5g overview

2. 2
Service Vision
Immersive
Experience
Ubiquitous
Connectivity
Everything
onCloud
Telepresence
Giga-bitDataRate
Ultra LowLatency
Giga-bitDataRate
Ultra LowLatency
MassiveConnectivity
UbiquitousCoverage
Giga-bitDataRate
Ultra LowLatency

3. 3
Technical Requirements
ITU-R WP5D, 5D/589-E

4. 4
DisruptiveRANTechnologiesforSignificantPerformanceEnhancements
Key Enabling Technologies
Peak Data Rate
Cell Edge
Data Rate
Cell Spectral
Efficiency
Mobility
Cost Efficiency
Simultaneous
Connection
Latency
Advanced
MIMO&BF
Technology
forAbove6GHz
Cell CapacityEnhancement Peak DataRateIncrease
Half
-Wavelength
Legacy Bands
3 GHz 30 GHz
700 MHz
New Bands
18 27

5. 5
FD-MIMOwithMassiveAntennaTechnologies
2D Array Based Adaptive Beamforming
Higher Order MU-MIMO with 3D Beamforming
FD-MIMO for <6GHz Bands (1/4)
Release 8
Max 4Tx (1V4H)
SU-MIMO
Horizontal beamforming
Release 10
Max 8Tx (1V8H)
MU-MIMO
Horizontal beamforming
FD-MIMO
Max 64Tx (8V8H)
Higher Order MU-MIMO
Horizontal & Vertical beamforming
FD-MIMO
Study Item Release 13
Work Item Release 14
Work Item
’15. 2Q ’16. 1Q ’17. 2Q
’14. 4Q

6. 6
SystemPerformanceofFD-MIMO(SimulationResults)
2~3-Fold Average System Throughput Enhancement
FD-MIMO for <6GHz Bands (2/4)
 2DBeamforming
 Max4MU-MIMO
 3DBeamforming
 Max8MU-MIMO
2-TierWrap-AroundModel
19cell/2-tierwraparound (3sector/cell)
3DUMi,200m ISD
2DAntennaPanelForm-Factor
Antennaspacing:0.8invertical/0.5inhorizontal
Subarray
(e.g., K=2)
32 Port Tx
Subarray
(K=8)
8 Port Tx
Array Configuration:
~275%
(bps/Hz)
5%tile
Spectral
Efficiency
Cell T-put
(TM4,9)
Cell T-put
(FD-MIMO)
5%tile Tput
Cell
average
Spectral
Efficiency
(bps/Hz)
(※ K : Number of antenna elements per port )
Conventional Ant. Array: FD-MIMO Ant. Array:

7. 7
FD-MIMOPoC1.0in2013
Indoor/Outdoor Environment for LTE TDD with 10MHz BW at 2.6GHz
Antenna Configuration : 32Tx/32Rx (4V8H)
FD-MIMO for <6GHz Bands (3/4)
FD-MIMO RF unit
with antenna panel
Front view
Back view
FD-MIMO
Baseband unit
• Compliant with LTE
air interface
• 32 channel
precoding with
sounding
• 4-UE MU-MIMO
• 128 elements
• 32 TX/RX
• TDD, 2.582GHz
• Automatic self
calibration
• Size: 50x100cm
UE emulator#1
IndoorTest
OutdoorTest
2-UEMU-MIMOw/adaptivebeamformingbasedonSRS
Test1:2-UEMU-MIMOw/fixedbeamforming
Test2:2-UEMU-MIMOw/adaptivebeamformingbasedonSRS
Indoor
Test
Outdoor
Test

8. 8
FD-MIMOPoC2.0
High Order (≥8 UEs) MU-MIMO Demonstration by FD-MIMO System at 3.5GHz
FD-MIMO for <6GHz Bands (4/4)
LTE Rel.13Pre-Release
small-cellFD-MIMO
CompacteNBwithfully
integratedarrayantenna,
RF andBB
※30cm(W)x50cm(H)
SupportofAdaptive
3D-Beamforming and
High-orderMU-MIMO
20MHzBW,32-TRXPorts
Novelant.calibrationnetwork
andCompactarrayarchitecture
Front-side
(Radome cover)
Inside
(RF/Antenna Board)

9. 9
World’smmWaveTestbedandHighSpeedMobilityTest
Recent R&D Results for mmWave - Testbed
5 mm
25
mm
42 mm
56
mm

10. Recent R&D Results for mmWave - Components
10
Antenna/RFICforMobileDevice
Polarization Interleaved Array and CMOS RFIC/GaAs FEM at 28 GHz
360° Coverage Antenna and 16 Chain CMOS RFIC at 60GHz
Beamforming CMOS RFIC
EVM -25 dB
16-chain
Beamforming
Tx/Rx EVM
End-Fire Antenna
Dual-Pol. Antenna
60GHz Module with Array Antenna
Area
for Ant.
360
Coverage
Polarization
Loss < 3 dB
CMOS RFIC
Client
Embedded BB Embedded BB
Server
D2D Active Measurement System
Beamforming CMOS RFIC / GaAs FEM
GaAs FEM One-Cable Connection
CMOS RFIC
Horizontal-Pol. Ant.
Vertical-Pol. Ant.
28GHz Array Antenna Module

11. Recent R&D Results for mmWave - ChannelModeling(1/2)
Universities&ResearchCenters
StandardardizationPlan
ResearchProjects
5GChannelModelSIin3GPP(’15.3Q)
NYU,USC,KAIST,CATR,BUPT
mmMAGICin5GPPP,COSTIC1004 Action
LeadingChannelModelingActivitytowardOutdoorCellularDeployment
Gbps Data Rate Support Envisioned by mmWave Propagation Analysis
TX
TX
Measurement at NYU Campus Calibration between Measurement & Simulation
1 2 3 4 5 6 7 8 9 10
0
10
20
30
40
50
60
70
80
90
100
Measurement Index #
Angular
Spread
Angle Spread Comparison @ New York
NYU Measurement
New York Ray-Tracing
50 80 100 150 200
100
110
120
130
140
150
160
170
Distance between transmitter and receiver (m)
Path
Loss
(dB)
Comparison of propagation models : 28GHz
Measurment Samples - NYU Campus
Measurement-based Pathloss Model (NLoS)
Ray-tracing Samples - NYU Campus
Ray-tracing-based Pathloss Model (NLoS)
Ray-tracing Simulation Channel Modeling for Large and Small Scale
pathloss model LoS Prob.
Angle Spread Cal. Pathloss Cal.

12. Recent R&D Results for mmWave - ChannelModeling(2/2)
GbpsDataRateSupportEnvisionedbymmWavePropagationAnalysis
Multi-cell Analysis Shows Gbps-Transmission Feasibility in an Urban Environment
12
28 GHz (7 BS) 60 GHz (10 BS)
System Margin : 146 dB
Bandwidth : 500 MHz
Peak Data Rate : 2.2 Gbps
System Margin : 136 dB
Bandwidth : 2.16 GHz
Peak Data Rate : 10 Gbps
10 Gbps
5 Gbps
2 Gbps
1 Gbps
0.3 Gbps
0.1 Gbps
Outage
Building
Ray-tracing Simulation (Urban Micro Scenario)
Ottawa, Canada 3D Building Model
600m 400m

13. 13
Global5GInitiativeswithSamsung’sActiveEngagements
Global 5G R&D Activities
5G Forum Executive Board Member
Member of Giga KOREA Project
IMT-2020 Promotion Group
Member of Future Forum
Contributor to 863 Project
NYU Wireless Center
(Board Member)
Issued NOI on the use of
above 24 GHz for Mobile
5GMF
(5G Mobile Promotion Forum)
5G PPP Association (Full Member)
Leading and Participating the EU Flagship 5G Projects
5GIC Founding Member

14. 14
StandardizationandSpectrumAllocation
Expected 5G Timelines
2015 2016 2017 2018 2019 2020
< 6GHz SI
> 6GHz SI
RAN 5G
Workshop
‘15. 9
Rel-15
Rel-14 (15mon)
Rel-13
‘17. 6
‘16. 3
WRC-15 WRC-19
Rel-16
‘19.12
Further Enhancements
< 6GHzWI
> 6GHz WI
‘18. 9
IMT-2020
Specification
*Finalized *Finalized
Channel
Model SI
5G Standards 5G Phase I 5G Phase II

15. 15
Samsung’s white paper on 5G technology
is now available for download
on the company’s website.
(http://www.samsung.com/global/business-images/insights/2015/Samsung-5G-Vision-0.pdf)

16. Thank You