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Optical ranging system based on multiple pulse train interference using soliton microcomb

Jihui Zheng, Yang Wang, Xinyu Wang, Fumin Zhang, Weiqiang Wang, Xin Ma, Jindong Wang, Jiawei Chen, Linhua Jia, Mingyu Song, Meiyan Yuan, Brent E. Little, Sai Tek Chu, Dong Cheng, Xinghua Qu, Wei Zhao, Wenfu Zhang

2021Applied Physics Letters30 citationsDOIOpen Access PDF

Abstract

The multiple pulse train interference (MPTI) ranging system takes advantage of the high accuracy and absolute length measurement capability, but traditional scheme has a large measurement dead zone. In this Letter, we propose a MPTI ranging scheme based on chip-based soliton microcomb to achieve high-precision but no dead-zone measurement. The measurement optical path is improved to solve the problem of cross correlation interference fringe overlap, and a peak fitting algorithm is employed to further improve the measurement accuracy of the system. Using a commercial He–Ne interferometer, a 384 nm precision is obtained in 1.5 m distance measurements. Advantages of the simple optical path, high precision, and no measurement dead zone are expected to realize on-chip integration and provide a solution for precision measurement.

Topics & Concepts

RangingInterferometryInterference (communication)OpticsAccuracy and precisionOptical pathChipOptical path lengthPhysicsSystem of measurementPulse (music)Computer scienceTelecommunicationsDetectorChannel (broadcasting)Quantum mechanicsAstronomyAdvanced Fiber Laser TechnologiesAdvanced Fiber Optic SensorsAdvanced Optical Sensing Technologies
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