Soft computational techniques to identify cotton leaf damage

Day 3 Wed, August 18, 2021 Pub Date : 2021-08-01 DOI:10.21475/ajcs.21.15.08.p3256

R. F. Caldeira, W. E. Santiago, B. Teruel

{"title":"Soft computational techniques to identify cotton leaf damage","authors":"R. F. Caldeira, W. E. Santiago, B. Teruel","doi":"10.21475/ajcs.21.15.08.p3256","DOIUrl":null,"url":null,"abstract":"The principal objective of agriculture is the production of a high yield of healthy crops. This yield may be improved by the automatic detection of diseases and the consequent reduction in the use of pesticides. A digital processing system for images was thus developed and used to identify lesions on the leaves of cotton plants. A collection of 60,659 images of sub-metric resolution showing samples of soil and both healthy and damaged leaves was obtained and processed with an algorithm for the extraction of texture from 102x102-pixel samples. Then they analyzed with a neuro-fuzzy classifier trained to discriminate the three types of regions (soil, healthy leaf, and lesioned leaf). The algorithm developed was able to recognize the three classes. It generated a great amount of information on recognition of background which was more consistent than leaf damage areas. Therefore, it surpassed the performance of areas of healthy leaves. A similar trend was found for sensitivity. The overall accuracy of the system was 71.2%, suggesting that the unbalanced data of the different classes had skewed the results of the algorithm, as the number of false positives for the less well represented classes was greater. The analysis of unbalance (F-Score) showed that, independent of the volume of data, the attributes of texture utilized yielded better results for the images containing areas of damage in relation to overall accuracy. Therefore, given the challenges involved in the automatic identification of lesions in agricultural crops, such as variations in illumination, color, and texture, as well as obstruction, overlapping, and complexity of the region of which the image was taken, the behavior of the model was deemed satisfactory. Given the hybrid nature of the model, it should contribute to the state of the art in the use of intelligent systems in agriculture. This algorithm is available at https://github.com/rafaeufg/Cotton-diseases","PeriodicalId":11184,"journal":{"name":"Day 3 Wed, August 18, 2021","volume":"47 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2021-08-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"1","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Day 3 Wed, August 18, 2021","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.21475/ajcs.21.15.08.p3256","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}

引用次数: 1

Abstract

The principal objective of agriculture is the production of a high yield of healthy crops. This yield may be improved by the automatic detection of diseases and the consequent reduction in the use of pesticides. A digital processing system for images was thus developed and used to identify lesions on the leaves of cotton plants. A collection of 60,659 images of sub-metric resolution showing samples of soil and both healthy and damaged leaves was obtained and processed with an algorithm for the extraction of texture from 102x102-pixel samples. Then they analyzed with a neuro-fuzzy classifier trained to discriminate the three types of regions (soil, healthy leaf, and lesioned leaf). The algorithm developed was able to recognize the three classes. It generated a great amount of information on recognition of background which was more consistent than leaf damage areas. Therefore, it surpassed the performance of areas of healthy leaves. A similar trend was found for sensitivity. The overall accuracy of the system was 71.2%, suggesting that the unbalanced data of the different classes had skewed the results of the algorithm, as the number of false positives for the less well represented classes was greater. The analysis of unbalance (F-Score) showed that, independent of the volume of data, the attributes of texture utilized yielded better results for the images containing areas of damage in relation to overall accuracy. Therefore, given the challenges involved in the automatic identification of lesions in agricultural crops, such as variations in illumination, color, and texture, as well as obstruction, overlapping, and complexity of the region of which the image was taken, the behavior of the model was deemed satisfactory. Given the hybrid nature of the model, it should contribute to the state of the art in the use of intelligent systems in agriculture. This algorithm is available at https://github.com/rafaeufg/Cotton-diseases

查看原文本刊更多论文

棉花叶片损伤识别的软计算技术

农业的主要目标是生产高产的健康作物。这种产量可以通过病害的自动检测和由此减少的杀虫剂的使用而得到提高。因此，开发了一种用于图像的数字处理系统，并用于识别棉花叶片上的病变。获得60,659张亚公制分辨率的土壤、健康和受损叶片样本图像，并使用102x102像素样本纹理提取算法进行处理。然后，他们用经过训练的神经模糊分类器进行分析，以区分三种类型的区域(土壤、健康叶片和受损叶片)。所开发的算法能够识别这三类。产生了大量的背景识别信息，与叶损区识别结果一致。因此，它超过了健康叶面积的性能。敏感度也有类似的趋势。系统的总体准确率为71.2%，这表明不同类别的不平衡数据扭曲了算法的结果，因为代表不太好的类别的误报数量更多。不平衡分析(F-Score)表明，与数据量无关，所利用的纹理属性对于包含损伤区域的图像产生了与整体精度相关的更好结果。因此，考虑到自动识别农作物损伤所涉及的挑战，例如光照、颜色和纹理的变化，以及图像拍摄区域的障碍物、重叠和复杂性，该模型的行为被认为是令人满意的。鉴于该模型的混合性质，它应该有助于在农业中使用智能系统的最先进的状态。该算法可在https://github.com/rafaeufg/Cotton-diseases上获得

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

Day 3 Wed, August 18, 2021

自引率

0.00%

发文量