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Chinese Journal of Lasers, Volume. 50, Issue 13, 1304002(2023)

Influence of Nonlinear Sound Field on Bandwidth of Laser Interferometry Systems in High‑Intensity Focused Ultrasound Pressure Measurements

Ke Wang, Ping Yang*, and Guangzhen Xing
Author Affiliations
  • Division of Mechanics and Acoustics Metrology, National Institute of Metrology, Beijing 100029, China
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    [1] Izadifar Z, Izadifar Z, Chapman D et al. An introduction to high intensity focused ultrasound: systematic review on principles, devices, and clinical applications[J]. Journal of Clinical Medicine, 9, 460(2020).

    [2] Martin E, Treeby B. Investigation of the repeatability and reproducibility of hydrophone measurements of medical ultrasound fields[J]. The Journal of the Acoustical Society of America, 145, 1270-1282(2019).

    [3] Rajagopal S, Sainsbury T, Treeby B E et al. Laser generated ultrasound sources using carbon-polymer nanocomposites for high frequency metrology[J]. Journal of the Acoustical, 144, 584-597(2018).

    [4] Koukoulas T, Robinson S, Rajagopal S et al. A comparison between heterodyne and homodyne interferometry to realise the SI unit of acoustic pressure in water[J]. Metrologia, 53, 891-898(2016).

    [5] Xing G Z, Wilkens V, Yang P. Review of field characterization techniques for high intensity therapeutic ultrasound[J]. Metrologia, 58, 022001(2021).

    [6] Matsuda Y, Yoshioka M, Uchida T. Absolute hydrophone calibration to 40 MHz using ultrasonic far-field[J]. Materials Transactions, 55, 1030-1033(2014).

    [7] Wang M, Koukoulas T et al. Measurement of underwater acoustic pressures in the frequency range 25 to 500 kHz using optical interferometry and discussion on associated uncertainties[C](2018).

    [8] Feng X J, Yang P, He L B et al. Influence of the frequency response of the photodetector on the heterodyne interferometer-based sound pressure standards in water[J]. Applied Optics, 57, 9635-9642(2018).

    [9] Theobald P D, Robinson S P, Thompson A D et al. Technique for the calibration of hydrophones in the frequency range 10 to 600 kHz using a heterodyne interferometer and an acoustically compliant membrane[J]. The Journal of the Acoustical Society of America, 118, 3110-3116(2005).

    [10] Barrière C, Royer D. Optical measurement of large transient mechanical displacements[J]. Applied Physics Letters, 79, 878-880(2001).

    [11] Jacob X, Barriere C, Takatsu R et al. Optical measurement of transient ultrasonic shock waves[C], 52-55(2004).

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    Ke Wang, Ping Yang, Guangzhen Xing. Influence of Nonlinear Sound Field on Bandwidth of Laser Interferometry Systems in High‑Intensity Focused Ultrasound Pressure Measurements[J]. Chinese Journal of Lasers, 2023, 50(13): 1304002

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    Paper Information

    Category: Measurement and metrology

    Received: May. 27, 2022

    Accepted: Aug. 4, 2022

    Published Online: Jul. 5, 2023

    The Author Email: Yang Ping (yangp@nim.ac.cn)

    DOI:10.3788/CJL220915

    Topics

    laser devices and laser physics
    Lasers and Laser Optics
    Laser physics
    laser manufacturing
    Instrumentation, Measurement and Metrology