物理学报
物理學報
물이학보
2013年
5期
19-26
,共8页
独立成分分析%经验模态分解%混沌信号%降噪
獨立成分分析%經驗模態分解%混沌信號%降譟
독립성분분석%경험모태분해%혼돈신호%강조
independent component analysis%empirical mode decomposition%chaotic signal%denoising
基于经验模态分解和独立成分分析去噪的特点,提出了一种联合独立成分分析和经验模态分解的混沌信号降噪方法.利用经验模态分解对混沌信号进行分解,根据平移不变经验模态分解的思想构造多维输入向量,通过所构造的多维输入向量和独立成分分析对混沌信号的各层内蕴模态函数进行自适应去噪处理;将处理后的所有内蕴模态函数进行累加重构,从而得到降噪后的混沌信号.仿真实验中分别对叠加不同强度高斯噪声的Lorenz混沌信号及实际观测的月太阳黑子混沌序列进行了研究,结果表明本文方法能够对混沌信号进行有效的降噪,而且能够较好地校正相空间中点的位置,逼近真实的混沌吸引子轨迹.
基于經驗模態分解和獨立成分分析去譟的特點,提齣瞭一種聯閤獨立成分分析和經驗模態分解的混沌信號降譟方法.利用經驗模態分解對混沌信號進行分解,根據平移不變經驗模態分解的思想構造多維輸入嚮量,通過所構造的多維輸入嚮量和獨立成分分析對混沌信號的各層內蘊模態函數進行自適應去譟處理;將處理後的所有內蘊模態函數進行纍加重構,從而得到降譟後的混沌信號.倣真實驗中分彆對疊加不同彊度高斯譟聲的Lorenz混沌信號及實際觀測的月太暘黑子混沌序列進行瞭研究,結果錶明本文方法能夠對混沌信號進行有效的降譟,而且能夠較好地校正相空間中點的位置,逼近真實的混沌吸引子軌跡.
기우경험모태분해화독립성분분석거조적특점,제출료일충연합독립성분분석화경험모태분해적혼돈신호강조방법.이용경험모태분해대혼돈신호진행분해,근거평이불변경험모태분해적사상구조다유수입향량,통과소구조적다유수입향량화독립성분분석대혼돈신호적각층내온모태함수진행자괄응거조처리;장처리후적소유내온모태함수진행루가중구,종이득도강조후적혼돈신호.방진실험중분별대첩가불동강도고사조성적Lorenz혼돈신호급실제관측적월태양흑자혼돈서렬진행료연구,결과표명본문방법능구대혼돈신호진행유효적강조,이차능구교호지교정상공간중점적위치,핍근진실적혼돈흡인자궤적.
According to the characteristics of empirical mode decomposition and denoise of independent component analysis, an adaptive denoising method of chaotic signal is proposed based on independent component analysis and empirical mode decomposition. First, the chaotic signal is decomposed into a set of intrinsic mode functions by empirical mode decomposition;then, the multi-dimensional input vectors are constructed based on the translation invariant empirical mode decomposition, and the noise of each intrinsic mode function is removed through the constructed multi-dimensional input vectors and the independent component analysis; finally, the denoisied chaotic signal is obtained by accumulating and reconstructing all the processed intrinsic mode functions. Both the chaotic signal generated by Lorenz map with different level Gaussian noises, and the observed monthly series of sunspots are respectively used for noise reduction using the proposed method. The results of numerical experiments show that the proposed method is efficient. It can better correct the positions of data points in phase space and approximate the real chaotic attractor trajectories more closely.