从一维信号中提取复杂波形。

Aleksandar Kalauzi, Tijana Bojić, Ljubisav Rakić
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引用次数: 18

摘要

背景:非线性方法通过计算Higuchi分形维数提供了一种估计一维采样信号复杂性的直接方法(结果:在这项工作中,我们提出了一种新的简单方法,通过引入信号历元的“归一化长度密度”来估计N < 100的FD,其中yn(i)表示幅度归一化后的第i个信号样本。信号FD的实际计算是基于在一组Weierstrass函数上构造单调校准曲线FD = f(NLD),并在理论上给出该函数的FD值。现有的Higuchi和连续差分两种方法同时应用于FD(白噪声和布朗运动)不变的信号,结果表明,计算窗口FD (FDw)的标准差随着历元的缩短而急剧增大。然而,对于新的NLD方法,特别是当N < 30时,获得了相当低的散射,但代价是计算平均FDw的精度有所降低。因此,当分析含有两个或三个不同FD值的短交替周期的合成信号时,可以获得更精确的FD波形重建。另外,枕部脑电图信号的10个epoch的FDw散点图表明,Higuchi的估计在某些epoch超过了理论FD极限,而nld的推导值则没有。结论:该方法在极短周期的FD(t)提取上比现有两种方法更准确,可用于FD可能突然变化的生理信号,如短相位现象或瞬态伪影,以及其他科学领域。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Extracting complexity waveforms from one-dimensional signals.

Extracting complexity waveforms from one-dimensional signals.

Extracting complexity waveforms from one-dimensional signals.

Extracting complexity waveforms from one-dimensional signals.

Background: Nonlinear methods provide a direct way of estimating complexity of one-dimensional sampled signals through calculation of Higuchi's fractal dimension (1

Results: In this work we propose a new and simple way to estimate FD for N < 100 by introducing 'normalized length density' of a signal epoch,where yn(i) represents the ith signal sample after amplitude normalization. The actual calculation of signal FD is based on construction of a monotonic calibration curve, FD = f(NLD), on a set of Weierstrass functions, for which FD values are given theoretically. The two existing methods, Higuchi's and consecutive differences, applied simultaneously on signals with constant FD (white noise and Brownian motion), showed that standard deviation of calculated window FD (FDw) increased sharply as the epoch became shorter. However, in case of the new NLD method a considerably lower scattering was obtained, especially for N < 30, at the expense of some lower accuracy in calculating average FDw. Consequently, more accurate reconstruction of FD waveforms was obtained when synthetic signals were analyzed, containig short alternating epochs of two or three different FD values. Additionally, scatter plots of FDw of an occipital human EEG signal for 10 sample epochs demontrated that Higuchi's estimations for some epochs exceeded the theoretical FD limits, while NLD-derived values did not.

Conclusion: The presented approach was more accurate than the existing two methods in FD(t) extraction for very short epochs and could be used in physiological signals when FD is expected to change abruptly, such as short phasic phenomena or transient artefacts, as well as in other fields of science.

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