Emerging adaptive optics facility at Large Binocular Telescope Observatory

Sam Ragland; Guido Brusa; Alessandro Cavallaro; Heejoo Choi; Juan Carlos Guerra; Tom Herbst; Michael Lefebvre; Douglas Miller; Fernando Pedichini; Jennifer Power; Joseph Shields; Mark Smithwright; Gregory Taylor; Christian Veillet; Xianyu Zhang; Roberto Biasi; Al Conrad; Laird Close; Simone Esposito; Daniele Gallieni; Elena Masciadri; Brandon Mechtley; Eliad Peretz; Enrico Pinna; Roberto Ragazzoni; Fabio Rossi; Guido Agapito; Matthieu Bec; Maria Bergomi; Thomas Bertram; Florian Briegel; Jacopo Farinato; John Hill; Daewook Kim; Luca Marafatto; Roberto Piazzesi; Kalyan Radhakrishnan; Armando Riccardi

doi:10.1117/12.3019441

Emerging adaptive optics facility at Large Binocular Telescope Observatory

Sam Ragland, Guido Brusa, Alessandro Cavallaro, Heejoo Choi, Juan Carlos Guerra, Tom Herbst, Michael Lefebvre, Douglas Miller, Fernando Pedichini, Jennifer Power, Joseph Shields, Mark Smithwright, Gregory Taylor, Christian Veillet, Xianyu Zhang, Roberto Biasi, Al Conrad, Laird Close, Simone Esposito, Daniele GallieniElena Masciadri, Brandon Mechtley, Eliad Peretz, Enrico Pinna, Roberto Ragazzoni, Fabio Rossi, Guido Agapito, Matthieu Bec, Maria Bergomi, Thomas Bertram, Florian Briegel, Jacopo Farinato, John Hill, Daewook Kim, Luca Marafatto, Roberto Piazzesi, Kalyan Radhakrishnan, Armando Riccardi

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

4 Scopus citations

Abstract

The Large Binocular Telescope (LBT) ^[1] Observatory pioneered Adaptive Optics (AO) technologies such as Adaptive Secondary Mirror (ASM)^[2], Pyramid wavefront sensor^[3], and Ground-layer AO using Rayleigh lasers^[4] at 8-10 m class telescopes. We have initiated an effort to turn LBT AO into a facility-class capability. The effort involves (1) building an AO team with AO development capability, (2) improving the robustness of the AO, (3) developing in-house AO expertise to maintain and troubleshoot the AO systems, (4) automating processes for efficient on-sky operation, (5) tracking performance metrics and cultivating accountability for on-sky AO performance, and (6) minimizing the operational risks for the ASMs. We present the status of these developments. LBTO continues its efforts to develop innovative technology. We explore the next phase of AO developments, including Agile Extreme Adaptive Optics (AgXAO) on the DX side of the LINC-NIRVANA^[5][6] optical bench to overcome the limitation imposed by varying and large atmospheric seeing at Mount Graham. AgXAO implementation includes the development of (1) a high-order, high-sensitivity wavefront sensor, (2) a high-density deformable mirror with 3000 actuators and next-generation ASM with about 950 actuators, (3) active optics integration, (4) vibration and wavefront piston control, (5) atmospheric turbulence measurements and weather forecast integration, and (6) a visible camera and an AO-corrected narrow-field fiber-coupled IFU spectrograph using one of the existing workhorse visible spectrographs. Developing AgXAO on the SX side, too, would enable Fizeau imaging in the visible wavelengths. AgXAO will also serve as a general-purpose high-contrast (and subsequently a Fizeau imaging) Testbed on LBT to test advanced wavefront control algorithms, including astrophotonics experiments, and machine learning algorithms with minimal impact on routine science operations. We propose developing AgXAO through student projects to train the next-generation scientists and engineers for the extremely large telescope (ELT) era. The ultimate goal is to push large aperture ground-based telescopes to their performance limits and make them competitive with space telescopes in terms of PSF stability and performance to enable breakthrough science.

Original language	English (US)
Title of host publication	Adaptive Optics Systems IX
Editors	Kathryn J. Jackson, Dirk Schmidt, Elise Vernet
Publisher	SPIE
ISBN (Electronic)	9781510675179
DOIs	https://doi.org/10.1117/12.3019441
State	Published - 2024
Event	Adaptive Optics Systems IX 2024 - Yokohama, Japan Duration: Jun 16 2024 → Jun 22 2024

Publication series

Name	Proceedings of SPIE - The International Society for Optical Engineering
Volume	13097
ISSN (Print)	0277-786X
ISSN (Electronic)	1996-756X

Conference

Conference	Adaptive Optics Systems IX 2024
Country/Territory	Japan
City	Yokohama
Period	6/16/24 → 6/22/24

Keywords

adaptive optics
adaptive secondary mirror
advanced wavefront control
high-contrast AO Testbed
high-contrast imaging and spectroscopy
hybrid (ground
Large Binocular Telescope Observatory
PSF stabilization
space) laser-guide star mode

ASJC Scopus subject areas

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

Access to Document

10.1117/12.3019441

Cite this

Ragland, S., Brusa, G., Cavallaro, A., Choi, H., Guerra, J. C., Herbst, T., Lefebvre, M., Miller, D., Pedichini, F., Power, J., Shields, J., Smithwright, M., Taylor, G., Veillet, C., Zhang, X., Biasi, R., Conrad, A., Close, L., Esposito, S., ... Riccardi, A. (2024). Emerging adaptive optics facility at Large Binocular Telescope Observatory. In K. J. Jackson, D. Schmidt, & E. Vernet (Eds.), Adaptive Optics Systems IX Article 130970L (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 13097). SPIE. https://doi.org/10.1117/12.3019441

Emerging adaptive optics facility at Large Binocular Telescope Observatory. / Ragland, Sam; Brusa, Guido; Cavallaro, Alessandro et al.
Adaptive Optics Systems IX. ed. / Kathryn J. Jackson; Dirk Schmidt; Elise Vernet. SPIE, 2024. 130970L (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 13097).

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

Ragland, S, Brusa, G, Cavallaro, A, Choi, H, Guerra, JC, Herbst, T, Lefebvre, M, Miller, D, Pedichini, F, Power, J, Shields, J, Smithwright, M, Taylor, G, Veillet, C, Zhang, X, Biasi, R, Conrad, A, Close, L, Esposito, S, Gallieni, D, Masciadri, E, Mechtley, B, Peretz, E, Pinna, E, Ragazzoni, R, Rossi, F, Agapito, G, Bec, M, Bergomi, M, Bertram, T, Briegel, F, Farinato, J, Hill, J, Kim, D, Marafatto, L, Piazzesi, R, Radhakrishnan, K & Riccardi, A 2024, Emerging adaptive optics facility at Large Binocular Telescope Observatory. in KJ Jackson, D Schmidt & E Vernet (eds), Adaptive Optics Systems IX., 130970L, Proceedings of SPIE - The International Society for Optical Engineering, vol. 13097, SPIE, Adaptive Optics Systems IX 2024, Yokohama, Japan, 6/16/24. https://doi.org/10.1117/12.3019441

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title = "Emerging adaptive optics facility at Large Binocular Telescope Observatory",

abstract = "The Large Binocular Telescope (LBT) [1] Observatory pioneered Adaptive Optics (AO) technologies such as Adaptive Secondary Mirror (ASM)[2], Pyramid wavefront sensor[3], and Ground-layer AO using Rayleigh lasers[4] at 8-10 m class telescopes. We have initiated an effort to turn LBT AO into a facility-class capability. The effort involves (1) building an AO team with AO development capability, (2) improving the robustness of the AO, (3) developing in-house AO expertise to maintain and troubleshoot the AO systems, (4) automating processes for efficient on-sky operation, (5) tracking performance metrics and cultivating accountability for on-sky AO performance, and (6) minimizing the operational risks for the ASMs. We present the status of these developments. LBTO continues its efforts to develop innovative technology. We explore the next phase of AO developments, including Agile Extreme Adaptive Optics (AgXAO) on the DX side of the LINC-NIRVANA[5][6] optical bench to overcome the limitation imposed by varying and large atmospheric seeing at Mount Graham. AgXAO implementation includes the development of (1) a high-order, high-sensitivity wavefront sensor, (2) a high-density deformable mirror with 3000 actuators and next-generation ASM with about 950 actuators, (3) active optics integration, (4) vibration and wavefront piston control, (5) atmospheric turbulence measurements and weather forecast integration, and (6) a visible camera and an AO-corrected narrow-field fiber-coupled IFU spectrograph using one of the existing workhorse visible spectrographs. Developing AgXAO on the SX side, too, would enable Fizeau imaging in the visible wavelengths. AgXAO will also serve as a general-purpose high-contrast (and subsequently a Fizeau imaging) Testbed on LBT to test advanced wavefront control algorithms, including astrophotonics experiments, and machine learning algorithms with minimal impact on routine science operations. We propose developing AgXAO through student projects to train the next-generation scientists and engineers for the extremely large telescope (ELT) era. The ultimate goal is to push large aperture ground-based telescopes to their performance limits and make them competitive with space telescopes in terms of PSF stability and performance to enable breakthrough science.",

keywords = "adaptive optics, adaptive secondary mirror, advanced wavefront control, high-contrast AO Testbed, high-contrast imaging and spectroscopy, hybrid (ground, Large Binocular Telescope Observatory, PSF stabilization, space) laser-guide star mode",

author = "Sam Ragland and Guido Brusa and Alessandro Cavallaro and Heejoo Choi and Guerra, {Juan Carlos} and Tom Herbst and Michael Lefebvre and Douglas Miller and Fernando Pedichini and Jennifer Power and Joseph Shields and Mark Smithwright and Gregory Taylor and Christian Veillet and Xianyu Zhang and Roberto Biasi and Al Conrad and Laird Close and Simone Esposito and Daniele Gallieni and Elena Masciadri and Brandon Mechtley and Eliad Peretz and Enrico Pinna and Roberto Ragazzoni and Fabio Rossi and Guido Agapito and Matthieu Bec and Maria Bergomi and Thomas Bertram and Florian Briegel and Jacopo Farinato and John Hill and Daewook Kim and Luca Marafatto and Roberto Piazzesi and Kalyan Radhakrishnan and Armando Riccardi",

note = "Publisher Copyright: {\textcopyright} 2024 SPIE.; Adaptive Optics Systems IX 2024 ; Conference date: 16-06-2024 Through 22-06-2024",

year = "2024",

doi = "10.1117/12.3019441",

language = "English (US)",

series = "Proceedings of SPIE - The International Society for Optical Engineering",

publisher = "SPIE",

editor = "Jackson, {Kathryn J.} and Dirk Schmidt and Elise Vernet",

booktitle = "Adaptive Optics Systems IX",

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TY - GEN

T1 - Emerging adaptive optics facility at Large Binocular Telescope Observatory

AU - Ragland, Sam

AU - Brusa, Guido

AU - Cavallaro, Alessandro

AU - Choi, Heejoo

AU - Guerra, Juan Carlos

AU - Herbst, Tom

AU - Lefebvre, Michael

AU - Miller, Douglas

AU - Pedichini, Fernando

AU - Power, Jennifer

AU - Shields, Joseph

AU - Smithwright, Mark

AU - Taylor, Gregory

AU - Veillet, Christian

AU - Zhang, Xianyu

AU - Biasi, Roberto

AU - Conrad, Al

AU - Close, Laird

AU - Esposito, Simone

AU - Gallieni, Daniele

AU - Masciadri, Elena

AU - Mechtley, Brandon

AU - Peretz, Eliad

AU - Pinna, Enrico

AU - Ragazzoni, Roberto

AU - Rossi, Fabio

AU - Agapito, Guido

AU - Bec, Matthieu

AU - Bergomi, Maria

AU - Bertram, Thomas

AU - Briegel, Florian

AU - Farinato, Jacopo

AU - Hill, John

AU - Kim, Daewook

AU - Marafatto, Luca

AU - Piazzesi, Roberto

AU - Radhakrishnan, Kalyan

AU - Riccardi, Armando

PY - 2024

Y1 - 2024

N2 - The Large Binocular Telescope (LBT) [1] Observatory pioneered Adaptive Optics (AO) technologies such as Adaptive Secondary Mirror (ASM)[2], Pyramid wavefront sensor[3], and Ground-layer AO using Rayleigh lasers[4] at 8-10 m class telescopes. We have initiated an effort to turn LBT AO into a facility-class capability. The effort involves (1) building an AO team with AO development capability, (2) improving the robustness of the AO, (3) developing in-house AO expertise to maintain and troubleshoot the AO systems, (4) automating processes for efficient on-sky operation, (5) tracking performance metrics and cultivating accountability for on-sky AO performance, and (6) minimizing the operational risks for the ASMs. We present the status of these developments. LBTO continues its efforts to develop innovative technology. We explore the next phase of AO developments, including Agile Extreme Adaptive Optics (AgXAO) on the DX side of the LINC-NIRVANA[5][6] optical bench to overcome the limitation imposed by varying and large atmospheric seeing at Mount Graham. AgXAO implementation includes the development of (1) a high-order, high-sensitivity wavefront sensor, (2) a high-density deformable mirror with 3000 actuators and next-generation ASM with about 950 actuators, (3) active optics integration, (4) vibration and wavefront piston control, (5) atmospheric turbulence measurements and weather forecast integration, and (6) a visible camera and an AO-corrected narrow-field fiber-coupled IFU spectrograph using one of the existing workhorse visible spectrographs. Developing AgXAO on the SX side, too, would enable Fizeau imaging in the visible wavelengths. AgXAO will also serve as a general-purpose high-contrast (and subsequently a Fizeau imaging) Testbed on LBT to test advanced wavefront control algorithms, including astrophotonics experiments, and machine learning algorithms with minimal impact on routine science operations. We propose developing AgXAO through student projects to train the next-generation scientists and engineers for the extremely large telescope (ELT) era. The ultimate goal is to push large aperture ground-based telescopes to their performance limits and make them competitive with space telescopes in terms of PSF stability and performance to enable breakthrough science.

AB - The Large Binocular Telescope (LBT) [1] Observatory pioneered Adaptive Optics (AO) technologies such as Adaptive Secondary Mirror (ASM)[2], Pyramid wavefront sensor[3], and Ground-layer AO using Rayleigh lasers[4] at 8-10 m class telescopes. We have initiated an effort to turn LBT AO into a facility-class capability. The effort involves (1) building an AO team with AO development capability, (2) improving the robustness of the AO, (3) developing in-house AO expertise to maintain and troubleshoot the AO systems, (4) automating processes for efficient on-sky operation, (5) tracking performance metrics and cultivating accountability for on-sky AO performance, and (6) minimizing the operational risks for the ASMs. We present the status of these developments. LBTO continues its efforts to develop innovative technology. We explore the next phase of AO developments, including Agile Extreme Adaptive Optics (AgXAO) on the DX side of the LINC-NIRVANA[5][6] optical bench to overcome the limitation imposed by varying and large atmospheric seeing at Mount Graham. AgXAO implementation includes the development of (1) a high-order, high-sensitivity wavefront sensor, (2) a high-density deformable mirror with 3000 actuators and next-generation ASM with about 950 actuators, (3) active optics integration, (4) vibration and wavefront piston control, (5) atmospheric turbulence measurements and weather forecast integration, and (6) a visible camera and an AO-corrected narrow-field fiber-coupled IFU spectrograph using one of the existing workhorse visible spectrographs. Developing AgXAO on the SX side, too, would enable Fizeau imaging in the visible wavelengths. AgXAO will also serve as a general-purpose high-contrast (and subsequently a Fizeau imaging) Testbed on LBT to test advanced wavefront control algorithms, including astrophotonics experiments, and machine learning algorithms with minimal impact on routine science operations. We propose developing AgXAO through student projects to train the next-generation scientists and engineers for the extremely large telescope (ELT) era. The ultimate goal is to push large aperture ground-based telescopes to their performance limits and make them competitive with space telescopes in terms of PSF stability and performance to enable breakthrough science.

KW - adaptive optics

KW - adaptive secondary mirror

KW - advanced wavefront control

KW - high-contrast AO Testbed

KW - high-contrast imaging and spectroscopy

KW - hybrid (ground

KW - Large Binocular Telescope Observatory

KW - PSF stabilization

KW - space) laser-guide star mode

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U2 - 10.1117/12.3019441

DO - 10.1117/12.3019441

M3 - Conference contribution

AN - SCOPUS:85200436847

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

BT - Adaptive Optics Systems IX

A2 - Jackson, Kathryn J.

A2 - Schmidt, Dirk

A2 - Vernet, Elise

PB - SPIE

T2 - Adaptive Optics Systems IX 2024

Y2 - 16 June 2024 through 22 June 2024

ER -

Emerging adaptive optics facility at Large Binocular Telescope Observatory

Abstract

Publication series

Conference

Keywords

ASJC Scopus subject areas

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