Travis Prochaska
Texas A&M University
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Publication
Featured researches published by Travis Prochaska.
Proceedings of SPIE | 2010
Brian L. Vattiat; Gary J. Hill; J. L. Marshall; D. L. DePoy; Svend M. Bauer; Andreas Kelz; Marc D. Rafal; Richard Savage; John M. Good; John A. Booth; Michael P. Smith; Travis Prochaska; Richard D. Allen
The Visible Integral-Field Replicable Unit Spectrograph (VIRUS) is an integral field spectrograph to support observations for the Hobby-Eberly Telescope Dark Energy Experiment (HETDEX). The VIRUS instrument is fed by more than 33,000 optical fibers and consists of 150 spectrographs in 75 individual, identical units. This paper discusses the evolution in mechanical design of the VIRUS unit spectrographs to maximize the cost benefit from volume production. Design features which enable volume manufacture and assembly are discussed. Strategies for reducing part count while enabling precision alignment are detailed. Design considerations for deployment, operation, and maintenance en mass at the Hobby-Eberly Telescope are also made. In addition, several enabling technologies are described including the use of cast aluminum in vacuum housings, use of cast Invar, and processing cast parts for precision tolerances.
Proceedings of SPIE | 2014
Gary J. Hill; Sarah E. Tuttle; Niv Drory; Hanshin Lee; Brian L. Vattiat; D. L. DePoy; J. L. Marshall; Andreas Kelz; Dionne M. Haynes; Maximilian Fabricius; Karl Gebhardt; Richard D. Allen; Heiko Anwad; Ralf Bender; Guillermo A. Blanc; Taylor S. Chonis; Mark E. Cornell; Gavin Dalton; John M. Good; Thomas Jahn; Hermanus Kriel; Martin Landriau; Phillip J. MacQueen; Jeremy D. Murphy; Trent Peterson; Travis Prochaska; H. Nicklas; Jason Ramsey; Martin M. Roth; Richard Savage
The Visible Integral-field Replicable Unit Spectrograph (VIRUS) consists of a baseline build of 150 identical spectrographs (arrayed as 75 unit pairs) fed by 33,600 fibers, each 1.5 arcsec diameter, at the focus of the upgraded 10 m Hobby-Eberly Telescope (HET). VIRUS has a fixed bandpass of 350-550 nm and resolving power R~700. VIRUS is the first example of industrial-scale replication applied to optical astronomy and is capable of surveying large areas of sky, spectrally. The VIRUS concept offers significant savings of engineering effort, cost, and schedule when compared to traditional instruments. The main motivator for VIRUS is to map the evolution of dark energy for the Hobby-Eberly Telescope Dark Energy Experiment (HETDEX), using 0.8M Lyman-α emitting galaxies as tracers. The full VIRUS array is due to be deployed starting at the end of 2014 and will provide a powerful new facility instrument for the HET, well suited to the survey niche of the telescope, and will open up large area surveys of the emission line universe for the first time. VIRUS is in full production, and we are about half way through. We review the production design, lessons learned in reaching volume production, and preparation for deployment of this massive instrument. We also discuss the application of the replicated spectrograph concept to next generation instrumentation on ELTs.
Proceedings of SPIE | 2014
Gary J. Hill; Niv Drory; John M. Good; Hanshin Lee; Brian L. Vattiat; Herman Kriel; Randy Bryant; Linda Elliot; Martin Landriau; Ron Leck; David Perry; Jason Ramsey; Richard Savage; Richard D. Allen; George Damm; D. L. DePoy; Jim Fowler; Karl Gebhardt; Marco Haeuser; Phillip J. MacQueen; J. L. Marshall; Jerry Martin; Travis Prochaska; Lawrence W. Ramsey; Jean Philippe Rheault; Matthew Shetrone; Emily Mrozinski; Sarah E. Tuttle; Mark E. Cornell; John A. Booth
The Hobby-Eberly Telescope (HET) is an innovative large telescope located in West Texas at the McDonald Observatory. The HET operates with a fixed segmented primary and has a tracker, which moves the four-mirror optical corrector and prime focus instrument package to track the sidereal and non-sidereal motions of objects. A major upgrade of the HET is in progress that will substantially increase the pupil size to 10 meters (from 9.2 m) and the field of view to 22 arcminutes (from 4 arcminutes) by replacing the corrector, tracker, and prime focus instrument package. In addition to supporting existing instruments, and a new low resolution spectrograph, this wide field upgrade will feed a revolutionary new integral field spectrograph called VIRUS, in support of the Hobby-Eberly Telescope Dark Energy Experiment (HETDEX§). The upgrade is being installed and this paper discusses the current status.
Proceedings of SPIE | 2012
Gary J. Hill; Sarah E. Tuttle; Hanshin Lee; Brian L. Vattiat; Mark E. Cornell; D. L. DePoy; Niv Drory; Maximilian Fabricius; Andreas Kelz; J. L. Marshall; Jeremy D. Murphy; Travis Prochaska; Richard D. Allen; Ralf Bender; Guillermo A. Blanc; Taylor S. Chonis; Gavin B. Dalton; Karl Gebhardt; John M. Good; Dionne M. Haynes; Thomas Jahn; Phillip J. MacQueen; Marc D. Rafal; Martin M. Roth; Richard Savage; Jan Snigula
The Visible Integral-field Replicable Unit Spectrograph (VIRUS) consists of a baseline build of 150 identical spectrographs (arrayed as 75 units, each with a pair of spectrographs) fed by 33,600 fibers, each 1.5 arcsec diameter, deployed over the 22 arcminute field of the upgraded 10 m Hobby-Eberly Telescope (HET). The goal is to deploy 82 units. VIRUS has a fixed bandpass of 350-550 nm and resolving power R~700. VIRUS is the first example of industrial-scale replication applied to optical astronomy and is capable of spectral surveys of large areas of sky. This approach, in which a relatively simple, inexpensive, unit spectrograph is copied in large numbers, offers significant savings of engineering effort, cost, and schedule when compared to traditional instruments. The main motivator for VIRUS is to map the evolution of dark energy for the Hobby-Eberly Telescope Dark Energy Experiment (HETDEX) using 0.8M Lyman-α emitting galaxies as tracers. The full VIRUS array is due to be deployed by early 2014 and will provide a powerful new facility instrument for the HET, well suited to the survey niche of the telescope. VIRUS and HET will open up wide-field surveys of the emission-line universe for the first time. We present the production design and current status of VIRUS.
Proceedings of SPIE | 2012
Sarah E. Tuttle; Richard D. Allen; Taylor S. Chonis; Mark E. Cornell; D. L. DePoy; Gary J. Hill; Hanshin Lee; J. L. Marshall; Travis Prochaska; Marc D. Rafal; Richard Savage; Brian L. Vattiat
The Hobby-Eberly Telescope Dark Energy Experiment (HETDEX) uses a novel technique of replicated spectrographs (VIRUS) to measure dark energy at intermediate redshifts (2 < z < 4). VIRUS contains over 30,000 fibers and over 160 independent and identical channels. Here we report on the construction and characterization of the initial batch of VIRUS spectrograph cameras. Assembly of the first batch of 16 is in progress. A brief overview of the assembly is presented, and where available performance is compared to specification.
Proceedings of SPIE | 2014
Travis Prochaska; Roland E. Allen; N. Mondrik; Jean-Philippe Rheault; Marcus Sauseda; Emily Boster; M. James; M. Rodriguez-Patino; G. Torres; J. Ham; Erika Cook; David B. Baker; D. L. DePoy; J. L. Marshall; Gary J. Hill; Dave M. Perry; Richard Savage; John M. Good; Brian L. Vattiat
The Visible Integral-Field Replicable Unit Spectrograph (VIRUS) instrument will be installed at the Hobby-Eberly Telescope† in the near future. The instrument will be housed in two enclosures that are mounted adjacent to the telescope, via the VIRUS Support Structure (VSS). We have designed the enclosures to support and protect the instrument, to enable servicing of the instrument, and to cool the instrument appropriately while not adversely affecting the dome environment. The system uses simple HVAC air handling techniques in conjunction with thermoelectric and standard glycol heat exchangers to provide efficient heat removal. The enclosures also provide power and data transfer to and from each VIRUS unit, liquid nitrogen cooling to the detectors, and environmental monitoring of the instrument and dome environments. In this paper, we describe the design and fabrication of the VIRUS enclosures and their subsystems.
Proceedings of SPIE | 2012
D. L. DePoy; Roland E. Allen; Robert H. Barkhouser; Emily Boster; D. W. Carona; Albert Harding; Randolph Hammond; J. L. Marshall; Joseph Orndorff; Casey Papovich; K. Prochaska; Travis Prochaska; Jean-Philippe Rheault; Stephen A. Smee; Stephen A. Shectman; S. Villanueva
We present a conceptual design for a moderate resolution optical spectrograph for the Giant Magellan Telescope (GMT). The spectrograph is designed to make use of the large field-of-view of the GMT and be suitable for observations of very faint objects across a wide range of optical wavelengths. We show some details of the optical and mechanical design of the instrument.
Proceedings of SPIE | 2014
J. L. Marshall; Patrick Williams; Jean-Philippe Rheault; Travis Prochaska; Richard D. Allen; D. L. DePoy
We present total and specular reflectance measurements of various materials that are commonly (and uncommonly) used to provide baffling and/or to minimize the effect of stray light in optical systems. More specifically, we investigate the advantage of using certain black surfaces and their role in suppressing stray light on detectors in optical systems. We measure the total reflectance of the samples over a broad wavelength range (250 < λ < 2500 nm) that is of interest to astronomical instruments in the ultraviolet, visible, and near-infrared regimes. Additionally, we use a helium-neon laser to measure the specular reflectance of the samples at various angles. Finally, we compare these two measurements and derive the specular fraction for each sample.
Proceedings of SPIE | 2014
Sarah E. Tuttle; Gary J. Hill; Hanshin Lee; Brian L. Vattiat; Eva Noyola; Niv Drory; Mark E. Cornell; Trent Peterson; Taylor S. Chonis; Richard D. Allen; Gavin Dalton; D. L. DePoy; Doug Edmonston; M. Fabricius; Dionne M. Haynes; Andreas Kelz; Martin Landriau; Michael P. Lesser; Bob Leach; J. L. Marshall; Jeremy D. Murphy; David Perry; Travis Prochaska; Jason Ramsey; Richard Savage
VIRUS is the massively replicated fiber-fed spectrograph being built for the Hobby-Eberly Telescope to support HETDEX (the Hobby-Eberly Telescope Dark Energy Experiment). The instrument consists of 156 identical channels, fed by 34,944 fibers contained in 78 integral field units, deployed in the 22 arcminute field of the upgraded HET. VIRUS covers 350-550nm at R ≈ 700 and is built to target Lyman α emitters at 1.9 < z < 3.5 to measure the evolution of dark energy. Here we present the assembly line construction of the VIRUS spectrographs, including their alignment and plans for characterization. We briefly discuss plans for installation on the telescope. The spectrographs are being installed on the HET in several stages, and the instrument is due for completion by the end of 2014.
Proceedings of SPIE | 2014
J. L. Marshall; D. L. DePoy; Travis Prochaska; Richard D. Allen; Patrick Williams; Jean-Philippe Rheault; Ting Li; D. Q. Nagasawa; Christopher Akers; David B. Baker; Emily Boster; Caitlin Campbell; Erika Cook; Alison Elder; Alex Gary; Joseph Glover; Michael James; Emily Martin; Will Meador; N. Mondrik; Marisela Rodriguez-Patino; S. Villanueva; Gary J. Hill; Sarah E. Tuttle; Brian L. Vattiat; Hanshin Lee; Taylor S. Chonis; Gavin Dalton; Mike Tacon
The Visual Integral-Field Replicable Unit Spectrograph (VIRUS) instrument is a baseline array 150 identical fiber fed optical spectrographs designed to support observations for the Hobby-Eberly Telescope Dark Energy Experiment (HETDEX). The collimator subassemblies of the instrument have been assembled in a production line and are now complete. Here we review the design choices and assembly practices used to produce a suite of identical low-cost spectrographs in a timely fashion using primarily unskilled labor.
