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使用机器学习模型评估和预测不同条件下加工和储存的 Jatobá-do-Cerrado 种子的物理性质和质量。

Evaluation and prediction of the physical properties and quality of Jatobá-do-Cerrado seeds processed and stored in different conditions using machine learning models.

机构信息

Department of Agronomy, Campus de Chapadão do Sul, Federal University of Mato Grosso do Sul, Chapadão do Sul, Mato Grosso do Sul, 79560-000, Brazil.

Laboratory of Postharvest (LAPOS), Federal University of Santa Maria, Campus Cachoeira do Sul, Cachoeira do Sul, RS, 96503-205, Brazil.

出版信息

Sci Rep. 2024 Nov 28;14(1):29580. doi: 10.1038/s41598-024-81260-x.

DOI:10.1038/s41598-024-81260-x
PMID:39609502
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11604944/
Abstract

The conservation of seed quality throughout storage depends on established conditions, monitoring, sampling and laboratory analysis, which are subject to errors and require technical and financial resources. Thus, machine learning techniques can help optimize processes and obtain more accurate results for decision-making regarding the processing and conservation of stored seeds. Therefore, the aim was to assess and predict the physical properties (moisture content, seed mass, length, thickness, width, volume, apparent specific mass, projected area, sphericity, mean diameter, circular area, circularity, drag coefficient), and physicochemical quality (crude protein, ash content, and acidity index) of Jatobá-do-Cerrado seeds under different processing conditions with pulp, without pulp (scarification), without pulp (fermented), and storage conditions at 10 and 23 °C over six months. Data were analyzed on Weka software (Waikato Environment for Knowledge Analysis) version 3.9.5. testing the following models: Pearson correlation, Artificial Neural Networks, decision tree algorithms RepTree and M5P, Random Forest, and Linear Regression. Processing cerrado jatobá seeds by fermentation and storage at 10 °C minimized physical changes and preserved the physicochemical quality of the seeds in polyethylene plastic, glass container, tetrapack, and polyethylene container, over six months. The combination of processing, temperature, and packaging variables for Artificial Neural Networks, RepTree, Random Forest, and M5P algorithms outperformed linear regression, providing higher accuracy rates. Artificial Neural Network and Random Forest models were the best predicting the effects of treatments on changes in physical properties and physicochemical quality of jatobá seed.

摘要

种子质量在储存过程中的保存取决于已建立的条件、监测、抽样和实验室分析,这些都容易出现错误,需要技术和财务资源。因此,机器学习技术可以帮助优化过程,并为处理和储存种子的决策提供更准确的结果。因此,本研究的目的是评估和预测不同加工条件(带果肉、去果肉(刻痕)、去果肉(发酵)和在 10 和 23°C 下储存)下,Jatobá-do-Cerrado 种子的物理特性(水分含量、种子质量、长度、厚度、宽度、体积、表观比重、投影面积、球形度、平均直径、圆形面积、圆形度、阻力系数)和理化质量(粗蛋白、灰分和酸度指数)。在 Weka 软件(Waikato Environment for Knowledge Analysis)版本 3.9.5 上分析数据,测试了以下模型:皮尔逊相关、人工神经网络、决策树算法 RepTree 和 M5P、随机森林和线性回归。在 10°C 下发酵和储存 cerrado jatobá 种子可最大限度地减少物理变化,并在六个月内保持聚乙烯塑料、玻璃容器、利乐包和聚乙烯容器中种子的理化质量。人工神经网络、RepTree、随机森林和 M5P 算法的加工、温度和包装变量的组合优于线性回归,提供了更高的准确率。人工神经网络和随机森林模型是预测处理对 jatobá 种子物理特性和理化质量变化影响的最佳模型。

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