约束调整修正模式超声波执行直线运动平台的非线性控制

IF 0.4 4区 工程技术 Q4 ENGINEERING, MULTIDISCIPLINARY Instruments and Experimental Techniques Pub Date : 2024-10-23 DOI:10.1134/S0020441224700659
F.-L. Wen, M.-H. Lai, C.-P. Wen
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引用次数: 0

摘要

基于比例-积分-派生(PID)的滑模控制(SMC)被应用于由约束调整修正模式(CTMM)超声波致动器驱动的线性平台。根据 CTMM 超声波致动器上的电压振幅和预载的驱动变化,基于 PID 的 SMC 控制器几乎可以完全抑制非线性现象,如机电共振中的频率偏移和移动响应中的死区。利用系统识别技术,可以为基于 PID 的 SMC 控制器的等效控制项获得线性级的近似二阶模型。通过估计模型误差,开关控制项的设计用于补偿机电耦合下谐振频率的移动特性。在跟踪实验中,目标命令整形函数与系统的响应速度相匹配。实验结果表明,SMC 控制器具有噪声抑制能力,可在双边跟踪运动中控制滑块的位置。其分辨率足以接近微米级精度。
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Nonlinear Control for Constraint-tuning Modified-mode Ultrasonic Actuating Linear Stage

A proportional-integral-derivative-based (PID based) sliding mode control (SMC) was applied to the linear stage driven by a constraint-tuning modified-mode (CTMM) ultrasonic actuator. Based upon the driving variation of voltage amplitude and the preload on the CTMM ultrasonic actuator, nonlinear phenomena, such as frequencies shifting in electromechanical resonance and the dead zone in moving response, could be suppressed almost completely by the PID based SMC controller with output biases. Using system identification technique, an approximate second-order model of the linear stage could be obtained for the equivalent control term of the PID based SMC controller. Through an estimated model error, the design of the switching control term was used to compensate for the shifting property of resonant frequencies under electromechanical coupling. A target-command-shaping function matched the responding speed of the system during tracking experiments. Experimental results demonstrate that the SMC controller has the capacity for noise rejection to control the slider’s position in bilateral tracking motions. Its resolution is sufficient to approach micrometer-level accuracy.

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来源期刊
Instruments and Experimental Techniques
Instruments and Experimental Techniques 工程技术-工程:综合
CiteScore
1.20
自引率
33.30%
发文量
113
审稿时长
4-8 weeks
期刊介绍: Instruments and Experimental Techniques is an international peer reviewed journal that publishes reviews describing advanced methods for physical measurements and techniques and original articles that present techniques for physical measurements, principles of operation, design, methods of application, and analysis of the operation of physical instruments used in all fields of experimental physics and when conducting measurements using physical methods and instruments in astronomy, natural sciences, chemistry, biology, medicine, and ecology.
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