Your search keyword '"Mauro Focardi"' showing total 2 results

1. The design of the instrument control unit and its role within the data processing system of the ESA PLATO Mission

Author

D. Biondi, Stefano Pezzuto, M. Steller, A. M. di Giorgio, H. Jeszenszky, Isabella Pagano, Vladimiro Noce, S. Natalucci, K. Westerdorff, Rainer Berlin, G. Peter, L. Serafini, P. Plasson, Harald Ottacher, Roland Ottensamer, Manuel Guedel, E. Tommasi, C. Del Vecchio Blanco, Rosario Cosentino, Mauro Focardi, G. Laky, Maurizio Pancrazzi, Emanuele Pace, D. Vangelista, G. Giusi, Franz Kerschbaum, and B. Ulmer

Subjects

Physics, Cosmic Vision, Astrophysics::Instrumentation and Methods for Astrophysics, Astronomy, Astrophysics::Cosmology and Extragalactic Astrophysics, Asteroseismology, Exoplanet, Stars, Planet, Astrophysics::Solar and Stellar Astrophysics, Terrestrial planet, Astrophysics::Earth and Planetary Astrophysics, Transit (astronomy), Circumstellar habitable zone, Astrophysics::Galaxy Astrophysics

Abstract

PLATO1 is an M-class mission of the European Space Agency's Cosmic Vision program, whose launch is foreseen by 2026. PLAnetary Transits and Oscillations of stars aims to characterize exoplanets and exoplanetary systems by detecting planetary transits and conducting asteroseismology of their parent stars. PLATO is the next generation planetary transit space experiment, as it will fly after CoRoT, Kepler, TESS and CHEOPS; its objective is to characterize exoplanets and their host stars in the solar neighbors. While it is built on the heritage from previous missions, the major breakthrough to be achieved by PLATO will come from its strong focus on bright targets, typically with mvv

Published

2018

2. Thermal architecture of the ESA ARIEL payload

Author

D. D'Ascanio, Giovanna Tinetti, Gianluca Morgante, Martin Crook, T. Hunt, Giuseppina Micela, Paul Eccleston, Giuseppe Malaguti, Emanuele Pace, Luca Terenzi, Mauro Focardi, and V. Da Deppo

Subjects

Cryogenics, Cosmic Vision, Temperature control, Computer science, business.industry, Payload, Passive cooling, Exoplanets, Context (language use), 01 natural sciences, Thermal control, law.invention, 010309 optics, Telescope, Space instrumentation, Operating temperature, law, 0103 physical sciences, Active cooling, Astrophysics::Earth and Planetary Astrophysics, Aerospace engineering, Infrared, business, 010303 astronomy & astrophysics, Spectroscopy

Abstract

The Atmospheric Remote-sensing Infrared Exoplanets Large-survey (ARIEL) is a space project selected by the European Space Agency for the Phase A study in the context of the M4 mission within the Cosmic Vision 2015-2025 programme. ARIEL will probe the chemical and physical properties of a large number of known exoplanets by observing spectroscopically their atmosphere, to extend our knowledge of how planetary systems form and evolve. To achieve its scientific objectives, the mission is designed as a dedicated 3.5-years survey for transit and eclipse spectroscopy, with an instrumental layout based on a 1-m class telescope feeding two spectrometer channels that cover the band 1.95 to 7.8 μm and four photometric channels in the visible to near-IR range. The high sensitivity requirements of the mission need an extremely stable thermo-mechanical platform. In this paper we describe the thermal architecture of the payload and discuss the main requirements that drive the design. The ARIEL thermal configuration is based on a passive and active cooling approach. Passive cooling is achieved by a V-Groove based design that exploits the L2 orbit favorable thermal conditions. The telescope and the optical bench are passively cooled to a temperature close to 50K to achieve the required sensitivity and stability. The photometric detectors are maintained at the operating temperature of 50K by a dedicated radiator coupled to cold space. The IR spectroscopic channel detectors require a lower temperature reference. This colder stage is provided by an active cooling system based on a Neon Joule-Thomson cold end, fed by a mechanical compressor, able to reach temperatures lower than 30K. Thermal stability of the telescope and detector units is one of the main drivers of the design. The periodical perturbations due to orbital changes, to the active cooling or to other internal instabilities make the temperature control one of the most critical issues of the whole architecture. The thermal control system design, based on a combination of passive and active solutions aimed at maintaining the required stability at the telescope and detector stages level, is described. We report here about the baseline thermal architecture at the end of the Phase A, together with the main trade-offs needed to enable the ARIEL exciting science in a technically feasible payload design. Thermal modeling results and preliminary performance predictions in terms of steady state and transient behavior are also discussed.

Published

2018