基于卫星作物水分胁迫指数的机器学习方法偏差校正

IF 6.5 1区农林科学 Q1 AGRONOMY

Agricultural Water Management Pub Date : 2025-10-03 DOI:10.1016/j.agwat.2025.109862

Elahe Zoratipour , Shadman Veysi , Amir Soltani Mohammadi , Saeed Boroomand Nasab , Abd Ali Naseri

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引用次数: 0

摘要

作物水分胁迫指数（CWSI）的准确估算对于支持水资源限制地区的灌溉调度至关重要。传统上，CWSI是通过野外冠层温度和气象测量来计算的；然而，这些方法往往受到成本高和空间覆盖稀疏的限制。卫星遥感通过提供对作物水分胁迫的大规模和重复观测，提供了一种实际的替代方案。然而，卫星输入的不确定性，特别是地表温度（LST），会给CWSI计算带来显著偏差。本研究利用伊朗西南部甘蔗田的卫星数据，解决了在CWSI计算中减轻偏差的挑战。为此，在2023年6月至9月期间获得了24张Landsat 8/9卫星图像。与卫星立交桥时间同步，收集甘蔗田18个点的数据，基于Idso方法计算CWSI，作为偏差校正的基准。现场测量包括，冠层温度（Tc）和气象变量（即Tmin， Tmax， RHmin和RHmax）从传感器配备点。利用谷歌earth engine （GEE）平台上的单通道算法（SC）计算地表温度。采用随机森林（Random Forest， RF）、支持向量机（Support Vector machine， SVM）和极端梯度增强（extreme gradient boost, XGBoost）三种不同的机器学习（ML）方法来减轻LST作为卫星数据CWSI主要驱动因素的偏差。结果表明，射频模型在LST偏差校正方面表现得非常好。总体而言，CWSI提高了准确度，R2 = 35 %,nRMSE= 47 %,rMBE= 50 %。该研究强调了ML方法在改进基于卫星图像的CWSI估算方面的有效性，并在计算CWSI以优化干旱地区灌溉管理方面迈出了一大步，支持可持续的水资源利用和粮食安全。

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Bias correction of satellite based crop water stress index using machine learning methods

Accurate estimation of the Crop Water Stress Index (CWSI) is essential for supporting irrigation scheduling in water-limited regions. Traditionally, CWSI has been computed from field-based canopy temperature and meteorological measurements; however, these approaches are often limited by high costs and sparse spatial coverage. Satellite remote sensing offers a practical alternative by providing large-scale and repeated observations of crop water stress. Nevertheless, uncertainties in satellite-derived inputs, particularly land surface temperature (LST), can introduce significant biases in CWSI computations. This study addresses the challenge of mitigating biases in the CWSI computations, utilizing satellite data within sugarcane fields in southwest Iran. For this goal, twenty-four Landsat 8/9 satellite images were acquired (June–September 2023). Concurrent with the satellite overpass times, data from 18 points across the sugarcane fields, were gathered to compute CWSI based on Idso method as a benchmark for bias correction. Field measurement includes, canopy temperature (T_c) and meteorological variables (i.e. T_min, T_max, RH_min, and RH_max) from sensor-equipped points. LST was calculated using the single-channel algorithm (SC) in google earth engine (GEE) platform. Three distinct machine learning (ML) methods, namely Random Forest (RF), Support Vector Machine (SVM), and extreme gradient boosting (XGBoost), were employed to mitigate bias in LST as main driver of CWSI based on satellite data. The results demonstrated that the RF model performed exceptionally well for LST bias correction. Overall, CWSI enhance accuracy, about with R² = 35 %, nRMSE= 47 % and rMBE= 50 %. This research highlights the effectiveness of ML methods in improving CWSI estimates based on satellite imagery and taking a big step towards calculating CWSI for optimizing irrigation management in arid regions, supporting sustainable water use and food security with minimal ground monitoring.

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来源期刊

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.