Title :
Low-order AR models for mean and maximum frequency estimation in the context of Doppler color flow mapping
Author :
Loupas, Thanasis ; McDicken, W. Norman
Abstract :
Autoregressive (AR) techniques are investigated by developing mean and maximum frequency estimators suitable for use in Doppler color flow mapping systems, where they are most needed. The estimators are based on low-order (for computational efficiency) AR models applied to complex signals whose real and imaginary parts are the in-phase and quadrature components of the analytical Doppler signal, respectively. A large number of simulated data sequences generated by a sinusoidal computer model and having different number of samples, spectral shapes, bandwidths, and signal-to-noise ratios are used to examine the performance (bias and variance) of the estimators in a systematic manner. Comparisons are made with the established autocorrelation technique, whose output is shown to be identical to one of the AR mean frequency estimators described.<>
Keywords :
biomedical ultrasonics; digital simulation; frequency measurement; haemodynamics; medical computing; spectral analysis; AR mean frequency estimators; Doppler color flow mapping systems; Doppler ultrasound; analytical Doppler signal; autocorrelation technique; autoregressive techniques; bandwidths; blood flow information; complex signals; low order complex AR models; maximum frequency estimation; mean frequency estimation; medical ultrasonic; quadrature components; signal-to-noise ratios; simulated data sequences; simulation model; sinusoidal computer model; spectral analysis; spectral shapes; Bandwidth; Computational efficiency; Computational modeling; Computer simulation; Frequency estimation; Image analysis; Signal analysis; Signal generators; Signal to noise ratio; Spectral shape;
Journal_Title :
Ultrasonics, Ferroelectrics, and Frequency Control, IEEE Transactions on
