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1. 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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2. KOLA: a concept for an optical multi-conjugate adaptive optics system for the W.M. Keck Observatory

   https://doi.org/10.1117/12.3020725  

   Lu, Jessica R; Dekany, Rich; Peck, Brianna; Bouchez, Antonin; Millar-Blanchaer, Max; Hinz, Philip M; Rider, Kodi; Chun, Mark; Wizinowich, Peter L; Wang, Lianqi; et al (August 2024, SPIE)

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

   We present progress on a conceptual design for a new Keck multi-conjugate adaptive optics system capable of visible light correction with a near-diffraction-limited spatial resolution. The KOLA (Keck Optical LGS AO) system will utilize a planned adaptive secondary mirror (ASM), 2 additional high-altitude deformable mirrors (DMs), and ≳ 8 laser guide stars (LGS) to sense and correct atmospheric turbulence. The field of regard for selecting guide stars will be 2’ and the corrected science field of view will be 60”. We describe science cases, system requirements, and performance simulations for the system performed with error budget spreadsheet tools and MAOS physical optics simulations. We will also present results from trade studies for the actuator count on the ASM. KOLA will feed a new optical imager and IFU spectrograph in addition to the planned Liger optical + infrared (λ > 850 nm) imager and IFU spectrograph. Performance simulations show KOLA will deliver a Strehl of 12% at g’, 21% at r’, 53% at Y, and 87% at K bands on axis with nearly uniform image quality over a 40”×40” field of view in the optical and over 60”×60” beyond 1 μm. Ultimately, the system will deliver spatial resolutions superior to HST and JWST (∼17 mas at r’-band) and comparable to the planned first-generation infrared AO systems for the ELTs. 

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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. 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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5. GPI 2.0: pre-integrated pyramid wavefront sensor results

   https://doi.org/10.1117/12.3020360  

   Perera, Saavidra; Maire, Jérôme; Do_Ó, Clarissa R; Nguyen, Jayke S; Chambouleyron, Vincent; Konopacky, Quinn M; Chilcote, Jeffrey; Sands, Brian; Hamper, Randall; Engstrom, Matthew; et al (August 2024, SPIE)

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

   The Gemini Planet Imager (GPI) is a high-contrast imaging instrument designed to directly detect and char- acterise young, Jupiter-mass exoplanets. After six years of operation at the Gemini South Telescope in Chile, the instrument is being upgraded and moved to the Gemini North Telescope in Hawaii as GPI 2.0. Several improvements have been made to the adaptive optics (AO) system as part of this upgrade. This includes re- placing the current Shack-Hartmann wavefront sensor with a pyramid wavefront sensor (PWFS) and a custom EMCCD. These changes will increase GPI’s sky coverage by accessing fainter targets, improving corrections on fainter stars and allowing faster and ultra-low latency operations on brighter targets. The PWFS subsystem was independently built and tested to verify its performance before being integrated into the GPI 2.0 instrument. This paper will present the pre-integration performance test results, including pupil image quality, throughput and linearity without modulation. 

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