Infrared and Laser Engineering, Volume. 51, Issue 5, 20210557(2022)
Friction observation compensation technology based on angular position information of photoelectric platform
[1] Zheng Chunyan, Zhang Honggang, Feng Xingwei, et al. ADRC of airborne electro-optical stabilized platform[J]. Electronics Optics & Control, 24, 51-54(2017).
[2] Hu Hongjie, Wang Yuanzhe. Composite compensation control scheme for airborne opto-electronic platform[J]. Optics and Precision Engineering, 20, 1272-1281(2012).
[3] Zhou Xiangyang, Yang Chao, Cai Tongtong. A model reference adaptive control/PID compound scheme on disturbance rejection for an aerial inertially stabilized platform[J]. Journal of Sensors, 17, 1-11(2016).
[4] Song Xiaoru, Chen Hua, Xue Yonggang. Stabilization precision control methods of photoelectric aim-stabilized system[J]. Optics Communications, 351, 115-120(2015).
[5] Zhang Mingyue, Liu Hui, Chu Hairong, et al. Double integral sliding mode control based on ESO for stabilized platform of seeker[J]. Infrared and Laser Engineering, 47, 0817009(2018).
[6] Chen Zengqiang, Liu Junjie, Sun Mingwei. Overview of a novel control method: active disturbance rejection control technology and its practical applications[J]. CAAI Transactions on Intelligent Systems, 13, 865-877(2018).
[7] Chen Xiaogang, Cai Meng, Dai Ning. A DOB based disturbance suppression method for airborne photoelectric stabilized platform[J]. Electronics Optics& Control, 27, 98-101(2020).
[8] Shi Lei, Xu Yongsen, Tian Dapeng, et al. Design of stable aviation platform operated by cable drive[J]. Optics and Precision Engineering, 28, 1245-1253(2020).
[9] Li Hongguang, Peng Fulun, Jiang Xu, et al. Stabilization platform of complex axes embedded into optical path for optics-electricity system with upside mirror[J]. Optics and Precision Engineering, 27, 2224-2232(2019).
[10] Ren Yan, Niu Zhiqiang. Application of new terminal sliding mode in photoelectric stabilized platform[J]. Infrared and Laser Engineering, 47, 0617005(2018).
[11] Zhang Zhiyong, Li Zhiqiang, Zhou Qingkun, et al. Application in prestiction friction compensation for angular velocity loop of inertially stabilized platforms[J]. Chinese Journal of Aeronautics, 27, 655-662(2014).
[12] Al-bender Farid, Swevers Jan. Characterization of friction force dynamics[J]. IEEE Control Systems Magazine, 28, 64-81(2008).
[13] Yao Jianyong, Jiao Zongxia, Yao Bin. Robust control for static loading of electro-hydraulic load simulator with friction compensation[J]. Chinese Journal of Aeronautics, 25, 954-962(2012).
[14] Chen Wenhua, Yang Jun, Guo Lei, et al. Disturbance observer-based control and related methods–An overview[J]. IEEE Transactions on Industrial Electronics, 63, 1083-1095(2016).
[15] [15] Wu Zhenyang. Digital Signal Processing[M]. Beijing: Higher Education Press, 2004: 134143. ( in Chinese)
[16] Sun Liteng, Dong Limin, Tang Chao. Design of electron wave Tilters in monolayer grapheme with velocity modulations[J]. Chin Phys B, 22, 1-5(2013).
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Yang Yu, Honggang Zhang, Junke Gao, Jiangang Wang. Friction observation compensation technology based on angular position information of photoelectric platform[J]. Infrared and Laser Engineering, 2022, 51(5): 20210557
Category: Photoelectric measurement
Received: Aug. 10, 2021
Accepted: --
Published Online: Jun. 14, 2022
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