Title :
Ultrasonic data compression via parameter estimation
Author :
Cardoso, Guilherme ; Saniie, Jafar
Author_Institution :
Dept. of Electr. & Comput. Eng., Illinois Inst. of Technol., Chicago, IL, USA
Abstract :
Ultrasonic imaging in medical arid industrial applications often requires a large amount of data collection. Consequently, it is desirable to use data compression techniques to reduce data and to facilitate the analysis and remote access of ultrasonic information. The precise data representation is paramount to the accurate analysis of the shape, size, and orientation of ultrasonic reflectors, as well as to the determination of the properties of the propagation path. In this study, a successive parameter estimation algorithm based on a modified version of the continuous wavelet transform (CWT) to compress and denoise ultrasonic signals is presented. It has been shown analytically that the CWT (i.e., time/spl times/frequency representation) yields an exact solution for the time-of-arrival and a biased solution for the center frequency. Consequently, a modified CWT (MCWT) based on the Gabor-Helstrom transform is introduced as a means to exactly estimate both time-of-arrival and center frequency of ultrasonic echoes. Furthermore, the MCWT also has been used to generate a phase/spl times/bandwidth representation of the ultrasonic echo. This representation allows the exact estimation of the phase and the bandwidth. The performance of this algorithm for data compression and signal analysis is studied using simulated arid experimental ultrasonic signals. The successive parameter estimation algorithm achieves a data compression ratio of (1 5N/J), where J is the number of samples and N is the number of echoes in the signal. For a signal with 10 echoes and 2048 samples, a compression ratio of 96% is achieved with a signal-to-noise ratio (SNR) improvement above 20 dB. Furthermore, this algorithm performs robustly, yields accurate echo estimation, and results in SNR enhancements ranging from 10 to 60 dB for composite signals having SNR as low as -10 dB.
Keywords :
acoustic signal processing; biomedical ultrasonics; data compression; medical image processing; parameter estimation; time-of-arrival estimation; wavelet transforms; Gabor-Helstrom transform; bandwidth representation; continuous wavelet transform; data compression ratio; denoise ultrasonic signals; medical applications; parameter estimation algorithm; phase-bandwidth representation; signal-noise ratio; time of arrival estimation; time-frequency representation; ultrasonic data compression; ultrasonic echo; ultrasonic information; ultrasonic reflectors; Biomedical imaging; Continuous wavelet transforms; Data compression; Frequency estimation; Information analysis; Parameter estimation; Phase estimation; Shape; Ultrasonic imaging; Wavelet transforms; Algorithms; Signal Processing, Computer-Assisted; Ultrasonics;
Journal_Title :
Ultrasonics, Ferroelectrics, and Frequency Control, IEEE Transactions on
DOI :
10.1109/TUFFC.2005.1406557