Assessing kiwifruit quality in storage through machine learning

IF 2.7 3区农林科学 Q3 ENGINEERING, CHEMICAL

Journal of Food Process Engineering Pub Date : 2024-07-07 DOI:10.1111/jfpe.14681

Mohsen Azadbakht, Shaghayegh Hashemi Shabankareh, Ali Kiapey, Abbas Rezaeiasl, Mohammad Javad Mahmoodi, Mohammad Vahedi Torshizi

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Abstract

Today, diets rich in fruits and vegetables are highly recommended since they contribute to health. The high deterioration rate of fruits distinguishes them from other crops. This study aimed to evaluate the effects of various storage conditions on some quality attributes of kiwifruit through machine learning (ML) using support vector machine (SVM) models. Kiwifruits were subjected to quasi-static loading and coated with different coatings, such as grape, date, and mulberry syrups. Then, the coated kiwifruits were stored at humidity levels of 90% and 95% in completely dark and bright environments with a Compact fluorescent lamp (CFL) bulb for 5, 10, and 15 days. Once the storage period had been completed, quality attributes of the kiwifruit, including antioxidant content, phenolic content, total soluble solids (TSS), pH, and firmness were measured. Each test was performed three times. The numerical results were analyzed through an ML approach using an SVM model on MATLAB. To predict the physical properties of kiwifruit using storage conditions and vice versa, it was found that the most accurate SVM model with a linear kernel predicted the weight loss of kiwifruit based on storage conditions, with the coefficient of determination (R²) being 0.54. To predict the biochemical properties using the storage conditions and vice versa, it was found that kiwifruit firmness was most accurately predicted by the SVM model with the Gaussian kernel, with an R² of 0.70. Moreover, humidity and storage duration were modeled by SVMs with linear kernels, calculating the coefficients of determination to be 0.39 and 0.90, respectively. To predict biochemical properties using physical properties and vice versa, it was observed that the weight loss was more accurately predicted by an SVM with a linear kernel, with an R²-value of 0.76. Reliable results were not obtained for further research for the other modeled parameters using an SVM approach.

Practical Applications

It was found that light was most accurately predicted by the linear SVM. Storage conditions revealed SVM (linear kernel) accurately predicting kiwifruit weight loss. Linear and Gaussian SVMs accurately modeled phenolic and antioxidant content, R²-values: 0.73 and 0.34, respectively.

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通过机器学习评估猕猴桃储藏质量

如今，人们强烈推荐多吃水果和蔬菜，因为它们有助于健康。水果的高变质率使其有别于其他作物。本研究旨在利用支持向量机（SVM）模型，通过机器学习（ML）评估各种贮藏条件对猕猴桃某些质量属性的影响。对猕猴桃进行准静态加载，并涂上不同的涂层，如葡萄浆、枣浆和桑椹浆。然后，将涂有涂层的猕猴桃在湿度分别为 90% 和 95% 的完全黑暗和明亮的环境中用紧凑型荧光灯（CFL）灯泡贮藏 5、10 和 15 天。贮藏期结束后，测量猕猴桃的质量属性，包括抗氧化剂含量、酚含量、总可溶性固形物（TSS）、pH 值和硬度。每项测试均进行三次。数值结果通过 MATLAB 上的 SVM 模型以 ML 方法进行分析。通过贮藏条件预测猕猴桃的物理性质，反之亦然，结果发现，采用线性核的 SVM 模型根据贮藏条件预测猕猴桃的重量损失最为准确，其判定系数 (R2) 为 0.54。在使用贮藏条件预测生化特性时，发现使用高斯核的 SVM 模型对猕猴桃硬度的预测最为准确，R2 为 0.70。此外，湿度和贮藏时间也可以用线性核的 SVM 模型来预测，计算出的决定系数分别为 0.39 和 0.90。用物理特性预测生化特性，反之亦然，观察发现，用线性核的 SVM 预测失重更为准确，R2-值为 0.76。在使用 SVM 方法对其他模型参数进行进一步研究时，没有获得可靠的结果。实际应用发现线性 SVM 对光的预测最为准确。贮藏条件显示，SVM（线性核）能准确预测猕猴桃的重量损失。线性和高斯 SVM 准确地模拟了酚和抗氧化剂的含量，R2-值分别为 0.73 和 0.34：分别为 0.73 和 0.34。

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来源期刊

Journal of Food Process Engineering 工程技术-工程：化工

CiteScore

5.70

自引率

10.00%

发文量

259

审稿时长

2 months

期刊介绍： This international research journal focuses on the engineering aspects of post-production handling, storage, processing, packaging, and distribution of food. Read by researchers, food and chemical engineers, and industry experts, this is the only international journal specifically devoted to the engineering aspects of food processing. Co-Editors M. Elena Castell-Perez and Rosana Moreira, both of Texas A&M University, welcome papers covering the best original research on applications of engineering principles and concepts to food and food processes.