Pretreatment and Wavelength Selection Method for Near-Infrared Spectra Signal Based on Improved CEEMDAN Energy Entropy and Permutation Entropy

Xiaoli Li,Chengwei Li

doi:10.3390/e19070380

Abstract

The noise of near-infrared spectra and spectral information redundancy can affect the accuracy of calibration and prediction models in near-infrared analytical technology. To address this problem, the improved Complete Ensemble Empirical Mode Decomposition with Adaptive Noise (CEEMDAN) and permutation entropy (PE) were used to propose a new method for pretreatment and wavelength selection of near-infrared spectra signal. The near-infrared spectra of glucose solution was used as the research object, the improved CEEMDAN energy entropy was then used to reconstruct spectral data for removing noise, and the useful wavelengths are selected based on PE after spectra segmentation. Firstly, the intrinsic mode functions of original spectra are obtained by improved CEEMDAN algorithm. The useful signal modes and noisy signal modes were then identified by the energy entropy, and the reconstructed spectral signal is the sum of useful signal modes. Finally, the reconstructed spectra were segmented and the wavelengths with abundant glucose information were selected based on PE. To evaluate the performance of the proposed method, support vector regression and partial least square regression were used to build the calibration model using the wavelengths selected by the new method, mutual information, successive projection algorithm, principal component analysis, and full spectra data. The results of the model were evaluated by the correlation coefficient and root mean square error of prediction. The experimental results showed that the improved CEEMDAN energy entropy can effectively reconstruct near-infrared spectra signal and that the PE can effectively solve the wavelength selection. Therefore, the proposed method can improve the precision of spectral analysis and the stability of the model for near-infrared spectra analysis.

Highlights

Diabetes, which is a kind of blood glucose metabolism disorder, causes serious health problems [1].According to the statistical data from the International Diabetes Federation (IDF), the number of people with diabetes will reach 592 million in 2025 [2]
The structure of the ECG signal is different from that of the Blocks signal. These results demonstrate the extensive application of the proposed method based on improved CEEMDAN energy entropy
SNR/mean square (MSE) of the proposed method is higher/smaller than that of others. These results demonstrate that the proposed method based on improved CEEMDAN energy entropy is effective for uniform distribution of noise

Summary

Introduction

Diabetes, which is a kind of blood glucose metabolism disorder, causes serious health problems [1].According to the statistical data from the International Diabetes Federation (IDF), the number of people with diabetes will reach 592 million in 2025 [2]. Diabetes, which is a kind of blood glucose metabolism disorder, causes serious health problems [1]. The foundations of diabetes treatment are regular blood glucose detection, diet plans, and injected or oral insulin. Blood glucose detection is the key step to an effective diabetes treatment. The non-invasive blood glucose detection method is a painless, convenient, and affordable method. Given the development of computer technology and chemometrics in recent years, high efficiency and low-cost near-infrared spectra technologies that can perform fast analysis are widely used in non-invasive blood glucose detection [3]. The electromagnetic wavelength near-infrared light between visible light and medium infrared light ranges from 700 to nm [4]. Glucose molecules contain C–H, N–H, and O–H groups, and the stretching

Methods

Results

Conclusion