基于高光谱和X-ray CT的苹果水心病无损检测方法

doi:10.12133/j.smartag.SA202507022

Smart Agriculture ›› 2025, Vol. 7 ›› Issue (4): 108-118.doi: 10.12133/j.smartag.SA202507022

• 专题--农产品品质智能感知与分级 • 上一篇

基于高光谱和X-ray CT的苹果水心病无损检测方法

于心圆¹, 王振杰¹, 尤思聪¹^,², 屠康¹, 兰维杰¹, 彭菁¹, 朱丽霞³, 陈涛⁴(), 潘磊庆¹^,²()

^1. 南京农业大学食品科学技术学院，江苏南京 211800，中国
^2. 南京农业大学三亚研究院，海南三亚 572025，中国
^3. 塔里木大学食品科学与工程学院，新疆阿拉尔 843300，中国
^4. 宿迁市产品质量监督检验所，江苏宿迁 223800，中国

收稿日期:2025-07-17 出版日期:2025-07-30
基金项目:
国家自然科学基金(32272389); 海南省自然科学基金(322CXTD523); 中央高校基本科研业务费专项资金项目(KYLH2024009)
作者简介:
于心圆，硕士研究生，研究方向为农产品无损检测。E-mail： yuxinyuan@stu.njau.edu.cn
通信作者:
陈涛，高级工程师，研究方向为食品质量安全与检验检测。E-mail： cxinyu888@163.com；
潘磊庆，博士，教授，研究方向为果蔬无损检测与质量控制。E-mail： pan_leiqing@njau.edu.cn

Non-destructive Detection of Apple Water Core Disease Based on Hyperspectral and X-ray CT Imaging

YU Xinyuan¹, WANG Zhenjie¹, YOU Sicong¹^,², TU Kang¹, LAN Weijie¹, PENG Jing¹, ZHU Lixia³, CHEN Tao⁴(), PAN Leiqing¹^,²()

^1. College of Food Science and Technology, Nanjing Agricultural University, Nanjing 210095, China
^2. Sanya Institute of Nanjing Agricultural University, Sanya 572025, China
^3. College of Food Science and Engineering, Tarim University, Alar 843300, China
^4. Suqian Product Quality Supervision and Inspection Institute, Suqian 223800, China

Received:2025-07-17 Online:2025-07-30
Foundation items:National Natural Science Foundation of China(32272389); Hainan Provincial Natural Science Foundation(322CXTD523); Fundamental Research Funds for the Central Universities(KYLH2024009)
About author:
YU Xinyuan, E-mail: yuxinyuan@stu.njau.edu.cn
Corresponding author:
CHEN Tao, E-mail: cxinyu888@163.com;
PAN Leiqing, E-mail: pan_leiqing@njau.edu.cn

摘要/Abstract

摘要：

【目的/意义】 苹果“冰糖心”又称水心病，是一种常见的果实病害，严重的水心病果会随着储藏时间的增加发生霉变，造成食品安全隐患。为实现不同等级水心病苹果快速无损检测，本研究旨在构建有效的分级与可溶性固形物（Soluble Solids Content, SSC）预测模型。 【方法】 本研究选取了230个富士苹果，其中正常、轻度、中度、重度水心苹果数量分别为113、61、47和9个，分别采集了400~1 000 nm范围的反射光谱和X射线计算机断层成像（X-ray Computed Tomography, X-ray CT）数据，并测定了SSC含量。 【结果和讨论】 SSC随水心程度加剧呈上升趋势，重度水心苹果呈现更高的光谱反射率，X-ray CT扫描成像观察到水心区域的组织体积平均密度高于健康组织，基于三维重建算法实现不同等级水心苹果内部水心组织可视化分布。基于偏最小二乘判别分析（Partial Least Squares Discriminant Analysis, PLSDA）构建的不同水心程度苹果果实分级模型建模集和测试集准确率分别为98.7%和95.9%；构建不同水心程度苹果果实SSC回归模型，校正集决定系数（Correlation Coefficient of Calibration, $R C 2$ ）为0.962，均方根误差（Root Mean Squares Error of Calibration, RMSEC）为0.264，测试集决定系数（Correlation Coefficient of Prediction, $R P 2$ ）为0.879，均方根误差（Root Mean Squares Error of Prediction, RMSEP）为0.435。 【结论】 该研究构建的不同水心程度苹果果实分级模型能够实现苹果不同等级水心病的预测，构建的不同水心程度苹果果实SSC回归模型能够较好地预测苹果果实的SSC，为苹果水心病无损检测和品质评估提供了有效方法。

关键词: 水心病, 高光谱成像技术, X-ray CT成像技术, 可溶性固形物

Abstract:

[Objective] Apple "sugar-glazed core" (also known as watercore) is a common physiological disorder in apple fruits. Apples with watercore possess a distinctive flavor and are highly favored by consumers. However, severely affected apples are prone to mold growth during storage, posing potential food safety risks. Currently, the primary method for detecting sugar-glazed core in apple relies on manual destructive inspection, which is inefficient for large-scale applications and fails to meet the demands of modern automated and intelligent industrial production. To achieve rapid and non-destructive detection of apples with varying watercore severity levels, effective grading and soluble solids content (SSC) prediction models were developed in this study. [Methods] The Xinjiang Aksu Red Fuji apples were used as the research subject. A total of 230 apple samples were selected, comprising 113 normal, 61 mild, 47 moderate, and 9 severe watercore apples. The watercore severity was quantified through image processing of the apples' cross-sectional images. X-ray computed tomography (X-ray CT) data were acquired, and SSC values were measured. A hyperspectral imaging system was used to collect reflectance spectra within the 400~1 000 nm range. After performing black-and-white correction and selecting regions of interest (ROI), the Sample Set Partitioning based on Joint X-Y Distances (SPXY) algorithm was applied to divide the dataset into modeling (training) and prediction sets at a 3:1 ratio. Using the iToolbox in MATLAB, discriminant models were constructed based on partial least squares discriminant analysis (PLS-DA), support vector machine (SVM), and convolutional neural network (CNN) algorithms with reflectance spectral data as the input. Regression models for predicting SSC across different watercore severity levels were also established. Feature wavelength selection was carried out using competitive adaptive reweighted sampling (CARS), successive projections algorithm (SPA), and uninformative variable elimination (UVE) methods. [Results and Discussions] The results indicated that as watercore severity increased, the SSC of Red Fuji apples exhibited an upward trend. The average SSC values were 13.4% for normal apples, 14.9% for mild watercore apples, 15.0% for moderate watercore apples, and 16.0% for severe watercore apples. X-ray CT imaging revealed that the average tissue density of watercore-affected regions was higher than that of healthy tissues. Three-dimensional reconstruction algorithms allowed visualization of the internal spatial distribution of watercore tissues at different severity levels. The spatial volume proportions of watercore tissues were 3.92% in mild, 6.11% in moderate, and 10.23% in severe watercore apples. Apples with severe watercore demonstrated higher spectral reflectance. The PLS-DA-based grading model achieved accuracies of 98.7% in the training set and 95.9% in the test set. The model based on feature wavelengths selected by the UVE algorithm also showed high precision, with accuracies of 95.67% in the training set and 86.06% in the test set. For SSC regression modeling, the partial least squares regression (PLSR) model performed best, with a coefficient of determination for calibration ( $R C 2$ ) of 0.962, root mean square error of calibration (RMSEC) of 0.264, coefficient of determination for prediction ( $R P 2$ ) of 0.879, and root mean square error of prediction (RMSEP) of 0.435. The model based on feature wavelengths selected by the SPA algorithm exhibited further improved prediction performance, yielding $R C 2$ 0.846, RMSEC 0.532, $R P 2$ ^{0.792, RMSEP 0.576, coefficient of determination for cross-validation ( $R C V 2$ ) 0.781, and root mean square error of cross-validation (RMSECV) 0.637. [Conclusions] This study leveraged hyperspectral imaging and X-ray CT technologies to analyze differences in optical reflectance and microstructural characteristics of apple tissues across different watercore severity levels. The developed grading model effectively predicted watercore severity in apples, providing critical technical support for the development of intelligent post-harvest sorting equipment. The SSC regression model accurately predicted SSC values in apples with varying watercore severity, offering an efficient method for non-destructive detection and quality assessment of watercore-affected apples.}

Key words: water core disease, hyperspectral imaging technology, X-ray CT imaging technology, soluble solid content (SSC)

中图分类号:

S436.611.1

于心圆, 王振杰, 尤思聪, 屠康, 兰维杰, 彭菁, 朱丽霞, 陈涛, 潘磊庆. 基于高光谱和X-ray CT的苹果水心病无损检测方法[J]. 智慧农业(中英文), 2025, 7(4): 108-118.

YU Xinyuan, WANG Zhenjie, YOU Sicong, TU Kang, LAN Weijie, PENG Jing, ZHU Lixia, CHEN Tao, PAN Leiqing. Non-destructive Detection of Apple Water Core Disease Based on Hyperspectral and X-ray CT Imaging[J]. Smart Agriculture, 2025, 7(4): 108-118.

图/表 16

图1

图2

图3

图4

图5

表1

图6

图7

图8

图9

图10

表2

图11

表3

表4

不同算法构建的不同水心程度苹果果实在400~1 000 nm处反射光谱SSC回归模型的预测效果

模型	校正集		预测集
模型	$R C 2$	RMSEC	$R P 2$	RMSEP
PLSR	0.962	0.264	0.879	0.435
SVR	0.998	0.057	0.771	1.057
CNN	0.930	0.355	0.822	0.539

表4

表5

基于不同水心程度苹果果实在特征波段处反射光谱SSC的PLSR模型效果

方法	校正集		测试集		交叉验证
方法	$R C 2$	RMSEC	$R P 2$	RMSEP	$R C V 2$	RMSECV
CARS	0.653	0.799	0.615	0.779	0.626	0.830
SPA	0.846	0.532	0.792	0.576	0.781	0.637
UVE	0.448	1.007	0.498	0.884	0.423	1.031

表5

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模型	样本集合	总体/%	正常组/%	轻度水心组/%	中度水心组/%	重度水心组/%
PLS	训练集	98.7	99.2	95.8	100.0	100.0
PLS	测试集	95.9	95.9	100.0	87.5	100.0
SVM	训练集	99.6	100.0	100.0	97.8	100.0
SVM	测试集	82.8	100.0	57.1	75.0	25.0
CNN	训练集	94.2	97.9	94.9	80.4	100.0
CNN	测试集	77.3	97.2	83.3	52.4	33.3

特征波段筛选方法	样本集合	总体/%	正常组/%	轻度水心组/%	中度水心组/%	重度水心组/%
CARS	训练集	90.25	95.08	91.49	74.42	100.00
CARS	测试集	86.06	95.92	73.33	75.00	100.00
SPA	训练集	77.92	83.61	65.96	72.09	90.00
SPA	测试集	82.87	89.8	66.67	75.00	100.00
UVE	训练集	95.67	98.36	93.62	90.70	100.00
UVE	测试集	86.06	95.92	73.33	75.00	100.00

基于高光谱和X-ray CT的苹果水心病无损检测方法

Non-destructive Detection of Apple Water Core Disease Based on Hyperspectral and X-ray CT Imaging

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水心病等级	批数/个				总计/个
水心病等级	第一批	第二批	第三批	第四批	总计/个
正常	58	28	19	8	113
轻微	10	21	17	13	61
中度	3	19	11	14	47
重度	1	2	2	4	9
总计	72	70	49	39	230