CONTENTS
Policy on Intellectual Property Right (IPR)
1 Introduction
1.1 Temporal and location variability
1.2 Apparent and free-space elevation angles
1.3 Relevant propagation mechanisms
2 Propagation mechanisms
2.1 Free space basic transmission loss 
(dB)
2.2 Depolarization attenuation 
(dB)
2.2.1 Cross-polar discrimination and cross polar
attenuation
2.2.2 Faraday rotation
2.2.3 Hydrometeor depolarization
2.3 Attenuation due to atmospheric gasses 
(dB)
2.4 Loss due to beam spreading 
(dB)
2.4.1 Ray bending
2.4.2 Beam-spreading attenuation (dB)
2.5 Scintillation
2.5.1 Ionospheric scintillation 
(dB)
2.5.2 Tropospheric scintillation 
(dB)
2.6 Diffraction/ducting loss due to terrain and/or specific
obstruction 
(dB)
2.7 Clutter loss 
(dB)
2.8 Building entry/exit loss 
(dB)
2.9 Precipitation-scatter transmission loss 
(dB)
2.10 Differential rain attenuation
3 Evaluation of interference
3.1 Basic transmission loss for single-entry interference
3.2 Clear-air basic transmission loss for multiple-entry
interference
4 Correlation between propagation losses
5 Multiple-entry interference analysis methods
5.1 Monte Carlo simulation
5.2 Analytical techniques
C.1 Introduction
C.2 Attenuation due to atmospheric gaseous on an Earth-space path
Step-by-step method
C.3 Descending ray when traced from Earth-based station
START OF LOOP FOR SUCCESSIVE ATMOSPHERIC LAYERS
END OF LOOP
C.4 Ascending ray when traced from Earth-based station
START OF LOOP FOR SUCCESSIVE ATMOSPHERIC LAYERS
END OF LOOP
C.5 Atmospheric parameters
C.6 Reference atmosphere
D.1 Introduction
D.2 Scintillation intensity
D.3 Tropospheric scintillation short-term variability
E.1
START OF LOOP
END OF LOOP
F.1