Advanced search
Publication Cover
International Journal of Digital Earth Volume 15, 2022 - Issue 1
Submit an article Journal homepage
1,449
Views
3
CrossRef citations to date
0
Altmetric
Articles

Performances of six reanalysis profile products in the atmospheric correction of passive microwave data for estimating land surface temperature under cloudy-sky conditions

Xin-Ming Zhua College of Resources and Environment, University of Chinese Academy of Sciences, Beijing, People’s Republic of China;b Yanshan Earth Critical Zone and Surface Fluxes Research Station, University of Chinese Academy of Sciences, Beijing, People’s Republic of ChinaView further author information
,
Xiao-Ning Songa College of Resources and Environment, University of Chinese Academy of Sciences, Beijing, People’s Republic of China;b Yanshan Earth Critical Zone and Surface Fluxes Research Station, University of Chinese Academy of Sciences, Beijing, People’s Republic of ChinaCorrespondence[email protected]
View further author information
,
Pei Lengc Key Laboratory of Agricultural Remote Sensing, Ministry of Agriculture//Institute of Agricultural Resources and Regional Planning, Chinese Academy of Agricultural Sciences, Beijing, People’s Republic of ChinaView further author information
,
Fang-Cheng Zhoud National Satellite Meteorological Centre, China Meteorological Administration, Beijing, People’s Republic of ChinaView further author information
,
Liang Gaoa College of Resources and Environment, University of Chinese Academy of Sciences, Beijing, People’s Republic of ChinaView further author information
&
Da Guoa College of Resources and Environment, University of Chinese Academy of Sciences, Beijing, People’s Republic of ChinaView further author information
Pages 296-322 | Received 28 Jul 2021, Accepted 21 Oct 2021, Published online: 04 Feb 2022

References

  • Aires, F., C. Prigent, W. B. Rossow, and M. Rothstein. 2001. “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.” Journal of Geophysical Research: Atmospheres 106 (D14): 14887–14907.
  • Anderson, M. C., J. M. Norman, W. P. Kustas, R. Houborg, P. J. Starks, and N. Agam. 2008. “A Thermal-Based Remote Sensing Technique for Routine Mapping of Land-Surface Carbon, Water and Energy Fluxes from Field to Regional Scales.” Remote Sensing of Environment 112 (12): 4227–4241.
  • Barsi, J. A., J. L. Barker, and J. R. Schott. 2003. “An Atmospheric Correction Parameter Calculator for a Single Thermal Band Earth-Sensing Instrument.” In IEEE International Geoscience and Remote Sensing Symposium, 3014–6. Toulouse, France: IEEE.
  • Bengtsson, L., and J. Shukla. 1988. “Integration of Space and in Situ Observations to Study Global Climate Change.” Bulletin of the American Meteorological Society 69 (38): 318–320.
  • Benjamin, T., R. Vincent, H. Mireille, H. Olivier, M. Sebastien, and B. Gilles. 2016. “A Software Tool for Atmospheric Correction and Surface Temperature Estimation of Landsat Infrared Thermal Data.” Remote Sensing 8 (9): 696.
  • Clough, S. A., M. W. Shephard, E. J. Mlawer, J. S. Delamere, M. J. Iacono, and K. Cady-Pereira. 2005. “Atmospheric Radiative Transfer Modeling: A Summary of the AER Codes.” Journal of Quantitative Spectroscopy and Radiative Transfer 91 (2): 233–244.
  • Coll, C., V. Caselles, E. Valor, and R. Niclòs. 2012. “Comparison Between Different Sources of Atmospheric Profiles for Land Surface Temperature Retrieval from Single Channel Thermal Infrared Data.” Remote Sensing of Environment 117: 199–210.
  • Davis, D. T., Z. Chen, J. N. Hwang, L. Tsang, and E. G. Njoku. 1995. “Solving Inverse Problems by Bayesian Iterative Inversion of a Forward Model with Applications to Parameter Mapping Using SMMR Remote Sensing Data.” IEEE Transactions on Geoscience and Remote Sensing 33: 1182–1193.
  • Dee, D. P., S. M. Uppala, A. J. Simmons, P. Berrisford, P. Poli, S. Kobayashi, U. Andrae, et al. 2011. “The ERA-Interim Reanalysis: Configuration and Performance of the Data Assimilation System.” Quarterly Journal of the Royal Meteorological Society 137 (656): 553–597.
  • Duan, S. B., X. J. Han, C. Huang, Z. L. Li, H. Wu, Y. Qian, M. Gao, and P. Leng. 2020. “Land Surface Temperature Retrieval from Passive Microwave Satellite Observations: State-of-the-art and Future Directions.” Remote Sensing 12 (16): 2573.
  • Duan, S. B., Z. L. Li, and P. Leng. 2017. “A Framework for the Retrieval of All-Weather Land Surface Temperature at a High Spatial Resolution from Polar-Orbiting Thermal Infrared and Passive Microwave Data.” Remote Sensing of Environment 195: 107–117.
  • Ermida, S. L., C. Jiménez, C. Prigent, I. F. Trigo, and C. C. DaCamara. 2017. “Inversion of AMSR-E Observations for Land Surface Temperature Estimation: 2. Global Comparison with Infrared Satellite Temperature.” Journal of Geophysical Research: Atmospheres 122: 3348–3360.
  • Fily, M., A. Royer, K. Goı̈ta, and C. Prigent. 2003. “A Simple Retrieval Method for Land Surface Temperature and Fraction of Water Surface Determination from Satellite Microwave Brightness Temperatures in sub-Arctic Areas.” Remote Sensing of Environment 85 (3): 328–338.
  • Han, X. J., S. B. Duan, C. Huang, and Z. L. Li. 2018. “Cloudy Land Surface Temperature Retrieval from Three-Channel Microwave Data.” International Journal of Remote Sensing 40 (2): 1–15.
  • Han, X. J., S. B. Duan, and Z. L. Li. 2017. “Atmospheric Correction for Retrieving Ground Brightness Temperature at Commonly-Used Passive Microwave Frequencies.” Optics Express 25: A36–A57.
  • Hersbach, H., B. Bell, P. Berrisford, S. Hirahara, A. Horányi, J. Muñoz-Sabater, J. Nicolas, et al. 2020. “The ERA5 Global Reanalysis.” Quarterly Journal of the Royal Meteorological Society 146: 1999–2049.
  • Hillebrand, F. L., U. F. Bremer, J. Arigony-Neto, C. da Rosa, C. W. Mendes, J. Costi, M. W. de Freitas, and F. Schardong. 2021. “Comparison Between Atmospheric Reanalysis Models ERA5 and ERA-Interim at the North Antarctic Peninsula Region.” Annals of the American Association of Geographers 111 (4): 1147–1159.
  • Huang, C., S. B. Duan, X. G. Jiang, X. J. Han, P. Leng, M. F. Gao, and Z. L. Li. 2019. “A Physically Based Algorithm for Retrieving Land Surface Temperature Under Cloudy Conditions from AMSR2 Passive Microwave Measurements.” International Journal of Remote Sensing 40 (5-6): 1828–1843.
  • Imaoka, K., M. Kachi, M. Kasahara, N. Ito, and T. Oki. 2010. “Instrument Performance and Calibration of AMSR-E and AMSR2.” International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences - ISPRS Archives 38: 13–16.
  • Jia, A. L., H. Ma, S. L. Liang, and D. D. Wang. 2021. “Cloudy-sky Land Surface Temperature from Viirs and Modis Satellite Data Using a Surface Energy Balance-Based Method.” Remote Sensing of Environment 263 (4): 112566.
  • Jorge, R., H. Rasmus, and F. M. Matthew. 2017. “Sensitivity of Landsat 8 Surface Temperature Estimates to Atmospheric Profile Data: A Study Using MODTRAN in Dryland Irrigated Systems.” Remote Sensing 9: 988.
  • Karnieli, A., N. Agam, R. T. Pinker, M. Anderson, M. L. Imhoff, G. G. Gutman, N. Panov, and A. Goldberg. 2010. “Use of NDVI and Land Surface Temperature for Drought Assessment: Merits and Limitations.” Journal of Climate 23 (3): 618–633.
  • Kobayashi, S., Y. Ota, Y. Harada, A. Ebita, M. Moriya, H. Onoda, K. Onogi, et al. 2015. “The JRA-55 Reanalysis: General Specifications and Basic Characteristics.” Journal of the Meteorological Society of Japan 93 (1): 5–48.
  • Kustas, W., and M. Anderson. 2009. “Advances in Thermal Infrared Remote Sensing for Land Surface Modeling.” Agricultural and Forest Meteorology 149 (12): 2071–2081.
  • Li, H., Q. Liu, Y. Du, J. Jiang, and H. Wang. 2013a. “Evaluation of the NCEP and MODIS Atmospheric Products for Single Channel Land Surface Temperature Retrieval with Ground Measurements: A Case Study of HJ-1B IRS Data.” IEEE Journal of Selected Topics in Applied Earth Observations & Remote Sensing 6 (3): 1399–1408.
  • Li, Z. L., B. H. Tang, H. Wu, H. Z. Ren, G. J. Yan, Z. M. Wan, I. F. Trigo, and J. A. Sobrino. 2013b. “Satellite-Derived Land Surface Temperature: Current Status and Perspectives.” Remote Sensing of Environment 131: 14–37.
  • Lima, J., and C. R. Alcntara. 2019. “Comparison Between ERA Interim/ECMWF, CFSR, NCEP/NCAR Reanalysis, and Observational Datasets Over the Eastern Part of the Brazilian Northeast Region.” Theoretical and Applied Climatology 138 (1): 2021–2041.
  • Liu, Z. L., H. Wu, B. H. Tang, S. Qiu, and Z. L. Li. 2013. “Atmospheric Corrections of Passive Microwave Data for Estimating Land Surface Temperature.” Optics Express 21 (13): 15654–15663.
  • Ma, L., T. Zhang, Q. Li, O. W. Frauenfeld, and D. Qin. 2008. “Evaluation of ERA-40, NCEP-1, and NCEP-2 Reanalysis Air Temperatures with Ground-Based Measurements in China.” Journal of Geophysical Research: Atmospheres 113: D15115.
  • Maeda, T., Y. Taniguchi, and K. Imaoka. 2016. “GCOM-W1 AMSR2 Level 1R Product: Dataset of Brightness Temperature Modified Using the Antenna Pattern Matching Technique.” IEEE Transactions on Geoscience and Remote Sensing 54 (2): 770–782.
  • Matzlar, C. 1994. “Passive Microwave Signatures of Landscapes in Winter.” Meteorology & Atmospheric Physics 54 (1-4): 241–260.
  • Meng, X. C., and J. Cheng. 2018. “Evaluating Eight Global Reanalysis Products for Atmospheric Correction of Thermal Infrared Sensor—Application to Landsat 8 TIRS10 Data.” Remote Sensing 10 (3): 474.
  • Molod, A., L. Takacs, M. Suarez, and J. Bacmeister. 2014. “Development of the GEOS-5 Atmospheric General Circulation Model: Evolution from MERRA to MERRA2.” Geoscientific Model Development Discussions 7 (6): 1339–1356.
  • Owe, M., and A. Van De Griend. 2001. “On the Relationship Between Thermodynamic Surface Temperature and High-Frequency (37 GHz) Vertically Polarized Brightness Temperature Under Semi-Arid Conditions.” International Journal of Remote Sensing 22 (17): 3521–3532.
  • Pérez-Planells, L., V. García-Santos, and V. Caselles. 2015. “Comparing Different Profiles to Characterize the Atmosphere for Three MODIS TIR Bands.” Atmospheric Research 161-162: 108–115.
  • Qiu, Y. B., J. C. Shi, L. Jiang, and K. B. Mao. 2007. “Study of Atmospheric Effects on AMSR-E Microwave Brightness Temperature over Tibetan Plateau.” In IEEE Conference on Geoscience and Remote Sensing, 1873–1876.
  • Rienecker, M. M., M. J. Suarez, R. Gelaro, R. Todling, J. Bacmeister, E. Liu, M. G. Bosilovich, et al. 2011. “MERRA: NASA's Modern-Era Retrospective Analysis for Research and Applications.” Journal of Climate 24 (14): 3624–3648.
  • Rosas, J., R. Houborg, and A. Mccabe. 2017. “Sensitivity of Landsat 8 Surface Temperature Estimates to Atmospheric Profile Data: A Study Using MODTRAN in Dryland Irrigated Systems.” Remote Sensing 2017 (10): 988.
  • Savoie, M. H., R. L. Armstrong, M. J. Brodzik, and J. R. Wang. 2009. “Atmospheric Corrections for Improved Satellite Passive Microwave Snow Cover Retrievals Over the Tibet Plateau.” Remote Sensing of Environment 113 (12): 2661–2669.
  • Sharifnezhad, Z., H. Norouzi, S. Prakash, R. Blake, and R. Khanbilvardi. 2021. “Diurnal Cycle of Passive Microwave Brightness Temperature Over Land at a Global Scale.” Remote Sensing 13 (4): 1–14.
  • Shwetha, H. R., and D. Nagesh Kumar. 2015. “Prediction of Land Surface Temperature Under Cloudy Conditions Using Microwave Remote Sensing and ANN.” Aquatic Procedia 4: 1381–1388.
  • Simmons, A. J., S. M. Uppala, D. P. Dee, and S. Kobayashi. 2007. “ERAInterim: New ECMWF Reanalysis Products from 1989 Onwards.” ECMWF Newsletter 10: 25–35.
  • Tedesco, M., and J. R. Wang. 2006. “Atmospheric Correction of AMSR-E Brightness Temperatures for Dry Snow Cover Mapping.” IEEE Geoscience & Remote Sensing Letters 3 (3): 320–324.
  • Trenberth, K. E., and J. G. Olson. 1988. “An Evaluation and Intercomparison of Global Analyses from the National Meteorological Center and the European Centre for Medium Range Weather Forecasts.” Bulletin of the American Meteorological Society 69 (9): 1047–1057.
  • Ulaby, F. T., R. K. Moore, and A. K. Fung. 1986. Microwave Remote Sensing: Active and Passive. Vol. 3, from Theory to Applications. Norwood, UK: Artech House.
  • Wang, A. H., and X. B. Zeng. 2012. “Evaluation of Multireanalysis Products with in Situ Observations Over the Tibetan Plateau.” Journal of Geophysical Research: Atmospheres 117 (D5): 5102.
  • Weng, F. Z., and N. C. Grody. 1998. “Physical Retrieval of Land Surface Temperature Using the Special Sensor Microwave Imager.” Journal of Geophysical Research: Atmospheres 103 (D8): 8839–8848.
  • Yang, J. J., S. B. Duan, X. Y. Zhang, P. H. Wu, C. Huang, P. Leng, and M. F. Gao. 2020. “Evaluation of Seven Atmospheric Profiles from Reanalysis and Satellite-Derived Products: Implication for Single-Channel Land Surface Temperature Retrieval.” Remote Sensing 12 (5): 791.
  • Zhang, Q., and J. Cheng. 2019. “An Empirical Algorithm for Retrieving Land Surface Temperature from AMSR-E Data Considering the Comprehensive Effects of Environmental Variables.” Earth and Space Science 7 (4): 1–26.
  • Zhang, R. H., J. Tian, H. B. Su, X. M. Sun, S. H. Chen, and J. Xia. 2008. “Two Improvements of an Operational Two-Layer Model for Terrestrial Surface Heat Flux Retrieval.” Sensors 8 (10): 6165–6187.
  • Zhu, X. M., X. N. Song, P. Leng, D. Guo, and S. H. Cai. 2020. “Impact of Atmospheric Correction on Spatial Heterogeneity Relations Between Land Surface Temperature and Biophysical Compositions.” IEEE Transactions on Geoscience and Remote Sensing 59 (3): 2680–2697.
  • Zhu, X. M., X. N. Song, P. Leng, X. T. Li, L. Gao, D. Guo, and S. H. Cai. 2021. “A Framework for Generating High Spatiotemporal Resolution Land Surface Temperature in Heterogeneous Areas.” Remote Sensing 13 (19): 3885.
  • Zhu, X. M., X. H. Wang, D. J. Yan, Z. Liu, and Y. F. Zhou. 2019. “Analysis of Remotely-Sensed Ecological Indexes’ Influence on Urban Thermal Environment Dynamic Using an Integrated Ecological Index: A Case Study of Xi'an, China.” International Journal of Remote Sensing 40 (9-10): 3421–3447.
  • Zia ul Rehman, T., A. Muhammad, A. Muhammad, H. Nasir, S. Hamza, and A. Hasnain. 2018. “Evaluation of NCEP-Products (NCEP-NCAR, NCEP-DOE, NCEP-FNL, NCEP-GFS) of Solar Radiation for Karachi, Pakistan.” In 12th International Conference on Solar Energy for Buildings and Industry, 1–12.

Related research

People also read lists articles that other readers of this article have read.

Recommended articles lists articles that we recommend and is powered by our AI driven recommendation engine.

Cited by lists all citing articles based on Crossref citations.
Articles with the Crossref icon will open in a new tab.