XIONG Hui, LIN Yu, ZHANG Yanwei, LI Ruihua, SHU Junyi, YAN Xinjie, FENG Jianwei. Composite Current Control Method for Small Inertia Infrared Stable Platforms[J]. Infrared Technology , 2021, 43(2): 116-126.
Citation: XIONG Hui, LIN Yu, ZHANG Yanwei, LI Ruihua, SHU Junyi, YAN Xinjie, FENG Jianwei. Composite Current Control Method for Small Inertia Infrared Stable Platforms[J]. Infrared Technology , 2021, 43(2): 116-126.

Composite Current Control Method for Small Inertia Infrared Stable Platforms

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  • Received Date: December 20, 2020
  • Revised Date: January 05, 2021
  • Miniaturization and high dynamics are the development trends of infrared imaging stabilization platform technology. Owing to a small moment of inertia, traditional PI(Proportion Integral)-type current loop control cannot completely overcome the slope interference of the back electromotive force(back-EMF), which will reduce the dynamic response of small inertia infrared stable platforms. Concurrently, balancing dynamics and anti-disturbance performance is another difficulty with regard to high dynamic and small inertia infrared stable platform technology. To solve the a forenoted problems, a composite current control method based on dead-beat predictive control and extended state observation(ESO) is proposed in this paper, which effectively improves the dynamic response and anti-disturbance ability of small inertia infrared stable platforms. Simulation and experimental results show that the composite current control method reduces the settling time of the current loop of a small inertia infrared stable platform by 1/3. It also improves the dynamic performance and anti-disturbance performance of the speed response, and has good performance robustness.
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