Airport gate assignment algorithm based on node prediction in conflict graph of assigned activities

doi:10.11772/j.issn.1001-9081.2025060684

Journal of Computer Applications ›› 2026, Vol. 46 ›› Issue (6): 1913-1921.DOI: 10.11772/j.issn.1001-9081.2025060684

• Advanced computing • Previous Articles

Airport gate assignment algorithm based on node prediction in conflict graph of assigned activities

Min LU¹^,², Hui ZHOU¹^,²()

^1.College of Computer Science and Technology，Civil Aviation University of China，Tianjin 300300，China
^2.The Key Laboratory of Smart Airport Theory and System （Civil Aviation University of China），Tianjin 300300，China

Received:2025-06-23 Revised:2025-10-24 Accepted:2025-11-05 Online:2025-11-12 Published:2026-06-10
Contact: Hui ZHOU
About author:LU Min， born in 1985， Ph. D.， associate professor. His research interests include intelligent airport operations and control， neural combinatorial optimization.
First author contact:ZHOU Hui， born in 1997， M. S. candidate. His research interests include intelligent airport operations and control， deep learning， graph neural networks.
Supported by:
National Natural Science Foundation of China(U2333206)

基于指派活动冲突图节点预测的机场停机位分配算法

卢敏¹^,², 周辉¹^,²()

^1.中国民航大学计算机科学与技术学院，天津 300300
^2.民航智慧机场理论与系统重点实验室（中国民航大学），天津 300300

通讯作者: 周辉
作者简介:卢敏（1985—），男，天津人，副教授，博士，主要研究方向：智慧机场的运行与控制、神经组合优化
第一联系人：周辉（1997—），男，江西上饶人，硕士研究生，主要研究方向：智慧机场的运行与控制、深度学习、图神经网络。
基金资助:
国家自然科学基金资助项目(U2333206)

Abstract

Abstract:

To address the challenge that the existing methods struggle to balance solution efficiency， assignment quality， and generalization in airport gate pre-assignment at large hub airports under dynamic changes in flight number， gate layout， and assignment rules， an airport gate assignment algorithm based on node prediction in conflict graph of assigned activities was proposed. Firstly， an airport gate assignment model was established with the objectives of maximizing gate assignment rate and cumulative soft preference. Secondly， the feasible airport gate assignment activities were screened through an airfield zoning strategy， the corresponding conflict graph of assignment activities was constructed， the Node-Edge Collaborative Updating Graph Neural Network （NECU-GNN） was designed， and the NECU-GNN for Node Prediction model （NECU-GNN4NP） was developed. Finally， the NECU-GNN4NP-guided ranking-based Max Weighted Independent Set Algorithm （MWISA） was proposed on the basis of NECU-GNN4NP， so as to solve the optimal set of assignment activities for the conflict graph of assignment activities and obtain the airport gate assignment scheme. Experimental results based on Shenzhen Bao’an International Airport data show that compared with the current optimal assignment scheme at Shenzhen Bao’an International Airport， the proposed algorithm increases the gate assignment rate by 4.2， 4.3， and 3.1 percentage points， respectively， improves the cumulative soft preference by 38.1%， 30.3%， and 42.8%， respectively， and reduces the solution time by 65.3%， 39.1%， and 41.4%， respectively， in low-peak， normal， and high-peak scenarios. In addition， migration experimental results based on Yinchuan Hedong International Airport data demonstrate that the proposed algorithm can be adapted and applied to other airports rapidly. It can be seen that the proposed algorithm not only has good generalization but also enables efficient and high-quality airport gate assignment.

Key words: aviation transportation engineering, airport gate assignment, Graph Neural Network (GNN), max weighted independent set, gate assignment rate, soft preference

摘要：

针对大型枢纽机场停机位预分配问题在航班数量、机位布局和分配规则动态变化背景下，现有方法难以兼顾求解效率、分配质量和泛化性的挑战，提出一种基于指派活动冲突图节点预测的机场停机位分配算法。首先，建立以最大化靠桥率与最大化累计软偏好为优化目标的停机位分配模型；其次，采用场面分区策略筛选可行的机位指派活动，构建相应的指派活动冲突图，设计基于节点-边协同更新的图神经网络（NECU-GNN），并设计基于NECU-GNN的节点预测模型（NECU-GNN4NP）；最后，设计基于NECU-GNN4NP引导排序的最大加权独立集算法（MWISA）以求解指派活动冲突图的最优指派活动集合，得到停机位分配解方案。基于深圳宝安国际机场数据的实验结果表明，在低峰期、普通和高峰期这3种场景下，与深圳宝安国际机场的目前最优分配方案相比，所提算法的靠桥率分别提升了4.2、4.3和3.1个百分点，累计软偏好分别提高了38.1%、30.3%和42.8%，求解时间分别减少了65.3%、39.1%和41.4%。此外，基于银川河东国际机场数据的迁移实验结果表明，所提算法能够快速迁移应用到其他机场。可见，所提算法不仅能高效与高质量地进行停机位分配，而且具有良好的泛化性。

关键词: 航空运输工程, 机场停机位分配, 图神经网络, 最大加权独立集, 靠桥率, 软偏好

CLC Number:

TP319.9

Min LU, Hui ZHOU. Airport gate assignment algorithm based on node prediction in conflict graph of assigned activities[J]. Journal of Computer Applications, 2026, 46(6): 1913-1921.

卢敏, 周辉. 基于指派活动冲突图节点预测的机场停机位分配算法[J]. 《计算机应用》唯一官方网站, 2026, 46(6): 1913-1921.

Figures/Tables 13

Fig.1 Taxi-in and Pushback conflicts

Fig.2 Schematic diagram of airfield zoning

Fig.3 Training process of NECU-GNN4NP

Tab. 1 Detailed information of some flights at Shenzhen Airport

任务ID	航班号	飞机型号	航班机型等级	日期	航班进港时间	航班出港时间
662322	N360UP	B763+	D	2023-08-01	00：01：00	04：02：00
662142	B6736	A320	C	2023-08-01	00：04：00	07：00：00
662271	B6765	A320	C	2023-08-01	00：07：00	01：24：00
662062	B1758	B738	C	2023-08-01	00：07：54	08：53：55
$⋮$
663551	B1626	A321	E	2023-08-01	23：08：25	24：00：00

Tab. 1 Detailed information of some flights at Shenzhen Airport

任务ID	航班号	飞机型号	航班机型等级	日期	航班进港时间	航班出港时间
662322	N360UP	B763+	D	2023-08-01	00：01：00	04：02：00
662142	B6736	A320	C	2023-08-01	00：04：00	07：00：00
662271	B6765	A320	C	2023-08-01	00：07：00	01：24：00
662062	B1758	B738	C	2023-08-01	00：07：54	08：53：55
$⋮$
663551	B1626	A321	E	2023-08-01	23：08：25	24：00：00

Tab. 2 Detailed information of some airport gates at Shenzhen Airport

停机位编号	停机位型号	机位属性	可容纳飞机机型	相邻机位
301	E	近机位	A319\|A320\|A321\|…\|A339	302、303
302	D	近机位	A310\|A319\|A320\|…\|MD90	301、303
303	E	近机位	A319\|A320\|A321\|…\|MD90	301、302
$⋮$
100	C	远机位	A319\|A320\|A321\|…\|B739	101、102
101	D	远机位	A310\|A319\|A320\|…\|GLF5	100、102

Tab. 2 Detailed information of some airport gates at Shenzhen Airport

停机位编号	停机位型号	机位属性	可容纳飞机机型	相邻机位
301	E	近机位	A319\|A320\|A321\|…\|A339	302、303
302	D	近机位	A310\|A319\|A320\|…\|MD90	301、303
303	E	近机位	A319\|A320\|A321\|…\|MD90	301、302
$⋮$
100	C	远机位	A319\|A320\|A321\|…\|B739	101、102
101	D	远机位	A310\|A319\|A320\|…\|GLF5	100、102

Tab. 3 Conflict graph datasets of Shenzhen Airport

数据集	时间范围	冲突图数	平均节点数	节点数范围	平均边数	边数范围	平均图密度
训练集	2023-03—2023-06	7 435	153.1	［2，1 344］	3 324.3	［1，39 422］	0.667 5
验证集	2023-07	1 924	155.1	［2，1 182］	3 215.4	［1，37 960］	0.658 4
测试集	2023-08	1 838	155.2	［2，1 160］	3 113.6	［1，38 570］	0.657 9

Tab. 4 Experimental parameters

参数	值
节点特征维度	4
边特征维度	3
隐藏层特征维度	32
GNN层数	12
采样策略	无放回随机采样
批量大小训练轮次	32 500
优化器	AdamW
初始学习率	10^-3
学习率更新步长	100
学习率衰减因子	0.1

Fig. 4 Training loss curves of node prediction models

Fig. 5 Training curves of gate assignment rate

Tab. 5 Comparison experimental results based on Shenzhen Airport flight data in August

算法	低峰期场景（383航班架次）			普通场景（489航班架次）			高峰期场景（553航班架次）
算法	靠桥率/%	累计软偏好	求解时间/s	靠桥率/%	累计软偏好	求解时间/s	靠桥率/%	累计软偏好	求解时间/s
人工分配	81.4	800.6	14 400.0	76.3	958.1	14 400.0	74.3	1 060.1	14 400.0
机场原算法	91.9	903.8	60.0	83.8	1 065.4	75.0	81.7	1 160.2	90.0
本文算法	96.1	1 248.1	20.8	88.1	1 388.5	45.7	84.8	1 657.2	52.7

Tab. 6 Comparison of airport operational characteristics

机场	机场规模	日均航班架次	停机位总数	近机位数	远机位数	近机位比例/%	运营密度
深圳机场	大型枢纽机场	400~600	381	129	252	33.9	高密度，机位紧张
银川机场	中型机场	100~120	64	22	42	34.4	中等密度，相对宽松

Tab. 7 Comparison experimental results based on flight data from Yinchuan Airport

算法	靠桥率/%	累计软偏好	求解时间/s
人工分配	94.3	342.3
本文算法	93.8	381.8	1.36

Tab. 8 Airport gate assignment results for Yinchuan Airport from April 1， 2025 to April 7， 2025

日期	总航班数	允许靠桥航班数	历史分配的靠桥航班数	算法分配的靠桥航班数	算法未分配的航班数	累计软偏好	算法分配时间/s
2025‑04‑01	116	114	108	108	1	402.5	1.50
2025‑04‑02	111	108	104	103	0	396.3	1.34
2025‑04‑03	108	108	99	103	0	385.6	1.35
2025‑04‑04	101	100	97	97	0	360.9	1.33
2025‑04‑05	104	104	97	99	0	360.9	1.34
2025‑04‑06	106	102	95	98	0	368.0	1.35
2025‑04‑07	105	101	95	96	0	364.4	1.34

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Airport gate assignment algorithm based on node prediction in conflict graph of assigned activities

基于指派活动冲突图节点预测的机场停机位分配算法

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