Integrated thermal-optical simulations of a GNSS Retroreflector Array

•We designed a full size array of retroreflectors for radionavigation satellites.•We integrated commercial software to simulate orbital performance.•The retroreflectors’ housing configuration minimizes internal thermal gradients.•Intensity variation throughout the orbit is contained compared to desi...

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Bibliographic Details
Published in:Advances in space research 2015-07, Vol.56 (1), p.85-91
Main Authors: Boni, A., Cantone, C., Dell’Agnello, S., Ciocci, E., Contessa, S., Delle Monache, G.O., Lops, C., Maiello, M., Martini, M., Mondaini, C., Patrizi, G., Porcelli, L., Salvatori, L., Tibuzzi, M., Tuscano, P., Vittori, R., Bianco, G.
Format: Article
Language:English
Subjects:
Arrays
Circularity
Earth observations (from space)
Galileo
GNSS
Laser polarization
Laser retroreflectors
Optical simulation
Orbits
Payloads
Retroreflectors
Satellite Laser Ranging
Satellite tracking
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Summary:•We designed a full size array of retroreflectors for radionavigation satellites.•We integrated commercial software to simulate orbital performance.•The retroreflectors’ housing configuration minimizes internal thermal gradients.•Intensity variation throughout the orbit is contained compared to design conditions.•Circular polarization of the laser reduces intensity rms over velocity aberration. Satellite Laser Ranging (SLR) is one of the most precise and cost effective satellite positioning techniques, used for many years on geodetic, Earth observation and scientific satellites. In the last decades it has been applied on radio-navigation satellites as well, however still in a limited way. The benefits that such technique could bring to these satellites are many, but, in order to support at best their tracking, some improvements need to be done; one is the enhancement of optical response of SLR payloads throughout the orbit. INFN-LNF with the ASI-INFN project ETRUSCO-2 studied hardware and software solution to optimize the optical response of such payloads, with the design and fabrication of a GNSS Retroreflector Array (GRA). We simulated the performance of a model of the GRA in a specific orbit of Galileo, showing contained variation of optical intensity, approximately 5%, throughout the orbit. A comparison between two polarization states, linear and circular, proves how a circularly polarized beam could reduce, up to 3 times, intensity fluctuations at a fixed velocity aberration.
ISSN:0273-1177
1879-1948
DOI:10.1016/j.asr.2015.03.035