Geostationary tether satellite system and its application tocommunication systems

The geostationary tether satellite system expands the geostationary orbit resource from a one-dimensional arc into a two-dimensional disk. The tethered satellites, each several thousand kilometers apart and aligned along the local vertical, are stabilized at the altitude of the geosynchronous orbital speed. When this system is applied to communications systems, it is estimated that the number of satellites can be increased as much as thirteenfold and the communication capacity can be increased more than seventeenfold, compared with a conventional geostationary satellite orbit system     

Interference experiments between fixed-satellite and terrestrialradio-relay services

To resolve interference problems between fixed-satellite and terrestrial radio relay services and expand coordination areas between the two services, theoretical and experimental studies were carried out. Theoretical D/U values calculation formulas between the two systems were derived, interference data from 4 GHz and 11 GHz band terrestrial radio-relay systems were obtained by a measuring system mounted on a vehicle. By comparing those results, it becomes clear that the ensemble interference reduction factors for 4 GHz and 11 GHz bands are around 20 dB, which is mixed values of attenuation and reflection from big buildings in urban areas     

Optical fiber geostationary tether satellite (F-GTS) system design

The geostationary satellite orbit (GSO) is a limited natural resource and its efficient utilization is very important. The geostationary tether satellite (GTS) system has a number of satellites aligned along the local vertical on either side of the nominal geostationary position. The system is synchronized with the Earth's rotation and all the various altitudes are geostationary, Furthermore, optical-fiber geostationary tether satellite (F-GTS) system has been introduced to improve the GTS system, with regard to increment of communication capacity, simplification of interference paths and intersatellite link (ISL) capability. The F-GTS system design is discussed with the purpose of achieving a realistic satellite network. Three frequency bands, i.e., the 14/11, 30/20, and 50/40 GHz bands, are examined for selection of the optimum frequency band. The F-GTS system example for covering the service areas in Japan is discussed with regard to satellite antenna diameter, communication capacities, etc. To apply the F-GTS system to the whole GSO, the diagonal azimuth orbit arrangement method is proposed for low latitude service areas. Moreover, the F-GTS communication capacity and total communication capacity, when the F-GTS systems are applied to the whole GSO, are also examined.     

Genetic algorithm application to efficient utilization of the GSO

Utilization of the geostationary satellite orbit (GSO) has reached full capacity in orbital arcs at certain longitudes. A variety of proposals and regulations have already been established to increase the number of possible satellite positions. The optimum satellite arrangement carried out by considering the geographical distribution of service areas is an effective strategy for efficient utilization of the GSO. The genetic algorithm (GA) method is applied here to optimize the satellite arrangement. Initially, an example of the optimum arrangement of eight satellites is demonstrated by using the GA method to ensure accuracy of the newly developed program. Subsequently, a multiple beam satellite system concept is introduced to further improve the efficient utilization of the GSO. Finally, 80 satellites (40 service areas) in the ITU Region 1 example is solved using the GA method, resulting in a quasi-optimum satellite arrangement solution. By using the GA method, the quasi-optimum solution can be obtained by very short (e.g., several ten seconds) calculation times.