Response spectrum-based analysis of airborne radar random vibration and multi-point control improvement

During the flight of a UAV (unmanned aerial vehicle), the LiDAR device undergoes random vibrations due to the changing flight attitude and wind speed conditions of the UAV. It is important to control the frequency and amplitude of the vibrations within a reasonable range by means of a damping struct...

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Bibliographic Details
Published in:Scientific reports 2024-03, Vol.14 (1), p.7565-7565, Article 7565
Main Authors: Liu, Jie, Liu, Zezheng, Chen, Wanqian, Lv, Jing, Jiang, Zixuan, Pang, Jiahao, Du, Libin
Format: Article
Language:English
Subjects:
639/166/988
639/766/189
639/766/930/1032
Flight
Humanities and Social Sciences
Lidar
Multi-point control
multidisciplinary
Radar
Random vibration
Response spectrum
Science
Science (multidisciplinary)
Spectrum analysis
Synthetic shock response
Unmanned aerial vehicles
Vibration
Vibrations
Virtual excitation
Wind speed
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Summary:During the flight of a UAV (unmanned aerial vehicle), the LiDAR device undergoes random vibrations due to the changing flight attitude and wind speed conditions of the UAV. It is important to control the frequency and amplitude of the vibrations within a reasonable range by means of a damping structure. As the vibrations caused by various factors during flight are random and non-linear, this paper innovates the analysis principle and damping control means for the random vibrations of airborne optoelectronic devices. The response spectrum analysis theory is used to establish the shock response spectrum, and an optimised and improved recursive digital filtering method is used to fit the frequencies of random vibration to the synthetic shock response. Considering the uncertainty of the vibration excitation signal, a virtual excitation method is used for the first time to simulate the random vibration to which the radar may be subjected in the air, and to simplify the calculation steps. The shock plate structure is designed using a multi-point control method to innovate a passive response to the random excitation. Finally, a modal analysis of the synthesised impact response was carried out. It is verified that the first six modal frequencies are controlled within 220 Hz, realising the frequency reduction. The amplitude of the three x, y, and z directions is controlled to within 0.5 mm, thus achieving vibration damping.
ISSN:2045-2322
2045-2322
DOI:10.1038/s41598-024-56783-y