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    Journals >Optical Communication Technology >Volume 47 >Issue 7 >Page 5 > Article
    • Optical Communication Technology
    • Vol. 47, Issue 7, 5 (2021)
    Phase-noise-compensation method of optical source for velocity measurement by FMCW lidar
    DAI Zhiwei, FAN Xinyu, and HE Zuyuan
    Author Affiliations
  • [in Chinese]
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    DOI: 10.13921/j.cnki.issn1002-5561.2021.07.002 Cite this Article
    DAI Zhiwei, FAN Xinyu, HE Zuyuan. Phase-noise-compensation method of optical source for velocity measurement by FMCW lidar[J]. Optical Communication Technology, 2021, 47(7): 5 Copy Citation Text show less
    References

    [3] BEHROOZPOUR B, SANDBORN P A M, WU M C, et al. Lidar system architectures and circuits[J]. IEEE Communications Magazine, 2017, 55(10): 135-142.

    [5] ZHANG X, POULS J, WU M C. Laser frequency sweep linearization by iterative learning pre-distortion for FMCW lidar[J]. Optics Express, 2019, 27(7): 9965-9974.

    [6] QIN J, ZHOU Q, XIE W L, et al. Coherence enhancement of a chirped DFB laser for frequency-modulated continuous-wave reflectometry using a composite feedback loop[J]. Optics letters, 2015, 40(19): 4500-4503.

    [7] ZHANG Y, HOU D, ZHAO J. Long-term frequency stabilization of an optoelectronic oscillator using phase-locked loop[J]. Journal of Lightwave Technology, 2014, 32(13): 2408-2414.

    [8] XU K, WU Z, ZHENG J, et al. Long-term stability improvement of tunable optoelectronic oscillator using dynamic feedback compensation[J]. Optics Express, 2015, 23(10): 12935-12941.

    [9] AFLATOUNI F, BAGHERI M, HASHEMI H. Design methodology and architectures to reduce the semiconductor laser phase noise using electrical feedforward schemes[J]. IEEE Transactions on Microwave Theory & Techniques, 2010, 58(11): 3290-3303.

    [10] CHEN J, LIU Q, HE Z. Feedforward laser linewidth narrowing scheme using acousto-optic frequency shifter and direct digital synthesizer[J]. Journal of Lightwave Technology, 2019, 37(18): 4657-4664.

    [11] KIM D Y, LEE J Y, AHN T J. Suppression of nonlinear frequency sweep in an optical frequency-domain reflectometer by use of Hilbert transformation[J]. Applied Optics, 2005, 44(35): 7630-7634.

    [12] FAN X, KOSHIKIYA Y, ITO F. Phase-noise-compensated optical frequency domain reflectometry with measurement range beyond laser coherence length realized using concatenative reference method[J]. Optics Letters, 2007, 32(22): 3227-3229.

    [13] AMZAJERDIAN F, PIERROTTET D, PETWAY L B, et al. Lidar sensors for autonomous landing and hazard avoidance[EB/OL].[2020-12-15]. https://search.scstl.org/lid5.102/15899376_kjbg20150410466184.shtml.

    [14] LU Z, LU W, ZHOU Y, et al. Three-dimensional coherent ladar based on FMCW and its flight demonstration[EB/OL].[2020-12-15]. http://www.cqvip.com/QK/85954X/20199/7003026642.html.

    [15] ZHANG Z, FAN X, WU M, et al. Phase-noise-compensated OFDR realized using hardware-adaptive algorithm for real-time processing[J]. Journal of Lightwave Technology, 2019, 37(11): 2634-2640.

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    DAI Zhiwei, FAN Xinyu, HE Zuyuan. Phase-noise-compensation method of optical source for velocity measurement by FMCW lidar[J]. Optical Communication Technology, 2021, 47(7): 5
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