NFV Platform and Identification of Target 5G-CLARITY ML Algorithms | https://www.5gclarity.com/wp-content/uploads/2020/12/5G-CLARITY_D41.pdf |
| 5G CLARITY | D5.1, Specification of Use Cases and Demonstration Plan | https://www.5gclarity.com/wp-content/uploads/2021/02/5G-CLARITY_D51.pdf |
| 5G CLARITY | D. Camps-Mur, et al, “5G-CLARITY: Integrating 5GNR, WiFi and LiFi in Private 5G Networks with Slicing Support,” EuCNC 2020 | https://research-information.bris.ac.uk/en/publications/5g-clarity-integrating-5gnr-wifi-and-lifi-in-private-5g-networks- |
| 5G COMPLETE | Jim (Shihuan) Zou, Silviu Adrian Sasu, Mirko Lawin, Annika Dochhan, Jörg-Peter Elbers, and Michael Eiselt, “Advanced optical access technologies for next-generation (5G) mobile networks [Invited],” J. Opt. Commun. Netw. 12, D86-D98 (2020)/td> | https://www.osapublishing.org/jocn/fulltext.cfm?uri=jocn-12-10-D86&id=432806 |
| 5G COMPLETE | D. A. Mesodiakaki, P. Maniotis, M. Gatzianas, C. Vagionas, N. Pleros, and G. Kalfas, “A Gated Service MAC Protocol for sub-ms Latency 5G Fiber-Wireless MmWave C-RANs”, IEEE Transactions on Wireless Communications, Volume: 20, Issue: 4, April 2021 | https://ieeexplore.ieee.org/document/9293176 |
| 5G COMPLETE | Viktoria-Maria Alevizaki, Markos Anastasopoulos, Anna Tzanakaki, and Dimitra Simeonidou, “Adaptive FH Optimization in MEC Assisted 5G environments”, Photonic Network Communications, Springer Photonic Network Communications (2020) 40:209–220 | https://doi.org/10.1007/s11107-020-00906-8 |
| 5GCroCo | 5G Cross-Border Operation for Connected and Automated Mobility: Challenges and Solutions |
https://www.mdpi.com/1999-5903/12/1/5 |
| 5G!Drones | D1.2 Initial description of the 5G trial facilities | https://www.5g-https://5gdrones.eu/wp-content/uploads/2020/05/D1.2-Initial-description-of-the-5G-trial-facilities-v2.pdfessence-h2020.eu/Portals/0/5G%20ESSENCE_%20Deliverable%202.2_v1.1_Final.pdf?ver=2018-11-27-112117-947 |
| 5G!Drones | D1.3 5G!Drones system architecture initial design | https://5gdrones.eu/wp-content/uploads/2020/05/D1.3-System-Architecture-Initial-Design.pdf |
| 5G!Drones | D1.4 Report on UAV business and regulatory ecosystem and the role of 5G | https://5gdrones.eu/wp-content/uploads/2020/06/D1.4-Report-on-UAV-business-and-regulatory-ecosystem-and-the-role-of-5G_v3.pdf |
| 5G!Drones | D1.5 Description of the 5G trial facilities and use case mapping | https://5gdrones.eu/wp-content/uploads/2020/06/D1_5_Description-of-the-5G-trial-facilities-and-use-case-mapping-v2.pdf |
| 5G!Drones | D2.1 Initial definition of the trial controller architecture, mechanisms, and APIs | https://5gdrones.eu/wp-content/uploads/2020/06/D2.1-Initial-definition-of-the-trial-controller-architecture-mechanisms-and-APIs_v1.1.pdf |
| 5G-EVE | The 5G EVE Multi-site Experimental Architecture and Experimentation Workflow | J. Garcia-Reinoso et al., “The 5G EVE Multi-site Experimental Architecture and Experimentation Workflow” 2019 IEEE 2nd 5G World Forum (5GWF), Dresden, Germany, 2019, pp. 335-340. https://ieeexplore.ieee.org/document/8911624 |
| 5G-EVE | D1.3 5G EVE end to end facility reference architecture for vertical industries and core applications | R. Román et al., “D1.3 5G EVE end to end facility reference architecture for vertical industries and core applications”, 2020, Zenodo. https://zenodo.org/record/3628333#.XkVsmmhKiUk |
| 5G-EVE | D4.1 Experimentation Tools and VNF Repository | G. Landi et al., “D4.1 Experimentation Tools and VNF Repository”, 2019, Zenodo. https://zenodo.org/record/3628201#.XkVtGmhKiUk |
| 5G-EVE | D4.2 First version of the experimental portal and service handbook | J. Almodóvar Herreros et al., “D4.2 First version of the experimental portal and service handbook.”, 2019, Zenodo. https://zenodo.org/record/3628316#.XkVtHGhKiUk |
| 5G-EVE | D2.4 Initial pilot test and validation | R. Legouable et al., “D2.4 Initial pilot test and validation”, 2020, Zenodo. https://zenodo.org/record/3946365#.X2tDNmgzY2w |
| 5G-EVE | D3.4 Second implementation of the interworking reference model | R. Perez et al., “D3.4 Second implementation of the interworking reference model”, 2020, Zenodo. https://zenodo.org/record/3946323#.X2tDNmgzY2w |
| 5G-EVE | D4.4 Report on benchmarking of new features and on the experimental portal (2nd version) | J. Garcia-Reinoso et al., “D4.4 Report on benchmarking of new features and on the experimental portal (2nd version)”, 2020, Zenodo. https://zenodo.org/record/3946283#.X2tDPWgzY2w |
| 5G-EVE | D5.3 Testing environmental conditions document with first version of testing and validation suite | C. Casetti et al., “D5.3 Testing environmental conditions document with first version of testing and validation suite”, 2020, Zenodo. https://zenodo.org/record/3946265#.X2tESmgzY2w |
| 5G-MOBIX | D3.1 – Corridor and Trial Sites Rollout Plan | https://www.5g-mobix.com/assets/files/5G-MOBIX-D3.1-Corridor-and-Trial-Sites-Rollout-Plan-v3.0.pdf |
| 5G-MOBIX | D3.2 – Report vehicle development and adaptation for 5G enabled CCAM use cases | https://www.5g-mobix.com/assets/files/5G-MOBIX-D3.2-Report-vehicle-development-and-adaptation-for-5G-enabled-CCAM-use-cases-v1.0.pdf |
| 5G-MOBIX | D3.3 – Report on the 5G technologies integration and roll-out | https://www.5g-mobix.com/assets/files/5G-MOBIX-3.3-Report-on-the-5G-technologies-integration-and-roll-out-v1.0.pdf |
| 5G-MOBIX | D3.4 – Report on corridor infrastructure development and integration | https://www.5g-mobix.com/assets/files/5G-MOBIX-D3.4-Report-on-corridor-infrastructure-development-and-integration-v1.0_Final.pdf |
| 5G-MOBIX | D3.5 – Report on the evaluation data management methodology and tools | https://www.5g-mobix.com/assets/files/5G-MOBIX-D3.5-Report-on-the-evaluation-data-management-methodology-and-tools-v1.0_Final.pdf |
| 5G-MOBIX | D4.2 – Report on the methodology and pilot site protocol | https://www.5g-mobix.com/assets/files/5G-MOBIX-D4.2-Report-on-the-methodology-and-pilot-site-protocol-_v1.0.pdf |
| 5G-SMART | D3.1 Rport on Industrial Shop Floor Wireless Infrastructure | https://5gsmart.eu/wp-content/uploads/5G-SMART-D3.1.pdf |
| 5G-SOLUTIONS | D1.1A Definition and analysis of use cases/scenarios and corresponding KPIs based on LLs (v1.0) | https://www.5gsolutionsproject.eu/uploadfiles/D1.1A%20Definition%20and%20analysis%20of%20use%20cases-scenarios%20and%20corresponding%20KPIs%20based%20on%20LLs_FNET_v1.4_29102019%20final2.pdf |
| 5G-SOLUTIONS | D1.4A Methodologies for the validation of 5G and for LL measurements (v1.0) | https://www.5gsolutionsproject.eu/uploadfiles/Deliverable%20D1.4A%20Methodologies%20for%20the%20validation%20of%205G%20and%20for%20LL%20measurements%20v1%20WIT%20Final.pdf |
| 5G-SOLUTIONS | Offline SLA-Constrained Deep Learning for 5G Networks Reliable and Dynamic End-to-End Slicing | H.Chergui. and Ch. Verikoukis “Offline SLA-Constrained Deep Learning for 5G Networks Reliable and Dynamic End-to-End Slicing”, in IEEE JSAC, Vol 38, Issue 2, pp. 350-360, February 2020. |
| 5G-VICTORI | D2.1 5G VICTORI Use case and requirements definition and reference architecture for vertical services | https://www.5g-victori-project.eu/wp-content/uploads/2020/06/2020-03-31-5G-VICTORI_D2.1_v1.0.pdf |
| 5G-VICTORI | D2.2 Preliminary individual site facility planning | https://www.5g-victori-project.eu/wp-content/uploads/2020/05/2020-05-21-5G-VICTORI_D2.2_v1.0.pdf |
| 5G-VICTORI | D2.5 5G-VICTORI Infrastructure Operating System – Initial Design Specification | https://www.5g-victori-project.eu/wp-content/uploads/2020/10/2020-07-31-5G-VICTORI_D2.5_v1.0.pdf |
| 5G-VICTORI | D4.1 Field trials methodology and guidelines | https://www.5g-victori-project.eu/wp-content/uploads/2020/10/2020-09-25-5G-VICTORI_D4.1_v1.0_Website_Version.pdf |
| 5G-VICTORI | (Conference Paper) Multi-technology on board wireless access planning | M. Anastasopoulos, A. Tzanakaki et al, Multi-technology Wireless Access for Railway Cabin Services: Planning and Performance Evaluation, TRA2020 Helsinki – Transport Research Arena, Helsinki, April 2020 |
| 5G-VINNI | White Paper on Onboarding Vertical Applications on 5G-VINNI Facility | https://doi.org/10.5281/zenodo.3695716 |
| 5G-VINNI | D1.1 Design of infrastructure architecture and subsystems | https://doi.org/10.5281/zenodo.2668754 |
| 5G-VINNI | D2.1 5G-VINNI Solution facility sites High Level Design (HLD) – v1 | https://doi.org/10.5281/zenodo.2668791 |
| 5G-VINNI | D3.1 Specification of services delivered by each of the 5G-VINNI facilities | https://doi.org/10.5281/zenodo.3345612 |
| 5G-VINNI | D4.1 Initial report on test-plan creation and methodology, and development of test orchestration framework | https://doi.org/10.5281/zenodo.3345626 |
| INSPIRE-5Gplus | D2.1 5G Security: Current Status and Future Trends | https://doi.org/10.5281/zenodo.3947894 |
| INSPIRE-5Gplus | C. Benzaid and T. Taleb. AI-driven Zero Touch Network and Service Management in 5G and Beyond: Challenges and Research Directions. IEEE Network Magazinearlos Manso, Pol Alemany Prats, Ricard Vilalta, Raul Muñoz, Ramon |
https://ieeexplore.ieee.org/document/8994961 |
| INSPIRE-5Gplus | Casellas, Ricardo Martinez, “End-to-end SDN/NFV orchestration of multi-domain transport networks and distributed computing infrastructure for beyond-5G services”, IEICE Transactions on Communications, Vol. E104-B (2), 2021, DOI: 10.1587/transcom.2020NVI0001 |
http://www.cttc.es/publication/end-to-end-sdnnfv-orchestration-of-multi-domain-transport-networks-and-distributed-computing-infrastructure-for-beyond-5g-services/ |
| INSPIRE-5Gplus | Ana Hermosilla, Alejandro Molina Zarca, Jorge Bernal Bernabe, Jordi Ortiz, Antonio Skarmeta, “Security orchestration and enforcement in NFV/SDN-aware UAV deployments”, IEEE Access, Vol. 8, pp. 131779 – 131795, DOI: 10.1109/ACCESS.2020.3010209 |
https://ieeexplore.ieee.org/document/9143099 |
| INSPIRE-5Gplus | Gürkan Gür, Mika Ylianttila, Madhusanka Liyanage, Yushan Siriwardhana, Chamitha De Alwis, “The Fight against the COVID-19 Pandemic with 5G Technologies”, IEEE Engineering Management Review, Vol. 48(3), pp. 72-84, 2020, DOI: 10.1109/EMR.2020.3017451 |
https://ieeexplore.ieee.org/document/9170773 |
| TERAWAY | C. Tsokos, E. Andrianopoulos, A. Raptakis, N. Lyras, L. Gounaridis, P. Groumas, H. Avramopoulos, and Ch. Kouloumentas, ‘Optical Beamforming Networks Supporting Multibeam and Multicast Operation’, 22nd International Conference on Transparent Optical Networks (ICTON), Bari, Italy, 1-5 (2020), DOI: 10.1109/ICTON51198.2020.9203380 | https://ieeexplore.ieee.org/document/9203380 |
| TERAWAY | M. U. Sheikh, Kalle Ruttik, N. Saba, E. Mutafungwa, R. Jäntti, and J. Hämäläinen, ‘Analysis of Drone Propagation With Ray Tracing From Sub-6 GHz Upto Terahertz Frequencies in a Real World Urban Environment’, 2021 International Conference on Information Networking (ICOIN), Jeju Island, Korea (South), 169-174 (2021), DOI:10.1109/ICOIN50884.2021.9333892 | https://ieeexplore.ieee.org/document/9333892 |
| TERAWAY | M. Ali, L. E. García-Muñoz, S. Nellen, B. Globisch, G. Carpintero, ‘High-speed Terahertz PIN Photodiode with WR-3 Rectangular Waveguide Output’, 2020 45th International Conference on Infrared, Millimeter, and Terahertz Waves (IRMMW-THz), Buffalo, NY, USA, 1-2 (2020) DOI: 10.1109/IRMMW-THz46771.2020.9370781. | https://ieeexplore.ieee.org/document/9370781 |
| TERAWAY | S. Nellen, S. Lauck, G. Schwanke, M. Deumer, R. B. Kohlhaas, L. Liebermeister, M. Schell, and B. Globisch, ‘Radiation pattern of planar optoelectronic antennas for broadband continuous-wave terahertz emission,” Opt. Express 29, 8244-8257 (2021) DOI: https://doi.org/10.1364/OE.416844 | https://ieeexplore.ieee.org/document/9370781 |
| VITAL-5G | EuCNC 2021 Paper: VITAL-5G: Innovative Network Applications (NetApps) Support over 5G Connectivity for the Transport & Logistics Vertical |
https://cms.cloudguideapp.com/v2/backend/uploads/documents/796_abstract_abstract/1570707652.pdf |
| VITAL-5G | Deliverable D1.1 “Reporton use case requirements”, 30/06/2021 | https://www.vital5g.eu/wp-content/uploads/2021/07/VITAL5G-D1.1_Report-on-Use-case-requirements_v1_Final.pdf |
| VITAL-5G | Deliverable D6.2 “Dissemination and Communication activities v1.0”, 31/05/2021 | https://www.vital5g.eu/wp-content/uploads/2021/07/VITAL5G-D6.2-Dissemination-and-Communication-activities_v1.0.pdf |