基于时空网络的大面积航班延误传播预测与评估方法

屈景怡; 邢佳龙; 王锦峰; 杨俊

doi:10.3963/j.jssn.1674-4861.2025.04.015

基于时空网络的大面积航班延误传播预测与评估方法

doi: 10.3963/j.jssn.1674-4861.2025.04.015

1.
中国民航大学天津市智能信号与图像处理重点实验室天津 300300
2.
中国民用航空华东地区空中交通管理局山东空管分局济南 250100

基金项目:

国家自然科学基金重点项目 U2133205

天津市教委科研计划重点项目 2022ZD006

详细信息

通讯作者:
屈景怡(1978—)，博士，教授. 研究方向：大数据与人工智能、空管自动化等. E-mail: qujingyicauc@163.com

中图分类号: TP183
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出版历程
- 收稿日期: 2025-02-27

Prediction and Evaluation Methods for Large-Scale Flight Delay Propagation Based on Spatiotemporal Network

1.
Tianjin Key Laboratory of Advanced Signal Processing, Civil Aviation University of China, Tianjin 300300, China
2.
Shandong Air Traffic Management Sub-Bureau, East Regional Administration of Civil Aviation of China, Jinan 250100, China

摘要

摘要: 针对航班运行在时空维度上的高度耦合性所引发的大面积延误在多机场间传播问题，采用动态网络分析方法，深入探究空中交通延误的传播规律。为精准捕捉延误传播动态，构建了1个以机场为节点、以离港航班为边、5 min为时间分辨率的时空网络。在航班延误时空图的构建过程中，将边的权重从直接采用延误时间的统计平均值或通过简单的经验规则估算，改进为基于深度学习预测得到的权重。针对航班延误预测任务，研究利用多任务学习的NR-DenseNet模型，同时预测航班延误时间(回归)与是否延误(分类)，提升了权重的准确性和实时性。通过对比不同网络深度的性能，实验表明：16层NR-DenseNet在双任务中表现最优，其回归预测的均方误差(mean squared error，MSE)和平均绝对误差(mean absolute error，MAE)分别达到58.30和3.28，分类准确率提升至94.8%。在指标度量方面，研究发现单一指标难以全面评估空中交通延误传播的复杂性，因此构建了3个评估指标：强度、传播率和速度，以定量分析延误传播的多维度特征。以华东空管局提供的国内数据为研究对象，结果表明：本文方法能有效阐明空中交通在计划航班时刻表上大面积延误传播的时空细节。
- 空中交通管理 /
- 延误传播预测 /
- 时空网络 /
- 深度学习 /
- 传播特性指标
Abstract: The highly coupled nature of flight operations in spatial and temporal dimensions leads to the widespread propagation of large-scale delays across multiple airports. This issue is addressed through using dynamic network analysis to explore the patterns of air traffic delay propagation. To accurately capture the dynamics of delay spread, a spatiotemporal network is constructed where airports are nodes, departing flights are edges, and a temporal resolu-tion is 5 min. In constructing the flight delay spatiotemporal graph, edge weights are improved. Initially estimated using statistical averages of delay times or simple empirical rules, the weights are predicted via deep learning. For the flight delay prediction task, a multi-task NR-DenseNet model is employed to simultaneously predict flight delay duration (regression) and delay occurrence (classification), enhancing the accuracy and timeliness of the weights. By comparing performances across different network depths, experiments demonstrated that a 16-layer NR-DenseNet achieved optimal performance in both tasks. The regression prediction yielding a mean squared error (MSE) of 58.30 and a mean absolute error (MAE) of 3.28, while classification accuracy reached 94.8%. Regarding metric evaluation, single metrics are found to be insufficient for fully assessing the complexity of air traffic delay propagation. Therefore, three evaluation metrics, intensity, propagation rate, and velocity, are established to quantita-tively analyze the multidimensional characteristics of delay spread. Using domestic data from the East China Air Traffic Management Bureau as the study, the results indicated that the proposed method effectively reveals the spa-tiotemporal details of large-scale delay propagation within the scheduled flight timetable.
- air traffic management /
- delay propagation prediction /
- spatiotemporal network /
- deep learning /
- delay propagation metrics

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图 1 时空网络构建

Figure 1. Spatiotemporal network construction

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图 2 NR-DenseNet权重模型

Figure 2. NR-DenseNet weight model

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图 3 NR-DenseNet网络结构

Figure 3. NR-DenseNet network architecture

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图 4 2018年42个机场的航班数据延误统计

Figure 4. Statistics on flight delays at 42 airports in 2018

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图 5 2018年8月每天的延误航班数量

Figure 5. Daily number of delayed flights in august 2018

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图 6 权重模型预测结果

Figure 6. Prediction results of the weighted model

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图 7 24 h内延误航班的分类准确率

Figure 7. Classification accuracy of delayed flights within 24 hours

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图 8 延误强度

Figure 8. Delay intensity

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图 9 延误传播率

Figure 9. Delay propagation rate

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图 10 延误传播速度

Figure 10. Delay propagation speed

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表 1 42个机场基本信息

Table 1. Basic information for 42 airports

机场	城市	航班量
ZBAA	北京市	212 553
ZGGG	广州市	167 676
ZGSZ	深圳市	144 139
ZUUU	成都市	133 813
ZLXY	咸阳市	129 282
ZSSS	上海市	124 940
ZUCK	重庆市	123 735
ZSPD	上海市	120 399
ZSHC	杭州市	120 004
ZPPP	昆明市	116 685
ZSNJ	南京市	97 186
ZHCC	郑州市	88 120
ZHHH	武汉市	79 714
ZSAM	厦门市	79 060
ZGHA	长沙市	78 343
ZSQD	青岛市	77 458
ZBTJ	天津市	68 747
ZJHK	海口市	68 354
ZWWW	乌鲁木齐	66 971
ZYHB	哈尔滨	58 068
ZSJN	济南市	57 917
ZYTL	大连市	56 714
ZYTX	沈阳市	56 203
ZJSY	三亚市	54 555
ZGNN	南宁市	51 595
ZBYN	太原市	50 070
ZSCN	南昌市	48 435
ZLLL	兰州市	46 182
ZSFZ	福州市	45 531
ZSOF	合肥市	41 315
ZYCC	长春市	40 677
ZGSD	珠海市	40 322
ZSWZ	温州市	39 408
ZSNB	宁波市	36 984
ZBSJ	石家庄	35 157
ZLIC	银川市	34 747
ZGKL	桂林市	34 184
ZLXN	海东市	27 392
ZGOW	揭阳市	23 679
ZGZJ	湛江市	11 663
ZWAK	阿克苏	5 692
ZBLA	呼伦贝尔	5 317

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表 2 特征属性

Table 2. Feature attributes

特征属性	特征含义
CRSDepTime	航班计划起飞的时间
CRSDepTime	航班计划降落的时间
CRSArrTime	航班实际起飞的时间
REALDepTime	航班实际降落的时间
REALArrTime	航班计划起飞的机场
PlanOriginAirport	航班实际起飞的机场
OriginAirport	航班计划降落的机场
PlanDestAirport	航班实际降落的机场
DestAirport	航班号
FlightNum	计划机型
PlanAircraft	巡航速度
CruSpeed	巡航高度
CruAltitude	任务类型
TaskType	保障等级
GuaranteeLevel	预计航路
EstimatedRoute	气象数据记录时间
Record_time	温度
TP	露点温度
DT	道面温度
PRE	风速2 min最小值
WS_2_MIN	风速2 min平均值
WS_2_AVG	风速2 min最大值
WS_2_MAX	风速10 min最小值
WS_10_MIN	风速10 min平均值
WS_10_AVG	风速10 min最大值
WS_10_MAX	相对湿度
RD	场压
FP	修正海压
CSP	降雨量
RAIN	能见度1 min平均值
VIS_1_AVG	能见度10 min平均值
VIS_10_AVG	跑道视程1 min最小值
RVR_1_MIN	跑道视程1 min平均值
RVR_1_AVG	跑道视程1 min最大值
RVR_1_MAX	跑道视程10 min最小值
RVR_10_MIN	跑道视程10 min平均值
RVR_10_AVG	跑道视程10 min平均值
RVR_10_MAX	跑道视程10 min最大值
MOR_1_AVG	气象光学视程1 min平均值
MOR_10_MIN	气象光学视程10 min最小值
MOR_10_AVG	气象光学视程10 min平均值
MOR_10_MAX	气象光学视程10 min最大值
BGB_1_AVG	背景亮度1 min平均值

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表 3 超参数配置

Table 3. Hyperparameter configuration

主要参数	参数值
损失函数	均方误差，交叉熵
学习率	0.001
优化器	SGD
最大迭代次数	400
损失权重分配	$\left[\alpha_{M S E}, \alpha_{A C C}\right]$
批处理量	1 024
隐藏层层数	10/13/16/19

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表 4 不同网络层数的预测结果

Table 4. Prediction results for different numbers of network layers

任务	评价指标	NR-DenseNet预测模型
任务	评价指标	L=10	L=13	L=16	L=19
	MSE	348.90	128.49	58.30	81.20
回归	MAE	11.16	5.99	3.28	3.79
	R²	0.902 3	0.964 0	0.978 7	0.967 3
	ACC	0.818 1	0.903 6	0.948 0	0.933 7
分类	P	0.819 8	0.904 2	0.947 9	0.933 9
	F₁	0.818 1	0.903 6	0.948 0	0.933 8

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表 5 损失函数权值分配

Table 5. Loss function weight allocation

权重设置	MSE	MAE	R²	ACC	P	F₁
^{[1, 1]}	63.36	3.88	0.972	0.938	0.938	0.938
[1, 0.75]	58.30	3.28	0.978	0.948	0.947	0.947
[1.25, 0.85]	69.68	3.38	0.973	0.946	0.946	0.946
[1.5, 0.85]	58.89	3.44	0.974	0.947	0.947	0.947

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表 6 不同模型预测结果对比

Table 6. Comparison of prediction results of different models

预测模型	评价指标
预测模型	MSE	MAE	R²	ACC	P	F₁
LightGBM	2 062.30	25.61	0.422 4	0.754 6	0.754 4	0.766 2
XGBoost	1 939.45	25.44	0.456 8	0.760 0	0.765 7	0.768 6
随机森林	2 353.60	27.45	0.340 8	0.743 8	0.741 4	0.757 5
NR-DenseNet(16)	58.3	3.28	0.978 7	0.948 0	0.947 9	0.948 0

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