Lightweight deep and cross residual skip connection separable CNN for plant leaf diseases classification

IF 1 4区 计算机科学 Q4 ENGINEERING, ELECTRICAL & ELECTRONIC
Naresh Vedhamuru, Ramanathan Malmathanraj, Ponnusamy Palanisamy
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引用次数: 0

Abstract

Crop diseases have an adverse effect on the yield, productivity, and quality of agricultural produce, which threatens the safety and security of the global feature of food supply. Addressing and controlling plant diseases through implementation of timely disease management strategies to reduce their transmission are essential for ensuring minimal crop loss, and addressing the increasing demand for food worldwide as the population continues to increase in a steadfast manner. Crop disease mitigation measures involve preventive monitoring, resulting in early detection and classification of plant diseases for effective agricultural procedure to improve crop yield. Early detection and accurate diagnosis of plant diseases enables farmers to deploy disease management strategies, such interventions are critical for better management contributing to higher crop output by curbing the spread of infection and limiting the extent of damage caused by diseases. We propose and implement a deep and cross residual skip connection separable convolutional neural network (DCRSCSCNN) for identifying and classifying leaf diseases for crops including apple, corn, cucumber, grape, potato, and guava. The significant feature of DCRSCSCNN includes residual skip connection and cross residual skip connection separable convolution block. The usage of residual skip connections assists in fixing the gradient vanishing issue faced by network architecture. The employment of separable convolution decreases the number of parameters, which leads to a model with a reduced size. So far, there has been limited exploration or investigation of leveraging separable convolution within lightweight neural networks. Extensive evaluation of several training and test sets using distinct datasets demonstrate that the proposed DCRSCSCNN outperforms other state-of-the-art approaches. The DCRSCSCNN achieved exceptional classification and identification accuracy rates of 99.89% for apple, 98.72% for corn, 100% for cucumber, 99.78% for grape, 100% for potato, 99.69% for guava1, and 99.08% for guava2 datasets.
用于植物叶片病害分类的轻量级深度和交叉残差跳接可分离 CNN
农作物病害对农产品的产量、生产率和质量都有不利影响,威胁着全球粮食供应的安全和保障。通过实施及时的病害管理策略来应对和控制植物病害,减少病害传播,对于确保将作物损失降至最低,以及应对全球人口持续增长带来的粮食需求增长至关重要。作物病害缓解措施包括预防性监测,从而及早发现植物病害并对其进行分类,以采取有效的农业措施提高作物产量。对植物病害的早期检测和准确诊断使农民能够部署病害管理策略,这种干预措施对更好地管理至关重要,可通过遏制感染传播和限制病害造成的损害程度来提高作物产量。我们提出并实施了一种深度和交叉残差跳接可分离卷积神经网络(DCRSCSCNN),用于对苹果、玉米、黄瓜、葡萄、马铃薯和番石榴等作物的叶片病害进行识别和分类。DCRSCSCNN 的重要特征包括残余跳转连接和交叉残余跳转连接可分离卷积块。残差跳转连接的使用有助于解决网络架构所面临的梯度消失问题。可分离卷积的使用减少了参数的数量,从而缩小了模型的规模。迄今为止,在轻量级神经网络中利用可分离卷积的探索或研究还很有限。利用不同的数据集对多个训练集和测试集进行的广泛评估表明,所提出的 DCRSCSCNN 优于其他最先进的方法。DCRSCSCNN 在苹果、玉米、黄瓜、葡萄、马铃薯、番石榴 1 和番石榴 2 数据集上的分类和识别准确率分别达到了 99.89%、98.72%、100%、99.78%、100%、99.69% 和 99.08%。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Journal of Electronic Imaging
Journal of Electronic Imaging 工程技术-成像科学与照相技术
CiteScore
1.70
自引率
27.30%
发文量
341
审稿时长
4.0 months
期刊介绍: The Journal of Electronic Imaging publishes peer-reviewed papers in all technology areas that make up the field of electronic imaging and are normally considered in the design, engineering, and applications of electronic imaging systems.
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