基于扰动观测器的光电稳定平台摩擦补偿策略

doi:10.13229/j.cnki.jdxbgxb201706028

Abstract

Abstract: In order to improve the isolation degree of disturbance of photoelectric stabilized platform, a friction compensations strategy based on Disturbance Observer (DOB) was put forward. First, the model of velocity loop was established by mechanism analysis, then a disturbance control scheme was proposed. Second, the identifications of the friction model parameters were determined by experiments. Based on the friction compensation control strategy, the DOB control strategy was designed. The accuracy of the strategy was verified by experiments. Finally, in order to test the feasibility and necessity of the control scheme, the aerial photoelectric stabilized platform was installed on the simulation platform, and the disturbance rejection capability of the platform was tested after the friction compensation and DOB were used. Experiment results show that, when the frequency of disturbance is within 3 Hz, the system disturbance isolation degree is increased by at least 14.52 dB. When the system is running at low speed, the tracking performance is improved obviously, and the tracking error is reduced from 0.1959 °/s to 0.0838 °/s. This control strategy can attenuate the mass unbalance torque. It has strong robustness and practical value.

Key words: automatic control technology, aerial photoelectrical stabilized platform, friction compensation, parameter identification, disturbance observer(DOB)

CLC Number:

TP273

JIN Chao-qiong, ZHANG Bao, LI Xian-tao, SHEN Shuai, ZHU Feng. Friction compensation strategy of photoelectric stabilized platform based on disturbance observer[J].吉林大学学报(工学版), 2017, 47(6): 1876-1885.

References

[1] 丛爽,孙光立,邓科,等. 陀螺稳定平台的自抗扰及其滤波控制[J]. 光学精密工程,2016,24(1):169-177.
Cong Shuang,Sun Guang-li,Deng Ke, et al. Active disturbance rejection and filter control of gyro-stabilized platform[J]. Optics and Precision Engineering,2016,24(1):169-177.
[2] Tian Da-peng, Shen Hong-hai, Dai Ming. Improving the rapidity of nonlinear tracking differentiator via feedforward[J]. IEEE Transactions on Industrial Electronics,2014,61(7):3736-3743.
[3] 李贤涛,张葆,孙敬辉,等. 航空光电稳定平台扰动频率自适应的自抗扰控制[J]. 红外与激光工程,2014,43(5):1574-1581.
Li Xian-tao,Zhang bao,Sun Jing-hui,et al. ADRC based on disturbance frequency adaptive of aerial photoelectrical stabilized platform[J]. Infrared and Laser Engineering, 2014,43(5):1574-1581.
[4] 汪达兴,杜福嘉. 大型天文望远镜摩擦传动系统低速特性的究[J]. 光学精密工程,2006,14(2):274-278.
Wang Da-xing,Du Fu-jia. Ultra-low speed research on friction driver for astronomical telescope[J]. Optics and Precision Engineering,2006,14(2):274-278.
[5] 克晶,苏宝库,曾鸣. 一种直流力矩电机系统的滞滑摩擦补偿方法[J]. 哈尔滨工业大学学报,2005,37(6):736-739.
Ke Jing,Su Bao-ku,Zeng Ming. Nonlinear stick slip friction compensation for DC motors[J]. Journal of Harbin Institute of Technology,2005,37(6):736-739.
[6] 魏伟,戴明,李嘉全,等. 基于重复-自抗扰控制的航空光电稳定平台控制系统设计[J]. 吉林大学学报:工学版,2015,45(6):1924-1932.
Wei Wei, Dai Ming,Li Jia-quan, et al. Design of airborne opto-electric platform control system based on ADRC and repetitive control theory[J]. Journal of Jilin University (Engineering and Technology Edition),2015,45(6):1924-1932.
[7] Harony A, Friedland B, Cohn S. Modeling and measuring friction effects: physics, apparatus, and experiments[J]. IEEE Control Systems Magazine,2008,28(6):82-91.
[8] Masten M K. Inertially stabilized platforms for optical imaging systems: tracking dynamic targets with mobile sensors[J]. IEEE Control Systems Magazine,2008,28(1):47-64.
[9] 向红标,裘祖荣,李醒飞,等. 精密实验平台的非线性摩擦建模与补偿[J]. 光学精密工程,2010,18(5):1119-1127.
Xiang Hong-biao,Qiu Zu-rong,Li Xing-fei,et al. Nonlinear friction modeling and compensation of high-precision experimental platform[J]. Optics and Precision Engineering,2010,18(5):1119-1127.
[10] Armstrong-Hélouvry B,Dupont P,de Wit C C. A survey of models, analysis tools and compensation methods for the control of machines with friction[J]. Automatica,1994,30(7):1083-1138.
[11] Johanastrom K, de Wit C C. Revisiting the LuGre friction model[J]. IEEE Control Systems,2008,28(6):101-114.
[12] 汪永阳,戴明,丁策,等. 光电稳定平台中高阶扰动观测器的应用[J]. 光学精密工程,2015,23(2):459-466.
Wang Yong-yang,Dai Ming,Ding Ce,et al. Application of high order disturbance observer in EO stabilized platform[J]. Optics and Precision Engineering,2015,23(2):459-466.
[13] 李贤涛,张葆,赵春蕾,等. 基于自适应的自抗扰控制技术提高扰动隔离度[J]. 吉林大学学报:工学版,2015,45(1):202-208.
Li Xian-tao,Zhang bao,Zhao Chun-lei, et al. Improve isolation degree based on adaptive active disturbance rejection controller[J]. Journal of Jilin University(Engineering and Technology Edition),2015,45(1):202-208.

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