吉林大学学报(工学版) ›› 2025, Vol. 55 ›› Issue (8): 2771-2781.doi: 10.13229/j.cnki.jdxbgxb.20231282

• 通信与控制工程 • 上一篇    

基于集成经验模态分解的磁共振全波信号随机噪声抑制方法

万玲1,2(),张嘉麟1,李时赫1,平清钰1   

  1. 1.吉林大学 仪器科学与电气工程学院,长春 130026
    2.地球信息探测仪器教育部重点实验室,长春 130026
  • 收稿日期:2023-11-20 出版日期:2025-08-01 发布日期:2025-11-14
  • 作者简介:万玲(1986-),女,教授,博士.研究方向:磁共振与瞬变电磁联合探测数据处理方法.E-mail: wanling@jlu.edu.cn
  • 基金资助:
    吉林省教育厅科学研究项目(JJKH20241275KJ);吉林大学青年师生交叉学科培育项目(2023-JCXK-09)

Random noise suppression method for magnetic resonance full-wave signal with ensemble empirical mode decomposition

Ling WAN1,2(),Jia-lin ZHANG1,Shi-he LI1,Qing-yu PING1   

  1. 1.College of Instrumentation & Electrical Engineering,Jilin University,Changchun 130026,China
    2.Key Laboratory of Geo-Information Detection Instruments,Ministry of Education,Changchun 130026,China
  • Received:2023-11-20 Online:2025-08-01 Published:2025-11-14

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摘要:

本文采用集成经验模态分解(EEMD)方法对磁共振全波信号进行分解降噪,获取了一系列本征模函数(IMF)分量后,根据自适应降噪原理计算每个IMF分量的能量密度和平均周期,去除噪声主导的IMF分量,将筛选所得的IMF分量进行重构,解决了磁共振全波信号受环境噪声干扰严重的问题。仿真实验数据结果表明,当磁共振信号的信噪比低至-10 dB时,经过EEMD处理后依然能够有效提取磁共振参数,初始振幅E0提取相对误差为1.57%,弛豫时间T2*提取相对误差为2.96%,信噪比提升至10.31 dB。实测数据的噪声抑制结果进一步验证了本文研究算法的有效性和实用性,为磁共振地下水探测技术在复杂噪声环境下应用提供技术支撑。

关键词: 地面磁共振技术, 磁共振全波信号, 集成经验模态分解, 随机噪声, 数据处理

Abstract:

This article uses the ensemble empirical mode decomposition (EEMD) method to decompose and denoise the magnetic resonance full-wave signal, after obtaining a series of intrinsic mode function (IMF) components, the energy density and average period of each IMF component are calculated based on the principle of adaptive denoising,the IMF components dominated by noise are removed, and the selected IMF components are reconstructed,solved the problem of severe environmental noise interference in magnetic resonance full-wave signals. The simulation experimental data results show that when the signal-to-noise ratio of the magnetic resonance signal is as low as -10 dB, after EEMD processing, the magnetic resonance parameters can still be effectively extracted. The relative error of initial amplitude E0 extraction is 1.57%, the relative error of relaxation time T2* extraction is 2.96%, and the signal-to-noise ratio is improved to 10.31 dB. The noise suppression results of the measured data further validate the effectiveness and practicality of the algorithm studied in this paper, provides technical support for the application of magnetic resonance groundwater detection technology in complex roise environments.

Key words: ground magnetic resonance technology, magnetic resonance full-wave signal, ensemble empirical mode decomposition, random noise, data processing

中图分类号: 

  • TH763

图1

氢质子磁共振响应模型"

图2

仿真MRS全波信号"

图 3

仿真数据上、下包络线"

图 4

仿真数据均值信号"

图5

MRS全波信号及其含随机噪声信号s(t)"

图 6

仿真信号s(t)的EEMD分解图"

表1

EEMD分解所得IMF分量的系数RP j"

IMF分量RP jIMF分量RP j
IMF10.724IMF70.791
IMF20.838IMF80.809
IMF30.852IMF90.863
IMF41.176IMF100.899
IMF52.528IMF110.834
IMF60.807IMF120.743

图 7

EEMD重构信号图"

表2

EMD分解所得IMF分量的系数RP j"

IMF分量RP jIMF分量RP j
IMF11.509IMF60.296
IMF20.175IMF70.271
IMF30.137IMF80.200
IMF40.069IMF90.596
IMF50.034res0.480

图 8

EMD重构信号图"

图 9

信噪比分别为10 dB和5 dB的仿真MRS全波信号处理结果"

图 10

信噪比分别为-5 dB和-10 dB的仿真MRS全波信号处理结果时频图"

表3

不同信噪比仿真信号经EEMD消噪处理后信号参数提取结果及信噪比"

仿真信号E0/nVfL/HzT2*/msSNR/dB
理想信号200.002 330.00150.00
SNR=10 dB200.912 330.01149.0332.587 2
SNR=5 dB200.012 330.03148.2827.443 8
SNR=0 dB202.192 330.03146.9523.138 6
SNR=-5 dB202.422 330.09146.2217.432 6
SNR=-10 dB203.172 329.98145.5610.316 7

图 11

实测数据经噪声处理后结果"

图 12

实测数据处理结果"

图 13

实测数据处理结果三维时频图"

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