Your search keyword '"Brian J. Comber"' showing total 6 results

1. Development of the Thermal Interface Between the Dragonfly Mass Spectrometer and the DrACO Sample Delivery Carousel

Author

Peter Barfknecht, Kelly A. Burch, Steven T. Cale, Brian J. Comber, Matthew B. Francom, Margaret L. Hudson, Bryan L. James, Vivek A. R. Laljani, Hak Seung Lee, Ryan S. McClelland, Richard S. Ottens, Franklin L. Robinson, and Paul E. Rueger

Subjects

Spacecraft Design, Testing and Performance

Published

2024

2. Status of resolve instrument onboard x-ray imaging and spectroscopy mission (XRISM)

Author

Yoshitaka Ishisaki, Richard L. Kelley, Hisamitsu Awaki, Jesus C. Balleza, Kim R. Barnstable, Thomas G. Bialas, Rozenn Boissay-Malaquin, Gregory V. Brown, Edgar R. Canavan, Renata S. Cumbee, Timothy M. Carnahan, Meng P. Chiao, Brian J. Comber, Elisa Costantini, Jan-Willem A. den Herder, Johannes Dercksen, Cor P. de Vries, Michael J. DiPirro, Megan E. Eckart, Yuichiro Ezoe, Carlo Ferrigno, Ryuichi Fujimoto, Nathalie Gorter, Steven M. Graham, Martin Grim, Leslie S. Hartz, Ryota Hayakawa, Takayuki Hayashi, Natalie Hell, Akio Hoshino, Yuto Ichinohe, Manabu Ishida, Kumi Ishikawa, Bryan L. James, Steven J. Kenyon, Caroline A. Kilbourne, Mark O. Kimball, Shunji Kitamoto, Maurice A. Leutenegger, Yoshitomo Maeda, Dan McCammon, Joseph J. Miko, Misaki Mizumoto, Takashi Okajima, Atsushi Okamoto, Stephane Paltani, Frederick S. Porter, Kosuke Sato, Toshiki Sato, Makoto Sawada, Keisuke Shinozaki, Russell Shipman, Peter J. Shirron, Gary A. Sneiderman, Yang Soong, Richard Szymkiewicz, Andrew E. Szymkowiak, Yoh Takei, Keisuke Tamura, Masahiro Tsujimoto, Yuusuke Uchida, Stephen Wasserzug, Michael C. Witthoeft, Rob Wolfs, Shinya Yamada, and Susumu Yasuda

Published

2022

3. Optical testing and verification methods for the James Webb Space Telescope Integrated Science Instrument Module element

Author

Raymond G. Ohl, Brian J. Comber, David Wright, Derek Sabatke, Joseph F. Sullivan, Gerry Warner, David A. Kubalak, J. Scott Smith, Scott Rohrbach, Douglas M. Kelly, Scott Antonille, Randy A. Kimble, Jeffrey R. Kirk, Wayne B. Landsman, Joseph M. Howard, Charles W. Bowers, Alistair Glasse, Raymond H. Wright, Corbett Smith, David L. Aronstein, Michael Maszkiewicz, William L. Eichhorn, George F. Hartig, Don J. Lindler, Emmanuel Cofie, Renee Gracey, Thomas P. Zielinski, Nicholas R. Collins, Cherie L. Miskey, Andrew Bartoszyk, Eliot M. Malumuth, Julia Zhou, Marcia J. Rieke, Randal Telfer, Maurice te Plate, N. Rowlands, and M. Begona Vila

Subjects

Physics, Scientific instrument, business.industry, James Webb Space Telescope, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Optical telescope, law.invention, 010309 optics, Telescope, Software, Observatory, law, 0103 physical sciences, Test plan, 0210 nano-technology, business, Adaptive optics, Computer hardware, Simulation

Abstract

NASA's James Webb Space Telescope (JWST) is a 6.6m diameter, segmented, deployable telescope for cryogenic IR space astronomy (~40K). The JWST Observatory includes the Optical Telescope Element (OTE) and the Integrated Science Instrument Module (ISIM) that contains four science instruments (SI) and the fine guider. The SIs are mounted to a composite metering structure. The SI and guider units were integrated to the ISIM structure and optically tested at the NASA Goddard Space Flight Center as a suite using the Optical Telescope Element SIMulator (OSIM). OSIM is a full field, cryogenic JWST telescope simulator. SI performance, including alignment and wave front error, were evaluated using OSIM. We describe test and analysis methods for optical performance verification of the ISIM Element, with an emphasis on the processes used to plan and execute the test. The complexity of ISIM and OSIM drove us to develop a software tool for test planning that allows for configuration control of observations, associated scripts, and management of hardware and software limits and constraints, as well as tools for rapid data evaluation, and flexible re-planning in response to the unexpected. As examples of our test and analysis approach, we discuss how factors such as the ground test thermal environment are compensated in alignment. We describe how these innovative methods for test planning and execution and post-test analysis were instrumental in the verification program for the ISIM element, with enough information to allow the reader to consider these innovations and lessons learned in this successful effort in their future testing for other programs.

Published

2016

4. Structural, thermal, and optical performance (STOP) modeling and results for the James Webb Space Telescope integrated science instrument module

Author

Brian J. Comber, Derek Sabatke, Renee Gracey, Raymond G. Ohl, Joseph M. Howard, Andrew Bartoszyk, George F. Hartig, Emmanuel Cofie, and Greg Wenzel

Subjects

Scientific instrument, Physics, business.industry, James Webb Space Telescope, 02 engineering and technology, Orbital mechanics, 021001 nanoscience & nanotechnology, 01 natural sciences, 010309 optics, 0103 physical sciences, Test program, Thermal, Test chamber, Aerospace engineering, 0210 nano-technology, Focus (optics), business, Simulation

Abstract

The James Webb Space Telescope includes the Integrated Science Instrument Module (ISIM) element that contains four science instruments (SI) including a Guider. We performed extensive structural, thermal, and optical performance(STOP) modeling in support of all phases of ISIM development. In this paper, we focus on modeling and results associated with test and verification. ISIMs test program is bound by ground environments, mostly notably the 1g and test chamber thermal environments. This paper describes STOP modeling used to predict ISIM system performance in 0g and at various on-orbit temperature environments. The predictions are used to project results obtained during testing to on-orbit performance.

Published

2016

5. James Webb Space Telescope Integrated Science Instrument Module Calibration and Verification of High-Accuracy Instrumentation to Measure Heat Flow in Cryogenic Testing

Author

Stuart D. Glazer and Brian J. Comber

Subjects

Scientific instrument, Engineering, Thermal conductivity, business.industry, Instrumentation, Thermal, James Webb Space Telescope, Calibration, Mechanical engineering, Cryogenics, business, Space environment

Abstract

The James Webb Space Telescope (JWST) is an upcoming flagship observatory mission scheduled to be launched in 2018. Three of the four science instruments are passively cooled to their operational temperature range of 36K to 40K, and the fourth instrument is actively cooled to its operational temperature of approximately 6K. The requirement for multiple thermal zoned results in the instruments being thermally connected to five external radiators via individual high purity aluminum heat straps. Thermal-vacuum and thermal balance testing of the flight instruments at the Integrated Science Instrument Module (ISIM) element level will take place within a newly constructed shroud cooled by gaseous helium inside Goddard Space Flight Center's (GSFC) Space environment Simulator (SES). The flight external radiators are not available during ISIM-level thermal vacuum/thermal testing, so they will be replaced in test with stable and adjustable thermal boundaries with identical physical interfaces to the flight radiators. Those boundaries are provided by specially designed test hardware which also measures the heat flow within each of the five heat straps to an accuracy of less than 2 mW, which is less than 5% of the minimum predicted heat flow values. Measurement of the heat loads to this accuracy is essential to ISIM thermal model correlation, since thermal models are more accurately correlated when temperature data is supplemented by accurate knowledge of heat flows. It also provides direct verification by test of several high-level thermal requirements. Devices that measure heat flow in this manner have historically been referred to a "Q-meters". Perhaps the most important feature of the design of the JWST Q-meters is that it does not depend on the absolute accuracy of its temperature sensors, but rather on knowledge of precise heater power required to maintain a constant temperature difference between sensors on two stages, for which a table is empirically developed during a calibration campaign in a small chamber at GSFC. This paper provides a brief review of Q-meter design, and discusses the Q-meter calibration procedure including calibration chamber modifications and accommodations, handling of differing conditions between calibration and usage, the calibration process itself, and the results of the tests used to determine if the calibration is successful.

Published

2012

6. James Webb Space Telescope Integrated Scientific Instrument Module: Design, Optimization, and Calibration of High-Accuracy Instrumentation to Measure Heat Flow in Cryogenic Testing

Author

Paul Cleveland, Stuart D. Glazer, and Brian J. Comber

Subjects

Scientific instrument, Physics, business.industry, Instrumentation, James Webb Space Telescope, Astrophysics::Instrumentation and Methods for Astrophysics, Electrical engineering, Range (aeronautics), Thermal, Calibration, Shroud, Aerospace engineering, business, Space environment

Abstract

The James Webb Space Telescope (JWST) is the next of the “Great Observatories”, scheduled to be launched before 2018. Three of the four science instruments are passively cooled to their operational temperature range of 36K to 40K, and the fourth instrument is actively cooled to its operational temperature of approximately 6K. The requirement for multiple thermal zones results in the instruments being thermally connected to five external radiators via individual high purity aluminum heat straps. Thermal-vacuum and thermal balance testing of the flight instruments at the Integrated Science Instrument Module (ISIM) element level will take place within a newly constructed shroud cooled by gaseous helium inside Goddard Space Flight Center’s (GSFC) Space Environment Simulator (SES). The flight external radiators are not available during ISIM-level thermal vacuum/thermal testing, so they will be replaced in test with controllable thermal boundaries with identical physical interfaces to the flight radiators. Those boundaries are provided on specially designed test hardware which measures the heat flow within each of the five heat straps to an accuracy of < 2 mW, which is less than 5% of the minimum predicted heat flow values. This is essential to ISIM thermal model correlation, since the physics of heat flow and temperature changes at these temperatures, coupled with instrumentation limitations, dictates that thermal models are more accurately correlated when temperature data is supplemented by accurate knowledge of heat flows. Devices that measure heat flow in this manner have historically been referred to as “Q-meters”. This paper lists the operational requirements, characteristics, and constraints for the special ISIM Q-meters, and presents the methodology used in their thermal design and evaluation. Factors leading to the selection of the optimal geometry, instrumentation, calibration program, and test usage are presented.

Published

2011