基于高光谱图像光谱和纹理特征的黄桃光斑保存时间检测

IF 2.3 4区 化学 Q1 SOCIAL WORK
Bin Li, Ji-ping Zou, Hai Yin, Yan-de Liu, Feng Zhang, Ai-guo Ou-yang
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引用次数: 0

摘要

黄桃很软,容易碰伤;黄桃的瘀伤部位容易滋生细菌和霉菌,因此黄桃的轻度瘀伤储存时间的差异会影响到黄桃的食用和相关产品的安全性。为了准确区分黄桃轻度瘀伤的保存时间,将样本瘀伤区域的光谱与基于灰度共生矩阵(GLCM)提取的纹理特征相结合,并采用深度学习算法进行建模。实验共制备了80个样品,分别在2、8、24和48 h四个时间段获取样品的高光谱图像,并从高光谱图像中提取出擦伤样品的反射光谱数据和纹理特征。首先,分别基于光谱特征、纹理特征和光谱特征与纹理特征相结合(Feature Fusion 1)构建随机森林(RF)和极端梯度增强(XGBoost)模型,Feature Fusion 1下的RF模型识别效果最好,总体准确率为98.33%。为了去除光谱的冗余信息,采用UVE和CARS算法对归一化光谱特征数据进行筛选,然后将纹理特征再次合并(feature Fusion 2),建立RF和XGBoost模型。结果表明,特征融合2 (CARS)下的RF模型是区分黄桃瘀伤后贮藏时间的最佳模型,总体准确率为98.33%。综上所述,本研究表明,光谱特征结合纹理特征可有效提高模型对黄桃瘀伤后贮藏时间的判别能力,也为高光谱成像技术判别果实瘀伤后贮藏时间提供了一定的理论依据。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Detection of the storage time of light bruises in yellow peaches based on spectrum and texture features of hyperspectral image

Yellow peaches are soft, and they bruise easily; the bruised areas of them are prone to breed bacteria and molds, so the consumption and the safety of related products of yellow peaches are affected by the difference in the storage time of light bruises in them. In order to accurately distinguish of the storage time of light bruises in yellow peaches, the spectra of the sample bruised region were combined with texture features extracted based on gray-level co-occurrence matrix (GLCM), and the deep learning algorithm was used for modeling. A total of 80 samples were prepared in the experiment, and the hyperspectral images of them were acquired at four time periods (2, 8, 24, and 48 h), and the reflection spectral data as well as the texture features of the bruised samples were extracted from the hyperspectral images. First, the random forest (RF) and extreme gradient boosting (XGBoost) models were built based on spectral, texture, and spectral features combined with texture features (Feature Fusion 1), respectively, and the best model discrimination was the RF model under Feature Fusion 1, with an overall accuracy of 98.33%. In order to remove the redundant information of spectrum, the UVE and CARS algorithms were used to screen the normalized spectral feature data, and then, the texture features were combined again (Feature Fusion 2), and the RF and XGBoost models were built. The results show that the optimal model for distinguishing the storage time of yellow peaches after bruising is the RF model under Feature Fusion 2 (CARS), with an overall accuracy of 98.33%. In summary, this study shows that spectral features combined with texture features can be used to effectively improve the model's discrimination of storage time after bruising of yellow peaches, and it also provides a certain theoretical basis for hyperspectral imaging technology to discriminate storage time after bruising of fruits.

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来源期刊
Journal of Chemometrics
Journal of Chemometrics 化学-分析化学
CiteScore
5.20
自引率
8.30%
发文量
78
审稿时长
2 months
期刊介绍: The Journal of Chemometrics is devoted to the rapid publication of original scientific papers, reviews and short communications on fundamental and applied aspects of chemometrics. It also provides a forum for the exchange of information on meetings and other news relevant to the growing community of scientists who are interested in chemometrics and its applications. Short, critical review papers are a particularly important feature of the journal, in view of the multidisciplinary readership at which it is aimed.
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