Mobile ultrasound imaging on heterogeneous multi-core platforms

2016 14th ACM/IEEE Symposium on Embedded Systems For Real-time Multimedia (ESTIMedia) Pub Date : 2016-10-01 DOI:10.1145/2993452.2993565

Andreas Kurth, Andreas Tretter, P. Hager, S. Sanabria, Orçun Göksel, L. Thiele, L. Benini

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引用次数: 5

Abstract

Ultrasound imaging is one of the most important medical diagnostic methods. The bulkiness of state-of-the-art high-quality ultrasound devices, however, drastically limits their usability in important application scenarios. In this paper, we show how a portable medical ultrasound device can be built using many-core technology and programmable logic, combining low power consumption with high flexibility. We discuss a typical ultrasound image reconstruction algorithm and howit can be parallelized using a pipelined design that efficiently partitions theworkload among heterogeneous processing elements. A special focus lies on the limited memory resources and data bandwidth between components. To tackle both problems, we use floating windowbuffers and approximate computations, and we minimize lookup table sizes using on-the-fly calculations. We evaluate the design on the Adapteva Parallella platform, which contains a power-efficient 16-core Epiphany coprocessor and a Zynq SoC including a dual-core ARM A9 processor and programmable logic. Experimental results show that parallel beamforming of 128 input channels to a 288x128 pixel ultrasound image can be achieved on the Parallella at a rate of 5.3 frames per second consuming only 2watt of dynamic power.

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异构多核平台上的移动超声成像

超声成像是最重要的医学诊断方法之一。然而，最先进的高质量超声设备的体积极大地限制了它们在重要应用场景中的可用性。在本文中，我们展示了如何使用多核技术和可编程逻辑构建便携式医疗超声设备，将低功耗与高灵活性相结合。我们讨论了一种典型的超声图像重建算法，以及如何使用流水线设计将其并行化，从而有效地在异构处理元素之间划分工作负载。特别关注的是组件之间有限的内存资源和数据带宽。为了解决这两个问题，我们使用浮动窗口缓冲区和近似计算，并使用动态计算最小化查找表大小。我们在Adapteva parallelella平台上评估了该设计，该平台包含一个节能的16核Epiphany协处理器和一个包含双核ARM A9处理器和可编程逻辑的Zynq SoC。实验结果表明，128个输入通道对288x128像素的超声图像可以实现并行波束形成，速率为5.3帧/秒，仅消耗2w的动态功率。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2016 14th ACM/IEEE Symposium on Embedded Systems For Real-time Multimedia (ESTIMedia)

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