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Literature DB >> 10738797

Maximum-likelihood approach to strain imaging using ultrasound

Abstract

A maximum-likelihood (ML) strategy for strain estimation is presented as a framework for designing and evaluating bioelasticity imaging systems. Concepts from continuum mechanics, signal analysis, and acoustic scattering are combined to develop a mathematical model of the ultrasonic waveforms used to form strain images. The model includes three-dimensional (3-D) object motion described by affine transformations, Rayleigh scattering from random media, and 3-D system response functions. The likelihood function for these waveforms is derived to express the Fisher information matrix and variance bounds for displacement and strain estimation. The ML estimator is a generalized cross correlator for pre- and post-compression echo waveforms that is realized by waveform warping and filtering prior to cross correlation and peak detection. Experiments involving soft tissuelike media show the ML estimator approaches the Cramer-Rao error bound for small scaling deformations: at 5 MHz and 1.2% compression, the predicted lower bound for displacement errors is 4.4 microns and the measured standard deviation is 5.7 microns.

Entities: Disease

Year: 2000 PMID： 10738797 PMCID： PMC2724659 DOI： 10.1121/1.428429

Source DB: PubMed Journal: J Acoust Soc Am ISSN： 0001-4966 Impact factor: 1.840

31 in total

Maximum-likelihood approach to strain imaging using ultrasound

1. Lagrangian speckle model and tissue-motion estimation--theory.

2. Feature-adaptive motion tracking of ultrasound image sequences using a deformable mesh.

3. Noninvasive measurement of transmural gradients in myocardial strain with MR imaging.

Review 4. Null functions and eigenfunctions: tools for the analysis of imaging systems.

5. Ultrasound-stimulated vibro-acoustic spectrography.

6. Statistical analysis of strain images estimated from overlapped and filtered echo signals.

7. Noise reduction in elastograms using temporal stretching with multicompression averaging.

8. A pulsed Doppler ultrasonic system for making noninvasive measurements of the mechanical properties of soft tissue.

9. An analytical study of Doppler ultrasound systems.

10. Elastography: elasticity imaging using ultrasound with application to muscle and breast in vivo.

1. Linear system models for ultrasonic imaging: application to signal statistics.

2. Adaptive clutter rejection filtering in ultrasonic strain-flow imaging.

3. Linear approach to axial resolution in elasticity imaging.

4. Estimation of displacement vectors and strain tensors in elastography using angular insonifications.

5. Spatial angular compounding for elastography without the incompressibility assumption.

6. Spatial-angular compounding for elastography using beam steering on linear array transducers.

7. A novel performance descriptor for ultrasonic strain imaging: a preliminary study.

8. Normal and shear strain estimation using beam steering on linear-array transducers.

9. Correlation analysis of the beam angle dependence for elastography.

10. A novel image formation method for ultrasonic strain imaging.