A Method of Identifying Collision Risk of Container Trucks in Port Terminal Areas under an Integrated Connected Vehicle BSM and Roadside Video Surveillance Data
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摘要: 大型港口集装箱码头运输车辆调度频繁,堆场过道和交换区等区域视距狭窄,容易导致港口集装箱卡车与设施、作业人员和车辆发生擦碰事故。为提高智能集装箱卡车在港口密集区域的轨迹跟踪精度和行车安全感知能力,提出了一种车联网条件下融合车载终端基本安全消息(Basic Safety Messages,BSM)数据和路侧视频数据的集装箱卡车碰撞风险辨识方法。采用YOLOv5s算法提取视频监控范围内的目标车辆和作业人员,根据目标集卡大尺寸特点设计非极大值抑制锚框来提高目标识别准确度。运用透视变换原理将目标像素坐标转换成地理坐标,并应用Deep-SORT算法匹配每帧图像的车辆轨迹信息。应用交互式多模型方法(interactive multi-model,IMM)融合视频轨迹信息和车载单元(on-board units,OBU)定位数据,减小了目标机动过程中的观测误差。基于集卡融合轨迹结果,提出了1种新型的轨迹冲突风险评估模型,能够根据目标集卡与周围目标轨迹的相对运动状态实时感知车辆碰撞危险,该碰撞危险检测结果在实际场景中可通过路侧设备对车载终端和作业人员终端实时播发预警信息。针对集卡跟踪误差的实验结果表明:IMM自适应跟踪轨迹的平均均方根误差为0.29 m,比集卡自主跟踪轨迹误差提升81.05%;融合路侧监控视频与车载终端定位数据能够克服车辆自主定位系统在密集堆场环境下的误差增大问题。集卡碰撞危险辨识的结果表明:车辆碰撞危险识别结果(预设ETTC阈值为2 s)的召回率、精确度和准确度相对集卡自主感知分别提升了7.39%,4.27%,2.50%,更准确地辨识出了视线遮挡情况下的轨迹冲突风险。Abstract: Large container terminals involve high-frequency transportation activities, and limited visibility in areas of stack aisles and exchange zones may easily lead to crashes between port container trucks and facilities, operators, and other vehicles. To improve the trajectory tracking accuracy and driving safety perception ability of intelligent container trucks in the densely populated port areas, a method for identifying container truck collision risks by integrating Connected Vehicle Basic Safety Messages (BSM) and roadside video surveillance data is proposed. A YOLOv5s algorithm is used to extract target vehicles and operators within the video surveillance, and a non-maximum suppression anchor box is designed based on the large size characteristics of the target container to improve detection accuracy. A perspective transformation principle is used to convert the target pixel coordinates into geographical coordinates, and a Deep-SORT algorithm is applied to match the vehicle trajectory information of each frame image. An interactive multi-model method (IMM) is used to fuse video trajectory information and vehicle positioning data of on-board units (OBU), reducing observation errors during target maneuvering process. Based on the trajectory fusion results, a new trajectory conflict risk assessment model is proposed, which can monitor vehicle collision risks in real-time according to the relative motion state of the target container and surrounding target trajectories. The detection of the collision risk can be broadcasted in real-time to on-board terminals and operator terminals through roadside equipment under most of practical scenarios. Experimental results show that the Root Mean Square Error (RMSE) of the IMM adaptive tracking method is only 0.29 m, which is 81.05% lower than that of the on-board tracking trajectory. It verifies that fusing roadside surveillance video with vehicle BSM positioning data can overcome the problem of increased errors from the on-board positioning systems under the dense stack environments. Study results also show that the recall rate, precision, and accuracy of collision risk identification results (with a pre-set ETTC threshold of 2 s) is improved by 7.39%, 4.27%, and 2.50%, respectively. The results indicate that the proposed method can more accurately identify collision risks in cases of obstructed visibility, when compared to the previous methods only using on-board detection techniques.
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表 1 不同YOLO版本性能对比
Table 1. Performance comparison of different YOLO versions
模型 图像尺寸px×px/ 数据集 平均精确度/% 帧/s 时间/(s/帧) YOLOv1 448×448 VOC2012 53.4 45 0.02 YOLOv2 544×544 VOC2012 49.0 40 0.03 YOLOv3 608×608 VOC2012 57.9 20 0.05 YOLOv4 608×608 VOC2012 69.7 62 0.02 YOLOv5s 640×640 VOC2012 75.4 140 0.01 
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表 2 集卡位置均方根误差均值
Table 2. Average RMSE of container truck positions
单位: m 跟踪方式 X坐标位置RMSE Y坐标位置RMSE 平均RMSE 集卡自主跟踪 1.59 1.47 1.53 IMM自适应跟踪 0.31 0.26 0.29
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表 3 碰撞危险辨识结果
Table 3. The results of crash risk identification
单位: % 感知方式 召回率 精确度 准确度 集卡自主感知 73.25 66.34 88.07 IMM自适应感知 78.66 69.17 90.27
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