Title :
High resolution processing techniques for ultrasound Doppler velocimetry in the presence of colored noise. I. Nonstationary methods
Author :
Kouamé, Denis ; Girault, Jean-Marc ; Patat, Frédéric
Author_Institution :
LUSSI, GIP Ultrasous Tours, France
fDate :
3/1/2003 12:00:00 AM
Abstract :
Real-time flow velocity measurement is a practical issue in industrial and biomedical applications. Because their good frequency resolution, parametric methods such as autoregressive (AR) modeling and time-frequency distributions (TFD) are generally preferred to Fourier analysis. However, these methods become highly inaccurate in the presence of colored noise. We review here the principal parametric and nonparametric techniques and show their limitations in the estimation of Doppler frequency in the presence of strong colored noise. Different solutions to overcome these limitations are then proposed and compared using synthetic Doppler signals with colored noise.
Keywords :
Doppler measurement; Fourier analysis; autoregressive processes; biomedical measurement; biomedical ultrasonics; flow measurement; frequency estimation; noise; time-frequency analysis; ultrasonic measurement; velocity measurement; AR modeling; Doppler frequency estimation; Fourier analysis; US Doppler velocimetry; autoregressive modeling; biomedical applications; colored noise; fluid flow measurements; high resolution processing techniques; industrial applications; nonparametric techniques; parametric techniques; pipes; real-time flow velocity measurement; time-frequency distributions; ultrasound Doppler velocimetry; Additive white noise; Colored noise; Fluid flow; Frequency estimation; Predictive models; Signal analysis; Signal resolution; Time frequency analysis; Ultrasonic imaging; Velocity measurement; Algorithms; Blood Flow Velocity; Blood Vessels; Image Enhancement; Models, Statistical; Quality Control; Rheology; Sensitivity and Specificity; Stochastic Processes; Ultrasonography, Doppler;
Journal_Title :
Ultrasonics, Ferroelectrics, and Frequency Control, IEEE Transactions on
DOI :
10.1109/TUFFC.2003.1193619
