Enhancing phenotyping efficiency in faba bean breeding: integrating UAV imaging and machine learning

IF 5.4 2区农林科学 Q1 AGRICULTURE, MULTIDISCIPLINARY

Precision Agriculture Pub Date : 2024-03-06 DOI:10.1007/s11119-024-10121-4

Shirin Mohammadi, Anne Kjersti Uhlen, Morten Lillemo, Åshild Ergon, Sahameh Shafiee

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Abstract

Unmanned aerial vehicles (UAVs) equipped with high-resolution imaging sensors have shown great potential for plant phenotyping in agricultural research. This study aimed to explore the potential of UAV-derived red–green–blue (RGB) and multispectral imaging data for estimating classical phenotyping measures such as plant height and predicting yield and chlorophyll content (indicated by SPAD values) in a field trial of 38 faba bean (Vicia faba L.) cultivars grown at four replicates in south-eastern Norway. To predict yield and SPAD values, Support Vector Regression (SVR) and Random Forest (RF) models were utilized. Two feature selection methods, namely the Pearson correlation coefficient (PCC) and sequential forward feature selection (SFS), were applied to identify the most relevant features for prediction. The models incorporated various combinations of multispectral bands, indices, and UAV-based plant height values at four different faba bean development stages. The correlation between manual and UAV-based plant height measurements revealed a strong agreement with a correlation coefficient (R²) of 0.97. The best prediction of SPAD value was achieved at BBCH 50 (flower bud present) with an R² of 0.38 and RMSE of 1.14. For yield prediction, BBCH 60 (first flower open) was identified as the optimal stage, using spectral indices yielding an R² of 0.83 and RMSE of 0.53 tons/ha. This development stage presents an opportunity to implement targeted management practices to enhance yield. The integration of UAVs equipped with RGB and multispectral cameras, along with machine learning algorithms, proved to be an accurate approach for estimating agronomically important traits in faba bean. This methodology offers a practical solution for rapid and efficient high-throughput phenotyping in faba bean breeding programs.

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提高蚕豆育种中的表型分析效率：将无人机成像与机器学习相结合

配备高分辨率成像传感器的无人飞行器（UAV）在农业研究中的植物表型分析方面显示出巨大潜力。本研究旨在探索无人机获得的红-绿-蓝（RGB）和多光谱成像数据在挪威东南部四次重复种植38个蚕豆（Vicia faba L.）栽培品种的田间试验中用于估测植株高度等经典表型测量指标以及预测产量和叶绿素含量（用SPAD值表示）的潜力。为了预测产量和 SPAD 值，采用了支持向量回归（SVR）和随机森林（RF）模型。采用了两种特征选择方法，即皮尔逊相关系数（PCC）和顺序前向特征选择（SFS），以确定与预测最相关的特征。这些模型结合了多光谱波段、指数和无人机在四种不同蚕豆生长阶段的植株高度值。人工植株高度测量值与无人机植株高度测量值之间的相关性很高，相关系数 (R2) 为 0.97。SPAD 值的最佳预测值出现在 BBCH 50（花蕾出现），R2 为 0.38，RMSE 为 1.14。在产量预测方面，BBCH 60（初花开放）被认为是最佳阶段，使用光谱指数得出的 R2 为 0.83，RMSE 为 0.53 吨/公顷。这一发育阶段为实施有针对性的管理措施以提高产量提供了机会。事实证明，将配备 RGB 和多光谱相机的无人机与机器学习算法相结合，是估算蚕豆重要农艺性状的准确方法。该方法为蚕豆育种计划中快速高效的高通量表型分析提供了实用的解决方案。

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.