Non-contact Sub-nanometer Displacement Sensing Based on Optical Digital Coherent Detection Using Frequency-Domain Filters

Jingwen Wang; Jiang Hong; Xiaoyan Wang; Lianhui Zheng; Wen Ren; Huixian Yan

doi:10.1587/elex.21.20240089

This article has now been updated. Please use the final version.

Non-contact Sub-nanometer Displacement Sensing Based on Optical Digital Coherent Detection Using Frequency-Domain Filters

Jingwen Wang, Jiang Hong, Xiaoyan Wang, Lianhui Zheng, Wen Ren, Huixian Yan

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Keywords: displacement sensing, optical digital coherent detection, frequency domain filter, non-contact, sub-nanometer displacement

JOURNAL FREE ACCESS Advance online publication

Article ID: 21.20240089

DOI https://doi.org/10.1587/elex.21.20240089

The final version of this article is now available: Vol. 21 (2024), No. 9 pp. 20240089-20240089

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Abstract

We have introduced a sub-nanometer non-contact displacement sensing method using phase-diversity optical digital coherent detection. The initial work achieved 0.62 nm displacement sensing with a 0.21 nm resolution using a temporal domain filter. However, optimizing the filter for a sharp transition band and low order posed challenges, limiting noise filtering. To overcome this, frequency-domain filter is proposed and investigated in this work. Employing a frequency-domain bandpass filter improved resolution to 0.07 nm at 0.62 nm displacement, resulting in an 18.5 dB signal-to-noise ratio—8 dB higher than temporal domain filtering. This advancement enhances precision for applications in precision instruments without any additional cost.

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