Editorial Type:
Article
Article Type:
Research Article

Analysis of the Merging Procedure for the MSU Daily Temperature Time Series

John R. Christy ESSL, GHCC, University of Alabama in Huntsville, Huntsville, Alabama

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Roy W. Spencer NASA/Marshall Space Flight Center, Huntsville, Alabama

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Elena S. Lobl ESSL, GHCC, University of Alabama in Huntsville, Huntsville, Alabama

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Print Publication:
01 Aug 1998
DOI:
https://doi.org/10.1175/1520-0442(1998)011<2016:AOTMPF>2.0.CO;2
Page(s):
2016–2041
Restricted access

Abstract

The merging procedure utilized to generate homogeneous time series of three deep-layer atmospheric temperature products from the nine microwave sounding units (MSUs) is described. A critically important aspect in the process is determining and removing the bias each instrument possesses relative to a common base (here being NOAA-6). Special attention is given to the lower-tropospheric layer and the calculation of the bias of the NOAA-9 MSU and its rather considerable impact on the trend of the overall time series. We show that the bias is best calculated by a direct comparison between NOAA-6 and NOAA-9, though there other possible methods available, and is determined to be +0.50°C. Spurious variations of individual MSUs due to orbital drift and/or cyclic variations tied to the annual cycle are also identified and eliminated. In general, intersatellite biases for the three instruments that form the backbone of the time series (MSUs on NOAA-6, -10 and -12) are known to within 0.01°C.

After slight modifications in the treatment of the bias, drift-error, and cyclic fluctuations, the authors produced a time series in which the decadal trend is +0.03°C warmer than previously reported for the lower troposphere. Because they are of much higher precision, the midtropospheric and lower-stratospheric products are only slightly affected by alterations to procedures applied in this study.

Recent suggestions that spurious jumps were present in the lower-tropospheric time series of earlier versions of the MSU data based on SST comparisons are addressed. Using independent comparisons of different satellites, radiosondes, and night marine air temperatures, no indication is found of the presence of these “spurious” jumps.

Corresponding author address: Dr. John R. Christy, ESSL/GHCC, University of Alabama in Huntsville, Huntsville, AL 35899.

Abstract

The merging procedure utilized to generate homogeneous time series of three deep-layer atmospheric temperature products from the nine microwave sounding units (MSUs) is described. A critically important aspect in the process is determining and removing the bias each instrument possesses relative to a common base (here being NOAA-6). Special attention is given to the lower-tropospheric layer and the calculation of the bias of the NOAA-9 MSU and its rather considerable impact on the trend of the overall time series. We show that the bias is best calculated by a direct comparison between NOAA-6 and NOAA-9, though there other possible methods available, and is determined to be +0.50°C. Spurious variations of individual MSUs due to orbital drift and/or cyclic variations tied to the annual cycle are also identified and eliminated. In general, intersatellite biases for the three instruments that form the backbone of the time series (MSUs on NOAA-6, -10 and -12) are known to within 0.01°C.

After slight modifications in the treatment of the bias, drift-error, and cyclic fluctuations, the authors produced a time series in which the decadal trend is +0.03°C warmer than previously reported for the lower troposphere. Because they are of much higher precision, the midtropospheric and lower-stratospheric products are only slightly affected by alterations to procedures applied in this study.

Recent suggestions that spurious jumps were present in the lower-tropospheric time series of earlier versions of the MSU data based on SST comparisons are addressed. Using independent comparisons of different satellites, radiosondes, and night marine air temperatures, no indication is found of the presence of these “spurious” jumps.

Corresponding author address: Dr. John R. Christy, ESSL/GHCC, University of Alabama in Huntsville, Huntsville, AL 35899.

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  • Angell, J. K., 1988: Variations and trends in tropospheric and stratospheric global temperatures 1958–87. J. Climate,1, 1296–1313.

  • Basist, A. N., and M. Chelliah, 1997: Comparison of tropospheric temperatures derived from the NCEP/NCAR reanalysis, NCEP operational analysis, and the Microwave Sounding Unit. Bull. Amer. Meteor. Soc.,78, 1431–1447.

  • Christy, J. R., 1995: Temperature above the surface layer. Climate Change,31, 455–474.

  • ——, and S. J. Drouilhet, 1994: Variability in daily, zonal mean lower-stratospheric temperatures. J. Climate,7, 106–120.

  • ——, R. W. Spencer, and R. T. McNider, 1995: Reducing noise in the MSU daily lower-tropospheric global temperature dataset. J. Climate,8, 888–896.

  • ——, ——, and W. D. Braswell, 1997: How accurate are satellite ‘thermometers’? Nature,389, 342.

  • Goldberg, M. D., and H. E. Fleming, 1995: An algorithm to generate deep-layer temperatures from microwave satellite observations for the purpose of monitoring climate change. J. Climate,8, 993–1004.

  • Hansen, J., H. Wilson, M. Sato, R. Ruedy, K. Shah, and E. Hansen, 1995: Satellite and surface temperature data at odds? Climate Change,30, 103–117.

  • ——, R. Ruedy, and M. Sato, 1996: Global surface air temperature in 1995: Return to pre-Pinatubo level. Geophys. Res. Lett.,23, 1665–1668.

  • Hurrell, J. W., and K. E. Trenberth, 1996: Satellite versus surface estimates of air temperature since 1979. J. Climate,9, 2222–2232.

  • ——, and ——, 1997: Spurious trends in satellite MSU temperatures from merging different satellite records. Nature,386, 164–167.

  • ——, and ——, 1998: Difficulties in obtaining reliable temperature trends: Reconciling the surface and satellite Microwave Sounding Unit records. J. Climate,11, 945–967.

  • Kidwell, K. B., 1995: NOAA polar orbiter data users guide. National Oceanic and Atmospheric Administration, 410 pp. [Available from NOAA, Federal Office Bldg. #3, Room G-233, Washington, DC 20233.].

  • Mo, T., 1994: A study of the microwave sounding unit on the NOAA-12 satellite. Proc. Int. Geoscience and Remote Sensing Symp., Pasadena, CA, California Institute of Technology, 1535–1537.

  • Nicholls, N. N., G. V. Gruza, J. Jouzel, T. R. Karl, L. A. Ogallo, and D. E. Parker, 1996: Observed climate variability and change. Climate Change 1995, J. T. Houghton et al., Eds., Cambridge University Press, 133–192.

  • Oort, A. H., and H. Liu, 1993: Upper-air temperature trends over the globe, 1958–1989. J. Climate,6, 292–307.

  • Parker, D. E., and C. K. Folland, 1991: Worldwide surface temperature trends since the mid-19th century. Greenhouse-Gas-Induced Climate Change: A Critical Appraisal of Simulations and Observations, M. E. Schlesinger, Ed., Elsevier Science, 173–193.

  • ——, ——, and M. Jackson, 1995: Marine surface temperature: Observed variations and data requirements. Climate Change,31, 429–470.

  • ——, M. Gordon, D. P. N. Cullum, D. M. H. Sexton, C. K. Folland, and N. Rayner, 1997: A new global gridded radiosonde temperature data base and recent temperature trends. Geophys. Res. Lett.,24, 1499–1502.

  • Richner, H., and P. D. Phillips, 1984: A comparison of temperatures from mountaintops and the free-atmosphere—Their diurnal variation and mean difference. Mon. Wea. Rev.,112, 1328–1340.

  • Spencer, R. W., and J. R. Christy, 1992a: Precision and radiosonde validation of satellite gridpoint temperature anomalies. Part I: MSU channel 2. J. Climate,5, 847–857.

  • ——, and ——, 1992b: Precision and radiosonde validation of satellite gridpoint temperature anomalies. Part II: A tropospheric retrieval and trends during 1979–90. J. Climate,5, 858–866.

  • ——, and ——, 1993: Precision lower stratospheric temperature monitoring with the MSU: Validation and results 1979–91. J. Climate,6, 1194–1204.

  • ——, ——, and N. C. Grody, 1990: Global atmospheric temperature monitoring with satellite microwave measurements: Methods and results 1979–84. J. Climate,3, 1111–1128.

  • Stendel, M., and L. Bengtsson, 1997: Toward monitoring the tropospheric temperature by means of a general circulation model. J. Geophys. Res.,102, 29 779–29 788.

  • Walliser, D. E., and W. Zhou, 1997: Removing satellite equatorial crossing time biases from OLR and HRC datasets. J. Climate,10, 2125–2146.

  • Webster, P. J., C. A. Clayson, and J. A. Curry, 1996: Clouds, radiation, and the diurnal cycle of sea surface temperatures in the tropical western Pacific. J. Climate,9, 1712–1730.

  • Weisberg, R. H., and C. Wang, 1997: Slow variability in the equatorial west-central Pacific in relation to ENSO. J. Climate,10, 1998–2017.

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