Nanotechnology and Precision Engineering (Dec 2018)

Review of low timing jitter mode-locked fiber lasers and applications in dual-comb absolute distance measurement

  • Haosen Shi,
  • Youjian Song,
  • Runmin Li,
  • Yuepeng Li,
  • Hui Cao,
  • Haochen Tian,
  • Bowen Liu,
  • Lu Chai,
  • Minglie Hu

Journal volume & issue
Vol. 1, no. 4
pp. 205 – 217

Abstract

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Passively mode-locked fiber lasers emit femtosecond pulse trains with excellent short-term stability. The quantum-limited timing jitter of a free running femtosecond erbium-doped fiber laser working at room temperature is considerably below one femtosecond at high Fourier frequency. The ultrashort pulse train with ultralow timing jitter enables absolute time-of-flight measurements based on a dual-comb implementation, which is typically composed of a pair of optical frequency combs generated by femtosecond lasers. Dead-zone-free absolute distance measurement with sub-micrometer precision and kHz update rate has been routinely achieved with a dual-comb configuration, which is promising for a number of precision manufacturing applications, from large step-structure measurements prevalent in microelectronic profilometry to three coordinate measurements in large-scale aerospace manufacturing and shipbuilding. In this paper, we first review the sub-femtosecond precision timing jitter characterization methods and approaches for ultralow timing jitter mode-locked fiber laser design. Then, we provide an overview of the state-of-the-art dual-comb absolute ranging technology in terms of working principles, experimental implementations, and measurement precisions. Finally, we discuss the impact of quantum-limited timing jitter on the dual-comb ranging precision at a high update rate. The route to high-precision dual-comb range finder design based on ultralow jitter femtosecond fiber lasers is proposed. Keywords: Timing jitter, Mode-locked lasers, Dual-comb, Absolute distance measurement