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机场群共用航路点的航班排序模型及算法

王莉莉 林雍雅

王莉莉, 林雍雅. 机场群共用航路点的航班排序模型及算法[J]. 交通信息与安全, 2021, 39(5): 93-99,136. doi: 10.3963/j.jssn.1674-4861.2021.05.012
引用本文: 王莉莉, 林雍雅. 机场群共用航路点的航班排序模型及算法[J]. 交通信息与安全, 2021, 39(5): 93-99,136. doi: 10.3963/j.jssn.1674-4861.2021.05.012
WANG Lili, LIN Yongya. Aircraft Sequencing Modeling and Algorithm for Shared Waypoints in Airport Group[J]. Journal of Transport Information and Safety, 2021, 39(5): 93-99,136. doi: 10.3963/j.jssn.1674-4861.2021.05.012
Citation: WANG Lili, LIN Yongya. Aircraft Sequencing Modeling and Algorithm for Shared Waypoints in Airport Group[J]. Journal of Transport Information and Safety, 2021, 39(5): 93-99,136. doi: 10.3963/j.jssn.1674-4861.2021.05.012

机场群共用航路点的航班排序模型及算法

doi: 10.3963/j.jssn.1674-4861.2021.05.012
基金项目: 

国家自然科学基金委员会与中国民用航空局联合资助项目 U1633124

详细信息
    通讯作者:

    王莉莉(1973—),博士,教授.研究方向:空中交通流量管理、空域规划. E-mail:llwang@cauc.edu.cn

  • 中图分类号: U8

Aircraft Sequencing Modeling and Algorithm for Shared Waypoints in Airport Group

  • 摘要:

    机场群上空空域资源共享、运行耦合复杂,拥堵往往发生在共用航路点。为缓解空域拥堵和航班延误问题,开展了机场群共用航路点的优化排序研究。针对共用航路点的运行特征,引入惩罚因子并以总延误时间成本最小为优化目标,建立了机场群共用航路点的航班优化排序模型,基于滑动时间窗算法和粒子群优化算法的原理提出了TW-PSO组合优化算法对模型进行求解。选取京津冀机场群过共用航路点的航班进行算例仿真,结果表明:TW-PSO组合优化算法与FCFS算法、滑动时间窗算法、粒子群优化算法相比在高峰时段的总延误时间成本分别减少了216,212,161 min;在算法性能方面,具有比经典算法迭代次数少、优化效果更佳的优点,能有效缓解航班延误问题,改善机场群的协同运行效率。

     

  • 图  1  延误时间成本累积折线图

    Figure  1.  Cumulative line chart of the delay time cost

    图  2  通行量统计图

    Figure  2.  Statistics of traffic volume

    表  1  变量定义

    Table  1.   Variable definitions

    变量 含义
    A 机场群系统中的机场集合
    a 机场群系统中的机场,aA
    n 从各机场起飞过共用航路点的航班总数
    T 航班过共用航路点的时间段
    t 航班过共用航路点的时刻
    FaT T时间段内从机场a起飞过共用航路点的航班集合,FaT = {fa1, fa2,…,fan}
    fai T时间段内从机场a起飞过共用航路点的第i个航班(i = 1, 2,…,n)
    ETfai 过共用航路点的计划时刻
    STfai 过共用航路点的实际时刻
    PTfai 最早过共用航路点的时刻
    DTfai 最晚过共用航路点的时刻
    Cp 时间段内共用航路点的最大容量
    Ca 时间段内共用航路点所在扇区的最大容量
    Si,i+1 前后2个航班在共用航路点的安全间隔
    xfai (t) = {0, 1}
    xfai (t) xfai (t) = 1,即t时刻航班fai过共用航路点
    xfai (t) = 0,即t时刻航班fai不过共用航路点
    下载: 导出CSV

    表  2  算法优化结果对比

    Table  2.   Comparison of the results of optimized algorithms

    航班号 起飞机场 计划过点时刻 FCFS算法优化结果 滑动时间窗算法优化结果 粒子群优化算法优化结果 TW-PSO组合优化算法优化结果
    实际过点时刻 延误时间成本/min 实际过点时刻 延误时间成本/min 排序结果 实际过点时刻 延误时间成本/min 排序结果 实际过点时刻 延误时间成本/min 排序结果
    F1 B 09:02 09:02 0 09:02 0 1 08:57 -10 1 08:57 -10 1
    F2 T 09:05 09:05 0 09:05 0 2 09:00 -5 2 09:00 -5 2
    F3 B 09:06 09:07 3 09:07 3 3 09:26 60 13 09:02 -8 3
    F4 B 09:07 09:09 6 09:17 30 8 09:02 -10 3 09:12 15 8
    F5 D 09:09 09:11 6 09:09 0 4 09:04 -10 4 09:04 -10 4
    F6 S 09:10 09:13 9 09:11 3 5 09:30 60 15 09:06 -8 5
    F7 T 09:12 09:15 6 09:15 6 7 09:07 -5 5 09:10 -2 7
    F8 D 09:13 09:17 12 09:13 0 6 09:33 60 16 09:08 -10 6
    F9 B 09:14 09:19 15 09:27 39 13 09:09 -10 6 09:22 24 13
    F10 B 09:15 09:21 18 09:29 42 14 09:23 24 12 09:24 27 14
    F11 T 09:17 09:23 12 09:31 28 15 09:12 -5 7 09:26 18 15
    F12 S 09:18 09:25 14 09:33 30 16 09:38 40 18 09:28 20 16
    F13 B 09:19 09:27 24 09:19 0 9 09:14 -10 8 09:14 -10 9
    F14 B 09:21 09:29 24 09:21 0 10 09:16 -10 9 09:16 -10 10
    F15 S 09:23 09:31 16 09:23 0 11 09:43 40 20 09:18 -5 11
    F16 B 09:24 09:33 27 09:25 3 12 09:19 -10 10 09:20 -8 12
    F17 D 09:26 09:35 27 09:37 33 18 09:21 -10 11 09:32 18 18
    F18 B 09:30 09:37 21 09:39 27 19 09:35 15 17 09:34 12 19
    F19 S 09:33 09:39 12 09:41 16 20 09:28 -5 14 09:36 6 20
    F20 T 09:34 09:41 14 09:35 2 17 09:40 12 19 09:30 -4 17
    总延误时间成本/min 266 262 211 50
    下载: 导出CSV
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  • 收稿日期:  2021-04-14

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