A distributed parameter Maxwell-Slip hysteresis model for piezoelectric actuators

2018 33rd Youth Academic Annual Conference of Chinese Association of Automation (YAC) Pub Date : 2018-05-18 DOI:10.1109/YAC.2018.8405796

Yanfang Liu, Desong Du, M. Huo, N. Qi, Kairui Cao

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Abstract

Hysteresis is an important nonlinearity existing in piezoelectric actuators. Modeling and compensation is a common approach to handle it. This paper proposes a distributed parameter Maxwell-slip (DPMS) model. It is extended from the Maxwell-slip (MS) model. The DPMS model replaces the spring-slider elements in the MS model by a sliding cell and a elastic cell with distributed parameters. The properties of the elastic cell are described by two functions, i.e. the saturation deformation function and the stiffness function. These two functions also govern the hysteresis generated by the DPMS model and only require a few parameters. An approach to identify model parameters are proposed. Experiments demonstrate the effectiveness of the DPMS model. With a linear function describing the saturation deformation function, only two parameters (the character length and a coefficient) are required and the normalized mean squire error is 1.96%. The hysteresis nonlinearity is reduced from 13.8% to 2.55% by 81.5% if it is compensated by the inverse DPMS model.

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压电作动器的分布参数Maxwell-Slip滞回模型

磁滞是压电作动器中存在的一种重要非线性。建模和补偿是处理它的常用方法。本文提出了一种分布参数麦克斯韦滑移(DPMS)模型。它是由麦克斯韦滑移(MS)模型推广而来的。DPMS模型用具有分布参数的滑动单元和弹性单元代替MS模型中的弹簧滑块单元。弹性单元的特性由饱和变形函数和刚度函数两个函数来描述。这两个函数还控制DPMS模型产生的滞后，只需要几个参数。提出了一种识别模型参数的方法。实验证明了DPMS模型的有效性。采用线性函数描述饱和变形函数，只需要两个参数(字符长度和系数)，归一化平均误差为1.96%。经反向DPMS模型补偿后，滞回非线性由13.8%减小到2.55%，减小幅度达81.5%。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2018 33rd Youth Academic Annual Conference of Chinese Association of Automation (YAC)

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