Smart Agriculture ›› 2023, Vol. 5 ›› Issue (2): 126-148.doi: 10.12133/j.smartag.SA202306002
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Received:
2023-06-02
Online:
2023-06-30
corresponding author:
ZHAO Chunjiang, E-mail:zhaocj@nercita.org.cn
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CLC Number:
ZHAO Chunjiang. Agricultural Knowledge Intelligent Service Technology: A Review[J]. Smart Agriculture, 2023, 5(2): 126-148.
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URL: https://www.smartag.net.cn/EN/10.12133/j.smartag.SA202306002
Table 1
Comparison of agricultural target detection technologies based on machine vision
模型 | 特点 | 作物类型 | 结果 | |
---|---|---|---|---|
两阶段农业目标检测 | Faster R-CNN[ | 针对背景复杂、多尺度小目标特征检测表现良好 | 番茄病虫害定位检测 | 平均识别精度达到85.98% |
改进Faster R-CNN[ | 采用区域特征聚集改进Faster R-CNN兴趣区域池化层,以降低特征量化误差 | 小麦锯蝇、小麦蚜、小麦螨 | 平均精度均值达到81.0% | |
MR3P-TS[ | 扩展了Mask R-CNN中Mask分支,通过计算掩模的多个连通域的面积,识别出了采摘主要部分 | 茶芽轮廓和采摘点检测 | 采摘点定位Pr=94.9, Recall=91% | |
一阶段农业目标检测 | 改进SSD网络[ | 融合多尺度卷积核和空洞卷积模块提高特征检测识别能力 | 原木端面识别 | 检测精确率达到97% |
GSC-YOLOv3[ | 将GhostNet作为主干网络,使用空间金字塔池化结构增强特征提取 | 红花丝检测 | 平均精度均值达到91.89% | |
YOLOv4-GCF[ | YOLOv4采用GhostNet作为主干网络,利用注意力机制CBAM提高检测精度 | 荔枝病虫害检测 | 平均精度达到89.76% | |
YOLOv4-Dense[ | YOLOv4结合DenseNet网络将先验框改为符合形状的圆形标记框 | 樱桃果实检测定位 | F1值达到0.947 | |
GHTR2-YOLOv5s[ | YOLOv5s融合卷积块注意力模块和加权双向特征金字塔网络,具有更高的检测精度 | 苹果果实病害检测 | 平均精度均值达到90.9% |
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