Classification of Healthy and Frozen Pomegranates Using Hyperspectral Imaging and Deep Learning

IF 3.1 3区 农林科学 Q1 HORTICULTURE Horticulturae Pub Date : 2024-01-01 DOI:10.3390/horticulturae10010043
Ali Mousavi, Raziyeh Pourdarbani, S. Sabzi, Dorrin Sotoudeh, Mehrab Moradzadeh, G. García-Mateos, Shohreh Kasaei, M. Rohban
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Abstract

Pomegranate is a temperature-sensitive fruit during postharvest storage. If exposed to cold temperatures above its freezing point for a long time, it will suffer from cold stress. Failure to pay attention to the symptoms that may occur during storage will result in significant damage. Identifying pomegranates susceptible to cold damage in a timely manner requires considerable skill, time and cost. Therefore, non-destructive and real-time methods offer great benefits for commercial producers. To this end, the purpose of this study is the non-destructive identification of healthy frozen pomegranates. First, healthy pomegranates were collected, and hyperspectral images were acquired using a hyperspectral camera. Then, to ensure that enough frozen pomegranates were collected for model training, all samples were kept in cold storage at 0 °C for two months. They were then transferred to the laboratory and hyperspectral images were taken from all of them again. The dataset consisted of frozen and healthy images of pomegranates in a ratio of 4:6. The data was divided into three categories, training, validation and test, each containing 1/3 of the data. Since there is a class imbalance in the training data, it was necessary to increase the data of the frozen class by the amount of its difference with the healthy class. Deep learning networks with ResNeXt, RegNetX, RegNetY, EfficientNetV2, VisionTransformer and SwinTransformer architectures were used for data analysis. The results showed that the accuracies of all models were above 99%. In addition, the accuracy values of RegNetX and EfficientNetV2 models are close to one, which means that the number of false positives is very small. In general, due to the higher accuracy of EfficientNetV2 model, as well as its relatively high precision and recall compared to other models, the F1 score of this model is also higher than the others with a value of 0.9995.
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利用高光谱成像和深度学习对健康石榴和冷冻石榴进行分类
石榴在采后贮藏期间是一种对温度敏感的水果。如果长时间暴露在冰点以上的低温环境中,石榴就会受到冷胁迫。如果不注意贮藏期间可能出现的症状,就会造成重大损失。及时识别易受冷害的石榴需要大量的技术、时间和成本。因此,非破坏性的实时方法可为商业生产者带来极大的益处。为此,本研究的目的是对健康冷冻石榴进行非破坏性鉴定。首先,采集健康石榴,使用高光谱相机获取高光谱图像。然后,为确保收集到足够的冷冻石榴用于模型训练,将所有样本在 0 °C 的冷库中保存两个月。然后将它们转移到实验室,再次对所有样品拍摄高光谱图像。数据集由冷冻和健康石榴图像组成,比例为 4:6。数据被分为三类:训练、验证和测试,每类包含 1/3 的数据。由于训练数据中存在类别不平衡的情况,因此有必要增加冷冻类别的数据,增加量为其与健康类别的差异量。数据分析使用了具有 ResNeXt、RegNetX、RegNetY、EfficientNetV2、VisionTransformer 和 SwinTransformer 架构的深度学习网络。结果显示,所有模型的准确率都在 99% 以上。此外,RegNetX 和 EfficientNetV2 模型的准确率值接近 1,这意味着误报的数量非常少。总体而言,由于 EfficientNetV2 模型的准确率较高,而且与其他模型相比,其精确度和召回率也相对较高,因此该模型的 F1 分数也高于其他模型,达到 0.9995。
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来源期刊
Horticulturae
Horticulturae HORTICULTURE-
CiteScore
3.50
自引率
19.40%
发文量
998
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