Dynamic capacity and variable runway configurations in airport slot allocation

The airport slot allocation procedure relies on a (fixed) capacity to allocate slots to airlines, which often leads to under/over utilization of slots, depending on how conservative the airport planners are. This demand and capacity imbalance over the peak period can best be addressed during the str...

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Main Authors: Cheung, Wai Lun, Piplani, Rajesh, Alam, Sameer, Bernard-Peyre, Lionel
Other Authors: School of Mechanical and Aerospace Engineering
Format: Article
Language:English
Published: 2021
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Online Access:https://hdl.handle.net/10356/152889
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Institution: Nanyang Technological University
Language: English
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spelling sg-ntu-dr.10356-1528892021-10-13T04:20:00Z Dynamic capacity and variable runway configurations in airport slot allocation Cheung, Wai Lun Piplani, Rajesh Alam, Sameer Bernard-Peyre, Lionel School of Mechanical and Aerospace Engineering Thales Solutions Asia Pte Ltd Engineering::Industrial engineering::Operations research Engineering::Civil engineering::Transportation Business::Management::Decision making Business::Management::Mathematical models Airport Slot Allocation Airport Demand Management The airport slot allocation procedure relies on a (fixed) capacity to allocate slots to airlines, which often leads to under/over utilization of slots, depending on how conservative the airport planners are. This demand and capacity imbalance over the peak period can best be addressed during the strategic planning phase by displacing flights from their originally allocated slots to neighboring ones with available capacity. The proposed Mixed Integer Programming (MIP) model addresses peak airport traffic with a leveling effect through minor adjustment of the demand with respect to a dynamic capacity derived from an analytical capacity model. The analytical capacity model provides a dynamic capacity estimation over the planning horizon based on a varying flight mix. Our approach also allows for exploration of possible runway configurations, arrival/departure priority, and operational modes (segregated/ mixed) to ensure that the higher levels of demand during the strategic planning phase does not lead to excessive delays on the day of operations. The MIP model lexicographically optimizes the flight slots, minimizing the number of displaced flights and total slot displacement for all flights, subject to scheduling, maximum acceptable slot displacement, capacity, and runway configuration constraints. We also investigate the benefit of the proposed model over fixed declared capacity models which do not account for operational mode changes. For the test data obtained for Singapore Changi airport, the proposed MIP model can handle 20% more flights over the current schedule with demand not exceeding estimated capacity in any slot, displacing less than 14% of flights with a maximum displacement of two slots (of fifteen minutes each). In addition, we explore the impact of segregated and mixed mode of runway operations on slot displacement. The proposed MIP model has the potential to be a strategic decision support tool for airport planners to allow them to manage future increase in demand with existing airport infrastructure and with minimum schedule adjustment. Economic Development Board (EDB) This research is partially supported by Thales Solutions Asia Pte. Ltd. (EDB-IPP) Grant No. M4061723. 2021-10-13T04:19:59Z 2021-10-13T04:19:59Z 2021 Journal Article Cheung, W. L., Piplani, R., Alam, S. & Bernard-Peyre, L. (2021). Dynamic capacity and variable runway configurations in airport slot allocation. Computers & Industrial Engineering, 159, 107480-. https://dx.doi.org/10.1016/j.cie.2021.107480 0360-8352 https://hdl.handle.net/10356/152889 10.1016/j.cie.2021.107480 159 107480 en M4061723 Computers & Industrial Engineering © 2021 Elsevier Ltd. All rights reserved.
institution Nanyang Technological University
building NTU Library
continent Asia
country Singapore
Singapore
content_provider NTU Library
collection DR-NTU
language English
topic Engineering::Industrial engineering::Operations research
Engineering::Civil engineering::Transportation
Business::Management::Decision making
Business::Management::Mathematical models
Airport Slot Allocation
Airport Demand Management
spellingShingle Engineering::Industrial engineering::Operations research
Engineering::Civil engineering::Transportation
Business::Management::Decision making
Business::Management::Mathematical models
Airport Slot Allocation
Airport Demand Management
Cheung, Wai Lun
Piplani, Rajesh
Alam, Sameer
Bernard-Peyre, Lionel
Dynamic capacity and variable runway configurations in airport slot allocation
description The airport slot allocation procedure relies on a (fixed) capacity to allocate slots to airlines, which often leads to under/over utilization of slots, depending on how conservative the airport planners are. This demand and capacity imbalance over the peak period can best be addressed during the strategic planning phase by displacing flights from their originally allocated slots to neighboring ones with available capacity. The proposed Mixed Integer Programming (MIP) model addresses peak airport traffic with a leveling effect through minor adjustment of the demand with respect to a dynamic capacity derived from an analytical capacity model. The analytical capacity model provides a dynamic capacity estimation over the planning horizon based on a varying flight mix. Our approach also allows for exploration of possible runway configurations, arrival/departure priority, and operational modes (segregated/ mixed) to ensure that the higher levels of demand during the strategic planning phase does not lead to excessive delays on the day of operations. The MIP model lexicographically optimizes the flight slots, minimizing the number of displaced flights and total slot displacement for all flights, subject to scheduling, maximum acceptable slot displacement, capacity, and runway configuration constraints. We also investigate the benefit of the proposed model over fixed declared capacity models which do not account for operational mode changes. For the test data obtained for Singapore Changi airport, the proposed MIP model can handle 20% more flights over the current schedule with demand not exceeding estimated capacity in any slot, displacing less than 14% of flights with a maximum displacement of two slots (of fifteen minutes each). In addition, we explore the impact of segregated and mixed mode of runway operations on slot displacement. The proposed MIP model has the potential to be a strategic decision support tool for airport planners to allow them to manage future increase in demand with existing airport infrastructure and with minimum schedule adjustment.
author2 School of Mechanical and Aerospace Engineering
author_facet School of Mechanical and Aerospace Engineering
Cheung, Wai Lun
Piplani, Rajesh
Alam, Sameer
Bernard-Peyre, Lionel
format Article
author Cheung, Wai Lun
Piplani, Rajesh
Alam, Sameer
Bernard-Peyre, Lionel
author_sort Cheung, Wai Lun
title Dynamic capacity and variable runway configurations in airport slot allocation
title_short Dynamic capacity and variable runway configurations in airport slot allocation
title_full Dynamic capacity and variable runway configurations in airport slot allocation
title_fullStr Dynamic capacity and variable runway configurations in airport slot allocation
title_full_unstemmed Dynamic capacity and variable runway configurations in airport slot allocation
title_sort dynamic capacity and variable runway configurations in airport slot allocation
publishDate 2021
url https://hdl.handle.net/10356/152889
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