1 / 44

Adaptive Imaging Preliminary: Speckle Correlation Analysis

Adaptive Imaging Preliminary: Speckle Correlation Analysis. sample volume. transducer. Speckle Formation. Speckle results from coherent interference of un-resolvable objects. It depends on both the frequency and the distance. Speckle Second-Order Statistics.

cyma
Download Presentation

Adaptive Imaging Preliminary: Speckle Correlation Analysis

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Adaptive Imaging Preliminary:Speckle Correlation Analysis Speckle Correlation Analysis

  2. sample volume transducer Speckle Formation • Speckle results from coherent interference of un-resolvable objects. It depends on both the frequency and the distance. Speckle Correlation Analysis

  3. Speckle Second-Order Statistics • The auto-covariance function of the received phase-sensitive signals (i.e., before envelope detection) is simply the convolution of the system’s point spread function if the insonified region is • macroscopically slow-varying. • microscopically un-correlated. Speckle Correlation Analysis

  4. Speckle Second-Order Statistics • The shape of a speckle spot (assuming fully developed) is simply determined by the shape of the point spread function. • The higher the spatial resolution, the finer the speckle pattern, and vice versa. Speckle Correlation Analysis

  5. Speckle Statistics • The above statements do not hold if the object has structures compared to or larger than the ultrasonic wavelength. • Rician distribution is often used for more general scatterer distribution. • Rayleigh distribution is a special case of Rician distribution. Speckle Correlation Analysis

  6. correlation coefficient displacement L/2 Lateral Speckle Correlation Speckle Correlation Analysis

  7. Lateral Speckle Correlation • Assuming the target is at focus, the correlation roughly decreases linearly as the lateral displacement increases. • The correlation becomes zero when the displacement is about half the aperture size. • Correlation may decrease in the presence of non-ideal beam formation. Speckle Correlation Analysis

  8. van Cittert-Zernike Theorem • A theorem originally developed in statistical optics. • It describes the second-order statistics of the field produced by an in-coherent source. • The insonification of diffuse scatterers is assumed in-coherent. • It is different from the aforementioned lateral displacement. Speckle Correlation Analysis

  9. van Cittert-Zernike Theorem • The theorem describes the spatial covariance of signals received at two different points in space. • For a point target, the correlation of the two signals should simply be 1. • For speckle, correlation decreases since the received signal changes. Speckle Correlation Analysis

  10. van Cittert-Zernike Theorem • The theorem assumes that the target is microscopically un-correlated. • The spatial covariance function is the Fourier transform of the radiation pattern at the point of interest. Speckle Correlation Analysis

  11. van Cittert-Zernike Theorem correlation radiation pattern Speckle Correlation Analysis

  12. van Cittert-Zernike Theorem • The theorem states that the correlation coefficient decreases from 1 to 0 as the distance increases from 0 to full aperture size. • The correlation is independent of the frequency, aperture size, …etc. Speckle Correlation Analysis

  13. van Cittert-Zernike Theorem • In the presence of tissue inhomogeneities, the covariance function is narrower since the radiation pattern is wider. • The decrease in correlation results in lower accuracy in estimation if signals from different channels are used. Speckle Correlation Analysis

  14. van Cittert-Zernike Theorem correlation distance Speckle Correlation Analysis

  15. Speckle Tracking • Estimation of displacement is essential in many imaging areas such as Doppler imaging and elasticity imaging. • Speckle targets, which generally are not as ideal as points targets, must be used in many clinical situations. Speckle Correlation Analysis

  16. Speckle Tracking • From previous analysis on speckle analysis, we found the local speckle patterns simply translate assuming the displacement is small. • Therefore, speckle patterns obtained at two instances are highly correlated and can be used to estimate 2D displacements. Speckle Correlation Analysis

  17. Speckle Tracking • Displacements can also be found using phase changes (similar to the conventional Doppler technique). • Alternatively, displacements in space can be estimated by using the linear phase shifts in the spatial frequency domain. Speckle Correlation Analysis

  18. Speckle Tracking • Tracking of the speckle pattern can be used for 2D blood flow imaging. Conventional Doppler imaging can only track axial motion. • Techniques using phase information are still inherently limited by the nature of Doppler shifts. Speckle Correlation Analysis

  19. Adaptive Imaging Methods Speckle Correlation Analysis

  20. body wall viscera point of interest v1 v2 v3 transducer array Sound Velocity Inhomogeneities Speckle Correlation Analysis

  21. Velocity (m/sec) water 1484 blood 1550 myocardium 1550 fat 1450 liver 1570 kidney 1560 Sound Velocity Inhomogeneities Speckle Correlation Analysis

  22. Sound Velocity Inhomogeneities • Sound velocity variations result in arrival time errors. • Most imaging systems assume a constant sound velocity. Therefore, sound velocity variations produce beam formation errors. • The beam formation errors are body type dependent. Speckle Correlation Analysis

  23. Sound Velocity Inhomogeneities • Due to beam formation errors, mainlobe may be wider and sidelobes may be higher. • Both spatial and contrast resolution are affected. no errors with errors Speckle Correlation Analysis

  24. beam formation geometric delay aligned velocity variations correction Near Field Assumption • Assuming the effects of sound velocity inhomogeneities can be modeled as a phase screen at the face of the transducer, beam formation errors can be reduced by correcting the delays between channels. Speckle Correlation Analysis

  25. Correlation Based Method • Time delay (phase) errors are found by finding the peak of the cross correlation function. • It is applicable to both point and diffuse targets. Speckle Correlation Analysis

  26. Correlation Based Method • The relative time delays between adjacent channels need to be un-wrapped. • Estimation errors may propagate. Speckle Correlation Analysis

  27. Correlation Based Method • Two assumptions for diffuse scatterers: • spatial white noise. • high correlation (van Cittert-Zernike theorem). filter correlator Dx Speckle Correlation Analysis

  28. Correlation Based Method • Correlation using signals from diffuse scatterers under-estimates the phase errors. • The larger the phase errors, the more severe the underestimation. • Iteration is necessary (a stable process). Speckle Correlation Analysis

  29. Alternative Methods • Correlation based method is equivalent to minimizing the l2 norm. Some alternative methods minimize the l1 norm. • Correlation based method is equivalent to a maximum brightness technique. Speckle Correlation Analysis

  30. Baseband Method • The formulation is very similar to the correlation technique used in Color Doppler. Speckle Correlation Analysis

  31. I I CORDIC acc. Q Q sign control Q sign bit acc. CORDIC acc. Baseband Method Speckle Correlation Analysis

  32. One-Dimensional Correction:Problems • Sound velocity inhomogeneities are not restricted to the array direction. Therefore, two-dimensional correction is necessary in most cases. • The near field model may not be correct in some cases. Speckle Correlation Analysis

  33. Two-Dimensional Correction • Using 1D arrays, time delay errors can only be corrected along the array direction. • The signal received by each channel of a 1D array is an average signal. Hence, estimation accuracy may be reduced if the elevational height is large. • 2D correction is necessary. Speckle Correlation Analysis

  34. Two-Dimensional Correction • Each array element has four adjacent elements. • The correlation path between two array elements can be arbitrary. • The phase error between any two elements should be independent of the correlation path. Speckle Correlation Analysis

  35. (1,1) (3,1) (2,1) corr corr corr (1,2) (2,2) (3,2) corr corr corr (3,3) (2,3) (1,3) Full 2D Correction corr corr corr corr corr corr Speckle Correlation Analysis

  36. (1,1) (2,1) (3,1) corr corr corr (3,2) (2,2) (1,2) corr corr corr (1,3) (2,3) (3,3) Row-Sum 2D Correction corr corr Speckle Correlation Analysis

  37. Correlation Based Method: Misc. • Signals from each channel can be correlated to the beam sum. • Limited human studies have shown its efficacy, but the performance is not consistent clinically. • 2D arrays are required to improve the 3D resolution. Speckle Correlation Analysis

  38. Displaced Phase Screen Model • Sound velocity inhomogeneities may be modeled as a phase screen at some distance from the transducer to account for the distributed velocity variations. • The displaced phase screen not only produces time delay errors, it also distorts ultrasonic wavefronts. Speckle Correlation Analysis

  39. phase screen Displaced Phase Screen Model • Received signals need to be “back-propagated” to an “optimal” distance by using the angular spectrum method. • The “optimal” distance is determined by using a similarity factor. Speckle Correlation Analysis

  40. Displaced Phase Screen Model • After the signals are back-propagated, correlation technique is then used to find errors in arrival time. • It is extremely computationally extensive, almost impossible to implement in real-time using current technologies. Speckle Correlation Analysis

  41. Wavefront Distortion • Measurements on abdominal walls, breasts and chest walls have shown two-dimensional distortion. • The distortion includes time delay errors and amplitude errors (resulting from wavefront distortion). Speckle Correlation Analysis

  42. displaced phase screen Phase Conjugation phase screen at face of transducer phase phase f f Speckle Correlation Analysis

  43. Phase Conjugation • Simple time delays result in linear phase shift in the frequency domain. • Displaced phase screens result in wavefront distortion, which can be characterized by non-linear phase shift in the frequency domain. Speckle Correlation Analysis

  44. Phase Conjugation • Non-linear phase shift can be corrected by dividing the spectrum into sub-bands and correct for “time delays” individually. • In the limit when each sub-band is infinitesimally small, it is essentially a phase conjugation technique. Speckle Correlation Analysis

More Related