Abstract

Multispectral images (MSIs) are valuable for precision agriculture due to the extra spectral information acquired compared to natural color RGB (ncRGB) images. In this paper, we thus aim to generate high spatial MSIs through a robust, deep-learning-based reconstruction method using ncRGB images. Using the data from the agronomic research trial for maize and breeding research trial for rice, we first reproduced ncRGB images from MSIs through a rendering model, Model-True to natural color image (Model-TN), which was built using a benchmark hyperspectral image dataset. Subsequently, an MSI reconstruction model, Model-Natural color to Multispectral image (Model-NM), was trained based on prepared ncRGB (ncRGB-Con) images and MSI pairs, ensuring the model can use widely available ncRGB images as input. The integrated loss function of mean relative absolute error (MRAEloss) and spectral information divergence (SIDloss) were most effective during the building of both models, while models using the MRAEloss function were more robust towards variability between growing seasons and species. The reliability of the reconstructed MSIs was demonstrated by high coefficients of determination compared to ground truth values, using the Normalized Difference Vegetation Index (NDVI) as an example. The advantages of using “reconstructed” NDVI over Triangular Greenness Index (TGI), as calculated directly from RGB images, were illustrated by their higher capabilities in differentiating three levels of irrigation treatments on maize plants. This study emphasizes that the performance of MSI reconstruction models could benefit from an optimized loss function and the intermediate step of ncRGB image preparation. The ability of the developed models to reconstruct high-quality MSIs from low-cost ncRGB images will, in particular, promote the application for plant phenotyping in precision agriculture.

Highlights

  • In multispectral images (MSIs), each pixel is composed of reflectance or radiance from multiple discrete wavebands—providing additional spectral information regarding the chemical composition of an object compared to natural color RGB

  • This study developed and validated a novel method for reconstructing MSIs using natural color RGB (ncRGB) images of maize and rice plots captured by unmanned aerial vehicle (UAV)

  • We improved the state-of-theart deep learning structure HSCNN-R by tuning the number of residual blocks inside the architecture for feature extraction and different loss functions to optimize the model convergence

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Summary

Introduction

Monitoring plant growth status during the whole growing season is an important objective targeted by multispectral imaging in both breeding and precision agriculture [1,2]. In multispectral images (MSIs), each pixel is composed of reflectance or radiance from multiple discrete wavebands—providing additional spectral information regarding the chemical composition of an object compared to natural color RGB (ncRGB; red, green, blue). MSIs can be regarded as a subset of hyperspectral images (HSIs) [3]. The broad application of spectral imaging techniques is still restrained due to the higher cost of multi/hyper-spectral sensors and the lower spatial resolution compared to conventional RGB sensors [4,5]. MSI super-resolution through deep learning has become a promising method to recover additional spectral information from RGB images without using more expensive MSI or HSI hardware [6]

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