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Irradiance Observations of SMM, Spacelab 1, UARS, and ATLAS Experiments

Published online by Cambridge University Press:  12 April 2016

Richard C. Willson
Richard C. Willson*
Affiliation:
Solar Irradiance Monitoring Group, Earth and Space Sciences Division, Jet Propulsion Laboratory, California Institute of Technology, Pasadena, CA 91109, USA

Abstract

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Detection of intrinsic solar variability on the total flux level was made using results from the first Active Radiometer Irradiance Monitor (ACRIM) experiment, launched on the Solar Maximum Mission (SMM) in early 1980. ACRIM I, specifically designed to start the high precision total solar irradiance database as part of the U.S. Climate Research Program, produced high precision results throughout the 9.75 years of the Solar Maximum Mission. The second ACRIM experiment was flown aboard the Space Shuttle as part of the NASA/ESA Spacelab 1 Mission in late 1983. Its primary function has been to provide a comparison with ACRIM I that could be used to relate its observations with future satellite solar monitors, should they and ACRIM I fail to overlap in time. The second ACRIM satellite solar monitoring experiment (ACRIM II) has provided high precision total solar irradiance observations since its launch as part of the Upper Atmosphere Research Satellite (UARS) mission in late 1991 and continues at present. The shuttle ACRIM instrumentation has been flown on the ATLAS 1 and 2 missions in 1992 and 1993, providing comparisons with the UARS/ACRIM II.

Type
Observational Programs for Solar and Stellar Irradiance Variability
Information
International Astronomical Union Colloquium , Volume 143: The Sun as a Variable Star: Solar and Stellar Irradiance Variations , 1994 , pp. 54 - 62
Copyright
Copyright © Kluwer 1994

References

Anderson, R.Y. 1991 Solar variability captured in climatic and high-resolution paleoclimatic and high-resolution paleoclimatic records: A geological perspective. In The Sun in Time (ed. Sonett, C.P., Giampapa, M.S. & Mathews, M.W.), pp. 543561. Univ. Arizona Press, Tucson, AZ, USA.Google Scholar
Brusa, R.W. & Fröhlich, .C. 1972 Entwicklung eines neuen Absolutradiometers. Technical Note 1. World Radiation Center, Davos, Switzerland.Google Scholar
Crommelynck, D. 1981 Fundamentals of absolute pyrheliometry and objective characterization. Technical Note World Radiation Center, Davos, Switzerland.Google Scholar
Crommelynck, D. 1993 Private communications.Google Scholar
Crommelynck, D., Domingo, V., Fichot, A. & Lee, R. 1994 Irradiance observations from the EURECA and ATLAS experiments. In The Sun as a Variable Star: Solar and Stellar Irradiance Variations (ed. Pap, J.M., Fröhlich, C., Hudson, H.S. & Solanki, S.K.). Cambridge University Press, in press.Google Scholar
Eddy, J.A. 1977 Historical evidence for the existence of the solar cycle. In Solar Output and Its Variation (ed. White, O.R.), pp. 5171, Univ. of Colorado Press, Boulder, CO, USA.Google Scholar
Fröhlich, .C. 1993 Private communications.Google Scholar
Fröhlich, .C. 1994 Reviews of space observations of total solar irradiance. In The Sun as a Variable Star: Solar and Stellar Irradiance Variations, (ed. Pap, J.M., Fröhlich, C., Hudson, H.S. & Solanki, S.K.). Cambridge Univ. Press, in press.Google Scholar
Hyot, D. & Kyle, L. 1990 An alternative derivation of the Nimbus-7 total solar irradiance variations. In Climate Impact of Solar Variability (ed. Schatten, K.H. & Arking, A.). NASACP-3086, 293300.Google Scholar
Romero, J., Wehrli, C. & FrÖhlich, C. 1994 Solar total irradiance variability from SOVA2 on board EURECA. Solar Phys., in press.Google Scholar
Willson, R.C. 1980 Solar irradiance observations from the SMM/ACRIM experiment. American Geophysical Union, Toronto, Canada, May 1980.Google Scholar
Willson, R.C. 1982 Solar irradiance variations and solar activity. J. Geophys. Res. 86, 43194326.Google Scholar
Willson, R.C. 1984 Measurements of solar total irradiance and its variability. Space Science Reviews 38, 203242.Google Scholar
Willson, R.C. 1992 Solar total irradiance monitoring, past, present and future. EOS Transactions, American Geophysical Union 73(14), pp. 242.Google Scholar
Willson, R.C. & Hudson, H.S. 1981 Variations of solar irradiance. Astroph. J. Lett. 24, 185189.Google Scholar
Willson, R.C. & Hudson, H.S. 1988 Solar luminosity variations in solar cycle 21, Nature 332, 810812.Google Scholar
Willson, R.C. & Hudson, H.S. 1991 The Sun’s luminosity over a complete solar cycle. Nature 351, 4244.Google Scholar
Willson, R.C., Gulkis, S., Janssen, M., Hudson, H.S. & Chapman, G.A. 1981 Observations of solar irradiance variability. Science 211, 700702.Google Scholar