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基于RPCA的激光点云道路标牌几何信息提取方法

柯昀皓 黄玉春 吴梓健

柯昀皓, 黄玉春, 吴梓健. 基于RPCA的激光点云道路标牌几何信息提取方法[J]. 交通信息与安全, 2024, 42(2): 76-86. doi: 10.3963/j.jssn.1674-4861.2024.02.008
引用本文: 柯昀皓, 黄玉春, 吴梓健. 基于RPCA的激光点云道路标牌几何信息提取方法[J]. 交通信息与安全, 2024, 42(2): 76-86. doi: 10.3963/j.jssn.1674-4861.2024.02.008
KE Yunhao, HUANG Yuchun, WU Zijian. A Geometric Information Extraction Method of Road Signs in LiDAR Point Cloud Based on RPCA[J]. Journal of Transport Information and Safety, 2024, 42(2): 76-86. doi: 10.3963/j.jssn.1674-4861.2024.02.008
Citation: KE Yunhao, HUANG Yuchun, WU Zijian. A Geometric Information Extraction Method of Road Signs in LiDAR Point Cloud Based on RPCA[J]. Journal of Transport Information and Safety, 2024, 42(2): 76-86. doi: 10.3963/j.jssn.1674-4861.2024.02.008

基于RPCA的激光点云道路标牌几何信息提取方法

doi: 10.3963/j.jssn.1674-4861.2024.02.008
基金项目: 

国家自然科学基金项目 41671419

详细信息
    作者简介:

    柯昀皓(2002—),硕士研究生. 研究方向:激光点云分类方法. E-mail: 2019302130260@whu.edu.cn

    通讯作者:

    黄玉春(1977—),博士,教授. 研究方向:激光点云分类方法. E-mail: hycwhu@whu.edu.cn

  • 中图分类号: U491.5+2

A Geometric Information Extraction Method of Road Signs in LiDAR Point Cloud Based on RPCA

  • 摘要: 道路标牌的位置、尺寸等几何参数普查是交通资产管理、无人驾驶等应用的关键环节。车载激光扫描三维点云中路牌不仅占比小,而且受周围树木干扰大,导致边缘点云缺失且包含大量噪声。为了准确提取点云中标牌杆和平面的位置和几何信息,提出了两阶段杆状物点云分割方法,由粗及细提取出标牌杆及其相连的标牌平面点云簇;进而通过鲁棒主成分分析(robust principal component analysis,RPCA)排除标牌周围噪声和杂点干扰,结合点云簇形态分析得到独立的主杆体和标牌平面2个部件;再引入环状域生长拟合圆柱体,法向量投影采样与定向包围盒(oriented bounding box,OBB)紧致拟合标牌平面,分别得到主杆体和标牌的准确几何信息。实验采集了湖北省武汉市洪山区、高新区和武昌区34个不同路口下的激光点云数据,在KPConv点云分割网络下进行训练与验证,准确率达到90.31%,标牌精确度达到91.07%,召回率达到了92.74%;并对上述数据中的20个路口的98个道路标牌进行几何信息提取,有效提取率达到89.80%,位置精度达到0.062 1 m,几何误差达到8.07%。实验表明:该方法能有效排除点云噪声和杂点干扰,实现对点云缺失在20%以内的标牌的有效提取。

     

  • 图  1  道路标牌几何信息提取流程

    Figure  1.  Geometric information extraction process of road sign

    图  2  道路标牌点云提取流程

    Figure  2.  Point cloud extraction process of road signs

    图  3  道路标牌激光点云数据异常

    Figure  3.  Abnormal occurrence of road sign laser point cloud data

    图  4  点云鲁棒主成分分析示意

    Figure  4.  Robust principal component analysis of point cloud

    图  5  垂直度阈值对照试验

    Figure  5.  Verticality threshold control test

    图  6  基于RPCA点云形态信息的部件分割

    Figure  6.  Part segmentation based on RPCA point cloud morphology information

    图  7  道路标牌几何信息提取

    Figure  7.  Geometric information extraction of road signs

    图  8  道路标牌的点云姿态

    Figure  8.  Posture of the road signs point-cloud

    图  9  剩余部分点云的聚类合并

    Figure  9.  Clustering of the remaining point clouds

    图  10  圆形标牌与方形标牌

    Figure  10.  Round signs and square signs

    图  11  AABB式包围盒与OBB式包围盒

    Figure  11.  axis-aligned bounding box and oriented bounding box

    图  12  网格投影采样

    Figure  12.  Grid projection sampling of road signs

    图  13  点云采集设备

    Figure  13.  Sensor equipment of LiDAR

    图  14  数据集采集区域概览

    Figure  14.  Overview of the datasets and the region

    图  15  KPConv网络验证集的语义分割结果

    Figure  15.  Segmentation of KPConv network on validation set

    图  16  AGConv与KPConv具体分割效果对比

    Figure  16.  The comparison of AGConv and KPConv in segmentation effect

    图  17  道路标牌几何参数提取总流程

    Figure  17.  Process of extracting geometric parameters of road signs

    图  18  普通道路标牌几何信息提取结果与量测结果对比

    Figure  18.  Comparison of geometric information extraction results and measurement results of common road sign

    图  19  小型道路标牌几何信息提取结果与量测结果对比

    Figure  19.  Comparison of geometric information extraction results and measurement results of small road sign

    图  20  缺损圆形道路标牌几何信息提取结果与量测结果对比

    Figure  20.  Comparison of geometric information extraction results and measurement results of Defective round road sign

    表  1  几何信息提取数据集中标牌形态分布

    Table  1.   Morphological distribution of road signs in the dataset

    数据集 路口数 方形标牌数 圆形标牌数 标牌总数
    武昌区 6 14 6 20
    八一路 5 18 8 26
    高新区 9 31 21 52
    总计 20 63 35 98
    下载: 导出CSV

    表  2  标牌提取运行环境

    Table  2.   Operating environment of sign extraction

    项目 型号
      CPU 12th Gen Intel Core i5-12490F
      GPU NVIDIA GeForce RTX 4060Ti 16GB
      操作系统 Ubuntu 22.04
      Python 3.8
      CUDA 11.6
      cudnn 8.9.6
      Pytorch 1.13.1
    下载: 导出CSV

    表  3  混淆矩阵中的样例预测组合

    Table  3.   Sample predictions in the confusion matrix

    真实类型 预测类型
    背景点 杆状物 树木
      背景点 A B C
      杆状物 D E F
      树木 G H I
    下载: 导出CSV

    表  4  测试集下KPConv与AGConv的精度指标对比

    Table  4.   Evaluation of KPConv and AGConv on test set

    分割网络 准确度/% 精度/% 召回率/%
    标牌 树木 标牌 树木
    KPConv 90.31 91.07 81.50 92.74 99.26
    AGConv 90.34 77.54 82.39 95.57 98.67
    下载: 导出CSV

    表  5  道路标牌几何信息提取效果

    Table  5.   Geometric information extraction effect of road signs

    采集区域 路口数标牌数 位置精度/m 几何误差/% 有效提取率/% 总用时/s
    八一路1 2 9 0.082 3 10.91 88.89 1 016
    八一路2 3 17 0.072 1 10.20 88.23 4 284
    武昌区 6 20 0.053 4 6.31 90.00 5 179
    高新区 9 52 0.057 5 7.57 90.38 22 594
    汇总 20 98 0.062 1 8.07 89.80 33 073
    下载: 导出CSV

    表  6  道路标牌几何信息提取有效提取率对比

    Table  6.   Comparison of the effective extraction rate in geometric information extraction of road signs

    方法 有效提取率/%
    本文 89.80
    文献[12] 88.78
    文献[15] 85.71
    下载: 导出CSV

    表  7  点云缺失下道路标牌几何信息提取效果

    Table  7.   Geometric information extraction effect of road signs based on defective point cloud

    缺失程度 数据示例 精度
    完整 位置精度/m 0.046 1
    几何误差/% 4.70
    约5% 位置精度/m 0.059 5
    几何误差/% 7.39
    约10% 位置精度/m 0.082 1
    几何误差/% 11.07
    约20% 位置精度/m 0.096 4
    几何误差/% 15.80
    30%以上 位置精度/m 0.132 6
    几何误差/% 21.51
    下载: 导出CSV
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  • 收稿日期:  2023-10-24
  • 网络出版日期:  2024-09-14

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