Browsing by Autor "Marcelo Vilela"

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    On the Use of the Integrated Global Radiosonde Archive in Satellite Propagation Studies in Bolivia
    (2018) Marcelo Vilela; Gustavo A. Siles
    As the use of high frequency bands, is becoming more and more attractive for using on future commercial and military satellite communications, the effects of atmospheric water vapor and oxygen are more relevant. In order to reduce gaseous absorption effects, high altitude sites can be good candidates for deploying high capacity ground stations at these frequencies. This paper explores the use of radiosoundings carried out in La Paz, Bolivia, at 4061 m.a.s.l., extracted from the Integrated Global Radiosonde Archive (IGRA), in order to estimate gaseous attenuation based on the last version of the ITU-R Recommendation P.676. Time series of gaseous attenuation at Ka, Q, V and W band are presented.
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    Propagation study at 4065 meters of altitude: Attenuation due to gases at Ka, Q, V and W bands using radiosonde observations
    (2019) Gustavo A. Siles; Miguel Heredia; Marcelo Vilela
    As frequency increases, gaseous attenuation in Earth-Space links becomes more relevant. High altitude sites can be an interesting option for future potential deployment of ground stations for satellites with broadband communication links under low gaseous attenuation conditions. The present paper is part of a study aimed to characterize the propagation conditions at high altitude sites, as a collaboration between Universidad Privada Boliviana and Agencia Boliviana Espacial, which operates a Satellite Ground Control Station located above 4000-m of altitude. A 2-year database of radiosonde observations carried out once a day at La Paz/El Alto Airport, located 13 km away from the station, at 4065-m of altitude and a height difference of 50 m, is exploited with the aim of estimating gaseous attenuation at Ka, Q, V and W bands. The calculations have been performed using the line-by-line method of the ITU-R P.676 Recommendation and compared to approximate methods. Results show a higher impact of attenuation caused by oxygen at 40, 50 and 75 GHz in relation to water vapor effects and prediction errors of approximate methods between 5% and 10% under these particular geographical conditions.