An Analysis of the Impact of Time Delay of Fusion Modes for Point Clouds from Cooperative Road Vehicle Systems on Autonomous Driving
-
摘要: 新一代通信技术的快速发展为车路协同感知提供了基础,可进一步提升自动驾驶车辆在复杂场景中的感知能力,现有研究对不同的协同感知信息融合模式进行了探索,但忽略了对感知精度与通信时延平衡性的分析。针对自动驾驶协同感知中点云融合模式的时延特征,本文以前融合、特征融合、后融合3种模式为研究对象,提出了基于模拟仿真的时延影响分析框架。考虑通信时延引起的协同感知结果时滞性,利用扩展卡尔曼滤波算法对存在时延的协同感知结果进行预测性补偿,创新提出了滞后补偿误差和等效时延评价指标,用以综合评价不同融合模式对协同感知结果的影响;针对不同点云融合模式的感知结果,构建了平均感知精度与平移误差分布关系模型,依据目标检测平移误差的分布特征生成带有感知误差的仿真轨迹,进而对协同感知效果进行评估。结合TrajNet++行人轨迹数据集,以不同时延参数及点云融合模式,对1 200条轨迹进行了180 000次数值仿真。结果显示,感知目标的已知轨迹长度越短、速度越高,时延对协同感知精度的影响越大,以100 ms时延下后融合为基准,当特征融合时延在500 ms以内、前融合时延在700 ms以内时,可以达到相同或更高的协同感知精度。针对目标易突然出现且速度快的复杂场景,宜采用低时延、低精度的后融合模式,反之,宜采用具有高时延、高精度的特征融合或前融合模式。本研究可为自动驾驶协同感知的点云融合模式选择提供依据。Abstract: The rapid development of the new generation of communication technologies provides a foundation for cooperative perception between autonomous vehicles (AVs) and road. This advancement holds the potential to significantly enhance the perception capabilities of AVs in complex scenarios. Previous studies have explored different information fusion modes for cooperative perception, but neglected to analyze the balance between perception accuracy and communication delay. Aiming at the delay characteristics of point cloud fusion in cooperative perception of AVs, a delay impact analysis framework is proposed based on simulation, concentrating on three fusion modes: pre-fusion, feature fusion, and post-fusion. Considering the time lag of cooperative perception results caused by communication delay, the Extended Kalman Filter algorithm is used to make predictive compensation for cooperative perception results with delay. The novel metrics, namely Lag Compensation Error and equivalent time delay, are proposed for comprehensive evaluation of the impact of different fusion modes on cooperative perception results. Based on perception results from various point cloud fusion modes, a model is established to fit the relationship between average perception accuracy and translation error distribution. Utilizing the distribution characteristics of translation errors, this model serves as the basis for generating simulated trajectories with perception errors and subsequently the evaluating of cooperative perception performance. Finally, leveraging the TrajNet++ pedestrian trajectory dataset, 180 000 numerical simulations are conducted across 1 200 trajectories with various point cloud fusion modes and different delay parameters. The results demonstrate that the shorter trajectory lengths and the higher target speeds amplify the impact of delay on cooperative perception accuracy. In comparison to post-fusion with a 100 ms delay as the benchmark, the equivalent or superior cooperative perception accuracy is feasible when the feature-fusion delay is below 500 ms and the front-fusion delay is below 700 ms. In complex scenarios involving sudden target appearances or high-speed targets, it is recommended to choose low-delay, low-accuracy post-fusion modes. Conversely, it is advisable to consider feature fusion or pre-fusion modes with high delay and high accuracy. This study can provide a basis for the selection of point cloud fusion modes for cooperative perception of autonomous driving.
-
图 7 基于点云的目标检测平均精度与平均平移误差关系
Figure 7. Relationship between mean average precision and mean average translation error of object detection based on point cloud
图 8 不同融合模式和已知轨迹时长下的滞后补偿误差
Figure 8. LCE under different fusion modes and known trajectory duration
图 9 不同融合模式和目标速度时长下的滞后补偿误差
Figure 9. LCE under different fusion modes and object velocity
表 1 点云目标检测模型的平均精度和平均平移误差
Table 1. mean average precision and mean average translation error of object detection models based on point cloud
序号 平均精度LmAP 平均平移误差LmATE 1 0.723 9 0.236 6 2 0.697 2 0.237 0 3 0.674 0 0.254 6 4 0.681 5 0.255 8 5 0.671 5 0.248 8 6 0.668 0 0.253 1 7 0.668 0 0.253 5 8 0.662 8 0.240 3 9 0.666 9 0.254 2 10 0.665 9 0.272 6 
下载: 导出CSV
表 2 点云融合模式评价指标
Table 2. Evaluationindexes of point cloud fusion modes
点云融合模式 时延/ms 平均精度LmAP 前融合 高(100~1 000) 0.762 9 特征融合 中(50~200) 0.635 1 后融合 低(0~100) 0.489 9
下载: 导出CSV
表 3 仿真实验参数
Table 3. Simulation experiment parameters
单位: ms 参数 取值 取值步长 时延 100~1 000 100 点云融合模式 前融合、特征融合、后融合 无
下载: 导出CSV
-
[1] 许庆, 王嘉伟, 王建强, 等. 网联通信时延下的混合队列控制特性分析[J]. 交通信息与安全, 2021, 39(1): 128-136.XU Q, WANG J W, WANG J Q, et al. A performance analysis of mixed platoon control under communication delay[J]. Journal of Transport Information and Safety, 2021, 39(1): 128-136. (in Chinese) [2] 陈志军, 张晶明, 熊盛光, 等. 智能网联车辆生态驾驶研究现状及展望[J]. 交通信息与安全. 2022, 40(4): 13-25.CHEN Z J, ZHANG J M, XIONG S G, et al. A review on research status and trends of eco-driving on intelligent connected vehicles[J]. Journal of Transport Information and Safety, 2022, 40(4): 13-25. (in Chinese) [3] ARNOLD E, DIANATI M, DE TEMPLE R, et al. Cooperative perception for 3D object detection in driving scenarios using infrastructure sensors[J]. IEEE Transactions on Intelligent Transportation Systems, 2022, 23(3): 1852-1864. [4] ZHOU Y, TUZEL O. VoxelNet: End-to-end learning for point cloudbased 3D object detection[C]. IEEE Conference on Computer Vision and Pattern Recognition (CVPR), Salt Lake City, United States: IEEE, 2018. [5] LANG A H, VORA S, CAESAR H, et al. Pointpillars: Fast encoders for object detection from point clouds[C]. IEEE Conference on Computer Vision and Pattern Recognition (CVPR), Long Beach, United States: IEEE, 2019. [6] QI C R, SU H, MO K, et al. PointNet: Deep learning on point sets for 3D classification and segmentation[C]. IEEE Conference on Computer Vision and Pattern Recognition(CVPR), Honolulu, Hawaii, United States: IEEE, 2017. [7] LI Y, BU R, SUN M, et al. Pointcnn: Convolution on x-transformed points[J]. Advances in Neural Information Processing Systems, 2018(31): 828-838. [8] THOMA RS, ANDRICH C, GALDO G, et al. Cooperative passive coherent location: a promising 5G service to support road safety[J]. IEEE Communications Magazine, 2019, 57 (9): 86-92. [9] CHEN Q, TANG S, YANG Q, et al. Cooper: Cooperative perception for connected autonomous vehicles based on 3D point clouds[C]. 39th International Conference on Distributed Computing Systems, Dallas, United States: IEEE, 2019. [10] CHEN Q, MA X, TANG S, et al. F-Cooper: Feature based cooperative perception for autonomous vehicle edge computing system using 3D point clouds[C]. 4th ACM/IEEE Symposium on Edge Computing, Washington, D. C., United States: ACM/IEEE, 2019. [11] XU R, XIANG H, XIA X, et al. Opv2v: An open benchmark dataset and fusion pipeline for perception with vehicle-to-vehicle communication[C]. International Conference on Robotics and Automation(ICRA), Philadelphia, United States: IEEE, 2022. [12] XU R, TU Z, XIANG H, et al. CoBEVT: Cooperative bird's eye view semantic segmentation with sparse transformers[J]. ProceedingsofMachine Learning Research, 2023, 205: 989-1000. [13] XU R, XIANG H, TU Z, et al. V2x-vit: Vehicle-to-everything cooperative perception with vision transformer[C]. European Conference on Computer Vision, Tel Aviv, Israel: Springer, 2022. [14] TSUKADA M, OI T, ITO A, et al. AutoC2X: Open-source software to realize V2X cooperative perception among autonomous vehicles[C]. IEEE 92nd Vehicular Technology Conference, Victoria, BC, Canada: IEEE, 2020. [15] GHOSH A, MAEDER A, BAKER M, et al. 5G evolution: A view on 5G cellular technology beyond 3GPP release 15[J]. IEEE Access, 2019, 7: 127639-127651. [16] HARTLEY R, GHAFFARI M, EUSTICE R M, et al. Contact-aided invariant extended Kalman filtering for robot state estimation[J]. The International Journal of Robotics Research, 2020, 39(4): 402-430. [17] KOTHARI P, KREISS S, ALAHI A. Human trajectory forecasting in crowds: a deep learning perspective[J]. IEEE Transactions on Intelligent Transportation Systems, 2021, 23 (7): 7386-7400. [18] ZHAO C, SONG A, DU Y, et al. TrajGAT: A map-embedded graph attention network for real-time vehicle trajectory imputation of roadside perception[J]. Transportation Research Part C: Emerging Technologies, 2022, 142: 103787. [19] GUO J, CARRILLO D, TANG S, et al. CoFF: Cooperative spatial feature fusion for 3D object detection on autonomous vehicles[J]. IEEE Internet of Things Journal, 2021, 8(14): 11078-11087. [20] CAESAR H, BANKITI V, LANG AH, et al. Nuscenes: A multimodal dataset for autonomous driving[C]. IEEE Conference on Computer Vision and Pattern Recognition, Washington, D. C., United States: IEEE, 2020. -
点击查看大图
图(10) / 表(3)
计量
- 文章访问数: 400
- HTML全文浏览量: 180
- PDF下载量: 29
- 被引次数: 0