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Auteurs principaux: Contreras, Kebin, Martinez, Emmanuel, Monroy, Brayan, Ardila, Sebastian, Ramirez, Cristian, Caicedo, Mariana, Garcia, Hans, Gelvez-Barrera, Tatiana, Poveda-Jaramillo, Juan, Arguello, Henry, Bacca, Jorge
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2510.23892
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author Contreras, Kebin
Martinez, Emmanuel
Monroy, Brayan
Ardila, Sebastian
Ramirez, Cristian
Caicedo, Mariana
Garcia, Hans
Gelvez-Barrera, Tatiana
Poveda-Jaramillo, Juan
Arguello, Henry
Bacca, Jorge
author_facet Contreras, Kebin
Martinez, Emmanuel
Monroy, Brayan
Ardila, Sebastian
Ramirez, Cristian
Caicedo, Mariana
Garcia, Hans
Gelvez-Barrera, Tatiana
Poveda-Jaramillo, Juan
Arguello, Henry
Bacca, Jorge
contents Cocoa bean quality assessment is essential for ensuring compliance with commercial standards, protecting consumer health, and increasing the market value of the cocoa product. The quality assessment estimates key physicochemical properties, such as fermentation level, moisture content, polyphenol concentration, and cadmium content, among others. This assessment has traditionally relied on the accurate estimation of these properties via visual or sensory evaluation, jointly with laboratory-based physicochemical analyses, which are often time-consuming, destructive, and difficult to scale. This creates the need for rapid, reliable, and noninvasive alternatives. Spectroscopy, particularly in the visible and near-infrared ranges, offers a non-invasive alternative by capturing the molecular signatures associated with these properties. Therefore, this work introduces a scalable methodology for evaluating the quality of cocoa beans by predicting key physicochemical properties from the spectral signatures of cocoa beans. This approach utilizes a conveyor belt system integrated with a VIS-NIR spectrometer, coupled with learning-based regression models. Furthermore, a dataset is built using cocoa bean batches from Santander, Colombia. Ground-truth reference values were obtained through standardized laboratory analyses and following commercial cocoa quality regulations. To further evaluate the proposed methodology's generalization, performance is tested on samples collected from other Colombian regions and from Cusco, Peru. Experimental results show that the proposed models achieved R2 scores exceeding 0.98 across all physicochemical properties, and reached 0.96 accuracy on geographically independent samples. This non-destructive approach represents a suitable and scalable alternative to conventional laboratory methods for quality assessment across the cocoa production chain.
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publishDate 2025
record_format arxiv
spellingShingle Learning-based Spectral Regression for Cocoa Bean Physicochemical Property Prediction
Contreras, Kebin
Martinez, Emmanuel
Monroy, Brayan
Ardila, Sebastian
Ramirez, Cristian
Caicedo, Mariana
Garcia, Hans
Gelvez-Barrera, Tatiana
Poveda-Jaramillo, Juan
Arguello, Henry
Bacca, Jorge
Signal Processing
Cocoa bean quality assessment is essential for ensuring compliance with commercial standards, protecting consumer health, and increasing the market value of the cocoa product. The quality assessment estimates key physicochemical properties, such as fermentation level, moisture content, polyphenol concentration, and cadmium content, among others. This assessment has traditionally relied on the accurate estimation of these properties via visual or sensory evaluation, jointly with laboratory-based physicochemical analyses, which are often time-consuming, destructive, and difficult to scale. This creates the need for rapid, reliable, and noninvasive alternatives. Spectroscopy, particularly in the visible and near-infrared ranges, offers a non-invasive alternative by capturing the molecular signatures associated with these properties. Therefore, this work introduces a scalable methodology for evaluating the quality of cocoa beans by predicting key physicochemical properties from the spectral signatures of cocoa beans. This approach utilizes a conveyor belt system integrated with a VIS-NIR spectrometer, coupled with learning-based regression models. Furthermore, a dataset is built using cocoa bean batches from Santander, Colombia. Ground-truth reference values were obtained through standardized laboratory analyses and following commercial cocoa quality regulations. To further evaluate the proposed methodology's generalization, performance is tested on samples collected from other Colombian regions and from Cusco, Peru. Experimental results show that the proposed models achieved R2 scores exceeding 0.98 across all physicochemical properties, and reached 0.96 accuracy on geographically independent samples. This non-destructive approach represents a suitable and scalable alternative to conventional laboratory methods for quality assessment across the cocoa production chain.
title Learning-based Spectral Regression for Cocoa Bean Physicochemical Property Prediction
topic Signal Processing
url https://arxiv.org/abs/2510.23892