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深度学习技术在自然图像中葡萄品种识别的应用。

Deep Learning Techniques for Grape Plant Species Identification in Natural Images.

机构信息

Instituto Politécnico do Porto, Escola Superior de Tecnologia e Gestão, Rua do Curral, Casa do Curral-Margaride, 4610-156 Felgueiras, Portugal.

INESC TEC/UTAD, Quinta de Prados, 5001-801 Vila Real, Portugal.

出版信息

Sensors (Basel). 2019 Nov 7;19(22):4850. doi: 10.3390/s19224850.

DOI:10.3390/s19224850
PMID:31703313
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6891615/
Abstract

Frequently, the vineyards in the Douro Region present multiple grape varieties per parcel and even per row. An automatic algorithm for grape variety identification as an integrated software component was proposed that can be applied, for example, to a robotic harvesting system. However, some issues and constraints in its development were highlighted, namely, the images captured in natural environment, low volume of images, high similarity of the images among different grape varieties, leaf senescence, and significant changes on the grapevine leaf and bunch images in the harvest seasons, mainly due to adverse climatic conditions, diseases, and the presence of pesticides. In this paper, the performance of the transfer learning and fine-tuning techniques based on AlexNet architecture were evaluated when applied to the identification of grape varieties. Two natural vineyard image datasets were captured in different geographical locations and harvest seasons. To generate different datasets for training and classification, some image processing methods, including a proposed four-corners-in-one image warping algorithm, were used. The experimental results, obtained from the application of an AlexNet-based transfer learning scheme and trained on the image dataset pre-processed through the four-corners-in-one method, achieved a test accuracy score of 77.30%. Applying this classifier model, an accuracy of 89.75% on the popular Flavia leaf dataset was reached. The results obtained by the proposed approach are promising and encouraging in helping Douro wine growers in the automatic task of identifying grape varieties.

摘要

通常,杜罗地区的葡萄园在每片土地甚至每行都种植多种葡萄品种。本文提出了一种葡萄品种识别的自动算法作为集成软件组件,可以应用于例如机器人采摘系统。然而,在其开发过程中突出了一些问题和限制,即自然环境下拍摄的图像、图像数量少、不同葡萄品种之间的图像相似度高、叶片衰老以及收获季节葡萄藤叶片和果穗图像的显著变化,主要是由于恶劣的气候条件、疾病和农药的存在。在本文中,评估了基于 AlexNet 架构的迁移学习和微调技术在葡萄品种识别中的性能。两个自然葡萄园图像数据集是在不同的地理位置和收获季节拍摄的。为了生成用于训练和分类的不同数据集,使用了一些图像处理方法,包括一种提出的四角合一图像变形算法。从应用基于 AlexNet 的迁移学习方案并在通过四角合一方法预处理的图像数据集上进行训练获得的实验结果,测试精度得分为 77.30%。应用该分类器模型,在流行的 Flavia 叶片数据集上达到了 89.75%的准确率。所提出方法的结果是有希望的,有助于杜罗葡萄酒种植者实现葡萄品种的自动识别任务。

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