Erika Cook
Texas A&M University
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Publication
Featured researches published by Erika Cook.
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 | 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.
arXiv: Instrumentation and Methods for Astrophysics | 2018
D. M. Faes; Aline Souza; Cynthia S. Froning; Luke M. Schmidt; Erika Cook; D. L. DePoy; Tae-Geun Ji; Damien Jones; J. L. Marshall; Hye-In Lee; Claudia Mendez de Oliveira; Soojong Pak; Casey Papovich; Travis Prochaska; Rafael A. S. Ribeiro; Keith Taylor; Daiana R. Bortoletto
An important tool for the development of the next generation of extremely large telescopes (ELTs) is a robust Systems Engineering (SE) methodology. GMACS is a first-generation multi-object spectrograph that will work at visible wavelengths on the Giant Magellan Telescope (GMT). In this paper, we discuss the application of SE to the design of next-generation instruments for ground-based astronomy and present the ongoing development of SE products for the GMACS spectrograph, currently in its Conceptual Design phase. SE provides the means to assist in the management of complex projects, and in the case of GMACS, to ensure its operational success, maximizing the scientific potential of GMT.
Optical Design and Engineering VII | 2018
Rafael A. S. Ribeiro; Damien Jones; Luke M. Schmidt; Keith Taylor; Erika Cook; D. L. DePoy; D. M. Faes; Cynthia S. Froning; Tae-Geun Ji; Hye-In Lee; J. L. Marshall; Claudia Mendes de Oliveira; Soojong Pak; Casey Papovich; Travis Prochaska; Aline Souza
We present the current optical design of GMACS, a multi-object wide field optical spectrograph currently being developed for the Giant Magellan Telescope, a member of the emerging generation of Extremely Large Telescopes (ELTs). Optical spectrographs for ELTs have unique design challenges and issues. For example, the combination of the largest practical field of view and beam widths necessary to achieve the desired spectral resolutions force the design of seeing limited ELT optical spectrographs to include aspheric lenses, broadband dichroics, and volume phase holographic gratings - all necessarily very large. We here outline details of the collimator and camera subsystems, the design methodology and trade-off analyses used to develop the collimator subsystem, the individual and combined subsystem performances and the predicted tolerances.
Ground-based and Airborne Instrumentation for Astronomy VII | 2018
Cynthia S. Froning; D. Bortoletto; Luke M. Schmidt; D. L. DePoy; Erika Cook; D. M. Faes; Tae-Geun Ji; Damien Jones; Hye-In Lee; J. L. Marshall; Claudia Mendes de Oliveira; Soojong Pak; Casey Papovich; Travis Prochaska; Rafael A. S. Ribeiro; Aline Souza; Keith Taylor
We discuss the latest developments of a spectrograph for the Giant Magellan Telescope. The instrument is designed to provide high throughput, moderate resolution, optical spectra for the telescope and be capable of flexible and rapid reconfiguration. The focal plane can be populated with custom slit masks or multiple fibers, allowing for observations of multiple objects simultaneously.
Ground-based and Airborne Instrumentation for Astronomy VII | 2018
Travis Prochaska; Caron Albert; James Beck; Erika Cook; D. L. DePoy; D. M. Faes; Cynthia S. Froning; Walter Grant; Isaac Gutierrez; Tae-Geun Ji; Damien Jones; Hye-In Lee; J. L. Marshall; Claudia Mendes de Oliveira; Soojong Pak; Casey Papovich; Rafael A. S. Ribeiro; Marcus Sauseda; Luke M. Schmidt; Aline Souza; Keith Taylor; Darius Williams
We describe the optical design of GMACS, a multi-object wide field optical spectrograph currently being developed for the Giant Magellan Telescope (GMT). Optical spectrographs for the emerging generation of Extreme Large Telescopes (ELTs) have unique design issues. For example, the combination of both the largest field of view practical and beam widths achieving the desired spectral resolutions force the design of seeing limited ELT optical spectrographs to include large refractive elements, which in turn requires a compromise between the optical performance, manufacturability, and operability. We outline the details of the GMACS optical design subsystems, their individual and combined optical performance, and the preliminary flexure tolerances. Updates to the detector specifications, field acquisition/alignment optics, and optical considerations for active flexure control are also discussed. The resulting design meets the technical instrument requirements generated from the GMACS science requirements, is expected to satisfy the available project budget, and has an acceptable level of risk for the subsystem manufacture and assembly.
Ground-based and Airborne Instrumentation for Astronomy VII | 2018
Erika Cook; Travis Prochaska; Hye-In Lee; Tae-Geun Ji; Soojong Pak; D. L. DePoy; J. L. Marshall; Luke M. Schmidt; Aline Souza; Keith Taylor; D. M. Faes; Cynthia S. Froning; Damien Jones; Claudia Mendes de Oliveira; Rafael A. S. Ribeiro; Casey Papovich
We describe the current electronics prototypes for the Flexure Compensation System (FCS) and the Slit Mask Exchange Mechanism (SMEM) for GMACS, a wide-field, multi-object, moderate-resolution optical spectrograph for the Giant Magellan Telescope (GMT). We discuss the details of the FCS and SMEM prototypes, how the prototypes relate to the preliminary conceptual designs of these systems, and what information the prototypes give that can be applied to the final design, as well as the possible next steps for each prototype.
Advances in Optical and Mechanical Technologies for Telescopes and Instrumentation III | 2018
Renny Spencer; Edmundo Balderrama; George Damm; Jim Fowler; John M. Good; Gary J. Hill; Hermanus Kriel; Emily Mrozinski; Dave M. Perry; Matthew Shetrone; Richard Savage; Erika Cook; Greg Smith; D. L. DePoy; J. L. Marshall; Travis Prochaska; Marcus Sauceda; Phillip J. MacQueen; Trent Peterson
The Visible Integral-field Replicable Unit Spectrograph (VIRUS) consists of 156 identical spectrographs fed by 35,000 fibers from the upgraded 10-meter Hobby-Eberly Telescope (HET). VIRUS is in a phased deployment. At the submission of this paper, over half of the units are installed and the full support infrastructure is operational. This paper will describe the VIRUS infrastructure which includes the physical support system, the air cooling, the cryogenic cooling, and the temperature control of VIRUS. The paper will also discuss the various installation, maintenance, and operational procedures based on growing experience with the VIRUS array.
Proceedings of SPIE | 2016
Travis Prochaska; Marcus Sauseda; James Beck; Luke M. Schmidt; Erika Cook; D. L. DePoy; J. L. Marshall; Rafael A. S. Ribeiro; Keith Taylor; Damien Jones; Cynthia S. Froning; Soojong Pak; Claudia Mendes de Oliveira; Casey Papovich; Tae-Geun Ji; Hye-In Lee
We describe a preliminary conceptual optomechanical design for GMACS, a wide-field, multi-object, moderate resolution optical spectrograph for the Giant Magellan Telescope (GMT). This paper describes the details of the GMACS optomechanical conceptual design, including the requirements and considerations leading to the design, mechanisms, optical mounts, and predicted flexure performance.
