LSGNet: A lightweight convolutional neural network model for tomato disease identification
LSGNet: A lightweight convolutional neural network model for tomato disease identification
Tomatoes are among the most extensively grown and consumed crops worldwide, but tomato production can be greatly reduced due to various diseases. Plant diseases show different symptoms at different stages. In addition, there are similarities in the symptoms of different types of plant diseases, which hinder the recognition of diseases by existing deep learning models. Traditional convolutional neural network (CNN) models for disease recognition have a large number of parameters that require high computational resources. To overcome these challenges, we propose a lightweight CNN model named LSGNet (lightweight sandglass network) for tomato disease identification. The LSGNet backbone consists of the sandglass with efficient channel attention (SGECA) and the position aware circular convolution sandglass (ParcSG) modules. The SGECA module reduces the interference of complex environments and thus focuses on extracting useful feature information. The ParcSG module has a global receptive field, which provides more detailed feature information on disease recognition. The results show that the recognition accuracies are 92.37%, 94.32%, 89.64%, 92.70%, 94.43%, 90.97%, 89.42%, 92.98%, 89.58%, and 95.54% for AlexNet, ResNet50, VGG16, MobileNetV3-Large, ShuffleNetV2-1 ×, EfficientNetV2-Small, ViT-Base, MobileViT-Small, Swin-Tiny, and LSGNet. Therefore, LSGNet has higher accuracy in recognizing tomato diseases compared to other classical models. In addition, LSGNet uses 0.75 million parameters. Compared to the lightweight CNN model MobileNetV3-Large, it only has 18% of the parameters. As a whole, the advantages of LSGNet in efficiency and lightweight structure would make it a useful tool for tomato disease recognition on mobile or embedded devices.
Attention mechanism, Convolutional neural network, Lightweight model, Tomato disease recognition
Yang, Shengxian
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Zhang, Licai
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Lin, Jianwu
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Cernava, Tomislav
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Cai, Jitong
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Pan, Renyong
13d5aa00-b2e5-41cb-b17b-b33579ebb4c2
Liu, Jiaming
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Wen, Xingtian
a9074589-7255-45a7-a7c4-8f632dd184cf
Chen, Xiaoyulong
02c0a0f6-0927-47d3-80ab-68b70e81c9fb
Zhang, Xin
3056a795-80f7-4bbd-9c75-ecbc93085421
30 April 2024
Yang, Shengxian
2e3f533c-fb9d-416d-ba13-e1530eebd453
Zhang, Licai
aa728472-c9f7-4410-95b5-3908345fdd94
Lin, Jianwu
7db282c5-c8a9-447c-bad4-34241c034b32
Cernava, Tomislav
a13d65aa-2529-479a-ba90-69ebbc4ba07f
Cai, Jitong
3af2a410-f108-4f4d-8bb5-76dd2550a7d9
Pan, Renyong
13d5aa00-b2e5-41cb-b17b-b33579ebb4c2
Liu, Jiaming
6f9d1ca2-a6b5-45e1-a86c-9108c45c1c20
Wen, Xingtian
a9074589-7255-45a7-a7c4-8f632dd184cf
Chen, Xiaoyulong
02c0a0f6-0927-47d3-80ab-68b70e81c9fb
Zhang, Xin
3056a795-80f7-4bbd-9c75-ecbc93085421
Yang, Shengxian, Zhang, Licai, Lin, Jianwu, Cernava, Tomislav, Cai, Jitong, Pan, Renyong, Liu, Jiaming, Wen, Xingtian, Chen, Xiaoyulong and Zhang, Xin
(2024)
LSGNet: A lightweight convolutional neural network model for tomato disease identification.
Crop Protection, 182, [106715].
(doi:10.1016/j.cropro.2024.106715).
Abstract
Tomatoes are among the most extensively grown and consumed crops worldwide, but tomato production can be greatly reduced due to various diseases. Plant diseases show different symptoms at different stages. In addition, there are similarities in the symptoms of different types of plant diseases, which hinder the recognition of diseases by existing deep learning models. Traditional convolutional neural network (CNN) models for disease recognition have a large number of parameters that require high computational resources. To overcome these challenges, we propose a lightweight CNN model named LSGNet (lightweight sandglass network) for tomato disease identification. The LSGNet backbone consists of the sandglass with efficient channel attention (SGECA) and the position aware circular convolution sandglass (ParcSG) modules. The SGECA module reduces the interference of complex environments and thus focuses on extracting useful feature information. The ParcSG module has a global receptive field, which provides more detailed feature information on disease recognition. The results show that the recognition accuracies are 92.37%, 94.32%, 89.64%, 92.70%, 94.43%, 90.97%, 89.42%, 92.98%, 89.58%, and 95.54% for AlexNet, ResNet50, VGG16, MobileNetV3-Large, ShuffleNetV2-1 ×, EfficientNetV2-Small, ViT-Base, MobileViT-Small, Swin-Tiny, and LSGNet. Therefore, LSGNet has higher accuracy in recognizing tomato diseases compared to other classical models. In addition, LSGNet uses 0.75 million parameters. Compared to the lightweight CNN model MobileNetV3-Large, it only has 18% of the parameters. As a whole, the advantages of LSGNet in efficiency and lightweight structure would make it a useful tool for tomato disease recognition on mobile or embedded devices.
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Accepted/In Press date: 24 April 2024
e-pub ahead of print date: 25 April 2024
Published date: 30 April 2024
Keywords:
Attention mechanism, Convolutional neural network, Lightweight model, Tomato disease recognition
Identifiers
Local EPrints ID: 490868
URI: http://eprints.soton.ac.uk/id/eprint/490868
ISSN: 0261-2194
PURE UUID: aab7abe9-9660-4ad1-a751-c6d5d039cc6b
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Date deposited: 07 Jun 2024 16:39
Last modified: 08 Jun 2024 02:08
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Contributors
Author:
Shengxian Yang
Author:
Licai Zhang
Author:
Jianwu Lin
Author:
Tomislav Cernava
Author:
Jitong Cai
Author:
Renyong Pan
Author:
Jiaming Liu
Author:
Xingtian Wen
Author:
Xiaoyulong Chen
Author:
Xin Zhang
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