超高速公路虚拟轨道模型的构建与验证研究

doi:10.3969/j.issn.1674-0696.2023.08.12

摘要/Abstract

摘要： 为提高超高速公路行驶安全性，用建立数学模型的方法研究了超高速公路虚拟轨道系统。该系统由信息采集子系统、信息处理子系统和信息反馈子系统组成。通过理论分析与信息采集子系统得到的数据，建立了直线路段和曲线路段上虚拟轨道偏离计算模型。利用计算模型得到了直线路段车辆偏离虚拟轨道安全范围时的预警信号值；曲线路段汽车驶离虚拟轨道安全范围所需时间及距离数据判断值。研究结果表明：当汽车行驶在超高速公路直线路段上时，理论距离与传感器检测距离的平方之差的绝对值小于1.85、2.78、3.70 m2时，就可保证车辆偏离中心线的距离分别小于0.50、0.75、1.00 m。当汽车行驶在曲线路段上时，汽车驶离虚拟轨道安全范围所需时间与行车速度、虚拟轨道安全范围以及曲线半径有关；偏离虚拟轨道的阈值分别取0.50、0.75、1.00 m，预警信号值为2、 3、 4 m时，可保证车辆不会驶离虚拟轨道安全阈值范围。因此，超高速公路虚拟轨道系统可将车辆限制在虚拟轨道安全范围内行驶，保证超高速公路行车的安全性。

关键词: 交通运输工程；超高速公路；虚拟轨道；车路协同；交通安全；自动驾驶

Abstract: In order to improve the driving safety of superhighways, the virtual track system of superhighways was studied by establishing mathematical models. The proposed system consisted of an information acquisition subsystem, an information processing subsystem and an information feedback subsystem. Through theoretical analysis and the data obtained by information acquisition subsystem, the virtual track deviation calculation models on straight and curved sections were established. The early warning signal values of vehicles deviating from the safety range of virtual track were obtained by using the calculation model. The estimated time and distance data required for vehicles to leave the virtual track safety range on the curved road sections were also obtained. The research results show that when the vehicle is driving on the straight section of superhighway, the absolute value of the square difference between the theoretical distance and the sensor detection distance is less than 1.85, 2.78 and 3.70 m2, the deviation distance of the vehicle from the centerline can be guaranteed to be less than 0.50, 0.75 and 1.00 m, respectively; when the vehicle is driving on the curved road section, the time required for the vehicle to leave the virtual track safety range is related to the driving speed, the virtual track safety range and the curve radius. When the threshold values of deviation from virtual track are 0.50 m, 0.75 m and 1.00 m respectively, as well as the early warning signal value is 2 m, 3 m and 4 m, it can be ensured that the vehicle does not exceed the virtual track safety threshold. Therefore, the virtual track system of the superhighway can limit the vehicles to travel within the safe range of the virtual track, ensuring the safety of the vehicle driving on the superhighway.

Key words: traffic and transportation engineering; superhighway; virtual track; vehicle-road coordination; traffic safety; autopilot

中图分类号:

U491

何永明1,2，冯佳1，权聪1,2，曹剑1，3,陈世升1,2. 超高速公路虚拟轨道模型的构建与验证研究[J]. 重庆交通大学学报（自然科学版）, 2023, 42(8): 77-85.

HE Yongming1,2, FENG Jia1, QUAN Cong1,2,CAO Jian1,3,CHEN Shisheng1,2. Construction and Verification of Superhighway Virtual Track Model[J]. Journal of Chongqing Jiaotong University(Natural Science), 2023, 42(8): 77-85.

参考文献

［1］ HE Y M, SONG Y T, PEI Y L, et al. Theoretical research on longitudinal profile design of superhighways ［J］. Journal of Advanced Transportation, 2020（1）: 1-14
［2］ HE Y M, KANG J, PEI Y L, et al. Research on influencing factors of fuel consumption on superhighway based on DEMATEL-ISM model ［J］. Energy Policy, 2021, 158:112545.
［3］刘展行. 超级高速公路设计初探［J］. 公路交通科技(应用技术版), 2018, 14(11): 260-262.
LIU Zhanhang. Preliminary study on superhighway design［J］.Journal of Highway and Transportation Research and Development (Application Technology Edition), 2018, 14(11): 260- 262.
［4］赵酉超, 毛红日, 刘江东. 超高速公路安全平曲线半径研究［J］. 西部交通科技, 2019(2): 159-163.
ZHAO Youchao, MAO Hongri, LIU Jiangdong. Research on safety flat-curve radius of superhighway ［J］. Western China Communi- cations Science & Technology, 2019 (2): 159-163.
［5］陈芬菲, 徐鹏. 基于SWOT分析法的超高速公路发展研究［J］. 科技视界, 2018(5): 139-140.
CHEN Fenfei, XU Peng. Research on superhighway development based on SWOT analysis ［J］. Science & Technology Vision, 2018 (5): 139-140.
［6］罗毅. 城市新型轨道交通发展的适应性研究——以四川省宜宾市为例［J］. 城市管理与科技, 2019, 21(2): 38-41.
LUO Yi. Study on adaptability of urban new rail transit development—A case study of Yibin City, Sichuan Province ［J］. Municipal Admini-stration and Technology, 2019, 21(2): 38-41.
［7］徐伟. 超级虚拟轨道快运系统（SRT）特点和适应性分析——以盐城市为例［J］. 工程技术研究, 2021, 6(5): 40-41，57.
XU Wei. Characteristics andadaptability analysis of super virtual rail express system (SRT): A case study of Yancheng city ［J］. Engineering and Technological Research, 2021, 6(5): 40-41，57.
［8］侯凯文. 基于虚拟轨道的自动驾驶车辆管控方法和系统研究［D］. 北京：北京交通大学, 2020.
HOU Kaiwen.Research on Method and System Management and Ccontrol for Autonomous Vehicles Based on Virtual Track ［D］. Beijing: Beijing Jiaotong University,2020.
［9］丁铁成, 林建辉, 杨岗, 等. 虚拟轨道列车综合舒适性评价研究［J］. 机车电传动, 2021(6): 18-24.
DING Tiecheng, LIN Jianhui, YANG Gang, et al. Research on comprehensive comfort evaluation of virtual train ［J］. Electric Drive for Locomotives, 2021(6): 18-24.
［10］花明磊. 虚拟轨道车辆广义综合舒适度研究［J］. 电子世界, 2021(15): 95-97.
HUA Minglei. Research on generalized comprehensive comfort of virtual rail vehicle ［J］. Electronics World, 2021(15): 95-97.
［11］柳慧鹏, 廖明军. 智慧虚拟轨道交通系统框架研究［J］. 数字通信世界, 2021(3): 67-68，116.
LIU Huipeng, LIAO Mingjun. Research on intelligent virtual rail transit system ［J］. Digital Communication World, 2021(3): 67- 68，116.
［12］曾厚铭, 车超, 解静, 等. 虚拟轨道列车循迹控制优化模型与仿真研究［J］. 计算机仿真, 2021, 38(7): 89-92，490.
ZENG Houming, CHE Chao, XIE Jing, et al. Research on optimized model and simulation ofvirtualorbit tramcar tracking control ［J］. Computer Simulation, 2021, 38(7): 89-92, 490.
［13］韩鹏. 基于虚拟轨道的自导向有轨电车控制策略研究［D］. 成都：西南交通大学, 2017.
HAN Peng.The Control Strategy of Self-guiding Tramcar Based on Virtual Track ［D］. Chengdu: Southwest Jiaotong University, 2017.
［14］孙帮成. 虚拟轨道列车及其关键技术研究［D］. 北京：北京交通大学, 2019.
SUN Bangcheng.Research on Virtual Rail Trian and Its Key Technologies ［D］. Beijing: Beijing Jiaotong University,2019.
［15］ HE Y M, PEI Y L, RAN B, et al. Superhighway virtual track system based on intelligent road buttons ［J］. IEEE Access, 2020, 8: 33419- 33427.
［16］ WANG C P, ZHANG J M, ZHOU H C, et al. Analysis of the running quality and road friendliness of the virtual track train in multiple running stages between stations ［J］. Journal of Mechanical Science and Technology, 2022, 36(2): 593-605.
［17］ ZHANG D H, YANG C J, ZHANG W H, et al. A novel tracking control method for the distributed-drive and active-steering articulated virtual rail train ［J］. Proceedings of the Institution of Mechanical Engineers, Part I: Journal of Systems and Control Engineering, 2022, 236(2): 418-440.
［18］ HAN P, ZHANG W H. The designation of a new kind of green streetcar based on virtual tracks and key technologies ［J］. Applied Mechanics and Materials, 2015, 741: 80-84.
［19］ YIN Z H, ZHANG J Y, LU H Y. Establishment and comparison of a spatial dynamics model for virtual track train with different steering modes ［J］. Proceedings of the Institution of Mechanical Engineers, Part K: Journal of Multi-body Dynamics, 2021, 235(3): 481-498.
［20］ CUI Hongmoing, PENG Anjin, SONG Pengyun, et al. Research on energy recovery method of virtual track train based on working conditions segmentation strategy ［J］. International Journal of Power and Energy Research, 2020，4(3): 34-35.
［21］方海洋. 基于GPS和激光雷达的无人驾驶策略研究［D］. 西安：长安大学, 2019.
FANG Haiyang.Research on Strategy of Driverless Car Based on GPS and Lidar ［D］. Xian: Changan University, 2019.
［22］许金良, 王恒, 赵利苹, 等. 考虑横风作用的公路平曲线最小半径研究［J］. 中国公路学报, 2014, 27(1): 38-43.
XU Jinliang, WANG Heng, ZHAO Liping, et al. Research on minimum radius of highway horizontal curve with crosswind considered ［J］. Chinese Journal of Highway and Transport, 2014, 27(1): 38-43.
［23］张玥. 基于横向力系数的公路平曲线半径及超高取值方法研究［J］. 中外公路, 2015, 35(2): 5-9.
ZHANG Yue. Study on highway curve radius and superelevation based on transverse force coefficient ［J］. Journal of China & Foreign Highway, 2015, 35(2): 5-9.

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