Your search keyword '"Davide Loreggia"' showing total 56 results

1. Validation of an automatic system to detect oil spills in X- and L-band SAR images.

Author

Paolo Trivero, Walter Biamino, Marco Cavagnero, Lorenza Di Matteo, and Davide Loreggia

Published

2014

2. CorMag - coronal magnetograph for the stratospheric Hemera mission

Author

Silvano Fineschi, Gerardo Capobianco, Luca Zangrilli, Donata Bonino, Federico Landini, Davide Loreggia, Maurizio Pancrazzi, Roberto Susino, Alessandro Bemporad, Valeria Caracci, Francesco Amadori, and Salvatore Caschera

Published

2022

3. Metrology on-board PROBA-3: The shadow position sensors subsystem

Author

Gerardo Capobianco, Marco Romoli, Jorg Versluys, Massimiliano Belluso, Steven Buckley, Vladimiro Noce, Silvano Fineschi, Aline Hermans, Marta Casti, Damien Galano, Mauro Focardi, Cédric Thizy, Alessandro Bemporad, and Davide Loreggia

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Spacecraft, business.industry, Payload, Computer science, Aerospace Engineering, Astronomy and Astrophysics, 01 natural sciences, Metrology, law.invention, Telescope, Geophysics, Space and Planetary Science, law, 0103 physical sciences, General Earth and Planetary Sciences, Satellite, Aerospace engineering, business, 010303 astronomy & astrophysics, Coronagraph, Position sensor, 0105 earth and related environmental sciences, Eclipse

Abstract

PROBA-3 is an ESA mission aimed at the demonstration of formation flying performance of two satellites that will form a giant coronagraph in space. The first spacecraft will host a telescope imaging the solar corona in visible light, while the second, the external occulter, will produce an artificial eclipse. This instrument is named ASPIICS (Association of Spacecraft for Polarimetric and Imaging Investigation of the Corona of the Sun). To accomplish the payload's scientific tasks, PROBA-3 will ensure sub-millimeter reciprocal positioning of its two satellites using closed-loop on-board metrology. Several metrology systems will be used and the Shadow Position Sensors (SPS) subsystem senses the penumbra around the instrument aperture and returns the 3-D displacement of the coronagraph satellite, with respect to its nominal position, by running a dedicated algorithm. In this paper, we describe how the SPS works and the choices made to accomplish the mission objectives.

Published

2021

4. The Space Weather X-Ray spectrometer for the Helianthus sub-L1 mission with solar photonic propulsion

Author

Vladimiro Noce, Salvatore Varisco, Federico Landini, Herve Haudemand, Roberto Candia, Marco Barbera, Ugo Lo Cicero, Fabio Frassetto, Luca Zangrilli, Valeria Caracci, Davide Loreggia, Alfonso Collura, Silvano Fineschi, Rocco Pellegrini, Enrico Cavallini, Marco Pizzarelli, Christian Circi, den Herder, Jan-Willem A., Noce, Vladimiro, Varisco, Salvatore, Landini, Federico, Haudemand, Herve, Candia, Roberto, Barbera, Marco, Lo Cicero, Ugo, Frassetto, Fabio, Zangrilli, Luca, Caracci, Valeria, Loreggia, Davide, Collura, Alfonso, Fineschi, Silvano, Pellegrini, Rocco, Cavallini, Enrico, Pizzarelli, Marco, and Circi, Christian

Subjects

Settore FIS/05 - Astronomia E Astrofisica, Solar Flares, Space Weather, X-Ray Solar Corona, X-Ray sources, X-Ray facilities, X-Ray filters

Abstract

Copyright 2022 Society of Photo‑Optical Instrumentation Engineers (SPIE). One print or electronic copy may be made for personal use only. Systematic reproduction and distribution, duplication of any material in this publication for a fee or for commercial purposes, and modification of the contents of the publication are prohibited. Helianthus is a phase A study of a space weather station with solar photonic propulsion. The scientific payload will be made of: an X-ray spectrometer to detect solar flares; SailCor, a coronagraph with a wide field of view; a plasma analyzer; a magnetometer. The maximum allowed mass for the entire scientific payload shall not exceed 5 kg. The two imaging devices (coronagraph and X-ray spectrometer) are of fundamental importance for the sake of remotely and timely mapping the status of the Sun and provide Earth stations with early warning of potentially disruptive events. An extensive research on available X-Ray detectors was performed and the Amptek FAST-SDD spectrometer was selected. It is a very light, compact and vacuum compatible instrument. In order to prove the device readiness for flight, a measurement campaign was organized to investigate its performance in terms of spectral range, spectral resolution, dynamic range and response speed. The campaign was run at the INAF XACT facility in Palermo (Italy). This paper describes the facility, the measurement campaign and the results.

Published

2022

5. Laboratory testbed for the calibration and the validation of the shadow position sensor subsystem of the PROBA3 ESA mission

Author

Francesco Amadori, Davide Loreggia, Gianalfredo Nicolini, Gerardo Capobianco, Giuseppe Massone, Alessandro Bemporad, Maurizio Pancrazzi, Vladimiro Noce, Marta Casti, Marco Romoli, L. Zangrilli, Silvano Fineschi, Federico Landini, and Massimiliano Belluso

Subjects

Computer science, Calibration (statistics), Testbed, Shadow, Position sensor, Remote sensing

Published

2021

6. Formation flying performances simulator for the shadow position sensors of the ESA PROBA-3 mission

Author

Raphaël Rougeot, Davide Loreggia, Cédric Thizy, Silvano Fineschi, Federico Landini, F. Amadori, Jorg Versluys, Gerardo Capobianco, Marta Casti, Vladimiro Noce, Alessandro Bemporad, Maurizio Pancrazzi, and Damien Galano

Subjects

Computer science, Shadow, Position sensor, Remote sensing

Published

2021

7. PROBA-3 mission and the Shadow Position Sensors: Metrology measurement concept and budget

Author

Jorg Versluys, Gianalfredo Nicolini, Laurence Rossi, Damien Galano, Luciano Accatino, Raymond Spillane, Federico Landini, Pierre Franco, Massimiliano Belluso, Alessandro Bemporad, Vladimiro Noce, Marta Casti, Giuseppe Massone, Martin O'Shea, Camille Galy, Ariane Pirard, Aline Hermans, L. Zangrilli, Marco Romoli, Gerardo Capobianco, Steve Buckley, Gianluca Morgante, Cédric Thizy, Luca Terenzi, Ken Hernan, Davide Loreggia, and Silvano Fineschi

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Spacecraft, Computer science, business.industry, Satellite constellation, Aerospace Engineering, Astronomy and Astrophysics, Field of view, 01 natural sciences, law.invention, Metrology, Telescope, Geophysics, Space and Planetary Science, law, 0103 physical sciences, General Earth and Planetary Sciences, Satellite, Aerospace engineering, business, 010303 astronomy & astrophysics, Coronagraph, Position sensor, 0105 earth and related environmental sciences

Abstract

PROBA-3 is a space mission of the European Space Agency that will test, and validate metrology and control systems for autonomous formation flying of two independent satellites. PROBA-3 will operate in a High Elliptic Orbit and when approaching the apogee at 6·104 Km, the two spacecraft will align to realize a giant externally occulted coronagraph named ASPIICS, with the telescope on one satellite and the external occulter on the other one, at inter-satellite distance of 144.3 m. The formation will be maintained over 6 hrs across the apogee transit and during this time different validation operations will be performed to confirm the effectiveness of the formation flying metrology concept, the metrology control systems and algorithms, and the spacecraft manoeuvring. The observation of the Sun's Corona in the field of view [1.08;3.0]RSun will represent the scientific tool to confirm the formation flying alignment. In this paper, we review the mission concept and we describe the Shadow Position Sensors (SPS), one of the metrological systems designed to provide high accuracy (sub-millimetre level) absolute and relative alignment measurement of the formation flying. The metrology algorithm developed to convert the SPS measurements in lateral and longitudinal movement estimation is also described and the measurement budget summarized.

Published

2021

8. PROBA-3 formation-flying metrology: algorithms for the shadow position sensor system

Author

M. Casti, Damien Galano, Silvano Fineschi, Federico Landini, Raphaël Rougeot, Gerardo Capobianco, Vladimiro Noce, Cédric Thizy, Davide Loreggia, and Alessandro Bemporad

Subjects

Spacecraft, Computer science, business.industry, Payload, Solar radius, law.invention, Metrology, law, Shadow, Satellite, business, Coronagraph, Algorithm, Position sensor

Abstract

PROBA-3 ESA’s mission aims at demonstrating the possibility and the capacity to carry out a space mission in which two spacecrafts fly in formation and maintain a fixed configuration. In particular, these two satellites - the Coronagraph Spacecraft (CSC) and the Occulter Spacecraft (OSC) – will form a 150-meters externally occulted coronagraph for the purpose of observing the faint solar corona, close to the solar limb – i.e. 1.05 solar radii from the Sun’s center (RΘ). The first satellite will host the ASPIICS (Association de Satellites Pour l'Imagerie et l'Interferometrie de la Couronne Solaire) coronagraph as primary payload. These features give to the PROBA-3 mission the characteristics of both, a technological and a scientific mission. Several metrology systems have been implemented in order to keep the formation-flying configuration. Among them, the Shadow Position Sensors (SPSs) assembly. The SPSs are designed to verify the sun-pointing alignment between the Coronagraph pupil entrance centre and the umbra cone generated by the Occulter Disk. The accurate alignment between the spacecrafts is required for observations of the solar corona as much close to the limb as 1.05 RΘ.The metrological system based on the SPSs is composed of two sets of four micro arrays of Silicon Photomultipliers (SiPMs) located on the coronagraph pupil plane and acquiring data related to the intensity of the penumbra illumination level to retrieve the spacecrafts relative position. We developed and tested a dedicated algorithm for retrieving the satellites position with respect to the Sun. Starting from the measurements of the penumbra profile in four different spots and applying a suitable logic, the algorithm evaluates the spacecraft tri-dimensional relative position. In particular, during the observational phase, when the two satellites will be at 150 meters of distance, the algorithm will compute the relative position around the ideal aligned position with an accuracy of 500μm within the lateral plane and 500 mm for the longitudinal measurement. This work describes the formation flying algorithm based on the SPS measurements. In particular, the implementation logic and the formulae are described together with the results of the algorithm testing.

Published

2019

9. The in-flight calibration procedures of the Shadow Position Sensors (SPS), a very accurate optical metrology system of the ESA/PROBA-3 formation flying mission

Author

Marta Casti, Damien Galano, Cédric Thizy, Davide Loreggia, Alessandro Bemporad, Vladimiro Noce, Silvano Fineschi, Federico Landini, Gerardo Capobianco, and Marco Romoli

Subjects

Computer science, business.industry, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Metrology, law.invention, 010309 optics, law, 0103 physical sciences, Shadow, Calibration, Radiometry, Aerospace engineering, 0210 nano-technology, Optical metrology, business, Coronagraph, Position sensor

Abstract

The PROBA-3 is a European Space Agency (ESA) mission devoted to obtain, as never before, highly accurate formation flying. A couple of satellites will works together as an externally occulted solar coronagraph. The distance between the two satellites is of 144 meters and the required longitudinal accuracy of the relative positioning is better than 1 mm. In this proceeding the in-flight calibration of one of the most accurate metrology subsystem, the SPS (Shadow Position Sensors), will be presented.

Published

2019

10. The Occulter Position Sensor Emitters (OPSE) metrology sub-system for the PROBA-3 mission

Author

Aline Hermans, Giuseppe Massone, Damien Galano, Munizer Purica, Ariane Pirard, Cédric Thizy, Davide Loreggia, Octavian Ionescu, Camille Galy, Ileana Cernica, Gerardo Capobianco, and Silvano Fineschi

Subjects

Spacecraft, business.industry, Computer science, Field of view, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, law.invention, Metrology, 010309 optics, Telescope, law, 0103 physical sciences, Satellite, Aerospace engineering, 0210 nano-technology, business, Coronagraph, Geocentric orbit, Position sensor

Abstract

The development and employment of metrology controlled diluted systems for astronomical applications in space represents a cornerstone to dramatically improve the observation limits. In this scenario, the ESA mission PROBA-3 is the first technology demonstration mission aimed at verifying and validating several metrological systems to obtain high accuracy formation flying (FF) of two satellites. The two spacecraft will be aligned and maintained in a FF, around the apogee of their geocentric orbit, at an average inter-satellite distance of 144m, with an accuracy down to sub-millimetre level. The scientific task of the mission, that is the FF validation tool, is the observation of the Sun’s Corona at high spatial and temporal resolution within the field of view [1.08; 3.0]R ⊙ . To this end, one satellite will house a coronagraph telescope, named ASPIICS, and the other one, the external occulter. In this paper, we review the metrology concept applied to the mission with a special focus on the Occulter Position Sensor Emitters (OPSE) metrology sub-system, a set of 3 monochromatic Led emitters positioned on opposite-Sun surface of the occulter and imaged at the ASPIICS’s focal plane.

Published

2019

11. The Shadow Position Sensors (SPS) metrology subsystem on-board PROBA-3 mission : Design and performance

Author

Steven Buckley, Cédric Thizy, Silvano Fineschi, Vladimiro Noce, M. Casti, Sergio Billotta, Alessandro Bemporad, Gerardo Capobianco, Marco Romoli, Davide Loreggia, Massimiliano Belliiso, and Luca Naponiello

Subjects

Spacecraft, business.industry, Computer science, Aperture, Payload, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Metrology, law.invention, 010309 optics, law, 0103 physical sciences, Shadow, Satellite, Aerospace engineering, 0210 nano-technology, business, Coronagraph, Position sensor

Abstract

PROBA-3 is a two-spacecraft ESA mission carrying the space-based diluted coronagraph ASPIICS. The imaging instrument is hosted on the first spacecraft with the second acting as external occulter. In order to accomplish the payload’s scientific tasks, PROBA-3 will ensure sub-millimeter reciprocal positioning of its two satellites by means of closedloop on-board metrology. The Shadow Position Sensors (SPS) sense the penumbra around the instrument aperture and return the 3-D displacement of the coronagraph satellite with respect to its nominal position by running a dedicated algorithm. In this paper we describe how the SPS works and the choices made in order to accomplish the mission objectives.

Published

2019

12. Development of ASPIICS: a coronagraph based on Proba-3 formation flying mission

Author

Michał Mosdorf, Lieve de Vos, Steve Buckley, Philippe Ledent, Raphaël Rougeot, Andrei Zhukov, Miroslaw Rataj, Cédric Thizy, Jérôme Jacob, Michal Kurowski, Tomasz Walczak, François Denis, Alessandro Bemporad, Alicja Zarzycka, Ileana Cernica, Munizer Purica, Michal Ladno, Joe Zender, Radek Peresty, N. Kranitis, Rafal Graczyk, Radek Melich, Lucas Salvador, Richard Jansen, Silvano Fineschi, Dominique Mollet, Damien Galano, Bartlomiej Radzik, Davide Loreggia, P. Horodyská, Antonios Paschalis, Vladimir Daniel, Jorg Versluys, and Camille Galy

Subjects

Spacecraft, business.industry, Payload, Computer science, 0211 other engineering and technologies, Polarimetry, Solar radius, 02 engineering and technology, Breadboard, 01 natural sciences, Corona, law.invention, 010309 optics, law, Primary (astronomy), 0103 physical sciences, Aerospace engineering, business, Coronagraph, 021101 geological & geomatics engineering

Abstract

This paper presents the recent achievements in the development of ASPIICS (Association of Spacecraft for Polarimetric and Imaging Investigation of the Corona of the Sun), a solar coronagraph that is the primary payload of ESA’s formation flying in-orbit demonstration mission PROBA-3. The PROBA-3 Coronagraph System is designed as a classical externally occulted Lyot coronagraph but it takes advantage of the opportunity to place the 1.4 meter wide external occulter on a companion spacecraft, about 150m apart, to perform high resolution imaging of the inner corona of the Sun as close as ~1.1 solar radii. Besides providing scientific data, ASPIICS is also equipped with sensors for providing relevant navigation data to the Formation Flying GNC system. This paper is reviewing the recent development status of the ASPIICS instrument as it passed CDR, following detailed design of all the sub-systems and testing of STM and various Breadboard models.

Published

2018

13. SOXS: a wide band spectrograph to follow up transients

Author

Johan P. U. Fynbo, H. U. Käufl, J. Lehti, A. Brucalassi, Massimo Turatto, T. Kumar, Matteo Accardo, H. Kuncarayacti, Matteo Genoni, Marco Riva, P. D'Avanzo, Daniela Fantinel, Matteo Aliverti, Jari Kotilainen, Federico Biondi, Davide Loreggia, Adam Rubin, Rosario Cosentino, Stephen J. Smartt, Sergio Campana, Fabrizio Vitali, Andrea Baruffolo, Seppo Mattila, R. Zanmar Sanchez, Salvo Scuderi, Matteo Munari, Giuliano Pignata, Francesco D'Alessio, Antonino Bianco, M. Hirvonen, Sergio D'Orsi, M. Della Valle, S. Ben Ami, Iair Arcavi, G. Capasso, Daniele Gardiol, D. Ricci, Luca Marafatto, G. Li Causi, Enrico Cappellaro, J. Achrén, Riccardo Claudi, Avishay Gal-Yam, J. Antonio Araiza-Duran, Giorgio Pariani, Bernardo Salasnich, Marco Landoni, O. Diner, O. Hershko, Pietro Schipani, M. Colapietro, and Michael Rappaport

Subjects

Physics, ta115, 010504 meteorology & atmospheric sciences, Gravitational wave, FOS: Physical sciences, Astronomy, 01 natural sciences, law.invention, SOXS, Telescope, Photometry (optics), Supernova, Limiting magnitude, law, Target of opportunity, 0103 physical sciences, Astrophysics - Instrumentation and Methods for Astrophysics, Instrumentation and Methods for Astrophysics (astro-ph.IM), 010303 astronomy & astrophysics, Spectrograph, astro-ph.IM, 0105 earth and related environmental sciences

Abstract

SOXS (Son Of X-Shooter) will be a spectrograph for the ESO NTT telescope capable to cover the optical and NIR bands, based on the heritage of the X-Shooter at the ESO-VLT. SOXS will be built and run by an international consortium, carrying out rapid and longer term Target of Opportunity requests on a variety of astronomical objects. SOXS will observe all kind of transient and variable sources from different surveys. These will be a mixture of fast alerts (e.g. gamma-ray bursts, gravitational waves, neutrino events), mid-term alerts (e.g. supernovae, X-ray transients), fixed time events (e.g. close-by passage of minor bodies). While the focus is on transients and variables, still there is a wide range of other astrophysical targets and science topics that will benefit from SOXS. The design foresees a spectrograph with a Resolution-Slit product ~ 4500, capable of simultaneously observing over the entire band the complete spectral range from the U- to the H-band. The limiting magnitude of R~20 (1 hr at S/N~10) is suited to study transients identified from on-going imaging surveys. Light imaging capabilities in the optical band (grizy) are also envisaged to allow for multi-band photometry of the faintest transients. This paper outlines the status of the project, now in Final Design Phase., Comment: 12 pages, 14 figures, to be published in SPIE Proceedings 10702

Published

2018

14. Formation flying metrology system for the ESA-PROBA3 mission: the Shadow Positioning Sensors (SPS)

Author

Marco Riva, Benoit Marquet, Marco Romoli, François Denis, Alessandro Bemporad, Gerardo Capobianco, L. Accatino, Silvano Fineschi, C. Calderoni, Cristian Baccani, Cédric Thizy, Vladimiro Noce, Gianalfredo Nicolini, Federico Landini, Davide Loreggia, Massimiliano Belluso, Stefano Pieraccini, P. Ledent, M. Casti, Damien Galano, Steve Buckley, L. Zangrilli, Gianluca Morgante, M. Moschetti, and Linda Terenzi

Subjects

Spacecraft, business.industry, Aperture, Computer science, law.invention, Metrology, Telescope, Silicon photomultiplier, law, Temporal resolution, Satellite, Aerospace engineering, business, Coronagraph

Abstract

PROBA3 is the first high precision formation flying (FF) mission under responsibility of the European Space Agency (ESA). It is a technology mission devoted to in-orbit demonstration of the FF techniques, with two satellites kept at an average inter-satellite distance of 144m. The guiding scientific rationale is to realize a diluted coronagraph with the telescope (ASPIICS) on one satellite and the external occulter on the other satellite to observe the inner Solar corona at high spatial and temporal resolution, down to 1.08R⊙. The two spacecraft will be orbiting in a high eccentricity geocentric trajectory with perigee at 600km and the apogee at 60000Km and with an orbital period of 19hrs. The FF acquisition and operations will last about 6 hrs around the apogee and different metrology systems will be used for realizing and controlling the FF. The alignment active most critical sub-system is the Shadow Positioning Sensors (SPS), a series of Si-PM (Silicon Photomultiplier) disposed around the ASPIICS telescope's entrance aperture and measuring the proper positioning of the penumbra generated by the occulter at the center of the coronagraph’s optical reference frame. The FF alignment measurement accuracies required to the SPS are: 500μm for lateral movements and 50mm for longitudinal movements. This paper gives an overview of the opto-mechanical and electronic design and of the software algorithm for the FF intersatellite positioning. The expected performance of the SPS metrology system are reported.

Published

2018

15. The acquisition camera system for SOXS at NTT

Author

Enrico Cappellaro, Marco Landoni, Federico Biondi, M. Hirvonen, Giorgio Pariani, A. Brucalassi, Salvatore Scuderi, Michael Rappaport, Bernardo Salasnich, Marco Riva, Daniela Fantinel, Pietro Schipani, M. Colapietro, O. Diner, J. Lehti, Sagi Ben-Ami, Matteo Genoni, Riccardo Claudi, Fabrizio Vitali, Jari Kotilainen, O. Hershko, Massimo Turatto, Luca Marafatto, Andrea Bianco, Avishay Gal-Yam, J. A. Araiza-Duran, Seppo Mattila, D. Ricci, Iair Arcavi, Sergio Campana, Johan P. U. Fynbo, Sergio D'Orsi, J. Achrén, G. Li Causi, Stephen J. Smartt, Hanindyo Kuncarayakti, R. Zanmar Sanchez, P. D'Avanzo, Matteo Aliverti, Davide Loreggia, Daniele Gardiol, Adam Rubin, Giuliano Pignata, Francesco D'Alessio, G. Capasso, Matteo Munari, Andrea Baruffolo, M. Della Valle, T. Kumar, and Rosario Cosentino

Subjects

ta115, ta114, Computer science, Real-time computing, Response time, 01 natural sciences, Target acquisition, Optical quality, law.invention, 010309 optics, SOXS, Telescope, Photometry (optics), Relay, law, 0103 physical sciences, 010303 astronomy & astrophysics, Spectrograph

Abstract

SOXS (Son of X-Shooter) will be the new medium resolution (R~4500 for a 1 arcsec slit), high-efficiency, wide band spectrograph for the ESO-NTT telescope on La Silla. It will be able to cover simultaneously optical and NIR bands (350-2000nm) using two different arms and a pre-slit Common Path feeding system. SOXS will provide an unique facility to follow up any kind of transient event with the best possible response time in addition to high efficiency and availability. Furthermore, a Calibration Unit and an Acquisition Camera System with all the necessary relay optics will be connected to the Common Path sub-system. The Acquisition Camera, working in optical regime, will be primarily focused on target acquisition and secondary guiding, but will also provide an imaging mode for scientific photometry. In this work we give an overview of the Acquisition Camera System for SOXS with all the different functionalities. The optical and mechanical design of the system are also presented together with the preliminary performances in terms of optical quality, throughput, magnitude limits and photometric properties.

Published

2018

16. Test plan for the PROBA3/ASPIICS scaled model measurement campaign

Author

Silvano Fineschi, Benoit Marquet, Alain Jody Corso, S. Vives, Davide Loreggia, M. Casti, Marco Romoli, Giuseppe Massone, Alessandro Bemporad, Gerardo Capobianco, Mauro Focardi, Maurizio Pancrazzi, Cristian Baccani, Cédric Thizy, Etienne Renotte, Vladimiro Noce, and Federico Landini

Subjects

Spacecraft, business.industry, Computer science, Stray light, Polarimetry, Occultation, law.invention, Metrology, Telescope, law, Solar simulator, Aerospace engineering, business, Coronagraph

Abstract

PROBA3/ASPIICS (Association of Spacecraft for Polarimetric and Imaging Investigation of the Corona of the Sun) is the first formation flight solar coronagraph, scheduled by ESA for a launch and currently in phase C/D. It is constituted by two spacecraft (one hosting the occulter, diameter 142 cm, and one with the telescope) separated by 144 m, kept in strict alignment by means of complex active and metrology custom systems. The stray light analysis, which is always one the most critical work packages for a solar coronagraph, has been only theoretically investigated so far due to the difficulty of replicating the actual size system in a clean laboratory environment. The light diffracted by the external occulter is the worst offender for the stray light level on the instrument focal plane, thus there is strong interest for scaling at least the occultation system of the coronagraph and test it in front of a solar simulator in order to experimentally validate the expected theoretical performance. The theory for scaling the occulter, the occulter-pupil distance and the source dimension has been developed and a scaled model is being manufactured. A test campaign is going to be conducted at the OPSys facility in Torino in front of a solar simulator (conveniently scaled). This work accounts for the description of the scaled model laboratory set-up and of the test plan.

Published

2017

17. An improved version of the Shadow Position Sensor readout electronics on-board the ESA PROBA-3 Mission

Author

Davide Loreggia, L. Accatino, Mauro Focardi, Maurizio Pancrazzi, Marco Romoli, Cédric Thizy, P. Ledent, Cristian Baccani, Gerardo Capobianco, Silvano Fineschi, Federico Landini, Marta Casti, Steve Buckley, Vladimiro Noce, François Denis, and Alessandro Bemporad

Subjects

Spacecraft, business.industry, Computer science, Photovoltaic system, 02 engineering and technology, Breadboard, 01 natural sciences, law.invention, Silicon photomultiplier, law, Control system, 0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, Orbit (dynamics), 020201 artificial intelligence & image processing, Aerospace engineering, business, 010303 astronomy & astrophysics, Coronagraph, Position sensor

Abstract

PROBA-3 [1] [2] is a Mission of the European Space Agency (ESA) composed by two satellites flying in formation and aimed at achieving unprecedented performance in terms of relative positioning. The mission purpose is, in first place, technological: the repeated formation break and acquisition during each orbit (every about twenty hours) will be useful to demonstrate the efficacy of the closed-loop control system in keeping the formation-flying (FF) and attitude (i.e. the alignment with respect to the Sun) of the system. From the scientific side, instead, the two spacecraft will create a giant instrument about 150 m long: an externally occulted coronagraph named ASPIICS (Association of Spacecraft for Polarimetric and Imaging Investigation of the Corona of the Sun) dedicated to the study of the inner part of the visible solar corona. The two satellites composing the mission are: the Coronagraph Spacecraft (CSC), hosting the Coronagraph Instrument (CI), and the disk-shaped (1.4 m diameter) Occulter Spacecraft (OSC). The PROBA-3 GNC (Guidance, Navigation and Control) system will employ several metrological subsystems to keep and retain the desired relative position and the absolute attitude (i.e. with respect to the Sun) of the aligned spacecraft, when in observational mode. The SPS subsystem [5] is one of these metrological instruments. It is composed of eight silicon photomultipliers (SiPMs), sensors operated in photovoltaic mode [6] that will sense the penumbra light around the Instrument’s pupil so to detect any FF displacement from the nominal position. In proximity of the CDR (Critical Design Review) phase, we describe in the present paper the changes occurred to design in the last year in consequence of the tests performed on the SPS Breadboard (Evaluation Board, EB) and the SPS Development Model (DM) and that will finally lead to the realization of the flight version of the SPS system.

Published

2017

18. Recent achievements on ASPIICS, an externally occulted coronagraph for PROBA-3

Author

Ileana Cernica, N. Kranitis, Andrei Zhukov, Sylvie Liébecq, Lucas Salvador, Tomasz Walczak, François Denis, Mateusz Mroczkowski, Kevin O'Neill, Estelle Graas, Miroslaw Rataj, Yvan Stockman, Michal Kurowski, Richard Desselle, Steve Buckley, Etienne Renotte, Michal Ladno, Dominique Mollet, Silvano Fineschi, Antonis Paschalis, Lieve de Vos, Damien Galano, Camille Galy, Jean-Sébastien Servaye, Radek Peresty, Radek Melich, Michał Mosdorf, Alicja Zarzycka, Bartlomiej Radzik, Cédric Thizy, Karl Fleury-Frenette, Karel Patočka, Rafal Graczyk, Idriss Mechmech, Jean-Marie Gillis, Davide Loreggia, and P. Horodyská

Subjects

Physics, Spacecraft, business.industry, Astronomy, Solar radius, Space weather, Orbital mechanics, Solar physics, 01 natural sciences, Corona, law.invention, 010309 optics, law, 0103 physical sciences, Coronal mass ejection, business, 010303 astronomy & astrophysics, Coronagraph

Abstract

This paper presents the current status of ASPIICS, a solar coronagraph that is the primary payload of ESA’s formation flying in-orbit demonstration mission PROBA-3. The “sonic region” of the Sun corona remains extremely difficult to observe with spatial resolution and sensitivity sufficient to understand the fine scale phenomena that govern the quiescent solar corona, as well as phenomena that lead to coronal mass ejections (CMEs), which influence space weather. Improvement on this front requires eclipse-like conditions over long observation times. The space-borne coronagraphs flown so far provided a continuous coverage of the external parts of the corona but their over-occulting system did not permit to analyse the part of the white-light corona where the main coronal mass is concentrated. The PROBA-3 Coronagraph System, also known as ASPIICS (Association of Spacecraft for Polarimetric and Imaging Investigation of the Corona of the Sun) is designed as a classical externally occulted Lyot coronagraph but it takes advantage of the opportunity to place the external occulter on a companion spacecraft, about 150m apart, to perform high resolution imaging of the inner corona of the Sun as close as ~1.1 solar radii. The images will be tiled and compressed on board in an FPGA before being down-linked to ground for scientific analyses. ASPIICS is built by a large European consortium including about 20 partners from 7 countries under the auspices of the European Space Agency. This paper is reviewing the recent development status of the ASPIICS instrument as it is approaching CDR.

Published

2016

19. Characterization of the ASPIICS/OPSE metrology sub-system and PSF centroiding procedure

Author

Cédric Thizy, Ileana Cernica, Vladimiro Noce, M. Casti, Jean-Sébastien Servaye, M. Nisulescu, Silvano Fineschi, Alessandro Bemporad, Mauro Focardi, Munizer Purica, Federico Landini, Etienne Renotte, Marco Romoli, M. Pancrazi, Giuseppe Massone, Cristian Baccani, Gerardo Capobianco, Davide Loreggia, and Gianalfredo Nicolini

Subjects

Physics, Spacecraft, business.industry, 02 engineering and technology, Orbital mechanics, 021001 nanoscience & nanotechnology, 01 natural sciences, Metrology, law.invention, 010309 optics, Interferometry, Optics, Observational astronomy, law, 0103 physical sciences, Satellite, 0210 nano-technology, business, Coronagraph, Position sensor, Remote sensing

Abstract

years have raised increasing interest. Many applications of astronomical observation techniques, as coronography and interferometry get great benefit when moved in space and the employment of diluted systems represents a milestone to step-over in astronomical research. In this work, we present the Optical Position Sensors Emitter (OPSE) metrological sub-system on-board of the PROBA3. PROBA3 is an ESA technology mission that will test in-orbit many metrology techniques for the maintenance of a Formation Flying with two satellites, in this case an occulter and a main satellite housing a coronagraph named ASPIICS, kept at an average inter-distance of 144m. The scientific task is the observation of the Sun’s Corona at high spatial and temporal resolution down to 1.08R⊙. The OPSE will monitor the relative position of the two satellites and consists of 3 emitters positioned on the rear surface of the occulter, that will be observed by the coronagraph itself. A Centre of Gravity (CoG) algorithm is used to monitor the emitter’s PSF at the focal plane of the Coronagraph retrieving the Occulter position with respect to the main spacecraft. The 3σ location target accuracy is 300μm for lateral movement and 21cm for longitudinal movements. A description of the characterization tests on the OPSE LED sources, and of the design for a laboratory set-up for on ground testing is given with a preliminary assessment of the performances expected from the OPSE images centroiding algorithm.

Published

2016

20. The satellite formation flying in lab: PROBA-3/ASPIICS metrology subsystems test-bed

Author

Giuseppe Massone, Munizer Purica, Gianalfredo Nicolini, Cédric Thizy, Alessandro Bemporad, Marta Casti, I. Mechmech, E. Budianu, Etienne Renotte, Kevin O'Neill, Marco Romoli, Steve Buckley, Gerardo Capobianco, Silvano Fineschi, Federico Landini, Davide Loreggia, Jean-Sébastien Servaye, Mauro Focardi, Ileana Cernica, Maurizio Pancrazzi, Cristian Baccani, and Vladimiro Noce

Subjects

Physics, Spacecraft, business.industry, Instrumentation, Astrophysics::Instrumentation and Methods for Astrophysics, Solar radius, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Metrology, law.invention, 010309 optics, law, Physics::Space Physics, 0103 physical sciences, Shadow, Astrophysics::Solar and Stellar Astrophysics, Satellite, Astrophysics::Earth and Planetary Astrophysics, 0210 nano-technology, business, Coronagraph, Position sensor, Remote sensing

Abstract

Formation flying is one of the most promising techniques for the future of astronomy and astrophysics from the space. The capabilities of the rockets strongly affect the dimensions and the weights of telescopes and instrumentation to be launched. Telescopes composed by several smallest satellites in formation flying, could be the key for build big space telescopes. With this aim, the ESA PROBA-3 mission will demonstrate the capabilities of this technology, maintaining two satellites aligned within 1 mm (longitudinal) when the nominal distance between the two is of around 144m. The scientific objective of the mission is the observation of the solar corona down to 1.08 solar radii. The Coronagraph Spacecraft (CSC) will observe the Sun, when the second spacecraft, the Occulter Spacecraft (OSC) will work as an external occulter, eclipsing to the CSC the sun disk. The finest metrology sub-systems, the Shadow Position Sensors (SPS) and the Occulter Position Sensor Emitters (OPSE) identifying respectively the CSC-Sun axis and the formation flying (i.e., CSC-OSC) axis will be considered here. In particular, this paper is dedicated to the test-bed for the characterization, the performance analysis and the algorithms capabilities analysis of the both the metrology subsystems. The test-bed is able to simulate the different flight conditions of the two spacecraft and will give the opportunity to check the response of the subsystems in the conditions as close as possible to the flight ones.

Published

2016

21. Instrument physical model for the SOXS (Son Of X-Shooter) spectrograph

Author

Daniele Gardiol, Davide Loreggia, and ITA

Subjects

SOXS, Engineering, Optics, Software, business.industry, Limiting magnitude, Electronic engineering, Ranging, Field of view, business, Spectrograph, Data reduction, Physical quantity

Abstract

We present the proposal for the physical instrument model of the SOXS (Son OF X-Shooter) spectroscopic facility mainly devoted to the follow-up observation of transient sources. A dedicated suitable instrument to exploit the science of these transients is lacking, resulting in severe science "dissipation". SOXS will cover the optical/NIR band (0.35-1.75 μm) with a medium resolution (R 4500), down to the limiting magnitude of R 20-20.5 (1 hr at S/N 10) that is perfectly suited to study transients from on-going imaging surveys. Imaging capabilities in the optical are also foreseen to allow for multi-band photometry of the faintest transients with a field of view of at least 2arcmin. We propose to implement a physical modelling approach in order to link the instrument parameters and behaviour to physical quantities, thus providing a description of the instrument that can be connected with measurements. The method has been already successfully applied to the X-shooter instrument. The X-shooter physical model is based on a kernel optical ray-tracing realised by means of matrix optics representation, which can handle a large number of wavelengths. This can be extended to the SOXS design. The foreseen applications of the SOXS physical model are broad, ranging from support to detailed instrument design and development of the data reduction software, wavelength calibration, evaluation of instrument performance as a function of the model parameters, instrument alignment, and support during the commissioning phase and as a tool for quality check during operations.

Published

2016

22. Gamma Astrometric Measurement Experiment (GAME) – Implementation and performance

Author

Mario Gai, Alberto Vecchiato, Sebastiano Ligori, Mario G. Lattanzi, and Davide Loreggia

Subjects

Atmospheric Science, Fizeau interferometer, Aperture, media_common.quotation_subject, Aerospace Engineering, law.invention, Telescope, Optics, law, Astrophysics::Solar and Stellar Astrophysics, Angular resolution, Space research, media_common, Physics, business.industry, Astrophysics::Instrumentation and Methods for Astrophysics, Astronomy, Astronomy and Astrophysics, Astrometry, Orbit, Geophysics, Space and Planetary Science, Sky, Physics::Space Physics, General Earth and Planetary Sciences, Astrophysics::Earth and Planetary Astrophysics, business

Abstract

The GAME mission concept is aimed at testing the General Relativity, through precise measurement of the gravitational deflection of light by the Sun, by means of an optimised telescope operating in the visible and launched in orbit on a small class satellite. We describe the proposed mission profile, the preliminary payload design and the expected performance. The targeted precision on the γ parameter of the PPN formulation of General Relativity is in the range 10−6 to 10−7. The measurement principle relies on the differential astrometric signature on the stellar positions. The instrument concept is based on a dual field, multiple aperture Fizeau interferometer, observing simultaneously two sky regions close to the solar limb. A beam combiner folds the telescope line of sight on two different directions on the sky, separated by a base angle of 4°. The diluted optics approach achieves an efficient rejection of the scattered solar radiation, while retaining an acceptable angular resolution on the science targets.

Published

2009

23. The new SOXS instrument for the ESO NTT

Author

V. De Caprio, Sergio Campana, Francesco D'Alessio, Matteo Munari, Sergio D'Orsi, Avishay Gal-Yam, Brian P. Schmidt, Enrico Cappellaro, Rosario Cosentino, Fabrizio Vitali, R. Franzen, Stephen J. Smartt, Stefano Basso, Salvatore Scuderi, A. de Ugarte Postigo, J. P. U. Fynbo, Andrea Baruffolo, S. Basa, Mario Hamuy, Enrico Giro, M. Della Valle, S. Savarese, Marco Riva, Giuliano Pignata, M. Iuzzolino, Davide Loreggia, Enrico Cascone, Riccardo Claudi, P. Schipani, Seppo Mattila, and Daniele Gardiol

Subjects

Physics, business.industry, Near-infrared spectroscopy, FOS: Physical sciences, 01 natural sciences, law.invention, 010309 optics, Telescope, SOXS, Optics, law, 0103 physical sciences, Visible band, business, Astrophysics - Instrumentation and Methods for Astrophysics, 010303 astronomy & astrophysics, Spectrograph, Instrumentation and Methods for Astrophysics (astro-ph.IM)

Abstract

SOXS (Son Of X-Shooter) will be a unique spectroscopic facility for the ESO-NTT 3.5-m telescope in La Silla (Chile), able to cover the optical/NIR band (350-1750 nm). The design foresees a high-efficiency spectrograph with a resolution-slit product of ~4,500, capable of simultaneously observing the complete spectral range 350 - 1750 nm with a good sensitivity, with light imaging capabilities in the visible band. This paper outlines the status of the project., Comment: 10 pages, submitted to SPIE Astronomical Telescopes & Instrumentation 2016, paper 9908-152

Published

2016

24. The shadow position sensors (SPS) formation flying metrology subsystem for the ESA PROBA-3 mission: present status and future developments

Author

Jean-Sébastien Servaye, Mauro Focardi, Cédric Thizy, Cristian Baccani, Maurizio Pancrazzi, Etienne Renotte, Kevin O'Neill, Gianalfredo Nicolini, Marta Casti, Gerardo Capobianco, Federico Landini, Silvano Fineschi, Vladimiro Noce, Alessandro Bemporad, Davide Loreggia, Steve Buckley, I. Mechmech, Marco Romoli, L. Accatino, and Giuseppe Massone

Subjects

Physics, 010504 meteorology & atmospheric sciences, Spacecraft, business.industry, Payload, Orbital mechanics, Breadboard, 01 natural sciences, law.invention, 010309 optics, Attitude control, Light intensity, Optics, law, 0103 physical sciences, business, Coronagraph, Position sensor, 0105 earth and related environmental sciences

Abstract

PROBA-3 [1] [2] is a Mission of the European Space Agency (ESA) composed of two formation-flying satellites, planned for their joint launch by the end of 2018. Its main purposes have a dual nature: scientific and technological. In particular, it is designed to observe and study the inner part of the visible solar corona, thanks to a dedicated coronagraph called ASPIICS (Association of Spacecraft for Polarimetric and Imaging Investigation of the Corona of the Sun), and to demonstrate the in-orbit formation flying (FF) and attitude control capability of its two satellites. The Coronagraph payload on-board PROBA-3 consists of the following parts: the Coronagraph Instrument (CI) with the Shadow Position Sensor (SPS) on the Coronagraph Spacecraft (CSC), the Occulter Position Sensor (OPSE) [3] [4] and the External Occulting (EO) disk on the Occulter Spacecraft (OSC). The SPS subsystem [5] is one of the main metrological devices of the Mission, adopted to control and to maintain the relative (i.e. between the two satellites) and absolute (i.e. with respect to the Sun) FF attitude. It is composed of eight micro arrays of silicon photomultipliers (SiPMs) [6] that shall be able to measure, with the required sensitivity and dynamic range as asked by ESA, the penumbral light intensity on the Coronagraph entrance pupil. With the present paper we describe the testing activities on the SPS breadboard (BB) and Development Model (DM) as well as the present status and future developments of this PROBA-3 metrological subsystem.

Published

2016

25. Models for the active optics system of the ASTRI SST-2M prototype proposed for the Cherenkov Telescope Array

Author

Davide Loreggia, Enrico Giro, Federico Russo, G. Rodeghiero, Luigi Lessio, Daniele Gardiol, and ITA

Subjects

Physics, Initial Seed, business.industry, Astrophysics::High Energy Astrophysical Phenomena, Astrophysics::Instrumentation and Methods for Astrophysics, Active optics, Cherenkov Telescope Array, Astronomical instrumentation, law.invention, Primary mirror, Telescope, Optics, law, Secondary mirror, business, Cherenkov radiation, Astrophysics::Galaxy Astrophysics

Abstract

ASTRI SST-2M is an end-to-end prototype of Small Size class of Telescope proposed for the Cherenkov Telescope Array (CTA). Currently under completion at the Serra La Nave observing station (Mt. Etna, Catania, Italy), the ASTRI SST- 2M telescope is the first imaging dual-mirror telescope ever realized for Cherenkov telescopes. A mini-array of nine such telescopes will form the ASTRI mini-array proposed as a precursor and initial seed of CTA to be installed at the final CTA southern site. ASTRI SST-2M is equipped with an active optics system, controlling both the segmented primary mirror and the monolithic secondary mirror, which allows optical re-alignment during telescope slew. We describe the hardware and software solution that have been implemented for optics control and the models we developed for the system.

Published

2016

26. OPSE metrology system onboard of the PROBA3 mission of ESA

Author

Davide Loreggia, Alessandro Bemporad, Silvano Fineschi, Giuseppe Massone, E. Budianu, Gianalfredo Nicolini, Gerardo Capobianco, Etienne Renotte, Munizer Purica, Ileana Cernica, Maurizio Pancrazzi, Marco Romoli, Federico Landini, Jean-Sébastien Servaye, Mauro Focardi, and Cédric Thizy

Subjects

Physics, Space technology, Spacecraft, business.industry, Orbital mechanics, law.invention, Metrology, Interferometry, law, Satellite, business, Coronagraph, Position sensor, Remote sensing

Abstract

In recent years, ESA has assessed several mission involving formation flying (FF). The great interest in this topics is mainly driven by the need for moving from ground to space the location of next generation astronomical telescopes overcoming most of the critical problems, as example the construction of huge baselines for interferometry. In this scenario, metrology systems play a critical role. PROBA3 is an ESA technology mission devoted to in-orbit demonstration of the FF technique, with two satellites, an occulter and a main satellite housing a coronagraph named ASPIICS, kept at an average inter-distance by about 144m, with micron scale accuracy. The guiding proposal is to test several metrology solution for spacecraft alignment, with the important scientific return of having observation of Corona at never reached before angular field. The Shadow Position Sensors (SPS), and the Optical Position Emitters Sensors (OPSE) are two of the systems used for FF fine tracking. The SPS are finalized to monitor the position of the two spacecraft with respect to the Sun and are discussed in dedicated papers presented in this conference. The OPSE will monitor the relative position of the two satellites and consists of 3 emitters positioned on the rear surface of the occulter, that will be observed by the coronagraph itself. By following the evolution of the emitters images at the focal plane the alignment of the two spacecrafts is retrieved via dedicated centroiding algoritm. We present an overview of the OPSE system and of the centroiding approach.

Published

2015

27. Design status of ASPIICS, an externally occulted coronagraph for PROBA-3

Author

Andres Alia, Jim Van der Meulen, Giuseppe Massone, Michał Mosdorf, Jean-Sébastien Servaye, Russell A. Howard, Michał Ładno, Joe Zender, Jean-Philippe A. Halain, Vít Lédl, Gianalfredo Nicolini, Serge Koutchmy, Carl Jackson, Mauro Focardi, Adrian Dinescu, Steve Buckley, Yvan Stockman, Gerardo Capobianco, Raluca Muller, Karel Patočka, Rafal Graczyk, Jean-Marie Gillis, Konrad Grochowski, Jan Rautakoski, Radek Peresty, Radek Lapáček, Antonios Paschalis, Camille Galy, Jacek Kosiec, Etienne Renotte, Radek Melich, Dominique Mollet, Aline Hermans, Radoslav Darakchiev, Kanaris Tsinganos, Tomáš Vít, Nico Van Vooren, Miroslaw Rataj, Michal Kurowski, Richard Desselle, Alessandro Bemporad, Marcin Darmetko, Tomasz Górski, Lucas Salvador, Estelle Graas, Damien Galano, Arkadiusz Swat, Vladimir Daniel, Łukasz Mosdorf, Piotr Orleanski, Mateusz Mroczkowski, Irina Popescu, Lieve de Vos, Pavel Psota, Roman Rybecký, Cristina Bramanti, Hubert Kasprzyk, Ileana Cernica, Cédric Thizy, Joseph Bernier, Jana Kovačičinová, Philippe Lamy, Brian McGarvey, Andrei Zhukov, Alicja Zarzycka, Maurizio Pancrazzi, Arnaud Debaize, Cornel Solomon, Davide Loreggia, Tomasz Walczak, Federico Landini, Karl Fleury-Frenette, Kevin O'Neill, Agnes Mestreau-Garreau, Michel Thome, François Denis, Marie-Catherine Palau, Bogdan Nicula, N. Kranitis, Sylvie Liébecq, A. Fumel, Emmanuel Janssen, Marco Romoli, Silvano Fineschi, and ITA

Subjects

Physics, Spacecraft, Solar eclipse, business.industry, Astronomy, Space weather, Solar physics, Corona, law.invention, law, Coronal mass ejection, business, Coronagraph, Eclipse, Remote sensing

Abstract

The "sonic region" of the Sun corona remains extremely difficult to observe with spatial resolution and sensitivity sufficient to understand the fine scale phenomena that govern the quiescent solar corona, as well as phenomena that lead to coronal mass ejections (CMEs), which influence space weather. Improvement on this front requires eclipse-like conditions over long observation times. The space-borne coronagraphs flown so far provided a continuous coverage of the external parts of the corona but their over-occulting system did not permit to analyse the part of the white-light corona where the main coronal mass is concentrated. The proposed PROBA-3 Coronagraph System, also known as ASPIICS (Association of Spacecraft for Polarimetric and Imaging Investigation of the Corona of the Sun), with its novel design, will be the first space coronagraph to cover the range of radial distances between ~1.08 and 3 solar radii where the magnetic field plays a crucial role in the coronal dynamics, thus providing continuous observational conditions very close to those during a total solar eclipse. PROBA-3 is first a mission devoted to the in-orbit demonstration of precise formation flying techniques and technologies for future European missions, which will fly ASPIICS as primary payload. The instrument is distributed over two satellites flying in formation (approx. 150m apart) to form a giant coronagraph capable of producing a nearly perfect eclipse allowing observing the sun corona closer to the rim than ever before. The coronagraph instrument is developed by a large European consortium including about 20 partners from 7 countries under the auspices of the European Space Agency. This paper is reviewing the recent improvements and design updates of the ASPIICS instrument as it is stepping into the detailed design phase.

Published

2015

28. MIDI observations of 1459 Magnya: First attempt of interferometric observations of asteroids with the VLTI

Author

Marco Delbo, Davide Loreggia, Davide Gandolfi, L. Saba, Mario G. Lattanzi, Alberto Cellino, C. Blanco, Sebastiano Ligori, Markus Wittkowski, Massimo Cigna, D. Licchelli, Mario Gai, Laboratoire de Cosmologie, Astrophysique Stellaire & Solaire, de Planétologie et de Mécanique des Fluides (CASSIOPEE), Université Nice Sophia Antipolis (... - 2019) (UNS), COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire de la Côte d'Azur, and Université Côte d'Azur (UCA)-COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-Université Côte d'Azur (UCA)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Physics, Absolute magnitude, Very Large Telescope, 010504 meteorology & atmospheric sciences, MIDI, Astrophysics::Instrumentation and Methods for Astrophysics, Astronomy, Astronomy and Astrophysics, Astrophysics::Cosmology and Extragalactic Astrophysics, computer.file_format, Albedo, 01 natural sciences, Photometry (optics), Interferometry, Space and Planetary Science, Asteroid, Observatory, 0103 physical sciences, Astrophysics::Solar and Stellar Astrophysics, Astrophysics::Earth and Planetary Astrophysics, 010303 astronomy & astrophysics, computer, Astrophysics::Galaxy Astrophysics, 0105 earth and related environmental sciences

Abstract

The Very Large Telescope Interferometer (VLTI) of the European Southern Observatory (ESO) can be used to obtain direct determination of the sizes and the albedos of asteroids. We present results of the first attempt to carry out interferometric observations of asteroids with the Mid Infrared Interferometric Instrument (MIDI) at the VLTI. Our target was 1459 Magnya. This is the only V-type asteroid known to exist in the outer main-belt, and its IRAS-albedo turns out to be rather low for an object of this taxonomic class. Interferometric fringes were not detected, very likely due to the fact that the flux emitted by the asteroid was lower than expected and below the MIDI threshold for fringe detection. However, by fitting the Standard Thermal Model to the N-band infrared flux measured by MIDI in photometric mode and to the visible absolute magnitude, obtained from quasi-simultaneous B- and V-band photometric observations, we have derived a geometric visible albedo of 0.37 ± 0.06 and an effective diameter of 17 ± 1 km. This new estimate of the albedo differs from that previously obtained by IRAS and is more consistent with the V-type taxonomic classification of 1459 Magnya.

Published

2006

29. Chromaticity in all-reflective telescopes for astrometry

Author

Mario G. Lattanzi, D. Busonero, Davide Loreggia, D. Gardiol, and Mario Gai

Subjects

Image formation, Wavefront, Physics, Mathematics::Combinatorics, business.industry, Optical engineering, Astrophysics (astro-ph), Astrophysics::Instrumentation and Methods for Astrophysics, Process (computing), FOS: Physical sciences, Physics::Optics, Astronomy and Astrophysics, Astrometry, Astrophysics, Optics, Space and Planetary Science, Position (vector), Chromatic scale, Chromaticity, business

Abstract

Chromatic effects are usually associated with refractive optics, so reflective telescopes are assumed to be free from them. We show that all-reflective optics still bears significant levels of such perturbations, which is especially critical to modern micro-arcsecond astrometric experiments. We analyze the image formation and measurement process to derive a precise definition of the chromatic variation of the image position, and we evaluate the key aspects of optical design with respect to chromaticity. The fundamental requirement related to chromaticity is the symmetry of the optical design and of the wavefront errors. Finally, we address some optical engineering issues, such as manufacturing and alignment, providing recommendations to minimize the degradation that chromaticity introduces into astrometry., 10 pages, 8 figures

Published

2006

30. The Shadow Positioning Sensors (SPS) for formation flying metrology on-board the ESA-PROBA3 mission

Author

Giuseppe Massone, Gerardo Capobianco, Etienne Renotte, Steve Buckley, Alessandro Bemporad, Marco Romoli, Federico Landini, Silvano Fineschi, Vladimiro Noce, Kevin O'Neill, Cristian Baccani, Cédric Thizy, Davide Loreggia, Jean-Sébastien Servaye, Mauro Focardi, Maurizio Pancrazzi, and Gianalfredo Nicolini

Subjects

Physics, Spacecraft, business.industry, Stray light, Orbital mechanics, law.invention, Entrance pupil, Light intensity, Optics, law, Satellite, business, Coronagraph, Position sensor

Abstract

PROBA3 is an ESA technology mission devoted to in-orbit demonstration of the formation flight (FF) technique, with two satellites kept at an average inter-distance by about 144 m. The ASPIIC instrument on-board PROBA3 will be the first ever space-based coronagraph working on one satellite and having the external occulter located on the second satellite, thus allowing observations of the inner solar corona with unprecedented reduction of stray light. During the observational periods, the FF configuration will be maintained with very high precision and two different techniques will be implemented: the use of Shadow Positioning Sensors (SPS) located on the Coronagraph Spacecraft (diodes measuring the penumbral light intensity on the entrance pupil plane) and the use of Occulter Position Sensor LEDs (OPSE) located on the back side of the Occulter Spacecraft. This paper will review the main instrumental requirements on the SPS needed to determine the 3-dimensional relative positioning of the two PROBA3 satellites with high precision.

Published

2015

31. Formation flying metrology for the ESA-PROBA3 mission: the Shadow Position Sensors (SPS) silicon photomultipliers (SiPMs) readout electronics

Author

Federico Landini, Steve Buckley, Jean-Sébastien Servaye, Etienne Renotte, Vladimiro Noce, Giuseppe Massone, Mauro Focardi, Gerardo Capobianco, Gianalfredo Nicolini, Cédric Thizy, Alessandro Bemporad, Kevin O'Neill, Cristian Baccani, Davide Loreggia, Maurizio Pancrazzi, Silvano Fineschi, and Marco Romoli

Subjects

Physics, business.industry, law.invention, Entrance pupil, Telescope, Light intensity, Optics, Silicon photomultiplier, law, Satellite, business, Coronagraph, Position sensor, Eclipse

Abstract

The European Space Agency (ESA) is planning to launch in 2018 the PROBA3 Mission, designed to demonstrate the inorbit formation flying (FF) attitude capability of its two satellites and to observe the inner part of the visible solar corona as the main scientific objective. The solar corona will be observed thanks to the presence on the first satellite, facing the Sun, of an external occulter producing an artificial eclipse of the Sun disk. The second satellite will carry on the coronagraph telescope and the digital camera system in order to perform imaging of the inner part of the corona in visible polarized light, from 1.08 R⦿ up to about 3 R⦿. One of the main metrological subsystems used to control and to maintain the relative (i.e. between the two satellites) and absolute (i.e. with respect to the Sun) FF attitude is the Shadow Position Sensor (SPS) assembly. It is composed of eight micro arrays of silicon photomultipliers (SiPMs) able to measure with the required sensitivity and dynamic range the penumbral light intensity on the Coronagraph entrance pupil. In the following of the present paper we describe the overall SPS subsystem and its readout electronics with respect to the capability to satisfy the mission requirements, from the light conversion process on board the silicon-based SPS devices up to the digital signal readout and sampling.

Published

2015

32. Significance of the occulter diffraction for the PROBA3/ASPIICS formation flight metrology

Author

Giuseppe Massone, Davide Loreggia, Etienne Renotte, Jean-Sébastien Servaye, Gianalfredo Nicolini, Mauro Focardi, Cédric Thizy, Vladimiro Noce, Cristian Baccani, Maurizio Pancrazzi, Silvano Fineschi, Federico Landini, Alessandro Bemporad, Gerardo Capobianco, and Marco Romoli

Subjects

Diffraction, Physics, Spacecraft, business.industry, Stray light, Aperture, law.invention, Metrology, Telescope, Optics, Silicon photomultiplier, law, business, Coronagraph

Abstract

PROBA-3/ASPIICS is a formation flying coronagraph selected by ESA and currently in its C/D phase. It is constituted by two spacecrafts (OSC, Occulter SpaceCraft, carrying the occulter, diameter 142 cm, and CSC, Coronagraph SpaceCraft, with the telescope) separated by ~144 m, kept in strict alignment by means of an active custom system. The alignment active system most critical components are the Shadow Positioning Sensors (SPS), a series of Si-PM (Silicon Photomultiplier) measuring the penumbra generated by the occulter. The arrangement of the SPSs around the telescope entrance aperture is defined as a trade-off between mechanical constraints and maximum sensitivity to misalignments. The signal detected by the SPSs can be approximately simulated with a geometrical analysis based on the variation of the penumbra generated by the external occulter. The stray light generated by the diffraction from the external occulter may affect the SPSs signal. It is mandatory to carefully evaluate its level in order to refine the active alignment adjustment algorithm. This work is dedicated to the description of the preliminary investigation performed in order to evaluate the impact of the diffraction on the SPSs signal.

Published

2015

33. Active optics system of the ASTRI SST-2M prototype for the Cherenkov Telescope Array

Author

Daniela Fantinel, Luigi Lessio, Federico Russo, Gerardo Capobianco, G. Rodeghiero, Enrico Giro, Antonio Volpicelli, Davide Loreggia, and Daniele Gardiol

Subjects

Physics, Reflecting telescope, business.industry, Astrophysics::High Energy Astrophysical Phenomena, Astrophysics::Instrumentation and Methods for Astrophysics, Astronomy, Active optics, Cherenkov Telescope Array, law.invention, Telescope, Primary mirror, Tilt (optics), Optics, law, Astrophysics::Earth and Planetary Astrophysics, Secondary mirror, business, Cherenkov radiation

Abstract

ASTRI (Astrofisica con Specchi a Tecnologia Replicante Italiana) SST-2M is an end-to-end prototype of Small Size class of Telescope for the Cherenkov Telescope Array. It will apply a dual mirror configuration to Imaging Atmospheric Cherenkov Telescopes. The 18 segments composing the primary mirror (diameter 4.3 m) are equipped with an active optics system enabling optical re-alignment during telescope slew. The secondary mirror (diameter 1.8 m) can be moved along three degrees of freedom to perform focus and tilt correc tions. We describe the kinematic model used to predict the system performance as well as the hardware and software de sign solution that will be implemented for optics control. Keywords: Imaging Atmospheric Cherenkov Telescope, CTA, ASTRI, gamma-rays, active optics 1. INTRODUCTION The dual-mirror ASTRI (Astrofisica con Specchi a Tecnologia Replicante Italiana) Small Size Telescope prototype, named ASTRI SST-2M, is a wide field of view Schwarzschild-Couder Cherenkov telescope developed within the Cherenkov Telescope Array (CTA) framework

Published

2014

34. Active optics system of the ASTRI SST-2M prototype for the Cherenkov Telescope ArrayAdvances in Optical and Mechanical Technologies for Telescopes and Instrumentation

Author

Ramón, Navarro, Cunningham, Colin R., Barto, Allison A., Daniele, Gardiol, Gerardo, Capobianco, Daniela, Fantinel, Enrico, Giro, Luigi, Lessio, Davide, Loreggia, Rodeghiero, Gabriele, Federico, Russo, and Volpicelli, Antonio C.

Published

2014

35. Improved stray light suppression performance for the solar orbiter/METIS inverted external occulter

Author

Maurizio Pancrazzi, C. Escolle, Silvano Fineschi, Gerardo Capobianco, Giuseppe Massone, Enzo Turchi, Mauro Focardi, Christophe Guillon, Federico Landini, Marco Romoli, S. Vives, and Davide Loreggia

Subjects

Physics, business.industry, Stray light, Curved mirror, law.invention, Entrance pupil, Telescope, Orbiter, Optics, law, Thermal, business, Coronagraph, Conic optimization

Abstract

The Solar Orbiter/METIS visible and UV coronagraph introduces the concept of occulter inversion in solar coronagraphy. Classical externally occulted coronagraphs usually have a disk in front of the telescope entrance pupil. According to the mission requirements, in order to reduce the amount of power entering the instrument and to limit the instrument dimensions, METIS is equipped with an inverted external occulter (IEO). The IEO consists of a circular aperture on the Solar Orbiter thermal shield that acts as coronagraph entrance pupil. A spherical mirror (M0), located ~800 mm behind the IEO, rejects back the disk-light through the IEO itself. A light-tight boom connects the IEO to the M0 through the thermal shield. In order to achieve high performance in stray light suppression, the IEO design needs optimization. Due to the novelty of the concept we can only use the heritage of past space-borne coronagraph occulters as a starting point to design a dedicated occulter optimization shape. A 1.5 years long, accurate test campaign has been carried out to evaluate the best optimization configuration for the IEO. Two prototypes were manufactured to take into account the impact of the boom geometry on the stray light suppression performance. Two optimization concepts were compared: the inverted cone (that derives from the conic optimization of classical occulting disks) and the serrated edge, of which several samples were manufactured, with different geometrical parameters, surface roughnesses and coatings. This work summarizes the activity we have been carrying on to define the flight specifications for the METIS occulter.

Published

2013

36. Modeling for instrument diagnostics: Gaia non-nominal configurations impact on astrometric performance

Author

Alberto Riva, Davide Loreggia, and Deborah Busonero

Subjects

Computer science, Payload, Systems engineering, Calibration, Context (language use), Field (computer science), Simulation

Abstract

The Gaia payload is a highly sophisticated system and many of its instrumental behaviors will be tested at proper accuracy only during the operational phase. However simulation results are critical parts for developing system integration, as well as for understanding unexpected behavior during commissioning and operations. The data analysis procedures are sensitive to several instrument parameters, as their variation over the field and with time. We focused our dissertation on the study and analysis of non-nominal configurations effects on astrometric accuracy, putting also in evidence the level of the effects that the difference between the design data and as-built data can produce if not adequately taken into account. We identify and quantify the effects. We move from this forward analysis to look at the data and perform instrument monitoring and diagnostic procedures, an essential activity for the verification of GAIA measurements. We conducted the study in the context of the Astrometric Verification Unit.

Published

2012

37. GAIA mock-up: an educational demonstrative GAIA model

Author

Alberto Riva, Mario G. Lattanzi, Mario Gai, Maria Teresa Crosta, Isidoro Sciarratta, and Davide Loreggia

Subjects

Physics, Payload, business.industry, Astrometry, law.invention, Telescope, Interferometry, Fringe pattern, Mockup, law, Measuring principle, Aerospace engineering, business, Laser beams, Remote sensing

Abstract

Gaia is ESA's next-generation space mission aimed at global astrometry at the microarcsecond level. Its science case is devoted to the understanding of our Galaxy's structure, evolution and composition. The GAIA payload includes two identical telescopes separated by a Basic Angle whose variations in time must be measured with very high accuracy, to fulll the astrometry goal. To this purpose, an interferometric sub-system, the Basic Angle Monitoring Device (BAMD), has been introduced. The BAMD optical concept is based on a pair of laser beams per telescope, producing fringes on a dedicated CCD. The basic measurement principle of BAMD consists in monitoring the stability of the fringe pattern phase. We are developing a demonstrator of the BAMD for educational purposes, considered representative of the driving design concept for the Gaia microarcsecond astrometry. In this paper we describe the design guidelines and analyze some of the key elements related to the demonstration of the basic angle monitoring concept.

Published

2012

38. ISAS: interferometric stratospheric astrometry for solar system

Author

Davide Loreggia, Mario G. Lattanzi, S. Chaillot, Mario Gai, Sebastiano Ligori, Daniele Gallieni, A. Fienga, Alberto Vecchiato, and Alberto Riva

Subjects

Physics, Solar System, Fizeau interferometer, Aperture, Conjunction (astronomy), Astrophysics::Instrumentation and Methods for Astrophysics, Astronomy, Astrometry, Orbital mechanics, Interferometry, Planet, Astrophysics::Solar and Stellar Astrophysics, Astrophysics::Earth and Planetary Astrophysics, Astrophysics::Galaxy Astrophysics

Abstract

The Interferometric Stratospheric Astrometry for Solar system (ISAS) project is designed for high precision astrometry on the brightest planets of the Solar System, with reference to many field stars, at the milli-arcsec (mas) level or better. The science goal is the improvement on our knowledge of the dynamics of the Solar System, complementing the Gaia observations of fainter objects. The technical goal is the validation of basic concepts for the proposed Gamma Astrometric Measurement Experiment (GAME) space mission, in particular, combination of Fizeau interferometry and coronagraphic techniques by means of pierced mirrors, intermediate angle dual field astrometry, smart focal plane management for increased dynamic range and pointing correction. We discuss the suitability of the stratospheric environment, close to space conditions, to the astrometric requirements. The instrument concept is a multiple field, multiple aperture Fizeau interferometer, observing simultaneously four fields, in order to improve on the available number of reference stars. Coronagraphic solutions are introduced to allow observation of internal planets (Mercury and Venus), as well as of external planets over a large fraction of their orbit, i.e. also close to conjunction with the Sun. We describe the science motivation, the proposed experiment profile and the expected performance.

Published

2012

39. Gravitation Astrometric Measurement Experiment (GAME)

Author

Mariateresa Crosta, Deborah Busonero, Sebastiano Ligori, Mario Gai, Davide Loreggia, Mario G. Lattanzi, Alberto Vecchiato, Alberto Riva, and A. Fienga

Subjects

Gravitation, Physics, Interferometry, Solar System, Optics, business.industry, General relativity, Measuring principle, Astrophysics::Instrumentation and Methods for Astrophysics, Dark energy, Astrometry, business, Image resolution

Abstract

GAME is a recent concept for a small/medium class mission aimed at Fundamental Physics tests in the Solar system, by means of an optimised instrument in the visible, based on smart combination of coronagraphy and Fizeau interferometry. The targeted precision on the γ and β parameters of the Parametrised Post-Newtonian formulation of General Relativity are respectively in the 10 -7 -10 -8 and 10 -5 -10 -6 range, improving by one or two orders of magnitude with respect to the expectations on current or near future experiments. Such precision is suitable to detect possible deviations from the unity value, associated to generalised Einstein models for gravitation, with potentially huge impacts on the cosmological distribution of dark matter and dark energy from a Solar system scale experiment. The measurement principle is based on the differential astrometric signature on the stellar positions, i.e. based on the spatial component of the effect rather than the temporal component as in the most recent experiments using radio link delay timing variation (Cassini). The instrument concept is based on multiple field, multiple aperture Fizeau interferometry, observing simultaneously regions close to the Solar limb (requiring the adoption of coronagraphic techniques), and others in opposition to the Sun. The diluted optics approach is selected for achieving an efficient rejection of the scattered solar radiation, while retaining an acceptable angular resolution on the science targets. The multiple field observation is aimed at cost-effective control of systematic effects through simultaneous calibration. We describe the science motivation, the proposed mission profile, the instrument concept and the expected performance.

Published

2012

40. Astrometric instrument model software tool for Gaia data reduction: challenges and implementation

Author

Federico Russo, D. Bonino, Alberto Riva, Mario G. Lattanzi, Deborah Busonero, Davide Loreggia, Leonardo Corcione, and Mario Gai

Subjects

Signal processing, Relation (database), Process (engineering), Computer science, Real-time computing, Calibration, Astrometry, Sensitivity (control systems), Simulation, Data reduction

Abstract

The Astrometric Instrument Model system comprises several monitoring and diagnostic tasks for the astrometric instrument aboard Gaia. It is a hierarchy of dedicated software modules aimed at decreasing the parameter degeneration of the relation linking the observations to the instrumental behavior, and optimize the estimation process at the CCD and field-of-view crossing level. Critical for the system is the definition and maintenance of a physical instrument model fitting the science data, and able to accommodate non nominal configurations. Precise modeling of the astrometric response is required for optimal definition of the data reduction and calibration algorithms, and to ensure high sensitivity to both instrumental and astrophysical source parameters.

Published

2010

41. Design of a four-mirror astrometric telescope for light bending measurements

Author

Sebastiano Ligori, Mario G. Lattanzi, Davide Loreggia, Mario Gai, and Alberto Vecchiato

Subjects

Physics, Fizeau interferometer, Stray light, business.industry, Astrophysics::Instrumentation and Methods for Astrophysics, Cassegrain reflector, Astrometry, law.invention, Telescope, Primary mirror, Interferometry, Optics, law, Focal length, business

Abstract

We present a new design of a four mirrors telescope for astrometric measurement to be used in the GAME mission, currently under study at the Astronomical Observatory of Turin, Italy. The main aim of GAME - Gamma Astrometric Measurement Experiment - is to measure the γ parameter of the Parameterized Post- Newtonian formulation by looking at the deflection of light produced by the Sun's gravitational curvature, as in the Dyson, Eddington et al. 1919 experiment, using a dedicated, space based dual-field telescope. A first design has been presented in recent years, based on a Cassegrain scheme with a mask in front of the primary mirror to realize multiple aperture Fizeau interferometry. The new design still implements a Fizeau interferometer, but the telescope layout is based on a Korsch-like scheme with four conical mirrors, long focal length, and without the use of exotic surfaces (aspheric or polynomial) as adopted in other long focal astrometric instruments. A different combination scheme of the two lines of sight makes the dimensioning of the primary mirror more relaxed allowing us to work with smaller surfaces and therefore to achieve a more compact payload configuration. The design of the instrument and the masked interferometry approach allow us to maximize the astrometric performances and at the same time to improve the baffling, minimizing the amount of stray light from the Sun. In this paper we describe the mission profile, the observation principle, the new instrument layout and the expected performances.

Published

2010

42. System overview of the VLTI Spectro-Imager

Author

Fabien Malbet, Udo Beckmann, Philippe Feautrier, Christopher A. Haniff, Dario Lorenzetti, J.-B. Le Bouquin, A. Chelli, Mario Gai, P. Kern, Gerard Zins, Karine Perraut, José Manuel Rebordão, Leonardo Corcione, P. Rabou, Gaspard Duchêne, Olivier Absil, Gerd Weigelt, David F. Buscher, Davide Loreggia, Alain Delboulbé, E. Herwats, Jorge Lima, E. Le Coarer, Jean-Phillipe Berger, Pierre Labeye, G. Li Causi, Myriam Benisty, António Amorim, Sebastiano Ligori, John Young, Paulo J. V. Garcia, Laurent Jocou, and Gilles Duvert

Subjects

Physics, Scientific instrument, Very Large Telescope, Astrophysics (astro-ph), Astrophysics::Instrumentation and Methods for Astrophysics, FOS: Physical sciences, Astrophysics, Interferometry, Temporal resolution, Closure phase, Angular resolution, Spectral resolution, Spectrograph, Remote sensing

Abstract

The VLTI Spectro Imager project aims to perform imaging with a temporal resolution of 1 night and with a maximum angular resolution of 1 milliarcsecond, making best use of the Very Large Telescope Interferometer capabilities. To fulfill the scientific goals (see Garcia et. al.), the system requirements are: a) combining 4 to 6 beams; b) working in spectral bands J, H and K; c) spectral resolution from R= 100 to 12000; and d) internal fringe tracking on-axis, or off-axis when associated to the PRIMA dual-beam facility. The concept of VSI consists on 6 sub-systems: a common path distributing the light between the fringe tracker and the scientific instrument, the fringe tracker ensuring the co-phasing of the array, the scientific instrument delivering the interferometric observables and a calibration tool providing sources for internal alignment and interferometric calibrations. The two remaining sub-systems are the control system and the observation support software dedicated to the reduction of the interferometric data. This paper presents the global concept of VSI science path including the common path, the scientific instrument and the calibration tool. The scientific combination using a set of integrated optics multi-way beam combiners to provide high-stability visibility and closure phase measurements are also described. Finally we will address the performance budget of the global VSI instrument. The fringe tracker and scientific spectrograph will be shortly described.

Published

2008

43. Multiple beam combination experiments for fringe tracking on next generation interferometers

Author

Giuseppe Massone, Davide Loreggia, Leonardo Corcione, Sebastiano Ligori, and Mario Gai

Subjects

business.industry, Computer science, Astrophysics::Instrumentation and Methods for Astrophysics, Tracking (particle physics), Set (abstract data type), Interferometry, Optics, Observatory, Astronomical interferometer, Multiple beam, Sensitivity (control systems), business, Throughput (business), Beam (structure)

Abstract

In this paper we present the status of different experiments set up at Turin Observatory on novel techniques for multiple beam combination, adopting mostly bulk optics. The goal of these experiments is to find the best scheme able to perform efficient fringe tracking operation on a densely populated (N>4) interferometer, while at the same time maximizing optical throughput and sensitivity on faint sources. One of these concepts has been proposed for the VSI fringe tracker (see Corcione et al, this conference). The schemes proposed have also the advantage of being in principle easily adapted to a large number of beams.

Published

2008

44. Near-IR spectrograph of VSI (VLTI Spectro Imager): dispersing the light from an integrated optics beam-combiner

Author

P. Kern, Laurent Jocou, Fabrizio Vitali, Carlo Baffa, Fabien Malbet, Roberto Speziali, Dario Lorenzetti, Davide Loreggia, G. Li Causi, and Patrick Rabou

Subjects

Cryostat, Physics, business.industry, Astrophysics (astro-ph), Astrophysics::Instrumentation and Methods for Astrophysics, FOS: Physical sciences, Astrophysics, Interferometry, Optics, Sampling (signal processing), Astrophysics::Solar and Stellar Astrophysics, Ir detector, Integrated optics, Astrophysics::Earth and Planetary Astrophysics, business, Spectrograph, Beam (structure)

Abstract

We present the optical and cryo-mechanical solutions for the Spectrograph of VSI (VLTI Spectro-Imager), the second generation near-infrared (J, H and K bands) interferometric instrument for the VLTI. The peculiarity of this spectrograph is represented by the Integrated Optics (IO) beam-combiner, a small and delicate component which is located inside the cryostat and makes VSI capable to coherently combine 4, 6 or even 8 telescopes. The optics have been specifically designed to match the IO combiner output with the IR detector still preserving the needed spatial and spectral sampling, as well as the required fringe spacing. A compact device that allows us to interchange spectral resolutions (from R=200 to R=12000), is also presented., 12 pages, 11 figures, SPIE Conference - Marseille 2008

Published

2008

45. Fringe tracker for the VLTI spectro-imager

Author

Mario Gai, Davide Loreggia, Leonardo Corcione, D. Bonino, G. Masssone, D. F. Busher, John Young, and Sebastiano Ligori

Subjects

Physics, Very Large Telescope, business.industry, Astrophysics (astro-ph), Astrophysics::Instrumentation and Methods for Astrophysics, FOS: Physical sciences, Astrophysics, Image synthesis, k-nearest neighbors algorithm, Interferometry, Optics, Three-phase, Scalability, Redundancy (engineering), business

Abstract

The implementation of the simultaneous combination of several telescopes (from four to eight) available at Very Large Telescope Interferometer (VLTI) will allow the new generation interferometric instrumentation to achieve interferometric image synthesis with unprecedented resolution and efficiency. The VLTI Spectro Imager (VSI) is the proposed second-generation near-infrared multi-beam instrument for the Very Large Telescope Interferometer, featuring three band operations (J, H and K), high angular resolutions (down to 1.1 milliarcsecond) and high spectral resolutions. VSI will be equipped with its own internal Fringe Tracker (FT), which will measure and compensate the atmospheric perturbations to the relative beam phase, and in turn will provide stable and prolonged observing conditions down to the magnitude K=13 for the scientific combiner. In its baseline configuration, VSI FT is designed to implement, from the very start, the minimum redundancy combination in a nearest neighbor scheme of six telescopes over six baselines, thus offering better options for rejection of large intensity or phase fluctuations over each beam, due to the symmetric set-up. The planar geometry solution of the FT beam combiner is devised to be easily scalable either to four or eight telescopes, in accordance to the three phase development considered for VSI. The proposed design, based on minimum redundancy combination and bulk optics solution, is described in terms of opto-mechanical concept, performance and key operational aspects., Comment: 11 pages, to be published in Proc. SPIE conference 7013 "Optical and Infrared Interferometry", Schoeller, Danchi, and Delplancke, F. (eds.)

Published

2008

46. VSI: the VLTI spectro-imager

Author

Uwe Beckmann, Fabien Malbet, Romano L. M. Corradi, A. Delboulbe, P. Kern, José Manuel Rebordão, André Moitinho, J.-B. Le Bouquin, Karl-Heinz Hofmann, Christopher A. Haniff, Gaspard Duchene, Leonardo Testi, Thomas Beckert, Sebastiano Ligori, Gilles Duvert, J. Lima, Myriam Benisty, Alessandro Marconi, T. Forveille, Éric Thiébaut, O. Chesneau, Andrea Chiavassa, P.-O. Petrucci, A. Cabral, Emilie Herwats, Alain Chelli, Gérard Zins, B. Aringer, Fabrizio Vitali, Olivier Absil, John Young, Dario Lorenzetti, Xavier Bonfils, M. De Becker, Brunella Nisini, E. Le Coarer, K. Perraut, Jean-Phillipe Berger, Mario Gai, J. Hron, Leonardo Corcione, Davide Loreggia, Mercedes E. Filho, G. Li Causi, António Amorim, Paulo J. V. Garcia, E. Tatulli, Jean Surdej, Gerd Weigelt, David F. Buscher, Roberto Speziali, R. Neuhaeuser, Laurent Jocou, P. Labeye, Laboratoire d'Astrophysique de Grenoble (LAOG), Université Joseph Fourier - Grenoble 1 (UJF)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS), Cavendish Laboratory, University of Cambridge [UK] (CAM), Max-Planck-Institut für Radioastronomie (MPIFR), Centro de Astrofísica da Universidade do Porto (CAUP), Universidade do Porto, INAF - Osservatorio Astrofisico di Torino (OATo), Istituto Nazionale di Astrofisica (INAF), INAF - Osservatorio Astronomico di Roma (OAR), Institut d'Astrophysique et de Géophysique [Liège], Université de Liège, Institut für Astronomie, Universität Wien (IFA), Universität Wien, Astrophysikalisches Institut und Universitäts-Sternwarte (AIU), Friedrich-Schiller-Universität = Friedrich Schiller University Jena [Jena, Germany], Jean-Marie Mariotti Center (JMMC), Centre National de la Recherche Scientifique (CNRS), Commissariat à l'énergie atomique et aux énergies alternatives - Laboratoire d'Electronique et de Technologie de l'Information (CEA-LETI), Direction de Recherche Technologique (CEA) (DRT (CEA)), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA), SIM/IDL Faculdade de Ciências da Universidade de Lisboa (FCUL), University of Lisboa, Centre de Recherche Astrophysique de Lyon (CRAL), École normale supérieure - Lyon (ENS Lyon)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences de l'Univers (INSU - CNRS), Instituto Nacional de Engenharia, Tecnologia e Inovacao (INETI), Laboratoire Hippolyte Fizeau (FIZEAU), Université Nice Sophia Antipolis (... - 2019) (UNS), COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire de la Côte d'Azur, Université Côte d'Azur (UCA)-COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-Université Côte d'Azur (UCA)-Centre National de la Recherche Scientifique (CNRS), Groupe de Recherche en Astronomie et Astrophysique du Languedoc (GRAAL), Université Montpellier 2 - Sciences et Techniques (UM2)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS), Instituto de Astrofisica de Canarias (IAC), European Southern Observatory (ESO), INAF - Osservatorio Astrofisico di Arcetri (OAA), VSI consortium, Universidade do Porto = University of Porto, École normale supérieure de Lyon (ENS de Lyon)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS), Université Nice Sophia Antipolis (1965 - 2019) (UNS), and COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-Université Côte d'Azur (UCA)-Université Côte d'Azur (UCA)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Active galactic nucleus, interferometer, FOS: Physical sciences, Astrophysics, Astrophysics::Cosmology and Extragalactic Astrophysics, Compact star, 01 natural sciences, 7. Clean energy, 010309 optics, [PHYS.ASTR.CO]Physics [physics]/Astrophysics [astro-ph]/Cosmology and Extra-Galactic Astrophysics [astro-ph.CO], compact astrophysical ob jects, Planet, 0103 physical sciences, Astrophysics::Solar and Stellar Astrophysics, Angular resolution, Spectral resolution, 010303 astronomy & astrophysics, Astrophysics::Galaxy Astrophysics, Physics, instrumentation, Very Large Telescope, Supermassive black hole, Astrophysics (astro-ph), Astrophysics::Instrumentation and Methods for Astrophysics, Astronomy, interferometry, Stars, infrared, Astrophysics::Earth and Planetary Astrophysics, high angular resolution

Abstract

The VLTI Spectro Imager (VSI) was proposed as a second-generation instrument of the Very Large Telescope Interferometer providing the ESO community with spectrally-resolved, near-infrared images at angular resolutions down to 1.1 milliarcsecond and spectral resolutions up to R=12000. Targets as faint as K=13 will be imaged without requiring a brighter nearby reference object. The unique combination of high-dynamic-range imaging at high angular resolution and high spectral resolution enables a scientific program which serves a broad user community and at the same time provides the opportunity for breakthroughs in many areas of astrophysic including: probing the initial conditions for planet formation in the AU-scale environments of young stars; imaging convective cells and other phenomena on the surfaces of stars; mapping the chemical and physical environments of evolved stars, stellar remnants, and stellar winds; and disentangling the central regions of active galactic nuclei and supermassive black holes. VSI will provide these new capabilities using technologies which have been extensively tested in the past and VSI requires little in terms of new infrastructure on the VLTI. At the same time, VSI will be able to make maximum use of new infrastructure as it becomes available; for example, by combining 4, 6 and eventually 8 telescopes, enabling rapid imaging through the measurement of up to 28 visibilities in every wavelength channel within a few minutes. The current studies are focused on a 4-telescope version with an upgrade to a 6-telescope one. The instrument contains its own fringe tracker and tip-tilt control in order to reduce the constraints on the VLTI infrastructure and maximize the scientific return., 12 pages, to be published in Proc. SPIE conference 7013 "Optical and Infrared Interferometry", Schoeller, Danchi, and Delplancke, F. (eds.). See also http://vsi.obs.ujf-grenoble.fr

Published

2008

47. Observation of Asteroids with the VLTI

Author

Markus Wittkowski, Marco Delbo, L. Saba, Alberto Cellino, Mario G. Lattanzi, Davide Loreggia, Mario Gai, and Sebastiano Ligori

Subjects

Thermal infrared, law, Asteroid, Polarimetry, Astronomy, Radar, Reliability (statistics), Minor planet, Geology, law.invention, Remote sensing

Abstract

We briefly discuss the capabilities of VLTI to obtain direct measurement of the sizes of asteroids. VLTI can play a crucial role in the study of interesting cases and to assess the reliability of thermal infrared, polarimetric and radar models.

Published

2007

48. Fizeau interferometry from space: a challenging frontier in global astrometry

Author

Deborah Busonero, Mario G. Lattanzi, Mario Gai, Daniele Gardiol, and Davide Loreggia

Subjects

Physics, Fizeau interferometer, Interferometry, Optics, business.industry, Astronomical interferometer, Focal length, Context (language use), Field of view, Astrometry, business, Space exploration

Abstract

The design and performance of a Fizeau interferometer with long focal length and large field of view are discussed. The optical scheme presented is well suited for very accurate astrometric measurements from space, being optimised, in terms of geometry and aberrations, to observe astronomical targets down to the visual magnitude mV=20, with a measurement accuracy of 10 microarcseconds at mV=15. This study is in the context of the next generation astrometric space missions, in particular for a mission profile similar to that of the Gaia mission of the European Space Agency. Beyond the accuracy goal, the great effort in optical aberrations reduction, particularly distortion, aims at the optimal exploitation of data acquisition done with CCD arrays working in Time Delay Integration mode. The design solution we present reaches the astrometric goals with a field of view of 0.5 square degrees.

Published

2004

49. End-to-end optomechanical simulation for high-precision global astrometry

Author

Mario Gai, Daniele Gardiol, Luca Perachino, Davide Loreggia, Sergio Mannu, S. Mottini, and Mario G. Lattanzi

Subjects

Physics, Telescope, Sight, Software, Optics, End-to-end principle, business.industry, law, Software tool, Astrometry, business, law.invention

Abstract

We describe a software tool developed to simulate the behaviour of the angle between two lines of sight in a dual view telescope assembly (usually referred to as basic angle) due to optical misalignments induced by thermo-mechanical fluctuations. The tool applies to a variety of reflective optical designs. In principle, not only the basic angle behaviour can be simulated, but also other optical parameters. As a practical example, we present and discuss results obtained from application of our software to the case of the Gaia baseline optical design. We show that the final error can be severely degraded by fluctuations of the basic angle due to thermo-mechanical effects.

Published

2004

50. SPECTRE: a spectro-heliograph for the transition region

Author

Marco Malvezzi, D. Moses, Daniele Gardiol, Silvano Fineschi, P. Nicolosi, Ester Antonucci, Giampiero Naletto, Marco Romoli, Russell A. Howard, L. Zangrilli, V. Da Deppo, and Davide Loreggia

Subjects

Physics, Solar dynamics observatory, Solar transition region, Astronomy, Solar atmosphere, Heliograph

Abstract

The SPECtro-heliograph for the Transition REgion (SPECTRE) experiment is one of the instruments of the Solar Heliospheric Activity Research and Prediction Program (SHARPP) suite initially foreseen aboard the NASA mission Solar Dynamics Observatory (SDO) of the International Living With a Star (ILWS) program. The scientific objective of the SPECTRE experiment was to characterize the rapid evolution of plasma in the transition region of the solar atmosphere, producing full-disk 1.2 arcsec-resolution images of the solar atmosphere at the very critical 63 nm OV spectral line, characterizing a solar plasma temperature of about 250,000 K. Unfortunately, NASA very recently and unexpectedly, during the instrument Phase A study, decided not to proceed with the realization of SHARPP. The authors of this paper think that all the work done so far in the definition of SPECTRE should not be lost. So, they have decided to summarize in this paper the main characteristics of this instrument and the results of the analysis so far performed: the hope is that in a next future this work can be used again for realizing an instrument having similar characteristics.

Published

2004