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基于高光谱图像 RGB 重建的大豆种子分类。

Classification of soybean seeds based on RGB reconstruction of hyperspectral images.

机构信息

College of Electronic Information Engineering, Changchun University of Science and Technology, Changchun, China.

Jilin Engineering Normal University, Changchun, China.

出版信息

PLoS One. 2024 Sep 4;19(9):e0307329. doi: 10.1371/journal.pone.0307329. eCollection 2024.

DOI:10.1371/journal.pone.0307329
PMID:39231155
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11373792/
Abstract

Soyabean is an incredibly significant component of Chinese agricultural product, and categorizing soyabean seeds allows for a better understanding of the features, attributes, and applications of many species of soyabean. This enables farmers to choose appropriate seeds for sowing in order to increase production and quality. As a result, this thesis provides a method for classifying soybean seeds that uses hyperspectral RGB picture reconstruction. Firstly, hyperspectral images of seven varieties of soybean, H1, H2, H3, H4, H5, H6 and H7, were collected by hyperspectral imager, and by using the principle of the three base colours, the R, G and B bands which have more characteristic information are selected to reconstruct the images with different texture and colour characteristics to generate a new dataset for seed segmentation, and finally, a comparison is made with the classification effect of the seven models. The experimental results in ResNet34 show that the classification accuracy of the dataset before and after RGB reconstruction increases from 88.87% to 91.75%, demonstrating that RGB image reconstruction can strengthen image features; ResNet18, ResNet34, ResNet50, ResNet101, CBAM-ResNet34, SENet-ResNet34, and SENet-ResNet34-DCN models have classification accuracies of 72.25%, 91.75%, 89%, 88.48%, 92.28%, 92.80%, and 94.24%, respectively.SENet-ResNet34-DCN achieves the greatest classification accuracy results, with a model loss of roughly 0.3. The proposed SENet-ResNet34-DCN model is the most effective at classifying soybean seeds. By classifying and optimally selecting seed varieties, agricultural production can become more scientific, efficient, and sustainable, resulting in higher returns for farmers and contributing to global food security and sustainable development.

摘要

大豆是中国农产品中非常重要的组成部分,对大豆种子进行分类可以更好地了解许多大豆品种的特征、属性和应用。这使得农民能够选择合适的种子进行播种,以提高产量和质量。因此,本论文提出了一种利用高光谱 RGB 图像重建的大豆种子分类方法。首先,使用高光谱成像仪采集了 H1、H2、H3、H4、H5、H6 和 H7 等七个品种的大豆高光谱图像,根据三基色原理,选择具有更多特征信息的 R、G 和 B 波段,对图像进行重建,生成具有不同纹理和色彩特征的新数据集,用于种子分割,最后与七个模型的分类效果进行比较。在 ResNet34 中的实验结果表明,RGB 重建前后数据集的分类精度从 88.87%提高到 91.75%,表明 RGB 图像重建可以增强图像特征;ResNet18、ResNet34、ResNet50、ResNet101、CBAM-ResNet34、SENet-ResNet34 和 SENet-ResNet34-DCN 模型的分类准确率分别为 72.25%、91.75%、89%、88.48%、92.28%、92.80%和 94.24%,SENet-ResNet34-DCN 模型的分类准确率最高,模型损失约为 0.3。提出的 SENet-ResNet34-DCN 模型在大豆种子分类方面最为有效。通过对种子进行分类和优化选择,可以使农业生产更加科学、高效和可持续,为农民带来更高的回报,为全球粮食安全和可持续发展做出贡献。

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