Policy on Intellectual Property Right (IPR)
TABLE OF CONTENTS
1 Introduction
2 Scope
3 Related documents
4 Radiowave propagation in bands
above 6 GHz
4.1 Propagation losses
4.1.1 Path loss
Path loss comparison
4.1.2 Atmospheric
and other losses
4.2 Recent activities on
radiocommunication channel characteristics and modelling
4.2.1 General
4.2.2 Frequency
range 6-30 GHz
Delay spread in ~30 GHz
Measurements of building entry losses at 28 GHz
4.2.3 Frequency
range 30-70 GHz
Channel model in ~60 GHz
Delay spread in ~40 GHz
Delay spread in ~60 GHz
4.2.4 Frequency
range 70-100 GHz
Delay spread in ~70 GHz
Millimetric wave angular spread
4.3 Summary of the results
of the studies
5 Characteristics of IMT in the
bands above 6 GHz
5.1 Outdoor-to-outdoor
coverage and link budget
5.2 Outdoor-to-indoor
coverage
5.3 Mobility
5.4 Impact of bandwidth
6 Enabling technologies toward
IMT in bands above 6 GHz
6.1 Antenna technology
6.1.1 Directional
fixed-beam antenna array
6.1.2 Full
adaptive antenna array
6.1.3 Modular
antenna array overview
6.1.4 Multi-antenna
transmission using modular phased antenna structures
6.2 Semiconductor
technology
6.2.1 Device for
low power consumption
6.2.2 Device for
high gain beamforming
7 Deployment scenarios and
architectures
7.1 Use cases for IMT in
bands above 6 GHz
Dense hotspot in an indoor shopping mall
Dense hotspot in an indoor enterprise environment
Dense hotspot in home and indoor environments
Dense urban hotspot in a square/street
Mobility in the city
7.2 Deployment
architecture
7.3 Deployment scenarios
7.3.1 Hotspot
7.3.2 Indoor
7.3.3 Outdoor
7.4 Flexible deployment of
access and backhaul
7.4.1 Wireless
backhaul for moving hotspot
8 Conclusions
Acronyms and Abbreviations
Annex 1 Semiconductor technology
status
A1.1 Introduction
A1.2 Semiconductor technology
Annex 2 Measurement results in bands
above 6 GHz
A2.1 Test results of
prototype mobile system
A2.2 Coverage test results
A2.3 High mobility test
results
A2.4 Multi-user MIMO test
results
A2.5 Test results in 70 GHz
bands
Annex 3 Simulation results above 6 GHz
A3.1 Simulations at 10 GHz,
30 GHz, and 60 GHz
A3.1.1 Introduction
A3.1.2 Propagation
models used in this study
A3.1.3 Scenario
A3.1.4 Simulation
results
1 Building type A (old building)
2 Building type B (new building)
1.2 30 GHz carrier
frequency
1.3 60 GHz carrier
frequency
2 Building type B
2.1 10 GHz carrier
frequency
2.2 30 GHz carrier
frequency
2.3 60 GHz carrier
frequency
A3.1.5 Conclusions
A3.2 System simulations at
72 GHz – Example 1
A3.3 System simulation
results on 72 GHz – Example 2
A3.3.1 Introduction
A3.3.2 Propagation
models used in this study
A3.3.3 Simulation
scenario and system parameters
A3.3.4 Simulation
results
A3.4 Performance comparison
of millimetric overlay HetNet
A3.4.1 Full-buffer
scenario
A3.4.2 Non-full-buffer
scenario
Annex 4 Details of propagation channel measurements and
modelling
A4.1 Description of a 10
and 18 GHz measurement campaign
A4.2 Outdoor NLoS channel
measurement results
A4.3 Measurements and
quasi-deterministic approach to channel modelling at 60 GHz
A4.3.1 Introduction
A.4.3.2 A novel methodology for experimental measurements in the 60 GHz band
A4.3.3 Novel quasi-deterministic
channel model methodology
1) Polarization for D-rays
2) Polarization for R-rays
A4.3.4 Blockage
modelling
A4.3.5 Mobility
effects
A4.3.6 Street
canyon millimetric wave 3D channel model example
A4.3.7 Multipath
modelling extension to outdoor for Hot Spots
A4.4 Measurement and
modelling of pathloss at 72 GHz
A4.5 Introduction of
MiWaveS project scope and findings
A4.5.1 Prototyping
millimetric use cases
A4.5.2 MiWaveS
summary on the millimetric small cell access points and backhaul system