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Título
Examination of lemon bruising using different CNN-based classifiers and local spectral-spatial hyperspectral imaging
Autor
Año del Documento
2023
Editorial
MDPI
Descripción
Producción Científica
Documento Fuente
Algorithms, 2023, Vol. 16, Nº. 2, 113
Résumé
The presence of bruises on fruits often indicates cell damage, which can lead to a decrease in the ability of the peel to keep oxygen away from the fruits, and as a result, oxygen breaks down cell walls and membranes damaging fruit content. When chemicals in the fruit are oxidized by enzymes such as polyphenol oxidase, the chemical reaction produces an undesirable and apparent brown color effect, among others. Early detection of bruising prevents low-quality fruit from entering the consumer market. Hereupon, the present paper aims at early identification of bruised lemon fruits using 3D-convolutional neural networks (3D-CNN) via a local spectral-spatial hyperspectral imaging technique, which takes into account adjacent image pixel information in both the frequency (wavelength) and spatial domains of a 3D-tensor hyperspectral image of input lemon fruits. A total of 70 sound lemons were picked up from orchards. First, all fruits were labeled and the hyperspectral images (wavelength range 400–1100 nm) were captured as belonging to the healthy (unbruised) class (class label 0). Next, bruising was applied to each lemon by freefall. Then, the hyperspectral images of all bruised samples were captured in a time gap of 8 (class label 1) and 16 h (class label 2) after bruising was induced, thus resulting in a 3-class ternary classification problem. Four well-known 3D-CNN model namely ResNet, ShuffleNet, DenseNet, and MobileNet were used to classify bruised lemons in Python. Results revealed that the highest classification accuracy (90.47%) was obtained by the ResNet model, followed by DenseNet (85.71%), ShuffleNet (80.95%) and MobileNet (73.80%); all over the test set. ResNet model had larger parameter sizes, but it was proven to be trained faster than other models with fewer number of free parameters. ShuffleNet and MobileNet were easier to train and they needed less storage, but they could not achieve a classification error as low as the other two counterparts.
Materias (normalizadas)
Frutas
Cítricos
Cítricos - Cultivo
Citrus
Citrus cultivation
Citrus fruits
Classification
Neural networks (Computer science)
Redes neuronales (Informática)
Hyperspectral imaging
Fruit
Fruit - Quality
Food science
Machine learning
Aprendizaje automático
Artificial intelligence
Image processing - Digital techniques
Procesamiento de imágenes - Técnicas digitales.
Computer mathematics
Ordenadores - Matemáticas
Numerical analysis
Análisis numérico
Materias Unesco
1203.17 Informática
1203.04 Inteligencia Artificial
3102 Ingeniería Agrícola
Palabras Clave
Bruise
ISSN
1999-4893
Revisión por pares
SI
Version del Editor
Propietario de los Derechos
© 2023 The authors
Idioma
eng
Tipo de versión
info:eu-repo/semantics/publishedVersion
Derechos
openAccess
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