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1. The NEID Port Adapter on-Sky Performance

Author

Sarah E. Logsdon, Marsha J. Wolf, Dan Li, Jayadev Rajagopal, Mark Everett, Qian Gong, Eli Golub, Jesus Higuera, Emily Hunting, Kurt P. Jaehnig, Ming Liang, Wilson Liu, William R. McBride, Michael W. McElwain, Jeffrey W. Percival, Susan Ridgway, Heidi Schweiker, Michael P. Smith, Erik Timmermann, Fernando Santoro, Christian Schwab, Chad F. Bender, Cullen H. Blake, Arvind F. Gupta, Samuel Halverson, Fred Hearty, Shubham Kanodia, Suvrath Mahadevan, Andrew J. Monson, Joe Ninan, Lawrence Ramsey, Paul Robertson, Arpita Roy, Ryan C. Terrien, and Jason T. Wright

Subjects
Astronomy, Instrumentation and Photography
Abstract

Here we detail the on-sky performance of the NEID Port Adapter one year into full science operation at the WIYN 3.5m Telescope at Kitt Peak National Observatory. NEID is an optical (380-930 nm), fiber-fed, precision Doppler radial velocity system developed as part of the NASA-NSF Exoplanet Observational Research (NN-EXPLORE) partnership. The NEID Port Adapter mounts directly to a bent-Cassegrain port on the WIYN Telescope and is responsible for precisely and stably placing target light on the science fibers. Precision acquisition and guiding is a critical component of such extreme precision spectrographs. In this work, we describe key on-sky performance results compared to initial design requirements and error budgets. While the current Port Adapter performance is more than sufficient for the NEID system to achieve and indeed exceed its formal instrumental radial velocity precision requirements, we continue to characterize and further optimize its performance and efficiency. This enables us to obtain better NEID datasets and in some cases, improve the performance of key terms in the error budget needed for future extreme precision spectrographs with the goal of observing ExoEarths, requiring ∼ 10 cm/s radial velocity measurements.

Published
2022
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3. Vibration measurements in the Daniel K. Inouye Solar Telescope

Author

Mackenzie Stratton and William R. McBride

Subjects
Vibration, Telescope, Computer science, law, Daniel K. Inouye Solar Telescope, Astrophysics::Instrumentation and Methods for Astrophysics, Astronomical seeing, Telescope mount, Accelerometer, Adaptive optics, Solar telescope, law.invention, Remote sensing
Abstract

The Daniel K. Inouye Solar Telescope (DKIST) will be the largest solar telescope in the world, providing a significant increase in the resolution of solar data available to the scientific community. In large ground-based telescopes, vibration of telescope optics caused by the telescope subsystems is typically the limiting factor of image resolution. 1 The impact of vibration increases with the resolution of the telescope and is therefore a much greater problem in long focal-length telescopes, such as the DKIST. In addition, vibration is a consumer of the adaptive optics image-quality error budget limiting the correction available for atmospheric seeing. In some cases, the adaptive optics might even amplify the vibration at higher frequencies. For all of these reasons, a vibration error budget is a critical component in any large telescope project, and a plan for active vibration management and mitigation is critical to the success of a large telescope project. In the design of a large telescope, finite element analysis is employed and this is historically the only effort put into understanding vibration issues. However, after the telescope mount is constructed and the instruments and ancillary equipment are more clearly defined, there are many opportunities to perform path analyses by directly measuring the low-frequency single- input-single-output (SISO) frequency response function (FRF) between vibration source locations and image motion on the focal plane. These measurements are carried out using inertial-mass shakers along with seismic accelerometers providing an accurate measurement of the image degradation that will be caused by vibration sources in various locations. This allows the designers to determine an appropriate vibration mitigation plan (if needed) long before the vibration source is attached to the telescope. These measurements have proven sensitive enough that they can be performed for equipment not mounted on the telescope structure but located in the telescope building or even in nearby buildings. In a previous paper, techniques were described for measuring vibration which is particularly challenging at frequencies below 10 Hz where accurate measurement requires several noise reduction techniques, including high-performance windows, noise-averaging, tracking filters, and spectral estimation. In this follow-up paper, the development of the DKIST vibration budget detailing the advantages of the shaker measurement technique is described, along with examples of testing performed on the DKIST structures currently under construction at the Haleakala High-Altitude Observatories site in Maui, HI.

Published
2018
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4. Construction update of the Daniel K. Inouye Solar Telescope project

Author

Stacey R. Sueoka, Steve Berukoff, Paul Jeffers, Heather Marshall, Wolfgang Schmidt, Friedrich Wöger, Chen Liang, Steve Shimko, Bret Goodrich, Predrag Sekulic, Mihalis Mathioudakis, Valentin Martinez Pillet, Erik M. Johansson, Joseph P. McMullin, Jeff Kuhn, Rich Summers, Andrew Ferayorni, Timothy R. Williams, Haosheng Lin, Thomas R. Rimmele, William R. McBride, Simon C. Craig, Ruth Kneale, William McVeigh, Mark Warner, Roberto Casini, Robert P. Hubbard, David M. Harrington, and Alexandra Tritschler

Subjects
Daniel K. Inouye Solar Telescope, Astronomy, Solar irradiance, 01 natural sciences, Solar telescope, law.invention, 010309 optics, Primary mirror, Telescope, law, 0103 physical sciences, Coronal mass ejection, Environmental science, Telescope mount, 010303 astronomy & astrophysics, Coronagraph
Abstract

Construction of the Daniel K. Inouye Solar Telescope (DKIST) is well underway on the Haleakalā summit on the Hawaiian island of Maui. Featuring a 4-m aperture and an off-axis Gregorian configuration, the DKIST will be the world’s largest solar telescope. It is designed to make high-precision measurements of fundamental astrophysical processes and produce large amounts of spectropolarimetric and imaging data. These data will support research on solar magnetism and its influence on solar wind, flares, coronal mass ejections, and solar irradiance variability. Because of its large aperture, the DKIST will be able to sense the corona’s magnetic field—a goal that has previously eluded scientists—enabling observations that will provide answers about the heating of stellar coronae and the origins of space weather and exo-weather. The telescope will cover a broad wavelength range (0.35 to 28 microns) and operate as a coronagraph at infrared (IR) wavelengths. Achieving the diffraction limit of the 4-m aperture, even at visible wavelengths, is paramount to these science goals. The DKIST’s state-of-the-art adaptive optics systems will provide diffraction-limited imaging, resolving features that are approximately 20 km in size on the Sun. At the start of operations, five instruments will be deployed: a visible broadband imager (VTF), a visible spectropolarimeter (ViSP), a visible tunable filter (VTF), a diffraction-limited near-IR spectropolarimeter (DLNIRSP), and a cryogenic near-IR spectropolarimeter (cryo-NIRSP). At the end of 2017, the project finished its fifth year of construction and eighth year overall. Major milestones included delivery of the commissioning blank, the completed primary mirror (M1), and its cell. Commissioning and testing of the coude rotator is complete and the installation of the coude cleanroom is underway; likewise, commissioning of the telescope mount assembly (TMA) has also begun. Various other systems and equipment are also being installed and tested. Finally, the observatory integration, testing, and commissioning (IT&C) activities have begun, including the first coating of the M1 commissioning blank and its integration within its cell assembly. Science mirror coating and initial on-sky activities are both anticipated in 2018.

Published
2018
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5. Vibration measurements of the Daniel K. Inouye Solar Telescope mount, Coudé rotator, and enclosure assemblies

Author

Daniel R. McBride and William R. McBride

Subjects
Computer science, business.industry, Acoustics, Daniel K. Inouye Solar Telescope, Astrophysics::Instrumentation and Methods for Astrophysics, Mirror mount, Accelerometer, law.invention, Solar telescope, Telescope, Primary mirror, Data acquisition, Optics, law, Telescope mount, business, Secondary mirror
Abstract

The Daniel K. Inouye Solar Telescope (DKIST) will be the largest solar telescope in the world, with a 4-meter off-axis primary mirror and 16 meter rotating Coude laboratory within the telescope pier. The off-axis design requires a mount similar to an 8-meter on-axis telescope. Both the telescope mount and the Coude laboratory utilize a roller bearing technology in place of the more commonly used hydrostatic bearings. The telescope enclosure utilizes a crawler mechanism for the altitude axis. As these mechanisms have not previously been used in a telescope, understanding the vibration characteristics and the potential impact on the telescope image is important. This paper presents the methodology used to perform jitter measurements of the enclosure and the mount bearings and servo system in a high-noise environment utilizing seismic accelerometers and high dynamic-range data acquisition equipment, along with digital signal processing (DSP) techniques. Data acquisition and signal processing were implemented in MATLAB. In the factory acceptance testing of the telescope mount, multiple accelerometers were strategically located to capture the six axes-of-motion of the primary and secondary mirror dummies. The optical sensitivity analysis was used to map these mirror mount displacements and rotations into units of image motion on the focal plane. Similarly, tests were done with the Coude rotator, treating the entire rotating instrument lab as a rigid body. Testing was performed by recording accelerometer data while the telescope control system performed tracking operations typical of various observing scenarios. The analysis of the accelerometer data utilized noise-averaging fast Fourier transform (FFT) routines, spectrograms, and periodograms. To achieve adequate dynamic range at frequencies as low as 3 Hz , the use of special filters and advanced windowing functions were necessary. Numerous identical automated tests were compared to identify and select the data sets with the lowest level of external interference. Similar testing was performed on the telescope enclosure during the factory test campaign. The vibration of the enclosure altitude and azimuth mechanisms were characterized. This paper details jitter tests using accelerometers placed in locations that allowed the motion of the assemblies to be measured while the control system performed various moves typical of on-sky observations. The measurements were converted into the rigid body motion of the structures and mapped into image motion using the telescope's optical sensitivity analysis.

Published
2016
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6. Construction status of the Daniel K. Inouye solar telescope

Author

Robert P. Hubbard, Erik M. Johansson, Valentin Martinez Pillet, Haosheng Lin, William McVeigh, William R. McBride, LeEllen Phelps, Steve Berukoff, Paul Jeffers, Stacey R. Sueoka, Heather Marshall, Andrew Ferayorni, Wolfgang Schmidt, David Elmore, Thomas R. Rimmele, Steve Hegwer, Friedrich Wöger, Joseph P. McMullin, Jeff Kuhn, Timothy R. Williams, Mark Warner, David M. Harrington, Roberto Casini, Alexandra Tritschler, Simon C. Craig, Mihalis Mathioudakis, Steve Shimko, and Bret Goodrich

Subjects
Physics, Solar observatory, Observatory, Daniel K. Inouye Solar Telescope, Coronal mass ejection, Telescope mount, Solar physics, Solar irradiance, Remote sensing, Solar telescope
Abstract

We provide an update on the construction status of the Daniel K. Inouye Solar Telescope. This 4-m diameter facility is designed to enable detection and spatial/temporal resolution of the predicted, fundamental astrophysical processes driving solar magnetism at their intrinsic scales throughout the solar atmosphere. These data will drive key research on solar magnetism and its influence on solar winds, flares, coronal mass ejections and solar irradiance variability. The facility is developed to support a broad wavelength range (0.35 to 28 microns) and will employ state-of-the-art adaptive optics systems to provide diffraction limited imaging, resolving features approximately 20 km on the Sun. At the start of operations, there will be five instruments initially deployed: Visible Broadband Imager (VBI; National Solar Observatory), Visible SpectroPolarimeter (ViSP; NCAR High Altitude Observatory), Visible Tunable Filter (VTF (a Fabry-Perot tunable spectropolarimeter); Kiepenheuer Institute for Solarphysics), Diffraction Limited NIR Spectropolarimeter (DL-NIRSP; University of Hawaii, Institute for Astronomy) and the Cryogenic NIR Spectropolarimeter (Cryo-NIRSP; University of Hawaii, Institute for Astronomy). As of mid-2016, the project construction is in its 4th year of site construction and 7th year overall. Major milestones in the off-site development include the conclusion of the polishing of the M1 mirror by University of Arizona, College of Optical Sciences, the delivery of the Top End Optical Assembly (L3), the acceptance of the Deformable Mirror System (Xinetics); all optical systems have been contracted and are either accepted or in fabrication. The Enclosure and Telescope Mount Assembly passed through their factory acceptance in 2014 and 2015, respectively. The enclosure site construction is currently concluding while the Telescope Mount Assembly site erection is underway. The facility buildings (Utility and Support and Operations) have been completed with ongoing work on the thermal systems to support the challenging imaging requirements needed for the solar research. Finally, we present the construction phase performance (schedule, budget) with projections for the start of early operations.

Published
2016
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7. Using frequency response functions to manage image degradation from equipment vibration in the Daniel K. Inouye Solar Telescope

Author

Daniel R. McBride and William R. McBride

Subjects
Frequency response, business.industry, Computer science, Acoustics, Daniel K. Inouye Solar Telescope, 02 engineering and technology, 021001 nanoscience & nanotechnology, Accelerometer, 01 natural sciences, Solar telescope, law.invention, 010309 optics, Vibration, Telescope, Signal-to-noise ratio, Optics, law, 0103 physical sciences, Astronomical seeing, 0210 nano-technology, business, Adaptive optics
Abstract

The Daniel K Inouye Solar Telescope (DKIST) will be the largest solar telescope in the world, providing a significant increase in the resolution of solar data available to the scientific community. Vibration mitigation is critical in long focal-length telescopes such as the Inouye Solar Telescope, especially when adaptive optics are employed to correct for atmospheric seeing. For this reason, a vibration error budget has been implemented. Initially, the FRFs for the various mounting points of ancillary equipment were estimated using the finite element analysis (FEA) of the telescope structures. FEA analysis is well documented and understood; the focus of this paper is on the methods involved in estimating a set of experimental (measured) transfer functions of the as-built telescope structure for the purpose of vibration management. Techniques to measure low-frequency single-input-single-output (SISO) frequency response functions (FRF) between vibration source locations and image motion on the focal plane are described. The measurement equipment includes an instrumented inertial-mass shaker capable of operation down to 4 Hz along with seismic accelerometers. The measurement of vibration at frequencies below 10 Hz with good signal-to-noise ratio (SNR) requires several noise reduction techniques including high-performance windows, noise-averaging, tracking filters, and spectral estimation. These signal-processing techniques are described in detail.

Published
2016
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8. Daniel K. Inouye Solar Telescope: integration, testing, and commissioning planning

Author

Predrag Sekulic, Timothy R. Williams, Ruth Kneale, Kerry Gonzales, Robert P. Hubbard, Simon C. Craig, Chen Liang, and William R. McBride

Subjects
Engineering, Project planning, Integration testing, Project commissioning, business.industry, Daniel K. Inouye Solar Telescope, Systems engineering, Project management, business, Simulation, Solar telescope
Abstract

The Daniel K. Inouye Solar Telescope (DKIST), formerly the Advanced Technology Solar Telescope (ATST), has been in its construction phase since 2010, anticipating the onset of the integration, test, and commissioning (IT&C) phase late in 2016, and the commencement of science verification in early 2019. In this paper we describe the planning of the Integration, Testing and Commissioning (IT&C) phase of the project.

Published
2016
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9. Project management and control of the Daniel K. Inouye Solar Telescope

Author

Steve Shimko, Bret Goodrich, Andrew Ferayorni, Robert P. Hubbard, LeEllen Phelps, Thomas R. Rimmele, Erik M. Johansson, Joseph P. McMullin, Simon C. Craig, Heather Marshall, Rex Hunter, Alexandra Tritschler, William McVeigh, Timothy R. Williams, Friedrich Wöger, Mark Warner, William R. McBride, and Paul Jeffers

Subjects
Physics, 010504 meteorology & atmospheric sciences, business.industry, Control (management), Daniel K. Inouye Solar Telescope, Context (language use), Solar physics, 01 natural sciences, Solar telescope, 010309 optics, Engineering management, Observatory, 0103 physical sciences, Project management, business, Simulation, 0105 earth and related environmental sciences
Abstract

We provide a brief update on the construction status of the Daniel K. Inouye Solar Telescope, a $344M, 10-year construction project to design and build the world's largest solar physics observatory. We review the science drivers along with the challenges in meeting the evolving scientific needs over the course of the construction period without jeopardizing the systems engineering and management realization. We review the tools, processes and performance measures in use in guiding the development as well as the risks and challenges as the project transitions through various developmental phases. We elaborate on environmental and cultural compliance obligations in building in Hawai'i. We discuss the broad "lessons learned". Finally, we discuss the project in the context of the evolving management oversight within the US (in particular under the NSF).

Published
2016
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10. DKIST telescope mount factory testing overview and lessons learned

Author

Paul Jeffers, Hans J. Kärcher, William R. McBride, Todd Trieloff, and Steffen Seubert

Subjects
Engineering, business.industry, Daniel K. Inouye Solar Telescope, 01 natural sciences, Mount, law.invention, Solar telescope, 010309 optics, Telescope, Primary mirror, Acceptance testing, law, 0103 physical sciences, Systems engineering, Factory (object-oriented programming), Telescope mount, business, 010303 astronomy & astrophysics, Remote sensing
Abstract

The Daniel K Inouye Solar Telescope (DKIST) will be the largest solar telescope in the world, and will be able to provide the sharpest views ever taken of the solar surface. The telescope has a 4m aperture primary mirror, however due to the off axis nature of the optical layout, the telescope Mount has proportions similar to an 8 metre class telescope. The Telescope Mount Assembly (TMA) includes both the telescope Mount and the 16m diameter laboratory table or Coude Rotator. The Coude Rotator supports the full instrument suite of up to 40 tonnes and has full rotation capabilities similar to the Mount azimuth axis. The TMA has been going through the design, fabrication and assembly process since 2009 with Ingersoll Machine Tool’s and this culminated with the Factory Acceptance Testing (FAT). The preparation for the FAT started not long after the Final Design Review was complete and planning continued through the assembly stages. The official Factory Acceptance testing of the Coude Rotator was conducted during May/Jun 2014 and the Mount in Feb through Apr 2015. This paper provides an overview and discussion of the testing that was carried out. The depth and extent of testing will be described with discussion on what we would do differently next time. Also details of the preparation / process that lead into the testing will be presented. Most importantly the results will be summarized and lessons learned during the testing provided as well as discussion on how this influences the planned site assembly and extent of re-test post assembly.

Published
2016
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11. DKIST enclosure modeling and verification during factory assembly and testing

Author

William R. McBride, Gaizka Murga, Ibon Larrakoetxea, and Heather Marshall

Subjects
Telescope, Physics, Acceptance testing, law, Shutter, Enclosure, Factory (object-oriented programming), Instrumentation (computer programming), Simulation, Marine engineering, Solar telescope, Design review, law.invention
Abstract

The Daniel K. Inouye Solar Telescope (DKIST, formerly the Advanced Technology Solar Telescope, ATST) is unique as, apart from protecting the telescope and its instrumentation from the weather, it holds the entrance aperture stop and is required to position it with millimeter-level accuracy. The compliance of the Enclosure design with the requirements, as of Final Design Review in January 2012, was supported by mathematical models and other analyses which included structural and mechanical analyses (FEA), control models, ventilation analysis (CFD), thermal models, reliability analysis, etc. During the Enclosure Factory Assembly and Testing the compliance with the requirements has been verified using the real hardware and the models created during the design phase have been revisited. The tests performed during shutter mechanism subsystem (crawler test stand) functional and endurance testing (completed summer 2013) and two comprehensive system-level factory acceptance testing campaigns (FAT#1 in December 2013 and FAT#2 in March 2014) included functional and performance tests on all mechanisms, off-normal mode tests, mechanism wobble tests, creation of the Enclosure pointing map, control system tests, and vibration tests. The comparison of the assumptions used during the design phase with the properties measured during the test campaign provides an interesting reference for future projects.

Published
2014
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12. ATST visible broadband imager

Author

Andrew Ferayorni, Steve Hegwer, William R. McBride, Friedrich Wöger, and B. Scott Gregory

Subjects
Diffraction, Computer science, business.industry, Field of view, First light, law.invention, Solar telescope, Telescope, Speckle pattern, Wavelength, Optics, Interference (communication), Filter (video), law, Computer graphics (images), Broadband, business
Abstract

The Advanced Technology Solar Telescope (ATST) is a 4 meter class telescope for observation of the solar atmosphere currently in the construction phase. The Visible Broadband Imager (VBI) is a diffraction limited imaging instrument planned to be the first-light instrument in the ATST instrumentation suite. The VBI is composed of two branches, the "VBI blue" and the "VBI red", and uses state-of-the-art narrow bandwidth interference filters and two custom designed high speed filter wheels to take bursts of images that will be re-constructed using a Graphics Processing Unit (GPU) optimized near-real-time speckle image reconstruction engine. At first light, the VBI instrument will produce diffraction-limited movies of solar activity at eight discrete wavelengths with a field of view of 2 arc minutes square. In this contribution, the VBI design team will discuss the capabilities of the VBI and describe the design of the instrument, highlighting the unique challenges faced in the development of this unique instrument.

Published
2012
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13. The Advanced Technology Solar Telescope: design and early construction

Author

Samuel C. Barden, Jennifer Ditsler, Steve Hegwer, Friedrich Wöger, Mark Warner, Steve Shimko, Robert P. Hubbard, Bret Goodrich, Joseph P. McMullin, Scott Bulau, Eric Hansen, Thomas R. Rimmele, Simon C. Craig, William R. McBride, and S. L. Keil

Subjects
Physics, Solar observatory, business.industry, Solar physics, law.invention, Solar telescope, Telescope, Software, law, Coronal mass ejection, Telescope mount, Aerospace engineering, business, Adaptive optics, Remote sensing
Abstract

The National Solar Observatory’s (NSO) Advanced Technology Solar Telescope (ATST) is the first large U.S. solar telescope accessible to the worldwide solar physics community to be constructed in more than 30 years. The 4-meter diameter facility will operate over a broad wavelength range (0.35 to 28 μm ), employing adaptive optics systems to achieve diffraction limited imaging and resolve features approximately 20 km on the Sun; the key observational parameters (collecting area, spatial resolution, spectral coverage, polarization accuracy, low scattered light) enable resolution of the theoretically-predicted, fine-scale magnetic features and their dynamics which modulate the radiative output of the sun and drive the release of magnetic energy from the Sun’s atmosphere in the form of flares and coronal mass ejections. In 2010, the ATST received a significant fraction of its funding for construction. In the subsequent two years, the project has hired staff and opened an office on Maui. A number of large industrial contracts have been placed throughout the world to complete the detailed designs and begin constructing the major telescope subsystems. These contracts have included the site development, AandE designs, mirrors, polishing, optic support assemblies, telescope mount and coude rotator structures, enclosure, thermal and mechanical systems, and high-level software and controls. In addition, design development work on the instrument suite has undergone significant progress; this has included the completion of preliminary design reviews (PDR) for all five facility instruments. Permitting required for physically starting construction on the mountaintop of Haleakalā, Maui has also progressed. This paper will review the ATST goals and specifications, describe each of the major subsystems under construction, and review the contracts and lessons learned during the contracting and early construction phases. Schedules for site construction, key factory testing of major subsystems, and integration, test and commissioning activities will also be discussed.

Published
2012
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14. The ATST visible broadband imager: a case study for real-time image reconstruction and optimal data handling

Author

Han Uitenbroek, Alexandra Tritschler, Steve Wampler, David Elmore, Bret Goodrich, Thomas R. Rimmele, Friedrich Wöger, Bruce Cowan, and William R. McBride

Subjects
Diffraction, Computer science, Aperture, business.industry, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Astrophysics::Instrumentation and Methods for Astrophysics, Iterative reconstruction, Solar telescope, law.invention, Telescope, law, Computer vision, Instrumentation (computer programming), Artificial intelligence, Speckle imaging, business, Adaptive optics, Image resolution, Image restoration
Abstract

At future telescopes, adaptive optics systems will play a role beyond the correction of Earth's atmosphere. These systems are capable of delivering information that is useful for instrumentation, e.g. if reconstruction algorithms are employed to increase the spatial resolution of the scientific data. For the 4m aperture Advanced Technology Solar Telescope (ATST), a new generation of state-of-the-art instrumentation is developed that will deliver observations of the solar surface at unsurpassed high spatial resolution. The planned Visual Broadband Imager (VBI) is one of those instruments. It will be able to record images at an extremely high rate and compute reconstructed images close to the telescope's theoretical diffraction limit using a speckle interferometry algorithm in near real-time. This algorithm has been refined to take data delivered by the adaptive optics system into account during reconstruction. The acquisition and reconstruction process requires the use of a high-speed data handling infrastructure to retrieve the necessary data from both adaptive optics system and instrument cameras. We present the current design of this infrastructure for the ATST together with a feasibility analysis of the underlying algorithms.

Published
2010
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15. Electron spin resonance study of several 1,4-dihydro-s-tetrazine cation radicals

Author

W. M. Tolles, William R. McBride, and Wayne E. Thun

Subjects
Electron nuclear double resonance, Electron density, Pulsed EPR, Radical, General Chemistry, Zero field splitting, Biochemistry, Ferromagnetic resonance, Catalysis, law.invention, Tetrazine, chemistry.chemical_compound, Colloid and Surface Chemistry, Nuclear magnetic resonance, chemistry, law, Electron paramagnetic resonance
Published
1969
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16. Ammoniates of the Ammonium Halides1

Author

George W. Watt and William R. McBride

Subjects
chemistry.chemical_compound, Colloid and Surface Chemistry, chemistry, Inorganic chemistry, Ammonium, General Chemistry, Biochemistry, Catalysis
Published
1955
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25. The Relative Strengths of Certain Acids in Liquid Ammonia1

Author

William R. McBride, Donald M. Sowards, and George W. Watt

Subjects
Ammonia, chemistry.chemical_compound, Colloid and Surface Chemistry, chemistry, Inorganic chemistry, Urea, Organic chemistry, General Chemistry, Solubility, Biochemistry, Chemical reaction, Quantitative analysis (chemistry), Catalysis
Published
1955
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27. Reactions of Carbon(IV) Iodide with Ammonia and Hydrazine1

Author

George W. Watt, William R. McBride, and Donald M. Sowards

Subjects
chemistry.chemical_classification, Ammonia, chemistry.chemical_compound, Colloid and Surface Chemistry, chemistry, Inorganic chemistry, Iodide, chemistry.chemical_element, General Chemistry, Iodine, Biochemistry, Carbon, Catalysis
Published
1956
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29. Solubility of Nitroguanidine in Water

Author

William R. McBride, Sol Skolnik, Joseph Cohen, and Ronald A. Henry

Subjects
chemistry.chemical_compound, Colloid and Surface Chemistry, Nitroguanidine, chemistry, Organic chemistry, General Chemistry, Solubility, Biochemistry, Catalysis
Published
1951
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31. Absorption Bands of Irradiated Magnesium Fluoride

Author

Marian E. Hills and William R. McBride

Subjects
Magnesium fluoride, chemistry.chemical_compound, Chemistry, Inorganic chemistry, General Physics and Astronomy, Irradiation, Physical and Theoretical Chemistry, Absorption (electromagnetic radiation), Nuclear chemistry
Published
1964
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32. Solubility of Nitroaminoguanidine

Author

G. B. L. Smith, William R. McBride, and Ronald A. Henry

Subjects
Colloid and Surface Chemistry, Chemistry, Organic chemistry, General Chemistry, Solubility, Biochemistry, Catalysis
Published
1949
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34. Use of Filters for Suppressing Scattered Light in Spectrometers Used in the Ultraviolet

Author

William R. McBride and H. E. Bennett

Subjects
Range (particle radiation), Materials science, Spectrometer, business.industry, Infrared, Materials Science (miscellaneous), medicine.disease_cause, Industrial and Manufacturing Engineering, law.invention, Wavelength, Optics, law, medicine, Optoelectronics, Business and International Management, Scattered light, business, Ultraviolet, Visible spectrum, Monochromator
Abstract

The range of spectrometers can be extended to wavelengths shorter than 3000 A in the ultraviolet without modifications which would impair their versatility at longer wavelengths by using an intense source and filtering out the scattered light in the visible and near ultraviolet. An absorption filter composed of nickel sulfate hexahydrate and Corning 9863 glass is described which extends the range of an absolute reflectometer having over thirty reflections and employing a single-beam, double-pass monochromator to about 2400 A.

Published
1964
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