Innovative prototype design and benchmarking for vibration displacement measurement ranging from sub-micron to micron via laser self-mixing interference

IF 5.2 2区工程技术 Q1 ENGINEERING, MULTIDISCIPLINARY

Measurement Pub Date : 2025-04-14 DOI:10.1016/j.measurement.2025.117528

Yuanfu Tan , Mubasher Ali , Zhou Su , Feng Lin , Wei-Hsin Liao , Hay Wong

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引用次数: 0

Abstract

Vibration displacement measurement is crucial in disciplines such as structural engineering, mechanical systems analysis, and condition monitoring. Laser vibrometers are commonly employed for assessing object vibration characteristics without physical contact. However, these devices typically require extra optical components or variable attenuators to manage optical power, resulting in increased cost and system complexity. This limitation impedes their broad application, particularly in constrained environments. In this study, a novel self-mixing prototype is introduced for measuring speaker vibration displacement via laser self-mixing interference. By utilizing a retro-reflective tape with prism reflection to enhance the self-mixing signal, the prototype achieves accurate vibration displacement measurement across various amplitudes and frequencies. The self-mixing prototype demonstrate the capability to deliver precise measurement ranging from 630 nm to 100.170 µm, with an investigation into the impact of laser wavelength on vibration displacement measurement. To assess its efficacy, a 3D scanning vibrometer serves as a benchmark, revealing an accuracy rate of up to 98.06 % in vibration displacement measurement for the self-mixing prototype. This study introduces a cost-effective and compact alternative that provides accurate vibration displacement measurement, rendering it suitable for applications such as vibration analysis, rail monitoring, and quality control. By streamlining the measurement process and reducing complexity, the self-mixing prototype emerges as a promising solution for industries requiring precise vibration measurement.

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基于激光自混合干涉的亚微米到微米振动位移测量的创新原型设计和基准测试

振动位移测量在结构工程、机械系统分析和状态监测等学科中至关重要。激光测振仪通常用于评估物体的振动特性而不需要物理接触。然而，这些设备通常需要额外的光学元件或可变衰减器来管理光功率，从而增加了成本和系统复杂性。这一限制阻碍了它们的广泛应用，特别是在受限的环境中。本文介绍了一种利用激光自混频干涉测量扬声器振动位移的新型自混频样机。利用棱镜反射的反反射带增强自混频信号，实现了不同振幅和频率下的精确振动位移测量。自混合原型机展示了在630 nm至100.170 μ m范围内进行精确测量的能力，并研究了激光波长对振动位移测量的影响。为了评估其有效性，以3D扫描振动计为基准，显示自混合原型的振动位移测量准确率高达98.06%。本研究介绍了一种具有成本效益和紧凑的替代方案，提供精确的振动位移测量，使其适用于振动分析，轨道监测和质量控制等应用。通过简化测量过程和降低复杂性，自混合原型成为需要精确振动测量的行业的有前途的解决方案。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Measurement 工程技术-工程：综合

CiteScore

10.20

自引率

12.50%

发文量

1589

审稿时长

12.1 months

期刊介绍： Contributions are invited on novel achievements in all fields of measurement and instrumentation science and technology. Authors are encouraged to submit novel material, whose ultimate goal is an advancement in the state of the art of: measurement and metrology fundamentals, sensors, measurement instruments, measurement and estimation techniques, measurement data processing and fusion algorithms, evaluation procedures and methodologies for plants and industrial processes, performance analysis of systems, processes and algorithms, mathematical models for measurement-oriented purposes, distributed measurement systems in a connected world.