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Detection of Common Underground Targets in Ground Penetrating Radar Images using the GDS-YOLOv8n model
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摘要: 针对当前探地雷达(GPR)图像检测中存在准确率低、误检和漏检等问题,该文提出了一种GPR常见地下目标检测模型GDS-YOLOv8n。该模型首先使用DRRB特征提取模块替换YOLOv8n模型中的部分C2f模块,旨在增强模型对多尺度特征的提取能力。其次使用SPD-Conv下采样模块替换像素为320×320及以下特征图所对应的Conv模块,有效克服分辨率受限以及存在小目标的GPR图像在下采样过程中的信息损失问题;同时利用辅助训练模块,在不增加检测阶段模型复杂度的前提下提升GPR图像的检测性能。最后,引入Inner-SIoU损失函数,在添加新约束条件的基础上,通过比例因子生成适合于当前GPR图像的辅助边界框,以提高预测框的准确性。实验结果表明,GDS-YOLOv8n模型对金属管、PVC管和电缆线等6类常见地下目标在实测GPR图像数据集上的P, R和mAP50分别为97.1%, 96.2%和96.9%,较YOLOv8n模型分别提高了4.0%, 6.1%和4.1%,尤其对PVC管和电缆线目标的检测效果提升更明显。与YOLOv5n, YOLOv7-tiny和SSD等模型相比,其mAP50分别提高了7.20%, 5.70%和14.48%。此外,将GDS-YOLOv8n模型部署到NVIDIA Jetson Orin NX嵌入式设备上,并使用TensorRT进行优化。经FP16量化后,模型的检测速度由22.0FPS提高到40.6FPS,能够满足移动场景下GPR地下目标实时探测任务的需求。Abstract: Ground Penetrating Radar (GPR) image detection currently faces challenges such as low accuracy, false detections, and missed detections. To overcome these challenges, we propose a novel model referred to as GDS-YOLOv8n for detecting common underground targets in GPR images. The model incorporates the DRRB (Dilated Residual Reparam Block) feature extraction module to achieve enhanced multiscale feature extraction, with certain C2f modules in the YOLOv8n architecture being effectively replaced. In addition, the space-to-depth Conv downsampling module is used to replace the Conv modules corresponding to feature maps with a resolution of 320×320 pixels and less. This replacement assists in mitigating information loss during the downsampling of GPR images, particularly for images with limited resolution and small targets. Furthermore, the detection performance is enhanced using an auxiliary training module, ensuring performance improvement without increasing inference complexity. The introduction of the Inner-SIoU loss function refines bounding box predictions by imposing new constraints tailored to GPR image characteristics. Experimental results on real-world GPR datasets demonstrate the effectiveness of the GDS-YOLOv8n model. For six classes of common underground targets, including metal pipes, PVC pipes, and cables, the model achieves a precision of 97.1%, recall of 96.2%, and mean average precision at 50% IoU (mAP50) of 96.9%. These results indicate improvements of 4.0%, 6.1%, and 4.1%, respectively, compared to corresponding values of the YOLOv8n model, with notable improvements observed when detecting PVC pipes and cables. Compared with those of models such as YOLOv5n, YOLOv7-tiny, and SSD (single shot multibox detector), our model’s mAP50 is improved by 7.20%, 5.70%, and 14.48%, respectively. Finally, the application of our model on a NVIDIA Jetson Orin NX embedded system results in an increase in the detection speed from 22 to 40.6 fps after optimization via TensorRT and FP16 quantization, meeting the demands for the real-time detection of underground targets in mobile scenarios.
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图 12 测试集上YOLOv8n模型的精确度-召回率曲线
Figure 12. P-R curve of YOLOv8n model on the test dataset
图 13 测试集上GSD-YOLOv8n模型的精确度-召回率曲线
Figure 13. P-R curve of GSD-YOLOv8n model on the test dataset
表 1 DRB模块参数
Table 1. DRB module parameter
size k d 5 3, 3 1, 2 7 5, 5, 3 1, 2, 3 9 5, 5, 3, 3 1, 2, 3, 4 11 5, 5, 3, 3, 3 1, 2, 3, 4, 5 13 5, 7, 3, 3, 3 1, 2, 3, 4, 5 
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表 2 DRRB模块性能对比
Table 2. DRRB module performance comparison
20×20 40×40 Params (Million) mAP50 (%) (5,7) (7,9) 2.69 93.9 (5,7) (9,11) 2.699 94 (7,9) (9,11) 2.706 95.3 (7,9) (11,13) 2.717 94.8 (9,11) (11,13) 2.727 94.1 注:(x, y)表示使用尺寸为x和y的DRB模块。
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表 3 模型训练参数设置
Table 3. Model Training Parameter Settings
参数名称 参数设置 迭代次数 300 批大小 16 早停机制 50 初始学习率 0.01 最终学习率 0.0001 动量 0.937 优化器权重衰减 0.0005 优化器 auto 注:优化器参数设置auto时,自动选择AdamW优化器。
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表 4 算法改进前后P, R值对比
Table 4. Comparison of P and R values before and after algorithm improvement
检测目标 性能指标 YOLOv8n GDS-YOLOv8n 金属管 P(%) 95.5 96.3 R(%) 82.1 87.2 PVC管 P(%) 93.4 97.5 R(%) 83.2 98.3 电缆线 P(%) 100 100 R(%) 85.1 100 含水塑料瓶 P(%) 93.2 100 R(%) 95.3 100 注浆不密实加固体空洞 P(%) 97.4 97.7 R(%) 96.5 93 管网 P(%) 79.5 91.2 R(%) 98.4 98.4 总计 P(%) 93.1 97.1 R(%) 90.1 96.2 注:加粗数字表示最优值。
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表 5 消融实验结果
Table 5. Results of ablation experiments
实验 模型 P (%) R (%) mAP50 (%) mAP50:95 (%) 1 YOLOv8n 93.1 90.1 92.8 60.7 2 YOLOv8n+A 95.1 93.2 95.3 63.4 3 YOLOv8n+B 94.6 92.6 94.4 61.3 4 YOLOv8n+C 96.5 91.3 94.7 61.9 5 YOLOv8n+D(ratio=1.29) 95.2 92 94.3 61.8 6 YOLOv8n+A+B 96.4 94.5 96 64 7 YOLOv8n+A+B+C 96.8 94.4 96.5 64.2 8 YOLOv8n+A+B+C+L(ratio=1.28) 97.1 96.2 96.9 64.3 注:加粗数字表示最优值,ratio是Inner-SIoU中的比例因子。
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表 6 对比实验结果
Table 6. Results of comparison experiments
模型 Params(Million) GFLOPs Model Size(MB) P (%) R (%) mAP50 (%) mAP50:90 (%) FPS (bs=1) SSD* 24.28 176.23 93.1 84.03 81.86 82.42 48.3 35.2 YOLOv5n 1.77 4.2 3.68 89.3 86 89.7 61.1 129.9 YOLOv5s 7.03 15.8 13.7 90.7 90.4 92.3 62.8 123.5 YOLOv7-tiny 6.03 13.1 11.7 91.9 92.6 91.2 57.6 80.0 YOLOv8n 3.01 8.1 5.94 93.1 90.1 92.8 60.7 109.9 YOLOv8s 11.13 28.4 21.4 94.7 90.7 93.7 62.0 103.1 YOLOv8m 25.8 78.7 49.5 94.1 96.3 96.7 63.3 55.6 GDS-YOLOv8n 4.43 11.2 10.3 97.1 96.2 96.9 64.3 97.2 注:加粗数字表示最优值;bs=1表示 batch size取1时的值;$* $表示输入图片尺寸是512×512。
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表 7 GDS-YOLOv8n模型部署格式性能对比
Table 7. Performance comparison of GDS-YOLOv8n model deployment formats
模型 Model Size
(MB)mAP50
(%)FPS
(bs=1)GDS-YOLOv8n.pt 10.3 96.9 22 GDS-YOLOv8n.onnx 17.1 96.9 6.5 GDS-YOLOv8n.engine(FP32) 19.1 96.9 31.4 GDS-YOLOv8n.engine(FP16) 10.7 96.9 40.6 GDS-YOLOv8n.engine(INT8) 5.6 84.1 46 注:FP32, FP16和INT8分别表示以32位、16位浮点数和8位整数量化模型。
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