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1. Final design and on-sky testing of the iLocater SX acquisition camera: broad-band single-mode fibre coupling

   https://doi.org/10.1093/mnras/staa3355  

   Crass, J; Bechter, A; Sands, B; King, D; Ketterer, R; Engstrom, M; Hamper, R; Kopon, D; Smous, J; Crepp, J R; et al (January 2021, Monthly Notices of the Royal Astronomical Society)

   null (Ed.)

   ABSTRACT Enabling efficient injection of light into single-mode fibres (SMFs) is a key requirement in realizing diffraction-limited astronomical spectroscopy on ground-based telescopes. SMF-fed spectrographs, facilitated by the use of adaptive optics (AO), offer distinct advantages over comparable seeing-limited designs, including higher spectral resolution within a compact and stable instrument volume, and a telescope independent spectrograph design. iLocater is an extremely precise radial velocity (EPRV) spectrograph being built for the Large Binocular Telescope (LBT). We have designed and built the front-end fibre injection system, or acquisition camera, for the SX (left) primary mirror of the LBT. The instrument was installed in 2019 and underwent on-sky commissioning and performance assessment. In this paper, we present the instrument requirements, acquisition camera design, as well as results from first-light measurements. Broad-band SMF coupling in excess of 35 per cent (absolute) in the near-infrared (0.97–1.31 $${\mu {\rm m}}$$) was achieved across a range of target magnitudes, spectral types, and observing conditions. Successful demonstration of on-sky performance represents both a major milestone in the development of iLocater and in making efficient ground-based SMF-fed astronomical instruments a reality. 

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2. Little iLocater: paving the way for iLocater

   https://doi.org/10.1093/mnras/stae2720  

   Harris, Robert_J; Crass, Jonathan; Johnson, Marshall_C; Bechter, Andrew_J; Power, Jennifer; Calcines Rosario, Ariadna; Crepp, Justin_R; Bechter, Eric_B; Sands, Brian_L; Kopon, Derek; et al (December 2024, Monthly Notices of the Royal Astronomical Society)

   ABSTRACT Diffraction-limited radial-velocity instruments offer a pathway towards improved precision and stability, and the exploration of new parameter spaces at high spatial and spectral resolution. However, achieving the necessary performance requires careful instrument design and considerable on-sky testing. We describe the design and construction of ‘Little iLocater’ (Lili), a compact spectrograph that has been used to validate the performance of the front-end fibre-injection system of the iLocater spectrograph. We present the design, assembly, and performance using on-sky data obtained at the Large Binocular Telescope (LBT), including extraction of spectra from standard stars, testing of the atmospheric dispersion corrector to elevations of 40°, and spatially resolved spectra from close companion systems. These results show the front-end fibre-injection system is performing as expected and is indicative of iLocater’s capabilities once installed at the LBT. 

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3. Keck adaptive optics facility: real time controller upgrade

   https://doi.org/10.1117/12.2629614  

   Chin, Jason C.; Cetre, Sylvain; Wizinowich, Peter; Ragland, Sam; Lilley, Scott J.; Wetherell, Ed; Surendran, Avinash; Correia, Carlos M.; Marin, Eduardo; Biasi, Roberto; et al (August 2022, SPIE Astronomical Telescopes + Instrumentation)

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

   The W. M. Keck Observatory Adaptive Optics (AO) facilities have been operating with a Field Programmable Gate Array (FPGA) based real time controller (RTC) since 2007. The RTC inputs data from various AO wavefront and tip/tilt sensors; and corrects image blurring from atmospheric turbulence via deformable and tip/tilt mirrors. Since its commissioning, the Keck I and Keck II RTCs have been upgraded to support new hardware such as pyramid wavefront and infrared tip-tilt sensors. However, they are reaching the limits of their capabilities in terms of processing bandwidth and the ability to interface with new hardware. Together with the Keck All-sky Precision Adaptive optics (KAPA) project, a higher performance and a more reliable RTC is needed to support next generation capabilities such as laser tomography and sensor fusion. This paper provides an overview of the new RTC system, developed with our contractor/collaborators (Microgate, Swinburne University of Technology and Australian National University), and the initial on-sky performance. The upgrade includes an Interface Module to interface with the wavefront sensors and controlled hardware, and a Graphical Processing Unit (GPU) based computational engine to meet the system’s control requirements and to provide a flexible software architecture to allow future algorithms development and capabilities. The system saw first light in 2021 and is being commissioned in 2022 to support single conjugate laser guide star (LGS) AO, along with a more sensitive EMCCD camera. Initial results are provided to demonstrate single NGS & LGS performance, system reliability, and the planned upgrade for four LGS to support laser tomography. 

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4. Characterization and performance of the upgraded NIRSPEC on the W. M. Keck Telescope

   https://doi.org/10.1117/12.2563075  

   Lopez, Ronald A.; Hoffman, Erika; Doppmann, Gregory; Fitzgerald, Michael P.; Johnson, Chris; Kassis, Marc; Lanclos, Kyle; Lyke, Jim; Martin, Emily C.; McLean, Ian; et al (December 2020, SPIE Astronomical Telescopes & Instrumentation 2020 Proceedings)

   Evans, Christopher J.; Bryant, Julia J.; Motohara, Kentaro (Ed.)

   NIRSPEC is a high-resolution near-infrared echelle spectrograph on the Keck II telescope that was commissioned in 1999 and upgraded in 2018. This recent upgrade was aimed at improving the sensitivity and longevity of the instrument through the replacement of the spectrometer science detector (SPEC) and slit-viewing camera (SCAM). Commissioning began in 2018 December, producing the first on-sky images used in the characterization of the upgraded system. Through the use of photometry and spectroscopy of standard stars and internal calibration lamps, we assess the performance of the upgraded SPEC and SCAM detectors. First, we evaluate the gain, readnoise, dark current, and the charge persistence of the spec detector. We then characterize the newly upgraded spectrometer and the resulting improvements in sensitivity, including spectroscopic zero points, pixel scale, and resolving power across the spectrometer detector field. Finally, for SCAM, we present zero points, pixel scale, and provide a map of the geometric distortion of the camera. 

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5. Prime Focus Spectrograph (PFS) for the Subaru Telescope: its start of the last development phase

   https://doi.org/10.1117/12.2628152  

   Tamura, Naoyuki; Moritani, Yuki; Yabe, Kiyoto; Ishizuka, Yuki; Kamata, Yukiko; Allaoui, Ali; Arai, Akira; Arnouts, Stéphane; Barkhouser, Robert H.; Barette, Rudy; et al (August 2022, Proceedings of the SPIE)

   Evans, Christopher J.; Bryant, Julia J.; Motohara, Kentaro (Ed.)

   PFS (Prime Focus Spectrograph), a next generation facility instrument on the Subaru telescope, is now being tested on the telescope. The instrument is equipped with very wide (1.3 degrees in diameter) field of view on the Subaru's prime focus, high multiplexity by 2394 reconfigurable fibers, and wide waveband spectrograph that covers from 380nm to 1260nm simultaneously in one exposure. Currently engineering observations are ongoing with Prime Focus Instrument (PFI), Metrology Camera System (MCS), the first spectrpgraph module (SM1) with visible cameras and the first fiber cable providing optical link between PFI and SM1. Among the rest of the hardware, the second fiber cable has been already installed on the telescope and in the dome building since April 2022, and the two others were also delivered in June 2022. The integration and test of next SMs including near-infrared cameras are ongoing for timely deliveries. The progress in the software development is also worth noting. The instrument control software delivered with the subsystems is being well integrated with its system-level layer, the telescope system, observation planning software and associated databases. The data reduction pipelines are also rapidly progressing especially since sky spectra started being taken in early 2021 using Subaru Nigh Sky Spectrograph (SuNSS), and more recently using PFI during the engineering observations. In parallel to these instrumentation activities, the PFS science team in the collaboration is timely formulating a plan of large-sky survey observation to be proposed and conducted as a Subaru Strategic Program (SSP) from 2024. In this article, we report these recent progresses, ongoing developments and future perspectives of the PFS instrumentation. 

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