论文信息 - A Runway Configuration Management (RCM) model with marginally decreasing transition capacities

A Runway Configuration Management (RCM) model with marginally decreasing transition capacities

The Runway Configuration Management (RCM) problem governs what combinations of airport runways are in use at a given time, and to what capacity. These are defined in terms of configurations (groupings of runways), operating under Runway Configuration Capacity Envelopes (RCCEs) which limit arrival and departure capacities. The RCCE identifies unique capacities constraints based on which tarmacs are used for arrivals, departures, or both, and their direction of travel. When switching between RCCEs, some decrement in arrival and departure capacities is incurred by the transition. Previous RCM models [1] have accounted for this cost through a required period of inactivity. In this paper, we instead focus on the introduction and assessment of a model capable of marginally decreasing RCCE capacities during configuration transitions. A transition penalty matrix is introduced, specifying the relative costs (in terms of accepted arrival and departure capacities) for switching between RCCEs i and j as a pij entry in the matrix. Although incurring inherent computational costs, this new model benefits from allowing customizable transition penalties which more closely represent real world conditions, and thereby increases model accuracy.

Christopher Weld | Rex Kincaid | Michael Duarte

[1] Amy Cohn,et al. Decreasing airline delay propagation by re-allocating scheduled slack , 2010 .

[2] Mark Hansen,et al. A dynamic rerouting model for air traffic flow management , 2009 .

[3] Edmund K. Burke,et al. The Effect of the Planning Horizon and the Freezing Time on Take-off Sequencing , 2006 .

[4] Marc Roubens,et al. Advances in Operations Research , 1977 .

[5] Amedeo R. Odoni,et al. Optimal Selection of Airport Runway Configurations , 2011, Oper. Res..

[6] Daniel Delahaye,et al. Distributed Trajectory Flexibility Preservation for Traffic Complexity Mitigation , 2009 .

[7] Gary W. Lohr,et al. Current Practices in Runway Configuration Management (RCM) and Arrival/Departure Runway Balancing (ADRB) , 2008 .

[8] Nicolas Durand,et al. Airport surface management and runways scheduling , 2009 .

[9] David J. Lovell,et al. Evaluating a New Formulation for Large-Scale Traffic Flow Management , 2009 .

[10] Amedeo R. Odoni,et al. The Air Traffic Flow Management Problem: An Integer Optimization Approach , 2008, IPCO.

[11] Edmund K. Burke,et al. On-line decision support for take-off runway scheduling with uncertain taxi times at London Heathrow airport , 2008, J. Sched..

[12] S. Atkins. Observation and measurement of metroplex phenomena , 2008, 2008 IEEE/AIAA 27th Digital Avionics Systems Conference.

[13] Yu-Heng Chang,et al. Air Traffic Flow Management in the Presence of Uncertainty , 2009 .