Towards a greener Extended-Arrival Manager in air traffic control: a heuristic approach for dynamic speed control using machine-learned delay prediction model
Extended Arrivals Manager (E-AMAN) is a concept that reduces congestion and holding time in the Terminal Maneuver Airspace (TMA) by managing the arrival aircraft during the en-route phase. However, current E-AMAN deployment is only limited to a horizon of 150 - 200NM from the airport, restricting th...
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sg-ntu-dr.10356-1601752022-11-19T23:30:24Z Towards a greener Extended-Arrival Manager in air traffic control: a heuristic approach for dynamic speed control using machine-learned delay prediction model Lim, Zhi Jun Alam, Sameer Dhief, Imen Schultz, Michael School of Mechanical and Aerospace Engineering Air Traffic Management Research Institute Engineering::Computer science and engineering::Computing methodologies::Artificial intelligence Engineering::Aeronautical engineering::Aviation Engineering::Computer science and engineering::Computing methodologies::Simulation and modeling Air Traffic Control Machine Learning Speed Control Extended Arrival Management Extended Arrivals Manager (E-AMAN) is a concept that reduces congestion and holding time in the Terminal Maneuver Airspace (TMA) by managing the arrival aircraft during the en-route phase. However, current E-AMAN deployment is only limited to a horizon of 150 - 200NM from the airport, restricting the window of opportunity for any early intervention, and the prediction of delay in TMA remains a challenge given the inherent uncertainties in the air traffic environment. In this context, this research work presents an approach for predicting, transferring and absorbing the flight delays and holdings from the highly constrained TMA to the en-route phase using both data-driven and optimization techniques. First, a method is developed to estimate holding time and TMA delay from historical data. Next, a Machine Learning based prediction framework is developed to predict holdings and delays in the TMA, from an extended horizon of 300 - 500NM from the airport. Finally, a heuristics-based optimization model is developed for dynamic speed management to transfer TMA delays to the en-route phase. To demonstrate the model's efficacy, a case study for Singapore airspace is developed using associated one-day air-traffic data. Four sets of experiments are designed to evaluate the performance of the speed management framework under different flight cooperation levels. For the experiment with the highest number of cooperative flights, the implementation of dynamic speed shows a transfer of 179 minutes of TMA delay to the en-route phase, equivalent to 65% of the initial TMA delay. This results in an estimated fuel saving of 1524 kg along with a reduction in carbon dioxide emissions of 4800 kg. The findings demonstrate that E-AMAN, for extended horizon with predictive delay modelling and dynamic speed management, has the potential to manage TMA congestion and reduce fuel consumption and emissions, therefore mitigating the environmental impact. Civil Aviation Authority of Singapore (CAAS) National Research Foundation (NRF) Submitted/Accepted version This research is supported by the National Research Foundation, Singapore, and the Civil Aviation Authority of Singapore, under the Aviation Transformation Programme. 2022-07-15T03:08:35Z 2022-07-15T03:08:35Z 2022 Journal Article Lim, Z. J., Alam, S., Dhief, I. & Schultz, M. (2022). Towards a greener Extended-Arrival Manager in air traffic control: a heuristic approach for dynamic speed control using machine-learned delay prediction model. Journal of Air Transport Management, 103, 102250-. https://dx.doi.org/10.1016/j.jairtraman.2022.102250 0969-6997 https://hdl.handle.net/10356/160175 10.1016/j.jairtraman.2022.102250 103 102250 en Journal of Air Transport Management © 2022 Elsevier Ltd. All rights reserved. This paper was published in Journal of Air Transport Management and is made available with permission of Elsevier Ltd. application/pdf |
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Engineering::Computer science and engineering::Computing methodologies::Artificial intelligence Engineering::Aeronautical engineering::Aviation Engineering::Computer science and engineering::Computing methodologies::Simulation and modeling Air Traffic Control Machine Learning Speed Control Extended Arrival Management |
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Engineering::Computer science and engineering::Computing methodologies::Artificial intelligence Engineering::Aeronautical engineering::Aviation Engineering::Computer science and engineering::Computing methodologies::Simulation and modeling Air Traffic Control Machine Learning Speed Control Extended Arrival Management Lim, Zhi Jun Alam, Sameer Dhief, Imen Schultz, Michael Towards a greener Extended-Arrival Manager in air traffic control: a heuristic approach for dynamic speed control using machine-learned delay prediction model |
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Extended Arrivals Manager (E-AMAN) is a concept that reduces congestion and holding time in the Terminal Maneuver Airspace (TMA) by managing the arrival aircraft during the en-route phase. However, current E-AMAN deployment is only limited to a horizon of 150 - 200NM from the airport, restricting the window of opportunity for any early intervention, and the prediction of delay in TMA remains a challenge given the inherent uncertainties in the air traffic environment. In this context, this research work presents an approach for predicting, transferring and absorbing the flight delays and holdings from the highly constrained TMA to the en-route phase using both data-driven and optimization techniques. First, a method is developed to estimate holding time and TMA delay from historical data. Next, a Machine Learning based prediction framework is developed to predict holdings and delays in the TMA, from an extended horizon of 300 - 500NM from the airport. Finally, a heuristics-based optimization model is developed for dynamic speed management to transfer TMA delays to the en-route phase. To demonstrate the model's efficacy, a case study for Singapore airspace is developed using associated one-day air-traffic data. Four sets of experiments are designed to evaluate the performance of the speed management framework under different flight cooperation levels. For the experiment with the highest number of cooperative flights, the implementation of dynamic speed shows a transfer of 179 minutes of TMA delay to the en-route phase, equivalent to 65% of the initial TMA delay. This results in an estimated fuel saving of 1524 kg along with a reduction in carbon dioxide emissions of 4800 kg. The findings demonstrate that E-AMAN, for extended horizon with predictive delay modelling and dynamic speed management, has the potential to manage TMA congestion and reduce fuel consumption and emissions, therefore mitigating the environmental impact. |
| author2 |
School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Lim, Zhi Jun Alam, Sameer Dhief, Imen Schultz, Michael |
| format |
Article |
| author |
Lim, Zhi Jun Alam, Sameer Dhief, Imen Schultz, Michael |
| author_sort |
Lim, Zhi Jun |
| title |
Towards a greener Extended-Arrival Manager in air traffic control: a heuristic approach for dynamic speed control using machine-learned delay prediction model |
| title_short |
Towards a greener Extended-Arrival Manager in air traffic control: a heuristic approach for dynamic speed control using machine-learned delay prediction model |
| title_full |
Towards a greener Extended-Arrival Manager in air traffic control: a heuristic approach for dynamic speed control using machine-learned delay prediction model |
| title_fullStr |
Towards a greener Extended-Arrival Manager in air traffic control: a heuristic approach for dynamic speed control using machine-learned delay prediction model |
| title_full_unstemmed |
Towards a greener Extended-Arrival Manager in air traffic control: a heuristic approach for dynamic speed control using machine-learned delay prediction model |
| title_sort |
towards a greener extended-arrival manager in air traffic control: a heuristic approach for dynamic speed control using machine-learned delay prediction model |
| publishDate |
2022 |
| url |
https://hdl.handle.net/10356/160175 |
| _version_ |
1751548487154008064 |