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ISSN 2415-3400 (Online)
ISSN 1028-821X (Print)

Usage of phase portraits in analysis of doppler signals reflected from drone rotors

heading: 
RADIOWAVE PROPAGATION, RADIOLOCATION AND REMOTE SENSING
Pashchenko, RE, Ivanov, VK, Tsyupak, DO
Organization: 

 

O. Ya. Usikov Institute for Radiophysics and Electronics of the National Academy of Sciences of Ukraine
12, Proskura st., Kharkov, 61085, Ukraine
E-mail:  r.paschenko@i.ua , ivanov@ire.kharkov.ua , tsyupak87@mail.ru
https://doi.org/10.15407/rej2020.04.018
Language: ukranian
Abstract: 

 

Subject and Purpose. Comparative analysis of the shapes of phase portraits of Doppler signals (DS) reflected from drone rotating rotors is given with regard to different time delays. The shapes of DS phase portraits are examined for various rotational velocities and numbers of the rotating rotors.

Methods and Methodology. A method using phase portraits is suggested for analysis of Doppler signals reflected from drone rotating rotors. The method determines the number of the rotors and estimates their rotational velocities.

Results. It has been found that the shape of the phase portrait of the baseline signal is practically independent of the time delay and can be described as an occasional movement of the image point following the phase trajectory in the center of the phase portrait. The appearance of characteristic regions on the periphery of the phase portrait allows separating baseline and sounding signals. It has been shown that the shape of the DS phase portrait of the rotating rotor during the flight movement of the drone depends on the time delay value. With a larger delay, phase portraits similar in shape appear at regular intervals equal to the Doppler signal period. With a larger rotational velocity of the rotor, the rate of similar phase portrait appearance diminishes.

Conclusion. During the sounding of drone rotating rotors, the shapes of DS phase portraits depend on the value of time delay. With a larger number of rotors in the drone flight, the periodic change character as to the DS phase portrait shape remains unchanged. In this case, DS phase portrait shapes differ substantially for different numbers of drone rotors
Keywords: Doppler signal, drone, phase portrait, pseudophase plane

Manuscript submitted  13.07.2020
Radiofiz. elektron. 2020, 25(4): 18-29
Full text (PDF)

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