Abstract
(1) Background: Information rich hyperspectral sensing, together with robust image analysis, is providing new research pathways in plant phenotyping. This combination facilitates the acquisition of spectral signatures of individual plant organs as well as providing detailed information about the physiological status of plants. Despite the advances in hyperspectral technology in field-based plant phenotyping, little is known about the characteristic spectral signatures of shaded and sunlit components in wheat canopies. Non-imaging hyperspectral sensors cannot provide spatial information; thus, they are not able to distinguish the spectral reflectance differences between canopy components. On the other hand, the rapid development of high-resolution imaging spectroscopy sensors opens new opportunities to investigate the reflectance spectra of individual plant organs which lead to the understanding of canopy biophysical and chemical characteristics. (2) Method: This study reports the development of a computer vision pipeline to analyze ground-acquired imaging spectrometry with high spatial and spectral resolutions for plant phenotyping. The work focuses on the critical steps in the image analysis pipeline from pre-processing to the classification of hyperspectral images. In this paper, two convolutional neural networks (CNN) are employed to automatically map wheat canopy components in shaded and sunlit regions and to determine their specific spectral signatures. The first method uses pixel vectors of the full spectral features as inputs to the CNN model and the second method integrates the dimension reduction technique known as linear discriminate analysis (LDA) along with the CNN to increase the feature discrimination and improves computational efficiency. (3) Results: The proposed technique alleviates the limitations and lack of separability inherent in existing pre-defined hyperspectral classification methods. It optimizes the use of hyperspectral imaging and ensures that the data provide information about the spectral characteristics of the targeted plant organs, rather than the background. We demonstrated that high-resolution hyperspectral imagery along with the proposed CNN model can be powerful tools for characterizing sunlit and shaded components of wheat canopies in the field. The presented method will provide significant advances in the determination and relevance of spectral properties of shaded and sunlit canopy components under natural light conditions.
Highlights
We introduce an image analysis pipeline along with a 1D-convolutional neural networks (CNN) model to automatically characterize the spectral variation of wheat leaves and spikes in shadowed and non-shadowed regions
The classification accuracy of the proposed methods was compared with conventional classification methods, such as stochastic gradient descent (SGD), and support vector machine (SVM) classifiers
We demonstrated that high-resolution hyperspectral imagery can be used to characterize shaded and sunlit components in wheat canopies
Summary
Hyperspectral imaging (HSI) was a breakthrough for remote sensing applications [1,2,3,4]. It combines imaging and spectroscopy to attain simultaneously and non-invasively both spatial and spectral information and forms a three-dimensional data cube. HSI provides a vast source of information by sampling the reflective portion of the electromagnetic spectrum covering a wide range from the visible region to the short-wave infrared region. These optical datasets, known as hypercubes, comprise two spatial dimensions and one spectral dimension. Each plane of the hypercube is a grayscale image corresponding to Remote Sens.
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