Micrometer-precision absolute distance measurement with a repetition-rate-locked soliton microcomb

The soliton microcomb has sparked interest in high-precision distance measurement, owing to its ultrahigh repetition rate and chip-integrated scale. We report absolute distance measurements based on synthetic wavelength interferometry with a soliton microcomb. We stabilized the repetition rate of 48...

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Bibliographic Details
Published in:Optics letters 2023-08, Vol.48 (16), p.4356-4359
Main Authors: Yang, Mingyue, Wang, Guochao, Wang, Zhichuang, Li, Xianbin, Zhu, Lingxiao, Wang, Weiqiang, Zhang, Wenfu, Yan, Shuhua, Yang, Jun
Format: Article
Language:English
Subjects:
Distance measurement
Formation flying
Frequency locking
Interferometers
Repetition
Solitary waves
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Summary:The soliton microcomb has sparked interest in high-precision distance measurement, owing to its ultrahigh repetition rate and chip-integrated scale. We report absolute distance measurements based on synthetic wavelength interferometry with a soliton microcomb. We stabilized the repetition rate of 48.98 GHz through injection locking, with fluctuations below 0.25 Hz. Distance measurements up to 64 mm were demonstrated, presenting residuals below 2.7 μ m compared with a referenced laser interferometer. Long-term distance measurements were made at two fixed positions of approximately 0.2 m and 1.4 m, resulting in a minimum Allan deviation as low as 56.2 nm at an average time of 0.05 s. The dynamic demonstration illustrated that the proposed system could track round-trip motion of 3 mm at speeds up to 100 mm/s. The proposed distance measurement system is, to our knowledge, the first microcomb-based synthetic wavelength interferometer and achieves a ranging precision of tens of nanometers, with potential applications in the fields of satellite formation flying, high-end manufacturing, and micro–nano processing.
ISSN:0146-9592
1539-4794
DOI:10.1364/OL.499291