Stability maps using historical NDVI images on durum wheat to understand the causes of spatial variability

IF 5.4 2区农林科学 Q1 AGRICULTURE, MULTIDISCIPLINARY

Precision Agriculture Pub Date : 2025-01-28 DOI:10.1007/s11119-025-10222-8

E. Romano, F. Fania, I. Pecorella, P. Spadanuda, M. Roncetti, D. Zullo, G. Giuntoli, C. Bisaglia, A. Bragaglio, S. Bergonzoli, P. De Vita

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引用次数: 0

Abstract

Durum wheat (Triticum durum Desf.) yield should be maximized to meet the growing global demand for pasta production. Precision agriculture (PA) could play a pivotal role in reaching this goal by correctly defining management zones (MZ) and optimizing the use of energy inputs. The aim of the work was to understand the relationship between MZ generated from observed yield data and those generated using a time series of Sentinel-derived vegetation indices (i.e. NDVI) obtained from satellite images and soil properties. For this purpose, two field trials of 10 ha each, cultivated with durum wheat, were carried out in Southern Italy. The results suggested a better strategy for defining MZs by merging soil characteristics and temporal NDVI stability maps. The on-the-go technology used for soil resistivity mapping also represented an excellent tool for delineating stable and homogeneous areas within the fields and estimating soil properties. In particular, the soil clay content had a determining effect on the identification of homogeneous yield areas. However, the integration of historical NDVI data helped delineate MZs within each field. To validate this hypothesis, we integrated soil and NDVI data into a linear predictive model to predict grain yield at the field level. Our findings showed a good level of accuracy and a significant improvement in yield simulated values by combining soil with crop data (R² = 0.620; RMSE = 0.425). Further studies are needed to explore the potential of NDVI stability maps into a linear predictive model to predict grain yield at the field level.

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利用硬粒小麦历史NDVI图像绘制稳定性图，了解其空间变异的原因

应最大限度地提高硬粒小麦（Triticum Durum Desf.）的产量，以满足全球对面食生产日益增长的需求。精准农业（PA）可以通过正确界定管理区域（MZ）和优化能源投入的利用，在实现这一目标方面发挥关键作用。这项工作的目的是了解由观测到的产量数据产生的MZ与利用sentinel衍生的植被指数（即NDVI）时间序列从卫星图像和土壤性质获得的MZ之间的关系。为此目的，在意大利南部进行了两次田间试验，每次10公顷，种植硬粒小麦。结果表明，将土壤特征与NDVI时序稳定性图相结合可以更好地定义MZs。用于土壤电阻率测绘的即时技术也代表了圈定田地内稳定和均匀区域以及估计土壤性质的优秀工具。其中，土壤粘粒含量对均匀产量区的识别具有决定性作用。然而，整合历史NDVI数据有助于在每个油田内划定mz。为了验证这一假设，我们将土壤和NDVI数据整合到一个线性预测模型中，以预测田间水平的粮食产量。我们的研究结果表明，将土壤与作物数据结合起来，产量模拟值具有良好的准确性和显着提高(R2 = 0.620；rmse = 0.425)。NDVI稳定性图的线性预测模型在田间产量预测方面的潜力有待进一步研究。

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

Precision Agriculture 农林科学-农业综合

CiteScore

12.30

自引率

8.10%

发文量

103

审稿时长

>24 weeks

期刊介绍： Precision Agriculture promotes the most innovative results coming from the research in the field of precision agriculture. It provides an effective forum for disseminating original and fundamental research and experience in the rapidly advancing area of precision farming. There are many topics in the field of precision agriculture; therefore, the topics that are addressed include, but are not limited to: Natural Resources Variability: Soil and landscape variability, digital elevation models, soil mapping, geostatistics, geographic information systems, microclimate, weather forecasting, remote sensing, management units, scale, etc. Managing Variability: Sampling techniques, site-specific nutrient and crop protection chemical recommendation, crop quality, tillage, seed density, seed variety, yield mapping, remote sensing, record keeping systems, data interpretation and use, crops (corn, wheat, sugar beets, potatoes, peanut, cotton, vegetables, etc.), management scale, etc. Engineering Technology: Computers, positioning systems, DGPS, machinery, tillage, planting, nutrient and crop protection implements, manure, irrigation, fertigation, yield monitor and mapping, soil physical and chemical characteristic sensors, weed/pest mapping, etc. Profitability: MEY, net returns, BMPs, optimum recommendations, crop quality, technology cost, sustainability, social impacts, marketing, cooperatives, farm scale, crop type, etc. Environment: Nutrient, crop protection chemicals, sediments, leaching, runoff, practices, field, watershed, on/off farm, artificial drainage, ground water, surface water, etc. Technology Transfer: Skill needs, education, training, outreach, methods, surveys, agri-business, producers, distance education, Internet, simulations models, decision support systems, expert systems, on-farm experimentation, partnerships, quality of rural life, etc.