Policy on Intellectual Property Right (IPR)
1 Introduction
1.1 Relevant ITU-R
references
1.2 Current regulatory
situation for MetSat service (space-to-Earth) and EESS (space-to-Earth) in the
frequency band 460-470 MHz
2 MetSat and EESS Systems
characteristics
2.1 Background Information
on MetSat (space-to-Earth) and EESS (space-to-Earth)
2.2 Technical characteristics
for MetSat (space-to-Earth) and EESS (space-to-Earth) Systems
2.2.1 GSO DCS
Downlink Characteristics
2.2.2 Non-GSO
MetSat (space-to-Earth) Service DCS downlink characteristics
2.2.3 Non-GSO
EESS (space-to-Earth) systems
3 Incumbent system
characteristics
3.1 Fixed service systems
3.1.1 Characteristics
of point-to-point (P-P) and point-to-multipoint (P-MP) fixed systems
3.1.2 Fixed
Service RF Central Station Alarm (CSA) mesh network
systems
3.2 Mobile service systems
3.2.1 Technical
and operational characteristics of conventional and trunked land mobile systems
3.2.2 Parameters
applicable for IMT Advanced & IMT‑2000 mobile systems
3.2.3 Maritime
mobile systems
3.3 Broadcast systems
3.4 Radio Astronomy
4 Static and Dynamic Analysis
Methods
4.1 Methodology to
determine the pfd thresholds
4.2 Methodology to
determine requirement for Dynamic analysis (GSO and non-GSO)
5 Study 1: GSO and non-GSO
assessment
5.1 Methodology to
determine the power flux density mask (GSO and non-GSO) required to protect
incumbent systems
5.2 Summary of pfd masks
(GSO and nonGSO)
5.2.1 Results
summary of dynamic studies (GSO and non-GSO)
5.2.2 Mitigating
factors (GSO and non-GSO)
5.3 Static analysis
summary (GSO and non-GSO)
5.3.1 Power flux
density mask to protect incumbent fixed P-P and P-MP systems (GSO and non-GSO)
5.3.2 Power flux
density mask (GSO and non-GSO) to protect fixed service mesh systems
5.3.3 Power flux
density level (GSO and non-GSO) required to protect MS systems
5.3.4 pfd level
(GSO and non-GSO) required to protect MS IMT mobile station systems
5.3.5 pfd level
(GSO and non-GSO) required to protect maritime mobile service systems
5.3.6 pfd (GSO
and non-GSO) required to protect Broadcast Service systems
5.3.7 pfd (GSO
and non-GSO) to protect Radio Astronomy
5.4 Dynamic analysis (GSO
and non-GSO)
5.4.1 Aggregate
interference from GSO and non-GSO
5.4.2 Dynamic
analysis of pfd (GSO and non-GSO) required to protect fixed service P-P and
P-MP networks
5.4.3 Dynamic
analysis of pfd (GSO and non-GSO) required to fixed service mesh network (RF
CSA)
5.4.4 Dynamic
analysis of pfd (GSO and non-GSO) required to protect mobile service narrowband
base station (MS NB BS)
6 Study 2: GSO and non-GSO
assessments
6.1 Radio Astronomy
6.2 Mobile service (MS)
Static Analysis (GSO and non-GSO)
6.2.1 pfd (GSO
and non-GSO) required to protect incumbent MS narrowband base station (NB BS)
systems
6.2.2 pfd (GSO
and non-GSO) required to protect incumbent mobile service narrowband mobile
station systems
6.2.3 pfd (GSO
and non-GSO) required to protect incumbent mobile service Wide Band (WB) mobile
station systems
6.2.4 Power flux
density (GSO and non-GSO) required to protect incumbent IMT-2000 mobile station
systems and LTE
6.3 Dynamic analysis
(non-GSO case)
6.3.1 Fractional Performance Degradation
(FDP)
6.3.2 Simulations
with non-GSO systems and fixed service
6.3.3 Simulations
with non-GSO systems and mobile service
6.4 Statistical simulation
(GSO case)
6.4.1 The employed methodology for both services (MS and
FS)
6.4.2 Mobile service characteristics
6.4.3 Fixed service characteristics
6.4.4 GSO satellites characteristics
6.4.5 Simulation for terrestrial services
6.4.6 Results for MS
6.4.7 Results for FS
6.4.8 Conclusion (GSO case)
7 Conclusions
8 Definitions and abbreviations