Dynamic spectral analysis of arterial Doppler blood flow signals using time-frequency representations

Proceedings of 18th Annual International Conference of the IEEE Engineering in Medicine and Biology Society Pub Date : 1996-10-31 DOI:10.1109/IEMBS.1996.652018

X. Long, J.W. Lee, V. C. Roberts

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引用次数: 2

Abstract

Doppler signals from a disturbed arterial blood flow are very likely to be nonstationary for they usually have a time-varying frequency structure caused by a complicated flow pattern. Therefore conventional Fourier analysis based methods are unsuitable for this application. This paper introduces the application of joint time-frequency analysis (TFA) to estimate the frequency dynamics of arterial Doppler blood flow signals and to detect the presence of small stenoses of the artery. The short time Fourier transform (STFT), Wigner distribution (WD), and Choi-Williams distribution (CWD) were investigated. The results of synthetic signal analysis show that the STFT, WD and CWD follow the transient changes of frequency well, and the STFT and CWD also behave well for multicomponent signals. Doppler spectra were obtained by means of the FFT, STFT, WD, and CWD for different flow rates and positions along a simulated blood vessel for stenoses ranging from 2% to 25% cross sectional area reduction (CSAR) using a blood analogue. The results indicate that all of these methods are to some extent capable of detecting stenoses as small as 2% CSAR by identifying the existence of negative frequency components in the spectra, and the CWD appears at this stage to be superior to the STFT and WD.

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动态频谱分析动脉多普勒血流信号使用时频表示

受到干扰的动脉血流的多普勒信号很可能是非平稳的，因为它们通常具有由复杂的血流模式引起的时变频率结构。因此，传统的基于傅里叶分析的方法不适合这种应用。本文介绍了联合时频分析(TFA)在估计动脉多普勒血流信号的频率动态和检测动脉小血管狭窄中的应用。研究了短时傅里叶变换(STFT)、Wigner分布(WD)和Choi-Williams分布(CWD)。综合信号分析结果表明，STFT、WD和CWD对频率的瞬态变化具有良好的跟踪性，对于多分量信号，STFT和CWD也表现良好。通过FFT、STFT、WD和CWD获得不同流速和位置的多普勒频谱，用于使用血液模拟物的狭窄范围为2%至25%的横截面积减少(CSAR)。结果表明，通过识别光谱中负频率成分的存在，这些方法都能在一定程度上检测到最小为2% CSAR的狭窄，并且CWD在这个阶段表现出优于STFT和WD。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Proceedings of 18th Annual International Conference of the IEEE Engineering in Medicine and Biology Society

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