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  4. Kinematic design as a means of specification of aircraft coordinates

Kinematic design as a means of specification of aircraft coordinates

MMC.
2025;
Volume 12, Number 3
: pp. 862–871
Received: March 19, 2025
Revised: September 05, 2025
Accepted: September 08, 2025

Fostiak V. T., Aftanaziv I. S., Markovych B. M., Korendiy V. M., Vaskiv O. M., Romanych I. B. Kinematic design as a means of specification of aircraft coordinates.  Mathematical Modeling and Computing. Vol. 12, No. 3, pp. 862–871 (2025)

Authors:
  1. V. T. Fostiak
  2. I. S. Aftanaziv
  3. B. M. Markovych
  4. V. M. Korendiy
  5. O. M. Vaskiv
  6. I. B. Romanych
1
Lviv Polytechnic National University
2
Lviv Polytechnic National University
3
Lviv Polytechnic National University
4
Lviv Polytechnic National University
5
Ivan Franko National University of Lviv
6
Ivan Franko National University of Lviv

This study proposes a method for determining the spatial coordinates of a Shahed-type enemy UAV using 3D trilateration from three fixed ground observers with known locations.  By measuring distances to the UAV at discrete time intervals, its flight trajectory is reconstructed.  The analysis shows the UAV follows a uniform, curvilinear path with steady angular velocity and descending altitude, modeled through parametric equations.  This allows accurate prediction of future positions and identification of an optimal interception point.  The method ensures high spatial precision, supporting air defense operations even under conditions of signal loss or complex terrain.  The results are particularly relevant for improving mobile detection and response systems in modern warfare contexts, such as in Ukraine.

Shahed UAV
3D trilateration
trajectory prediction
interception modeling
uniform curvilinear motion
air defense
Localization
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