Abstract
Fractional-order flight control has a history of nearly 10 years. Fractional-order controllers (FOCs) have been proved to be better in rising time, overshoot and robustness against plant variation. However, there are still not many real applications of FOC in industry. More case studies need to be carried out to accelerate the maturation of FOC. Quadrotor vision-based control often has a large and time-varying sampling period due to drone’s resource limitation. Therefore, our research has been focused on a specific case for drone vision-based control to investigate the benefits of FOC. In this paper, FOC has been first discovered to be able to tolerate larger sampling period than integer-order controllers. This fact has been proved both theoretically and numerically. First of all, the speed model was identified from real flight tests. Then an integral-order proportional, integral and derivative (IOPID) controller and a fractional-order proportional–derivative (FOPD) controller were designed. After that, a stability criteria, optimization method, graphic method and parallel computing techniques were employed to theoretically prove that the largest sampling period of the designed FOC (0.933 s) is much larger than that of the designed integral-order controller (0.546 s). Later, Simulink simulation with identified linear model proved that the FOC can tolerate larger sampling period. Finally, flight tests showed that the designed FOC has a nearly 20% better precision on drone vision-based hovering than the IOC.
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Acknowledgements
Thank Bo Shang’s wife Juyao Dong’s support on taking care of their little daughter. Thank Bo Shang’s parents’ financial support to keep this research going on.
Funding
This work was supported in part by Xihua University, China Scholarship Council (CSC), Shenyang City Foundation #17-87-0-00, the National Natural Science Foundation of China under Grant nos. 61701101, U1713216, 61803077, the National Key Robot Project under Grant nos. 2017YFB1300900, 2017YFB1301103, and the Fundamental Research Fund for the Central Universities of China N172603001, N181602014, N172604004, N172604003, and N172604002.
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This work was supported in part by the research project granted by Xihua University and China Scholarship Council (CSC), National Key R&D Program of China, No. 2017YFB1300900 and Shenyang City Foundation #17-87-0-00.
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Shang, B., Liu, J., Zhang, Y. et al. Fractional-order flight control of quadrotor UAS on vision-based precision hovering with larger sampling period. Nonlinear Dyn 97, 1735–1746 (2019). https://doi.org/10.1007/s11071-019-05103-5
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DOI: https://doi.org/10.1007/s11071-019-05103-5