Development of a unified framework of low-rank approximation and deep neural networks for predicting the spatial variability of SSC in `Spania' watermelons using vis/NIR hyperspectral imaging

IF 6.4 1区 农林科学 Q1 AGRONOMY Postharvest Biology and Technology Pub Date : 2024-09-25 DOI:10.1016/j.postharvbio.2024.113222
Jobin Francis , Sony George , Binu M. Devassy , Sudhish N. George
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Abstract

Soluble Solids Content (SSC) is an important quality attribute that represents the internal quality of fruits. Visible and near-infrared (Vis/NIR) combined with chemometric algorithms are now popular methods for non-invasive measurement and visualization of SSC. However, in fruits with a thick rind and a large flesh volume, such as watermelon, SSC is not evenly distributed across the fruit. The variability in SSC across the fruit flesh may have an adverse effect on the accuracy of quality analysis algorithms. Thus, this paper presents an accurate and efficient approach for predicting the spatial variation of SSC in watermelons using a combined framework of low-rank approximation and deep neural networks. Watermelon ‘Spania’ was selected for this study, and hyperspectral images of each watermelon were taken from various views, including the top, bottom, and two lateral views. The low-rank property is employed as a constraint in this approach to eliminate the unwanted variations in the spectral data. The low-rank component of the spectral data, free of unwanted variations, is then fed into a fully connected neural network (FNN) for the prediction of watermelon SSC values. The proposed approach obtained optimal performance in calibration and prediction with RC2=0.982, RMSEP = 0.132, and RP2=0.945, RMSEP = 0.195 respectively. Further, the prediction outcomes of the proposed method were compared with state-of-the-art such as Partial Least Square Regression (PLSR), Support Vector Regression (SVR), Multiple Linear Regression (MLR), Decision Tree (DT), and Random Forest (RF). The overall results showed that combining HSI data with a low-rank and deep neural network framework is an efficient method for accurately predicting SSC in watermelons as well as correctly predicting spatial variability of SSC in individual fruits.
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利用可见光/近红外高光谱成像技术,开发用于预测 "斯帕尼亚 "西瓜 SSC 空间变化的低秩近似和深度神经网络统一框架
可溶性固形物含量(SSC)是代表水果内部质量的重要质量属性。可见光和近红外(可见光/近红外)结合化学计量学算法是目前非侵入式测量和可视化 SSC 的流行方法。然而,在西瓜等果皮厚、果肉体积大的水果中,SSC 在整个水果中的分布并不均匀。果肉中 SSC 的变化可能会对质量分析算法的准确性产生不利影响。因此,本文提出了一种准确、高效的方法,利用低秩近似和深度神经网络的组合框架来预测西瓜 SSC 的空间变化。本研究选择了西瓜 "Spania",并从不同视角(包括顶部、底部和两个侧视图)拍摄了每个西瓜的高光谱图像。这种方法采用低秩属性作为约束,以消除光谱数据中不必要的变化。然后,将光谱数据中没有多余变化的低秩分量输入全连接神经网络(FNN),用于预测西瓜的 SSC 值。所提出的方法在校准和预测方面获得了最佳性能,RC2=0.982,RMSEP=0.132;RP2=0.945,RMSEP=0.195。此外,还将所提方法的预测结果与最先进的方法进行了比较,如部分最小平方回归(PLSR)、支持向量回归(SVR)、多元线性回归(MLR)、决策树(DT)和随机森林(RF)。总体结果表明,将 HSI 数据与低秩深度神经网络框架相结合是准确预测西瓜 SSC 以及正确预测单个果实 SSC 空间变化的有效方法。
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来源期刊
Postharvest Biology and Technology
Postharvest Biology and Technology 农林科学-农艺学
CiteScore
12.00
自引率
11.40%
发文量
309
审稿时长
38 days
期刊介绍: The journal is devoted exclusively to the publication of original papers, review articles and frontiers articles on biological and technological postharvest research. This includes the areas of postharvest storage, treatments and underpinning mechanisms, quality evaluation, packaging, handling and distribution of fresh horticultural crops including fruit, vegetables, flowers and nuts, but excluding grains, seeds and forages. Papers reporting novel insights from fundamental and interdisciplinary research will be particularly encouraged. These disciplines include systems biology, bioinformatics, entomology, plant physiology, plant pathology, (bio)chemistry, engineering, modelling, and technologies for nondestructive testing. Manuscripts on fresh food crops that will be further processed after postharvest storage, or on food processes beyond refrigeration, packaging and minimal processing will not be considered.
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