An Overview of Piezoelectric Self-Sensing Actuation for Nanopositioning Applications: Electrical Circuits, Displacement, and Force Estimation

Liseli, Joël Bafumba; Agnus, Joël; Lutz, Philippe; Rakotondrabe, Micky

doi:10.1109/tim.2019.2950760

Cited by 42 publications

(26 citation statements)

References 87 publications

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“…The mechanics of the hysteresis curve of the PEA employed is shown in Figure 3, which was produced by using 2 triangle cycles with the previously described features where the maximum hysteresis achieved was 4.47 µm at 37.7 V. The sequence starts at the initial point ( 1) which is also known as the initial point since it is where the PEA undertakes its operation; thus, a first ascending curve climbs until (2), which is the upper target point at the maximum voltage (145 VCC). Thereafter, the fall is through an asymmetric path along the first descending curve until (3), the lower converging point.…”

Section: Hysteresis and References Usedmentioning

confidence: 99%

“…In the early 1970s, the high accuracy positioning was constrained only at academic domains; however, as a result of advanced fabrication methods, the beginning of the current century leads the possibility of bringing micro-actuators in industrial environments [1]. Piezoelectric actuators (PEAs) are suitable candidates when there is an application that needs for nano-microdisplacement combined with precision as requirements [2]. Additionally, these systems provide accuracy and mechanical capabilities due to their high stiffness [3].…”

Section: Introductionmentioning

confidence: 99%

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High-Performance Tracking for Piezoelectric Actuators Using Super-Twisting Algorithm Based on Artificial Neural Networks

et al. 2021

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Piezoelectric actuators (PEA) are frequently employed in applications where nano-Micr-odisplacement is required because of their high-precision performance. However, the positioning is affected substantially by the hysteresis which resembles in an nonlinear effect. In addition, hysteresis mathematical models own deficiencies that can influence on the reference following performance. The objective of this study was to enhance the tracking accuracy of a commercial PEA stack actuator with the implementation of a novel approach which consists in the use of a Super-Twisting Algorithm (STA) combined with artificial neural networks (ANN). A Lyapunov stability proof is bestowed to explain the theoretical solution. Experimental results of the proposed method were compared with a proportional-integral-derivative (PID) controller. The outcomes in a real PEA reported that the novel structure is stable as it was proved theoretically, and the experiments provided a significant error reduction in contrast with the PID.

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Section: Hysteresis and References Usedmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

High-Performance Tracking for Piezoelectric Actuators Using Super-Twisting Algorithm Based on Artificial Neural Networks

et al. 2021

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“…The principle known as self-sensing describes the ability of piezoelectric actuators to determine physical states such as deflection xpiezo or applied force Fpiezo without use of external sensors [8]. Values are determined by using signals, which are generated by the piezoelectric actuator itself and can be measured with relatively little effort.…”

Section: Self-sensingmentioning

confidence: 99%

“…There are different approaches for "self-sensing" that use either the piezoelectric effect or the changes in electrical properties of the actuators [8]. The use of the piezoelectric effect is based on the reversible correlation between an applied force Fpiezo and the generation of an electric field E caused by electrical charges q.…”

Section: Self-sensingmentioning

confidence: 99%

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Accuracy in Force Estimation Applied on a Piezoelectric Fine Positioning System for Machine Tools

Uhlmann¹,

Polte²,

Triebel³

et al. 2021

Journal of Machine Engineering

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In order to improve the accuracy of machine tools, the use of additional active modules meeting the requirements of the "Plug & Produce" approach is focused. In this context one approach is the installation of a high precision positioning table for online compensation of machine tool deflections. For the model-based determination of the deflection, the knowledge of the effecting process force is crucial. This article examines the use of displacement sensors for force estimation in a piezoelectric system. The method is implemented on a high precision positioning table applicable in milling machine tools. In order to compensate nonlinear effects of piezoelectric actuators, a hysteresis operator is implemented. Experimental investigations are carried out to quantify the influence of preload stiffness, preload force and workpiece weight. Finally, a resolution d ≤ 78 N could be achieved and further improvements to meet the requirements for online compensation of machine tool deflection are discussed.

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Control design for beam stabilization with self-sensing piezoelectric actuators: managing presence and absence of hysteresis

Mattioni,

Prieur,

Tarbouriech

2024

Math. Control Signals Syst.

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An Overview of Piezoelectric Self-Sensing Actuation for Nanopositioning Applications: Electrical Circuits, Displacement, and Force Estimation

Cited by 42 publications

References 87 publications

High-Performance Tracking for Piezoelectric Actuators Using Super-Twisting Algorithm Based on Artificial Neural Networks

High-Performance Tracking for Piezoelectric Actuators Using Super-Twisting Algorithm Based on Artificial Neural Networks

Accuracy in Force Estimation Applied on a Piezoelectric Fine Positioning System for Machine Tools

Control design for beam stabilization with self-sensing piezoelectric actuators: managing presence and absence of hysteresis

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