Abstract
Air traffic networks, where airports are the nodes that interconnect the entire system, have a time-varying and stochastic nature. An incident in the airport environment may easily propagate through the network and generate system-level effects. This paper analyses the aircraft flow through the Airport Transit View framework, focusing on the airspace/airside integrated operations. In this analysis, we use a dynamic spatial boundary associated with the Extended Terminal Manoeuvring Area concept. Aircraft operations are characterised by different temporal milestones, which arise from the combination of a Business Process Model for the aircraft flow and the Airport Collaborative Decision-Making methodology. Relationships between factors influencing aircraft processes are evaluated to create a probabilistic graphical model, using a Bayesian network approach. This model manages uncertainty and increases predictability, hence improving the system’s robustness. The methodology is validated through a case study at the Adolfo Suárez Madrid-Barajas Airport, through the collection of nearly 34,000 turnaround operations. We present several lessons learned regarding delay propagation, time saturation, uncertainty precursors and system recovery. The contribution of the paper is two-fold: it presents a novel methodological approach for tackling uncertainty when linking inbound and outbound flights and it also provides insight on the interdependencies among factors driving performance.
Highlights
Introduction and MotivationAir transport operations rely on a complex network architecture, where several facilities, processes and agents are interrelated and interact with each other [1]
Thisthe section illustrates the outcomes that have arisen from previous models: (1) the operational framework for stage (including the statistical characterisation of processes and uncertainty framework for the Airport Transit View (ATV) stage; and (2) the causal model for uncertainty management (BN)
We used a dynamic spatial boundary associated with the Extended Terminal Manoeuvring Area (E-TMA) concept, so that a linkage between inbound and outbound flights could be proposed
Summary
Air transport operations rely on a complex network architecture, where several facilities, processes and agents are interrelated and interact with each other [1] In this large-scale and dynamic system, airports are the interconnection nodes that help aircraft distribution through the network and transport modal changes for passengers [2]. Failures and delays (due to service disruptions, unexpected events or capacity constraints) may propagate throughout the different nodes of the network, making it vulnerable [5,6,7]. This situation has led to system-wide congestion problems and has worsened due to the strong growth in the number of airport operations during the last few decades [8]. Constraints at a particular airport may cause partial network degradation [6]
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