Estimating plant height, nitrogen uptake and above-ground biomass using UAV multispectral imaging coupled with machine learning in industrial hemp (Cannabis sativa L.)

IF 6.2 1区农林科学 Q1 AGRICULTURAL ENGINEERING

Industrial Crops and Products Pub Date : 2025-10-17 DOI:10.1016/j.indcrop.2025.122130

Anmoldeep Singh , Ravinder Singh , Kulpreet Singh , Yogendra Raj Upadhyaya , Ayush K. Sharma , Zachary Brym , Lakesh K. Sharma , Hardeep Singh

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引用次数: 0

Abstract

Industrial hemp (Cannabis sativa L.) is known for its high fiber production with lower ecological footprint. Nitrogen (N) status and stem biomass (SB) and total above-ground biomass (AGB) of the crop highly influence fiber quantity and quality. Conventional monitoring practices are labour intensive and time consuming. Unmanned Aerial Vehicles (UAVs) with imaging sensors can be a promising tool for mitigating these challenges. This study evaluated the performance of multispectral camera-equipped UAV in predicting key agronomic parameters, i.e., plant height (PH), Leaf Nitrogen Uptake (LNU) and SB and AGB. Field trials were conducted at UF/IFAS West Florida Research and Education Centre, Jay, FL during the years 2021 and 2022 consisting of two cultivars and six N treatments. The PH was estimated through Crop Height Model, yielding an R² of 0.87 at full crop maturity (90 days after planting). Twenty-seven Vegetation Indices (VIs) were extracted and features, including PH and VIs, were selected through Recursive Feature Elimination with adjusted Variance Inflation Factor (VIF<10) to develop machine learning models for the estimation of yield components. The LNU prediction was best with Support Vector Machine model with R², RMSE and nRMSE % value of 0.364, 34.55 kg N ha⁻¹ and 68.48 respectively. Random Forest Regressor predicted the SB and total AGB most accurately with R², RMSE and nRMSE % value of 0.752 and 0.707, 890.70 and 1492.73 kg ha⁻¹, 48.86 and 43.05 respectively. The results demonstrate the potential of UAVs to generate more reliable estimates of PH, SB and total AGB whereas it remained unreliable for LNU.

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利用无人机多光谱成像和机器学习技术估算工业大麻（Cannabis sativa L.）植株高度、氮素吸收和地上生物量

工业大麻（大麻sativa L.）以其高纤维产量和低生态足迹而闻名。氮素(N)状况、茎生物量（SB）和地上总生物量（AGB）对作物纤维的数量和品质影响很大。传统的监测做法是劳动密集型和耗时的。带有成像传感器的无人驾驶飞行器（uav）可能是缓解这些挑战的一个很有前途的工具。本研究评估了配备多光谱相机的无人机在预测关键农艺参数（即株高（PH）、叶片氮吸收（LNU）、SB和AGB）方面的性能。田间试验于2021年和2022年在佛罗里达州杰伊的UF/IFAS西佛罗里达研究和教育中心进行，包括两个品种和6个氮肥处理。通过作物高度模型估算PH值，在作物完全成熟（种植后90天）时，其R2为0.87。提取27个植被指数（VIs），并通过调整方差膨胀因子（VIF<10）递归特征消除（Recursive Feature Elimination）选择PH和VIs等特征，建立机器学习模型，用于估计产量成分。支持向量机模型预测LNU效果最好，R2、RMSE和nRMSE %分别为0.364、34.55 kg N ha−1和68.48。随机森林回归预测SB和总AGB最准确，R2、RMSE和nRMSE %分别为0.752和0.707、890.70和1492.73 kg ha−1、48.86和43.05。结果表明，无人机的潜力产生更可靠的PH， SB和总AGB的估计，而它仍然不可靠的LNU。

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来源期刊

Industrial Crops and Products 农林科学-农业工程

CiteScore

9.50

自引率

8.50%

发文量

1518

审稿时长

43 days

期刊介绍： Industrial Crops and Products is an International Journal publishing academic and industrial research on industrial (defined as non-food/non-feed) crops and products. Papers concern both crop-oriented and bio-based materials from crops-oriented research, and should be of interest to an international audience, hypothesis driven, and where comparisons are made statistics performed.