永磁直线同步电动机伺服系统的自适应加加速度控制

doi:10.19595/j.cnki.1000-6753.tces.190675

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摘要针对永磁直线同步电动机（PMLSM）伺服系统中易受不确定性因素影响的问题, 该文提出一种自适应加加速度控制（AJC）方法。首先建立含有不确定性的PMLSM伺服系统动态方程。然后, 通过模型前馈控制补偿系统的参数不确定性所产生的模型误差, 提高系统的响应速度。最后, 采用AJC抑制系统中外部扰动、非线性摩擦力等不确定性因素, 自适应律使鲁棒增益收敛于有界范围内, 提高系统的鲁棒性;AJC的输出信号积分后形成了反馈控制律, 削弱了控制律中开关函数激励未建模动态引起的高频谐振, 保证了控制信号的稳定性和连续性。系统实验结果表明, 该控制方法能够产生平稳的控制信号, 明显地提高系统的控制性能, 减小跟踪误差, 避免高频振荡, 进而改善PMLSM伺服系统的控制精度。

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关键词 ：永磁直线同步电动机, 不确定性, 自适应加加速度控制, 鲁棒性

Abstract：An adaptive jerk control (AJC) scheme was proposed in view of the susceptibility of uncertainty factors in the permanent magnet linear synchronous motor (PMLSM) servo system. Firstly, the dynamic of the PMLSM servo system with uncertainties was established. Then, the model-based feedforward control was used to compensate for the dynamic error caused by parametric uncertainties, and the response speed of the system was improved. Moreover, AJC was adopted to suppress the uncertainties such as external disturbance and nonlinear friction in the system. Robust gain was convergent following an adaptive law in a bounded range and the robustness of the system was enhanced. The output signal of AJC was integrated to form the feedback control law, which weakened the high frequency resonance caused by unmodeled dynamics of the switching function excitation, ensuring the stability and continuity of the control signal. The experimental results indicate that the control method can generate a smooth control signal and the control performance of the system is improved significantly. The tracking error is reduced and high frequency oscillation is successfully avoided. The control precision of the PMLSM servo system is more accurate.

Key words： Permanent magnet linear synchronous motor uncertainty adaptive jerk control robustness

收稿日期: 2019-06-05

PACS:	TP273
	TM351

通讯作者: 赵希梅女, 1979年生, 教授, 博士生导师, 研究方向为电机控制、机器人控制、智能控制等。E-mail: zhaoxm_sut@163.com

作者简介: 原浩男, 1992年生, 博士研究生, 研究方向为直线伺服、智能控制等。E-mail: yuanhao_sut@163.com

引用本文:

原浩, 赵希梅. 永磁直线同步电动机伺服系统的自适应加加速度控制[J]. 电工技术学报, 2020, 35(16): 3406-3413. Yuan Hao, Zhao Ximei. Adaptive Jerk Control for Permanent Magnet Linear Synchronous Motor Servo System. Transactions of China Electrotechnical Society, 2020, 35(16): 3406-3413.

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