基于可拉伸光纤和干涉测量的振动传感器

吴加俊; 谢康; 曹磊; 曹璇; 李振佳; 赵国帅; 何佳程; 涂郭结

doi:10.37188/CO.EN-2025-0010

基于可拉伸光纤和干涉测量的振动传感器

安徽大学物理与光电工程学院, 信息材料与智能感知安徽省实验室, 光电信息获取与控制教育部重点实验室, 安徽合肥230601

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出版历程
- 收稿日期: 2025-02-21
- 录用日期: 2025-04-10
- 网络出版日期: 2025-04-19

Vibration sensor based on stretchable optical fiber and interferometric measurement

doi: 10.37188/CO.EN-2025-0010

School of Physics and Optoelectronic Engineering, Information Materials and Intelligent Sensing Laboratory of Anhui Province, Key Laboratory of Opto-Electronic Information Acquisition and Manipulation, Ministry of Education, Anhui University, Hefei 230601, China

Funds: Supported by Anhui Province Key Research and Development Plan Project under Grant 2023Z04020012, in part by the Key Research and Development Project of Anhui Province under Grant 1704a0902061, and in part by the Natural Science Foundation of China under Grant 62405003 and 61705001.

More Information

Author Bio:
WU Jiajun (2000—), male, from Tianmen, Hubei, is a master's student who obtained his bachelor's degree from Hubei University for Nationalities in 2022. He mainly engages in research on distributed fiber optic sensing and signal processing technology. E-mail: wujiajun0911@163.com

XIE Kang (1997—), male, from Chuzhou, Anhui Province, is a master's student who obtained his bachelor's degree from Anhui University in 2020. He mainly engages in research on distributed fiber optic sensing and signal processing technology. E-mail: 1147034188@qq.com

TU Guojie (1981—), male, born in Anqing, Anhui Province, holds a doctor's degree, associate professor's degree and master's supervisor. He obtained a bachelor's degree in science from Anhui University in 2007 and a doctor's degree from Anhui Institute of Optics and Precision Mechanics, Chinese Academy of Sciences in 2012. In the same year, he entered the Optical Communication Engineering Research Center of Nanjing University for postdoctoral research. I started working at Anhui University in 2015 and was promoted to associate professor in 2020. At present, we mainly engage in fiber optic sensing and atmospheric trace gas detection. E-mail: 15041@ahu.edu.cn

Corresponding author: 15041@ahu.edu.cn

摘要

摘要:
软聚合物光纤（SPOF）因其优异的机械性能和光导特性，在基于光学的可穿戴和可植入生物传感器中显示出巨大的潜力。然而，柔性光纤的多模态特性限制了它们与传统光纤传感器的集成。本文首次介绍了一种基于激光干涉技术的柔性光纤振动传感器，可应用于大拉伸条件下的振动测量。该传感器利用聚二甲基硅氧烷（PDMS）制成的弹性光纤作为传感元件，结合相位发生载体技术，在0~42%的拉伸范围内实现50~260 Hz的振动测量。
- 可拉伸光纤传感 /
- 光纤振动传感器 /
- 相位生成载波
Abstract:
Soft polymer optical fiber (SPOF) has shown great potential in optical based wearable and implantable biosensors due to its excellent mechanical properties and optical guiding characteristics. However, the multimodality characteristics of SPOF limit their integration with traditional fiber optic sensors. This article introduces for the first time a flexible fiber optic vibration sensor based on laser interference technology, which can be applied to vibration measurement under high stretch conditions. This sensor utilizes elastic optical fibers made of polydimethylsiloxane (PDMS) as sensing elements, combined with phase generating carrier technology, to achieve vibration measurement at 50−260 Hz within the stretch range of 0−42%.
- stretchable optical fiber sensing /
- fiber optic vibration sensor /
- phase generated carrier.

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Figure 1. (a) Structure diagram of vibration sensing system based on SPOF. (b) schematic diagram of arctangent algorithm

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Figure 2. (a) PDMS flexible optical waveguide fabrication process. (b), (c) Sectional images and surface morphology of SPOF under optical microscope. (d) MMF-SPOF-MMF structure after demolding.

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Figure 3. Mechanical and optical properties of SPOF: (a) PDMS transmission spectrum. (b) Optical loss evaluation of 5 SPOF samples, blue represents the optical loss measured without any testing, and red represents the optical loss measured after 1000 stretching cycles. (c) Optical loss of SPOF. (d) Optical loss of SPOF measured after 1000 stretching cycles.

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Figure 4. Mechanical properties of SPOF (a) The relationship between transmitted light intensity and stretching amount under cyclic dynamic stretching state. (b) The relationship between stretching length and transmitted light intensity.

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Figure 5. The relationship between the interference signal and the signal generated by the signal light passing through the point of and the reference light when the random disturbance is applied.

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Figure 6. SPOF measures the phase change response use of several representative frequency points at a fixed stretch.

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Figure 7. PDMS-SPOF affixed to the surface of the balloon is used to obtain different stretching amounts of the measured fiber by charging and deflating the balloon.

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Figure 8. When the signal to be measured is a 90 Hz sinusoidal signal: (a) The time domain phase change response under different stretching values measured by the SPOF sensor. (b) the frequency domain of the demodulated phase signal.

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