Development of a Compact Three-Degree-of-Freedom Laser Measurement System with Self-Wavelength Correction for Displacement Feedback of a Nanopositioning Stage

Cai, Yindi; Lou, Zhifeng; Ling, Siying; Liao, Bo-syun; Fan, Kuang‐Chao

doi:10.3390/app8112209

Cited by 15 publications

(23 citation statements)

References 26 publications

(33 reference statements)

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“…At the last step, before interpolation and determination of displacement, correction of residual ellipticity is carried out, if it is not eliminated in the optical branch, as well as for the correction of random phase deviations in real time. The signal errors depending on the positioning of elements in the optical system in accordance with Abbe errors [24,25] is not the subject of the current research, although it is very important in the practical realization. The Abbe errors need to be aligned in the scheme to avoid interference break in the plane of the photodetectors, where it is necessary to provide an interference strip of infinite wide.…”

Section: Optical Conceptmentioning

confidence: 99%

Phase Imbalance Optimization in Interference Linear Displacement Sensor with Surface Gratings

Одиноков

Shishova

Kovalev

et al. 2020

Sensors

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In interferential linear displacement sensors, accurate information about the position of the reading head is calculated out of a pair of quadrature (sine and cosine) signals. In double grating interference schemes, diffraction gratings combine the function of beam splitters and phase retardation devices. Specifically, the reference diffraction grating is located in the reading head and regulates the phase shifts in diffraction orders. Measurement diffraction grating moves along with the object and provides correspondence to the displacement coordinate. To stabilize the phase imbalance in the output quadrature signals of the sensor, we propose to calculate and optimize the parameters of these gratings, based not only on the energetic analysis, but along with phase relationships in diffraction orders. The optimization method is based on rigorous coupled-wave analysis simulation of the phase shifts of light in diffraction orders in the optical system. The phase properties of the reference diffraction grating in the interferential sensor are studied. It is confirmed that the possibility of quadrature modulation depends on parameters of static reference scale. The implemented optimization criteria are formulated in accordance with the signal generation process in the optical branch. Phase imbalance and amplification coefficients are derived from Heydemann elliptic correction and expressed through the diffraction efficiencies and phase retardations of the reference scale. The phase imbalance of the obtained quadrature signals is estimated in ellipticity correction terms depending on the uncertainties of influencing parameters.

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Section: Optical Conceptmentioning

confidence: 99%

Phase Imbalance Optimization in Interference Linear Displacement Sensor with Surface Gratings

Одиноков

Shishova

Kovalev

et al. 2020

Sensors

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“…This part includes incremental distance interferometer, absolute distance interferometer and grating diffraction interferometer. For the miniaturization of laser interferometer, a compact laser diode-based interferometer was developed by Cai et al of Dalian University of Technology [20]. The wavelength cannot be determined by the Edlén Equation, which is mainly used for He-Ne lasers.…”

Section: Laser Interferometer Length Measurementsmentioning

confidence: 99%

Special Issue on Precision Dimensional Measurements

Fan

Chen

2019

Applied Sciences

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“…Linear stages, which are expected to travel along a straight line and precisely stop at some prescribed positions, play a crucial role in the manufacturing field and measurement field [1,2,3,4]. However, due to the manufacturing imperfections and the assembling errors, the linear stage inherits six-degree-of-freedom (six-DOF) error motions, including three linear errors (positioning error, horizontal and vertical straightness errors) and three angular errors (pitch, yaw and roll errors).…”

Section: Introductionmentioning

confidence: 99%

Error Analysis and Compensation of a Laser Measurement System for Simultaneously Measuring Five-Degree-of-Freedom Error Motions of Linear Stages

Cai

Sang

Lou

et al. 2019

Sensors

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A robust laser measurement system (LMS), consisting of a sensor head and a detecting part, for simultaneously measuring five-degree-of-freedom (five-DOF) error motions of linear stages, is proposed and characterized. For the purpose of long-travel measurement, all possible error sources that would affect the measurement accuracy are considered. This LMS not only integrates the merits of error compensations for the laser beam drift, beam spot variation, detector sensitivity variation, and non-parallelism of dual-beam that have been resolved by the author’s group before, but also eliminates the crosstalk errors among five-DOF error motions in this study. The feasibility and effectiveness of the designed LMS and modified measurement model are experimentally verified using a laboratory-built prototype. The experimental results show that the designed LSM has the capability of simultaneously measuring the five-DOF error motions of a linear stage up to one-meter travel with a linear error accuracy in sub-micrometer and an angular error accuracy in sub-arcsecond after compensation.

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Development of a Compact Three-Degree-of-Freedom Laser Measurement System with Self-Wavelength Correction for Displacement Feedback of a Nanopositioning Stage

Cited by 15 publications

References 26 publications

Phase Imbalance Optimization in Interference Linear Displacement Sensor with Surface Gratings

Phase Imbalance Optimization in Interference Linear Displacement Sensor with Surface Gratings

Special Issue on Precision Dimensional Measurements

Error Analysis and Compensation of a Laser Measurement System for Simultaneously Measuring Five-Degree-of-Freedom Error Motions of Linear Stages

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