CONTENTS - Report ITU-R M.2541-0 (05/2024) -

Report ITU-R M.2541-0
Policy on Intellectual Property Right (IPR)
�1�� Introduction
�2�� Scope
�3�� ITU Related documents
�4�� Radio wave propagation in bands above 100 GHz
�� 4.1�� Radio channel characteristics
�� 4.1.1�� Basic transmission loss (path loss)
�� 4.1.2�� Atmospheric loss
�� 4.1.3�� Blocking loss and other losses
�� 4.1.4�� Channel sparsity
�� 4.1.5�� Channel non-stationarity
�� 4.1.6�� Near-field effect
�� 4.1.7�� Scattering characteristic
�� 4.2�� Activities on radiocommunication channel characteristics and modelling
�� 4.2.1�� Frequency around 100 GHz
�� 4.2.2�� Frequency range 140-160 GHz
�� 4.2.3�� Frequency range 220-240 GHz
�� 4.2.4�� Frequency around 300 GHz
�5�� Characteristics of IMT in bands above 100 GHz
�� 5.1�� Outdoor-to-outdoor coverage
�� 5.2�� Outdoor-to-indoor coverage
�� 5.3�� Indoor-to-indoor coverage
�� 5.4�� Mobility
�� 5.5�� Impact of bandwidth
�6�� Enabling technologies toward IMT in bands above 100 GHz
�� 6.1�� Antenna technology
�� 6.1.1�� Photo-conductive lens antenna
�� 6.1.2�� Reflect-array and transmit-array
�� 6.1.3�� Metasurfaces
�� 6.1.4�� Nano-photodetectors
�� 6.1.5�� Antenna-on-chip and antenna-in-package
�� 6.1.6�� Miniaturized antenna
�� 6.1.7�� Feeder line technologies for active antenna system
�� 6.2�� Semiconductor technology
�� 6.3�� Material technology
�� 6.4�� MIMO and beamforming
�� 6.4.1�� Directional antennas and pencil beamforming
�� 6.4.2�� Distributed arrays
�� 6.4.3�� Beam-tracking
�� 6.4.4�� Ultra-massive MIMO
�� 6.4.5�� RIS-aided beamforming
�� 6.4.6�� Large intelligent surfaces and beam focusing
�� 6.4.7�� Wavefront engineering
�� 6.4.8�� Localization with RIS-assisted beamforming
�7�� Deployment scenarios and architectures
�� 7.1�� Use cases for IMT in bands above 100 GHz
�� 7.2�� Deployment scenarios
�� 7.2.1�� Hot spot deployments
�� 7.2.2�� Industrial networks
�� 7.2.3�� Autonomous vehicles and smart railway networks
�� 7.2.4�� Indoor D2D
�� 7.3�� Deployment architecture
�� 7.3.1�� Overlay network architecture
�� 7.3.2�� Wireless backhaul
�8�� Conclusions
References
Acronyms and abbreviations
Annex 1�� Summary worldwide measurement campaigns
�� A1.1�� Measurement campaigns
�� A1.2�� References
Annex 2� Channel characterization study on frequency band� 140 GHz, 220 GHz and 300 GHz
�� A2.1�� Introduction
�� A2.2�� Channel measurement campaign
�� A2.2.1�� Channel sounder configuration
�� A2.2.2�� Environment and measurement deployment
�� A2.3�� Measurement results
�� A2.3.1�� Pathloss model for indoor LOS scenarios at 140GHz and 220GHz
�� A2.3.2�� Propagation analysis for indoor NLoS scenarios at 220 GHz
�� A2.3.3�� Path loss model for an outdoor urban scenario at 220 GHz
�� A2.3.4�� Propagation analysis at 300 GHz
�� A2.3.5�� Channel characterization at 300 GHz in indoor hallway and indoor corridor
�� A2.4�� Conclusion
�� A2.5�� References
Annex 3� Channel characteristics on frequency band 100 GHz and 220 GHz� to 330 GHz in indoor scenario and 132 GHz in urban microcellular scenario
�� A3.1�� Introduction
�� A3.2�� Channel measurement campaign
�� A3.2.1�� Channel sounder configuration
�� A3.2.2�� Environment and measurement deployment
�� A3.3�� Measurement results
�� A3.3.1�� Pathloss model
�� A3.3.2�� Root-mean-square delay spread
�� A3.3.3�� Azimuth angle spread of arrival and other parameters for indoor office scenario at 100 GHz
�� A3.4�� Conclusion
�� A3.5�� References
Annex 4� Channel measurement results for both LoS and NLoS (non-LoS) links in outdoor urban environments
�� A4.1�� Introduction
�� A4.2�� Measurement equipment and site
�� A4.2.1�� Testbed description
�� A4.2.2�� Site description
�� A4.3�� Measurement results
�� A4.3.1�� Measurement parameters
�� A4.3.2�� LoS measurements
�� A4.3.3�� NLoS measurements
�� A4.4�� Conclusion
�� A4.5�� References
Annex 5� Basic transmission loss study on frequency band from 2 GHz to� 300 GHz bands in urban microcell scenario
�� A5.1�� Introduction
�� A5.2�� Measurement campaign
�� A5.2.1�� Measurement system setup
�� A5.2.2�� Environment and measurement deployment
�� A5.3�� Measurement Results
�� A5.4�� Summary
�� A5.5�� References
Annex 6� Channel measurement campaign performed in an urban micro� and in an indoor scenario at 158 GHz and 300 GHz
�� A6.1�� Introduction
�� A6.2�� Channel sounder
�� A6.3�� Measurement scenario
�� A6.4�� Discussion of first results
�� A6.5�� References
Annex 7� Study on the dependence of rain attenuation on the rain drop dimension
Annex 8� 159 GHz measurements and characteristics in an urban street-canyon and indoor office environments
�� A8.1�� Introduction
�� A8.2�� Measurement campaign
�� A8.2.1�� Measurement equipment
�� A8.2.2�� Measurement scenarios
�� A8.3�� Analysis results
�� A8.3.1�� Outdoor urban street-canyon environment
�� A8.3.2�� Indoor office environment
�� A8.4�� Summary
�� A8.5�� References
Annex 9� Study on the effect of reflected waves at 160 GHz and 300 GHz in an indoor corridor
�� A9.1�� Introduction
�� A9.2�� Measurement campaign
�� A9.2.1�� Measurement system configuration
�� A9.2.2�� Environment and measurement deployment
�� A9.3�� Measurement results
�� A9.4�� Summary
�� A9.5�� References
Annex 10� Study on the angle of arrival at 160 GHz and 300 GHz in an indoor conference room
�� A10.1�� Introduction
�� A10.2�� Measurement campaign
�� A10.2.1�� Measurement system configuration
�� A10.2.2�� Environment and measurement deployment
�� A10.3�� Measurement results
�� A10.4�� Summary
�� A10.5�� References
Annex 11� Sub-THz propagation measurement campaign at 142 GHz� in an outdoor urban environment
�� A11.1�� Introduction
�� A11.2�� Measurement equipment and locations
�� A11.2.1�� Channel sounder description
�� A11.2.2�� Measurement locations and procedures
�� A11.3�� Measurement results
�� A11.3.1�� Path loss model
�� A11.3.2�� Spatial and angular spreads
�� A11.4�� Conclusion
�� A11.5�� References
Annex 12� Field test of communication prototype in the 220 GHz band
�� A12.1�� Test case A: Test field at short-distance (< 100 m)
�� A12.2�� Test case B: Test field at mid-distance (~500 m)
�� A12.3�� Test case C: Test field at long-distance (~km)
�� A12.4�� Conclusion
�� A12.5�� References
Annex 13� Pathloss study on frequency band 140 GHz in an indoor data centre
�� A13.1�� Introduction
�� A13.2�� Channel measurement campaign
�� A13.2.1�� Channel sounder
�� A13.2.2�� Environment and measurement deployment
�� A13.3�� Pathloss model
�� A13.4�� Conclusion
�� A13.5�� References
Annex 14� Terahertz channel measurement and characterization on a desktop from 75 to 400 GHz
�� A14.1�� Introduction
�� A14.2�� Channel measurement campaigns
�� A14.2.1�� Configuration of measurement campaigns
�� A14.2.2�� System calibration
�� A14.2.3�� System parameters
�� A14.3�� THz channel characterization and analysis
�� A14.3.1�� Power delay profile
�� A14.3.2�� RMS delay spread
�� A14.3.3�� Rician K-factor
�� A14.4�� References
Annex 15� A case study for sub-THz channel modelling
�� A15.1�� Introduction
�� A15.2�� Sub-THz channel modelling requirements
�� A15.3�� The modelling scenario
�� A15.3.1�� Motivation
�� A15.3.2�� Objectives
�� A15.4�� The need for theoretical/stochastic channel modelling
�� A15.5�� Conclusion
�� A15.6�� References
Annex 16� Channel measurement campaign for the indoor hotspot office channels at 142 GHz
�� A16.1�� Introduction
�� A16.2�� Measurement equipment and locations
�� A16.2.1�� Channel sounder description
�� A16.2.2�� Measurement locations and procedures
�� A16.3�� Measurement results
�� A16.3.1�� Path loss model
�� A16.3.2�� Spatial and angular spreads
�� A16.4�� Conclusion
�� A16.5�� References
Annex 17� Measurements of building penetration loss at 2, 26, 97 and 158 GHz
�� A17.1�� Introduction
�� A17.2�� Measurement
�� A17.2.1�� Measurement system setup
�� A17.2.2�� Measurement deployment
�� A17.3�� Measurement results
�� A17.4�� Summary
�� A17.5�� References
Annex 18� Study on the angle of arrival at 300 GHz in an indoor office
�� A18.1�� Introduction
�� A18.2�� Measurement campaign
�� A18.2.1�� Measurement system configuration
�� A18.2.2�� Environment and Measurement Deployment
�� A18.3�� Measurement results
�� A18.4�� Summary
�� A18.5�� References
Annex 19� Study on properties of path loss and cross-polarization characteristics at 300 GHz in indoor environment
�� A19.1�� Introduction
�� A19.2�� Measurement campaign
�� A19.2.1�� Measurement system configuration
�� A19.2.2�� Antennas
�� A19.2.3�� Environment and measurement deployment
�� A19.3�� Measurement results
�� A19.3.1�� Path loss and cross-polarization characteristics
�� A19.3.2�� Effects of blockage by the human body
�� A19.3.3�� Delay spread calculation using ray tracing simulation
�� A19.4�� Summary
�� A19.5�� References
Annex 20� Sub-THz wireless channel field measurements: a study at 140 GHz
�� A20.1�� Introduction
�� A20.2�� Channel sounder methodology
�� A20.2.1�� Channel sounder design
�� A20.2.2�� Channel sounder design details
�� A20.2.3�� Channel sounder calibration
�� A20.3�� Experimental results
�� A20.3.1�� Indoor office environment
�� A20.3.2�� Bridgewater, NJ Campus Foliage loss measurements
�� A20.4�� Coverage implications
�� A20.4.1�� Indoor NLoS path loss implications
�� A20.4.2�� Foliage loss implications
�� A20.5�� Conclusion
�� A20.6�� References
Annex 21� Outdoor propagation measurements at 96 GHz
�� A21.1�� Introduction
�� A21.2�� Measurement setup
�� A21.3�� Analysis
�� A21.4�� Results
�� A21.5�� Conclusions
�� A21.6�� Comparing pathloss with stochastic models
Annex 22� Sub-THz propagation measurement campaigns at 143 GHz in two indoor scenarios
�� A22.1�� Introduction
�� A22.2�� Measurement campaign
�� A22.2.1�� Measurement set-up and procedure
�� A22.2.2�� Scenarios and measurement deployment
�� A22.3�� Measurement results
�� A22.3.1�� Measurement results for the open area with adjacent conference rooms
�� A22.3.2�� Measurement results for the open office scenario
�� A22.4�� Summary
�� A22.5�� References