Realtime control of multiple-focus phased array heating patterns based on noninvasive ultrasound thermography

A. Casper, Dalong Liu, E. Ebbini
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引用次数: 6

Abstract

We present results from realtime feedback control of single- and multiple-focus phased array heating patterns based on ultrasound thermography. The results illustrate several important aspects of realtime control of phased array heating patterns as they are envisioned to be used in noninvasive, image-guided thermal therapy applications. First, complex, multiple-focus heating patterns require multi-point, noninvasive temperature feedback that may not be easily available using thermocouple or other invasive proibes. Second, multiple-focus pattern synthesis must be optimized to maintain the highest efficiency of the phased array driver in order to achieve the control objectives. This has led to the development of a dynamic power reallocation algorithm for realtime management of the power share of each focus accoring to maximize its heating rate. Third, realtime integration between the feedback thermography and array driver control with high spatial and temporal resolution is necessary, especially for short exposures used in ablative treatments. These aspects are well illustrated by the results shown: 1) realtime thermography at frame rates up to 100 fps, 2) realtime multiple-focus pattern resynthesis with update rates up to 1000 patterns per second, and 3) an intelligent dynamic power reallocation scheme to distribute the available driving power according to the collective needs of the individual foci in the multiple-focus heating patterns. Without this dynamic power reallocation, the standard multiple-focus pattern synthesis may produce low-efficiency driving patterns that may fail to achieve the control objective at the some or all control points in the heating pattern.
基于无创超声热成像的多焦点相控阵加热模式实时控制
本文介绍了基于超声热成像的单焦点和多焦点相控阵加热模式的实时反馈控制结果。这些结果说明了相控阵加热模式实时控制的几个重要方面,因为它们被设想用于无创、图像引导的热治疗应用。首先,复杂的多焦点加热模式需要多点、非侵入性的温度反馈,而使用热电偶或其他侵入性探针可能不容易获得。其次,为了实现控制目标,必须优化多焦点方向图合成以保持相控阵驱动器的最高效率。这导致了一种动态功率重新分配算法的发展,该算法可以根据最大的加热速率实时管理每个焦点的功率份额。第三,反馈热成像和阵列驱动控制之间的实时集成是必要的,具有高空间和时间分辨率,特别是在烧蚀治疗中使用的短曝光。结果表明:1)帧速率高达100 fps的实时热成像;2)更新速率高达1000帧/秒的实时多焦点模式重新合成;3)一种智能动态功率重新分配方案,根据多焦点加热模式中单个焦点的集体需求分配可用驱动功率。如果没有这种动态功率再分配,标准的多焦点模式综合可能会产生低效率的驱动模式,可能无法在加热模式的某些或所有控制点实现控制目标。
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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