SHARK-NIR: from design to installation, ready to dive into first light

M. Bergomi; L. Marafatto; E. Carolo; D. Greggio; D. Ricci; D. Vassallo; L. Lessio; K. K. Radhakrishnan Santhakumari; G. Umbriaco; M. Dima; S. Di Filippo; V. D’Orazi; D. Mesa; M. Montoya; L. Mohr; V. Viotto; A. Baruffolo; F. Biondi; S. Chavan; S. Chinellato; M. De Pascale; K. W. Don; P. Grenz; F. Laudisio; J. Leisenrin; R. Ragazzoni; F. Pedichini; R. Piazzesi; E. Pinna; A. Puglisi; A. Bianco; A. Carlotti; C. Knapic; M. Vicinanza; A. Zanutta; J. Christou; A. Conrad; L. Funk; C. Veillet; J. Farinato

doi:10.1117/12.2629388

SHARK-NIR: from design to installation, ready to dive into first light

M. Bergomi, L. Marafatto, E. Carolo, D. Greggio, D. Ricci, D. Vassallo, L. Lessio, K. K. Radhakrishnan Santhakumari, G. Umbriaco, M. Dima, S. Di Filippo, V. D’Orazi, D. Mesa, M. Montoya, L. Mohr, V. Viotto, A. Baruffolo, F. Biondi, S. Chavan, S. ChinellatoM. De Pascale, K. W. Don, P. Grenz, F. Laudisio, J. Leisenrin, R. Ragazzoni, F. Pedichini, R. Piazzesi, E. Pinna, A. Puglisi, A. Bianco, A. Carlotti, C. Knapic, M. Vicinanza, A. Zanutta, J. Christou, A. Conrad, L. Funk, C. Veillet, J. Farinato

Steward Observatory

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

3 Scopus citations

Abstract

SHARK-NIR is a near-infrared (0.96-1.7µm) coronagraphic camera with low-resolution spectroscopic capability designed to exploit the excellent performances, in terms of resolution and contrast, of the LBT Adaptive Optics system SOUL (recently commissioned). Second generation instrument of the LBT, SHARK-NIR left 5 years ago its paper and models realm to become a real working instrument, through realization and testing of single components at first and then the full AIV of the system. Its compact size is a consequence of the available volume and required stiffness, but shall not convince you of a simple opto-mechanical design, translating in requirements for all the interconnected fields of software, electronics, archiving, etc. The instrument is equipped with a cryostat containing the H2RG detector, several custom made optics and motors to operate the instrument, like de-rotator, wheels (to introduce filters, coronographic masks, prisms for spectroscopy), ADC stages, linear stages and actuators for calibration and alignment to star purposes. Its main science target is the detection and characterization of exoplanets, to be achieved through a set of different coronagraphic techniques. However, the analysis and study of protoplanetary disks, stellar jets, AGN, QSOs and solar system bodies are also foreseen scientific cases of the instrument. Coupled with its visible counterpart SHARK-VIS, it will offer the possibility to perform binocular observations in a wide wavelength domain (0.5µm to 1.7µm). In this paper we will report the main steps that let SHARK-NIR become a real instrument with laboratory validated performances, including procurement and shipment, the lessons learned and the upcoming path towards commissioning, focusing on the coordination, interfaces and interactions of all the different involved fields, expertise and institutes of the consortium as well as of the hosting telescope.

Original language	English (US)
Title of host publication	Modeling, Systems Engineering, and Project Management for Astronomy X
Editors	George Z. Angeli, Philippe Dierickx
Publisher	SPIE
ISBN (Electronic)	9781510653559
DOIs	https://doi.org/10.1117/12.2629388
State	Published - 2022
Event	Modeling, Systems Engineering, and Project Management for Astronomy X 2022 - Montreal, Canada Duration: Jul 17 2022 → Jul 22 2022

Publication series

Name	Proceedings of SPIE - The International Society for Optical Engineering
Volume	12187
ISSN (Print)	0277-786X
ISSN (Electronic)	1996-756X

Conference

Conference	Modeling, Systems Engineering, and Project Management for Astronomy X 2022
Country/Territory	Canada
City	Montreal
Period	7/17/22 → 7/22/22

Keywords

commissioning
coronagraphy
exoplanets
ground-based
instrumentation
procurement
project management
shipment

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Condensed Matter Physics
Computer Science Applications
Applied Mathematics
Electrical and Electronic Engineering

Access to Document

10.1117/12.2629388

Cite this

Bergomi, M., Marafatto, L., Carolo, E., Greggio, D., Ricci, D., Vassallo, D., Lessio, L., Radhakrishnan Santhakumari, K. K., Umbriaco, G., Dima, M., Di Filippo, S., D’Orazi, V., Mesa, D., Montoya, M., Mohr, L., Viotto, V., Baruffolo, A., Biondi, F., Chavan, S., ... Farinato, J. (2022). SHARK-NIR: from design to installation, ready to dive into first light. In G. Z. Angeli, & P. Dierickx (Eds.), Modeling, Systems Engineering, and Project Management for Astronomy X Article 1218709 (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 12187). SPIE. https://doi.org/10.1117/12.2629388

SHARK-NIR: from design to installation, ready to dive into first light. / Bergomi, M.; Marafatto, L.; Carolo, E. et al.
Modeling, Systems Engineering, and Project Management for Astronomy X. ed. / George Z. Angeli; Philippe Dierickx. SPIE, 2022. 1218709 (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 12187).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Bergomi, M, Marafatto, L, Carolo, E, Greggio, D, Ricci, D, Vassallo, D, Lessio, L, Radhakrishnan Santhakumari, KK, Umbriaco, G, Dima, M, Di Filippo, S, D’Orazi, V, Mesa, D, Montoya, M, Mohr, L, Viotto, V, Baruffolo, A, Biondi, F, Chavan, S, Chinellato, S, De Pascale, M, Don, KW, Grenz, P, Laudisio, F, Leisenrin, J, Ragazzoni, R, Pedichini, F, Piazzesi, R, Pinna, E, Puglisi, A, Bianco, A, Carlotti, A, Knapic, C, Vicinanza, M, Zanutta, A, Christou, J, Conrad, A, Funk, L, Veillet, C & Farinato, J 2022, SHARK-NIR: from design to installation, ready to dive into first light. in GZ Angeli & P Dierickx (eds), Modeling, Systems Engineering, and Project Management for Astronomy X., 1218709, Proceedings of SPIE - The International Society for Optical Engineering, vol. 12187, SPIE, Modeling, Systems Engineering, and Project Management for Astronomy X 2022, Montreal, Canada, 7/17/22. https://doi.org/10.1117/12.2629388

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abstract = "SHARK-NIR is a near-infrared (0.96-1.7µm) coronagraphic camera with low-resolution spectroscopic capability designed to exploit the excellent performances, in terms of resolution and contrast, of the LBT Adaptive Optics system SOUL (recently commissioned). Second generation instrument of the LBT, SHARK-NIR left 5 years ago its paper and models realm to become a real working instrument, through realization and testing of single components at first and then the full AIV of the system. Its compact size is a consequence of the available volume and required stiffness, but shall not convince you of a simple opto-mechanical design, translating in requirements for all the interconnected fields of software, electronics, archiving, etc. The instrument is equipped with a cryostat containing the H2RG detector, several custom made optics and motors to operate the instrument, like de-rotator, wheels (to introduce filters, coronographic masks, prisms for spectroscopy), ADC stages, linear stages and actuators for calibration and alignment to star purposes. Its main science target is the detection and characterization of exoplanets, to be achieved through a set of different coronagraphic techniques. However, the analysis and study of protoplanetary disks, stellar jets, AGN, QSOs and solar system bodies are also foreseen scientific cases of the instrument. Coupled with its visible counterpart SHARK-VIS, it will offer the possibility to perform binocular observations in a wide wavelength domain (0.5µm to 1.7µm). In this paper we will report the main steps that let SHARK-NIR become a real instrument with laboratory validated performances, including procurement and shipment, the lessons learned and the upcoming path towards commissioning, focusing on the coordination, interfaces and interactions of all the different involved fields, expertise and institutes of the consortium as well as of the hosting telescope.",

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author = "M. Bergomi and L. Marafatto and E. Carolo and D. Greggio and D. Ricci and D. Vassallo and L. Lessio and {Radhakrishnan Santhakumari}, {K. K.} and G. Umbriaco and M. Dima and {Di Filippo}, S. and V. D{\textquoteright}Orazi and D. Mesa and M. Montoya and L. Mohr and V. Viotto and A. Baruffolo and F. Biondi and S. Chavan and S. Chinellato and {De Pascale}, M. and Don, {K. W.} and P. Grenz and F. Laudisio and J. Leisenrin and R. Ragazzoni and F. Pedichini and R. Piazzesi and E. Pinna and A. Puglisi and A. Bianco and A. Carlotti and C. Knapic and M. Vicinanza and A. Zanutta and J. Christou and A. Conrad and L. Funk and C. Veillet and J. Farinato",

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doi = "10.1117/12.2629388",

language = "English (US)",

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AU - Bergomi, M.

AU - Marafatto, L.

AU - Carolo, E.

AU - Greggio, D.

AU - Ricci, D.

AU - Vassallo, D.

AU - Lessio, L.

AU - Radhakrishnan Santhakumari, K. K.

AU - Umbriaco, G.

AU - Dima, M.

AU - Di Filippo, S.

AU - D’Orazi, V.

AU - Mesa, D.

AU - Montoya, M.

AU - Mohr, L.

AU - Viotto, V.

AU - Baruffolo, A.

AU - Biondi, F.

AU - Chavan, S.

AU - Chinellato, S.

AU - De Pascale, M.

AU - Don, K. W.

AU - Grenz, P.

AU - Laudisio, F.

AU - Leisenrin, J.

AU - Ragazzoni, R.

AU - Pedichini, F.

AU - Piazzesi, R.

AU - Pinna, E.

AU - Puglisi, A.

AU - Bianco, A.

AU - Carlotti, A.

AU - Knapic, C.

AU - Vicinanza, M.

AU - Zanutta, A.

AU - Christou, J.

AU - Conrad, A.

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AU - Veillet, C.

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AB - SHARK-NIR is a near-infrared (0.96-1.7µm) coronagraphic camera with low-resolution spectroscopic capability designed to exploit the excellent performances, in terms of resolution and contrast, of the LBT Adaptive Optics system SOUL (recently commissioned). Second generation instrument of the LBT, SHARK-NIR left 5 years ago its paper and models realm to become a real working instrument, through realization and testing of single components at first and then the full AIV of the system. Its compact size is a consequence of the available volume and required stiffness, but shall not convince you of a simple opto-mechanical design, translating in requirements for all the interconnected fields of software, electronics, archiving, etc. The instrument is equipped with a cryostat containing the H2RG detector, several custom made optics and motors to operate the instrument, like de-rotator, wheels (to introduce filters, coronographic masks, prisms for spectroscopy), ADC stages, linear stages and actuators for calibration and alignment to star purposes. Its main science target is the detection and characterization of exoplanets, to be achieved through a set of different coronagraphic techniques. However, the analysis and study of protoplanetary disks, stellar jets, AGN, QSOs and solar system bodies are also foreseen scientific cases of the instrument. Coupled with its visible counterpart SHARK-VIS, it will offer the possibility to perform binocular observations in a wide wavelength domain (0.5µm to 1.7µm). In this paper we will report the main steps that let SHARK-NIR become a real instrument with laboratory validated performances, including procurement and shipment, the lessons learned and the upcoming path towards commissioning, focusing on the coordination, interfaces and interactions of all the different involved fields, expertise and institutes of the consortium as well as of the hosting telescope.

KW - commissioning

KW - coronagraphy

KW - exoplanets

KW - ground-based

KW - instrumentation

KW - procurement

KW - project management

KW - shipment

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T3 - Proceedings of SPIE - The International Society for Optical Engineering

BT - Modeling, Systems Engineering, and Project Management for Astronomy X

A2 - Angeli, George Z.

A2 - Dierickx, Philippe

PB - SPIE

Y2 - 17 July 2022 through 22 July 2022

ER -

SHARK-NIR: from design to installation, ready to dive into first light

Abstract

Publication series

Conference

Keywords

ASJC Scopus subject areas

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