University Links: Home Page | Site Map
Covenant University Repository

Total atmospheric absorption of fixed satellite communication signal due to oxygen and water vapor in Nigeria

Omotosho, T. V. and Akinyemi, M. L. and Mandeep, J. S and Abdullah, M. (2014) Total atmospheric absorption of fixed satellite communication signal due to oxygen and water vapor in Nigeria. IEEE Antennas and Propagation Magazine, 56 (2). pp. 108-121.

[img] PDF
Download (84kB)

Abstract

Total atmospheric absorption values due to oxygen and water vapor on terrestrial and Earth-space paths at frequencies between 1 GHz and 50 GHz were evaluated for 1% unavailability of an average year at two elevation angles of 5° and 55°, which are typical for terrestrial and Earth-space links, respectively. Practical links to the Nigerian communication satellite (NigComsat1) uplink/downlink in the Ku (12/14 GHz), Ka (20/30 GHz), and V (40/50 GHz) bands for 1% unavailability of an average year were also investigated. The basic input climatic data used included monthly and yearly mean meteorological parameters for each station, such as surface and vertical profiles of pressure, temperature, and relative humidity, obtained from the Atmospheric Infrared Sounder (AIRS) instrument on NASA's Aqua spacecraft for seven years (2002 to 2009). The International Telecommunication Union Radio Propagation Recommendation (2009) procedure was used for the computation of gaseous attenuation for each of the 37 stations in Nigeria. The results obtained at various elevation angles (of 44° to 55°) for Earth-space links to NigComsat-1 showed that in the absence of rain, 99% availability was possible at Ku, Ka, and V bands for uplink and downlink at all of the 37 stations in Nigeria, as the gaseous attenuation values obtained were between 0.05 dB to 4.81 dB. For low elevation angles of 5°(terrestrial link) at V band, 99% availability was not practical, as atmospheric loss was between 15.30 dB to 17.62 dB in Nigeria. The results consistently showed that gaseous attenuation was very high at six stations across Nigeria; Calabar (South-South regions), followed, in descending order, by the Ikeja (South-West), Abakaliki (South-East), Abuja (Middle-Belt), Dutse (North-East), and Kastina (North-West) regions. The present results of gaseous attenuation will be very useful for satellite communication-system design engineers across the six regions in Nigeria.

Item Type: Article
Subjects: Q Science > Q Science (General)
Q Science > QC Physics
Divisions: Faculty of Engineering, Science and Mathematics > School of Physics
Depositing User: Mrs Patricia Nwokealisi
Date Deposited: 28 Mar 2018 10:48
Last Modified: 28 Mar 2018 10:48
URI: http://eprints.covenantuniversity.edu.ng/id/eprint/10529

Actions (login required)

View Item View Item