A. Gregorio
University of Trieste
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Publication
Featured researches published by A. Gregorio.
Journal of Instrumentation | 2009
L. Valenziano; F. Cuttaia; A. De Rosa; L. Terenzi; A Brighenti; G P Cazzola; A Garbesi; S Mariotti; G Orsi; L. Pagan; F. Cavaliere; M. Biggi; R. Lapini; E Panagin; Paola Battaglia; R. C. Butler; M. Bersanelli; O. D'Arcangelo; S Levin; Nazzareno Mandolesi; A. Mennella; G. Morgante; G. Morigi; M. Sandri; A. Simonetto; M. Tomasi; F. Villa; M. Frailis; S. Galeotta; A. Gregorio
The LFI radiometers use a pseudo-correlation design where the signal from the sky is continuously compared with a stable reference signal, provided by a cryogenic reference load system. The reference unit is composed by small pyramidal horns, one for each radiometer, 22 in total, facing small absorbing targets, made of a commercial resin ECCOSORB CRTM, cooled to ~ 4.5 K. Horns and targets are separated by a small gap to allow thermal decoupling. Target and horn design is optimized for each of the LFI bands, centered at 70, 44 and 30 GHz. Pyramidal horns are either machined inside the radiometer 20K module or connected via external electro-formed bended waveguides. The requirement of high stability of the reference signal imposed a careful design for the radiometric and thermal properties of the loads. Materials used for the manufacturing have been characterized for thermal, RF and mechanical properties. We describe in this paper the design and the performance of the reference system.
Journal of Instrumentation | 2009
A. Mennella; F. Villa; L. Terenzi; F. Cuttaia; P. Battaglia; M. Bersanelli; R. C. Butler; O. D'Arcangelo; E. Artal; R. J. Davis; M. Frailis; C. Franceschet; S. Galeotta; A. Gregorio; N. Hughes; P. Jukkala; D. Kettle; V. H. Kilpiä; M. Laaninen; P. M. Lapolla; R. Leonardi; P. Leutenegger; S. R. Lowe; Nazzareno Mandolesi; M. Maris; P. R. Meinhold; L. Mendes; M. Miccolis; G. Morgante; N. Roddis
In this paper we discuss the linearity response of the Planck-LFI receivers, with particular reference to signal compression measured on the 30 and 44 GHz channels. In the article we discuss the various sources of compression and present a model that accurately describes data measured during tests performed with individual radiomeric chains. After discussing test results we present the best parameter set representing the receiver response and discuss the impact of non linearity on in-flight calibration, which is shown to be negligible.
Journal of Instrumentation | 2009
F. Cuttaia; A. Mennella; L. Stringhetti; M. Maris; L. Terenzi; M. Tomasi; F. Villa; M. Bersanelli; R. C. Butler; B Cappellini; L. P. Cuevas; O. D'Arcangelo; R. J. Davis; M. Frailis; C. Franceschet; E. Franceschi; A. Gregorio; R Hoyland; R. Leonardi; S. R. Lowe; Nazzareno Mandolesi; P. R. Meinhold; L. Mendes; N. Roddis; M. Sandri; L. Valenziano; A. Wilkinson; A. Zacchei; A. Zonca; P. Battaglia
This paper describes the Planck Low Frequency Instrument tuning activities performed through the ground test campaigns, from Unit to Satellite Levels. Tuning is key to achieve the best possible instrument performance and tuning parameters strongly depend on thermal and electrical conditions. For this reason tuning has been repeated several times during ground tests and it has been repeated in flight before starting nominal operations. The paper discusses the tuning philosophy, the activities and the obtained results, highlighting developments and changes occurred during test campaigns. The paper concludes with an overview of tuning performed during the satellite cryogenic test campaign (Summer 2008) and of the plans for the just started in-flight calibration.
Journal of Instrumentation | 2009
L. Terenzi; Mj Salmon; A Colin; A. Mennella; G. Morgante; M. Tomasi; P. Battaglia; M Lapolla; M. Bersanelli; Rc Butler; F. Cuttaia; O. D'Arcangelo; R. J. Davis; C. Franceschet; S. Galeotta; A. Gregorio; N. Hughes; P. Jukkala; D. Kettle; M. Laaninen; P. Leutenegger; R. Leonardi; Nazzareno Mandolesi; M. Maris; P. R. Meinhold; M. Miccolis; N. Roddis; L Sambo; M. Sandri; R. Silvestri
This paper describes the impact of the Planck Low Frequency Instrument front end physical temperature fluctuations on the output signal. The origin of thermal instabilities in the instrument are discussed, and an analytical model of their propagation and impact on the receivers signal is described. The experimental test setup dedicated to evaluate these effects during the instrument ground calibration is reported together with data analysis methods. Finally, main results obtained are discussed and compared to the requirements.
arXiv: Instrumentation and Methods for Astrophysics | 2018
F. Cuttaia; L. Terenzi; G. Morgante; M. Sandri; F. Villa; A. De Rosa; E. Franceschi; M. Frailis; S. Galeotta; A. Gregorio; P. Delannoy; S. Foley; B. Gandolfo; A. Neto; C. Watson; F. Pajot; M. Bersanelli; R. C. Butler; N. Mandolesi; A. Mennella; J. Tauber; A. Zacchei
Archive | 2013
S. Colafrancesco; S. Colombi; L. P. L. Colombo; F. Cuttaia; G. de Gasperis; J. Delabrouille; C. Dickinson; H. Dole; S. Donzelli; M. Douspis; G. Efstathiou; F. Finelli; O. Forni; M. Frailis; E. Franceschi; S. Galeotta; Y. Giraud-Héraud; J. González-Nuevo; A. Gregorio; A. Gruppuso; S. Henrot-Versillé; C. Hernández-Monteagudo; D. Herranz; E. Hivon; M. Hobson; T. Jagemann; T. S. Kisner; R. Kneissl; J. Knoche; L. Knox
