An Approach to Improve the Spatial Resolution and Accuracy of AMSR2 Passive Microwave Snow Depth Product Using Machine Learning in Northeast China

Snow cover plays a highly critical role in the global water cycle and energy exchange. Accurate snow depth (SD) data are important for research on hydrologic processes, climate change, and natural disaster prediction. However, existing passive microwave (PMW) SD products have high uncertainty in Nor...

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Bibliographic Details
Published in:Remote sensing (Basel, Switzerland) Switzerland), 2022-03, Vol.14 (6), p.1480
Main Authors: Wei, Yanlin, Li, Xiaofeng, Li, Li, Gu, Lingjia, Zheng, Xingming, Jiang, Tao, Li, Xiaojie
Format: Article
Language:English
Subjects:
Accuracy
Algorithms
Climate change
Correlation coefficient
Correlation coefficients
Datasets
downscaling model
Error reduction
Feasibility studies
Ground stations
Hydrologic cycle
Hydrologic research
Hydrology
Influence
Machine learning
Mathematical models
Mountains
Natural disasters
Northeast China
Parameters
passive microwave
Performance enhancement
Radiation
Remote sensing
Root-mean-square errors
Seasons
Snow
Snow cover
Snow depth
Spatial discrimination
Spatial resolution
Water depth
Weather stations
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Summary:Snow cover plays a highly critical role in the global water cycle and energy exchange. Accurate snow depth (SD) data are important for research on hydrologic processes, climate change, and natural disaster prediction. However, existing passive microwave (PMW) SD products have high uncertainty in Northeast China owing to their coarse spatial resolution. Surface environment parameters should also be considered to reduce errors in existing SD products. Otherwise, it is difficult to accurately capture snow spatiotemporal variations, especially in a complex environment (e.g., mountain or forests areas). To improve the inversion accuracy and spatial resolution of existing SD products in Northeast China, a multifactor SD downscaling model was developed by combining PMW SD data from the AMSR2 sensor, optical snow cover extent data, and surface environmental parameters to produce fine scale (500 m × 500 m) and high precision SD data. Validations at 98 ground meteorological stations show that the developed model greatly improved the spatial resolution and inversion accuracy of the raw AMSR2 SD product; its root-mean-square error (RMSE) reduced from 26.15 cm of the raw product to 7.58 cm, and the correlation coefficient (R) increased from 0.39 to 0.53. For other SD products (WESTDC and FY), the multifactor SD downscaling model still has good applicability, it could further improve the performance of the WESTDC and FY SD products in time and space and achieve better inversion accuracy than raw SD products. Furthermore, the proposed model exhibited good agreement with the observed SD data in a field quadrat (3 km × 2 km) within the fine scale, with an error ranging between −2 and 2 cm. Compared with the existing downscaling methods, the proposed model presented the best performance.
ISSN:2072-4292
2072-4292
DOI:10.3390/rs14061480