4.7 Article

How do different sensors impact IMERG precipitation estimates during hurricane days?

Journal

REMOTE SENSING OF ENVIRONMENT
Volume 259, Issue -, Pages -

Publisher

ELSEVIER SCIENCE INC
DOI: 10.1016/j.rse.2021.112417

Keywords

GPM; IMERG; MRMS; PMW sensors; Hurricane; Precipitation; Satellite precipitation products; Ground radars; Object-based; Morphing; Rainfall; Precipitaiton; Storm; Merged precipitation products; Storm area; Extreme precipitation

Funding

  1. Australian Research Council as part of the Center of Excellence for Climate Extremes [CE170100023]
  2. NASA Weather and Atmospheric Dynamics award [NNH19ZDA001N-ATDM]

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This study evaluated the uncertainties of a merged satellite product by comparing IMERG with a ground-based radar product in the eastern United States during hurricane days. The results showed that IMERG had better agreement with a bias reduction of 75% and 65% in terms of average precipitation intensity and area, respectively.
Ground observation absence in many parts of the world highlights the importance of merged satellite precipitation products. In this study, we aim to evaluate the effect of different sources of data in the uncertainties of a merged satellite product, by comparing the Integrated Multi-satellitE Retrievals for GPM (IMERG) Final product (V06B) with a ground-based radar product, Multi-Radar Multi-Sensor (MRMS), using both pixel-based and object-based approaches. This study is focused on the eastern United States (land-only) during the hurricane days that occurred in 2016?2018. The results showed that IMERG had better agreement in terms of the average precipitation intensity and area with a bias reduction of 75% and 65%, respectively, when the passive microwave (PMW) sensor overpass is matched instantaneously with MRMS compared to temporally averaged MRMS data (MRMS-Averaged). PMW observations tend to show storms with smaller areas in the IMERG Final product in comparison with MRMS, possibly due to the effect of light precipitation not detected properly by PMW sensors. However, by removing the light precipitation (less than 1 mm/h) in the object-based approach, hurricane objects in the IMERG Final product tend to be larger during the PMW observations, which might be related to different viewing angles of sensors contributing to MRMS and IMERG products. Precipitation estimates have smaller areas with higher average intensity during the PMW observations in the IMERG Final product compared to data estimated by Morphed or IR (morph/IR) observations, which is probably related to the effect of morphing technique, leading to homogenization of the varying rainstorm characteristics. In addition, with the longer absence of PMW observations, the quality of morph/IR estimates in IMERG Final product deteriorates with a decreasing correlation coefficient, a growth in precipitation area and a downward trend in average precipitation intensity. Finally, the inter-comparison of PMW sensors showed the priority of imagers over sounders with GMI as the best among imagers and MHS as the best among sounders in terms of correlation and average intensity compared to MRMS; however, SSMIS was the best in capturing the precipitation area.

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