This work shows the feasibility of performing ultrafast 3D ultrasound imaging by producing diverging waves (DW) with 2D sparse arrays. The 3D volumes were experimentally acquired by individually driving the 1024 elements of a full 32x32 matrix array. The volumes obtained with different sparse configurations were compared to those obtained with two references arrays: the full 32x32 array and a dense array of 716 elements where obtained by de-activating the corner elements of the full array. The comparison criteria were the lateral resolution using the full width at half maximum (FWHM) and the contrast to noise ratio (CNR), measured on the images obtained by scanning a grayscale phantom. The results show that ultrafast 3D ultrasound imaging can be performed with a reduced number of channels using 2D sparse arrays. However, there is still space to find the optimal 2D sparse array configurations to best transmit 3D DWs and potential improvements on image quality may be achieved with dedicated optimization e.g. cost function to homogenize DW wave front.
3D Diverging Waves With 2D Sparse Arrays: A Feasibility Study / Roux, Emmanuel; Varray, François; Petrusca, Lorena; Mattesini, Paolo; Cachard, Christian; Tortoli, Piero; Liebgott, Hervé. - ELETTRONICO. - (2017), pp. 1-4. (Intervento presentato al convegno 2017 IEEE International Ultrasonics Symposium).
3D Diverging Waves With 2D Sparse Arrays: A Feasibility Study
ROUX, EMMANUEL;MATTESINI, PAOLO;TORTOLI, PIERO;
2017
Abstract
This work shows the feasibility of performing ultrafast 3D ultrasound imaging by producing diverging waves (DW) with 2D sparse arrays. The 3D volumes were experimentally acquired by individually driving the 1024 elements of a full 32x32 matrix array. The volumes obtained with different sparse configurations were compared to those obtained with two references arrays: the full 32x32 array and a dense array of 716 elements where obtained by de-activating the corner elements of the full array. The comparison criteria were the lateral resolution using the full width at half maximum (FWHM) and the contrast to noise ratio (CNR), measured on the images obtained by scanning a grayscale phantom. The results show that ultrafast 3D ultrasound imaging can be performed with a reduced number of channels using 2D sparse arrays. However, there is still space to find the optimal 2D sparse array configurations to best transmit 3D DWs and potential improvements on image quality may be achieved with dedicated optimization e.g. cost function to homogenize DW wave front.
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