ACRIMSAT explained

ACRIMSAT
Names List:Active Cavity Radiometer Irradiance Monitor Satellite
Mission Type:Solar astronomy
Operator:NASAJPL
Cospar Id:1999-070B
Satcat:26033
Mission Duration:5 years (planned)
(achieved) [1]
Manufacturer:Orbital Sciences Corporation
Dimensions: wide
high
Total span with solar arrays
Power:80 watts
Launch Date:21 December 1999, 07:13 UTC
Launch Rocket:Taurus 2110
Launch Site:Vandenberg, LC-576E
Launch Contractor:Orbital Sciences Corporation
Entered Service:April 2000
Deactivated:30 July 2014
Last Contact:14 December 2013
Orbit Reference:Geocentric orbit[2]
Orbit Regime:Sun-synchronous orbit
Orbit Inclination:98.30°
Orbit Period:99.00 minutes
Apsis:gee
Instruments:Active Cavity Radiometer Irradiance Monitor-3 (ACRIM-3)

The Active Cavity Radiometer Irradiance Monitor Satellite, or ACRIMSAT was a satellite carrying the ACRIM-3 (Active Cavity Radiometer Irradiance Monitor 3) instrument. It was one of the 21 observational components of NASA's Earth Observing System program. The instrument followed upon the ACRIM-1 and ACRIM-2 instruments that were launched on multi-instrument satellite platforms. ACRIMSAT was launched on 20 December 1999 from Vandenberg Air Force Base as the secondary payload on the Taurus launch vehicle that launched KOMPSAT. It was placed into a high inclination of 98.30°, at 720 km. Sun-synchronous orbit from which the ACRIM-3 instrument monitored total solar irradiance (TSI).[3] Contact with the satellite was lost on 14 December 2013.[4]

History

ACRIM-3 made measurements of the TSI since the start of its mission in April 2000. It extended the TSI measurement database begun by earlier ACRIM instruments on the NASA Solar Maximum Mission (SolarMax) (ACRIM-1: 1980–1989) and Upper Atmosphere Research Satellite (UARS) (ACRIM-2: 1991–2001).[5]

ACRIMSAT/ACRIM3 tracked TSI during a 2004 transit of Venus and measured the 0.1% reduction in the solar intensity caused by the planet's shadow.[6] It also recorded data for the Transit of Venus, 2012.[7]

Team

Richard C. Willson was the principal investigator and led the science team.[8] Willson designed the active cavity radiometer type of sensor used by self-calibrating satellite TSI monitoring experiments. The ACRIM3 instrument was a collaboration between Willson, original JPL/ACRIMSAT Project manager Ronald Zenone and ACRIM3 Instrument Scientist Roger Helizon. The mission was controlled using the ACRIMSAT tracking station at the Jet Propulsion Laboratory (JPL) Table Mountain Observatory in Southern California. Co-investigators were: Nicola Scafetta (climate impact of solar variability), Hugh Hudson (solar physics) and Alexander Mordvinov (solar physics).

ACRIMSAT instrument

The ACRIMSAT instrument and spacecraft represent a unique, new capability for NASA research. The instrument is lighter and more compact than its predecessor by a factor of more than two. This allows the radiometer to be flown in a small, dedicated spacecraft like the ACRIMSAT. The satellite/radiometer combination is small enough to be easily launched as a secondary payload on any of an array of boosters, providing its sponsors with the flexibility of numerous launch opportunities while keeping launch costs to a minimum. The active cavity radiometer instrument is designed for precise, continuous measurements of total solar irradiance in spaceflight experiments and is capable of measuring solar energy in the far-ultraviolet to far-infrared wavelength range. The instrument includes three identical active cavity radiometers that are used in different cycles. One monitors the Sun all the time. Data from the second instrument will be compared to data from the first instrument once every few months. The third sensor's data will be used as a comparison with the first and second instruments' data once every two months. With this rotating system of data comparison, anticipated slow changes in the first sensor, caused by exposure to the Sun and space, will be calibrated and removed from its measurement results.[9]

Technology

ACRIMSAT was a spin-stabilized, single-purpose satellite constructed by Orbital Sciences Corporation. Its total cost, including the instrument, launch, ground station, operations, and science team activities during its 14-year mission was less than US$50 million.

End of the mission

In December 2013, ACRIMSAT suffered a mission-ending failure when its degrading batteries could no longer sustain operations. The spacecraft has not responded to ground commands since on 14 December 2013. After several unsuccessful recovery attempts and extensive failure analysis, the mission was determined to be unrecoverable and officially terminated on 30 July 2014.[1]

The spacecraft will remain in orbit for approximately 64 years before returning to Earth.[4]

External links

Notes and References

  1. Web site: ACRIMSAT . Gunter's Space Page. 20 September 2018. 29 October 2021.
  2. Web site: ACRIMSAT 1999-070B 26033 . NASA. 28 October 2021. 29 October 2021.
  3. Web site: ACRIM TSI time series. acrim.com. https://web.archive.org/web/20110716140550/http://www.acrim.com/TSI%20Monitoring.htm. 16 July 2011. 29 October 2021.
  4. Web site: Sun sets for a NASA solar monitoring spacecraft. NASA Jet Propulsion Laboratory. 8 August 2014. 29 October 2021.
  5. Web site: Active Cavity Radiometer Irradiance Monitor Satellite (ACRIMSAT). NASA's Earth Observing System. 23 October 2019. 29 October 2021.
  6. The Astrophysical Journal. 641. Schneider. G.. J. M.. Pasachoff. Richard C.. Willson. The Effect of the Transit of Venus on ACRIM's Total Solar Irradiance Measurements: Implications for Transit Studies of Extrasolar Planets. 641. 565–571. 10.1086/500427. astro-ph/0512251. 2006ApJ...641..565S. 7100975. 2006.
  7. Web site: Photojournal: PIA15820 - NASA's ACRIMSAT Observes Venus Transit. NASA. 15 June 2012. 29 October 2021.
  8. Web site: SCIENCE AND INSTRUMENT TEAM. acrim.com. https://web.archive.org/web/20110925020619/http://www.acrim.com/staff.htm. 25 September 2011. 29 October 2021.
  9. Web site: ACRIMSAT Press Kit . NASA JPL. December 1999. 29 October 2021.