Your search keyword '"Astronomical instrumentation"' showing total 3,112 results

1. Theoretical Performance Evaluation of Wide-band Diffraction-limited Coronagraph for the Next-generation Segmented Large Telescopes.

Author

Kojima, Reiki, Satoshi, Itoh, Ota, Shunsuke, Yuji, Ikeda, Bessho, Taiki, and Matsuo, Taro

Subjects

*ANGULAR distance, *TELESCOPES, *OPTICS, *CHROMATICITY, *BANDWIDTHS

Abstract

We investigate the raw-contrast mitigation ability of the spectroscopic coronagraph. We consider a mis-modulation of the complex amplitude by the transmissive focal-plane mask that is an intrinsic problem dependent on the spectral resolving power of a grating in a spectroscopic coronagraph, stellar angular radius, and non-common path error (NCP) that is due to chromaticity in the active wavefront control (WFC) as limitation factors to the performance of the spectroscopic coronagraph. Concerning the impact of the mis-modulation and stellar angular radius under the assumption with the an achromatic WFC, we found that the spectroscopic coronagraph potentially archives the raw-contrast of 1.25 × 10−10 at the spectral resolving power R greater than or equal to 2000 at 2 λ / D with the 10 pc distant solar radius 0.93 mas. It corresponds to approximately 0.03 λ / D where the wavelength λ is 800 nm and telescope diameter D is 6 m. The inner working angle (defined as the minimal angular distance where planetary throughput is the maximal throughput) of the spectroscopic coronagraph is 2 λ / D . In addition, we found that the NCP limits the raw-contrast mitigation ability to 7.3 × 10−11 and 5.5 × 10−10 at 2 λ / D for 3% and 8% spectral bandwidths, respectively. We conclude that the spectroscopic coronagraph may serve as a promising method of broadband direct imaging of potentially habitable exoplanets located at small inner working angles with the next-generation segmented large telescopes. [ABSTRACT FROM AUTHOR]

Published

2024

2. Detection Limits of Thermal-infrared Observations with Adaptive Optics. I. Observational Data.

Author

Sauter, J. R., Brandner, W., Heidt, J., and Cantalloube, F.

Subjects

*ADAPTIVE optics, *INFRARED astronomy, *HEAT radiation & absorption, *ADAPTIVE modulation, *DETECTION limit

Abstract

Ground-based thermal infrared observations face substantial challenges in correcting the predominant background emitted as thermal radiation from the atmosphere and the telescope itself. With the upcoming 40 m class ELTs, unprecedented sensitivities from ground will be reached, underlining the need of even more sophisticated background correction strategies. This study aims to investigate the impact of thermal backgrounds on ground-based observations and identify possible limiting factors in dedicated correction strategies. We evaluate temporal and spatial characteristics of the thermal background in direct imaging data obtained with different telescopes and observation modes. In particular, three distinct data sets, acquired using VLT/NACO and KECK/NIRC2, are analyzed. Our analysis reveals that the observations are not fully photon shot noise limited, but exhibit additional sensitivity losses caused by imperfect background compensation in the different data sets. We identify correlations between background fluctuations and the activity of the adaptive optics system. We hypothesize that the pupil modulation of the adaptive optics mirrors introduces high frequency spatial and temporal fluctuations to the background, which could ultimately constrain the detection limit if they are not compensated adequately. [ABSTRACT FROM AUTHOR]

Published

2024

3. Mapper of the IGM spin temperature: instrument overview.

Author

Monsalve, R A, Altamirano, C, Bidula, V, Bustos, R, Bye, C H, Chiang, H C, Díaz, M, Fernández, B, Guo, X, Hendricksen, I, Hornecker, E, Lucero, F, Mani, H, McGee, F, Mena, F P, Pessôa, M, Prabhakar, G, Restrepo, O, Sievers, J L, and Thyagarajan, N

Subjects

*TEMPERATURE measuring instruments, *MICROWAVE radiometers, *ANTENNAS (Electronics), *MIDDLE Ages, *INTERSTELLAR medium, *RADIOMETERS

Abstract

The observation of the global 21 cm signal produced by neutral hydrogen gas in the intergalactic medium (IGM) during the Dark Ages, Cosmic Dawn, and Epoch of Reionization requires measurements with extremely well-calibrated wideband radiometers. We describe the design and characterization of the Mapper of the IGM Spin Temperature (MIST), which is a new ground-based, single-antenna, global 21 cm experiment. The design of MIST was guided by the objectives of avoiding systematics from an antenna ground plane and cables around the antenna, as well as maximizing the instrument's on-sky efficiency and portability for operations at remote sites. We have built two MIST instruments, which observe in the range 25–105 MHz. For the 21 cm signal, this frequency range approximately corresponds to redshifts 55.5 > z > 12.5, encompassing the Dark Ages and Cosmic Dawn. The MIST antenna is a horizontal blade dipole of 2.42 m in length, 60 cm in width, and 52 cm in height above the ground. This antenna operates without a metal ground plane. The instruments run on 12 V batteries and have a maximum power consumption of 17 W. The batteries and electronics are contained in a single receiver box located under the antenna. We present the characterization of the instruments using electromagnetic simulations and lab measurements. We also show sample sky measurements from recent observations at remote sites in California, Nevada, and the Canadian High Arctic. These measurements indicate that the instruments perform as expected. Detailed analyses of the sky measurements are left for future work. [ABSTRACT FROM AUTHOR]

Published

2024

4. Eyes in the sky usher in new era of law and order.

Author

Savage, Neil

Abstract

Satellite imagery is getting sharper and is gradually making its way into the courtroom. [ABSTRACT FROM AUTHOR]

Published

2024

5. Reconstructing Turbulence-Distorted Wavefronts Through Laser-Beam Profiles

Author

Buendía-Roca, Alejandro, Pérez-Fernández, Saúl, González-Gutiérrez, Carlos, Iglesias-Álvarez, Santiago, Rodríguez-Rodríguez, Javier, Fernández-Díaz, Julia María, Sánchez-Lasheras, Fernando, Bharmal, Nazim Ali, Calvo-Rolle, José Luis, de Cos Juez, Francisco Javier, Kacprzyk, Janusz, Series Editor, Gomide, Fernando, Advisory Editor, Kaynak, Okyay, Advisory Editor, Liu, Derong, Advisory Editor, Pedrycz, Witold, Advisory Editor, Polycarpou, Marios M., Advisory Editor, Rudas, Imre J., Advisory Editor, Wang, Jun, Advisory Editor, Zayas-Gato, Francisco, editor, Díaz-Longueira, Antonio, editor, Casteleiro-Roca, José-Luis, editor, and Jove, Esteban, editor

Published

2024

6. The WEAVE fibre positioner : calibration, commissioning, and first-light

Author

Hughes, Sarah, Dalton, Gavin, Lewis, Ian, and Terrett, David

Subjects

Metrology, Astronomical Instrumentation

Abstract

This thesis details the final assembly and calibration procedures for the WEAVE fibre positioner, from October 2019 to first-light in September 2022. The positioner was successfully mounted to the William Herschel Telescope (WHT) in May 2022. I present the first-light results of WEAVE for each of its three observing modes and discuss whether the positioner has met its design expectations. Chapter one describes the evolution of astronomical spectroscopy and the scientific motivations behind the construction of WEAVE. This is followed by the instrument design specification and sub-systems required to meet them. Chapter two will focus on the positioner in detail and include the evolution of our quality control methods. An account of the calibration procedures, in both the lab environment and on the elevation testing rig, is given in chapter three. The test rig revealed flexure behaviour in the positioner's structure, which was modified to correct for this. The calibration work was repeated with improved techniques, to predict changes in the positioner's metrology with elevation. This chapter then presents the results of the fibre movement testing, including the current placement timings To maximise the scientific output from WEAVE, I applied a series of adjustments to a subset of target fields, identifying methods that will improve the survey output using the fibre assignment program, Configure, and highlight potential selection effects. Chapter five presents the first-light results and the steps taken to achieve this. It required extensive measurements of the optical distortion map across the FoV, which were carefully mapped using astrometry of the night-sky across our focal plane. I then compare these results with the observational requirements from WEAVE's conception, to define its overall success. Chapter 6 provides an overview of the work completed in this thesis and describes potential upgrades to the instrument in the future.

Published

2023

7. Performance analysis and optimization of solar multiconjugate adaptive optics systems.

Author

Ke, Zibo, Zhang, Lanqiang, Yang, Ying, and Rao, Changhui

Subjects

*ADAPTIVE optics, *SOLAR telescopes, *SOLAR system, *TELESCOPES

Abstract

Multiconjugate adaptive optics (MCAO) stands as an essential technology for the development of future large-aperture solar telescopes. Its primary objective is to empower telescopes to achieve nearly diffraction-limited performance while substantially extending the correction field of view (FoV). Conventional solar MCAO relies on the combination of adaptive optics and high-altitude correction (AO + HAC) modules for multiconjugate correction. However, this architectural approach excels in correction performance primarily at the central position, with performance deteriorating as one moves farther from the centre. Consequently, it results in poor consistency of FoV correction performance. To address these limitations, a new architectural approach was introduced, which combines ground layer AO with HAC (GLAO + HAC). Preliminary results have shown that, compared to AO + HAC, this approach significantly enhances FoV correction uniformity. Building upon these initial findings, this paper undertakes a more extensive research of the GLAO + HAC system. Its objective is to compare various solar MCAO system architectures, including AO + HAC, GLAO + HAC, and general MCAO, to finally propose optimization tailored to GLAO + HAC. Through this analysis, the paper conducts the performance comparison between GLAO + HAC and general MCAO. It underscores that, under equivalent configuration parameters, the differences between these two systems are marginal. However, due to the advantage of the independent control of dual correction modules in GLAO + HAC, it can introduce an optimization strategy by increasing the number of subapertures at the cost of reducing the GLAO guide star sensing FoV. Finally, the results of this strategy demonstrate an obvious enhancement in performance and FoV correction consistency within the GLAO + HAC system. [ABSTRACT FROM AUTHOR]

Published

2024

8. Design and Characterization of the Engineering Model of the Spectrometer Onboard LuSEE‐Night.

Author

Tamura, Emi, Fried, Jack, Herrmann, Sven, O'Connor, Paul, Raguzin, Eric J., and Slosar, Anže

Subjects

ENGINEERING models, ENGINEERING design, SPECTROMETERS, DIGITAL electronics, LUNAR surface

Abstract

The Lunar Surface Electromagnetics Explorer—Night, LuSEE‐Night, is a low‐frequency radio astronomy experiment that will explore the cosmic Dark Ages signal on the radio‐quiet farside of the Moon. The LuSEE‐Night carries a radio frequency spectrometer consisting of a set of antennas, analog and digital processing electronics, and will be launched by NASA's Commercial Lunar Payload Services in 2025. The spectrometer is designed to observe the spectrum of the radio sky in the 0.5−50 MHz band. The engineering model (EM) of the four‐channel spectrometer has been developed. The EM has been characterized for linearity, gain, noise, and their temperature dependence, confirming that the EM meets all the requirements for LuSEE‐Night. Three mitigation techniques have been implemented and verified to suppress self‐induced electromagnetic interference. The flight model of the spectrometer is currently being developed and is scheduled to be shipped to the integration site in early 2024. Plain Language Summary: LuSEE‐Night is a four‐channel radio spectrometer scheduled for delivery to the lunar farside in 2025. The 0.5−50 MHz instrument is a pathfinder intended to explore the feasibility of searching the 21 cm global spectrum from the Dark Ages epoch of the early Universe. The engineering model of the LuSEE‐Night spectrometer was evaluated for gain, bandwidth, and noise and confirmed to meet the mission requirements. Its temperature dependence was measured and found to be within the requirements. Three mitigation techniques have been implemented to suppress electromagnetic interference; all switching waveforms must be limited to multiples of the system frequency of 100 kHz, the differential sensing of the input signals in the analog signal chain, and the notch filter of the field‐programmable gate array spectral engine. These techniques can be verified to effectively remove the artificial switching noise. The flight model of the spectrometer is being developed. Key Points: The engineering model of the spectrometer developed for the LuSEE‐Night mission meets all mission requirementsThree mitigation techniques have been successfully implemented to suppress electromagnetic interferenceThe flight model is currently being developed and will be delivered to the integration site in early 2024 [ABSTRACT FROM AUTHOR]

Published

2024

9. The Science Performance of the Gemini High Resolution Optical Spectrograph.

Author

McConnachie, Alan W., Hayes, Christian R., Robertson, J. Gordon, Pazder, John, Ireland, Michael, Burley, Greg, Churilov, Vladimir, Lothrop, Jordan, Zhelem, Ross, Kalari, Venu, Anthony, André, Baker, Gabriella, Berg, Trystyn, Chapin, Edward L., Chin, Timothy, Densmore, Adam, Diaz, Ruben, Dunn, Jennifer, Edgar, Michael L., and Farrell, Tony

Subjects

*OPTICAL resolution, *SPECTROGRAPHS, *HIGH resolution spectroscopy, *VELOCITY measurements

Abstract

The Gemini High Resolution Optical Spectrograph (GHOST) is a fiber-fed spectrograph system on the Gemini South telescope that provides simultaneous wavelength coverage from 348 to 1061 nm, and is designed for optimal performance between 363 and 950 nm. It can observe up to two objects simultaneously in a 7.′5 diameter field of regard at R ≃ 56,000 or a single object at R ≃ 75,000. The spectral resolution modes are obtained by using integral field units to image slice a 1.″2 aperture by a factor of five in width using 19 fibers in the high resolution mode and by a factor of three in width using 7 fibers in the standard resolution mode. GHOST is equipped with hardware to allow for precision radial velocity measurements, expected to approach meters per second precision. Here, we describe the basic design and operational capabilities of GHOST, and proceed to derive and quantify the key aspects of its on-sky performance that are of most relevance to its science users. [ABSTRACT FROM AUTHOR]

Published

2024

10. In situ cryogenic transmission electron microscopy observation on the formation of hydrogen-ordered hexagonal ices and its astrophysical implications.

Author

Yamazaki, Tomoya, Kouchi, Akira, Murata, Ken-ichiro, Katsuno, Hiroyasu, Nada, Hiroki, Hama, Tetsuya, and Kimura, Yuki

Subjects

*TRANSMISSION electron microscopy, *PROTOPLANETARY disks, *TRANSITION temperature

Abstract

Water ices play a critical role in various astrophysical phenomena and store information about the thermal history of icy grains. To understand this history, clarifying the formation conditions in astrophysical environments is critical. In addition to taking the form of amorphous ices, ice can take four crystalline forms: hexagonal ice I (ice Ih), cubic ice I (ice Ic) and hydrogen-ordered hexagonal ice (ice XIh) and cubic ice (ice XIc). The aim of this article is to study the conditions for phase transitions among these different crystalline ices. We found through cryogenic transmission electron microscopy observations that some polymorphs of ice XIh were formed by simple annealing of ice Ih at 120–150 K without any dopant or irradiation. We also investigated the formation conditions of ice Ih by vapour deposition and heating of ice Ic in protoplanetary discs. The transition kinetics from ice Ih to ice XIh suggested that ice XIh exists between the transition temperature from ice Ic to ice Ih and 150 K. From these results, we constructed a water-vapour flux–temperature–time diagram that clarifies the amorphous, Ic, Ih, XIc and XIh ice phases. We found that, under the conditions encountered in most protostars, hydrogen-ordered ices XIh and XIc can exist just outside the snow line and below 125 K, respectively. The infrared libration modes should enable these phases to be distinguished observationally. Because some of these phases are chiral, their presence could fundamentally affect the evolution of other homochiral organic molecules that develop on their surface. [ABSTRACT FROM AUTHOR]

Published

2024

11. Implementation and Application of a Regional Fireball Monitoring Network Based on All-sky Camera Networking.

Author

Zhi-jian, XU, Yan-shan, XIAO, Bin, LI, and Hai-bin, ZHAO

Subjects

*NEAR-Earth objects, *METEORS, *ORBITS (Astronomy), *SMALL solar system bodies, *CAMERAS, *METEORITES, *COMPUTER networking equipment

Abstract

Fireball monitoring network is the main equipment for monitoring impact from small-size near-Earth objects (NEOs), and determining meteorite fall locations. In this paper, a monitoring system using a multi-station distributed all-sky video camera network is proposed, and a regional prototype system has been constructed in Jiangsu and surrounding areas. The main processes of fireball monitoring were implemented, including network control, video capture, data processing, trajectory determination, and orbit calculation. After running for 1 yr, the results show that the limiting apparent magnitude - 1.0 for meteors in the video, and the absolute magnitude exhaustive detection regime can reach around - 2.5. The flux of fireballs is found to be 2.68 × 10 − 7 km − 2 · h − 1. The percentages of streams and sporadic meteors are 46% and 54%, respectively, and the fraction of cometary orbits equals 72.9%, while for asteroidal-type it is 27.1%. The statistical results are close to those of the international meteor monitoring networks, which verified the monitoring capability of the network system in practical operation. [ABSTRACT FROM AUTHOR]

Published

2024

12. First Constraints on Helium + He 3 Evolution in z = 3–4 Using the 8.67 GHz Hyperfine Transition.

Author

Trott, Cathryn M. and Wayth, Randall B.

Subjects

*RADIO interference, *HELIUM, *POWER spectra, *ANTENNAS (Electronics), *PROOF of concept

Abstract

We present the first constraints on the cross-correlation power spectrum of the He ii (+He3) signal strength using the redshifted 8.67 GHz hyperfine transition between z = 2.9 and 4.1 and with interferometric data obtained from the public archive of the Australia Telescope Compact Array (ATCA). 210 hr of observations of the primary calibrator source B1934-638 were extracted from data obtained with the telescope from 2014–2021, and coherently combined in a power spectrum pipeline to measure the He ii power across a range of spatial scales, and at three redshifts that span the period of helium reionization. Our best limit places the fluctuation of the brightness temperature to be less than 557 μ K on spatial scales of 30′ at z = 2.91, and less than 755 μ K on scales of 30′ at z = 4.14 (2 σ noise limited). We measure a temperature of 489 μ K at z = 2.91. ATCA's few antennas and persistent remaining radio frequency interference in the data prevent deeper integrations improving the results. This work is a proof of principle to demonstrate how this type of experiment can be undertaken to reach the 0.01–1 μ K level expected for the helium signal at z ∼ 4. [ABSTRACT FROM AUTHOR]

Published

2024

13. The Fibre Resolved OpticAl and Near-Ultraviolet Czerny–Turner Imaging Spectropolarimeter (francis).

Author

Jess, David B., Grant, Samuel D. T., Bate, William, Liu, Jiajia, Jafarzadeh, Shahin, Keys, Peter H., Vieira, Luís E. A., Dal Lago, Alisson, Guarnieri, Fernando L., Christian, Damian J., Gilliam, Doug, and Banerjee, Dipankar

Subjects

*SUN, *SOLAR telescopes, *SPECTRAL lines, *QUANTUM efficiency, *FIBERS

Abstract

The solar physics community is entering a golden era that is ripe with next-generation ground- and space-based facilities, advanced spectral inversion techniques, and realistic simulations that are becoming more computationally streamlined and efficient. With ever-increasing resolving power stemming from the newest observational telescopes, it becomes more challenging to obtain (near-)simultaneous measurements at high spatial, temporal and spectral resolutions, while operating at the diffraction limit of these new facilities. Hence, in recent years there has been increased interest in the capabilities integral field units (IFUs) offer towards obtaining the trifecta of high spatial, temporal and spectral resolutions contemporaneously. To date, IFUs developed for solar physics research have focused on mid-optical and infrared measurements. Here, we present an IFU prototype that has been designed for operation within the near-ultraviolet to mid-optical wavelength range, which enables key spectral lines (e.g., Ca ii H/K, H β , Sr ii, Na i D1/D2, etc.) to be studied, hence providing additional spectral coverage to the instrument suites developed to date. The IFU was constructed as a low-budget proof-of-concept for the upcoming 2 m class Indian National Large Solar Telescope and employs circular cross-section fibres to guide light into a Czerny–Turner configuration spectrograph, with the resulting spectra captured using a high quantum efficiency scientific CMOS camera. Mapping of each input fibre allows for the reconstruction of two-dimensional spectral images, with frame rates exceeding 20 s − 1 possible while operating in a non-polarimetric configuration. Initial commissioning of the instrument was performed at the Dunn Solar Telescope, USA, during August 2022. The science verification data presented here highlights the suitability of fibre-fed IFUs operating at near-ultraviolet wavelengths for solar physics research. Importantly, the successful demonstration of this type of instrument paves the way for further technological developments to make a future variant suitable for upcoming ground-based and space-borne telescope facilities. [ABSTRACT FROM AUTHOR]

Published

2023

14. Characterization and mitigation of terrestrial and astrophysical foreground effects in 21cm cosmology

Author

Josaitis, Alec and De Lera Acedo, Eloy

Subjects

Radio Interferometry, 21cm Cosmology, Astronomical Instrumentation

Abstract

I present a PhD thesis with four primary contributions relevant to the commissioning of 21cm cosmology experiments, the first two being devoted to the characterization and mitigation of VHF-band radio frequency interference (RFI), and the last two being devoted to the characterization and mitigation of astrophysical foregrounds in radio interferometers, in the presence of mutual coupling between array elements. First, The SDR Pathfinder for Understanding Transient and Noise-level Interference in the Karoo (SPUTNIK) is presented. I describe how a low-cost RFI monitoring system, using solely consumer-off-the-shelf (COTS) components, directly contributes to the analysis efforts of a precision 21cm cosmology instrument. A SPUTNIK system overview is provided, as well as a generalized software-defined radio (SDR) internal calibration technique to achieve wideband, ±1.5 dBm-level accuracy and a measured dynamic range of ≥40dB. Second, I present findings from a survey of the 50-240 MHz radio spectrum at various locations of the SKA-SA core site, the results of which informed the site selection for the Radio Experiment for the Analysis of Cosmic Hydrogen (REACH), a global 21cm experiment. Third, I derive a general formalism for interferometric visibilities, which considers first-order antenna-antenna coupling and assumes steady-state, incident radiation. I simulate such coupling features for non-polarized skies on a compact, redundantly-spaced array and present a phenomenological analysis of the coupling features. Contrary to previous studies, I find mutual coupling features manifest themselves at nonzero fringe rates. For all studied baseline lengths, baseline orientations, and local sidereal times (LSTs), coupling features appear at delays which are outside the foreground `wedge', which has been studied extensively and contains non-coupled astrophysical foreground features. Fourth, I analyze HERA Phase II data for systematics related to mutual coupling between array elements. For all baselines and frequencies studied, I find coupling features to be consistent with predictions made from the semi-analytic model. To mitigate these effects, which if ignored could prevent HERA Phase II from placing competitive upper limits on (or making a detection of) the EoR signal, I apply a fringe-rate filter and baseline orientation de-selection strategy to both the observed and simulated data. While the noise floors of the observed power spectra are too high to directly compare improvements to simulation, through application of the mitigation strategy to simulated power spectra I find that, in both LST ranges analyzed, some k-modes are consistent with having no coupling effects down to at least Δ² = 50[(mK)²h⁻³Mpc³k³/(2π²)], a level consistent with fiducial models of the 21cm power spectrum. The semi-analytic coupling model herein presented is not only helpful to the field of 21cm cosmology, but any study involving interferometric measurements, where coupling effects at the level of at least 1 part in $10^4$ could corrupt the scientific result. The model may be used to mitigate coupling systematics in existing radio interferometers and to design future arrays where the configuration of array elements inherently mitigates coupling effects at desired LSTs and angular resolutions.

Published

2022

15. Vortex Fiber Nulling for Exoplanet Observations: First Direct Detection of M Dwarf Companions around HIP 21543, HIP 94666, and HIP 50319

Author

Daniel Echeverri, Jerry W. Xuan, John D. Monnier, Jacques-Robert Delorme, Jason J. Wang, Nemanja Jovanovic, Katelyn Horstman, Garreth Ruane, Bertrand Mennesson, Eugene Serabyn, Dimitri Mawet, J. Kent Wallace, Sofia Hillman, Ashley Baker, Randall Bartos, Benjamin Calvin, Sylvain Cetre, Greg Doppmann, Luke Finnerty, Michael P. Fitzgerald, Chih-Chun Hsu, Joshua Liberman, Ronald López, Maxwell Millar-Blanchaer, Evan Morris, Jacklyn Pezzato, Jean-Baptiste Ruffio, Ben Sappey, Tobias Schofield, Andrew J. Skemer, Ji Wang, Yinzi Xin, Narsireddy Anugu, Sorabh Chhabra, Noura Ibrahim, Stefan Kraus, Gail H. Schaefer, and Cyprien Lanthermann

Subjects

Exoplanet detection methods, Astronomical instrumentation, Direct detection interferometry, High resolution spectroscopy, Companion stars, Astrophysics, QB460-466

Abstract

Vortex fiber nulling (VFN) is a technique for detecting and characterizing faint companions at small separations from their host star. A near-infrared (∼2.3 μ m) VFN demonstrator mode was deployed on the Keck Planet Imager and Characterizer (KPIC) instrument at the Keck Observatory and presented earlier. In this Letter, we present the first VFN companion detections. Three targets, HIP 21543 Ab, HIP 94666 Ab, and HIP 50319 B, were detected with host–companion flux ratios between 70 and 430 at and within one diffraction beamwidth ( λ / D ). We complement the spectra from KPIC VFN with flux ratio and position measurements from the CHARA Array to validate the VFN results and provide a more complete characterization of the targets. This Letter reports the first direct detection of these three M dwarf companions, yielding their first spectra and flux ratios. Our observations provide measurements of bulk properties such as effective temperatures, radial velocities, and $v\sin i$ , and verify the accuracy of the published orbits. These detections corroborate earlier predictions of the KPIC VFN performance, demonstrating that the instrument mode is ready for science observations.

Published

2024

16. A summary of instruments proposed for observing pulsating variables from the Mt. Abu Observatory

Author

Mishra, Anwesh Kumar, Sarkar, Deekshya Roy, Prajapati, Prachi, Singh, Alka, Kasarla, Prashanth K., and Ganesh, Shashikiran

Published

2024

17. The Radiation Environments of Middle-aged F-type Stars.

Author

Cruz Aguirre, F., France, K., Nell, N., Kruczek, N., Fleming, B., Hinton, P. C., Ulrich, S., and Behr, P. R.

Subjects

*SPECTRAL energy distribution, *RADIAL velocity of stars, *RADIATION, *ULTRAVIOLET radiation, *DWARF stars, *STELLAR activity, *STELLAR orbits

Abstract

Far-ultraviolet (FUV) emission lines from dwarf stars are important driving sources of photochemistry in planetary atmospheres. Properly interpreting spectral features of planetary atmospheres critically depends on the emission of its host star. While the spectral energy distributions (SEDs) of K- and M-type stars have been extensively characterized by previous observational programs, the full X-ray to infrared SED of F-type stars has not been assembled to support atmospheric modeling. On the second flight of the Suborbital Imaging Spectrograph for Transition-region Irradiance from Nearby Exoplanet host stars (SISTINE-2) rocket-borne spectrograph, we successfully captured the FUV spectrum of Procyon A (F5 IV-V) and made the first simultaneous observation of several emission features across the FUV bandpass (1010–1270 and 1300–1565 Å) of any cool star. We combine flight data with stellar models and archival observations to develop the first SED of a mid-F star. We model the response of a modern Earth-like exoplanet's upper atmosphere to the heightened X-ray and extreme UV radiation within the habitable zone of Procyon A. These models indicate that this planet would not experience significant atmospheric escape. We simulate observations of the Ly α transit signal of this exoplanet with the Hubble Space Telescope (HST) and the Habitable Worlds Observatory (HWO). While marginally detectable with HST, we find that H i Ly α transits of potentially habitable exoplanets orbiting high radial velocity F-type stars could be observed with HWO for targets up to 150 pc away. [ABSTRACT FROM AUTHOR]

Published

2023

18. Estimation of the Atmospheric Turbulence Parameters Using the Angle-of-Arrival Covariance Function.

Author

Bennoui, F. and Bahloul, D.

Abstract

The Fried's length r0, the outer scale L0, the isoplanatism θ0, the coherence time τ0, and the profile of the optical turbulence energy are parameters of the wavefront spatiotemporal coherence. Numerous optical methods are used to determine the images quality through the estimation of the parameters r0, L0, θ0, and τ0, where numerical simulations of the transversal and longitudinal covariance (as a function of the angle-of-arrival (AA)) play a significant role. In this work, we, first, perform the statistical analysis of the fluctuations of angle-of-arrival using theoretical models of the atmospheric turbulence, and second, the statistical analysis of the AA fluctuations in solar limb images. This analysis plays a significant role in the optimization of techniques, such as adaptive optics (OA) and in interferometry, in astronomical observations with high angular resolution. [ABSTRACT FROM AUTHOR]

Published

2023

19. The Near Infrared Imager and Slitless Spectrograph for the James Webb Space Telescope. I. Instrument Overview and In-flight Performance.

Author

René, Doyon, Willott, Chris J., Hutchings, John B., Sivaramakrishnan, Anand, Albert, Loïc, Lafrenière, David, Rowlands, Neil, Vila, M. Begoña, Martel, André R., LaMassa, Stephanie, Aldridge, David, Artigau, Étienne, Cameron, Peter, Chayer, Pierre, Cook, Neil J., Cooper, Rachel A., Darveau-Bernier, Antoine, Dupuis, Jean, Earnshaw, Colin, and Espinoza, Néstor

Subjects

*SPECTROGRAPHS, *ANGULAR distance, *BINARY stars, *SPACE vehicles, *PHOTOMETRY, *SPECTROMETRY, *SPACE telescopes

Abstract

The Near-Infrared Imager and Slitless Spectrograph (NIRISS) is the science module of the Canadian-built Fine Guidance Sensor onboard the James Webb Space Telescope (JWST). NIRISS has four observing modes: (1) broadband imaging featuring seven of the eight NIRCam broadband filters, (2) wide-field slitless spectroscopy at a resolving power of ∼150 between 0.8 and 2.2 μ m, (3) single-object cross-dispersed slitless spectroscopy (SOSS) enabling simultaneous wavelength coverage between 0.6 and 2.8 μ m at R ∼ 700, a mode optimized for exoplanet spectroscopy of relatively bright (J < 6.3) stars and (4) aperture masking interferometry (AMI) between 2.8 and 4.8 μ m enabling high-contrast (∼10−3 − 10−4) imaging at angular separations between 70 and 400 mas for relatively bright (M < 8) sources. This paper presents an overview of the NIRISS instrument, its design, its scientific capabilities, and a summary of in-flight performance. NIRISS shows significantly better response shortward of ∼2.5 μ m resulting in 10%–40% sensitivity improvement for broadband and low-resolution spectroscopy compared to pre-flight predictions. Two time-series observations performed during instrument commissioning in the SOSS mode yield very stable spectro-photometry performance within ∼10% of the expected noise. The first space-based companion detection of the tight binary star AB Dor AC through AMI was demonstrated. [ABSTRACT FROM AUTHOR]

Published

2023

20. Applications of High-Contrast Imaging Techniques and Polarimetry to (Exo-)Planetary Science

Author

Lewis, Briley Lynn

Subjects

Astronomy, Astrophysics, Planetology, Astronomical instrumentation, Debris disks, Europa, Exoplanets, Infrared astronomy, Polarimetry

Abstract

The goal of this thesis is to characterize circumstellar disks and substellar objects, from moons to brown dwarfs, by improving and applying techniques from high-contrast imaging. To do so, I led four projects, two of which expand the range of targets accessible by high-contrast imaging. In Project 1, I develop an improved algorithm for high-contrast imaging data processing, enabling detection of fainter, smaller planets; this algorithm uses both spatial and temporal information on the speckle noise present in high-contrast images, and will be especially useful for next-generation photon-counting detectors such as Microwave Kinetic Inductance Detectors (MKIDs). In Project 2, I demonstrate a new technique to detect and monitor ejections of ice particles from subsurface oceans on outer solar system bodies, such as Jupiter’s icy moon Europa, using ground-based polarimetric imaging. Such plumes have not been confirmed on Europa, but are of significant interest for astrobiology and planning for the upcoming Europa Clipper mission.The remaining two projects use existing analysis techniques to investigate individual systems of interest that add to our understanding of planet formation. In Project 3, I characterize the atmosphere of a brown dwarf around HIP 93398, a recently discovered companion identified via the Hipparcos Gaia Catalog of Accelerations, using high-resolution spectra from SCExAO/CHARIS. With both a dynamical mass measurement and high-resolution spectroscopy, HIP 93398 B provides substantial constraints on models of brown dwarf evolution. In Project 4, I constrain the morphology and scattering properties of the debris disk around the bright star HD 155623, a unique “hybrid” debris disk that shows signs of youth despite its age, using polarimetric data from the Gemini Planet Imager. With the information from my investigation, the HD 156623 system can now serve as a benchmark for models aiming to explain how gas and dust interact during the later stages of planet formation. These investigations both further innovation in exoplanet imaging techniques and, respectively, provide insight into detections of extrasolar planets, the nature of oceans beyond Earth, the mechanisms of planet formation, and the atmospheres of giant planets and brown dwarfs.

Published

2024

21. Telescopes and techniques for the high-resolution characterisation of exoplanets

Author

Hawker, George, Parry, Ian, and Madhusudhan, Nikku

Subjects

Astronomical Instrumentation, Exoplanet Atmospheres

Abstract

In this thesis I present two strands of research relating to the characterisation of exoplanets in high resolution. The first investigates high-resolution Doppler spectroscopy (HRDS) - a technique for detecting chemical species in exoplanet atmospheres. I present results from analysing high-resolution spectra of three hot Jupiters - HD 209458b, HD 189733b and 51 Pegasi b. Evidence for H2O, CO and of HCN was found in all three datasets - the latter molecule had not previously been found in an exoplanet atmosphere. These studies used HRDS analysis techniques common to the literature but put their associated hyperparameters on an explicit, quantitative footing. This meant different techniques could have their robustness probed and be compared. Doing so revealed that the removal of telluric contamination from infrared spectra should be treated carefully as it has the potential to introduce biases in detections of chemical species. If robust though, such HRDS detections could aid the tracing of exoplanets' formation and migration histories which are thought to leave significant imprints on their present day atmospheric compositions. The second strand of my research is in developing SUPER-SHARP, an optical alignment technology for use in future large aperture unfolding space telescopes. Such facilities and technologies are needed for conducting the high spatial resolution observations required for characterising Earth-like exoplanets. In this work I have developed an automated alignment routine for telescopes with segmented primary mirrors. Starting from methods documented in the literature, I derived the necessary theory and validated the routine using numerical and ray tracing simulations. I then tested it experimentally by implementing the alignment routine - producing a proof-of-concept self-aligning telescope capable of capturing diffraction-limited thermal infrared imagery. This technology demonstrator has an autonomously aligned segmented primary mirror. It achieves sub-micron alignment through the use of optical metrology and nano-positioning actuators driven by my software in a closed loop control system. Finally, I also prototyped and tested potentially novel primary mirror optics that were invented to improve the compactness/practicality of this alignment technology.

Published

2021

22. Designing a beam combiner for faint limiting magnitudes in optical interferometry

Author

Mortimer, Daniel and Buscher, David

Subjects

optical interferometry, Optical design, astronomical instrumentation

Abstract

In this thesis I present and discuss the work carried out during my PhD in the astrophysics group of the Cavendish Laboratory. The majority of this work has been to develop the Free-space Optical multi-apertUre combineR for IntERferometry (FOURIER), a novel, high sensitivity, near-infrared beam combiner intended to be the first generation science beam combiner for the Magdalena Ridge Observatory Interferometer (MROI). FOURIER is a three telescope, J, H and K band image plane beam combiner. I first highlight the scientific motivation for a faint limiting magnitude beam combiner and the design requirements this placed on FOURIER. This is followed by a discussion of how the optical design was derived from these requirements. The simulated performance of the instrument is then discussed including the alignment and manufacturing error budget, limiting magnitude estimation, spectral resolution and modelling of thermal effects on cooling the instrument to its liquid nitrogen operating temperature. The cryogenic optomechanics are described as well as a series of laboratory tests of the fringe contrast, spectral resolution and throughput to verify the instruments performance. In addition to the development of FOURIER I discuss a numerical simulation of an optical interferometer subject to atmospheric seeing, used to quantify previously unaccounted for image plane crosstalk effects arising due to various combinations of atmospheric seeing, long propagation distances and finite sized optics present in long baseline optical interferometers.

Published

2021

23. Measuring and calibrating non-common path aberrations in adaptive optics assisted image-slicer based spectrographs

Author

Menduina, Alvaro, Thatte, Niranjan, and Tecza, Matthias

Subjects

Machine learning, astronomical instrumentation

Abstract

HARMONI is the first-light, visible and near-IR integral field spectrograph for ESO's Extremely Large Telescope (ELT), which promises to revolutionise observational astrophysics with its high spatial resolution, offering quasi-diffraction-limited performance from a ground-based observatory. The performance of Adaptive Optics assisted instruments such as HARMONI is hindered by the presence of differential aberrations between the AO wavefront sensing and science optical paths, known as NonCommon Path Aberrations (NCPA). These aberrations, which primarily affect the spatial point spread function (PSF) in HARMONI, cannot be sensed directly due to the absence of phase information in focal plane intensity measurements, so special techniques are needed to calibrate and pre-compensate them. This is particularly problematic in high-contrast observations aimed at detecting and characterising exoplanets, as NCPA give rise to quasi-static speckles that resemble planetary signals and severely limit the contrast. Although extensive research has been devoted to developing NCPA calibration techniques for AO systems and coronagraphic instruments, these have not been demonstrated in the context of integral field spectrographs like HARMONI that contain an image slicer. This optical component, made out of a stack of thin mirrors, slices a 2D field of view into slitlets and re-arranges them into a long pseudo-slit that can be dispersed by a spectrograph. The effects of an image slicer on light propagation could have a negative impact on the behaviour of state-of-the-art techniques for NCPA calibration, and require modifications to account for these effects to ensure they could be applied to instruments such as HARMONI. This DPhil thesis makes several novel contributions to this field of research. First of all, I have investigated the impact of an image slicer on light propagation and characterised its effects on the PSF following two approaches: a theoretical one, using a mathematical framework crossvalidated with simulations based on optical models of the HARMONI sub-systems; and an experimental one, for which I have designed and conducted an experiment with the engineering model of the SWIFT instrument image slicer. Secondly, given that image slicers can affect the relationship between phase aberrations and focal plane intensity, and the unproven behaviour of traditional techniques, I decided to explore alternative approaches that could circumvent this drawback. I have developed a novel technique for NCPA calibration that relies on machine learning methods to estimate the aberrations directly from PSF images. I have demonstrated that this technique can discriminate between features from image slicers and features caused by aberrations in the system. I have thoroughly characterised its response to multiple sources of uncertainty and shown how it can be successfully applied to HARMONI. Lastly, I have developed the capability to create and analyse End-toEnd Monte Carlo models of HARMONI that aggregate the different subsystems to form a realistic representation of how the as-built instrument would behave. This has been used to support our calibration efforts in multiple ways: to characterise the expected level of NCPA in the system and its major contributors, to define requirements for NCPA calibration accuracy based on the intrinsic limitation of field-dependent aberrations, and to train the machine learning calibration models with realistic wavefront maps that reproduce the typical NCPA that we will encounter in HARMONI. All of these efforts shed light on the question of how NCPA can be calibrated in instruments that contain image slicers, and will pave the way for its future application in HARMONI. The only missing piece of the puzzle is the thorough characterisation of how image slicers impact the behaviour of traditional methods like Phase Diversity and how they could be adapted to account for such effects. Due to time constraints, this could not be fully explored and will be the subject of future research.

Published

2021

24. Imaging exoplanets with coronagraphic instruments

Author

Galicher, Raphaël and Mazoyer, Johan

Subjects

Exoplanets, Astronomical Instrumentation, Coronagraphy, high-contrast imaging, high-angular resolution, Physics, QC1-999

Abstract

Exoplanetary science is a very active field of astronomy nowadays, with questions still opened such as how planetary systems form and evolve (occurrence, process), why such a diversity of exoplanets is observed (mass, radius, orbital parameters, temperature, composition), and what are the interactions between planets, circumstellar disk and their host star. Several complementary methods are used for the detection of exoplanets. Among these, imaging aims at the direct detection of the light reflected, scattered or emitted by exoplanets and circumstellar disks. This allows their spectral and polarimetric characterization. Such imaging remains challenging because of the large luminosity ratio ($10^4$-$10^{10}$) and the small angular separation (fraction of an arcsecond) between the star and its environment. Over the past two decades, numerous techniques, including coronagraphy, have been developed to make exoplanet imaging a reality.This paper gives a broad overview of the subsystems that make up a coronagraphic instrument for imaging exoplanetary systems. It is especially intended for non-specialists or newcomers in the field. We explain the principle of coronagraphy and propose a formalism to understand their behavior. We discuss the impact of wavefront aberrations on the performance of coronagraphs and how they induce stellar speckles in the scientific image. Finally, we present instrumental and signal processing techniques used for on-sky minimization or a posteriori calibration of these speckles in order to improve the performance of coronagraphs.

Published

2023

25. Splendid squirrel sneezes at will

Published

2024

26. Probing the Atmospheric Precipitable Water Vapor with SOFIA, Part. IV. Water Vapor Estimates from FORCAST Grism Spectra.

Author

Vacca, W. D., Iserlohe, C., Shenoy, S., Clarke, M., Fischer, C., Thorpe, A., and Chambers, E.

Subjects

*PRECIPITABLE water, *ATMOSPHERIC water vapor, *WATER vapor, *ATMOSPHERIC water vapor measurement, *ATMOSPHERE, *DATA libraries

Abstract

SOFIA was an airborne observatory for far-infrared astronomy stationed at the Armstrong Flight Research Center in Palmdale, CA, USA. Although SOFIA flew at altitudes of ∼41,000 ft, any far-infrared observations from within the Earth's atmosphere are nevertheless hampered by water vapor absorbing the astronomical signal. The primary atmospheric parameter governing absorption at far-infrared wavelengths is the total upward precipitable water vapor (PWV). In this paper we present a method of deriving PWV values directly from low resolution (R ∼ 100–200) mid-infrared (5–40 μ m) spectroscopic observations and apply it to low resolution grism spectra obtained with the FORCAST instrument on-board SOFIA. We then compare these values with those determined from the fifth European Re-analysis (ERA5) of the global atmospheric parameters provided by the European Centre for Medium-Range Weather Forecasts (ECMWF) for the time and altitude corresponding to the SOFIA observations. In general, we find a very good correlation between the ERA5-ECMWF values and the values derived from the FORCAST grism spectra, especially for high signal-to-noise ratio data. These results indicate that ERA5-ECMWF PWV values can be used to generate the telluric corrections for FORCAST imaging data as well as grism spectra for which the PWV values cannot be determined directly. We also derive the resolving power of the various grism and slit width combinations for FORCAST. Our results will be useful for reprocessing the FORCAST data in the SOFIA archive. [ABSTRACT FROM AUTHOR]

Published

2023

27. Diving deep into the milky way using anti-reflection coatings for astronomical CCDs.

Author

Aggarwal, Anmol, Mittal, Ashi, Seabroke, George M., and Puri, Nitin K.

Subjects

*MILKY Way, *DEEP diving, *ANTIREFLECTIVE coatings, *EDIBLE coatings, *OPTICAL astronomy, *TANTALUM compounds, *TANTALUM oxide

Abstract

We report two anti-reflection (AR) coatings that give better quantum efficiency (QE) than the existing AR coating on the Gaia astrometric field (AF) charged coupled devices (CCDs). Light being the core of optical astronomy is extremely important for such missions, therefore, the QE of the devices that are used to capture it should be substantially high. To reduce the losses due to the reflection of light from the surface of the CCDs, AR coatings can be applied. Currently, the main component of the Gaia satellite, the AF CCDs use hafnium dioxide (HfO2) AR coating. In this paper, the ATLAS module of the SILVACO software has been employed for simulating and studying the AF CCD pixel structure and several AR coatings. Our findings suggest that zirconium dioxide (ZrO2) and tantalum pentoxide (Ta2O5) will prove to be better AR coatings for broadband astronomical CCDs in the future and will open new avenues to understand the evolution of the milky way. [ABSTRACT FROM AUTHOR]

Published

2023

28. Classifying FRB spectrograms using nonlinear dimensionality reduction techniques.

Author

Yang, X, Zhang, S-B, Wang, J-S, and Wu, X-F

Subjects

*DIMENSIONAL reduction algorithms, *DIMENSION reduction (Statistics), *SPECTROGRAMS

Abstract

Fast radio bursts (FRBs) are mysterious astronomical phenomena, and it is still uncertain whether they consist of multiple types. In this study, we use two nonlinear dimensionality reduction algorithms – Uniform Manifold Approximation and Projection (UMAP) and t-distributed stochastic neighbour embedding (t-SNE) – to differentiate repeaters from apparently non-repeaters in FRBs. Based on the first Canadian Hydrogen Intensity Mapping Experiment (CHIME) FRB catalogue, these two methods are applied to standardized parameter data and image data from a sample of 594 sub-bursts and 535 FRBs, respectively. Both methods are able to differentiate repeaters from apparently non-repeaters. The UMAP algorithm using image data produces more accurate results and is a more model-independent method. Our result shows that in general repeater clusters tend to be narrowband, which implies a difference in burst morphology between repeaters and apparently non-repeaters. We also compared our UMAP predictions with the CHIME/FRB discovery of six new repeaters, the performance was generally good except for one outlier. Finally, we highlight the need for a larger and more complete sample of FRBs. [ABSTRACT FROM AUTHOR]

Published

2023

29. QTT Ultra-wideband Signal Acquisition and Baseband Data Recording System Design Based on the RFSoC Platform.

Author

Pei, Xin, Li, Jian, Duan, Xuefeng, and Zhang, Hailong

Subjects

*VERY long baseline interferometry, *SYSTEMS design, *ACQUISITION of data, *DATA recorders & recording, *DATA collection platforms, *RADIO telescopes

Abstract

The 110 m QiTai radio Telescope (QTT) will be equipped with multiple Ultra-WideBand (UWB) receivers in the primary and Gregory focus to achieve continuous frequency coverage from 270 MHz to 115 GHz, which poses great challenges to signal acquisition, transmission, and real-time processing. Aiming at 10 GHz and above full-bandwidth acquisition and multi-scientific processing for the QTT UWB signals, an experimental system with high-speed signal acquisition, 100 Gb network multi-path distribution, and fast recording is designed by using advanced direct RF-sampling technology and heterogeneous architecture. The system employs a ZCU111 board to digitize dual-polarization signals with a sampling rate of 4.096 GigaSamples-Per-Second and 12-bit quantization. The collected wideband signals are channelized into 2048 chunks, which are then assembled into 16 sets of digital narrow basebands with 128 MHz bandwidth and transmitted to the processing servers through two 100 Gb ports. A HASPIPE pipeline, UWB_HASHPIPE is designed to receive and store multiple subbands in parallel. Data distribution links can be flexibly configured based on IP addresses and port numbers. The system is verified by pulsar observation experiments on the Nanshan 26 m telescope. 512 MHz bandwidth is selected from the collected L -band receiver signals and recorded in VDIF file format with 8 parallel instances. The test results show that the data integrity is excellent, and the signal-to-noise ratio of the band-merged pulsar profile is stronger than single subband data. This paper provides a high-performance and flexible solution for the design of versatile UWB backends. Meanwhile, the developed platform can be integrated into QTT backends for baseband data collection and Very Long Baseline Interferometry observation. [ABSTRACT FROM AUTHOR]

Published

2023

30. A Method of Superimposing Subapertures for Shark–Hartmann Wave Front Sensing with Faint Objects.

Author

Wu, Xiaosong, Huang, Linhai, and Gu, Naiting

Subjects

*ADAPTIVE optics, *SOLAR telescopes, *SYNCOPE, *PHOTON flux, *SIGNAL-to-noise ratio, *ATMOSPHERIC turbulence

Abstract

For the astronomical adaptive optics systems, the observation condition is always in a regime of low photon flux. We present a method of superimposing subapertures for the Shark–Hartmann wave front sensing with faint objects. This approach significantly improves the signal-to-noise ratio (S/N) of the spot pattern by superimposing adjacent subapertures, thus circumventing the invalid wave front sensing with faint object, enhancing the accuracy of the wave front detection. In addition, we demonstrate that the validity of this approach is not an incidental result under a specific condition, which can be explained theoretically by exploiting the atmospheric turbulence model. Then we validate the approach with simulations and experimental realization under weak-light and bright-light conditions. Results show that the proposed subaperture superposition approach can achieve accurate wave front reconstruction for low S/N or faint object even in cases beyond the ability of conventional methods. It brings out a new idea, besides long exposure and variable sampling, that comes with a tradeoff between temporal sampling frequency and spatial resolution. In addition, this method is also valid for extended objects; we preliminarily validate this method on a 600 mm aperture solar telescope, achieving stable closed-loop control with lower-contrast objects. [ABSTRACT FROM AUTHOR]

Published

2023

31. The Near Infrared Imager and Slitless Spectrograph for the James Webb Space Telescope. III. Single Object Slitless Spectroscopy.

Author

Albert, Loïc, Lafrenière, David, René, Doyon, Artigau, Étienne, Volk, Kevin, Goudfrooij, Paul, Martel, André R., Radica, Michael, Rowe, Jason, Espinoza, Néstor, Roy, Arpita, Filippazzo, Joseph C., Darveau-Bernier, Antoine, Talens, Geert Jan, Sivaramakrishnan, Anand, Willott, Chris J., Fullerton, Alexander W., LaMassa, Stephanie, Hutchings, John B., and Rowlands, Neil

Subjects

*SCIENTIFIC apparatus & instruments, *SPECTROGRAPHS, *PLANETARY atmospheres, *ATMOSPHERE, *GAS giants, *SPACE telescopes, *INNER planets

Abstract

The Near Infrared Imager and Slitless Spectrograph instrument (NIRISS) is the Canadian Space Agency contribution to the suite of four science instruments of the James Webb Space Telescope. As one of the three NIRISS observing modes, the Single Object Slitless Spectroscopy (SOSS) mode is tailor-made to undertake time-series observations of exoplanets to perform transit spectroscopy. The SOSS permits observing point sources between 0.6 and 2.8 μ m at a resolving power of 650 at 1.25 μ m using a slitless cross-dispersing grism while its defocussing cylindrical lens enables observing targets as bright as J = 6.7 by spreading light across 23 pixels along the cross-dispersion axis. This paper officially presents the design of the SOSS mode, its operation, characterization, and its performance, from ground-based testing and flight-based commissioning. On-sky measurements demonstrate a peak photon conversion efficiency of 55% at 1.2 μ m. The first time series on the A-type star BD+60°1753 achieves a flux stability close to the photon-noise limit, so far tested to a level of 20 parts per million on a 40 minute timescale after simply subtracting a long-term trend. Uncorrected 1/ f noise residuals underneath the spectral traces add an extra source of noise equivalent to doubling the readout noise. Preliminary analysis of an HAT-P-14b transit time series indicates that it is difficult to remove all of the noise in pixels with partially saturated ramps. Overall, the SOSS delivers performance at the level required to tackle key exoplanetary science programs such as detecting secondary atmospheres on terrestrial planets and measuring abundances of several chemical species in gas giants. [ABSTRACT FROM AUTHOR]

Published

2023

32. Simulation of the Earth's radio-leakage from mobile towers as seen from selected nearby stellar systems.

Author

Saide, Ramiro C, Garrett, M A, and Heeralall-Issur, N

Subjects

*EARTH (Planet), *ALPHA Centauri, *NATURAL satellites, *MOBILE antennas, *PLANETARY surfaces, *RADIO technology, *POWER spectra

Abstract

Mobile communication towers represent a relatively new but growing contributor to the total radio-leakage associated with planet Earth. We investigate the overall power contribution of mobile communication towers to the Earth's radio leakage budget, as seen from a selection of different nearby stellar systems. We created a model of this leakage using publicly available data of mobile tower locations. The model grids the surface of the planet into small, computationally manageable regions, assuming a simple integrated transmission pattern for the mobile antennas. In this model, these mobile tower regions rise and set as the Earth rotates. In this way, a dynamic power spectrum of the Earth was determined, summed over all cellular frequency bands. We calculated this dynamic power spectrum from three different viewing points – HD 95735, Barnard's star, and Alpha Centauri A. Our preliminary results demonstrate that the peak power leaking into space from mobile towers is ∼4GW. This is associated with Long Term Evolution (LTE) mobile tower technology emanating from the East Coast of China as viewed from HD 95735. We demonstrate that the mobile tower leakage is periodic, direction dependent, and could not currently be detected by a nearby civilization located within 10 light-years of the Earth, using instrumentation with a sensitivity similar to the Green Bank Telescope. We plan to extend our model to include more powerful 5G mobile systems, radar installations, ground based up-links (including the Deep Space Network), and various types of satellite services, including low-Earth orbit constellations, such as Starlink and OneWeb. [ABSTRACT FROM AUTHOR]

Published

2023

33. A Digital Calibration Source for 21 cm Cosmology Telescopes.

Author

Bhopi, Kalyani, Tyndall, Will, Sanghavi, Pranav, Bandura, Kevin, Newburgh, Laura, and Gallicchio, Jason

Subjects

*TELESCOPES, *RADIO interferometers, *GLOBAL Positioning System, *AMPLITUDE estimation, *AIR traffic control

Abstract

Foreground mitigation is critical to all next-generation radio interferometers that target cosmology using the redshifted neutral hydrogen 21 cm emission line. Attempts to remove this foreground emission have led to new analysis techniques as well as new developments in hardware specifically dedicated to instrument beam and gain calibration, including stabilized signal injection into the interferometric array and drone-based platforms for beam mapping. The radio calibration sources currently used in the literature are broad-band incoherent sources that can only be detected as excess power and with no direct sensitivity to phase information. In this paper, we describe a digital radio source which uses Global Positioning Satellite (GPS) derived time stamps to form a deterministic signal that can be broadcast from an aerial platform. A copy of this source can be deployed locally at the instrument correlator such that the received signal from the aerial platform can be correlated with the local copy, and the resulting correlation can be measured in both amplitude and phase for each interferometric element. We define the requirements for such a source, describe an initial implementation and verification of this source using commercial Software Defined Radio boards, and present beam map slices from antenna range measurements using the commercial boards. We found that the commercial board did not meet all requirements, so we also suggest future directions using a more sophisticated chipset. [ABSTRACT FROM AUTHOR]

Published

2023

34. Scientific CMOS Sensors in Astronomy: IMX455 and IMX411.

Author

Alarcon, Miguel R., Licandro, Javier, Serra-Ricart, Miquel, Joven, Enrique, Gaitan, Vicens, and de Sousa, Rebeca

Abstract

Scientific complementary metal-oxide-semiconductor (CMOS) detectors have developed quickly in recent years thanks to their low cost and high availability. They also have some advantages over charge-coupled devices (CCDs), such as high frame rate or typically lower readout noise. These sensors started to be used in astronomy following the development of the first back-illuminated models. Therefore, it is worth studying their characteristics, advantages, and weaknesses. One of the most widespread CMOS sensors are those from the Sony IMX series, which are included in large astronomical survey projects based on small and fast telescopes because of their low cost, and capability for wide-field and high-cadence surveys. In this paper, we aim to characterize the IMX455M and IMX411M sensors, which are integrated into the QHY600 and QHY411 cameras, respectively, for use in astronomical observations. These are large (36 × 24 and 54 × 40 mm) native 16 bit sensors with 3.76 μ m pixels and are sensitive in the optical range. We present the results of the laboratory characterization of both cameras. They showed a very low dark current of 0.011 and 0.007 e− px−1 s−1 @–10°C for the QHY600 and QHY411 cameras, respectively. They also show the presence of warm pixels, ∼0.024% in the QHY600 and 0.005% in the QHY411. Warm pixels proved to be stable and linear with exposure time, and are therefore easily corrected using dark frames. Pixels affected by the Salt & Pepper noise are ∼2% of the total and a method to correct for this effect is presented. Both cameras were attached to night telescopes and several on-sky tests were performed to prove their capabilities. On-sky tests demonstrate that these CMOS behave as well as CCDs of similar characteristics and (for example) they can attain photometric accuracies of a few mili-magnitudes. [ABSTRACT FROM AUTHOR]

Published

2023

35. The Science Performance of JWST as Characterized in Commissioning.

Author

Rigby, Jane, Perrin, Marshall, McElwain, Michael, Kimble, Randy, Friedman, Scott, Lallo, Matt, Doyon, René, Feinberg, Lee, Ferruit, Pierre, Glasse, Alistair, Rieke, Marcia, Rieke, George, Wright, Gillian, Willott, Chris, Colon, Knicole, Milam, Stefanie, Neff, Susan, Stark, Christopher, Valenti, Jeff, and Abell, Jim

Subjects

*SCIENTIFIC apparatus & instruments, *NEAR-earth asteroids, *SPACE telescopes, *ASTEROIDS, *TELESCOPES, *INFRARED astronomy

Abstract

This paper characterizes the actual science performance of the James Webb Space Telescope (JWST), as determined from the six month commissioning period. We summarize the performance of the spacecraft, telescope, science instruments, and ground system, with an emphasis on differences from pre-launch expectations. Commissioning has made clear that JWST is fully capable of achieving the discoveries for which it was built. Moreover, almost across the board, the science performance of JWST is better than expected; in most cases, JWST will go deeper faster than expected. The telescope and instrument suite have demonstrated the sensitivity, stability, image quality, and spectral range that are necessary to transform our understanding of the cosmos through observations spanning from near-earth asteroids to the most distant galaxies. [ABSTRACT FROM AUTHOR]

Published

2023

36. First Sodium Laser Guide Star Asterism Launching Platform in China on the 1.8 m Telescope at Gaomeigu Observatory.

Author

Wang, Rui-Tao, Li, Hong-Yang, Feng, Lu, Li, Min, Bian, Qi, Zuo, Jun-Wei, Jin, Kai, Wang, Chen, Liang, Yue, Wang, Ming, Dou, Jun-Feng, Zhang, Ding-Wen, Wei, Kai, Guo, You-Ming, Bo, Yong, and Xue, Sui-Jian

Subjects

*LASER guide star adaptive optics, *TELESCOPES, *OBSERVATORIES, *ATMOSPHERIC turbulence, *GENERATING functions, *WAVEFRONT sensors

Abstract

The application of a sodium laser guide star is the key difference between a modern adaptive optics system and traditional adaptive optics system. Especially in system such as multiconjugate adaptive optics, a sodium laser guide star asterism that is formed by several laser guide stars in a certain pattern is required to probe more atmospheric turbulence in different directions. To achieve this, a sodium laser guide star asterism launching platform is required. In this paper, we introduce the sodium laser guide star asterism launching platform built and tested on the 1.8 m telescope of Gaomeigu Observatory. The platform has two functions: one function is to compare the performance of sodium laser guide stars generated by different lasers at the same place, and the other function is to generate a sodium laser guide star asterism with an adjustable shape. The field test results at the beginning of 2021 verified the important role of the platform, which is also the first time that a sodium laser guide star asterism was realized in China. [ABSTRACT FROM AUTHOR]

Published

2023

37. Spectroscopic Time Series Performance of the Mid-infrared Instrument on the JWST.

Author

Bouwman, Jeroen, Kendrew, Sarah, Greene, Thomas P., Bell, Taylor J., Lagage, Pierre-Olivier, Schreiber, Jürgen, Dicken, Daniel, Sloan, G. C., Espinoza, Néstor, Scheithauer, Silvia, Coulais, Alain, Fox, Ori D., Gastaud, René, Glauser, Adrian M., Jones, Olivia C., Labiano, Alvaro, Lahuis, Fred, Morrison, Jane E., Murray, Katherine, and Mueller, Michael

Subjects

*TIME series analysis, *SPACE telescopes, *RANDOM noise theory, *DATA analysis, *NOISE

Abstract

We present here the first ever mid-infrared spectroscopic time series observation of the transiting exoplanet L 168-9 b with the Mid-Infrared Instrument (MIRI) on the James Webb Space Telescope. The data were obtained as part of the MIRI commissioning activities, to characterize the performance of the Low Resolution Spectroscopy (LRS) mode for these challenging observations. To assess the MIRI LRS performance, we performed two independent analyses of the data. We find that with a single transit observation we reached a spectro-photometric precision of ∼50 ppm in the 7–8 μ m range at R = 50, consistent with ∼25 ppm systematic noise. The derived band averaged transit depth is 524 ± 15 ppm and 547 ± 13 ppm for the two applied analysis methods, respectively, recovering the known transit depth to within 1 σ. The measured noise in the planet's transmission spectrum is approximately 15%–20% higher than random noise simulations over wavelengths 6.8 ≲ λ ≲ 11 μ m. We observed an larger excess noise at the shortest wavelengths of up to a factor of two, for which possible causes are discussed. This performance was achieved with limited in-flight calibration data, demonstrating the future potential of MIRI for the characterization of exoplanet atmospheres. [ABSTRACT FROM AUTHOR]

Published

2023

38. Modeling the Wavelength Dependence of Pixel Response Nonuniformity of a CCD Sensor

Author

Zun Luo, Wei Du, Baocun Chen, Xianmin Meng, and Hu Zhan

Subjects

Astronomical instrumentation, Astronomical detectors, Astronomical techniques, CCD photometry, Astronomy, QB1-991

Abstract

Precision measurements in astronomy require stringent control of systematics such as those arising from imperfect correction of sensor effects. In this work, we develop a parametric method to model the wavelength dependence of pixel response nonuniformity (PRNU) for a laser-annealed backside-illuminated charge-coupled device. The model accurately reproduces the PRNU patterns of flat-field images taken at nine wavelengths from 290 to 950 nm, leaving the rms residuals no more than 0.2% in most cases. By removing the large-scale nonuniformity in the flat fields, the rms residuals are further reduced. This model fitting approach gives more accurate predictions of the PRNU than cubic-spline interpolation does with fewer free parameters. It can be applied to make PRNU corrections for individual objects according to their spectral energy distribution to reduce the photometry errors caused by the wavelength-dependent PRNU, if sub-percent level precision is required.

Published

2024

39. The SDSS-V Local Volume Mapper Telescope System

Author

T. M. Herbst, Peter Bizenberger, Guillermo A. Blanc, Florian Briegel, Niv Drory, Cynthia S. Froning, Wolfgang Gaessler, Maximilian Häberle, Nicholas P. Konidaris, Markus Kuhlberg, Alicia Lanz, Richard Mathar, Lars Mohr, Solange Ramirez, Christopher Ritz, Ralf-Rainer Rohloff, José Sánchez-Gallego, Stefanie Wachter, Hojae Ahn, Felipe Besser, Scott Case, Tobias Feger, Anthony Hebert, Juna A. Kollmeier, Soojong Pak, Hans-Walter Rix, David Robertson, Paula Stępień, and Ross Zhelem

Subjects

Automated telescopes, Wide-field telescopes, Telescopes, Sky surveys, Astronomical instrumentation, Astronomy, QB1-991

Abstract

This paper presents the Local Volume Mapper (LVM) telescope system. LVM is one of three surveys that form the fifth generation of the Sloan Digital Sky Survey (SDSS-V), and it employs a coordinated network of four, 16 cm diameter telescopes feeding integral field units (IFUs) leading to three fiber spectrographs. One telescope hosts the science IFU, while two others observe adjacent fields to calibrate geocoronal emission. The fourth telescope makes rapid observations of bright stars to compensate for telluric absorption. The entrance slits of the spectrographs intersperse the fibers from all three types of telescope, producing truly simultaneous science and calibration exposures. We describe the final design of the telescope system and report on its construction, alignment and testing in the laboratory, as well as the integration, testing, commissioning, and actual on-sky performance at Las Campanas Observatory.

Published

2024

40. Overview of the Fiber System for the Dark Energy Spectroscopic Instrument

Author

Claire Poppett, Luke Tyas, J. Aguilar, Christopher Bebek, D. Bramall, T. Claybaugh, J. Edelstein, P. Fagrelius, H. Heetderks, P. Jelinsky, S. Jelinsky, Robin Lafever, A. Lambert, M. Lampton, Michael E. Levi, P. Martini, C. Rockosi, J. Schmoll, Ray M. Sharples, Martin Sirk, Edward Wishnow, Jiaxi Yu, S. Ahlen, A. Bault, S. BenZvi, D. Brooks, S. Cole, A. de la Macorra, Arjun Dey, P. Doel, K. Fanning, A. Font-Ribera, J. E. Forero-Romero, E. Gaztañaga, S. Gontcho A Gontcho, A. X. Gonzalez-Morales, C. Hahn, K. Honscheid, J. Jimenez, S. Juneau, D. Kirkby, A. Kremin, M. Landriau, L. Le Guillou, M. Manera, A. Meisner, R. Miquel, J. Moustakas, E. Mueller, A. Muñoz-Gutiérrez, A. D. Myers, J. Nie, G. Niz, N. Palanque-Delabrouille, W. J. Percival, F. Prada, D. Rabinowitz, M. Rezaie, G. Rossi, E. Sanchez, Edward F. Schlafly, D. Schlegel, M. Schubnell, H. Seo, D. Sprayberry, G. Tarlé, M. Vargas-Magaña, B. A. Weaver, and R. Zhou

Subjects

Cosmological evolution, Astronomical instrumentation, Galaxy spectroscopy, Astronomy, QB1-991

Abstract

The Dark Energy Spectroscopic Instrument (DESI) is a revolutionary instrument designed for precise measurements of cosmic distances and the investigation of dark energy. DESI utilizes 5000 optical fibers to simultaneously measure the spectra of distant objects and aims to measure 40 million galaxies and quasars in a 5 yr survey. One of the critical challenges to DESI’s success was ensuring that the fiber system was not only highly efficient but also delivered a highly stable beam enabling more reliable sky subtraction for measurements of faint objects. We achieved this stability by minimizing the stress on the fiber system during the manufacture and operation of the telescope and fiber positioning robots. We installed the DESI fiber system on the 4 m Mayall telescope with ≥99% of fibers intact, and the instrument has delivered superb optical performance throughout the initial years of the DESI survey, including ≥90% average throughput when injected with a focal ratio of ∼ f /3.9 as delivered by the primary focus corrector, excluding fiber absorption losses. The design of DESI required multiple innovations to achieve these requirements, such as cleaved fibers bonded with a UV-curing epoxy to glass ferrules in the focal plane and fusion splicing instead of physical connectors. In this paper, we describe the development, delivery, and installation of the fiber system, the innovations that made the state-of-the-art performance possible, and the key lessons learned that could benefit future projects.

Published

2024

41. Concept of a Double Tilted Rowland Spectrograph for X-Rays

Author

Hans Moritz Günther, Casey T. DeRoo, Ralf K. Heilmann, and Edward Hertz

Subjects

Astronomical instrumentation, Spectrometers, Space observatories, X-ray telescopes, Astrophysics, QB460-466

Abstract

High-resolution spectroscopy in soft X-rays (

Published

2024

42. Gemini High-resolution Optical Spectrograph (GHOST) at Gemini South: Instrument Performance and Integration, First Science, and Next Steps

Author

V. M. Kalari, R. J. Diaz, G. Robertson, A. McConnachie, M. Ireland, R. Salinas, P. Young, C. Simpson, C. Hayes, J. Nielsen, G. Burley, J. Pazder, M. Gomez-Jimenez, E. Martioli, S. B. Howell, M. Jeong, S. Juneau, R. Ruiz-Carmona, S. Margheim, A. Sheinis, A. Anthony, G. Baker, T. A. M. Berg, T. Cao, E. Chapin, T. Chin, K. Chiboucas, V. Churilov, E. Deibert, A. Densmore, J. Dunn, M. L. Edgar, J. Heo, D. Henderson, T. Farrell, J. Font, V. Firpo, J. Fuentes, K. Labrie, S. Lambert, J. Lawrence, J. Lothrop, R. McDermid, B. W. Miller, G. Perez, V. M. Placco, P. Prado, C. Quiroz, F. Ramos, R. Rutten, K. M. G. Silva, J. Thomas-Osip, C. Urrutia, W. D. Vacca, K. Venn, F. Waller, L. Waller, M. White, S. Xu, and R. Zhelem

Subjects

High resolution spectroscopy, Astronomical instrumentation, Optical observatories, Astronomy, QB1-991

Abstract

The Gemini South telescope is now equipped with a new high-resolution spectrograph called the Gemini High-resolution Optical SpecTrograph (GHOST). This instrument provides high-efficiency, high-resolution spectra covering 347–1060 nm in a single exposure of either one or two targets simultaneously, along with precision radial velocity spectroscopy utilizing an internal calibration source. It can operate at a spectral element resolving power of either 76,000 or 56,000, and can reach a signal-to-noise ratio of ∼5 in a 1 hr exposure on a V ∼ 20.8 mag target in median site seeing and dark skies (per resolution element). GHOST was installed on-site in 2022 June, and we report performance after full integration to queue operations in 2023 November, in addition to scientific results enabled by the integration observing runs. These results demonstrate the ability to observe a wide variety of bright and faint targets with high efficiency and precision. With GHOST, new avenues to explore high-resolution spectroscopy have opened up to the astronomical community. These are described, along with the planned and potential upgrades to the instrument.

Published

2024

43. The SDSS-V Local Volume Mapper (LVM): Scientific Motivation and Project Overview

Author

Niv Drory, Guillermo A. Blanc, Kathryn Kreckel, Sebastián F. Sánchez, Alfredo Mejía-Narváez, Evelyn J. Johnston, Amy M. Jones, Eric W. Pellegrini, Nicholas P. Konidaris, Tom Herbst, José Sánchez-Gallego, Juna A. Kollmeier, Florence de Almeida, Jorge K. Barrera-Ballesteros, Dmitry Bizyaev, Joel R. Brownstein, Mar Canal i Saguer, Brian Cherinka, Maria-Rosa L. Cioni, Enrico Congiu, Maren Cosens, Bruno Dias, John Donor, Oleg Egorov, Evgeniia Egorova, Cynthia S. Froning, Pablo García, Simon C. O. Glover, Hannah Greve, Maximilian Häberle, Kevin Hoy, Hector Ibarra, Jing Li, Ralf S. Klessen, Dhanesh Krishnarao, Nimisha Kumari, Knox S. Long, José Eduardo Méndez-Delgado, Silvia Anastasia Popa, Solange Ramirez, Hans-Walter Rix, Aurora Mata Sánchez, Ravi Sankrit, Natascha Sattler, Conor Sayres, Amrita Singh, Guy Stringfellow, Stefanie Wachter, Elizabeth Jayne Watkins, Tony Wong, and Aida Wofford

Subjects

Astronomical instrumentation, Stellar feedback, Interstellar medium, Sky surveys, Astronomy, QB1-991

Abstract

We present the Sloan Digital Sky Survey V Local Volume Mapper (LVM). The LVM is an integral-field spectroscopic survey of the Milky Way, Magellanic Clouds, and a sample of local volume galaxies, connecting resolved parsec-scale individual sources of feedback to kiloparsec-scale ionized interstellar medium (ISM) properties. The 4 yr survey covers the southern Milky Way disk at spatial resolutions of 0.05–1 pc, the Magellanic Clouds at 10 pc resolution, and nearby large galaxies at larger scales totaling >4300 deg ^2 of sky and more than 55M spectra. It utilizes a new facility of alt–alt mounted siderostats feeding 16 cm refractive telescopes, lenslet-coupled fiber optics, and spectrographs covering 3600–9800 Å at R ∼ 4000. The ultra-wide-field integral-field unit has a diameter of 0.°5 with 1801 hexagonally packed fibers of 35.″3 apertures. The siderostats allow for a completely stationary fiber system, avoiding instability of the line-spread function seen in traditional fiber feeds. Scientifically, LVM resolves the regions where energy, momentum, and chemical elements are injected into the ISM at the scale of gas clouds, while simultaneously charting where energy is being dissipated (via cooling, shocks, turbulence, bulk flows, etc.) to global scales. This combined local and global view enables us to constrain physical processes regulating how stellar feedback operates and couples to galactic kinematics and disk-scale structures, such as the bar and spiral arms, as well as gas in- and outflows.

Published

2024

44. SPRITEly: Time-domain Millimeter Interferometry at the Owens Valley Radio Observatory

Author

Nitika Yadlapalli Yurk, Vikram Ravi, Mark W. Hodges, James W. Lamb, Richard Hobbs, David P. Woody, and Anthony C. S. Readhead

Subjects

Radio interferometry, Time domain astronomy, Radio transient sources, Astronomical instrumentation, Astronomy, QB1-991

Abstract

Though the time-domain millimeter sky is yet to be well characterized, the scarcity of millimeter observing resources in the world at present hampers progress toward it. In efforts to bolster the exploration of millimeter transients, we present the Stokes Polarization Radio Interferometer for Time-Domain Experiments (SPRITEly). Located at the Owens Valley Radio Observatory, SPRITEly is currently deployed as a two-element short-baseline 90 GHz interferometer uniquely focused on monitoring bright variable millimeter-continuum sources. We leverage two existing 10.4 m antennas and their existing receiver systems to begin, but we make significant upgrades to the back-end system during the commissioning process. With the ability to achieve rms noise of a few mJy, we plan to monitor known variable sources along with new nearby transients detected from optical surveys at high cadence, with the goal of producing well-sampled light curves. Interpreting these data in conjunction with multiwavelength observations stands to provide insight into the physical properties of the sources that produce transient millimeter emission. We present commissioning and early-science observations that demonstrate the performance of the instrument, including observations of the flaring BL Lac object S2 0109+22 and a periastron passage of the binary T Tauri system DQ Tau.

Published

2024

45. The Active Optics System on the Vera C. Rubin Observatory: Optimal Control of Degeneracy among the Large Number of Degrees of Freedom

Author

Guillem Megias Homar, Steven M. Kahn, Joshua M. Meyers, John Franklin Crenshaw, and Sandrine J. Thomas

Subjects

Astronomical optics, Optical aberration, Wide-field telescopes, Astronomical instrumentation, Observational astronomy, Astrophysics, QB460-466

Abstract

The Vera C. Rubin Observatory is a unique facility for survey astronomy that will soon be commissioned and begin operations. Crucial to many of its scientific goals is the achievement of sustained high image quality, limited only by the seeing at the site. This will be maintained through an active optics system that controls optical element misalignments and corrects mirror figure error to minimize aberrations caused by both thermal and gravitational effects. However, the large number of adjustment degrees of freedom available on the Rubin Observatory introduces a range of degeneracies, including many that are induced by noise due to imperfect measurement of the wave-front errors. We present a structured methodology for identifying these degeneracies through an analysis of image noise level. We also present a novel scaling strategy based on truncated singular value decomposition that mitigates the degeneracy and optimally distributes the adjustment over the available degrees of freedom. Our approach ensures the attainment of optimal image quality, while avoiding excursions around the noise-induced subspace of degeneracies, marking a significant improvement over the previous techniques adopted for Rubin, which were based on an optimal integral controller. This new approach is likely to also yield significant benefits for all telescopes that incorporate large numbers of degrees of freedom of adjustment.

Published

2024

46. A Hierarchical Point-spread Function Reconstruction Method

Author

Pedro Alonso, Jun Zhang, and Cong Liu

Subjects

Astronomical instrumentation, Astronomical techniques, Telescopes, Astrometry, Gravitational lensing, Astrophysics, QB460-466

Abstract

Reconstruction of the point-spread function (PSF) plays an important role in many areas of astronomy, including photometry, astrometry, galaxy morphology, and shear measurement. The atmospheric and instrumental effects are the two main contributors to the PSF, both of which may exhibit complex spatial features. Current PSF reconstruction schemes typically rely on individual exposures, and their ability to reproduce the complicated features of the PSF distribution is therefore limited by the number of stars. Interestingly, in conventional methods, after stacking the model residuals of the PSF ellipticities and (relative) sizes from a large number of exposures, one can often observe some stable and nontrivial spatial patterns on the entire focal plane, which could be quite detrimental to, e.g., weak-lensing measurements. These PSF residual patterns are caused by instrumental effects, as they consistently appear in different exposures. Taking this as an advantage, we propose a multilayer PSF reconstruction method to remove such PSF residuals, the second and third layers of which make use of all available exposures together. We test our method on the i -band data of the second release of the Hyper Suprime-Cam. Our method successfully eliminates most of the PSF residuals. Using the Fourier_Quad shear measurement method, we further test the performance of the resulting PSF fields on shear recovery using the field distortion effect. The PSF residuals have strong correlations with the shear residuals, and our new multilayer PSF reconstruction method can remove most of such systematic errors related to the PSF, leading to much smaller shear biases.

Published

2024

47. The Optical Corrector for the Dark Energy Spectroscopic Instrument

Author

Timothy N. Miller, Peter Doel, Gaston Gutierrez, Robert Besuner, David Brooks, Giuseppe Gallo, Henry Heetderks, Patrick Jelinsky, Stephen M. Kent, Michael Lampton, Michael E. Levi, Ming Liang, Aaron Meisner, Michael J. Sholl, Joseph Harry Silber, David Sprayberry, Jessica Nicole Aguilar, Axel de la Macorra, Daniel Eisenstein, Kevin Fanning, Andreu Font-Ribera, Enrique Gaztañaga, Satya Gontcho A Gontcho, Klaus Honscheid, Jorge Jimenez, Dick Joyce, Robert Kehoe, Theodore Kisner, Anthony Kremin, Martin Landriau, Laurent Le Guillou, Christophe Magneville, Paul Martini, Ramon Miquel, John Moustakas, Jundan Nie, Will Percival, Claire Poppett, Francisco Prada, Graziano Rossi, David Schlegel, Michael Schubnell, Hee-Jong Seo, Ray Sharples, Gregory Tarlé, Mariana Vargas-Magaña, Zhimin Zhou, and the DESI Collaboration

Subjects

Dark energy, Astronomical instrumentation, Optical telescopes, Wide-field telescopes, Lenses, Prime focus, Astronomy, QB1-991

Abstract

The Dark Energy Spectroscopic Instrument (DESI) is currently measuring the spectra of 40 million galaxies and quasars, the largest such survey ever made to probe the nature of cosmological dark energy. The 4 m Mayall telescope at Kitt Peak National Observatory has been adapted for DESI, including the construction of a 3.°2 diameter prime focus corrector that focuses astronomical light onto a 0.8 m diameter focal surface with excellent image quality over the DESI bandpass of 360–980 nm. The wide-field corrector includes six lenses, as large as 1.1 m in diameter and as heavy as 237 kilograms, including two counterrotating wedged lenses that correct for atmospheric dispersion over zenith angles from 0° to 60°. The lenses, cells, and barrel assembly all meet precise alignment tolerances on the order of tens of microns. The barrel alignment is maintained throughout a range of observing angles and temperature excursions in the Mayall dome by use of a hexapod, which is itself supported by a new cage, ring, and truss structure. In this paper we describe the design, fabrication, and performance of the new corrector and associated structure, focusing on how they meet DESI requirements. In particular, we describe the prescription and specifications of the lenses, design choices and error budgeting of the barrel assembly, stray light mitigations, and integration and test at the Mayall telescope. We conclude with some validation highlights that demonstrate the successful corrector on-sky performance, and we list some lessons learned during the multiyear fabrication phase.

Published

2024

48. Cosmology Large Angular Scale Surveyor (CLASS): 90 GHz Telescope Pointing, Beam Profile, Window Function, and Polarization Performance

Author

Rahul Datta, Michael K. Brewer, Jullianna Denes Couto, Joseph Eimer, Yunyang Li, Zhilei Xu, Aamir Ali, John W. Appel, Charles L. Bennett, Ricardo Bustos, David T. Chuss, Joseph Cleary, Sumit Dahal, Francisco Raul Javier Espinoza Inostroza, Thomas Essinger-Hileman, Pedro Fluxá, Kathleen Harrington, Kyle Helson, Jeffrey Iuliano, John Karakla, Tobias A. Marriage, Sasha Novack, Carolina Núñez, Ivan L. Padilla, Lucas Parker, Matthew A. Petroff, Rodrigo Reeves, Karwan Rostem, Rui Shi, Deniz A. N. Valle, Duncan J. Watts, Janet L. Weiland, Edward J. Wollack, and Lingzhen Zeng

Subjects

Astronomical instrumentation, Telescopes, Polarimeters, Cosmic microwave background radiation, Observational cosmology, Astrophysics, QB460-466

Abstract

The Cosmology Large Angular Scale Surveyor (CLASS) is a telescope array that observes the cosmic microwave background (CMB) over ∼75% of the sky from the Atacama Desert, Chile, at frequency bands centered near 40, 90, 150, and 220 GHz. CLASS measures the large angular scale CMB polarization to constrain the tensor-to-scalar ratio and the optical depth to last scattering. This paper presents the optical characterization of the 90 GHz telescope. Observations of the Moon establish the pointing while dedicated observations of Jupiter are used for beam calibration. The standard deviations of the pointing error in azimuth, elevation, and boresight angle are 1.′3, 2.′1, and 2.′0, respectively, over the first 3 yr of observations. This corresponds to a pointing uncertainty ∼7% of the beam’s full width at half-maximum (FWHM). The effective azimuthally symmetrized instrument 1D beam estimated at 90 GHz has an FWHM of 0.°620 ± 0.°003 and a solid angle of 138.7 ± 0.6(stats.) ± 1.1(sys.) μ sr integrated to a radius of 4°. The corresponding beam window function drops to ${b}_{{\ell }}^{2}=0.93,0.71,0.14$ at ℓ = 30, 100, 300, respectively. Far-sidelobes are studied using detector-centered intensity maps of the Moon and measured to be at a level of 10 ^−3 or below relative to the peak. The polarization angle of Tau A estimated from preliminary survey maps is 149°.6 ± 0°.2(stats.) in equatorial coordinates. The instrumental temperature-to-polarization ( T → P ) leakage fraction, inferred from per-detector demodulated Jupiter scan data, has a monopole component at the level of 1.7 × 10 ^−3 , a dipole component with an amplitude of 4.3 × 10 ^−3 , with no evidence of quadrupolar leakage.

Published

2024

49. CHIME/FRB Outriggers: KKO Station System and Commissioning Results

Author

Adam E. Lanman, Shion Andrew, Mattias Lazda, Vishwangi Shah, Mandana Amiri, Arvind Balasubramanian, Kevin Bandura, P. J. Boyle, Charanjot Brar, Mark Carlson, Jean-François Cliche, Nina Gusinskaia, Ian T. Hendricksen, J. F. Kaczmarek, Tom Landecker, Calvin Leung, Ryan Mckinven, Juan Mena-Parra, Nikola Milutinovic, Kenzie Nimmo, Aaron B. Pearlman, Andre Renard, Mubdi Rahman, J. Richard Shaw, Seth R. Siegel, Rick J. Smegal, Tomas Cassanelli, Shami Chatterjee, Alice P. Curtin, Matt Dobbs, Fengqiu Adam Dong, Mark Halpern, Hans Hopkins, Victoria M. Kaspi, Kholoud Khairy, Kiyoshi W. Masui, Bradley W. Meyers, Daniele Michilli, Emily Petroff, Tristan Pinsonneault-Marotte, Ziggy Pleunis, Masoud Rafiei-Ravandi, Kaitlyn Shin, Kendrick Smith, Keith Vanderlinde, and Tarik J. Zegmott

Subjects

Radio telescopes, Astronomical instrumentation, Radio interferometers, Very long baseline interferometry, Radio transient sources, Telescopes, Astronomy, QB1-991

Abstract

Localizing fast radio bursts (FRBs) to their host galaxies is an essential step to better understanding their origins and using them as cosmic probes. The Canadian Hydrogen Intensity Mapping Experiment (CHIME)/FRB Outriggers program aims to add very long baseline interferometry localization capabilities to CHIME, such that FRBs may be localized to tens of milliarcsecond precision at the time of their discovery, more than sufficient for host galaxy identification. The first-built outrigger telescope is the Outrigger (KKO), located 66 km west of CHIME. Cross-correlating KKO with CHIME can achieve arcsecond precision along the baseline axis while avoiding the worst effects of the ionosphere. Since the CHIME–KKO baseline is mostly east/west, this improvement is mostly in right ascension. This paper presents measurements of KKO’s performance throughout its commissioning phase, as well as a summary of its design and function. We demonstrate KKO’s capabilities as a standalone instrument by producing full-sky images, mapping the angular and frequency structure of the primary beam, and measuring feed positions. To demonstrate the localization capabilities of the CHIME–KKO baseline, we collected five separate observations each, for a set of 20 bright pulsars, and aimed to measure their positions to within 5″. All of these pulses were successfully localized to within this specification. The next two outriggers are expected to be commissioned in 2024 and will enable subarcsecond localizations for approximately hundreds of FRBs each year.

Published

2024

50. SuperBIT Superpressure Flight Instrument Overview and Performance: Near-diffraction-limited Astronomical Imaging from the Stratosphere

Author

Ajay S. Gill, Steven J. Benton, Christopher J. Damaren, Spencer W. Everett, Aurelien A. Fraisse, John W. Hartley, David Harvey, Bradley Holder, Eric M. Huff, Mathilde Jauzac, William C. Jones, David Lagattuta, Jason S.-Y. Leung, Lun Li, Thuy Vy T. Luu, Richard Massey, Jacqueline E. McCleary, Johanna M. Nagy, C. Barth Netterfield, Emaad Paracha, Susan F. Redmond, Jason D. Rhodes, Andrew Robertson, L. Javier Romualdez, Jürgen Schmoll, Mohamed M. Shaaban, Ellen L. Sirks, Georgios N. Vassilakis, and André Z. Vitorelli

Subjects

High altitude balloons, Galaxy clusters, Space telescopes, Gravitational lensing, Weak gravitational lensing, Astronomical instrumentation, Astronomy, QB1-991

Abstract

SuperBIT was a 0.5 m near-UV to near-infrared wide-field telescope that launched on a NASA superpressure balloon into the stratosphere from New Zealand for a 45-night flight. SuperBIT acquired multiband images of galaxy clusters to study the properties of dark matter using weak gravitational lensing. We provide an overview of the instrument and its various subsystems. We then present the instrument performance from the flight, including the telescope and image stabilization system, the optical system, the power system, and the thermal system. SuperBIT successfully met the instrument’s technical requirements, achieving a telescope pointing stability of 0.″34 ± 0.″10, a focal plane image stability of 0.″055 ± 0.″027, and a point-spread function FWHM of ∼0.″35 over 5-minute exposures throughout the 45-night flight. The telescope achieved a near-diffraction-limited point-spread function in all three science bands ( u , b , and g ). SuperBIT served as a pathfinder to the GigaBIT observatory, which will be a 1.34 m near-UV to near-infrared balloon-borne telescope.

Published

2024