Tea leaf disease detection and identification based on YOLOv7 (YOLO-T)

Soeb, Md. Janibul Alam; Jubayer, Md. Fahad; Tarin, Tahmina Akanjee; Mamun, Muhammad Rashed Al; Ruhad, Fahim Mahafuz; Parven, Aney; Mubarak, Nabisab Mujawar; Karri, Soni Lanka; Meftaul, Islam Md

doi:10.1038/s41598-023-33270-4

Cited by 56 publications

(35 citation statements)

References 58 publications

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“…The primary objective of object detection is to accurately identify objects in an image or video and label their location. Recently, deep learning algorithms have been successfully deployed in practical applications such as pathology analysis [1], ore detection [2], tea disease detection [3], and crop weed detection [4]. However, obtaining a large amount of labelled data for training and testing is often necessary for deep‐learning object detection.…”

Section: Introductionmentioning

confidence: 99%

“…used a target localization method [1, 18]. (a) Few people have considered improving the neck part of the deep neural network model, which will limit model performance and increase code runtime [2–4]. (b) The high computational resource requirements of high‐resolution object detection [16, 17] hinder its widespread adoption in many enterprises.…”

Section: Introductionmentioning

confidence: 99%

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Few‐shot object detection based on global context and implicit knowledge decoupled head

Li,

Yang,

Liu

et al. 2024

IET Image Processing

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The acquisition cycle of remote sensing images is slow, and the labelling process encounters challenges, which have become prominent with the rapid development of remote sensing image object detection research. Therefore, this article provides a way to make the model better capture the diversity and contextual relationships in the data, and solve this problem by more than just data augmentation. Specifically, this method is a few‐shot object detection method for remote sensing based on global context combined with implicit knowledge decoupled head (GC‐IKDH). This method first uses a segmentation strategy to convert high‐resolution images into low‐resolution images and expands the sample size through a generative model. Secondly, GC attention is introduced to generate a GC vector by weighting and averaging the information of each position in the input sequence, which helps the model better understand the semantics of the input sequence. Finally, an IKDH is added to improve the model head, which is used to learn specific features in the data so that the model can better handle the diversity in the data. Experimental results show that GC attention and IKDH boosting provide a good performance boost to the baseline model. Compared with other few‐shot samples, this method achieves state‐of‐the‐art performance under different shot settings and highly competitive results on two benchmark datasets (NWPU VHR‐10 and DIOR).

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Few‐shot object detection based on global context and implicit knowledge decoupled head

Li,

Yang,

Liu

et al. 2024

IET Image Processing

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“…YOLO-v7 leverages a trainable bag-of-freebies approach, enabling significant improvements in precision for real-time detection tasks without incurring additional inference costs. By integrating extend and compound scaling, it effectively reduce the number of parameters and calculations, resulting in a substantial acceleration of the detection rate 25 . To the best of our knowledge, no studies have applied this YOLO model to the diagnostic distinction of cervical lymphadenopathy.…”

Section: Introductionmentioning

confidence: 99%

Diagnosis of cervical lymphoma using a YOLO-v7-based model with transfer learning

Wang,

Yang,

Yang

et al. 2024

Sci Rep

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To investigate the ability of an auxiliary diagnostic model based on the YOLO-v7-based model in the classification of cervical lymphadenopathy images and compare its performance against qualitative visual evaluation by experienced radiologists. Three types of lymph nodes were sampled randomly but not uniformly. The dataset was randomly divided into for training, validation, and testing. The model was constructed with PyTorch. It was trained and weighting parameters were tuned on the validation set. Diagnostic performance was compared with that of the radiologists on the testing set. The mAP of the model was 96.4% at the 50% intersection-over-union threshold. The accuracy values of it were 0.962 for benign lymph nodes, 0.982 for lymphomas, and 0.960 for metastatic lymph nodes. The precision values of it were 0.928 for benign lymph nodes, 0.975 for lymphomas, and 0.927 for metastatic lymph nodes. The accuracy values of radiologists were 0.659 for benign lymph nodes, 0.836 for lymphomas, and 0.580 for metastatic lymph nodes. The precision values of radiologists were 0.478 for benign lymph nodes, 0.329 for lymphomas, and 0.596 for metastatic lymph nodes. The model effectively classifies lymphadenopathies from ultrasound images and outperforms qualitative visual evaluation by experienced radiologists in differential diagnosis.

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“…Although these models cannot recognize high-resolution images in real-time, faster R-CNN, consisting of region proposal networks (RPN) ( Chen and Wu, 2023 ) and classification networks, considerably decrease detection time. By combining target categorization and localization into a regression problem, the recently suggested You Only Look Once (YOLO) ( Soeb et al., 2023 ) method simplifies the problem. Due to its lack of RPN, YOLO employs regression to directly locate targets in the image, significantly improving its detection speed.…”

Section: Introductionmentioning

confidence: 99%

Detection and identification of plant leaf diseases using YOLOv4

Aldakheel,

Zakariah,

Alabdalall

2024

Front. Plant Sci.

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Detecting plant leaf diseases accurately and promptly is essential for reducing economic consequences and maximizing crop yield. However, farmers’ dependence on conventional manual techniques presents a difficulty in accurately pinpointing particular diseases. This research investigates the utilization of the YOLOv4 algorithm for detecting and identifying plant leaf diseases. This study uses the comprehensive Plant Village Dataset, which includes over fifty thousand photos of healthy and diseased plant leaves from fourteen different species, to develop advanced disease prediction systems in agriculture. Data augmentation techniques including histogram equalization and horizontal flip were used to improve the dataset and strengthen the model’s resilience. A comprehensive assessment of the YOLOv4 algorithm was conducted, which involved comparing its performance with established target identification methods including Densenet, Alexanet, and neural networks. When YOLOv4 was used on the Plant Village dataset, it achieved an impressive accuracy of 99.99%. The evaluation criteria, including accuracy, precision, recall, and f1-score, consistently showed high performance with a value of 0.99, confirming the effectiveness of the proposed methodology. This study’s results demonstrate substantial advancements in plant disease detection and underscore the capabilities of YOLOv4 as a sophisticated tool for accurate disease prediction. These developments have significant significance for everyone involved in agriculture, researchers, and farmers, providing improved capacities for disease control and crop protection.

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Tea leaf disease detection and identification based on YOLOv7 (YOLO-T)

Cited by 56 publications

References 58 publications

Few‐shot object detection based on global context and implicit knowledge decoupled head

Few‐shot object detection based on global context and implicit knowledge decoupled head

Diagnosis of cervical lymphoma using a YOLO-v7-based model with transfer learning

Detection and identification of plant leaf diseases using YOLOv4

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