Toward a 5G Ecosystem with More Vitality and Long Life Cycle

Toward a 5G Ecosystem with More Vitality and Long Life Cycle Wan Lei Director of HUAWEI Wireless Standard

5G Use Case Scenario, to Full Connected World ITU-R IMT2020 Evaluation 5 Scenarios w. 13 Metrics Peak rate/se Cell avg./edge SE User perceived rate Regional load density User-plane latency Control-plane latency Mobility Mobility HO latency Network/terminal EE Connection density Reliability Smart Access mmtc Smart Home /Building Smart City Urban -mmtc 1million/KM 2 embb Future IMT ITU-R WP5D 10Gbps Indoor Dense urban Rural 3D Video, UHD Screen Work and play in the cloud Augmented reality Industry automation Mission critical applications Self driving car urllc Urban-URLLC AR/VR 1ms Smart Drive HUAWEI TECHNOLOGIES CO., LTD. Page 2

Latency Challenges of Services & Network Requirements Challenges of Service Experience Challenges of Network Requirements 1ms Autonomous car Tactile internet AR [10~20]Gbps 100Mbps~1Gbps cell edge user data rate 10ms Disaster alert Real time gaming v VR Multi-person video call 10Mbps/m 2 [3+]x IMT-A cell average SE 100ms Automotive ecall Bi-directional remote control >1s Sensors Device remote control Office in cloud Mobile video Personal cloud EE 100x IMT-A 500km/h <1Mbps 10Mbps 100Mbps >1Gbps data rate Source: GSMA & Huawei Wireless X Labs 10^6/km 2 Connection 1ms Latency

Global 5G Trial Spectrum Plan China EU 2020 commercial <6GHz, C-Band embb Non-Standalone Japan 2017 28GHz,39GHz WTTX Standalone US Product R&D Trial : 2018 3.4-3.6GHz embb, NB-IOT, Internet of vehicles Standalone 2019 Pre commercial <6GHz, C-Band embb IoT Non-Standalone Korea 2018 Winter Olympic,2020 commercial 28GHz, [C-Band] embb Internet of vehicles Standalone Non-Standalone?

5G Ecosystem Spectrum Global Harmonization Standard Unification Technology Enabler

Higher Frequency: G30/G40 as complementary Coverage hole ratio Coverage Low O2I penetration loss Penetration Loss 11.7dB 5.5dB 12dB High O2I penetration loss 30GHz 40GHz 70GHz 30GHz 40GHz 70GHz Umi 9 % 18 % 65 % 55 % 70% 80 % Uma 15% 24 % 66 % 60 % 70 % 81 % Key assumption: For Group30/40/70, bandwidth is 1/1/2 GHz, BS antenna configuration is (M,N,P) = (8/8/32,16,2), 32ports, MS antenna element number is 32, 80%/20% indoor/outdoor user ratio, 3D indoor user distribution according to TR 36.873. 8dB UMa (O2I, high loss) UMa (O2I, low loss) UMa (O2O) UMi (O2I, high loss) UMi (O2I, low loss) UMi (O2O) InH DL link-budget for 1Gbps 70 GHz 40 GHz 30GHz 16 32 45 67 113 148 313 374 433 5 12 17 26 48 65 145 180 214 59 63 76 0 50 100 150 200 250 300 350 400 450 500 Coverage distance (m) G30/G40 Bands: for hotspot O2O & indoor deployment 30GHz over 3.5GHz: 12dB Extra penetration loss

Sub 6GHz: the core 5G Spectrum Below 6GHz 1 2 3 4 5 6 10 20 30 40 50 60 70 80 GHz C-band: Global Harmonization (GHz) 3.3 3.4 3.5 3.6 3.7 3.8 3.9 4.0 4.1 4.2 4.3 4.4 4.5 4.6 4.7 4.8 4.9 Japan Korea EU Available to MBB Being considered by regulators Potential for MBB USA China

C-Band Deployment Speeded up w. UL/DL Decoupling 70 60 50 40 30 20 10 0 UL is the Coverage Bottleneck UL PUSCH Coverage DL PBCH Coverage DL PDSCH Coverage Bottleneck Low UL traffic load in LTE at Sub3GHz PRB utilization ratio Operator A Operator B Operator C DL PRB Utility Ratio(%) MBB traffic asymmetry: DL : UL traffic = 4~10 : 1 Sub3GHz for UL, C-Band for DL&UL Co-site deployment of C-band with LTE low freq. band UL/DL decoupling to eliminate C-band UL coverage bottleneck. Fast introduction of NR with spectrum sharing instead of refarming to protect LTE investment. 3.5GHz 2.6GHz 2.3GHz 1.9G Hz 1.8GHz (UL) 800/900MHz(UL)

L_SRS L_SRS N_GP N_GP N_SRS N_SRS N_GP N_SRS N_SRS N_GP C-Band/SUL Combination Standardization NR-LTE co-existence has been adopted into R15 NR-WID scope(ran#75) - Support co-existence of LTE UL and NR UL within the bandwidth of an LTE component carrier - specify at least one NR band/lte-nr band combination for this operation F TDD/SDL Band NR LTE DL NR Dynamic UL sharing LTE NR LTE PUCCH LTE SRS NR Guard Period NR SRS F TDD/SDL Band Static/semi-static UL sharing NR NR LTE DL FDD L_U L_U L_U LTE/ NR Shared UL N_U N_U LTE UL 1ms N_U N_U L_U N_U L_U T FDD LTE/ NR Shared UL NR UL LTE UL NR UL T Proposed frequency ranges for NR/LTE Co-existence 1710-1785MHz (UL)/3.3-4.2 GHz*(DL&UL) 832-862MHz (UL)/3.3-4.2 GHz*(DL&UL) 880-915MHz (UL)/3.3-4.2 GHz*(DL&UL) 703-748MHz (UL)/3.3-4.2 GHz* (DL&UL) Operators CTC, CUC, CMCC, DT (1800MHz) Orange, Telefonica, DT, ET (800MHz) CMCC (900MHz) Orange, Telefonica, ET (700MHz)

3GPP 5G Standard Roadmap 2015 2016 2017 2018 2019 2020 WRC-15 ITU Workshop 5G Evaluation WRC-19 Criterion Evaluation Requirement 5G Proposal Spec Rel-13 Rel-14 Rel-15 Rel-16 Rel-17 5G New Radio SI 5G evaluation SI NR WI NR WIs for R16 NR WIs for R17 Standalone NR Non-standalone NR SA2 WI: 5G New Core phase-i SA2 WIs: 5G New Core phase-2 LTE-Advanced Pro LTE Further Evolution 2015 R13~14 2018 R15 ~

3GPP Rel-15 5G Deployment Options Opt.3 Non-standalone LTE-Assisted with EPC EPC Non-Standalone Standalone Opt.2 Standalone NR with NGCN NextGen Core LTE NR NR LTE-NC (NSA) Opt.7 Non-standalone, LTE-Assisted with NGCN NextGen Core LTE-NC (SA) Opt.5 Standalone LTE Rel-15 with NGCN NextGen Core elte NR elte Phase1.1(2017.12) Phase1.2 (2018.6)

5G RAN Key Enabling Technologies Framework Higher Spectral Efficiency UAI (Unified Air Interface) UCNC (User Centric No Cell) RAT Agnostic Technologies Focus Multi-antenna UL/DL traffic asymmetric Light overhead Mix-Numerology Narrow band & wide band Low Latency UDN & Hetnet Simplify Mobility Further embb enh. MMTC URLLC CCH BF & M-MIMO Self-contained sub- Hyper Cell Massive MIMO Flexible duplex frame CloudRAN NB-IoT Enablers F-OFDM F-OFDM / Polar code CloudAir Grant Free 5G is much more than Massive MIMO

5G Core Network Evolution Roadmap Distributed Deployment SOC (Service Oriented Core) DC Cloudified Architecture Database USN UGW MSE Load Balance DC DC User Plane Edge DC Control Plane Center DC User Plane Edge DC CUPS Based On demand deployment MEC, mcdn, Smart Campus, Smart Stadium Service Based Architecture On demand slicing Access Agnostic AR/VR, V2X, undirected connection, Industry internet..

5G Trial in China

5G Technology R&D Trial Launched in China 2015 2016 2017 2018 2019 2020 Step 1: Key tech trial Phase 1: Technology R&D Trial Step 2: Tech scheme trial Step 3: System trial Phase 2: Product R&D Trial Verify 5G key technologies Promote 5G technologies R&D Promote standard consensus on 5G key technologies Single BS performance test to verify the 5G key features Multi-cell network verification 5G typical service demo

Step-2 of 5G Technology R&D Trial Six leading vendors participation Huairou, Beijing Requirements Common Test/Trial Sites Common Test Requirement Common trial equipment specification and trial platform Common trial test specifications and test cases Open test interface Common Test Frequency Low Frequency:3.4-3.6GHz (might expand) High Frequency:Encourage the system vendor to conduct the high frequency test, in the absence of allocation of specific trial high frequency band, the trial can be conducted at indoor lab.

Test Scenarios and Baseline in Step-2 7 scenarios ITU scenarios Hotspot with High capacity Hybrid Scenarios Higher bands and lower bands Other Scenarios Wide Area Coverage Low Power Consumption Massive Connections Ultra-reliable Low latency Lower Frequency Higher Frequency Baseline for passing the test Test completion in scenarios with wide area coverage and IoT. Support to interconnect and interwork with at least one chip manufacturer and one instrument manufacturers.

Huawei Trial in Huairou Wide Area Coverage Cell peak data rate > 11.7Gbps Single user data rate > 1.6Gbps Massive Connections 4 million/mhz/cell 64 Channels 200MHz BW 12 UEs Ultra-reliable Low latency User plane air-interface delay < 1ms Hybrid Scenarios Cell peak data rate>8.29gbs; delay<1ms, 4million connections

Thank you!