Detecting cloud contamination in passive microwave satellite measurements over land

Abstract. Remotely sensed brightness temperatures from passive observations in the microwave (MW) range are used to retrieve various geophysical parameters, e.g. near-surface temperature. Cloud contamination, although less of an issue at MW than at visible to infrared wavelengths, may adversely affect retrieval quality, particularly in the presence of strong cloud formation (convective towers) or precipitation. To limit errors associated with cloud contamination, we present an index derived from stand-alone MW brightness temperature observations, which measure the probability of residual cloud contamination. The method uses a statistical neural network model trained with the Global Precipitation Microwave Imager (GMI) observations and a cloud classification from Meteosat Second Generation-Spinning Enhanced Visible and Infrared Imager (MSG-SEVIRI). This index is available over land and ocean and is developed for multiple frequency ranges to be applicable to successive generations of MW imagers. The index confidence increases with the number of available frequencies and performs better over the ocean, as expected. In all cases, even for the more challenging radiometric signatures over land, the model reaches an accuracy of ≥70 % in detecting contaminated observations. Finally an application of this index is shown that eliminates grid cells unsuitable for land surface temperature estimation.

[1]  Filipe Aires,et al.  Land Surface Microwave Emissivities over the Globe for a Decade , 2006 .

[2]  Darren L. Jackson,et al.  A physical retrieval of cloud liquid water over the global oceans using special sensor microwave/imager (SSM/I) observations , 1993 .

[3]  José A. Sobrino,et al.  Thermal remote sensing of land surface temperature from satellites: Current status and future prospects , 1995 .

[4]  F. Aires,et al.  Toward “all weather,” long record, and real‐time land surface temperature retrievals from microwave satellite observations , 2016 .

[5]  W. Linwood Jones,et al.  The WindSat spaceborne polarimetric microwave radiometer: sensor description and early orbit performance , 2004, IEEE Transactions on Geoscience and Remote Sensing.

[6]  Justus Notholt,et al.  A cloud filtering method for microwave upper tropospheric humidity measurements , 2007 .

[7]  F. Aires,et al.  A new neural network approach including first guess for retrieval of atmospheric water vapor, cloud liquid water path, surface temperature, and emissivities over land from satellite microwave observations , 2001 .

[8]  John Scott Bridle,et al.  Probabilistic Interpretation of Feedforward Classification Network Outputs, with Relationships to Statistical Pattern Recognition , 1989, NATO Neurocomputing.

[9]  C. Kummerow,et al.  The Tropical Rainfall Measuring Mission (TRMM) Sensor Package , 1998 .

[10]  Catherine Prigent,et al.  Inversion of AMSR‐E observations for land surface temperature estimation: 1. Methodology and evaluation with station temperature , 2017 .

[11]  Lucila Ohno-Machado,et al.  Logistic regression and artificial neural network classification models: a methodology review , 2002, J. Biomed. Informatics.

[12]  N. Grody Classification of snow cover and precipitation using the special sensor microwave imager , 1991 .

[13]  H. Michael Goodman,et al.  Precipitation retrieval over land and ocean with the SSM/I - Identification and characteristics of the scattering signal , 1989 .

[14]  Geoffrey E. Hinton,et al.  Learning representations by back-propagation errors, nature , 1986 .

[15]  F. Aires,et al.  Impact of the inundation occurrence on the deep convection at continental scale from satellite observations and modeling experiments , 2011 .

[16]  David G. Long,et al.  A cloud-removal algorithm for SSM/I data , 1999, IEEE Trans. Geosci. Remote. Sens..

[17]  J. Pekel,et al.  High-resolution mapping of global surface water and its long-term changes , 2016, Nature.

[18]  Geoffrey E. Hinton,et al.  Learning representations by back-propagating errors , 1986, Nature.

[19]  Sandra C. Freitas,et al.  Land surface temperature from multiple geostationary satellites , 2013 .

[20]  M. Derrien,et al.  MSG/SEVIRI cloud mask and type from SAFNWC , 2005 .

[21]  W. Rossow,et al.  Advances in understanding clouds from ISCCP , 1999 .

[22]  Timothy J. Schmit,et al.  A Closer Look at the ABI on the GOES-R Series , 2017 .

[23]  Kurt Hornik,et al.  Approximation capabilities of multilayer feedforward networks , 1991, Neural Networks.

[24]  Ralph Ferraro,et al.  Special sensor microwave imager derived global rainfall estimates for climatological applications , 1997 .

[25]  Edwin W. Pak,et al.  An extended AVHRR 8‐km NDVI dataset compatible with MODIS and SPOT vegetation NDVI data , 2005 .

[26]  Catherine Prigent,et al.  Land Surface Microwave Emissivities Derived from AMSR-E and MODIS Measurements with Advanced Quality Control , 2011 .

[27]  J. Schmid,et al.  The SEVIRI Instrument , 2000 .

[28]  A. Hou,et al.  The Global Precipitation Measurement Mission , 2014 .

[29]  Filipe Aires,et al.  A Land and Ocean Microwave Cloud Classification Algorithm Derived from AMSU-A and -B, Trained Using MSG-SEVIRI Infrared and Visible Observations , 2011 .