Portable and Cost-Effective Handheld Ultrasound System Utilizing FPGA-Based Synthetic Aperture Imaging

IF 1.8 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY IEEE Open Journal of Nanotechnology Pub Date : 2024-11-07 DOI:10.1109/OJNANO.2024.3494544
Wenping Wang;Ziliang Feng
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Abstract

The handheld ultrasound has been widely applied in various clinical applications due to its high portability and cost-effectiveness advantages. The smaller hardware architecture can expand its range of application scenarios. However, miniaturized ultrasound devices face the challenges in terms of image quality, frame rate, and power consumption. The achievement of high-quality and high-frame-rate imaging depends on numerous channels and higher pulse repetition frequency (PRF) at the cost of power consumption. The proposed work aims to design a field-programmable gate array (FPGA)-based prototype with synthetic aperture method for portable and cost-effective handheld ultrasound system. The prototype supports 8 transmit and receive channels and forms up to 8 synthetic apertures. In addition, to optimize the FPGA resources, the auto delay calculation and segmented apodizations are employed for 4 parallel beamforming lines. To evaluate the performance of our proposed prototype, scan sequences of B-mode, C-mode, and D-mode are implemented for image construction. The results show that the proposed prototype can provide a lateral resolution of 0.30 mm, a contrast-to-noise ratio (CNR) of 7.58 dB, and a frame rate of 22 frames per second (FPS) in dual-mode imaging. Moreover, it is remarkable that the memory and logic resources in the FPGA (EP4CE55) account for 73.7% and 66.2%, respectively, which makes the FPGA's power consumption only about 530 mW. The proposed prototype is suitable for handheld and other miniaturized ultrasound imaging systems.
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利用基于 FPGA 的合成孔径成像技术的便携式低成本手持超声系统
手持式超声波因其便携性强、成本效益高的优势,已被广泛应用于各种临床应用中。较小的硬件结构可以扩大其应用范围。然而,小型化超声设备在图像质量、帧速率和功耗方面面临着挑战。要实现高质量和高帧频成像,必须以功耗为代价,获得更多的通道和更高的脉冲重复频率(PRF)。本研究旨在设计一种基于现场可编程门阵列(FPGA)的原型,采用合成孔径方法,用于便携式、高性价比的手持超声系统。该原型支持 8 个发射和接收通道,最多可形成 8 个合成孔径。此外,为了优化 FPGA 资源,4 条并行波束形成线采用了自动延迟计算和分段光阑。为了评估我们提出的原型的性能,我们采用了 B-模式、C-模式和 D-模式的扫描序列来构建图像。结果表明,在双模成像中,所提出的原型可提供 0.30 毫米的横向分辨率、7.58 分贝的对比度-噪声比(CNR)和每秒 22 帧的帧频(FPS)。此外,FPGA(EP4CE55)的内存和逻辑资源分别占 73.7% 和 66.2%,这使得 FPGA 的功耗仅约为 530 mW。所提出的原型适用于手持式和其他微型超声成像系统。
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来源期刊
CiteScore
3.90
自引率
17.60%
发文量
10
审稿时长
12 weeks
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