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利用可见-近红外光谱和基于可解释光谱图的改进残差网络模型对马铃薯黑心进行在线检测。

Online inspection of blackheart in potatoes using visible-near infrared spectroscopy and interpretable spectrogram-based modified ResNet modeling.

作者信息

Guo Yalin, Zhang Lina, He Yakai, Lv Chengxu, Liu Yijun, Song Haiyun, Lv Huangzhen, Du Zhilong

机构信息

Chinese Academy of Agricultural Mechanization Sciences Group Co., Ltd., Beijing, China.

Key Laboratory of Agricultural Products Processing Equipment in the Ministry of Agriculture and Rural Affairs, Beijing, China.

出版信息

Front Plant Sci. 2024 Jun 7;15:1403713. doi: 10.3389/fpls.2024.1403713. eCollection 2024.

DOI:10.3389/fpls.2024.1403713
PMID:38911981
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11190306/
Abstract

INTRODUCTION

Blackheart is one of the most common physiological diseases in potatoes during storage. In the initial stage, black spots only occur in tissues near the potato core and cannot be detected from an outward appearance. If not identified and removed in time, the disease will seriously undermine the quality and sale of theentire batch of potatoes. There is an urgent need to develop a method for early detection of blackheart in potatoes.

METHODS

This paper used visible-near infrared (Vis/NIR) spectroscopy to conduct online discriminant analysis on potatoes with varying degrees of blackheart and healthy potatoes to achieve real-time detection. An efficient and lightweight detection model was developed for detecting different degrees of blackheart in potatoes by introducing the depthwise convolution, pointwise convolution, and efficient channel attention modules into the ResNet model. Two discriminative models, the support vector machine (SVM) and the ResNet model were compared with the modified ResNet model.

RESULTS AND DISCUSSION

The prediction accuracy for blackheart and healthy potatoes test sets reached 0.971 using the original spectrum combined with a modified ResNet model. Moreover, the modified ResNet model significantly reduced the number of parameters to 1434052, achieving a substantial 62.71% reduction in model complexity. Meanwhile, its performance was evidenced by a 4.18% improvement in accuracy. The Grad-CAM++ visualizations provided a qualitative assessment of the model's focus across different severity grades of blackheart condition, highlighting the importance of different wavelengths in the analysis. In these visualizations, the most significant features were predominantly found in the 650-750 nm range, with a notable peak near 700 nm. This peak was speculated to be associated with the vibrational activities of the C-H bond, specifically the fourth overtone of the C-H functional group, within the molecular structure of the potato components. This research demonstrated that the modified ResNet model combined with Vis/NIR could assist in the detection of different degrees of black in potatoes.

摘要

引言

黑心是马铃薯贮藏期间最常见的生理病害之一。在初期,黑点仅出现在马铃薯薯心附近的组织中,从外观上无法检测到。如果不及时识别和去除,病害将严重损害整批马铃薯的品质和销售。迫切需要开发一种早期检测马铃薯黑心的方法。

方法

本文利用可见 - 近红外(Vis/NIR)光谱对不同程度黑心的马铃薯和健康马铃薯进行在线判别分析,以实现实时检测。通过将深度卷积、逐点卷积和高效通道注意力模块引入ResNet模型,开发了一种高效轻量级的检测模型,用于检测马铃薯不同程度的黑心。将支持向量机(SVM)和ResNet模型这两种判别模型与改进后的ResNet模型进行了比较。

结果与讨论

使用原始光谱结合改进后的ResNet模型,对黑心和健康马铃薯测试集的预测准确率达到了0.971。此外,改进后的ResNet模型将参数数量显著减少至1434052个,模型复杂度大幅降低了62.71%。同时,其性能体现在准确率提高了4.18%。Grad-CAM++可视化提供了对模型在不同严重程度黑心条件下关注重点的定性评估,突出了不同波长在分析中的重要性。在这些可视化中,最显著的特征主要出现在650 - 750 nm范围内,在700 nm附近有一个明显的峰值。据推测,这个峰值与马铃薯成分分子结构中C - H键的振动活动有关,特别是C - H官能团的第四泛音。本研究表明,改进后的ResNet模型结合Vis/NIR能够辅助检测马铃薯不同程度的黑心。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/0c33/11190306/301664e20023/fpls-15-1403713-g011.jpg
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