Taxi-speed prediction by spatio-temporal graph-based trajectory representation and its applications

Taxi-speed prediction by spatio-temporal graph-based trajectory representation and its applications

Airport surface movement systems require aircraft taxing speed as a key input to perform ground movement optimization and path planning processes. With the increasing availability of surface movement data from systems such as A-SMGCS, a data-driven framework using a spatio-temporal graph-based traje...

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Bibliographic Details
Main Authors: Tran, Thanh-Nam, Pham, Duc-Thinh, Alam, Sameer, Duong, Vu
Other Authors: School of Mechanical and Aerospace Engineering
Format: Conference or Workshop Item
Language:English
Published: 2021
Subjects:
Engineering::Aeronautical engineering::Air navigation
Airport Surface Movement
Conflict Detection
Online Access:https://hdl.handle.net/10356/146853
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Institution: Nanyang Technological University
Language: English
Description
Summary:Airport surface movement systems require aircraft taxing speed as a key input to perform ground movement optimization and path planning processes. With the increasing availability of surface movement data from systems such as A-SMGCS, a data-driven framework using a spatio-temporal graph-based trajectory representation is proposed in this paper to predict aircraft taxing speed. The proposed framework includes a data preparation module for converting track points data to graph-based representation and a developing predictive model module for learning taxi-speed model. The Random Forest algorithm is selected as our predictive model. The model predicts the aircraft taxi-speed with an error of 1.08 m/s for taxi-out procedure and 0.97 m/s for taxi-in procedure, when compared with the actual taxi-speed from A-SMGCS data, respectively. Further, three applications of our approach are discussed which are taxi-speed profile, unimpeded taxi time and potential conflict detection. The results of our methods outperform all baseline methods. In detail, for generating taxi-speed profile, our method obtains the error 1.38 m/s while for computing unimpeded taxi time, our method outperforms the baseline model with the mean absolute percentage error is 11.03% for the taxi-in and 16.8% for taxi-out procedure, respectively.

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