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1. GPI 2.0: exploring the impact of different readout modes on the wavefront sensor's EMCCD

   https://doi.org/10.1117/12.3019439  

   Do_Ó, Clarissa R; Perera, Saavidra; Maire, Jérôme; Nguyen, Jayke S; Chambouleyron, Vincent; Konopacky, Quinn M; Chilcote, Jeffrey; Fitzsimmons, Joeleff; Hamper, Randall; Kerley, Dan; et al (August 2024, SPIE)

   Schmidt, Dirk; Vernet, Elise; Jackson, Kathryn J (Ed.)

   The Gemini Planet Imager (GPI) is a high contrast imaging instrument that aims to detect and characterize extrasolar planets. GPI is being upgraded to GPI 2.0, with several subsystems receiving a re-design to improve its contrast. To enable observations on fainter targets and increase performance on brighter ones, one of the upgrades is to the adaptive optics system. The current Shack-Hartmann wavefront sensor (WFS) is being replaced by a pyramid WFS with an low-noise electron multiplying CCD (EMCCD). EMCCDs are detectors capable of counting single photon events at high speed and high sensitivity. In this work, we characterize the performance of the HNu ̈ 240 EMCCD from Nuvu Cameras, which was custom-built for GPI 2.0. Through our performance evaluation we found that the operating mode of the camera had to be changed from inverted-mode (IMO) to non-inverted mode (NIMO) in order to improve charge diffusion features found in the detector’s images. Here, we characterize the EMCCD’s noise contributors (readout noise, clock-induced charges, dark current) and linearity tests (EM gain, exposure time) before and after the switch to NIMO. 

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2. Residual wavefront control of segmented mirror telescopes

   https://doi.org/10.1117/12.2630269  

   Ragland, Sam; Wizinowich, Peter L.; van Kooten, Maaike A.; Bottom, Michael; Calvin, Ben; Fitzgerald, Michael P.; Hinz, Philip M.; Jensen-Clem, Rebecca M.; Mawet, Dimitri; Peretz, Eliad (January 2022, Adaptive Optics Systems VIII, SPIE, 2022.)

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

   Uncorrected residual wavefront errors limit the ultimate performance of adaptive optics (AO) systems. We present different contributing factors and techniques to estimate and compensate these wavefront errors in the Keck natural guide star (NGS) AO systems. The error terms include low order static and semi-static aberrations from multiple sources, periodic and random segment piston errors, single-segment low order aberrations, wavefront sensor aliasing, vibrations, calibration drifts, and AO-to-telescope offload related errors. We present the design of a new AO subsystem, a residual wavefront controller (rWFC) to monitor the performance of the AO control loops and the image quality of the AO science instruments and apply the necessary changes to the telescope and AO parameters to minimize the residual wavefront errors. The distributed system consists of components at the telescope, AO bench and the science instruments. A few components of this system are already tested as on-demand standalone tools and will be integrated into a high-level graphical user interface (GUI) to operate the system. The software tool will periodically collect AO telemetry data, perform control loop parameter optimization and update AO parameters such as loop gains, centroid gain, etc. In addition, the system will analyze the science data at the end of each exposure and estimate telescope/AO performance when a bright point source is available in the science field. The benefits of reducing or eliminating the residual wavefront errors have broad implications for optical astronomy. Testing these techniques on a segmented telescope will be extremely useful to the teams developing high contrast AO systems for all extremely large telescopes and future segmented space telescopes. 

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3. The Robo-AO-2 facility for rapid visible/near-infrared AO imaging and the demonstration of hybrid techniques

   https://doi.org/10.1117/12.2312835  

   Baranec, Christoph; Chun, Mark; Hall, Donald; Connelley, Michael; Hodapp, Klaus; Huber, Daniel; Liu, Michael; Magnier, Eugene; Meech, Karen; Takamiya, Marianne; et al (July 2018, SPIE Astronomical Telescopes + Instrumentation, Adaptive Optics System VI)

   We are building a next-generation laser adaptive optics system, Robo-AO-2, for the UH 2.2-m telescope that will deliver robotic, diffraction-limited observations at visible and near-infrared wavelengths in unprecedented numbers. The superior Maunakea observing site, expanded spectral range and rapid response to high-priority events represent a significant advance over the prototype. Robo-AO-2 will include a new reconfigurable natural guide star sensor for exquisite wavefront correction on bright targets and the demonstration of potentially transformative hybrid AO techniques that promise to extend the faintness limit on current and future exoplanet adaptive optics systems. 

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4. Making the unmodulated pyramid wavefront sensor smart: II. First on-sky demonstration of extreme adaptive optics with deep learning

   https://doi.org/10.1051/0004-6361/202553753  

   Landman, R; Haffert, S Y; Long, J D; Males, J R; Close, L M; Foster, W B; Van_Gorkom, K; Guyon, O; Hedglen, A D; Johnson, P T; et al (April 2025, Astronomy & Astrophysics)

   Pyramid wavefront sensors (PWFSs) are the preferred choice for current and future extreme adaptive optics (XAO) systems. Almost all instruments use the PWFS in its modulated form to mitigate its limited linearity range. However, this modulation comes at the cost of a reduction in sensitivity, a blindness to petal-piston modes, and a limit to the sensor’s ability to operate at high speeds. Therefore, there is strong interest to use the PWFS without modulation, which can be enabled with nonlinear reconstructors. Here, we present the first on-sky demonstration of XAO with an unmodulated PWFS using a nonlinear reconstructor based on convolutional neural networks. We discuss the real-time implementation on the Magellan Adaptive Optics eXtreme (MagAO-X) instrument using the optimized TensorRT framework and show that inference is fast enough to run the control loop at > 2 kHz frequencies. Our on-sky results demonstrate a successful closed-loop operation using a model calibrated with internal source data that delivers stable and robust correction under varying conditions. Performance analysis reveals that our smart PWFS achieves nearly the same Strehl ratio as the highly optimized modulated PWFS under favorable conditions on bright stars. Notably, we observe an improvement in performance on a fainter star under the influence of strong winds. These findings confirm the feasibility of using the PWFS in its unmodulated form and highlight its potential for next-generation instruments. Future efforts will focus on achieving even higher control loop frequencies (> 3 kHz), optimizing the calibration procedures, and testing its performance on fainter stars, where more gain is expected for the unmodulated PWFS compared to its modulated counterpart. 

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5. From Clear to DKIST: advancing solar MCAO from 1.6 to 4 meters

   https://doi.org/10.1117/12.2313787  

   Rimmele, Thomas R.; Marino, José; Johnson, Luke C.; Gorceix, Nicolas; Goode, Philip R.; Berkefeld, Thomas; Schmidt, Dirk; Schmidt, Dirk; Schreiber, Laura; Close, Laird M. (January 2019, Proceedings of the SPIE)

   The MCAO pathfinder Clear on the 1.6-meter Goode Solar Telescope has been enabling us to advance solar MCAO from early conceptual demonstrations to science grade wide-field image correction. We report on recent improvements to the control loop and we comment on issues such as the co-aligning of wavefront sensors and deformable mirrors and the sensitivity of wavefront sensor gains. Further, we comment on the challenges to wavefront sensing and the control system architecture faced when scaling up to a 4-meter aperture. Finally, we present an early concept of the future MCAO upgrade for the Daniel K. Inouye Solar Telescope. 

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