A chance-constrained programming model for airport ground movement optimisation with taxi time uncertainties

Xinwei Wang,Alexander E.I Brownlee,Michal Weiszer,John R Woodward,Mahdi Mahfouf,Jun Chen

doi:10.1016/j.trc.2021.103382

Xinwei Wang, Alexander E.I Brownlee + Show 4 more

Open Access

https://doi.org/10.1016/j.trc.2021.103382

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Abstract

Airport ground movement remains a major bottleneck for air traffic management. Existing approaches have developed several routing allocation methods to address this problem, in which the taxi time traversing each segment of the taxiways is fixed. However, taxi time is typically difficult to estimate in advance, since its uncertainties are inherent in the airport ground movement optimisation due to various unmodelled and unpredictable factors. To address the optimisation of taxi time under uncertainty, we introduce a chance-constrained programming model with sample approximation, in which a set of scenarios is generated in accordance with taxi time distributions. A modified sequential quickest path searching algorithm with local heuristic is then designed to minimise the entire taxi time. Working with real-world data at an international airport, we compare our proposed method with the state-of-the-art algorithms. Extensive simulations indicate that our proposed method efficiently allocates routes with smaller taxiing time, as well as fewer aircraft stops during the taxiing process.

Highlights

The International Air Transport Association forecasts current passenger numbers could double to 8.2 billion no later than 2040 (International Air Transport Association, 2020a)
To better incorporate the taxi time uncertainties into the airport ground movement (AGM) model and generate more effective aircraft routes, this paper introduces the chance-constrained programming (CCP) model with sample approximate method (Charnes and Cooper, 1959; Luedtke and Ahmed, 2008), and proposes a modified CCP-quickest path problem with time windows (QPPTW) algorithm with a local heuristic method to allocate more efficient aircraft routes that are still robust
The confidence level acts as a parameter for CCP-QPPTW, and different setting of α only influences which routes would be scheduled, while all the aircraft operational constraints are satisfied in the simulations

Summary

Introduction

The International Air Transport Association forecasts current passenger numbers could double to 8.2 billion no later than 2040 (International Air Transport Association, 2020a). Despite the global pandemic of 2020, it is believed that the longterm growth of aviation is likely to resume in time (International Air Transport Association, 2020c). This increasing trend for air transport, and the economic benefits driven by aviation, could be curtailed due to limited airport infrastructure capacities (International Air Transport Association, 2020b). This bottleneck has been recognised as one of the greatest challenges to future aviation industry (European Commission, 2020), and there is an urgent need to develop a more efficient decision support system for airport operations.

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