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http://dx.doi.org/10.9718/JBER.2007.28.6.803

Ultrasound Synthetic Aperture Beamformer Architecture Based on the Simultaneous Multi-scanning Approach  

Lee, Yu-Hwa (Department of Electronic Engineering, Sogang University)
Kim, Seung-Soo (Department of Electronic Engineering, Sogang University)
Ahn, Young-Bok (Department of Electronic Engineering, Konkuk University)
Song, Tai-Kyong (Department of Electronic Engineering, Sogang University)
Publication Information
Journal of Biomedical Engineering Research / v.28, no.6, 2007 , pp. 803-810 More about this Journal
Abstract
Although synthetic aperture focusing techniques can improve the spatial resolution of ultrasound imaging, they have not been employed in a commercial product because they require a real-time N-channel beamformer with a tremendously increased hardware complexity for simultaneous beamforming along M multiple lines. In this paper, a hardware-efficient beamformer architecture for synthetic aperture focusing is presented. In contrast to the straightforward design using NM delay calculators, the proposed method utilizes only M delay calculators by sharing the same values among the focusing delays which should be calculated at the same time between the N channels for all imaging points along the M scan lines. In general, synthetic aperture beamforming requires M 2-port memories. In the proposed beamformer, the input data for each channel is first upsampled with a 4-fold interpolator and each polyphase component of the interpolator output is stored into a 2-port memory separately, requiring 4M 2-port memories for each channel. By properly limiting the area formed with the synthetic aperture focusing, the input memory buffer can be implemented with only 4 2-port memories and one short multi-port memory.
Keywords
medical ultrasound imaging; ultrasound beamformer; synthetic aperture;
Citations & Related Records
Times Cited By KSCI : 1  (Citation Analysis)
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