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一种水稻冠层病虫害智能监测系统。

An intelligent monitoring system of diseases and pests on rice canopy.

作者信息

Li Suxuan, Feng Zelin, Yang Baojun, Li Hang, Liao Fubing, Gao Yufan, Liu Shuhua, Tang Jian, Yao Qing

机构信息

School of Computer Science and Technology, Zhejiang Sci-Tech University, Hangzhou, China.

State Key Laboratory of Rice Biology, China National Rice Research Institute, Hangzhou, China.

出版信息

Front Plant Sci. 2022 Aug 11;13:972286. doi: 10.3389/fpls.2022.972286. eCollection 2022.

DOI:10.3389/fpls.2022.972286
PMID:36035691
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9403268/
Abstract

Accurate and timely surveys of rice diseases and pests are important to control them and prevent the reduction of rice yields. The current manual survey method of rice diseases and pests is time-consuming, laborious, highly subjective and difficult to trace historical data. To address these issues, we developed an intelligent monitoring system for detecting and identifying the disease and pest lesions on the rice canopy. The system mainly includes a network camera, an intelligent detection model of diseases and pests on rice canopy, a web client and a server. Each camera of the system can collect rice images in about 310 m of paddy fields. An improved model YOLO-Diseases and Pests Detection (YOLO-DPD) was proposed to detect three lesions of and on rice canopy. The residual feature augmentation method was used to narrow the semantic gap between different scale features of rice disease and pest images. The convolution block attention module was added into the backbone network to enhance the regional disease and pest features for suppressing the background noises. Our experiments demonstrated that the improved model YOLO-DPD could detect three species of disease and pest lesions on rice canopy at different image scales with an average precision of 92.24, 87.35 and 90.74%, respectively, and a mean average precision of 90.11%. Compared to RetinaNet, Faster R-CNN and Yolov4 models, the mean average precision of YOLO-DPD increased by 18.20, 6.98, 6.10%, respectively. The average detection time of each image is 47 ms. Our system has the advantages of unattended operation, high detection precision, objective results, and data traceability.

摘要

准确及时地调查水稻病虫害对于控制病虫害和防止水稻减产至关重要。当前水稻病虫害的人工调查方法耗时、费力、主观性强且难以追溯历史数据。为了解决这些问题,我们开发了一种智能监测系统,用于检测和识别水稻冠层上的病虫害病斑。该系统主要包括网络摄像头、水稻冠层病虫害智能检测模型、网页客户端和服务器。系统的每个摄像头可在约310米的稻田内采集水稻图像。提出了一种改进模型YOLO-病虫害检测(YOLO-DPD),用于检测水稻冠层上的三种病斑。采用残差特征增强方法来缩小水稻病虫害图像不同尺度特征之间的语义差距。在骨干网络中添加了卷积块注意力模块,以增强区域病虫害特征,抑制背景噪声。我们的实验表明,改进后的模型YOLO-DPD能够在不同图像尺度下检测水稻冠层上的三种病虫害病斑,平均精度分别为92.24%、87.35%和90.74%,平均平均精度为90.11%。与RetinaNet、Faster R-CNN和Yolov4模型相比,YOLO-DPD的平均平均精度分别提高了18.20%、6.98%、6.10%。每张图像的平均检测时间为47毫秒。我们的系统具有无人值守操作、检测精度高、结果客观和数据可追溯性等优点。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/8bb5/9403268/be5e7ddc2c4e/fpls-13-972286-g009.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/8bb5/9403268/bdf7a404f959/fpls-13-972286-g001.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/8bb5/9403268/e53d18ee29d6/fpls-13-972286-g006.jpg
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