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1. Using AI for Wave-front Estimation with the Rubin Observatory Active Optics System

   https://doi.org/10.3847/1538-3881/ad1661  

   Crenshaw, John Franklin ; Connolly, Andrew J. ; Meyers, Joshua E. ; Kalmbach, J. Bryce ; Megias Homar, Guillem ; Ribeiro, Tiago ; Suberlak, Krzysztof ; Thomas, Sandrine ; Tsai, Te-Wei ( January 2024 , The Astronomical Journal)

   The Vera C. Rubin Observatory will, over a period of 10 yr, repeatedly survey the southern sky. To ensure that images generated by Rubin meet the quality requirements for precision science, the observatory will use an active-optics system (AOS) to correct for alignment and mirror surface perturbations introduced by gravity and temperature gradients in the optical system. To accomplish this, Rubin will use out-of-focus images from sensors located at the edge of the focal plane to learn and correct for perturbations to the wave front. We have designed and integrated a deep-learning (DL) model for wave-front estimation into the AOS pipeline. In this paper, we compare the performance of this DL approach to Rubin’s baseline algorithm when applied to images from two different simulations of the Rubin optical system. We show the DL approach is faster and more accurate, achieving the atmospheric error floor both for high-quality images and low-quality images with heavy blending and vignetting. Compared to the baseline algorithm, the DL model is 40× faster, the median error 2× better under ideal conditions, 5× better in the presence of vignetting by the Rubin camera, and 14× better in the presence of blending in crowded fields. In addition, the DL model surpasses the required optical quality in simulations of the AOS closed loop. This system promises to increase the survey area useful for precision science by up to 8%. We discuss how this system might be deployed when commissioning and operating Rubin.

    

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2. Demonstration of a photonic-lantern focal-plane wavefront sensor using fibre mode conversion and deep learning

   https://doi.org/10.1117/12.2629852  

   Norris, Barnaby R. ; Wei, Jin ; Betters, Christopher ; Leon-Saval, Sergio ; Xin, Yinzi ; Lin, Jonathan ; Kim, Yoo Jung ; Sallum, Steph ; Lozi, Julien ; Vievard, Sébastien ; et al ( August 2022 , Adaptive Optics Systems VIII)

   Schmidt, Dirk ; Schreiber, Laura ; Vernet, Elise (Ed.)

   A focal plane wavefront sensor offers major advantages to adaptive optics, including removal of non-commonpath error and providing sensitivity to blind modes (such as petalling). But simply using the observed point spread function (PSF) is not sufficient for wavefront correction, as only the intensity, not phase, is measured. Here we demonstrate the use of a multimode fiber mode converter (photonic lantern) to directly measure the wavefront phase and amplitude at the focal plane. Starlight is injected into a multimode fiber at the image plane, with the combination of modes excited within the fiber a function of the phase and amplitude of the incident wavefront. The fiber undergoes an adiabatic transition into a set of multiple, single-mode outputs, such that the distribution of intensities between them encodes the incident wavefront. The mapping (which may be strongly non-linear) between spatial modes in the PSF and the outputs is stable but must be learned. This is done by a deep neural network, trained by applying random combinations of spatial modes to the deformable mirror. Once trained, the neural network can instantaneously predict the incident wavefront for any set of output intensities. We demonstrate the successful reconstruction of wavefronts produced in the laboratory with low-wind-effect, and an on-sky demonstration of reconstruction of low-order modes consistent with those measured by the existing pyramid wavefront sensor, using SCExAO observations at the Subaru Telescope. 

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3. Keck All sky Precision Adaptive optics program overview

   https://doi.org/10.1117/12.2628275  

   Wizinowich, Peter ; Lu, Jessica ; Cetre, Sylvain ; Chin, Jason C. ; Correia, Carlos M. ; Delorme, Jacques R. ; Gers, Luke ; Lilley, Scott J. ; Lyke, Jim E. ; Marin, Eduardo ; et al ( August 2022 , SPIE Astronomical Telescopes + Instrumentation)

   Schmidt, Dirk ; Schreiber, Laura ; Vernet, Elise (Ed.)

   We present the status and plans for the Keck All sky Precision Adaptive optics (KAPA) program. KAPA includes (1) an upgrade to the Keck I laser guide star adaptive optics (AO) facility to improve image quality and sky coverage, (2) the inclusion of AO telemetry-based point spread function estimates with all science exposures, (3) four key science programs, and (4) an educational component focused on broadening the participation of women and underrepresented groups in instrumentation. For this conference we focus on the KAPA upgrades since the 2020 SPIE proceedings1 including implementation of a laser asterism generator, wavefront sensor, real-time controller, asterism and turbulence simulators, the laser tomography system itself along with new operations software and science tools, and modifications to an existing near-infrared tip-tilt sensor to support multiple natural guide star and focus measurements. We will also report on the results of daytime and on-sky calibrations and testing. 

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4. Keck all sky precision adaptive optics: project overview

   https://doi.org/10.1117/12.2560017  

   Wizinowich, Peter L. ; Chin, Jason C. ; Correia, Carlos M. ; Lu, Jessica R. ; Brown, Thomas ; Casey, Kelleen ; Cetre, Sylvain ; Delorme, Jacques-Robert ; Gers, Luke ; Hunter, Lisa ; et al ( December 2020 , Proceedings of the SPIE)

   Schmidt, Dirk ; Schreiber, Laura ; Vernet, Elise (Ed.)

   We present the status and plans for the Keck All sky Precision Adaptive optics (KAPA) program. KAPA includes four key science programs, an upgrade to the Keck I laser guide star (LGS) adaptive optics (AO) facility to improve image quality and sky coverage, AO telemetry based point spread function (PSF) estimates for all science exposures, and an educational component focused on broadening the participation of women and underrepresented groups in instrumentation. For the purpose of this conference we will focus on the AO facility upgrade which includes implementation of a new laser, wavefront sensor and real-time controller to support laser tomography, the laser tomography system itself, and modifications to an existing near-infrared tip-tilt sensor to support multiple natural guide star (NGS) and focus measurements. 

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5. Exoplanet detection with photonic lanterns for focal-plane wavefront sensing and control

   https://doi.org/10.1117/12.2630692  

   Lin, Jonathan ; Xin, Yinzi ; Norris, Barnaby R. ; Kim, Yoo Jung ; Sallum, Steph ; Betters, Christopher ; Leon-Saval, Sergio ; Lozi, Julien ; Vievard, Sebastian ; Guyon, Olivier ; et al ( August 2022 , Adaptive Optics Systems VIII)

   Schmidt, Dirk ; Schreiber, Laura ; Vernet, Elise (Ed.)

   Inner working angle is a key parameter for enabling scientific discovery in direct exoplanet imaging and characterization. Approaches to improving the inner working angle to reach the diffraction limit center on the sensing and control of wavefront errors, starlight suppression via coronagraphy, and differential techniques applied in post-processing. These approaches are ultimately limited by the shot noise of the residual starlight, placing a premium on the ability of the adaptive optics system to sense and control wavefront errors so that the coronagraph can effectively suppress starlight reaching the science focal plane. Photonic lanterns are attractive for use in the science focal plane because of their ability to spatially filter light using a finite basis of accepted modes and effectively couple the results to diffraction-limited spectrometers, providing a compact and cost-effective means to implement post-processing based on spectral diversity. We aim to characterize the ability of photonic lanterns to serve as focal-plane wavefront sensors, allowing the adaptive optics system to control aberrations affecting the science focal plane and reject additional stellar photon noise. By serving as focal-plane wavefront sensors, photonic lanterns can improve sensitivity to exoplanets through both direct and coronagraphic observations. We have studied the sensing capabilities of photonic lanterns in the linear and quadratic regimes with analytical and numerical treatments for different lantern geometries (including non-mode-selective, mode-selective, and hybrid geometries) as a function of port number. In this presentation we report on the sensitivity of such lanterns and comment on the relative suitability and sensitivity impacts of different lantern geometries for focal-plane wavefront sensing. 

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