Improved algorithm for lightweight identification of 3D GPR images of hidden road defects
Article Text (Baidu Translation)
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摘要: 针对目前三维探地雷达检测技术中对于道路隐性病害实时检测真实数据规模较小、人工解译困难、传统算法检测精度和效率不足的问题,提出了一种基于YOLOv8的轻量化改进算法YOLOv8-CES;根据采集到的道路隐性病害三维探地雷达图谱,对病害进行信息标注分类以建立数据集;基于无参SimAM注意力机制对小目标检测做出改进,提出了一种Cut_SimAM注意力机制,添加于主干网络中以提高对目标区域的关注度和小目标检测能力;基于C2f结构,在颈部网络引入C2f_EFAttention特征提取模块,优化特征融合过程,降低了参数量提高检测效率;使用Slide Loss滑动加权损失函数结合D-IoU边界框损失函数,加快模型收敛,提高了对困难样本的检测精度;采用多类别平均精度、参数量、计算量、检测帧率等指标,通过消融试验验证了各个模块对模型性能的影响,通过对比试验评价了改进算法相较于其他算法的检测精度和检测效率。试验结果表明:在采集到的雷达病害图谱数据集中,YOLOv8-CES的多类别平均精度达到了61.5%,相较于基线模型提高了3.6%,且参数量从3.0×106降低至2.5×106,每秒浮点运算次数从8.1 GFLOPs减少至7.1 GFLOPs,每秒检测帧数提高16.7%;改进后的模型对于道路隐性病害的识别与分类精度更高,且模型对于计算资源的需求量更低。YOLOv8-CES算法的高精度和轻量化设计使其更有利于嵌入三维探地雷达检测设备并实现实时检测,表明其在道路检测方面具有潜在应用价值。Abstract: To address the problems of small real data scale, difficulty in manual interpretation, and insufficient accuracy and efficiency of traditional algorithms in real-time detection of hidden road defects using three-dimensional ground penetrating radar (3D GPR), a lightweight improved algorithm based on the YOLOv8 algorithm YOLOv8-CES was proposed. Based on the collected 3D GPR images of hidden road defects, defect information was annotated and classified to establish a dataset. A Cut_SimAM attention mechanism was proposed based on the parameter-free SimAM attention mechanism to improve small target detection, and it was added to the backbone network to enhance focus on target regions and improve small object detection ability. Based on the C2f structure, a C2f_EFAttention feature extraction module was introduced into the neck network to optimize the feature fusion process, reduce the number of parameters, and improve detection efficiency. The Slide Loss sliding weighted loss function was used in combination with the D-IoU bounding box loss function to accelerate model convergence and improve detection accuracy for difficult samples. Ablation experiments were conducted to verify the effect of each module on model performance, using mean average precision (mAP), number of parameters, floating point operations per second (FLOPs), and frames per second (FPS) as indicators. The detection accuracy and efficiency of the improved algorithm compared with other algorithms were evaluated through comparative experiments. Test results show that in the collected 3D GPR image dataset of defects, the mAP of YOLOv8-CES reaches 61.5%, increasing by 3.6% compared with the baseline model. The number of parameters reduces from 3.0×106 to 2.5×106, and FLOPs reduces from 8.1 GFLOPs to 7.1 GFLOPs; FPS increases by 16.7%. The improved model achieves higher accuracy and lower computational demand in the recognition and classification of hidden road defects. The high accuracy and lightweight design of the YOLOv8-CES algorithm make it more suitable for embedding in 3D GPR detection devices and achieving real-time detection, indicating its potential application value in road detection.
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Key words:
- road engineering /
- defect detection /
- YOLOv8 /
- deep learning /
- ground penetrating radar /
- attention mechanism
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图 1 道路隐性病害雷达图谱数据集构建整体流程
Figure 1. Overall process of constructing radar image dataset for hidden road defects
图 7 具有剪切功能的Cut_SimAM网络结构
Figure 7. Network structure of Cut_SimAM with cutting function
图 13 改进算法的4类病害热力图对比
Figure 13. Comparison of heatmaps for four types of defects using improved algorithm
图 14 改进算法的4类病害预测结果
Figure 14. Prediction results for four types of defects using improved algorithm
图 15 YOLOv8-C与YOLOv8-CE训练细节对比
Figure 15. Comparison of training details between YOLOv8-C and YOLOv8-CE
表 1 Raptor-80车载式雷达技术参数
Table 1. Technical parameters of Raptor-80 vehicle-mounted radar
技术指标 天线中心频率/MHz 通道数 采样间距/cm 时窗/ns 驻留时间/μs 检测速度/(km·h-1) 技术参数 800 24 2.5~5.0 25~75 3 30 
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表 2 病害数据集分类
Table 2. Classification of defects dataset
病害类型 层间不良 层间含水 层间松散 结构松散 标注名称 poor_l water_l loose_l loose_s 病害数量/处 3 092 2 742 3 035 231 病害特征 水平方向有加强同相轴 呈“白-黑-白”条状分布 深度方向有加强同相轴 局部同相轴断裂起伏 特征图 
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表 3 试验环境配置
Table 3. Experimental environment configuration
环境配置 参数 操作系统 Windows 11 CPU Intel(R) Core(TM) i9-14900KF GPU NVIDIA GeForce RTX 4080 内存/GB 64 显存/GB 16 深度学习框架 PyTorch 2.3.1 编程语言 Python 3.8 CUDA 11.8
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表 4 消融试验设计
Table 4. Ablation experiment design
模型 SimAM Cut_SimAM EFAttention Slide Loss YOLOv8n YOLOv8-Sim √ YOLOv8-C √ YOLOv8-E √ YOLOv8-S √ YOLOv8-CE √ √ YOLOv8-CES √ √ √
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表 5 不同注意力机制对比试验
Table 5. Comparison of different attention mechanisms
% 注意力机制 召回率 精确率 mAP poor_l water_l loose_l loose_s YOLOv8n 59.6 52.0 56.8 61.2 65.8 49.7 50.3 EMA 52.6 53.1 54.2 60.6 66.3 42.3 48.3 CBAM 53.4 53.6 56.1 62.1 63.2 48.8 50.2 SENet 54.4 56.4 56.7 61.5 64.0 49.2 52.1 SimAM 54.7 58.8 57.9 60.9 65.2 50.1 55.5 Cut_SimAM 56.8 53.8 58.1 61.2 65.3 53.6 52.2 注:表中加粗数字为最优值,下同。
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表 6 YOLOv8-C与YOLOv8-CE测试集对比
Table 6. Comparison between YOLOv8-C and YOLOv8-CE test sets
模型 召回率/% 精确率/% mAP/% 参数量/106 检测帧率/FPS 计算量/GFLOPs YOLOv8-C 56.2 58.0 60.0 3.0 180.6 8.1 YOLOv8-CE 57.2 55.7 58.5 2.5 214.3 7.1
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表 7 不同边界框损失函数训练结果对比
Table 7. Comparison of training results for different bounding box loss functions
模型 召回率/% 精确率/% mAP/% poor_l/% water_l/% loose_l/% loose_s/% YOLOv8-CE 54.8 57.6 56.0 62.7 67.2 52.3 41.9 C-IoU 56.9 58.3 59.4 61.0 65.9 51.8 58.9 D-IoU 58.3 57.6 59.7 64.1 67.1 53.5 54.2 W-IoU 58.3 52.8 56.2 62.4 67.7 52.4 42.2 NWD 56.8 54.5 58.6 60.7 65.0 51.8 56.9 注:YOLOv8-CE表示未使用Slide Loss损失函数,C-IoU、D-IoU、W-IoU、NWD表示搭载了Slide Loss的YOLOv8-CE模型所用的边界框损失函数。
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表 8 测试集消融试验
Table 8. Ablation experiment on test sets
模型 召回率/% 精确率/% mAP/% 参数量/106 检测帧率/FPS 计算量/GFLOPs YOLOv8n 53.8 60.2 57.9 3.0 195.8 8.1 YOLOv8-Sim 56.8 61.1 59.2 3.0 180.1 8.1 YOLOv8-C 56.2 58.0 60.0 3.0 180.6 8.1 YOLOv8-E 56.2 58.7 57.4 2.5 225.9 7.1 YOLOv8-S 59.8 51.0 57.5 3.0 237.0 8.1 YOLOv8-CE 57.2 55.7 58.5 2.5 214.3 7.1 YOLOv8-CES 61.4 59.8 61.5 2.5 228.5 7.1
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表 9 不同算法对比
Table 9. Comparison of different algorithms
模型 召回率/% 精确率/% mAP/% 参数量/106 检测帧率/FPS 计算量/GFLOPs Faster R-CNN 60.8 58.8 53.7 41.4 13.2 134.5 SSD 58.2 57.1 56.3 26.5 51.7 60.6 YOLOv5 56.0 57.2 54.3 12.8 139.0 17.3 YOLOv7 56.5 54.3 55.1 17.3 156.8 18.8 YOLOv8m 60.4 50.6 56.2 25.9 130.5 10.3 YOLOv8s 57.1 54.7 58.2 11.1 177.6 8.2 YOLOv8n 53.8 60.2 57.9 3.0 195.8 8.1 YOLOv8-CES 61.4 59.8 61.5 2.5 228.5 7.1
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