Propagation modelling for advanced future radio systems - Challenges for a congested radio spectrum
Foreword
Foreword
Editor-in-Chief's message
EDITORIAL BOARD
TABLE OF CONTENTS
LIST OF ABSTRACTS
A POWERFUL SIGNAL NEARBY L1 FREQUENCY BAND JAMMING GNSS STATIONS INOBSERVATOIRE DE PARIS
     1. INTRODUCTION
     2. GNSS STATIONS IN OP
     3. IRRUPTION OF A JAMMING SIGNAL
     4. IMPACT OF THE JAMMING SIGNAL ON LABORATORY ACTIVITIES
     5. GNSS ANTENNA BANDWIdTH
     6. DIFFERENT EFFECTS ON TIME TRANSFER RECEIVERS
     7. MONITORING OF JAMMING SIGNAL
     8. THE WAY FORWARD
     9. CONCLUSION
     ACKNOWLEDGEMENT
     REFERENCES
A QUICK OVERVIEW OF A NEW SCINTILLATION DATABASE
     1. INTRODUCTION
     2. Experimental scenario
     3. Data analysis
     4. Results and analysis
          4.1 Meteorological dependencies
          4.2 Diurnal variation
          4.3 Distribution of fades and enhancements
          4.4 Concurrent standard deviation at the two bands
     5. Scintillation models
     6. CONCLUSION
     ACKNOWLEDGEMENT
     REFERENCES
SUB-THz CHANNEL CHARACTERIZATION FROM RAY-BASED DETERMINISTIC SIMULATIONS
     1. INTRODUCTION
     2. Propagation challenges and modeling in sub-THz band
          2.1 Extension of the EM material properties library up to 200 GHz
          2.2 Management of highly-detailed geographical representation
     3. Scenario and set-up
          3.1 In-office scenario
          3.2 In-street scenario
     4. Simulation results
          4.1 In-office scenario
          4.2 In-street scenario
     5. Conclusion
     ACKNOWLEDGEMENT
     REFERENCES
IRACON PROPAGATION MEASUREMENTS AND CHANNEL MODELS FOR 5G AND BEYOND
     1. INTRODUCTION
     2. Body Area Network Channel Models
     3. MASSIVE MIMO BELOW 6 GHz
     4. VEHICLE TO VEHICLE
          4.1 Corner scenario at mm-waves
          4.2 Urban intersections
     5. BUILDING ENTRY LOSS AND CLUTTER LOSS AT 26 GHz
     6. CHANNEL MODELING FOR THz COMMUNICATION
          6.1 Atmospheric effects for outdoor applications
          6.2 Models for close-proximity communications.
     7. CONCLUSION
     ACKNOWLEDGEMENT
     REFERENCES
DIRECTIONAL ANTENNA CHANNEL MODELING IN URBAN AREA USING RAY TRACING
     1. Introduction
     2. Literature Review
     3. System Model
          3.1 Transmitter and receiver system model
          3.2 Virtual urban scenario
     4. Ray Tracing Simulations for DACM
     5. Directional Antenna Channel modeling
          5.1 Clusters of the incident rays
          5.2 Number of clusters
          5.3 Cluster center
          5.4 Cluster power ratio
     6. Simulation Results
     7. DACM Implementation Steps Using Software Tools
     8. DACM Verification
     9. Conclusion
     REFERENCES
ALPHASAT SITE DIVERSITY EXPERIMENTS IN GREECE AND THE UK AT KA BAND: COMPARISON OF 2-YEARS’ RESULTS
     1. INTRODUCTION
     2. ALPHASAT PRopagation CAMPAIGN in GREECE and the UK
          2.1 Receivers’ details
               2.1.1 Receivers in Greece
               2.1.2 Receivers in the UK
          2.2 Ancillary equipment
          2.3 Data preprocessing
     3. Analysis of ExPERIMENTTAL Results AND DISCUSSION
          3.1 Single site statistics receivers
          3.2 Joint site diversity statistics
     4. CONCLUSION
     ACKNOWLEDGEMENT
     REFERENCES
ANALYTIC MODELS FOR BI-STATIC SCATTERING FROM A RANDOMLY ROUGH SURFACE WITH COMPLEX RELATIVE PERMITTIVITY
     1. INTRODUCTION
     2. Problem Formulation
     3. DIFFUSE BI-STATIC COEFFICIENT BASED ON the SMALL PERTURBATION METHOD (SPM)
     4. DIFFUSE BI-STATIC SCATTERING COEFFICIENT BASED ON the PHYSICAL OPTICS (PO) MODEL
     5. DIFFUSE BI-STATIC SCATTERING COEFFICIENT BASED ON the KIRCHHOFF APPROXIMATION
     6. SUMMARY AND CONCLUSION
     REFERENCES