High sensitivity measurement of seawater velocity based on panda fiber coupled aluminum-cantilever

IF 3.1 3区 物理与天体物理 Q2 Engineering Optik Pub Date : 2024-08-06 DOI:10.1016/j.ijleo.2024.171983
Lin Sun , Yu Li , Jing Meng , Xu Chen , Qiang Li , Zhiwei Liu , Shanshan Wang , Jing Wang
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Abstract

A target-type fiber optic velocity sensor is presented based on panda fiber attached to aluminum-cantilever, and experimentally demonstrated high sensitivity and precision measurement of seawater velocity. In this paper, the velocity sensitivity formula of the sensor is derived first, and the effective elastic coefficient (Pe) of Panda fiber is calculated to be 0.988 by finite element algorithm. Secondly, seawater velocity measurement system was established experimentally with circulating flow tank, and experimental results showed that the velocity sensitivity is up to 114.69 nm/(ms‐1) at 0.31 m/s when the target radius and cantilever thickness are 2.00 cm and 0.20 mm respectively, which proves that highly sensitive velocity measurement is achieved with panda fiber coupled aluminum-cantilever. Comparing the measurement results of the sensor with Acoustic Doppler Velocimetry, the average absolute error and the root mean square error (RMSE) are 0.012 m/s and 0.00249 m/s respectively, which realized high precision measurement of seawater velocity. Therefore, the system has good application in the measurement of seawater velocity due to its advantages of high sensitivity, wide range and simple structure.

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基于熊猫纤维耦合铝悬臂的海水流速高灵敏度测量技术
本文提出了一种基于铝悬臂的熊猫光纤靶式速度传感器,并通过实验证明了其对海水速度的高灵敏度和高精度测量。本文首先推导了传感器的速度灵敏度公式,并通过有限元算法计算出熊猫光纤的有效弹性系数(Pe)为 0.988。其次,利用循环水流槽建立了海水速度测量系统,实验结果表明,当目标半径和悬臂厚度分别为 2.00 厘米和 0.20 毫米时,在 0.31 米/秒时的速度灵敏度高达 114.69 nm/(ms-1),这证明熊猫纤维耦合铝悬臂实现了高灵敏度的速度测量。该传感器的测量结果与声学多普勒测速仪的测量结果相比,平均绝对误差和均方根误差(RMSE)分别为 0.012 m/s 和 0.00249 m/s,实现了对海水速度的高精度测量。因此,该系统具有灵敏度高、量程宽、结构简单等优点,在海水流速测量中具有良好的应用前景。
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来源期刊
Optik
Optik 物理-光学
CiteScore
6.90
自引率
12.90%
发文量
1471
审稿时长
46 days
期刊介绍: Optik publishes articles on all subjects related to light and electron optics and offers a survey on the state of research and technical development within the following fields: Optics: -Optics design, geometrical and beam optics, wave optics- Optical and micro-optical components, diffractive optics, devices and systems- Photoelectric and optoelectronic devices- Optical properties of materials, nonlinear optics, wave propagation and transmission in homogeneous and inhomogeneous materials- Information optics, image formation and processing, holographic techniques, microscopes and spectrometer techniques, and image analysis- Optical testing and measuring techniques- Optical communication and computing- Physiological optics- As well as other related topics.
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