Geo-spatial distribution of cloud cover and influence of cloud induced attenuation and noise temperature on satellite signal propagation over Nigeria

•Geo-spatial distribution of cloud cover and noise temperature on satellite links.•Mapping of correlation coefficients and dependence index of cloud cover.•Earth-space link budgeting for the proposed Nigerian multi-sensors satellite. The study of the influence of cloud cover on satellite propagation...

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Bibliographic Details
Published in:Advances in space research 2017-05, Vol.59 (10), p.2611-2622
Main Author: Ojo, Joseph Sunday
Format: Article
Language:English
Subjects:
Cloud attenuation
Cloud cover
Cloud noise temperature
Geo-spatial
Satellite applications
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Summary:•Geo-spatial distribution of cloud cover and noise temperature on satellite links.•Mapping of correlation coefficients and dependence index of cloud cover.•Earth-space link budgeting for the proposed Nigerian multi-sensors satellite. The study of the influence of cloud cover on satellite propagation links is becoming more demanding due to the requirement of larger bandwidth for different satellite applications. Cloud attenuation is one of the major factors to consider for optimum performance of Ka/V and other higher frequency bands. In this paper, the geo-spatial distribution of cloud coverage over some chosen stations in Nigeria has been considered. The substantial scale spatial dispersion of cloud cover based on synoptic meteorological data and the possible impact on satellite communication links at higher frequency bands was also investigated. The investigation was based on 5years (2008–2012) achieved cloud cover data collected by the Nigerian Meteorological Agency (NIMET) Federal Ministry of Aviation, Oshodi Lagos over four synoptic hours of the day covering day and night. The performances of satellite signals as they traverse through the cloud and cloud noise temperature at different seasons and over different hours of days at Ku/W-bands frequency are also examined. The overall result shows that the additional total atmospheric noise temperature due to the clear air effect and the noise temperature from the cloud reduces the signal-to-noise ratio of the satellite receiver systems, leading to more signal loss and if not adequately taken care of may lead to significant outage. The present results will be useful for Earth-space link budgeting, especially for the proposed multi-sensors communication satellite systems in Nigeria.
ISSN:0273-1177
1879-1948
DOI:10.1016/j.asr.2017.03.006