Assessing field scale spatiotemporal heterogeneity in salinity dynamics using aerial data assimilation

IF 5.9 1区 农林科学 Q1 AGRONOMY
Saman Ebrahimi , Mahdis Khorram , Santosh Palmate , Vijaya Chaganti , Girisha Ganjegunte , Saurav Kumar
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Abstract

Soil moisture and salinity shifts within the root zone can significantly alter crop yields. Thus, spatiotemporal dynamics of these parameters are essential for precision crop management. Airborne or spaceborne earth observation methods based on vegetation and soil observations have sometimes been used with limited success to indirectly understand parameters like soil salinity. These datasets lack spatiotemporal resolution to discern field-scale heterogeneities, and estimates’ accuracy is poor. A Metropolis-Hasting Markov Chain-Monte Carlo (MCMC) based method was developed to estimate field-scale soil salinity by assimilating estimated evapotranspiration (ET) data obtained from aerial canopy temperature sensing with ET outputs from a one-dimensional soil-water transport model. By aligning the two estimated ET values, we inferred anticipated soil salinity levels in a mature pecan orchard (28,951 m2). Our results aligned closely with in-situ measurements with a spatial cross-correlation more than 0.86 and highlighted the expected heterogeneities and nonlinearities. This research offers an approach to refine the current state-of-the-art crop models by accounting for field scale heterogeneities using remotely sensed data. This assimilation method will pave the way for a more inclusive agricultural system modeling that can infer critical but hard-to-measure soil properties from easier-to-obtain remotely sensed datasets. Though this paper concentrates on aerial observations, we anticipate similar methods can be used for satellite-based imagery, especially those with high spatial, temporal, and spectral resolutions.
利用航空数据同化技术评估盐度动态的实地时空异质性
根区土壤水分和盐度的变化会显著改变作物产量。因此,这些参数的时空动态对于精确作物管理至关重要。基于植被和土壤观测的机载或空间对地观测方法有时被用于间接了解土壤盐分等参数,但效果有限。这些数据集缺乏时空分辨率,无法辨别田间尺度的异质性,而且估算精度较低。研究人员开发了一种基于 Metropolis-Hasting Markov Chain-Monte Carlo(MCMC)的方法,通过同化从航空冠层温度感应中获得的估算蒸散量(ET)数据和一维土壤水分传输模型的 ET 输出值来估算田间尺度的土壤盐度。通过调整两个估计蒸散发值,我们推断出了一个成熟山核桃果园(28951 平方米)的预期土壤盐度水平。我们的结果与现场测量结果非常吻合,空间交叉相关性超过 0.86,并突出了预期的异质性和非线性。这项研究提供了一种方法,通过利用遥感数据考虑田间尺度的异质性来完善当前最先进的作物模型。这种同化方法将为建立更具包容性的农业系统模型铺平道路,该模型可以从更容易获得的遥感数据集中推断出关键但难以测量的土壤特性。虽然本文主要讨论的是航空观测数据,但我们预计类似的方法也可用于卫星图像,尤其是那些具有高空间、时间和光谱分辨率的图像。
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来源期刊
Agricultural Water Management
Agricultural Water Management 农林科学-农艺学
CiteScore
12.10
自引率
14.90%
发文量
648
审稿时长
4.9 months
期刊介绍: Agricultural Water Management publishes papers of international significance relating to the science, economics, and policy of agricultural water management. In all cases, manuscripts must address implications and provide insight regarding agricultural water management.
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