Assessment of Capacitor-based Charge Estimators for Piezoelectric Actuators

2021 IEEE International Conference on Mechatronics (ICM) Pub Date : 2021-03-07 DOI:10.1109/ICM46511.2021.9385677

M. Mohammadzaheri, Sami AlSulti, M. Ghodsi, I. Bahadur, Mohammadreza Emadi

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引用次数: 2

Abstract

This paper focuses at charge estimators of piezoelectric actuators with a sensing capacitor. They have been claimed in the literature to be outperformed by their newly emerged competitors, charge estimators with a sensing resistor, widely known as digital charge estimators. This paper proposes a digital implementation of capacitor-based estimators and compares them with resistor-based ones both analytically and experimentally. Although, the sensing capacitors are normally bulkier than the sensing resistors used in newer resistor-based estimators; a resistor-based estimator needs to have a variable resistance to deal with different excitation frequencies satisfactorily; this is a major drawback which does not exist in capacitor-based estimators. Both capacitor-based and resistor-based estimators, if designed appropriately, are quite comparable in terms of voltage drop and range of measurable charge. This research concludes that capacitor-based estimators, with right design and implementation, can be still of wide use in nanopositioning.

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基于电容的压电执行器电荷估计器的评估

本文主要研究带传感电容的压电执行器的电荷估计问题。他们已经在文献中声称，优于他们的新出现的竞争对手，电荷估计与传感电阻，广泛称为数字电荷估计。本文提出了一种基于电容的估计器的数字实现方法，并将其与基于电阻的估计器进行了分析和实验比较。虽然，传感电容器通常比在新的基于电阻的估计器中使用的传感电阻体积更大;基于电阻器的估计器需要具有可变电阻才能令人满意地处理不同的激励频率;这是在基于电容的估计器中不存在的一个主要缺点。基于电容和基于电阻的估计器，如果设计得当，在电压降和可测量电荷范围方面是相当可比的。该研究表明，只要设计和实现得当，基于电容的估计器在纳米定位中仍有广泛的应用前景。

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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2021 IEEE International Conference on Mechatronics (ICM)

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