Piezo displacement sensors for a compact high-speed x–y nanopositioner in differential actuation mode

Bazaei, Ali; Boudaoud, Mokrane; Ettefagh, Massoud Hemmasian; Chen, Zhiyong; Regnier, Stephane

Title: Piezo displacement sensors for a compact high-speed x–y nanopositioner in differential actuation mode
Creator: Bazaei, Ali; Boudaoud, Mokrane; Ettefagh, Massoud Hemmasian; Chen, Zhiyong; Regnier, Stephane
Relation: Mechatronics Vol. 86, Issue October 2022, no. 102860
Publisher Link: http://dx.doi.org/10.1016/j.mechatronics.2022.102860
Publisher: Elsevier
Resource Type: journal article
Date: 2022
Description: An emerging actuation technique in piezo driven nanopositioners is differential actuation, where each axis has two opposing actuators that operate differentially and provide bilateral motion. It has simultaneous benefits of improving linearity and range of displacement. However, few methods for displacement sensing employing in-situ transducers have been considered for this kind of nanopositioners. We address a novel application of PZT piezoelectric chips for direct displacement sensing in differentially driven nanopositioners. First, an electromechanical force analysis is performed in order to increase the PZT sensor sensitivity through the structural design of the nanopositioner. Secondly, the sensing performances of the proposed in-situ PZT sensor are compared with those from an alternative built-in piezoresistive (PZR) strain gauge sensor under equal circumstances, in different sensing and actuation configurations. While the PZR sensor has a larger sensing bandwidth than the PZT one and performs better if the actuation frequency is smaller than 30 Hz, the PZT sensors provides better accuracy when the actuation is well within its sensing bandwidth. The accuracy of the differential sensors and the input-displacement linearity are improved when the mechanical preload force magnitudes on the opposing actuators are balanced. The differential PZT sensor can provide accurate measurements even in a non-differential mode after recalibration.
Subject: displacement sensor; Piezoelectric transducer; Piezoresistive silicon strain gauge; nanopositioner; differential actuation; differential sensor
Identifier: http://hdl.handle.net/1959.13/1487448
Identifier: uon:52142
Identifier: ISSN:0957-4158
Language: eng
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