Information Support for Aircraft Crew in Takeoff and Landing Modes

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详细

Methods for assessing the current state and forecasting critical events are developed in order to reduce the stress load on the pilot of an aircraft. These methods are based on the energy approach to flight control. Algorithms for forecasting the possibility of safe takeoff in the presence of high-rise obstacles on the trajectory are obtained. Forecast correction algorithms are introduced. Algorithms for
calculating the braking distance depending on the runway condition are found in the modes of landing or emergency braking at takeoff. Some ways to correct forecasts considering the sequence and operation time of all braking devices are proposed. Model tests are carried out for the algorithms in the entire range of operating conditions.

作者简介

A. Shevchenko

Trapeznikov Institute of Control Sciences, Russian Academy of Sciences

Email: shev-chik@yandex.ru
Moscow, Russia

B. Pavlov

Trapeznikov Institute of Control Sciences, Russian Academy of Sciences

Email: pavlov@ipu.ru
Moscow, Russia

G. Nachinkina

Trapeznikov Institute of Control Sciences, Russian Academy of Sciences

编辑信件的主要联系方式.
Email: nach_gala@ipu.ru
Moscow, Russia

参考

  1. Авиационные происшествия и инциденты в 1-м квартале 2023 г. http://old.aviamettelecom.ru.
  2. Accidents statistics. http://www.planecrashinfo.com/cause
  3. Borodkin S., Volynchuk A., Ganiev Sh., et al. Modern methods of preventing aircraft overrunning the runway // Научный Вестник МГТУ ГА. 2022. Т. 25. № 02. С. 1-12.
  4. Grebenkin A., Burdun I. Landing under extreme conditions: early safety screening by means of the "pilot-automaton-air-craft-operating environment" system dynamics model // SAE 2019 Aviation Technology Forum. 2019.
  5. Гребенкин А.В., Лушников А.А. Учет человеческого фактора в задачах интеграции ручного и автоматического управления в сложных многофакторных условиях посадки магистрального самолета // Сб. науч. ст. по материалам II Всероссийского форума с международным участием "Академические Жуковские чтения", Воронеж: ВУНЦ ВВС "ВВА", 2022. С. 224-231.
  6. Никифоров С.П. Бортовая система контроля разбега - эффективное средство повышения безопасности взлетов транспортных самолетов // ТВФ № 3-4. 2002. С. 47-54.
  7. Shevchenko A. Some Means for Informational Support of Airliner Pilot // 5th Int. Scientific Conf. on Physics and Control (Physcon 2011). Leon, Spain. 2011. P. 1-5.
  8. Kuznetsov A., Shevchenko A., Solonnikov Ju. The Methods of Forecasting Some Events During the Aircraft Takeoff and Landing // 19th IFAC Symposium on Automatic Control in Aerospace (АСА2013). Germany. 2013. P. 183-187.
  9. Kurdjukov A., Nachinkina G., Shevtchenko A. Energy approach to flight control // AIAA Conf. Navigation, Guidance and Control. AAIA Paper 98-4211. Boston. 1998.
  10. Lambregts A. Vertical Flight Path and Speed Control Autopilot Design Using Total Energy Principles // AIAA Paper 83-2239CP. 1983. P. 559-569.

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