IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing (Jan 2020)

Retrieving Soil and Vegetation Temperatures From Dual-Angle and Multipixel Satellite Observations

  • Zunjian Bian,
  • Hua Li,
  • Frank M. Gottsche,
  • Ruibo Li,
  • Yongming Du,
  • Huazhong Ren,
  • Biao Cao,
  • Qing Xiao,
  • Qinhuo Liu

DOI
https://doi.org/10.1109/JSTARS.2020.3024190
Journal volume & issue
Vol. 13
pp. 5536 – 5549

Abstract

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Land surface component temperatures (LSCTs), i.e., the temperatures of soil and vegetation, are important parameters in many applications, such as estimating evapotranspiration and monitoring droughts. However, the multiangle algorithm is affected due to different spatial resolution between nadir and oblique views. Therefore, we propose a combined retrieval algorithm that uses dual-angle and multipixel observations together. The sea and land surface temperature radiometer onboard ESA's Sentinel-3 satellite allows for quasi-synchronous dual-angle observations, from which LSCTs can be retrieved using dual-angle and multipixel algorithms. The better performance of the combined algorithm is demonstrated using a sensitivity analysis based on a synthetic dataset. The spatial errors in the oblique view due to different spatial resolution can reach 4.5 K and have a large effect on the multiangle algorithm. The introduction of multipixel information in a window can reduce the effect of such spatial errors, and the retrieval results of LSCTs can be further improved by using multiangle information for a pixel. In the validation, the proposed combined algorithm performed better, with LSCT root mean squared errors of 3.09 K and 1.91 K for soil and vegetation at a grass site, respectively, and corresponding values of 3.71 K and 3.42 K at a sparse forest site, respectively. Considering that the temperature differences between components can reach 20 K, the results confirm that, in addition to a pixel-average LST, the combined retrieval algorithm can provide information on LSCTs. This article demonstrates the potential of utilizing additional information sources for better LSCT results, which makes the presented combined strategy a promising option for deriving large-scale LSCT products.

Keywords