Design of a multi-channel pre-beamform data acquisition system for an ultrasound research scanner

Tsang, Ivan K. H.; Yiu, Billy Y. S.; Cheung, Dave K. H.; Chiu, Harry C. T.; Cheung, Chris C. P.; Yu, Alfred C. H.

doi:10.1109/ultsym.2009.5441869

Cited by 4 publications

(3 citation statements)

References 13 publications

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“…To evaluate the computational performance of our GPUbased beamformer prototype, a series of processing trials has been carried out. These trial runs are conducted on SAI and PWI test data acquired using a pre-beamform data acquisition system [15] that is connected to a reconfigured research scanner (Sonix-RP; Ultrasonix, Richmond, Canada). The RF sampling rate for the test datasets is 40 MHz, and each frame of pre-beamform data (i.e.…”

Section: A Overview Of Methodologymentioning

confidence: 99%

Real-time GPU-based software beamformer designed for advanced imaging methods research

Yiu¹,

Tsang²,

Yu³

2010

2010 IEEE International Ultrasonics Symposium

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High computational demand is known to be a technical hurdle for real-time implementation of advanced methods like synthetic aperture imaging (SAI) and plane wave imaging (PWI) that work with the pre-beamform data of each array element. In this paper, we present the development of a software beamformer for SAI and PWI with real-time parallel processing capacity. Our beamformer design comprises a pipelined group of graphics processing units (GPU) that are hosted within the same computer workstation. During operation, each available GPU is assigned to perform demodulation and beamforming for one frame of prebeamform data acquired from one transmit firing (e.g. point firing for SAI). To facilitate parallel computation, the GPUs have been programmed to treat the calculation of depth pixels from the same image scanline as a block of processing threads that can be executed concurrently, and it would repeat this process for all scanlines to obtain the entire frame of image data -i.e. lowresolution image (LRI). To reduce processing latency due to repeated access of each GPU's global memory, we have made use of each thread block's fast-shared memory (to store an entire line of pre-beamform data during demodulation), created texture memory pointers, and utilized global memory caches (to stream repeatedly used data samples during beamforming). Based on this beamformer architecture, a prototype platform has been implemented for SAI and PWI, and its LRI processing throughput has been measured for test datasets with 40 MHz sampling rate, 32 receive channels, and imaging depths between 5-15 cm. When using two Fermi-class GPUs (GTX-470), our beamformer can compute LRIs of 512-by-255 pixels at over 3200 fps and 1300 fps respectively for imaging depths of 5 cm and 15 cm. This processing throughput is roughly 3.2 times higher than a Tesla-class GPU (GTX-275).

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Section: A Overview Of Methodologymentioning

confidence: 99%

Real-time GPU-based software beamformer designed for advanced imaging methods research

Yiu¹,

Tsang²,

Yu³

2010

2010 IEEE International Ultrasonics Symposium

Self Cite

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“…Dunmire 等 [19] 则结合平面波传输提出了交叉波束的多普勒方法, 通过发射两个对称的平面波束实现在波束交叉区域的二维速度矢量成像. 为进一步提升成像帧率, 子孔径传输的矢量多普勒逐渐兴起 [20,21] , 通过设置特定子孔径偏转接收来估算不同方向上的速度, 进而推导出整个流场信息, 且在短时间内获取大量的数据. 另外, 基于多波束传输原理的矢量多普勒方法在重建二维流场方面效果显著 [22,23]…”

Section: 引言unclassified

Blood flow image by multi-angle composite ultrasonic Doppler vector

王康宇¹,

周昱林²,

何丽媛³

et al. 2022

Acta Phys. Sin.

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Precise measurement of blood flow is of vital importance for studying formation of thrombus and atherosclerotic plaque. However, conventional color Doppler methods are limited to obtain velocity component along the ultrasound beam and have poor accuracy. Several Doppler flow imaging methods based on plane wave emission can estimate the blood velocity vectors and visualize hemodynamic parameters, which provide more detailed blood flow information and effectively improve the ability of clinical diagnosis treatment. Considering the low accuracy of the Doppler flow methods for measuring velocity in complex flow fields, an optimization technique was applied to improve the imaging quality and the accuracy of velocity estimation. This study proposed a modified vector Doppler method, combining multi-angle compound technique, to reconstruct blood velocity vectors of carotid bifurcations obtained from 3D printing. Since the multi-angle compound technology can effectively improve the quality of imaging, this technology was used in Doppler imaging to achieve high-accuracy velocity estimation. It can significantly decrease the velocity estimation errors. Comparing the velocity estimation accuracy of different angle compound numbers (n=1, 3, 5, and 7) in the simulation, it is found that the accuracy of velocity estimation increases with angle compound increasing. Beside, 5-angle compound method is more robust for velocity estimation and can obtain higher frames. The experiments were carried out using a programmable ultrasonic array system and a high-frequency linear array transducer L12-5c with a central frequency of 8.125MHz. The sample rate was set at 31.25MHz. The imaging results of carotid bifurcation also shows that the vector Doppler based on 5-angle compound can obtain a clear image of intravascular vector flow, which is beneficial to identify complex flow state and realize intravascular dynamic imaging. Especially, it can capture the vortex phenomenon in the blood stream. The quantitative results indicated that this method significantly reduces the error between the flow calculation results and the reference results, making the estimation results more accurate. In conclusion, the vector Doppler method based on multi-angle compound has good performance of visualizing complex blood flow and quantifying hemodynamic parameter changes. It also provides reference for the diagnosis of cardiovascular disease and the research of flow imaging methods.

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“…), which is the driving need for a reconfigurable processor to switch between the two modalities in real-time using the same receiving frontend, and to manage the digital resources for optimizing the speed in each mode. Furthermore, the FPGA code allows real-time acquisition of pre-beamformed data for both modalities [18], this capability will provide researchers with an extended tool for forming their own images using extended imaging algorithms. Though the overall achieved co-registered frame rate is 1 Hz, this is primarily because of the use of the current DSP board, which has a slow link to the host PC.…”

Section: Introductionmentioning

confidence: 99%

FPGA-based reconfigurable processor for ultrafast interlaced ultrasound and photoacoustic imaging

Alqasemi

Aguirre

et al. 2012

IEEE Trans. Ultrason., Ferroelect., Freq. Contr.

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Design of a multi-channel pre-beamform data acquisition system for an ultrasound research scanner

Cited by 4 publications

References 13 publications

Real-time GPU-based software beamformer designed for advanced imaging methods research

Real-time GPU-based software beamformer designed for advanced imaging methods research

Blood flow image by multi-angle composite ultrasonic Doppler vector

FPGA-based reconfigurable processor for ultrafast interlaced ultrasound and photoacoustic imaging

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