论文信息 - Periodically gapped data spectral velocity estimation in medical ultrasound using spatial and temporal dimensions

Periodically gapped data spectral velocity estimation in medical ultrasound using spatial and temporal dimensions

Modern medical ultrasound scanners estimate blood velocity distribution by computing the spectrogram of a temporal data sequence, typically using periodogram methods which require long observation windows. Furthermore, an additional B-mode image is often displayed, resulting in gaps in the data at B-mode emissions. We propose a data-adaptive velocity estimator for periodically gapped (PG) data that extends PG-Capon and PG-APES by using two dimensional spatial and temporal data to estimate a one dimensional spectrum. We show through realistic flow simulations that our method improves spectral resolution and reduces leakage in comparison to PG-Capon, PG-APES, and correlogram based gapped data velocity estimators, potentially increasing the maximum detectable velocity and temporal resolution of blood flow using ultrasound.

Dong C. Liu | Paul Liu

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