The International Telecommunication Union (ITU) announced an IMT-2020 vision as future IMT systems
            should support the enhanced mobile broadband (eMBB) use case, emerging use cases with a variety of
            applications  such  as  massive  machine-type  communications  (mMTC)  and  ultra-reliable  and  low  latency
            communications (URLLC).

            Looking into the future, analysts’ say that new demands, such as more traffic volume, many more devices
            with large gamma of service requirements, better quality of user experience (QoE) and better affordability
            by  further  reducing  costs,  will  require  an  increasing  number  of  innovative  solutions.  The  same  forecast
            experts  claim,  billions  of  people  and  devices  in  5G  networks  will  communicate  at  a  speed  of  1  Gbit/s.
            Technology allowing this should be in place by 2020.
            The new generation of the mobile communication changes roughly each 10 years. Nowadays we are rapidly
            approaching the 5G era of mobile communication. One can question why 4G systems are not good? The
            answer  comes  from  the  ITU-R  5G  vision  document  that  the  exponential  growth  of  the  need  for
            communication over the wireless devises by the end of 2020 will require the high reaction of the system
            (ideally with the delay less that one millisecond) and ultra-broadband connectivity of mass mobile devices.
            This may be further described by the increased flexibility end-to-end, mobility of users while accessing a
            service, energy efficiency and system reliability.
            To set up first steps towards this, ITU-T work on such a pre-5G area as virtualization of the networks further
            developed in the orchestrated software defined networking solutions. IMT-2020 network management and
            orchestration should support a combination of IMT-2020 network systems and existing systems (e.g., LTE-
            Advanced, Wi-Fi and Fixed Network), coupled with new/revolutionary technologies designed to meet new
            customer’s demands. To meet these new requirements, the cost of deployment and operation will increase
            enormously.  Network  operators  need  to optimize  CAPEX/OPEX  by  strategically  interacting with  multiple
            technology ecosystems especially for different radio/fixed access and virtualized core network technologies.
            Therefore,  management  and  orchestration  for  IMT-2020  network  is  required  to  support  both  existing
            networks as well as evolving networks in an integrated manner.
            What is the difference from the previous generation of mobile communication? It is a very rapid response of
            the  system  that  allows  multiple  applications  to  provide  services  almost  immediately.  This  will  have
            implementations  in  the  remote  surgery  and  best  route  choice  for  medical  emergency  to  reach  the  car
            accident  site,  autonomous  driving,  bus/fleet  traffic  management,  railways  or  high  speed  train
            communication, robotics and factory manipulators automation, holograms creation, other latency critical
            applications.  To  give  some  figures,  in  the  future  the  user  will  get  used  to  the  high  quality  video/text
            information he gets on his wireless device at a speed of 10 Gbit/s with the system reply less than 1 ms.

            A dream to have reliable services anytime everywhere at any unit with stable quality independent of the
            access is coming true. In order to have such high-speed communication the latter is pushed to the upper
            frequency bands, tens GHz. These frequency bands are not much in use and will provide a bandwidth for the
            high-speed communication. However the particularity of such frequency bands is an elevated signal loss or
            changes at the recipient side. To avoid this the antennas of the receivers should be located in the proximity
            of the end user. Visible obstacles also caused problems to radio waves propagation at these frequencies.
            Therefore to suit a requirement of the high speed communication the signal should be routed using the
            optimal path to each concrete user taking into account its move relatively to the base station.
            Trials of 5G networks prototypes have already been presented by such companies as: Huawei, Vodafone,
            Nokia, Sonera, Ericsson, Qualcomm, Cisco, Samsung, Huawei, NTT DoCoMo and others. These and other
            representatives of the telecommunication market offer various innovative solutions for the 5G. For example,
            recently, Optus and Huawei have improved the data rate record in pre-5G networks, raising them to 35
            Gbit/s, having tests at 73 GHz, and at the international economic forum in St. Petersburg MegaFon and
            Huawei presented the fifth generation base station in operation, in the millimetre frequency range at a
            frequency of 70 GHz with a bandwidth of 2 GHz, having demonstrated the work of the fifth-generation
            network at a speed of 35 Gbit/s.







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