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考虑旅客到达准时性的城市值机移动站点动态分布模型

张铭霞 周航 胡小兵

张铭霞, 周航, 胡小兵. 考虑旅客到达准时性的城市值机移动站点动态分布模型[J]. 交通信息与安全, 2023, 41(5): 167-175. doi: 10.3963/j.jssn.1674-4861.2023.05.017
引用本文: 张铭霞, 周航, 胡小兵. 考虑旅客到达准时性的城市值机移动站点动态分布模型[J]. 交通信息与安全, 2023, 41(5): 167-175. doi: 10.3963/j.jssn.1674-4861.2023.05.017
ZHANG Mingxia, ZHOU Hang, HU Xiaobing. A Dynamic Distribution Model of Urban Mobile Stations Considering Passengers' Arrival Punctuality[J]. Journal of Transport Information and Safety, 2023, 41(5): 167-175. doi: 10.3963/j.jssn.1674-4861.2023.05.017
Citation: ZHANG Mingxia, ZHOU Hang, HU Xiaobing. A Dynamic Distribution Model of Urban Mobile Stations Considering Passengers' Arrival Punctuality[J]. Journal of Transport Information and Safety, 2023, 41(5): 167-175. doi: 10.3963/j.jssn.1674-4861.2023.05.017

考虑旅客到达准时性的城市值机移动站点动态分布模型

doi: 10.3963/j.jssn.1674-4861.2023.05.017
基金项目: 

中央高校基本科研业务费中国民航大学专项 2000530441

详细信息
    作者简介:

    张铭霞(1998—),硕士研究生. 研究方向:空管智能决策. E-mail:Zhang_mx0502@163.com

    通讯作者:

    周航(1990—),博士,讲师. 研究方向:计算智能,空管智能决策,计算电磁学. E-mail:h-zhou@cauc.edu.cn

  • 中图分类号: U121

A Dynamic Distribution Model of Urban Mobile Stations Considering Passengers' Arrival Punctuality

  • 摘要: 现有城市值机移动服务站点设施分布模型在优化中未考虑旅客到达服务站点的时间不确定性,其优化结果通常与实际情况存在差异,导致无法对提前或延误到达的旅客进行服务。为解决时间不确定性对优化求解造成的不利影响,研究基于旅客准时性概率函数的动态设施分布模型。针对城市值机移动服务站点布局优化问题,构建完整的数学模型,并提出动态设施分布的优化评价指标。采用正态分布型旅客准时性概率函数,用以预估旅客实际到站时间与申报到站时间的差异。基于不同服务时段客源点的位置分布,采用涟漪扩散算法和遗传算法优化服务站点位置并计算所有旅客与站点间的最优路径。基于天津市路网和旅客分布的真实数据,对旅客准时到站和考虑旅客到站时间不确定2种场景进行仿真对比实验。结果表明:旅客到站时间概率模型优化结果优于旅客准时到站模型,动态设施分布评价指标提升4.31%。其中,旅客到达站点的平均路径长度减少0.35%,旅客可接受距离总超出量减少6.26%,站点服务容量总超出量减少4.13%。旅客到站时间概率模型能够充分考虑到站时间不确定性,并基于旅客实际到站时间更好地优化设施布局。基于旅客准时性概率函数的城市值机移动服务站点动态分布模型具有可移植性,可应用于物流服务的动态选址等问题。

     

  • 图  1  城市值机移动服务站点(UMS)示意图

    Figure  1.  Schematic diagram of urban mobile station mode(UMS)

    图  2  UMS系统运行流程图(以07:00—09:00为例)

    Figure  2.  UMS system operation flow chart(take 07:00—09:00 as a case study)

    图  3  基于正态分布的旅客到站时间概率密度函数

    Figure  3.  Probability density function of passenger arrival time based on normal distribution

    图  4  4组旅客到站时间概率密度分布示意图

    Figure  4.  Schematic diagram of probability density distribution of arrival time of four groups of passengers

    图  5  旅客准时到站模型3个时段路网权重示意图

    Figure  5.  Schematic diagram of road network weight in three periods of passenger punctual arrival model

    图  6  旅客到站时间概率模型3个时段路网权重示意图

    Figure  6.  Schematic diagram of road network weight in three periods of passenger arrival time probability model

    图  7  RSA的路径优化过程

    Figure  7.  Path Optimization Process of RSA

    图  8  旅客准时到站模型05:00—11:00等3个时段位置信息图

    Figure  8.  Location information diagram of 05:00—11:00 position information diagram for three time periods

    图  9  旅客到站时间概率模型05:00—11:00共3个时段位置信息图

    Figure  9.  Passenger arrival time probability model 05:00—11:00 position information diagram for three time periods

    表  1  旅客准时到站模型100次测试结果

    Table  1.   100 test results of passenger punctual arrival model

    时段 G G1/km G2/km G3/(人·次)
    05:00—07:00 20.42 3.32 11.7 5.4
    07:00—09:00 130 3.16 20.67 106.17
    09:00—11:00 104.31 3.04 10.4 90.87
    11:00—13:00 80.42 3.22 12.6 64.6
    13:00—15:00 47.33 3.14 7.26 36.93
    15:00—17:00 51.96 3.19 12.67 36.1
    17:00—19:00 66.93 2.73 9.77 54.43
    19:00—21:00 6.05 2.92 3.13 0
    平均 63.43 3.09 11.02 49.31
    下载: 导出CSV

    表  2  旅客到站时间概率模型100次测试结果

    Table  2.   100 test results of passenger arrival time probability model

    时段 G G1/km G2/km G3/(人·次)
    05:00—07:00 17.51 3.28 9.53 4.7
    07:00—09:00 120.67 3.13 17.27 100.27
    09:00—11:00 103.14 3.07 12.07 88
    11:00—13:00 78.26 3.19 12.6 62.47
    13:00—15:00 48.39 3.09 6.77 38.53
    15:00—17:00 50.86 3.03 11.9 35.93
    17:00—19:00 60.7 2.84 9.63 48.23
    19:00—21:00 5.91 3.01 2.9 0
    平均 60.69 3.08 10.33 47.27
    下载: 导出CSV

    表  3  动态设施分布模型评价指标有优化率

    Table  3.   Optimization rate of evaluation index of dynamic facility distribution model

    类型 优化率/%
    G G1 G2 G3
    动态设施分布模型评价指标 4.31 0.35 6.26 4.13
    下载: 导出CSV
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  • 收稿日期:  2023-03-12
  • 网络出版日期:  2024-01-18

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