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基于卷积神经网络的激光自混合干涉微位移重构OA

Laser self-mixing interference micro displacement reconstruction based on convolutional neural network

中文摘要英文摘要

提出了一种基于卷积神经网络(CNN)的半导体激光自混合干涉(SMI)微位移重构方法,将 SMI信号分段并以窗口平均位移作为标签输入卷积神经网络,实现了物体微米量级位移的直接重构,避免了位移重构过程中复杂的 SMI信号相位解包裹计算过程.所使用的卷积神经网络由三组卷积层、池化层和线性整流函数组成,其中卷积层用于提取 SMI信号中的局部位移特征,池化层用于压缩 SMI信号中的特征信息并增强抗干扰能力,线性整流函数有助于突出 SMI信号中的关键位移特征.在理论仿真中,将具有 10 dB噪声的 SMI信号输入至已训练完成的卷积神经网络中,直接输出物体重构微位移的均方根误差为5.3×10-8;在实验中,将包含系统噪声的 SMI信号输入已训练完成的卷积神经网络中,直接输出物体重构微位移的均方根误差为2.1×10-7.理论仿真与实际实验结果均表明,卷积神经网络通过分析 SMI信号的时序片段,能够实现半导体激光自混合干涉信号的微米量级位移重构.

[Background]Laser self-mixing interferometry(SMI)is a highly sensitive and non-contact technique widely used for micro-displacement measurement.However,traditional displacement reconstruction methods typically involve complex phase unwrapping calculations,which increases computational difficulty and limits the efficiency of signal processing in practical applications.[Purpose]This study aims to propose a novel micro-displacement reconstruction method for semiconductor laser SMI based on convolutional neural networks(CNN).The objective is to achieve direct and accurate reconstruction of micron-scale displacement while bypassing the tedious phase unwrapping process.[Methods]The proposed method involves segmenting the SMI signal and using the window-averaged displacement as the label for training the CNN.The architecture of the network consists of three sets of convolutional layers,pooling layers,and Rectified Linear Unit(ReLU)functions.Specifically,the convolutional layers are utilized to extract local displacement features from the SMI signal,the pooling layers are designed to compress feature information and enhance noise immunity,and the ReLU functions help highlight critical displacement features within the signal.[Results]In theoretical simulations,SMI signals with 10 dB noise were input into the trained CNN,resulting in a displacement reconstruction RMSE of 5.3×10-8.In experimental tests,SMI signals containing system noise were processed by the network,yielding a reconstructed displacement RMSE of 2.1×10-7.The simulation and experimental results demonstrate consistent performance.[Conclusions]Both theoretical and experimental results indicate that the convolutional neural network can effectively achieve micron-level displacement reconstruction by analyzing the temporal segments of SMI signals.This method provides an efficient alternative for semiconductor laser self-mixing interference systems by eliminating the need for complex phase-based algorithms.

李鑫涛;刘晖;乔硕;杨一帆;吕杨;刘霞;熊玲玲

西安工程大学 机电工程学院,西安 710048西安工程大学 机电工程学院,西安 710048西安工程大学 机电工程学院,西安 710048西安工程大学 机电工程学院,西安 710048西安工程大学 机电工程学院,西安 710048西安工程大学 机电工程学院,西安 710048西安工程大学 机电工程学院,西安 710048

信息技术与安全科学

激光自混合干涉微位移重构卷积神经网络特征提取半导体激光器

laser self-mixing interferencedisplacement reconstructionconvolutional neural networkfeature extractionsemiconductor laser

《强激光与粒子束》 2026 (4)

1-11,11

陕西省自然科学基础研究计划项目(2025JC-YBMS-770)陕西省秦创原"科学家+工程师"队伍项目(2023KXJ-129)

10.11884/HPLPB202638.250370

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