Design of Real-time nspection System for Unmanned Aerial Vehicle (UAV) Power Assemblies.
Аuthors
1*, 1, 2, 1, 1, 1, 11. Nanjing Univ Aeronaut & Astronaut, Nanjing, China
2. Harbin Institute of Technology, Suzhou, China
*e-mail: xinmai_xm@nuaa.edu.cn
Abstract
Although drones are not a new type of equipment, their advantages in application are very significant, and they can accomplish many dangerous and difficult operations. This type of equipment has been widely used in various fields, both in the military field and the civil field, with excellent performance, reflecting high application value. However, in the absence of engineers and technicians to accompany the situation, especially in the event of failure, there will be a very passive situation. The maintenance of such equipment is of great significance, and the safeguarding of the engine, as the core power component of the UAV, is even more important. Therefore, it is necessary to use advanced technology to monitor the power system in real-time, predict the occurrence of failures, and repair them beforehand, to keep the equipment in good condition. By using LABVIEW2022, combined with various algorithms of time-frequency analysis technology, this research team develops a corresponding vibration signal analysis tool to realize the study of signals and fault identification. We have developed a wireless signal fidelity transmission system based on a variety of technologies to realize effective transmission of engine vibration signals over various distances. By combining the above signal analysis tools and transmission systems, the state monitoring and analysis of the UAV power system at various distances was finally realized. The performance parameters and indexes of the equipment are in line with the needs of engineering applications, which can effectively solve the problems of research on the engine system of unmanned aircraft. Many experiments have proved that the study of engine vibration signals carried by UAVs is a simple and intuitive detection method, and the combination of high-performance vibration sensors, high-fidelity transmission devices, and powerful analysis systems can realize the above application goals.
Keywords:
UAV, powertrain, Real-time non-destructive testingReferences
1. Guseinov G.A. et al. Trudy MAI, 2022, no. 126. URL: https://trudymai.ru/eng/published.php?ID=169012. DOI: 10.34759/trd-2022-126-26
2. Turner Cotterman et al. The transition to electrified vehicles: Evaluating the labor demand of manufacturing conventional versus battery electric vehicle powertrains, Energy Policy, 2024, vol. 188, pp. 114064. DOI: 10.1016/J.ENPOL.2024.114064
3. Suman Saha, Partha Pratim Bandyopadhyay. Non-destructive measurement of MUCT in micro-milling using surface topography generated by bi-planer size effects, International Journal of Mechanical Sciences, 2024, vol. 275, pp. 109332. DOI:10.1016/J.IJMECSCI.2024.109332
4. Mohamed Adel Gabry et al. Advanced Deep Learning for microseismic events prediction for hydraulic fracture treatment via Continuous Wavelet Transform, Geoenergy Science and Engineering, 2024, vol. 239, pp. 212983. DOI:10.1016/J.GEOEN.2024.212983
5. Jae Ho Sim et al. Deep Learning Model for Cosmetic Gel Classification Based on a Short-Time Fourier Transform and Spectrogram, ACS applied materials & interfaces, 2024. DOI:10.1021/ACSAMI.4C03675
6. Scott F Thrall et al. A comparison of wavelet-based action potential detection from the NeuroAmp and the Iowa Bioengineering Nerve Traffic Analysis system, Journal of neurophysiology, 2024. DOI:10.1152/JN.00448.2023
7. Demi Ai, Duluan Zhang, Hongping Zhu. A damage localization approach for concrete structure using discrete wavelet transform of electromechanical admittance of bonded PZT transducers, Mechanical Systems and Signal Processing, 2024, vol. 218, pp. 111531. DOI: 10.1016/J.YMSSP.2024.111531
8. Minesh K Joshi, Patel R R. Fault detection through discrete wavelet transforms and radial basis function neural network in shunt compensated distribution systems, Engineering Research Express, 2024, vol. 6.2. DOI:10.1088/2631-8695/AD46E7
9. Benamira Nadir et al. Exploring the effects of overvoltage unbalances on three phase induction motors: Insights from motor current spectral analysis and discrete wavelet transform energy assessment, Computers and Electrical Engineering, 2024, vol. 117, pp. 109242. DOI:10.1016/J.COMPELECENG.2024.109242
10. Alimagadov K.A., Umnyashkin S.V. White Noise Suppression Based on Wiener Filtering Using Neural Network Technologies in the Domain of the Discrete Wavelet Transform, Russian Microelectronics, 2024, vol. 52.7, pp. 722-729. DOI:10.1134/S106373972307003X
11. Pavani Cherukuru, Mumtaz Begum Mustafa. CNN-based noise reduction for multi-channel speech enhancement system with discrete wavelet transform (DWT) preprocessing, PeerJ Computer science, 2024, vol. 10. DOI:10.7717/PEERJ-CS.1901
12. Dash Sonali et al. Real Time Retinal Optic Disc Segmentation via Guided filter and Discrete Wavelet Transform, Journal of Physics: Conference Series, 2022, vol. 2312.1. DOI:10.1088/1742-6596/2312/1/012007
13. Ravikumar M., Shivaprasad B.J., Guru D.S. Enhancement of MRI Brain Images Using Notch Filter Based on Discrete Wavelet Transform, International Journal of Image and Graphics, 2022, vol. 22.01. DOI:10.1142/S0219467822500103
14. Goran Savić et al. Memory Efficient Hardware Architecture for 5/3 Lifting-Based 2-D Forward Discrete Wavelet Transform, Microprocessors and Microsystems, 2021, vol. 87, pp. 104176. DOI:10.1016/J.MICPRO.2021.104176
15. Tong Hao et al. Automatic Detection of Subglacial Water Bodies in the AGAP Region, East Antarctica, Based on Short-Time Fourier Transform, Remote Sensing, 2023, vol. 15.2, pp. 363-363. DOI:10.3390/RS1502036
16. Patrick D. Cerna et al. Bisayan Dialect Short-time Fourier Transform Audio Recognition System using Convolutional and Recurrent Neural Network, International Journal of Advanced Computer Science and Applications (IJACSA), 2023, vol. 14.3. DOI: 10.1456vol/9/IJACSA.2023.01403111
17. Knutsen Helge. A fractal uncertainty principle for the short-time Fourier transform and Gabor multipliers, Applied and Computational Harmonic Analysis, 2023, vol. 62, pp. 365-389. DOI:10.1016/J.ACHA.2022.10.001
18. Amiri Mohsen, Aghaeinia Hassan, Amindavar Hamid Reza. Automatic epileptic seizure detection in EEG signals using sparse common, spatial pattern and adaptive short-time Fourier transform-based synchrosqueezing transform, Biomedical Signal Processing and Control, 2023, vol. 79. DOI:10.1016/J.BSPC.2022.104022
19. Zachary Huffman, Joana Rocha. The Derivation of an Empirical Model to Estimate the Power Spectral Density of Turbulent Boundary Layer Wall Pressure in Aircraft Using Machine Learning Regression Techniques, Aerospace, 2024, vol. 11.6, pp. 446. DOI:10.3390/AEROSPACE11060446
20. Marius Bittner, Marco Behrendt, Michael Beer. Relaxed evolutionary power spectral density functions: A probabilistic approach to model uncertainties of non-stationary stochastic signals, Mechanical Systems and Signal Processing, 2024, vol. 211, pp, 111210. DOI:10.1016/J.YMSSP.2024.111210
21. Jian Yu et al. Evolutionary power spectrum density of earthquake-induced rail geometric irregularities, Structure and Infrastructure Engineering, 2022, vol. 20 (3), pp. 1-16. DOI: 10.1080/15732479.2022.2103155
22. Yoshiki Murayama et al. Characterization of larger-single-Lorentzian noise deviated from 1/f characteristics detected by a power-spectral-density-integration method, Japanese Journal of Applied Physics, 2024, vol. 63.3.
23. WonsulKim et al. Cumulative power spectral density‐based damping estimation, Earthquake Engineering & Structural Dynamics, 2024, vol. 53.5, pp. 1787-1802. DOI:10.1002/EQE.4092
24. Bol'shakov R.S, Gozbenko V.E., Vyong K.Ch. Trudy MAI, 2023, no. 133. URL: https://trudymai.ru/eng/published.php?ID=177669
25. Xuejiang Chen et al. A short time series rolling bearing fault diagnosis method based on FMTF-CNN, Engineering Research Express, 2024, vol. 6.2. DOI:10.1088/2631-8695/AD4957
26. Zaitsev D.O., Pavlov D.A., Nestechuk E.A. Trudy MAI, 2021, no. 121. URL: https://trudymai.ru/eng/published.php?ID=162665. DOI: 10.34759/trd-2021- 121-18
27. Gerasimchuk V.V., Zhiryakov A.V., Kuznetsov D.A., Telepnev P.P. Trudy MAI, 2023, no. 131. URL: https://trudymai.ru/eng/published.php?ID=175908. DOI: 10.34759/trd-2023-131-02
28. Al'rubei M.A. Trudy MAI, 2023, no. 130. URL: https://trudymai.ru/eng/published.php?ID=174612. DOI: 10.34759/trd-2023-130-15
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