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混沌信号的压缩感知去噪
引用本文:李广明,吕善翔. 混沌信号的压缩感知去噪[J]. 物理学报, 2015, 64(16): 160502-160502. DOI: 10.7498/aps.64.160502
作者姓名:李广明  吕善翔
作者单位:1. 东莞理工学院计算机学院, 东莞 523808;2. 华南理工大学电子与信息学院, 广州 510641
基金项目:国家自然科学基金(批准号: 61170216, 61372082)资助的课题.
摘    要:对非线性时间序列进行噪声抑制是从中提取有效信息的前提. 混沌信号的去噪算法不仅要使滤波后的信号具有较高的信噪比, 也要具有较好的不确定性. 从压缩感知的角度出发,提出了一种新的噪声抑制方法. 该方法包括估计噪声方差, 以及依据动态的稀疏度将观测值往确定的过完备字典上投影. 仿真实验表明, 该方法比常用的小波阈值法和局部曲线拟合法具有更高的输出信噪比, 而原始信号的混沌特性也能得到较大程度的恢复.

关 键 词:混沌信号  去噪  压缩感知  稀疏度
收稿时间:2015-03-25

Chaotic signal denoising in a compressed sensing perspective
Li Guang-Ming,Lü Shan-Xiang. Chaotic signal denoising in a compressed sensing perspective[J]. Acta Physica Sinica, 2015, 64(16): 160502-160502. DOI: 10.7498/aps.64.160502
Authors:Li Guang-Ming  Lü Shan-Xiang
Affiliation:1. School of Computer Science, Dongguan University of Technology, Dongguan 523808, China;2. School of Electronic and Information Engineering, South China University of Technology, Guangzhou 510641, China
Abstract:Nonlinear time series denoising is the premise for extracting useful information from an observable, for the applications in analyzing natural chaotic signals or achieving chaotic signal synchronizations. A good chaotic signal denoising algorithm processes not only a high signal-to-noise ratio (SNR), but also a good unpredictability of a signal. Starting from the compressed sensing perspective, in this work we provide a novel filtering algorithm for chaotic flows. The first step is to estimate the strength of the noise variance, which is not explicitly provided by any blind algorithm. Then the second step is to construct a deterministic projection matrix, whose columns are polynomials of different orders, which are sampled from the Maclaurin series. Since the noise variance is provided from the first step, then a sparsity level with regard to this signal can be fully constructed, and this sparsity value in conjunction with the orthogonal matching pursuit algorithm is used to recover the original signal. Our method can be regarded as an extension to the local curve fitting algorithm, where the extension lies in allowing the algorithm to choose a wider range of polynomial orders, not just those of low orders. In the analysis of our algorithm, the correlation coefficient of the proposed projection matrix is given, and the reason for shrinking the sparsity when the noise variance increases is also presented, which emphasizes that there is a larger probability of error column selection with larger noise variance. In the simulation, we compare the denoising performance of our algorithm with those of the wavelet shrinking algorithm and the local curve fitting algorithm. In terms of SNR improvement for the Lorenz signal, the proposed algorithm outperforms the local curve fitting method in an input SNR range from 0 dB to 20 dB. And this superiority also exists if the input SNR is larger than 9 dB when compared with the wavelet methods. A similar performance also exists concerning the Rössler chaotic system. The last simulation shows that the chaotic properties of the originals are largely recovered by using our algorithm, where the quantity for "chaotic degree" is described by using the proliferation exponent.
Keywords:chaotic signal  denoising  compressed sensing  sparsity
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