法布里-珀罗干涉仪
解调
光纤
光纤传感器
温度测量
光学
计算机科学
电子工程
材料科学
算法
物理
光电子学
电信
工程类
波长
频道(广播)
量子力学
作者
Qi Wang,Zhong-jia Li,Yi-Jie Fan,Bing Zhou
标识
DOI:10.1109/tim.2025.3558789
摘要
To address the contradiction between speed and accuracy in the demodulation algorithms of fibre optic Fabry-Perot temperature sensors, as well as the problem of the low accuracy of existing neural network demodulation methods, a temperature demodulation method combining principal component analysis (PCA), particle swarm optimization (PSO) and Elman neural network is proposed for the first time. The high linear correlation among input spectral features and the significant overlap in content found in neural network algorithms worsen the variance of model training parameter estimates, leading to decreased prediction accuracy—a challenge that cannot be entirely resolved through model correction alone. PCA effectively resolves the problem of the multicollinearity inherent in spectral data, and reduces the dimensionality of the original data features. The data compression ratio can reach 0.0005. PSO enhances the ability of neural network to avoid local minima in the training process, and helps neural network to search global minima more comprehensively in the parameter domain. The addition of a feedback mechanism in the Elman neural network enhances its fitting ability, enabling it to handle more complex data than traditional feedforward neural networks. Without spectral denoising, the model was trained and tested on 4,100 samples with temperatures ranging from -5 to 35 °C. The final results achieved a root mean square error (RMSE) of 0.002 °C and a demodulation speed of 0.06 ms. Consequently, the proposed PCA-PSO-Elman demodulation method can effectively captures the nonlinear mapping between temperature and spectra, and achieve higher demodulation accuracy and greater demodulation speed.
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