TY - GEN
T1 - Low complexity 3D ultrasound imaging using synthetic aperture sequential beamforming
AU - Zhou, Jian
AU - Wei, Siyuan
AU - Sampson, Richard
AU - Yang, Ming
AU - Jintamethasawat, Rungroj
AU - Kripfgans, Oliver D.
AU - Fowlkes, J. Brian
AU - Wenisch, Thomas F.
AU - Chakrabarti, Chaitali
N1 - Funding Information:
This work was supported in part by NSF CCF-1406739 and CCF-1406810.
PY - 2016/12/9
Y1 - 2016/12/9
N2 - Synthetic aperture sequential beamforming (SASB) is a technique to achieve range-independent resolution in 2D images with lower computational complexity compared to synthetic aperture ultrasound (SAU). It is a two stage process, wherein the first stage performs fixed-focus beamforming followed by dynamic-focus beamforming in the second stage. In this work, we extend SASB to 3D imaging and propose two schemes to reduce its complexity: (1) reducing the number of elements in both transmit and receive and (2) implementing separable beamforming in the second stage. Our Field-II simulations demonstrate that reducing transmit and receive apertures to 32×32 and 16×16 elements, respectively, and using separable beamforming reduces 3D SASB computational complexity by 15× compared to the 64×64 aperture case with almost no loss in image quality. We also describe a hardware architecture for 3D SASB that performs first-stage beamforming in the scan head, reducing the amount of data that must be transferred for offchip processing in the second stage beamformer by up to 256×. We describe an implementation approach for the second stage that performs an optimized in-place update for both steps of separable beamforming and is well suited for GPU.
AB - Synthetic aperture sequential beamforming (SASB) is a technique to achieve range-independent resolution in 2D images with lower computational complexity compared to synthetic aperture ultrasound (SAU). It is a two stage process, wherein the first stage performs fixed-focus beamforming followed by dynamic-focus beamforming in the second stage. In this work, we extend SASB to 3D imaging and propose two schemes to reduce its complexity: (1) reducing the number of elements in both transmit and receive and (2) implementing separable beamforming in the second stage. Our Field-II simulations demonstrate that reducing transmit and receive apertures to 32×32 and 16×16 elements, respectively, and using separable beamforming reduces 3D SASB computational complexity by 15× compared to the 64×64 aperture case with almost no loss in image quality. We also describe a hardware architecture for 3D SASB that performs first-stage beamforming in the scan head, reducing the amount of data that must be transferred for offchip processing in the second stage beamformer by up to 256×. We describe an implementation approach for the second stage that performs an optimized in-place update for both steps of separable beamforming and is well suited for GPU.
UR - http://www.scopus.com/inward/record.url?scp=85013218901&partnerID=8YFLogxK
UR - http://www.scopus.com/inward/citedby.url?scp=85013218901&partnerID=8YFLogxK
U2 - 10.1109/SiPS.2016.14
DO - 10.1109/SiPS.2016.14
M3 - Conference contribution
AN - SCOPUS:85013218901
T3 - IEEE Workshop on Signal Processing Systems, SiPS: Design and Implementation
SP - 33
EP - 38
BT - Proceedings - IEEE International Workshop on Signal Processing Systems, SiPS 2016
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 2016 IEEE International Workshop on Signal Processing Systems, SiPS 2016
Y2 - 26 October 2016 through 28 October 2016
ER -