OPERATIVE CORRECTION OF AIRCRAFT TRAJECTORIES BASED ON AIRBORNE WEATHER RADARS INFORMATION

Authors

  • Yuliya Averyanova National Aviation University
  • Anna Rudiakova National Aviation University
  • Felix Yanovsky National Aviation University

DOI:

https://doi.org/10.18372/2306-1472.85.15133

Keywords:

meteorological radar, AWR, flight trajectory optimization algorithm

Abstract

Trajectory prediction and optimization capabilities are considered as crucial part for efficient Air Traffic Management (ATM) operation. One of the key factors that influence onto trajectory prediction is weather situation at the departure and arrival points and along the flight route. In this context it is important to utilize widely systems of operative obtaining information about weather hazards for short-term flight trajectory correction. Airborne weather radars (AWR) are powerful and convenient tool for operative data obtaining during the aircraft flight when atmospheric and weather disturbances arise. In this paper possibilities of trajectory correction by providing accurate and operative meteorological data using the onboard radar system are shown and discussed.

Author Biographies

Yuliya Averyanova, National Aviation University

Doctor of Engineering. Associate Professor. Professor of Air Navigation Systems Department. IEEE Senior Member. Education: National Aviation University. Kyiv. Ukraine (1999).

Anna Rudiakova, National Aviation University

Ph.D. Associate Professor. Education: Donetsk State University. Donetsk. Ukraine (1997).

Felix Yanovsky, National Aviation University

DSc (Engineering), PhD, Professor. Department of Electronics, Robotics, Monitoring and IoT Technologies (ERMIT). IEEE Life Fellow. Education: Kyiv Institute of Civil Aviation Engineers (Dec.1968).

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Published

22-12-2020

How to Cite

Averyanova, Y., Rudiakova, A., & Yanovsky, F. (2020). OPERATIVE CORRECTION OF AIRCRAFT TRAJECTORIES BASED ON AIRBORNE WEATHER RADARS INFORMATION. Proceedings of National Aviation University, 85(4), 13–20. https://doi.org/10.18372/2306-1472.85.15133

Issue

Vol. 85 No. 4 (2020)

Section

AEROSPACE SYSTEMS FOR MONITORING AND CONTROL

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