Assessing the spatial-temporal performance of machine learning in predicting grapevine water status from Landsat 8 imagery via block-out and date-out cross-validation

IF 5.9 1区农林科学 Q1 AGRONOMY

Agricultural Water Management Pub Date : 2024-11-26 DOI:10.1016/j.agwat.2024.109163

Eve Laroche-Pinel , Vincenzo Cianciola , Khushwinder Singh , Gaetano A. Vivaldi , Luca Brillante

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引用次数: 0

Abstract

Grapevine production worldwide is adversely impacted by climate change, including limited water availability, low-quality or sudden excess of water, and more frequent, severe, and prolonged heatwaves. As a result, grapevine growers require reliable spatial and temporal information on vine water status to adapt practices. This research evaluates the use of Landsat 8 satellite imagery in conjunction with weather data, and a machine learning algorithm (Gradient Boosting Machine) to predict vine water status in large vineyard blocks. The accuracy of predictions was assessed across both space (mapping) and time (forecast) using block-out and date-out cross-validation techniques. The study was conducted over two consecutive growing seasons on a Vitis vinifera, L. cv. Merlot vineyard in Central California. The ground data included measurements of midday stem water potentials, Ψ_stem and leaf gas exchange (net assimilation, A_N and stomatal conductance, g_s). Data acquisition was performed in twenty-four experimental units on the same day of the satellite overpasses. The results of the study demonstrate that machine learning is accurate in predicting vine water status spatially within the training measurement dates with low errors (NRMSE_Ψstem = 2.7 %, NRMSE_gs = 16.2 %, NRMSE_AN = 11.2 %) and a high degree of accuracy (R² greater than 0.8 in the prediction of all three measurements) as assessed by block-out cross-validation. The temporal forecast, assed via date-out cross-validation, proves to be more challenging, although the addition of ground data at one single spatial location improves the date-out performances and allows the NRMSE to reach 6.8 % for Ψ_stem with R² of 0.90, 53.4 % for g_s with R² of 0.74, and 25.5 % for A_N with R² of 0.78. The findings from this study have important implications for precision viticulture. They provide an assessment of Landsat 8 imagery, coupled with machine learning, as a means for growers to monitor and forecast vine water status at the field scale. The study highlights the importance of the validation method to ensure the proper use and assessment of machine learning models on agriculture data.

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通过分块输出和日期输出交叉验证，评估机器学习在根据大地遥感卫星 8 号图像预测葡萄水分状况方面的时空性能

世界各地的葡萄生产都受到气候变化的不利影响，包括水资源供应有限、水质低劣或突然过量，以及热浪更加频繁、严重和持久。因此，葡萄种植者需要关于葡萄树水分状况的可靠时空信息来调整种植方法。本研究评估了陆地卫星 8 号卫星图像与气象数据以及机器学习算法（梯度提升机）的结合使用情况，以预测大型葡萄园区块的葡萄藤水分状况。利用区块淘汰和日期淘汰交叉验证技术，对预测的准确性进行了跨空间（绘图）和跨时间（预测）评估。这项研究是在加利福尼亚州中部的一个葡萄品种梅洛葡萄园连续两个生长季节进行的。地面数据包括正午茎干水势、Ψ 干和叶片气体交换（净同化、AN 和气孔导度 gs）的测量值。数据采集是在卫星搭载的同一天在 24 个实验单元中进行的。研究结果表明，机器学习能在训练测量日期内准确预测葡萄树的空间水分状况，误差小（NRMSEΨstem = 2.7 %，NRMSEgs = 16.2 %，NRMSEAN = 11.2 %），通过分块交叉验证评估，准确度高（所有三项测量的预测 R2 均大于 0.8）。虽然增加了一个单一空间位置的地面数据改善了日期-输出性能，并使Ψstem 的 NRMSE 达到 6.8%（R2 为 0.90），gs 的 NRMSE 达到 53.4%（R2 为 0.74），AN 的 NRMSE 达到 25.5%（R2 为 0.78），但通过日期-输出交叉验证评估的时间预测证明更具挑战性。这项研究的结果对精准葡萄栽培具有重要意义。研究评估了陆地卫星 8 号图像与机器学习的结合，为种植者在田间监测和预测葡萄树水分状况提供了一种手段。该研究强调了验证方法的重要性，以确保在农业数据上正确使用和评估机器学习模型。

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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.