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DOI QR Code

QAR 데이터기반 XGBoost 모델링을 활용한 복행 후 항공기 동적 반응 및 안정성 연구

A Study on Aircraft Dynamic Response and Stability After Go-Around Using XGBoost Modeling Based on QAR Data

  • 전제형 (한국항공대학교 항공운항관리학과) ;
  • 김현덕 (한국항공대학교 항공운항학과)
  • 투고 : 2024.08.18
  • 심사 : 2024.08.30
  • 발행 : 2024.09.30

초록

The go-around procedure plays a crucial role in aviation safety, allowing pilots to abort unsafe landings and attempt a new approach. While existing studies have primarily focused on predicting the onset of go-arounds, relatively little attention has been paid to evaluating aircraft stability and performance after a go-around has been initiated. This study aims to address this gap by systematically assessing the dynamic response and stability of aircraft following a go-around using Quick Access Recorder (QAR) data. The methodology involves classifying go-around events into 'near-ground' and 'at-altitude' categories, and analyzing changes in pitch, descent rate, engine performance, and environmental factors after the initiation of the go-around to evaluate its stability and efficiency. The XGBoost machine learning algorithm is employed to model the aircraft's response post go-around and to predict stability across various go-around scenarios. The findings from this study provide insights that can enhance the safety and efficiency of go-around procedures through systematic analysis of QAR data, contributing to improvements in operational protocols and pilot training programs.

키워드

참고문헌

  1. Figuet, B., Koelle, R., Calvo Fernandez, E., and Waltert, M., "Analysing the impact of go-around occurrences at large european airports", Journal of Open Aviation Science, 1(2), 2023, pp.1-16.
  2. Holder, B., "Procedures to make aborted landings safer", Embry-Riddle Aeronautical University, 2023, Available from: https:// news.erau.edu/headlines/2023/proceduresto-make-aborted-landings-safer
  3. Kim, H., "Mitigation strategies for unstable approaches based on flight data analysis", Journal of the Korean Society for Aeronautical & Space Sciences, 48(1), 2020, pp.34-42.
  4. Kim, H., "A comparative study on the perception of safety culture of safety culture of airline flight crew in Korea", Journal of the Korean Society for Aviation and Aeronautics, 32(1), 2024, pp.103-108.
  5. Kumar, S., Corrado, S., Puranik, T., and Mavris, D., "Classification and analysis of goarounds in commercial aviation using ADS-B data", Aerospace, 8, 291, 2021, pp.1-21.
  6. Lee, J. S., and Choi, H. S., "A study on go-around operations in modern aviation", Journal of Aviation Science and Technology, 15(3), 2020, pp.123-130.
  7. Michael, G., "Understanding go-around pro-cedures in aviation", Aviation Safety Journal, 12(4), 1999, pp.47-52.
  8. Monstein, R., Figuet, B., Krauth, T., Waltert, M., and Dettling, M., "Large landing trajectory dataset for go-around analysis", Engineering Proceedings, 28(1), 2022, pp.1-12.
  9. Wingtalkers, "The Top Causes of Aircraft Emergency Landings", Wingtalkers.com, 2023, Available from: https://wingtalkers.com/emergency-landings
  10. Kim, H. D., "Flight data analysis based mitigation strategies for unstable approaches", Journal of Navigation and Aviation Safety, 45(2), 2020, pp. 54-63.
  11. Chen, T., and Guestrin, C., "XGBoost: A scalable tree boosting system", Proceedings of the 22nd ACM SIGKDD International Conference on Knowledge Discovery and Data Mining, 2016, pp.785-794.
  12. Friedman, J. H., "Greedy function approximation: A gradient boosting machine", Annals of Statistics, 29(5), 2001, pp.1189-1232.