Yu Shuan, Fan Jiangchuan, Lu Xianju, Wen Weiliang, Shao Song, Guo Xinyu, Zhao Chunjiang
National Engineering Research Center for Agro-Ecological Big Data Analysis and Application, Anhui University, Hefei, China.
Beijing Key Laboratory of Digital Plant, China National Engineering Research Center for Information Technology in Agriculture, Beijing, China.
Front Plant Sci. 2022 Jun 30;13:927832. doi: 10.3389/fpls.2022.927832. eCollection 2022.
The currently available methods for evaluating most biochemical traits of plant phenotyping are destructive and have extremely low throughput. However, hyperspectral techniques can non-destructively obtain the spectral reflectance characteristics of plants, which can provide abundant biophysical and biochemical information. Therefore, plant spectra combined with machine learning algorithms can be used to predict plant phenotyping traits. However, the raw spectral reflectance characteristics contain noise and redundant information, thus can easily affect the robustness of the models developed multivariate analysis methods. In this study, two end-to-end deep learning models were developed based on 2D convolutional neural networks (2DCNN) and fully connected neural networks (FCNN; Deep2D and DeepFC, respectively) to rapidly and non-destructively predict the phenotyping traits of lettuces from spectral reflectance. Three linear and two nonlinear multivariate analysis methods were used to develop models to weigh the performance of the deep learning models. The models based on multivariate analysis methods require a series of manual feature extractions, such as pretreatment and wavelength selection, while the proposed models can automatically extract the features in relation to phenotyping traits. A visible near-infrared hyperspectral camera was used to image lettuce plants growing in the field, and the spectra extracted from the images were used to train the network. The proposed models achieved good performance with a determination coefficient of prediction ( ) of 0.9030 and 0.8490 using Deep2D for soluble solids content and DeepFC for pH, respectively. The performance of the deep learning models was compared with five multivariate analysis method. The quantitative analysis showed that the deep learning models had higher than all the multivariate analysis methods, indicating better performance. Also, wavelength selection and different pretreatment methods had different effects on different multivariate analysis methods, and the selection of appropriate multivariate analysis methods and pretreatment methods increased more time and computational cost. Unlike multivariate analysis methods, the proposed deep learning models did not require any pretreatment or dimensionality reduction and thus are more suitable for application in high-throughput plant phenotyping platforms. These results indicate that the deep learning models can better predict phenotyping traits of plants using spectral reflectance.
目前用于评估植物表型分析中大多数生化特性的方法具有破坏性且通量极低。然而,高光谱技术可以无损获取植物的光谱反射特征,这能够提供丰富的生物物理和生化信息。因此,结合机器学习算法的植物光谱可用于预测植物表型特征。然而,原始光谱反射特征包含噪声和冗余信息,因此很容易影响基于多元分析方法所开发模型的稳健性。在本研究中,基于二维卷积神经网络(2DCNN)和全连接神经网络(FCNN,分别为Deep2D和DeepFC)开发了两个端到端深度学习模型,以从光谱反射率中快速无损地预测生菜的表型特征。使用三种线性和两种非线性多元分析方法开发模型,以衡量深度学习模型的性能。基于多元分析方法的模型需要一系列手动特征提取,如预处理和波长选择,而所提出的模型能够自动提取与表型特征相关的特征。使用可见近红外高光谱相机对田间生长的生菜植株进行成像,并将从图像中提取的光谱用于训练网络。所提出的模型表现良好,使用Deep2D预测可溶性固形物含量时的预测决定系数( )为0.9030,使用DeepFC预测pH值时为0.8490。将深度学习模型的性能与五种多元分析方法进行了比较。定量分析表明,深度学习模型的 值高于所有多元分析方法,表明其性能更好。此外,波长选择和不同的预处理方法对不同的多元分析方法有不同影响,选择合适的多元分析方法和预处理方法会增加更多时间和计算成本。与多元分析方法不同,所提出的深度学习模型不需要任何预处理或降维,因此更适合在高通量植物表型分析平台中应用。这些结果表明,深度学习模型能够利用光谱反射率更好地预测植物的表型特征。
