Estimation of Leaf Nitrogen Content in Wheat Based on Fusion of Spectral Features and Deep Features from Near Infrared Hyperspectral Imagery

Estimation of Leaf Nitrogen Content in Wheat Based on Fusion of Spectral Features and Deep Features from Near Infrared Hyperspectral Imagery

Nitrogen is an important indicator for monitoring wheat growth. The rapid development and wide application of non-destructive detection provide many approaches for estimating leaf nitrogen content (LNC) in wheat. Previous studies have shown that better results have been obtained in the estimation of...

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Veröffentlicht in:Sensors (Basel, Switzerland) Switzerland), 2021-01, Vol.21 (2), p.613
Hauptverfasser: Yang, Baohua, Ma, Jifeng, Yao, Xia, Cao, Weixing, Zhu, Yan
Format: Artikel
Sprache:eng
Schlagworte:
Accuracy
Agricultural production
Artificial intelligence
convolutional neural network
deep features
Deep learning
Discriminant analysis
Fertilizers
Hyperspectral imaging
Infrared imagery
leaf nitrogen content
Least-Squares Analysis
Model accuracy
Monitoring
Nitrogen
Nutrition
Physiology
Plant Leaves
Principal components analysis
Software
Spectra
spectral features
Spectrum Analysis
Support vector machines
Technical services
Triticum
Vegetation
Wavelet transforms
Wheat
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creator Yang, Baohua
Ma, Jifeng
Yao, Xia
Cao, Weixing
Zhu, Yan
description Nitrogen is an important indicator for monitoring wheat growth. The rapid development and wide application of non-destructive detection provide many approaches for estimating leaf nitrogen content (LNC) in wheat. Previous studies have shown that better results have been obtained in the estimation of LNC in wheat based on spectral features. However, the lack of automatically extracted features leads to poor universality of the estimation model. Therefore, a feature fusion method for estimating LNC in wheat by combining spectral features with deep features (spatial features) was proposed. The deep features were automatically obtained with a convolutional neural network model based on the PyTorch framework. The spectral features were obtained using spectral information including position features (PFs) and vegetation indices (VIs). Different models based on feature combination for evaluating LNC in wheat were constructed: partial least squares regression (PLS), gradient boosting decision tree (GBDT), and support vector regression (SVR). The results indicate that the model based on the fusion feature from near-ground hyperspectral imagery has good estimation effect. In particular, the estimation accuracy of the GBDT model is the best (R = 0.975 for calibration set, R = 0.861 for validation set). These findings demonstrate that the approach proposed in this study improved the estimation performance of LNC in wheat, which could provide technical support in wheat growth monitoring.
doi_str_mv 10.3390/s21020613
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The results indicate that the model based on the fusion feature from near-ground hyperspectral imagery has good estimation effect. In particular, the estimation accuracy of the GBDT model is the best (R = 0.975 for calibration set, R = 0.861 for validation set). 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The rapid development and wide application of non-destructive detection provide many approaches for estimating leaf nitrogen content (LNC) in wheat. Previous studies have shown that better results have been obtained in the estimation of LNC in wheat based on spectral features. However, the lack of automatically extracted features leads to poor universality of the estimation model. Therefore, a feature fusion method for estimating LNC in wheat by combining spectral features with deep features (spatial features) was proposed. The deep features were automatically obtained with a convolutional neural network model based on the PyTorch framework. The spectral features were obtained using spectral information including position features (PFs) and vegetation indices (VIs). Different models based on feature combination for evaluating LNC in wheat were constructed: partial least squares regression (PLS), gradient boosting decision tree (GBDT), and support vector regression (SVR). The results indicate that the model based on the fusion feature from near-ground hyperspectral imagery has good estimation effect. In particular, the estimation accuracy of the GBDT model is the best (R = 0.975 for calibration set, R = 0.861 for validation set). These findings demonstrate that the approach proposed in this study improved the estimation performance of LNC in wheat, which could provide technical support in wheat growth monitoring.</abstract><cop>Switzerland</cop><pub>MDPI AG</pub><pmid>33477350</pmid><doi>10.3390/s21020613</doi><orcidid>https://orcid.org/0000-0002-1884-2404</orcidid><orcidid>https://orcid.org/0000-0002-1967-8845</orcidid><oa>free_for_read</oa></addata></record>
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subjects Accuracy
Agricultural production
Artificial intelligence
convolutional neural network
deep features
Deep learning
Discriminant analysis
Fertilizers
Hyperspectral imaging
Infrared imagery
leaf nitrogen content
Least-Squares Analysis
Model accuracy
Monitoring
Nitrogen
Nutrition
Physiology
Plant Leaves
Principal components analysis
Software
Spectra
spectral features
Spectrum Analysis
Support vector machines
Technical services
Triticum
Vegetation
Wavelet transforms
Wheat
title Estimation of Leaf Nitrogen Content in Wheat Based on Fusion of Spectral Features and Deep Features from Near Infrared Hyperspectral Imagery
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