Submillimeter Wave Astronomy Satellite
Illustration of SWAS | |||||
Names | Explorer-74, SMEX-3 | ||||
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Mission type | Submillimeter astronomy | ||||
Operator | NASA / Goddard | ||||
COSPAR ID | 1998-071A | ||||
SATCAT № | 25560 | ||||
Website | https://www.cfa.harvard.edu/swas/ | ||||
Mission duration |
Planned: 2 years Final: 6 years, 8 months and 26 days[1] | ||||
Spacecraft properties | |||||
Manufacturer | NASA / Goddard | ||||
Launch mass | 288 kg (635 lb)[2] | ||||
Payload mass | 102 kg (225 lb)[2] | ||||
Dimensions | 1.63 × 1.02 m (5.3 × 3.3 ft)[3] | ||||
Power | 230 W[2] | ||||
Start of mission | |||||
Launch date | December 6, 1998, 00:57 UTC[4] | ||||
Rocket | Pegasus XL | ||||
Launch site |
Stargazer Vandenberg AFB, California, U.S. | ||||
Contractor | Orbital Sciences | ||||
Orbital parameters | |||||
Reference system | Geocentric | ||||
Regime | Low Earth | ||||
Semi-major axis | 6,968.1 km (4,329.8 mi) | ||||
Eccentricity | 0.0005458 | ||||
Perigee | 586.2 km (364.2 mi) | ||||
Apogee | 593.8 km (369.0 mi) | ||||
Inclination | 69.8979° | ||||
Period | 96.4833 min | ||||
RAAN | 85.8457° | ||||
Argument of perigee | 74.6613° | ||||
Mean anomaly | 285.5145° | ||||
Mean motion | 14.9254 rev/day | ||||
Epoch | September 9, 2015, 13:11:43 UTC[5] | ||||
Revolution number | 90902 | ||||
Main telescope | |||||
Name | Submillimeter Wave Telescope | ||||
Type | Cassegrain | ||||
Diameter | 55 × 71 cm (22 × 28 in)[6] | ||||
Wavelengths | 540-610 μm | ||||
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The Submillimeter Wave Astronomy Satellite (SWAS) is a NASA submillimeter astronomy satellite, and is the third spacecraft in the Small Explorer program. It was launched on December 6, 1998 (UTC), from Vandenberg Air Force Base aboard a Pegasus XL rocket.[6] The telescope was designed by the Smithsonian Astrophysical Observatory and integrated by Ball Aerospace, while the spacecraft was built by NASA's Goddard Space Flight Center.[7] The mission's principal investigator is Gary J. Melnick.[6]
Mission
SWAS was designed to study the composition and structure of interstellar clouds and investigate the processes of stellar and planetary formation.[6] Its sole instrument is a telescope operating in the submillimeter wavelengths of far infrared and microwave radiation. The telescope is composed of three main components: a 55 × 71 cm (22 × 28 in) elliptical off-axis Cassegrain reflector,[6][8] two Schottky diode receivers, and an acousto-optical spectrometer.[7] The system is sensitive to frequencies between 487–557 GHz (538–616 μm), which allows it to focus on the spectral lines of molecular oxygen (O2) at 487.249 GHz; neutral carbon (C i) at 492.161 GHz; isotopic water (H218O) at 548.676 GHz; isotopic carbon monoxide (13CO) at 550.927 GHz; and water (H2O) at 556.936 GHz.[6][7]
Comparison[9] | |||
Name | Year | Wavelength | Aperture |
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Human eye | - | 0.39–0.75 μm | 0.01 m |
SWAS | 1998 | 540–610 μm | 0.55×0.71 m |
Spitzer | 2003 | 3–180 μm | 0.85 m |
Hubble WFC3 | 2009 | 0.2–1.7 μm | 2.4 m |
Herschel | 2009 | 60–672 μm | 3.5 m |
History
The Submillimeter Wave Astronomy Satellite mission was approved on April 1, 1989. The project began with the Mission Definition Phase, officially starting on September 29, 1989, and running through January 31, 1992. During this time, the mission underwent a conceptual design review on June 8, 1990, and a demonstration of the Schottky receivers and acousto-optical spectrometer concept was performed on November 8, 1991.[10]
The mission's Development Phase ran from February 1992, through May 1996. The Submillimeter Wave Telescope underwent a preliminary design review on May 13, 1992, and a critical design review on February 23, 1993. Ball Aerospace was responsible for the construction of and integration of components into the telescope. The University of Cologne delivered the acousto-optical spectrometer to Ball for integration into the telescope on December 2, 1993, while Millitech Corporation delivered the Schottky receivers to Ball on June 20, 1994. Ball delivered the finished telescope to Goddard Space Flight Center on December 20, 1994. Goddard, which was responsible for construction of the spacecraft bus, conducted integration of spacecraft and instrument from January through March 1995. Spacecraft qualification and testing took place between April 1, 1995, and December 15, 1995. After this, SWAS was placed into storage until September 1, 1998, when launch preparation was begun.[10]
The spacecraft was delivered to Orbital Sciences Corporation at Vandenberg Air Force Base on November 2, 1998, for integration onto their Pegasus XL rocket.[10] Launch occurred on December 6, 1998, at 00:57 UTC, from Orbital Sciences' Stargazer L-1011 TriStar mothership.[4][11] Its initial orbit was a near-circular 638 × 651 km (396 × 405 mi) with an inclination of 69.9 degrees.[4]
SWAS was originally scheduled to launch in June 1995, but was delayed due to back-to-back launch failures of the Pegasus XL rocket in June 1994 and June 1995. A launch opportunity in January 1997 was again canceled due to a Pegasus XL launch failure in November 1996.[12]
The commissioning phase of the mission lasted until December 19, 1998, when the telescope began producing useful science data.[13] The SWAS mission had a planned duration of two years and a cost estimate of US$60 million,[12][14] but mission extensions allowed for five and a half years of continuous science operations. During this time, data was taken on more than 200 astronomical objects.[10] The decision was made to end science and spacecraft operations on July 21, 2004, at which time the spacecraft was placed into hibernation.[3]
To support the Deep Impact mission at comet 9P/Tempel, SWAS was brought out of hibernation on June 1, 2005. Vehicle check-out was completed on June 5 with no discernible degradation of equipment found. SWAS observations of the comet focused on isotopic water output both before and after the Deep Impact impactor struck the comet's nucleus on July 4. While water output was found to naturally vary by more than a factor of three during the observation campaign, SWAS data showed that there was no excessive release of water due to the impact event. After three months of observation, SWAS was once again placed into hibernation on September 1, 2005.[1]
As of 2015, SWAS remains in Earth orbit on stand-by.
References
- 1 2 Bensch, Frank; Melnick, Gary J.; Neufeld, David A.; Harwit, Martin; Snell, Ronald L.; et al. (October 2006). "Submillimeter Wave Astronomy Satellite observations of Comet 9P/Tempel 1 and Deep Impact". Icarus 184 (2): 602–610. arXiv:astro-ph/0606045. Bibcode:2006Icar..184..602B. doi:10.1016/j.icarus.2006.05.016.
- 1 2 3 "The SWAS Spacecraft". Harvard–Smithsonian Center for Astrophysics. Retrieved September 5, 2015.
- 1 2 Rumerman, Judy A. (2009). NASA Historical Data Book, Volume VII: NASA Launch Systems, Space Transportation/Human Spaceflight, and Space Science 1989-1998 (PDF). NASA History Series. NASA. p. 814-815. ISBN 978-0-16-080501-1. SP-2009-4012.
- 1 2 3 "SWAS - Trajectory Details". National Space Science Data Center. NASA. Retrieved September 8, 2015.
- ↑ "SWAS - Orbit". Heavens Above. September 9, 2015. Retrieved September 9, 2015.
- 1 2 3 4 5 6 "SWAS". National Space Science Data Center. NASA. Retrieved September 5, 2015.
- 1 2 3 Melnick, Gary J.; Stauffer, John R.; Ashby, Matthew L. N.; Bergin, Edwin A.; Chin, Gordon; et al. (August 2000). "The Submillimeter Wave Astronomy Satellite: Science Objectives and Instrument Description". The Astrophysical Journal 539 (2): L77–L85. Bibcode:2000ApJ...539L..77M. doi:10.1086/312856.
- ↑ "The SWAS Instrument". Harvard–Smithsonian Center for Astrophysics. Retrieved September 5, 2015.
- ↑ "Herschel Space Observatory: Related Missions". NASA / Jet Propulsion Laboratory. Retrieved August 9, 2011.
- 1 2 3 4 Tolls, V.; Melnick, G. J.; Ashby, M. L. N.; Bergin, E. A.; Gurwell, M. A.; et al. (May 2004). "Submillimeter Wave Astronomy Satellite Performance on the ground and in orbit". The Astrophysical Journal Supplement Series 152 (1): 137–162. Bibcode:2004ApJS..152..137T. doi:10.1086/382507.
- ↑ "The Launch". Harvard–Smithsonian Center for Astrophysics. Retrieved September 8, 2015.
- 1 2 Cowen, Ron (January 18, 1997). "Space 1997: The New Year Brings an Uncertain Launch Schedule". Science News 151 (3). Archived from the original on January 18, 1997.
- ↑ "SWAS Data Online". Legacy Archive for Microwave Background Data Analysis. NASA. April 18, 2008. Retrieved September 9, 2015.
- ↑ "SWAS". NASA / Science Mission Directorate. Retrieved September 9, 2015.
Further reading
- Melnick, Gary J. (July 1990). "Small Explorer Project: Submillimeter Wave Astronomy Satellite (SWAS), Mission Operations and Data Analysis Plan" (PDF). NASA.
- Slater, Dan (1994). A 550 GHz Near-field Antenna Measurement System for the NASA Submillimeter Wave Astronomy Satellite. Antenna Measurement Techniques Association Conference. October 3–7, 1994. Norwood, Massachusetts.
External links
Wikimedia Commons has media related to SWAS. |
- SWAS website by the Harvard–Smithsonian Center for Astrophysics
- SWAS data archive by NASA's Legacy Archive for Microwave Background Data Analysis
- SWAS data archive by the NASA/IPAC Infrared Science Archive
- SWAS website (archive) by NASA's Goddard Space Flight Center
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