View on 5G Architecture: Version 1.0

The current white paper focuses on the produced results after one year research mainly from 16 projects working on the abovementioned domains. During several months, representatives from these projects have worked together to identify the key findings of their projects and capture the commonalities and also the different approaches and trends. Also they have worked to determine the challenges that remain to be overcome so as to meet the 5G requirements. The goal of 5G Architecture Working Group is to use the results captured in this white paper to assist the participating projects achieve a common reference framework. The work of this working group will continue during the following year so as to capture the latest results to be produced by the projects and further elaborate this reference framework. The 5G networks will be built around people and things and will natively meet the requirements of three groups of use cases: • Massive broadband (xMBB) that delivers gigabytes of bandwidth on demand • Massive machine-type communication (mMTC) that connects billions of sensors and machines • Critical machine-type communication (uMTC) that allows immediate feedback with high reliability and enables for example remote control over robots and autonomous driving. The demand for mobile broadband will continue to increase in the next years, largely driven by the need to deliver ultra-high definition video. However, 5G networks will also be the platform enabling growth in many industries, ranging from the IT industry to the automotive, manufacturing industries entertainment, etc. 5G will enable new applications like for example autonomous driving, remote control of robots and tactile applications, but these also bring a lot of challenges to the network. Some of these are related to provide low latency in the order of few milliseconds and high reliability compared to fixed lines. But the biggest challenge for 5G networks will be that the services to cater for a diverse set of services and their requirements. To achieve this, the goal for 5G networks will be to improve the flexibility in the architecture. The white paper is organized as follows. In section 2 we discuss the key business and technical requirements that drive the evolution of 4G networks into the 5G. In section 3 we provide the key points of the overall 5G architecture where as in section 4 we elaborate on the functional architecture. Different issues related to the physical deployment in the access, metro and core networks of the 5G network are discussed in section 5 while in section 6 we present software network enablers that are expected to play a significant role in the future networks. Section 7 presents potential impacts on standardization and section 8 concludes the white paper

View on 5G Architecture: Version 2.0

The 5G Architecture Working Group as part of the 5GPPP Initiative is looking at capturing novel trends and key technological enablers for the realization of the 5G architecture. It also targets at presenting in a harmonized way the architectural concepts developed in various projects and initiatives (not limited to 5GPPP projects only) so as to provide a consolidated view on the technical directions for the architecture design in the 5G era. The first version of the white paper was released in July 2016, which captured novel trends and key technological enablers for the realization of the 5G architecture vision along with harmonized architectural concepts from 5GPPP Phase 1 projects and initiatives. Capitalizing on the architectural vision and framework set by the first version of the white paper, this Version 2.0 of the white paper presents the latest findings and analyses with a particular focus on the concept evaluations, and accordingly it presents the consolidated overall architecture design

Towards User-Centric Operation in 5G Networks

© 2016 Monserrat et al. Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made.There are three pillars that characterize the new 5G revolution, namely, the use of heterogeneous wireless access technologies conforming an ultra-dense network, the software-driven flexibility of this network, and the simplified and user-centric operation and management of the system. This next-generation network operation and management shall be based on the usage of Big Data Analytics techniques to monitor the end-user quality of experience through direct measures of the network. This paper describes the Astellia approach towards this network revolution and presents some results on the performance of quality estimation techniques in current cellular networks. Thanks to the use of this approach, operators may fill the gap of knowledge between network key performance indicators and user experience. This way, they can operate in a proactive manner and have actual measurements of the users' experience, which leads to a fairer judgement of the users' complaints.The authors would like to thank the funding received from the Ministerio de Industria, Energia y Turismo TSI-100102-2013-106 funds.Monserrat Del Río, JF.; Alepuz Benaches, I.; Cabrejas Peñuelas, J.; Osa Ginés, V.; López Bayo, J.; García-Zarza, R.; Domenech-Benlloch, MJ.... (2016). Towards User-Centric Operation in 5G Networks. EURASIP Journal on Wireless Communications and Networking. 2016(6):1-7. https://doi.org/10.1186/s13638-015-0506-zS1720166J Monserrat et al., Rethinking the mobile and wireless network architecture: the METIS research into 5G, in European Conference on Networks and Communications (EuCNC), 2014, pp. 1–55G-PPP, The 5G Infrastructure Public Private Partnership: the next generation of communication networks and services, 2015. Available at http://5g-ppp.eu/wp-content/uploads/2015/02/5G-Vision-Brochure-v1.pdfJF Monserrat, M Fallgren (eds.), Report on simulation results and evaluations, 2015. ICT-317669 METIS Deliverable 6.5Z Yingxiao, Z Ying Jun, User-centric virtual cell design for Cloud Radio Access Networks, in IEEE Signal Processing Advances in Wireless Communications (SPAWC), 2014, pp. 249–253JF Monserrat, G Mange, V Braun, H Tullberg, G Zimmermann, Ö Bulakci, METIS research advances towards the 5G mobile and wireless system definition. EURASIP. J. Wirel. Commun. Netw. 2015, 53 (2015)F Boccardi, RW Heath, A Lozano, TL Marzetta, P Popovski, Five disruptive technology directions for 5G. IEEE. Commun. Mag. 52(2), 74–80 (2014)P Agyapong, M Iwamura, D Staehle, W Kiess, A Benjebbour, Design considerations for a 5G network architecture. IEEE. Commun. Mag. 52(11), 65–75 (2014)Nokia Siemens Networks, Acquisition and retention white paper, 2013. http://networks.nokia.com/sites/default/files/document/acquisition___retention_white_paper.pdfDZ Yazti, S Krishnaswamy, Mobile big data analytics: research, practice, and opportunities, in IEEE 15th International Conference on Mobile Data Management (MDM), 2014R Kreher, UMTS performance measurement: a practical guide to KPIs for the UTRAN environment (Wiley, Chichester, 2006)S Mehrotra, On the implementation of a primal-dual interior point method. SIAM. J. Optim. 2, 575–601 (1992)V Osa, J Matamales, J Monserrat, J Lopez, Localization in wireless networks: the potential of triangulation techniques. Wirel. Pers. Commun. 68(4), 1525–1538 (2013