Deep learning estimation of northern hemisphere soil freeze-thaw dynamics using satellite multi-frequency microwave brightness temperature observations.

IF 2.4 Q3 COMPUTER SCIENCE, INFORMATION SYSTEMS
Frontiers in Big Data Pub Date : 2023-11-17 eCollection Date: 2023-01-01 DOI:10.3389/fdata.2023.1243559
Kellen Donahue, John S Kimball, Jinyang Du, Fredrick Bunt, Andreas Colliander, Mahta Moghaddam, Jesse Johnson, Youngwook Kim, Michael A Rawlins
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Abstract

Satellite microwave sensors are well suited for monitoring landscape freeze-thaw (FT) transitions owing to the strong brightness temperature (TB) or backscatter response to changes in liquid water abundance between predominantly frozen and thawed conditions. The FT retrieval is also a sensitive climate indicator with strong biophysical importance. However, retrieval algorithms can have difficulty distinguishing the FT status of soils from that of overlying features such as snow and vegetation, while variable land conditions can also degrade performance. Here, we applied a deep learning model using a multilayer convolutional neural network driven by AMSR2 and SMAP TB records, and trained on surface (~0-5 cm depth) soil temperature FT observations. Soil FT states were classified for the local morning (6 a.m.) and evening (6 p.m.) conditions corresponding to SMAP descending and ascending orbital overpasses, mapped to a 9 km polar grid spanning a five-year (2016-2020) record and Northern Hemisphere domain. Continuous variable estimates of the probability of frozen or thawed conditions were derived using a model cost function optimized against FT observational training data. Model results derived using combined multi-frequency (1.4, 18.7, 36.5 GHz) TBs produced the highest soil FT accuracy over other models derived using only single sensor or single frequency TB inputs. Moreover, SMAP L-band (1.4 GHz) TBs provided enhanced soil FT information and performance gain over model results derived using only AMSR2 TB inputs. The resulting soil FT classification showed favorable and consistent performance against soil FT observations from ERA5 reanalysis (mean percent accuracy, MPA: 92.7%) and in situ weather stations (MPA: 91.0%). The soil FT accuracy was generally consistent between morning and afternoon predictions and across different land covers and seasons. The model also showed better FT accuracy than ERA5 against regional weather station measurements (91.0% vs. 86.1% MPA). However, model confidence was lower in complex terrain where FT spatial heterogeneity was likely beneath the effective model grain size. Our results provide a high level of precision in mapping soil FT dynamics to improve understanding of complex seasonal transitions and their influence on ecological processes and climate feedbacks, with the potential to inform Earth system model predictions.

基于卫星多频微波亮度温度观测的北半球土壤冻融动态深度学习估计。
卫星微波传感器非常适合监测景观冻融(FT)转变,因为它对主要冻结和解冻条件之间液态水丰度的变化具有强烈的亮度、温度(TB)或反向散射响应。FT检索也是一个敏感的气候指标,具有很强的生物物理重要性。然而,检索算法很难将土壤的FT状态与积雪和植被等上覆特征区分开来,而多变的土地条件也会降低性能。在此,我们采用AMSR2和SMAP TB记录驱动的多层卷积神经网络深度学习模型,并对地表(~0-5 cm)土壤温度FT观测数据进行训练。土壤FT状态被分类为当地早上(上午6点)和晚上(下午6点)的条件,对应于SMAP下降和上升的轨道立交桥,映射到跨越五年(2016-2020)记录和北半球域的9公里极地网格。使用针对FT观测训练数据优化的模型成本函数,推导出冻结或解冻条件概率的连续变量估计。使用组合多频(1.4、18.7、36.5 GHz) TB获得的模型结果比仅使用单一传感器或单频TB输入的其他模型获得的土壤FT精度最高。此外,与仅使用AMSR2 TB输入的模型结果相比,SMAP l波段(1.4 GHz) TB提供了更好的土壤FT信息和性能增益。所得土壤FT分类结果与ERA5再分析结果(平均准确率,MPA: 92.7%)和现场气象站(MPA: 91.0%)的土壤FT分类结果一致。土壤FT的准确性在上午和下午的预测之间以及不同的土地覆盖和季节之间总体上是一致的。该模型对区域气象站测量的FT精度也优于ERA5(91.0%比86.1% MPA)。然而,在复杂地形中,模型置信度较低,在这种地形中,FT的空间异质性可能低于有效模型粒度。我们的研究结果为绘制土壤FT动态提供了高水平的精度,以提高对复杂季节转变及其对生态过程和气候反馈的影响的理解,并有可能为地球系统模型预测提供信息。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
5.20
自引率
3.20%
发文量
122
审稿时长
13 weeks
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