Regional Model to Predict Sugarcane Yield Using Sentinel-2 Imagery in São Paulo State, Brazil

IF 1.8 3区农林科学 Q2 AGRONOMY Sugar Tech Pub Date : 2024-08-28 DOI:10.1007/s12355-024-01468-z

Rafaella Pironato Amaro, Mathias Christina, Pierre Todoroff, Guerric Le Maire, Peterson Ricardo Fiorio, Ester de Carvalho Pereira, Ana Claudia dos Santos Luciano

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Abstract

Sugarcane yield prediction is an important tool to support the sugar-energy sector. This study aimed to create a regional empirical model, using the random forest algorithm, to predict sugarcane yield in the state of Sao Paulo. For this, we used Sentinel-2 imagery (vegetation indices NDVIRE and CIRE, spectral bands Red-edge and near-infrared arrow), agronomic data (variety and ratoon stage and plant cane), climatic data (temperature, precipitation) and crop water deficit data from three mills. We created two predictive yield model based on three scenarios with different training and testing data: (SI) Scenario I is the regional model considered all data from the three mills, (SII) Scenario II was training similar SI and testing individuals for each mill, (SIII) Scenario III includes regional individual’s models for sugarcane ratoon stage and plant cane. In each case, 70% of the dataset was used for training and 30% for testing. SI gave R² equal to 0.72, while SII R² was between 0.60 and 0.78; the RMSE for SI was 11.7 \({\text{tonha}}^{{ - 1}}\), while for SII from 8.62 to 15.56 \({\text{tonha}}^{{ - 1}}\). The rRMSE was 16.5% for SI and from 12.4 to 21.6%, for SII. SIII showed R² greater than 0.61, and RMSE between 9.6 and 13.5 \(ton {ha}^{-1}\). The CIRE and NDVIRE vegetation indices, crop water deficit and precipitation were the most important variables to estimate sugarcane yield. The model created considering SI and SII showed potential to be applied to different locals using data from three mills.

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利用哨兵-2 图像预测巴西圣保罗州甘蔗产量的区域模型

甘蔗产量预测是支持糖能源行业的重要工具。本研究旨在利用随机森林算法创建一个区域经验模型，以预测圣保罗州的甘蔗产量。为此，我们使用了哨兵-2 图像（植被指数 NDVIRE 和 CIRE、光谱带红边和近红外箭线）、农艺数据（品种、成熟期和植株甘蔗）、气候数据（温度、降水量）以及来自三个工厂的作物缺水数据。我们利用不同的训练和测试数据创建了基于三种情景的两种预测产量模型：（SI）情景 I 是区域模型，考虑了来自三家工厂的所有数据；（SII）情景 II 是训练类似的 SI，并对每家工厂的个体进行测试；（SIII）情景 III 包括甘蔗成熟期和植株甘蔗的区域个体模型。在每种情况下，70% 的数据集用于训练，30% 用于测试。SI 的 R2 等于 0.72，而 SII 的 R2 介于 0.60 和 0.78 之间；SI 的均方根误差为 11.7 \({text{tonha}}^{-1}}/)，而 SII 的均方根误差为 8.62 到 15.56 \({text{tonha}}^{-1}}/)。SI 的 rRMSE 为 16.5%，SII 为 12.4% 至 21.6%。SIII 的 R2 大于 0.61，RMSE 介于 9.6 和 13.5 之间。CIRE 和 NDVIRE 植被指数、作物缺水和降水是估算甘蔗产量最重要的变量。利用三家糖厂的数据，考虑 SI 和 SII 建立的模型显示了应用于不同地区的潜力。

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来源期刊

Sugar Tech AGRONOMY-

CiteScore

3.90

自引率

21.10%

发文量

145

期刊介绍： The journal Sugar Tech is planned with every aim and objectives to provide a high-profile and updated research publications, comments and reviews on the most innovative, original and rigorous development in agriculture technologies for better crop improvement and production of sugar crops (sugarcane, sugar beet, sweet sorghum, Stevia, palm sugar, etc), sugar processing, bioethanol production, bioenergy, value addition and by-products. Inter-disciplinary studies of fundamental problems on the subjects are also given high priority. Thus, in addition to its full length and short papers on original research, the journal also covers regular feature articles, reviews, comments, scientific correspondence, etc.