5G

For other uses, see 5G (disambiguation).

5th generation mobile networks or 5th generation wireless systems, abbreviated 5G, are the proposed next telecommunications standards beyond the current 4G/IMT-Advanced standards. Rather than faster peak Internet connection speeds, 5G planning aims at higher capacity than current 4G, allowing higher number of mobile broadband users per area unit, and allowing consumption of higher or unlimited data quantities in gigabyte per month and user. This would make it feasible for a large portion of the population to stream high-definition media many hours per day with their mobile devices, when out of reach of wifi hotspots. 5G research and development also aims at improved support of machine to machine communication, also known as the Internet of things, aiming at lower cost, lower battery consumption and lower latency than 4G equipment.

There is currently no standard for 5G deployments. The Next Generation Mobile Networks Alliance defines the following requirements that a 5G standard should fulfill:[1]

The Next Generation Mobile Networks Alliance feels that 5G should be rolled out by 2020 to meet business and consumer demands.[3] In addition to providing simply faster speeds, they predict that 5G networks also will need to meet new use cases,[4] such as the Internet of Things (internet connected devices) as well as broadcast-like services and lifeline communication in times of natural disaster. Carriers, chipmakers, OEMS and OSATs, such as Advanced Semiconductor Engineering (ASE), have been gearing up for this next-generation (5G) wireless standard, as mobile systems and base stations will require new and faster application processors, basebands and RF devices.[5]

Although updated standards that define capabilities beyond those defined in the current 4G standards are under consideration, those new capabilities have been grouped under the current ITU-T 4G standards. The U.S. Federal Communications Commission (FCC) approved the spectrum for 5G, including the 28 Gigahertz, 37 GHz and 39 GHz bands, on July 14, 2016.[6][7]

Background

A new mobile generation has appeared approximately every 10 years since the first 1G system, Nordic Mobile Telephone, was introduced in 1982. The first '2G' system was commercially deployed in 1992, and the 3G system appeared in 2001. 4G systems fully compliant with IMT Advanced were first standardized in 2012. The development of the 2G (GSM) and 3G (IMT-2000 and UMTS) standards took about 10 years from the official start of the R&D projects, and development of 4G systems began in 2001 or 2002.[8][9] Predecessor technologies have been on the market a few years before the new mobile generation, for example the pre-3G system CdmaOne/IS95 in the US in 1995, and the pre-4G systems Mobile WiMAX in South-Korea 2006, and first release-LTE in Scandinavia 2009. In April 2008, NASA partnered with Machine-to-Machine Intelligence (M2Mi) Corp to develop 5G communication technology[10]

Mobile generations typically refer to nonbackward-compatible cellular standards following requirements stated by ITU-R, such as IMT-2000 for 3G and IMT-Advanced for 4G. In parallel with the development of the ITU-R mobile generations, IEEE and other standardization bodies also develop wireless communication technologies, often for higher data rates, higher frequencies, shorter transmission ranges, no support for roaming between access points and a relatively limited multiple access scheme. The first gigabit IEEE standard was IEEE 802.11ac, commercially available since 2013, soon to be followed by the multigigabit standard WiGig or IEEE 802.11ad.

Debate

Based on the above observations, some sources suggest that a new generation of 5G standards may be introduced in the early 2020s.[11][12] However, significant debate continued, on what 5G is about exactly. Prior to 2012, some industry representatives expressed skepticism toward 5G.[13] 3GPP held a conference in September 2015 to plan development of the new standard.[14]

New mobile generations are typically assigned new frequency bands and wider spectral bandwidth per frequency channel (1G up to 30 kHz, 2G up to 200 kHz, 3G up to 5 MHz, and 4G up to 20 MHz), but skeptics argue that there is little room for larger channel bandwidths and new frequency bands suitable for land-mobile radio.[13] The higher frequencies would overlap with K-band transmissions of communication satellites.[15] From users' point of view, previous mobile generations have implied substantial increase in peak bitrate (i.e. physical layer net bitrates for short-distance communication), up to 1 gigabit per second to be offered by 4G.

If 5G appears and reflects these prognoses, then the major difference, from a user point of view, between 4G and 5G must be something other than faster speed (increased peak bit rate). For example, higher number of simultaneously connected devices, higher system spectral efficiency (data volume per area unit), lower battery consumption, lower outage probability (better coverage), high bit rates in larger portions of the coverage area, lower latencies, higher number of supported devices, lower infrastructure deployment costs, higher versatility and scalability, or higher reliability of communication. Those are the objectives in several of the research papers and projects below.

GSMHistory.com[16] has recorded three very distinct 5G network visions that had emerged by 2014:

In its white paper, 5G Empowering Vertical Industries, 5G PPP, the collaborative research programme organized as part of the European Commission's Horizon 2020 programme, suggests that to support the main vertical sectors in Europe - namely automotive, transportation, healthcare, energy, manufacturing, and media and entertainment - the most important 5G infrastructure performance requirements are a latency below 5 ms, support for device densities of up to 100 devices/m2 and reliable coverage area, and that a successful 5G deployment will integrate telecommunication technologies including mobile, fixed, optical and satellite (both GEO and MEO).[18]

Research & development projects

In 2008, the South Korean IT R&D program of "5G mobile communication systems based on beam-division multiple access and relays with group cooperation" was formed.[19]

In 2012, the UK Government announced the establishment of a 5G Innovation Centre at the University of Surrey – the world's first research center set up specifically for 5G mobile research.[20]

In 2012, NYU WIRELESS was established as a multidisciplinary research center, with a focus on 5G wireless research, as well as its use in the medical and computer-science fields. The center is funded by the National Science Foundation and a board of 10 major wireless companies (as of July 2014) that serve on the Industrial Affiliates board of the center. NYU WIRELESS has conducted and published channel measurements that show that millimeter wave frequencies will be viable for multigigabit-per-second data rates for future 5G networks.

In 2012, the European Commission, under the lead of Neelie Kroes, committed 50 million euros for research to deliver 5G mobile technology by 2020.[21] In particular, The METIS 2020 Project was the flagship project that allowed reaching a world-wide consensus on the requirements and key technology components of the 5G. Driven by several telecommunication companies, the METIS overall technical goal was to provide a system concept that supports 1,000 times higher mobile system spectral efficiency, compared to current LTE deployments.[4][12] In addition, in 2013, another project has started, called 5GrEEn,[22] linked to project METIS and focusing on the design of green 5G mobile networks. Here the goal is to develop guidelines for the definition of a new-generation network with particular emphasis on energy efficiency, sustainability and affordability.

In November 2012, a research project funded by the European Union under the ICT Programme FP7 was launched under the coordination of IMDEA Networks Institute (Madrid, Spain): i-JOIN (Interworking and JOINt Design of an Open Access and Backhaul Network Architecture for Small Cells based on Cloud Networks). iJOIN introduces the novel concept of the radio access network (RAN) as a service (RANaaS), where RAN functionality is flexibly centralized through an open IT platform based on a cloud infrastructure. iJOIN aims for a joint design and optimization of access and backhaul, operation and management algorithms, and architectural elements, integrating small cells, heterogeneous backhaul and centralized processing. Additionally to the development of technology candidates across PHY, MAC, and the network layer, iJOIN will study the requirements, constraints and implications for existing mobile networks, specifically 3GPP LTE-A.

In January 2013, a new EU project named CROWD (Connectivity management for eneRgy Optimised Wireless Dense networks) was launched under the technical supervision of IMDEA Networks Institute, to design sustainable networking and software solutions for the deployment of very dense, heterogeneous wireless networks. The project targets sustainability targeted in terms of cost effectiveness and energy efficiency. Very high density means 1000x higher than current density (users per square meter). Heterogeneity involves multiple dimensions, from coverage radius to technologies (4G/LTE vs. Wi-Fi), to deployments (planned vs. unplanned distribution of radio base stations and hot spots).

In September 2013, the Cyber-Physical System (CPS) Lab at Rutgers University, NJ, started to work on dynamic provisioning and allocation under the emerging cloud radio-access network (C-RAN). They have shown that the dynamic demand-aware provisioning in the cloud will decrease the energy consumption while increasing the resource utilization.[23] They also have implemented a test bed for feasibility of C-RAN and developed new cloud-based techniques for interference cancellation. Their project is funded by the National Science Foundation.

In November 2013, Chinese telecom equipment vendor Huawei said it will invest $600 million in research for 5G technologies in the next five years.[24] The company's 5G research initiative does not include investment to productize 5G technologies for global telecom operators. Huawei will be testing 5G technology in Malta.[25][26]

In 2015, Huawei and Ericsson are testing 5G-related technologies in rural areas in northern Netherlands.[27]

In July 2015, the METIS-II and 5GNORMA European projects were launched. The METIS-II project[28] builds on the successful METIS project and will develop the overall 5G radio access network design and to provide the technical enablers needed for an efficient integration and use of the various 5G technologies and components currently developed. METIS-II will also provide the 5G collaboration framework within 5G-PPP for a common evaluation of 5G radio access network concepts and prepare concerted action towards regulatory and standardisation bodies. On the other hand, the key objective of 5G NORMA is to develop a conceptually novel, adaptive and future-proof 5G mobile network architecture. The architecture is enabling unprecedented levels of network customisability, ensuring stringent performance, security, cost and energy requirements to be met; as well as providing an API-driven architectural openness, fuelling economic growth through over-the-top innovation. With 5G NORMA, leading players in the mobile ecosystem aim to underpin Europe's leadership position in 5G.[29]

Additionally, in July 2015, the European research project mmMAGIC was launched. The mmMAGIC project will develop new concepts for mobile radio access technology (RAT) for mmwave band deployment. This is a key component in the 5G multi-RAT ecosystem and will be used as a foundation for global standardization. The project will enable ultrafast mobile broadband services for mobile users, supporting UHD/3D streaming, immersive applications and ultra-responsive cloud services. A new radio interface, including novel network management functions and architecture components will be designed taking as guidance 5G PPP's KPI and exploiting the use of novel adaptive and cooperative beam-forming and tracking techniques to address the specific challenges of mm-wave mobile propagation. The ambition of the project is to pave the way for a European head start in 5G standards and to strengthen European competitiveness. The consortium brings together major infrastructure vendors, major European operators, leading research institutes and universities, measurement equipment vendors and one SME. mmMAGIC is led and coordinated by Samsung. Ericsson acts as technical manager while Intel, Fraunhofer HHI, Nokia, Huawei and Samsung will each lead one of the five technical work packages of the project. [30]

In July 2015, IMDEA Networks launched the Xhaul project, as part of the European H2020 5G Public-Private Partnership (5G PPP). Xhaul will develop an adaptive, sharable, cost-efficient 5G transport network solution integrating the fronthaul and backhaul segments of the network. This transport network will flexibly interconnect distributed 5G radio access and core network functions, hosted on in-network cloud nodes. Xhaul will greatly simplify network operations despite growing technological diversity. It will hence enable system-wide optimisation of Quality of Service (QoS) and energy usage as well as network-aware application development. The Xhaul consortium comprises 21 partners including leading telecom industry vendors, operators, IT companies, small and medium-sized enterprises and academic institutions. [31]

In July 2015, the European 5G research project Flex5Gware was launched. The objective of Flex5Gware is to deliver highly reconfigurable hardware (HW) platforms together with HW-agnostic software (SW) platforms targeting both network elements and devices and taking into account increased capacity, reduced energy footprint, as well as scalability and modularity, to enable a smooth transition from 4G mobile wireless systems to 5G. This will enable that 5G HW/SW platforms can meet the requirements imposed by the anticipated exponential growth in mobile data traffic (1000 fold increase) together with the large diversity of applications (from low bit-rate/power for M2M to interactive and high resolution applications).[32]

In July 2015, the SUPERFLUIDITY project, part of the European H2020 Public-Private Partnership (5G PPP) and led by CNIT, an Italian inter-university consortium, was started. The SUPERFLUIDITY consortium comprises telcos and IT players for a total of 18 partners. In physics, superfluidity is a state in which matter behaves like a fluid with zero viscosity. The SUPERFLUIDITY project aims at achieving superfluidity in the Internet: the ability to instantiate services on-the-fly, run them anywhere in the network (core, aggregation, edge) and shift them transparently to different locations. The project tackles crucial shortcomings in today's networks: long provisioning times, with wasteful over-provisioning used to meet variable demand; reliance on rigid and cost-ineffective hardware devices; daunting complexity emerging from three forms of heterogeneity: heterogeneous traffic and sources; heterogeneous services and needs; and heterogeneous access technologies, with multi-vendor network components. SUPERFLUIDITY will provide a converged cloud-based 5G concept that will enable innovative use cases in the mobile edge, empower new business models, and reduce investment and operational costs. [33]

In September 2016, China Ministry of Industry and Information Technology (MIIT) announced that the government-led 5G Phase-1 tests of key wireless technologies for future 5G networks were completed with satisfactory results. Seven companies were invited to participate – Datang Telecom, Ericsson, Huawei, Intel, Nokia Shanghai Bell, Samsung and ZTE. The next step in China 5G technology development involving tech trials is underway. These government efforts as well as tests across 100 cities and the schedule to launch commercial operation of 5G in 2020, following with large-scale deployments in 2022 or 2023 underscore China’s aim to be a leader of 5G technology development and 5G commercialization.

Research

The first widely cited proposal for the use of millimeter wave spectrum for cellular/mobile communications appeared in the IEEE Communications Magazine in June 2011.[34] The first reports of radio channel measurements that validated the ability to use millimeter wave frequencies for urban mobile communication were published in April and May 2013 in the IEEE Access Journal and IEEE Transactions on Antennas and Propagation, respectively.[35][36]

The IEEE Journal on Selected Areas in Communications published a special issue on 5G in June 2014, including, a comprehensive survey of 5G enabling technologies and solutions.[37] IEEE Spectrum has a story about millimeter-wave wireless communications as a viable means to support 5G in its September 2014 issue.[38]

History

See also

Further reading

References

  1. Afif Osseiran; et al. (May 2014). "Scenarios for 5G mobile and wireless communications: the vision of the METIS project". Communications Magazine. IEEE. 52 (5). doi:10.1109/MCOM.2014.6815890. ISSN 1790-0832.
  2. Best, Jo (2013-08-28). "The race to 5G: Inside the fight for the future of mobile as we know it". TechRepublic. Retrieved 2016-01-14.
  3. https://www.ngmn.org/uploads/media/NGMN_5G_White_Paper_V1_0.pdf
  4. 1 2 3 4 5 6 Afif Osseiran; Jose F. Monserrat; Patrick Marsch (June 2016). 5G Mobile and Wireless Communications Technology. Cambridge University Press. ISBN 9781107130098. Retrieved 20 July 2016.
  5. By Mark LaPedus, Semiconductor Engineering. “Waiting For 5G Technology.” June 23, 2016. Retrieved September 2, 2016.
  6. Mike, Snider (July 14, 2016). "FCC Approves Spectrum for 5G Advances". USA Today. Retrieved 25 July 2016.
  7. Tom, Wheeler. "Leading Towards Next Generation "5G" Mobile Services". Federal Communications Commission. Federal Communications Commission. Retrieved 25 July 2016.
  8. 1 2 3 4 5 Akhtar, Shakil (August 2008) [2005]. Pagani, Margherita, ed. 2G-5G Networks: Evolution of Technologies, Standards, and Deployment (Second ed.). Hershey, Pennsylvania, US: IGI Global. pp. 522–532. doi:10.4018/978-1-60566-014-1.ch070. ISBN 978-1-60566-014-1. Archived from the original (PDF) on 2 June 2011. Retrieved 2 June 2011.
  9. Emerging Wireless Technologies; A look into the future of wireless communication – beyond 3G (PDF). SafeCom (a US Department of Homeland Security program). Retrieved 27 September 2013. Since the general model of 10 years to develop a new mobile system is being followed, that time line would suggest 4G should be operational some time around 2011.
  10. 1 2 "NASA Ames Partners With M2MI For Small Satellite Development".
  11. Xichun Li; Abudulla Gani; Rosli Salleh; Omar Zakaria (February 2009). The Future of Mobile Wireless Communication Networks (PDF). International Conference on Communication Software and Networks. ISBN 978-0-7695-3522-7. Retrieved 27 September 2013.
  12. 1 2 "The METIS 2020 Project – Mobile and Wireless Communication Enablers for the 2020 Information Society" (PDF). METIS. 6 July 2013. Retrieved 27 September 2013.
  13. 1 2 "Interview with Ericsson CTO: There will be no 5G - we have reached the channel limits". DNA India. 23 May 2011. Retrieved 27 September 2013.
  14. "RAN 5G Workshop - The Start of Something". 3GPP. September 19, 2015. Retrieved 30 September 2015.
  15. "In 5G proceeding, SpaceX urges FCC to protect future satellite ventures". FierceWirelessTech. Retrieved 2015-10-02.
  16. "what is 5g, 5g visions,". GSM History: History of GSM, Mobile Networks, Vintage Mobiles. GSMHistory.com.
  17. "Demand Attentive Networks (DAN)".
  18. 5G Empowering Vertical Industries (White Paper). 5G PPP. February 2016. Retrieved March 1, 2016
  19. 1 2 The Korean IT R&D program of MKE/IITA: 2008-F-004-01 "5G mobile communication systems based on beam-division multiple access and relays with group cooperation".
  20. "5G Innovation Centre". University of Surrey - Guildford.
  21. "Mobile communications: Fresh €50 million EU research grants in 2013 to develop '5G' technology". Europa.eu. 26 February 2013. Retrieved 27 September 2013.
  22. "5GrEEn project webpage - Towards Green 5G Mobile Networks". EIT ICT Labs. 15 January 2013. Retrieved 27 September 2013.
  23. Pompili, Dario; Hajisami, Abolfazl; Viswanathan, Hariharasudhan (March 2015). "Dynamic Provisioning and Allocation in Cloud Radio Access Networks (C-RANs)". Ad Hoc Networks. 30: 128–143. doi:10.1016/j.adhoc.2015.02.006.
  24. "Huawei to Invest $600M in 5G Research & Innovation by 2018 - Huawei Press Center". Huawei. Retrieved 2016-01-14.
  25. Allied Newspapers Ltd. "Update 2: Agreement for 5G technology testing signed; 'You finally found me' - Sai Mizzi Liang". timesofmalta.com. Retrieved 2016-01-14.
  26. Allied Newspapers Ltd. "PM thanks Sai Mizzi as Chinese telecoms giant prepares to test 5G in Malta". timesofmalta.com. Retrieved 2016-01-14.
  27. "Noord-Groningen krijgt onvoorstelbaar snel mobiel internet". RTV Noordx. August 2015.
  28. 1 2 "The METIS-II Project – Mobile and Wireless Communication Enablers for the 2020 Information Society". METIS. 1 July 2015. Retrieved 20 July 2016.
  29. "5GNORMA website".
  30. "mmMAGIC website".
  31. "Xhaul website".
  32. "Flex5Gware website".
  33. "SUPERFLUIDITY website".
  34. Z. Pi, F. Khan, "An introduction to millimeter-wave mobile broadband systems," IEEE Communications Magazine, Vol. 49, No. 6, June 2011, pp. 101-107.
  35. T. S. Rappaport, et. al., "Millimeter Wave Mobile Communications for 5G Cellular: It will work!," IEEE Access, No. 1, Vol. 1,p. 335-354.
  36. T. S. Rappaport, "Broadband Millimeter-Wave Propagation Measurements and Models Using Adaptive-Beam Antennas for Outdoor Urban Cellular Communications, " IEEE Trans. Ant. Prop., Vol. 61, No. 4, pp. 1850-1859, April 2013.
  37. J. G. Andrews, S. Buzzi, W. Choi, S. Hanly, A. Lozano, A.C.K. Soong, and J. Zhang, "What will 5G be?," IEEE Journal on Selected Areas in Communications, Vol. 32, No. 6, pp. 1065 - 1082, June 2014.
  38. Theodore S. Rappaport, Wonil Roh & Kyungwhoon Cheun," Mobile's Millimeter-Wave Makeover," IEEE Spectrum, Vol. 51, No. 9, pp. 34-58, Sept. 2014.
  39. T. S. Rappaport, et. al., "Wideband Millimeter-Wave Propagation Measurements and Channel Models for Future Wireless Communication System Design," IEEE Trans. Comm., Vol. 63, No. 9, Sept. 2015, pp. 3029-3056.
  40. G. MacCartney, et. al., "Indoor Office Wideband Millimeter-Wave Propagation Measurements and Channel Models at 28 and 73 GHz for Ultra-Dense 5G Wireless Networks," IEEE Access, Vol. 3, 2388-2424, October 2015.
  41. T. L. Marzetta (November 2010). "Noncooperative Cellular Wireless with Unlimited Numbers of Base Station Antennas". IEEE Transactions on Wireless Communications. Bell Labs., Alcatel-Lucent. 9 (11): 56–61, 3590–3600. doi:10.1109/TWC.2010.092810.091092. ISSN 1536-1276.
  42. J. Hoydis; S. ten Brink; M. Debbah (February 2013). "Massive MIMO in the UL/DL of Cellular Networks: How Many Antennas Do We Need?". IEEE Journal on Selected Areas in Communications. Bell Labs., Alcatel-Lucent. 31 (2): 160–171. doi:10.1109/JSAC.2013.130205.
  43. E. Bjornson; E. G. Larsson; M. Debbah (February 2016). "Massive MIMO for Maximal Spectral Efficiency: How Many Users and Pilots Should Be Allocated?". IEEE Transactions on Wireless Communications. IEEE. 15 (2): 1293–1308. doi:10.1109/TWC.2015.2488634.
  44. E. Bjornson; L. Sanguinetti; J. Hoydis; M. Debbah (June 2015). "Optimal Design of Energy-Efficient Multi-User MIMO Systems: Is Massive MIMO the Answer?". IEEE Transactions on Wireless Communications. IEEE. 14 (6): 3059–3075. doi:10.1109/TWC.2015.2400437.
  45. Rusek, F.; Persson, D.; Buon Kiong Lau; Larsson, E.G.; Marzetta, T.L.; Edfors, O.; Tufvesson, F (2013). "Scaling Up MIMO: Opportunities and Challenges with Very Large Arrays". IEEE Signal Processing Magazine. 30 (1): 40, 60. Bibcode:2013ISPM...30...40R. doi:10.1109/MSP.2011.2178495. Retrieved 7 January 2013.
  46. B. Kouassi, I. Ghauri, L. Deneire, Reciprocity-based cognitive transmissions using a MU massive MIMO approach. IEEE International Conference on Communications (ICC), 2013
  47. E. Bastug; M. Bennis; M. Debbah (August 2014). "Living on the edge: The role of proactive caching in 5G wireless networks". IEEE Communications Magazine. IEEE. 52 (8): 82–89. doi:10.1109/MCOM.2014.6871674.
  48. E. Bastug; M. Bennis; M. Kountouris; M. Debbah (August 2014). "Cache-enabled small cell networks: modeling and tradeoffs". EURASIP Journal on Wireless Communications and Networking. Springer. 2015 (1): 41. arXiv:1405.3477Freely accessible [cs.IT]. Bibcode:2014arXiv1405.3477B. Retrieved 8 November 2015.
  49. Semiari, Omid; Saad, Walid; Bennis, Mehdi; Valentin, Stefan; Poor, Vincent (2015). "Context-Aware Small Cell Networks: How Social Metrics Improve Wireless Resource Allocation". IEEE Transactions on Wireless Communications. 14 (11): 5927–5940. arXiv:1505.04220Freely accessible. Bibcode:2015arXiv150504220S. doi:10.1109/TWC.2015.2444385.
  50. Gu, Yunan; Saad, Walid; Bennis, Mehdi; Debbah, Merouane; Han, Zhu (2015). "Matching Theory for Future Wireless Networks: Fundamentals and Applications". IEEE Communications Magazine. 53 (15): 52–59. arXiv:1410.6513Freely accessible. Bibcode:2014arXiv1410.6513G. doi:10.1109/MCOM.2015.7105641.
  51. Zhang, Yanru; Pan, Erte; Song, Lingyang; Saad, Walid; Dawy, Zaher; Han, Zhu (2015). "Social Network Aware Device-to-Device Communication in Wireless Networks" (PDF). IEEE Transactions on Wireless Communications. 14 (1).
  52. "Communications, Caching, and Computing for Content-Centric Mobile Networks | IEEE Communications Society". Comsoc.org. 2016-01-01. Retrieved 2016-01-14.
  53. 1 2 3 Asadi, Arash; Wang, Qing; Mancuso, Vincenzo (24 April 2014). "A Survey on Device-to-Device Communication in Cellular Networks". Communications Surveys & Tutorials, IEEE. 16 (4): 1801-1819.
  54. D. Gesbert; S. Hanly; H. Huang; S. Shamai; O. Simeone; W. Yu (December 2010). "Multi-cell MIMO cooperative networks: A new look at interference". IEEE Journal on Selected Areas in Communications. EURECOM. 28 (9): 1380–1408. doi:10.1109/JSAC.2010.101202.
  55. Emil Björnson; Eduard Jorswieck (2013). "Optimal Resource Allocation in Coordinated Multi-Cell Systems". Foundations and Trends in Communications and Information Theory. NOW – The Essence of Knowledge. 9 (2–3): 113–381. Retrieved 27 September 2013.
  56. Samarakoon, Sumudu; Bennis, Mehdi; Saad, Walid; Matti, Latva-aho (2016). "Dynamic Clustering and ON/OFF Strategies for Wireless Small Cell Networks". IEEE Transactions on Wireless Communications. 15 (3). arXiv:1511.08631Freely accessible.
  57. R. Baldemair; E. Dahlman; G. Fodor; G. Mildh; S. Parkvall; Y. Selen; H. Tullberg; K. Balachandran (March 2013). "Evolving Wireless Communications: Addressing the Challenges and Expectations of the Future". IEEE Vehicular Technology Magazine. Ericsson Research. 8 (1): 24–30. doi:10.1109/MVT.2012.2234051.
  58. 1 2 3 Abdullah Gani; Xichun Li; Lina Yang; Omar Zakaria; Nor Badrul Anuar (February 2009). "Multi-Bandwidth Data Path Design for 5G Wireless Mobile Internets". WSEAS Transactions on Information Science and Applications archive. 6 (2). ISSN 1790-0832. Retrieved 27 September 2013.
  59. C. Liang; F. Richard Yu (2014). "Wireless Network Virtualization: A Survey, Some Research Issues and Challenges". IEEE Communications Surveys & Tutorials. Retrieved 3 November 2014.
  60. Loretta W. Prencipe (28 February 2003). "Tomorrow's 5g cell phone; Cognitive radio, a 5g device, could forever alter the power balance from wireless service provider to user". Infoworld Newsletters / Networking. Retrieved 27 September 2013.
  61. Cornelia-Ionela Badoi; Neeli Prasad; Victor Croitoru; Ramjee Prasad (2010). "5G based cognitive radio". Wireless Personal Communications. 57 (3): 441–464. doi:10.1007/s11277-010-0082-9. Retrieved 27 September 2013.
  62. Leonardo S. Cardoso; Marco Maso; Mari Kobayashi; Mérouane Debbah (July 2011). "Orthogonal LTE two-tier Cellular Networks" (PDF). 2011 IEEE International Conference on Communications: 1–5. Retrieved 27 September 2013.
  63. Toni Janevski (10–13 January 2009). 5G Mobile Phone Concept. Consumer Communications and Networking Conference, 2009 6th IEEE. Facility of Electrical Engineering & Information Technology, University Sv. Kiril i Metodij. ISBN 1-4244-2308-2. Retrieved 27 September 2013.
  64. National Instruments and the University of Edinburgh Collaborate on Massive MIMO Visible Light Communication Networks to Advance 5G, Cambridge Wireless, 20 November 2013
  65. "The world's first academic research center combining Wireless, Computing, and Medical Applications". Nyu Wireless. 2014-06-20. Retrieved 2016-01-14.
  66. "NYU Wireless' Rappaport envisions a 5G, millimeter-wave future - FierceWirelessTech". Fiercewireless.com. 2014-01-13. Retrieved 2016-01-14.
  67. Alleven, Monica (2015-01-14). "NYU Wireless says U.S. falling behind in 5G, presses FCC to act now on mmWave spectrum". Fiercewireless.com. Retrieved 2016-01-14.
  68. Kelly, Spencer (13 October 2012). "BBC Click Programme - Kenya". BBC News Channel. Retrieved 15 October 2012. Some of the world biggest telecoms firms have joined forces with the UK government to fund a new 5G research center. The facility, to be based at the University of Surrey, will offer testing facilities to operators keen to develop a mobile standard that uses less energy and less radio spectrum, while delivering faster speeds than current 4G technology that's been launched in around 100 countries, including several British cities. They say the new tech could be ready within a decade.
  69. "The University Of Surrey Secures £35M For New 5G Research Centre". University of Surrey. 8 October 2012. Retrieved 15 October 2012.
  70. "5G research centre gets major funding grant". BBC News. BBC News Online. 8 October 2012. Retrieved 15 October 2012.
  71. Philipson, Alice (9 October 2012). "Britain aims to join mobile broadband leaders with £35m '5G' research centre". The Daily Telegraph. London: Telegraph Media Group. Retrieved 7 January 2013.
  72. "METIS projet presentation" (PDF). November 2012.
  73. "Speech at Mobile World Congress: The Road to 5G". March 2015.
  74. "삼성전자, 5세대 이동통신 핵심기술 세계 최초 개발". 12 May 2013. Retrieved 12 May 2013.
  75. "General METIS presentations available for public".
  76. "India and Israel have agreed to work jointly on development of 5G". The Times Of India. 25 July 2013. Retrieved 25 July 2013.
  77. "DoCoMo Wins CEATEC Award for 5G". 3 October 2013. Retrieved 3 October 2013.
  78. Embley, Jochan (6 November 2013). "Huawei plans $600m investment in 10Gbps 5G network". The Independent. London. Retrieved 11 November 2013.
  79. "Japan's NTT DoCoMo to Start Testing 5G Mobile Networks". cellular-news. 2014-05-08. Retrieved 2014-05-08.
  80. ""Мегафон" и Huawei начинают создание сети 5G". CNews. 19 November 2014. Retrieved 19 November 2014.
  81. "Huawei plans to trial 5G mobile internet at the 2018 World Cup". TechRadar. 19 November 2014. Retrieved 19 November 2014.
  82. "SingTel and Huawei Ink MOU to Launch 5G Joint Innoviation Program". Huawei. 19 November 2014. Retrieved 21 November 2014.
  83. "Μέτρα €7,9 δισ. το 2015-2016 προτείνει η κυβέρνηση". Capital.gr. 2014-12-31. Retrieved 2016-01-14.
  84. "Verizon sets roadmap to 5G technology in U.S.; Field trials to start in 2016". Verizon. 8 September 2015. Retrieved 9 September 2015.
  85. Directmatin. "Orange va expérimenter la 5G en France" (in French). www.directmatin.fr. Retrieved 2016-01-14.
  86. Ericsson. "TeliaSonera and Ericsson go 5G". www.ericsson.com. Retrieved 2016-01-26.
  87. NTT Docomo. "https://www.nttdocomo.co.jp/english/info/media_center/pr/2016/0222_03.html" Retrieved 2016-05-21.
  88. By Alan F., Phone Arena. "Verizon, partnering with Samsung, starts 5G trials." February 22, 2016. Retrieved July 13, 2016.
  89. Harris, Mark (29 January 2016). "Project Skybender: Google's secretive 5G internet drone tests revealed". The Guardian. Retrieved 31 January 2016.
  90. "Government confirmed plans to make the UK a world leader in 5G".
  91. "Qualcomm Announces Its First 5G Modem". PCMAG. Retrieved 2016-10-21.
  92. "Snapdragon X50 5G Modem". Qualcomm. 2016-09-26. Retrieved 2016-10-21.
  93. Liyanage, Madhusanka (2015). Software Defined Mobile Networks (SDMN): Beyond LTE Network Architecture. UK: Wiley Publishers. pp. 1–438. ISBN 978-1-118-90028-4.

External links

Preceded by
4th Generation (4G)
Mobile Telephony Generations Succeeded by
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