9 research outputs found
3-D Coherent Multi-Transducer Ultrasound Imaging with Sparse Spiral Arrays
Coherent multi-transducer ultrasound (CoMTUS) creates an extended effective
aperture through the coherent combination of multiple arrays, which results in
images with enhanced resolution, extended field-of-view, and higher
sensitivity. The subwavelength localization accuracy of the multiple
transducers required to coherently beamform the data is achieved by using the
echoes backscattered from targeted points. In this study, CoMTUS is implemented
and demonstrated for the first time in 3-D imaging using a pair of 256-element
2-D sparse spiral arrays, which keep the channel-count low and limit the amount
of data to be processed. The imaging performance of the method was investigated
using both simulations and phantom tests. The feasibility of free-hand
operation is also experimentally demonstrated. Results show that, in comparison
to a single dense array system using the same total number of active elements,
the proposed CoMTUS system improves spatial resolution (up to 10 times) in the
direction where both arrays are aligned, contrast-to-noise-ratio (CNR, up to
30%), and generalized CNR (up to 11%). Overall, CoMTUS shows narrower main lobe
and higher contrast-to-noise-ratio, which results in an increased dynamic range
and better target detectability.Comment: 10 pages, 6 figure
Requirements and Hardware Limitations of High-Frame-Rate 3-D Ultrasound Imaging Systems
The spread of high frame rate and 3-D imaging techniques has raised pressing requirements for ultrasound systems. In particular, the processing power and data transfer rate requirements may be so demanding to hinder the real-time (RT) implementation of such techniques. This paper first analyzes the general requirements involved in RT ultrasound systems. Then, it identifies the main bottlenecks in the receiving section of a specific RT scanner, the ULA-OP 256, which is one of the most powerful available open scanners and may therefore be assumed as a reference. This case study has evidenced that the “star” topology, used to digitally interconnect the system’s boards, may easily saturate the data transfer bandwidth, thus impacting the achievable frame/volume rates in RT. The architecture of the digital scanner was exploited to tackle the bottlenecks by enabling a new “ring“ communication topology. Experimental 2-D and 3-D high-frame-rate imaging tests were conducted to evaluate the frame rates achievable with both interconnection modalities. It is shown that the ring topology enables up to 4400 frames/s and 510 volumes/s, with mean increments of +230% (up to +620%) compared to the star topology
Requirements and Hardware Limitations of High-Frame-Rate 3-D Ultrasound Imaging Systems
The spread of high frame rate and 3-D imaging techniques has raised pressing requirements for ultrasound systems. In particular, the processing power and data transfer rate requirements may be so demanding to hinder the real-time (RT) implementation of such techniques. This paper first analyzes the general requirements involved in RT ultrasound systems. Then, it identifies the main bottlenecks in the receiving section of a specific RT scanner, the ULA-OP 256, which is one of the most powerful available open scanners and may therefore be assumed as a reference. This case study has evidenced that the “star” topology, used to digitally interconnect the system’s boards, may easily saturate the data transfer bandwidth, thus impacting the achievable frame/volume rates in RT. The architecture of the digital scanner was exploited to tackle the bottlenecks by enabling a new “ring“ communication topology. Experimental 2-D and 3-D high-frame-rate imaging tests were conducted to evaluate the frame rates achievable with both interconnection modalities. It is shown that the ring topology enables up to 4400 frames/s and 510 volumes/s, with mean increments of +230% (up to +620%) compared to the star topology