Mr. Takaharu Nakamura Acting Chairman, Technical Committee 5GMF and Fujitsu Hosted by
5G for 2020s and beyond Nakamura, Takaharu Acting Chairman, Technical Committee of 5GMF, Fujitsu 2
Outline 1 Role of 5G (Bridging Digital World and Physical World) 2 Background (What s going on?) 3 A case study (Basic exercises on demographics of Japan and Tokyo) 4 Then what to do and how (UDN as an example) 5 Conclusion (a trailer before the coming table talks) 3
Role of 5G Bridging Digital World and Physical World 4
5G role: Bridging Digital World and Physical World Disaster Prediction Shared Experience Remote Access Smart Citizen Services Transport massive information Secure, Stable, Efficient connectivity Sensing 5G Navigation Real-time feedback Advanced analysis technique 5G ICT creates new knowledge and supports activity of humans and machines in real time, by analyzing large amounts of data in physical world. 5
Background of 5G Mass wholesales to Retail sales of communication services over and above 6
Market demands and Mobile Communication systems 1980s 1990s 2000s 2010s 2020s Mobile Core Network profile Radio Access Technologies Market Demand W-LAN (R-LAN) Analog cell phone systems ISDN Voice Call Capacity improvement PDC AMPS GSM (2G) ATM Global standard + Multi-media capable IMT-2000 (3G) IP network Mass wholesales of communication services of unified Quality/Nature LTE (3.9G) LTE-Advanced (4G) IP friendly mobile ( Portable Internet) W-LAN [IEEE802 series] Portable Doors to Variety of Services Mass 2020&Beyond sales plus ( 5G ) Retail sales of variety of communications services 7
Applications Usage scenarios enabled of IMT-2020 by 5G and beyond Quality of User Experience (Reliability, Low latency) Applications enabled by 5G Enhancement mobile broadband( embb) Online trading Infrastructure Autonomous Augmented / Telemedicine surveillance driving Virtual reality Sensor-assisted rehabilitation Computer-supported cooperative work 4K/8K live streaming for public sports viewing Dynamic hot-spot services Huge density area/ Peak-hour Commuters Applications delivered by existing technologies Massive machine type Communications( mmtc) Quantity of Data (Peak data rate, Number of devices) Ultra - reliable & low latency Communications ( URLLC) Source 5G Mobile Communications Systems for 2020 and beyond (V1.1), The fifth Generation Mobile Communications Promotion Forum (5GMF) White paper (Sep 2017). Source: Recommendation ITU-R M.2083-0 (09/2015) 8
New traffic types from potential new fields Urgent: Fixed Cope and with Mobile enormously communications increasing Traffic traffic in (on Japan going story in 4G networks) Foreseen: Handling of genuine mobile specific traffic. (New type traffic) X 10 within 7 years! X 100 within 14 years? X 1000 in 21 years??? Depending on Cost vs. Value provided Mobile specific traffic (Mobile specific applications) Mobile specific traffic Genuine new Fixed comm. Type Traffic Alike traffic 1910Gbps Replacement of fixed 1910Gbps (wired) communications Existing mobile 2017 traffic Existing mobile Wired traffic communication alike traffic 202x? 2017 Sources: "Status of the mobile communications traffic of Japan (Sep. 2017)," Information and Communications Statistics Database, Ministry of Internal Affairs and Communications of Japan, Nov. 2017. "Aggregation and Provisional Calculation of Internet Traffic in Japan (as of May 2017)," Ministry of Internal Affairs and Communications of Japan, Feb. 2018. Sources: "Status of the mobile communications traffic of Japan (Sep. 2017)," Information and Communications Statistics Database, Ministry of Internal Affairs and Communications of Japan, Nov. 2017. "Aggregation and Provisional Calculation of Internet Traffic in Japan (as of May 2017)," Ministry of Internal Affairs and Communications of Japan, Feb. 2018. 202x 9
A case study Basic exercises on demographics of Japan and Tokyo 10
An exercise to see practical 5G deployment: The ways to cope with demanding communication traffic 1. Improvement of spectral efficiency 1. Improvement of spectral efficiency Applying Applying OFDM OFDM based based efficient efficient radio radio access access technologies technologies as as in in LTE. LTE. 2. Utilization of wider frequency spectrum Development of higher spectrum in EHF or SHF. 3. Higher spatial reuse factor Deployment of smaller cells How many small cells do we need? Dynamics of the traffic? A macro-scopic simple exercises follow: (Note: The following exercises do not intent to provide actual deployment scenarios.) 11
Demographics of Japan Day time populations and areas Day time population density and areas Demographics of Japan of Japan (Day (Day time time population density vs. area vs. area of 1892 of 1892 local local governments in Japan) in Japan) of local governments in Japan of local governments in Japan Source: Population based on place of working or schooling (Daytime population), Population based on place of usual residence (Nighttime population), Rate of daytime population Source: to Nighttime Population population based - Shi, on place Ku, Machi of working and Mura or schooling (2010), (Daytime Statistics population), Bureau of Japan, Population 2010-2015 based (In on Japanese) place of usual residence (Nighttime population), Area of Shi, Ku, Machi and Mura in each Rate Ken, of daytime Geospatial population Information to Nighttime Authority population of Japan, - Shi, Ku, Machi and Mura (2010), Statistics Bureau of Japan, 2010-2015 (In Japanese) Area of Shi, Ku, Machi and Mura in each Ken, Geospatial Information Authority of Japan, 12
Demographics of Japan P psns/cell TP d tp TP Note: The chart does not intent to provide actual deployment scenarios. Source: Population based on place Source: of working Population or schooling based on (Daytime place of population), working or Population schooling (Daytime based on population), place of usual Population residence based (Nighttime on place population), of usual residence (Nighttime population), Rate of daytime population to Nighttime Rate of daytime population population - Shi, Ku, to Machi Nighttime and Mura population (2010), - Shi, Statistics Ku, Machi Bureau and of Mura Japan, (2010), 2010-2015 Statistics (In Bureau Japanese) of Japan, 2010-2015 (In Japanese) Area of Shi, Ku, Machi and Mura Area in each of Shi, Ken, Ku, Geospatial Machi and Information Mura in each Authority Ken, Geospatial of Japan, Information Authority of Japan, 13
Demographics of Tokyo area (Commuters flow in the area) +1,740% 7.1 million commuters/day Sources: Population based on place of working or schooling (Daytime population), Population based on place of usual residence (Nighttime population), Rate of daytime population to Nighttime population - Shi, Ku, Machi and Mura (2010), Statistics Bureau of Japan, 2010-2015 (In Japanese) Area of Shi, Ku, Machi and Mura in each Ken, Geospatial Information Authority of Japan, Report of analysis on the eleventh Metropolis Transportation Census (2010), Ministry of Land, Infrastructure, Transport and Tourism, Mar. 2013 (In Japanese) (URL: http://www.mlit.go.jp/sogoseisaku/transport/sosei_transport_tk_000047.html). 14 Copyright 2017 FUJITSU LIMITED
What to do and how Ultra dense network as an example of enabling technologies 15
Probability of Line of sight in smaller cells Small cell deployment Urban macro/micro cell deployment Rural macro cell deployment Source Further advancements for E-UTRA physical layer aspects, 3GPP TR 36.814 V9.2.0 (2017-03). 16
Ultra High-Density Distributed Smart Antenna Systems TP Virtual cells CBBU Ultra High-Density Distributed Antenna Systems Ref: 5G R&D Activities for High Capacity Technologies with Ultra High-Density Multi-Band and Multi-Access Layered Cells, IEICE RCS2015-250 (Dec. 2015) Field Trial of Ultra High-Density Distributed Antenna Systems for 5G Ref: Fujitsu Launches Field Trial of Ultra High-Density Distributed Antenna Systems for 5G, Press release of Fujitsu, (Nov. 2017) [http://www.fujitsu.com/global/about/resources/news/pressreleases/2017/1107-01.html] 17
5G RAT and LTE Evolution 5G Phase-1 (To be deployed in 2020) New RAT (up to 30GHz) Mainly for embb Massive MTC, Ultra reliable MTC E2E latency reduction Flexible TDD Enhancements for UDN Forward/ Backward compatibility 5G Phase-2 (To be deployed in 2022~2023) Extension of BW using new spectrum above 6GHz (New RAT up to 100GHz, BF/MIMO) Support of full-duplex operation (mmwave) wireless back/fronthaul Tight interworking LTE Evolution embb elaa for 5GHz unlicensed Flexible duplex (FDD) WiGig aggregation MUST Latency reduction, V2X, LTE Evolution continues Technologies for LTE evolution can also be used also for 5G new RAT. So, the above classification may not be strictly followed. Source: R&D activities towards 5G in Fujitsu, Multimedia Promotion Forum, presentation #678, (Oct. 2015) 19
Conclusion a trailer before the coming table talks 20
Conclusion 1. Role of 5G Bridging Digital World and Physical World in secure, stable and efficient manner 2. Phased approach and candidate features Phase 1: May meet a sub set of 5G requirements Forwards compatibility to Phase 2 and beyond Phase 2: Has to meet all ITU-R IMT-2020 requirements Backwards compatibility to Phase 1 3. Enabling technology(ies) Ultra High-Density Distributed Smart Antenna Systems mmwave beamforming Space-division full duplex(sdfd) 21
22