DETECTION OF UNSTABLE APPROACHES IN FLIGHT TRACK WITH RECURRENT NEURAL NETWORK
Due to the increasing of air traffic density is needed to improve flight safety level <br /> <br /> especially in approach and landing phase. A potentially risky approach phase of <br /> <br /> flight is called an unstable approach. There are related studies in detecting...
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| Format: | Theses |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/25225 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Due to the increasing of air traffic density is needed to improve flight safety level <br />
<br />
especially in approach and landing phase. A potentially risky approach phase of <br />
<br />
flight is called an unstable approach. There are related studies in detecting these <br />
<br />
conditions, including anomaly detection of flight tracks for all flight phases. <br />
<br />
Compare with Multiple Kernel and Clustering methods, Recurrent Neural Network <br />
<br />
(RNN) has advantages in term of accuracy, sensitivity towards short term anomaly, <br />
<br />
and does not require dimensional reduction to identify the flight track anomaly <br />
<br />
pattern. However, RNN require experts to identify the risk event characteristics that <br />
<br />
cause anomalies. While heuristic methods can identify anomaly patterns <br />
<br />
specifically in the approach phase or called unstable approach with rule-based for <br />
<br />
each risk event. Therefore, this study combines the two methods approach to <br />
<br />
identify the unstable approach pattern. The main focus of this research is to prepare <br />
<br />
the data until ready to do the process of model formation by preprocessing <br />
<br />
technique, then done data modelling using RNN method with architecture stacked <br />
<br />
Long Short Term Memory (LSTM), and identify the type of risk event that influence <br />
<br />
unstable approach with heuristic method. In the modelling experiment performed <br />
<br />
by tuning the optimum value for each input parameter. The optimum value for batch <br />
<br />
size = 128, epoch = 150, and optimizer is rmsprop, with accuracy value equal to <br />
<br />
90.12%, recall value equal to 59,44%, and precision value equal to 100%. That <br />
<br />
results show that the established model has been able to classify unstable and stable <br />
<br />
approaches, with high precision value, but the recall value is still low. Therefore <br />
<br />
for future work, the more amount of unstable approach data can be used to improve <br />
<br />
performance of data training. |
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