A machine learning model to predict runway exit at Vienna airport

Herrema, Floris; Curran, Ricky; Hartjes, S.; Ellejmi, Mohamed; Bancroft, Steven; Schultz, Michael

doi:10.1016/j.tre.2019.10.002

Cited by 35 publications

(20 citation statements)

References 20 publications

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“…In the context of aviation, several methods from the field of artificial intelligence are used to cluster [15]- [18], detect anomalies [19]- [22] and predict aircraft trajectories [23]- [25], develop dynamic airspace designs [26], [27], analyse runway and apron operations [21], [28]- [30], determine airport performance including the impact of local weather events [31], [32], and for airport terminal operations (turnaround) [33]. More initiatives to leverage ADS-B open data in order to improve the state of the art are already commonplace, esp.…”

Section: A State Of the Artmentioning

confidence: 99%

“…We consequently follow a research agenda for a datadriven management of airport operations: (a) concept of a performance-based, integrated airport management [36], (b) analysis of operational scenarios to mitigate impacts of capacity restrictions [37], (c) systematic analysis of correlations between airport performance and weather conditions at European airports [38], (d) data-driven models to forecast operational delays using neural networks [31], [32], and (e) forecast of specific parts of aircraft ground trajectory [28].…”

Section: A State Of the Artmentioning

confidence: 99%

“…Inbound trajectories determine landing times and are part of the airport arrival management to ensure an efficient use of runway capacity. After the aircraft landed, the runway occupancy time determine the further use of this particular runway, and dependent operations at other runways, for arrival and departure procedures [28].…”

Section: Analysis Of Airport Operational Environmentmentioning

confidence: 99%

See 2 more Smart Citations

Analysis of airport ground operations based on ADS-B data

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et al. 2020

2020 International Conference on Artificial Intelligence and Data Analytics for Air Transportation (AIDA-At)

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Section: A State Of the Artmentioning

confidence: 99%

Section: A State Of the Artmentioning

confidence: 99%

Section: Analysis Of Airport Operational Environmentmentioning

confidence: 99%

See 1 more Smart Citation

Analysis of airport ground operations based on ADS-B data

Schultz

Olivé

Rosenow

et al. 2020

2020 International Conference on Artificial Intelligence and Data Analytics for Air Transportation (AIDA-At)

Self Cite

View full text Add to dashboard Cite

“…Airports have embraced digital change, whether it is encoding analogue information into a digital format or using technologies to alter and add value to existing processes and functions. For some, change is now being driven by current or emerging technologies such as augmented reality ( Eschen, 2018 ), Big Data Analytics ( Mullan, 2019 ), blockchain ( Di Vaio and Varriale, 2020 ), cloud computing ( Amadeus, 2014 ), cognitive computing ( Herrema et al, 2019 ; Sadjadi and Jarrah, 2011 ), cybersecurity ( ACI, 2020 ), systems integration ( Stocking et al, 2009 ), the Internet of Things ( Mariani et al, 2019 ; Zmud et al, 2018 ) and virtual modelling and simulation ( Ørsted, 2019 ). These technologies allow airports to develop systems that monitor, visualise and respond to digital processes and functions in real-time, and as part of a wider ecosystem that connects all stakeholders ( Halpern et al, 2021 ).…”

Section: Introductionmentioning

confidence: 99%

Ready for digital transformation? The effect of organisational readiness, innovation, airport size and ownership on digital change at airports

Halpern

Mwesiumo

Suau-Sánchez

et al. 2021

Journal of Air Transport Management

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This study investigates the effect of organisational readiness, innovation and airport size and ownership on digital change at airports. Data is collected from a survey of managers at 94 airports worldwide and analysed using partial least squares structural equation modelling. Organisational readiness is found to have a direct effect on digital change. Organisational readiness also has a direct effect on innovation, which subsequently affects digital change. Airport size has a direct effect on digital change while the effect of ownership is not significant. The findings show that successful development of organisational readiness can be used to speed up the rate of innovation needed for digital change at airports.

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“…In their case study, the runway capacity was estimated to be around 8 to 18% higher than the results obtained with FTS [14], as their model did not fully capture the characteristics of the constraints imposed by the airport infrastructure. In order to identify the precursors of an increase in ROT or a runway exit miss, Herrema et al (2019) [15] proposed a machine learning approach for predicting the runway exit to be used based on actual movements at the airport. The results showed that their proposed model achieved 79% accuracy rate of the decision variable which determined whether a flight rolled out runway exit following the procedure or not.…”

Section: Introductionmentioning

confidence: 99%

Data-Driven Simulation for Evaluating the Impact of Lower Arrival Aircraft Separation on Available Airspace and Runway Capacity at Tokyo International Airport

et al. 2021

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Although the application of new wake turbulence categories, the so-called “RECAT (wake turbulence category re-categorization)”, will realize lower aircraft separation minima and directly increase runway throughput, the impacts of increasing arrival traffic on the surrounding airspace and arrival traffic flow as a whole have not yet been discussed. This paper proposes a data-driven simulation approach and evaluates the effectiveness of the lower aircraft separation in the arrival traffic at the target airport. The maximum runway capacity was clarified using statistics on aircraft types, stochastic distributions of inter-aircraft time and runway occupancy time, and the levels of the automation systems that supported air traffic controllers’ separation work. Based on the estimated available runway capacity, simulation models were proposed by analyzing actual radar track and flight plan data during the 6 months between September 2019 and February 2020, under actual operational constraints and weather conditions. The simulation results showed that the application of RECAT would reduce vectoring time in the terminal area by 7% to 10% under the current airspace and runway capacity when following a first-come first-served arrival sequence. In addition, increasing airspace capacity by 10% in the terminal area could dramatically reduce en-route and takeoff delay times while keeping vectoring time the same as under the current operation in the terminal area. These findings clarified that applying RECAT would contribute to mitigating air traffic congestion close to the airport, and to reducing delay times in arrival traffic as a whole while increasing runway throughput. The simulation results demonstrated the relevance of the theoretical results given by queue-based approaches in the authors’ past studies.

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A machine learning model to predict runway exit at Vienna airport

Cited by 35 publications

References 20 publications

Analysis of airport ground operations based on ADS-B data

Analysis of airport ground operations based on ADS-B data

Ready for digital transformation? The effect of organisational readiness, innovation, airport size and ownership on digital change at airports

Data-Driven Simulation for Evaluating the Impact of Lower Arrival Aircraft Separation on Available Airspace and Runway Capacity at Tokyo International Airport

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