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利用形态分析和机器学习算法鉴别14个橄榄品种

Discrimination of 14 olive cultivars using morphological analysis and machine learning algorithms.

作者信息

Blazakis Konstantinos N, Stupichev Danil, Kosma Maria, El Chami Mohamad Ali Hassan, Apodiakou Anastasia, Kostelenos George, Kalaitzis Panagiotis

机构信息

Department of Horticultural Genetics and Biotechnology, Mediterranean Agronomic Institute of Chania (MAICh), Chania, Greece.

Kostelenos Olive Nurseries, Poros, Greece.

出版信息

Front Plant Sci. 2024 Aug 8;15:1441737. doi: 10.3389/fpls.2024.1441737. eCollection 2024.

DOI:10.3389/fpls.2024.1441737
PMID:39175491
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11340652/
Abstract

Traditional morphological analysis is a widely employed tool for the identification and discrimination of olive germplasm by using morphological markers which are monitored by subjective manual measurements that are labor intensive and time-consuming. Alternatively, an automated methodology can quantify the geometrical features of fruits, leaves and endocarps with high accuracy and efficiency in order to define their morphological characteristics. In this study, 24 characteristics for fruits, 16 for leaves and 25 for endocarps were determined and used in an automated way with basic classifiers combined with a meta-classsifier approach. This resulted to the discrimination of 14 olive cultivars utilizing data obtained from two consecutive olive growing periods. The cultivar classification algorithms were based on machine learning techniques. The 95% accuracy rate of the meta-classifier approach indicated that was an efficient tool to discriminate olive cultivars. The contribution of each morphological feature to cultivar discrimination was quantified, and the significance of each one was automatically detected in a quantitative way. The higher the contribution of each feature, the higher the significance for cultivar discrimination. The identification of most cultivars was guided by the features of both endocarps and fruits, while those of leaves were only efficient to identify the Kalamon cultivar. The combined use of morphological features of three olive organs might have an additive effect leading to higher capacity for discrimination of cultivars. The proposed methodology might be considered a phenomics tool for olive cultivar identification and discrimination in a wide range of applications including breeding.

摘要

传统形态学分析是一种广泛应用的工具,通过使用形态学标记来鉴定和区分橄榄种质,这些标记通过主观的人工测量进行监测,既耗费人力又耗时。相比之下,一种自动化方法可以高精度、高效率地量化果实、叶子和内果皮的几何特征,以确定它们的形态特征。在本研究中,确定了果实的24个特征、叶子的16个特征和内果皮的25个特征,并将其与基本分类器相结合,以元分类器方法自动使用。这使得利用连续两个橄榄生长季节获得的数据对14个橄榄品种进行了区分。品种分类算法基于机器学习技术。元分类器方法95%的准确率表明它是区分橄榄品种的有效工具。对每个形态特征对品种区分的贡献进行了量化,并以定量方式自动检测了每个特征的显著性。每个特征的贡献越高,对品种区分的显著性就越高。大多数品种的鉴定由内果皮和果实的特征指导,而叶子的特征仅能有效鉴定卡拉蒙品种。三个橄榄器官形态特征的联合使用可能具有累加效应,从而提高品种区分能力。所提出的方法可被视为一种表型组学工具,用于在包括育种在内的广泛应用中鉴定和区分橄榄品种。

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