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Microsystem Technologies
Published in: Microsystem Technologies 6/2018

20-11-2017 | Technical Paper

Compact compliant parallel XY nano-positioning stage with high dynamic performance, small crosstalk, and small yaw motion

Authors: Hak-Jun Lee, Siwoong Woo, Jaehyun Park, Jae-Heon Jeong, Myeonghyeon Kim, Jiheun Ryu, Dae-Gab Gweon, Young-Man Choi

Published in: Microsystem Technologies | Issue 6/2018

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Abstract

This paper presents a novel XY nano-positioning stage using a compliant parallel mechanism with small crosstalk and yaw motion. A parallel mechanism can implement multi-degree-of-freedom motion with a small footprint. However, this implies crosstalk between the motion axes. In an effort to reduce crosstalk and yaw motion, we proposed a novel flexure guide structure. The proposed stage consists of two flexure displacement amplifiers driven by piezoelectric actuators, two combined double four-bar flexure guides, and two additional parallelogram guides. To prevent the rotational deformation of one amplifier due to the transverse force of the other, we introduce an intermediate leaf spring at the output ends of the amplifiers. This new parallel mechanism is optimally designed based on an analytical model of the stage to assure small crosstalk and yaw motion. The analytical model is verified as being well-described using a finite element analysis. An XY nano-positioning stage of size 150 × 150 × 30 mm3 is fabricated following the optimal design. Experiments are carried out to verify the static and dynamic performances of the proposed XY nano-positioning stage. The proposed stage has an X and Y directional motion range of 120 μm in closed loop. The resolution of the stage is 3 nm in both the X and Y directional motions. The actual crosstalk and yaw were limited to 0.770 μm and 13.5 μrad, while in the optimal design they were estimated at 0.5 μm and 15 μrad, respectively.
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Metadata
Title
Compact compliant parallel XY nano-positioning stage with high dynamic performance, small crosstalk, and small yaw motion
Authors
Hak-Jun Lee
Siwoong Woo
Jaehyun Park
Jae-Heon Jeong
Myeonghyeon Kim
Jiheun Ryu
Dae-Gab Gweon
Young-Man Choi
Publication date
20-11-2017
Publisher
Springer Berlin Heidelberg
Published in
Microsystem Technologies / Issue 6/2018
Print ISSN: 0946-7076
Electronic ISSN: 1432-1858
DOI
https://doi.org/10.1007/s00542-017-3626-z

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