Optimal Ultrasonic Pulse Transmission for Miniaturized Biomedical Implants

2019 IEEE Biomedical Circuits and Systems Conference (BioCAS) Pub Date : 2019-10-01 DOI:10.1109/BIOCAS.2019.8918704

Z. Kashani, M. Kiani

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引用次数: 5

Abstract

This paper presents optimal ultrasonic pulse transmission that could be used for data transmission to/from millimeter-sized biomedical implants in general or the selfimage-guided ultrasonic (SIG-US) wireless power transfer (WPT), which we have recently proposed. To reduce the power consumption of the implant, data bits can be applied as sharp pulses across the implant’s ultrasonic transducer, resulting in a signal in the form of a short ringing across the external unit transducer (or array). In SIG-US WPT, also short pulses are transmitted by the implant periodically. The relative delays in received signal by each external transducer in an array are then used to guide the beamformer for optimal steering of the power beam towards the implant. Through simulations and measurements, the effect of transmitted number of pulses (Np) on the amplitude of the received signal (VDRx) has been studied, which is vital for low-power robust transmission. In measurements with two identical disc-shaped transducers (spaced by d = 50 mm inside water) with the diameter of 1.2 mm and thickness of 0.9 mm (series resonance frequency of ~1.3 MHz), VDRx increased almost linearly with Np (50% duty cycle with the period of 1/1.3 MHz ~ 770 ns) up to Np = 5 beyond which VDRX increase was negligible and started to saturate at Np = 10. In the SIG-US context, it was also shown in measurements that for up to 25 mm misalignment of the implant at d = 50 mm, the relative delay in receiving 4 pulses increased from 40 ns to 4.75 μs, which are quite measurable.

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微型生物医学植入物的最佳超声脉冲传输

本文提出了一种最佳的超声脉冲传输方法，可以用于毫米级生物医学植入物之间的数据传输，也可以用于我们最近提出的自图像引导超声(SIG-US)无线电力传输(WPT)。为了降低植入物的功耗，可以将数据位作为尖锐脉冲应用于植入物的超声波换能器，从而在外部单元换能器(或阵列)上产生短环形式的信号。在SIG-US WPT中，植入物也周期性地传输短脉冲。阵列中每个外部换能器接收信号的相对延迟然后用于引导波束形成器，以最佳地将功率波束转向植入物。通过仿真和测量，研究了发射脉冲数(Np)对接收信号幅值(VDRx)的影响，这对低功率鲁棒传输至关重要。在直径为1.2 mm，厚度为0.9 mm(串联谐振频率为~1.3 MHz)的两个相同的圆盘形换能器(在水中间隔d = 50 mm)的测量中，VDRx几乎随Np(50%占空比，周期为1/1.3 MHz ~ 770 ns)线性增加，直至Np = 5，超过该值VDRx的增加可以忽略不计，并在Np = 10时开始饱和。在SIG-US背景下，测量结果也表明，当植入物在d = 50 mm处偏离25 mm时，接收4个脉冲的相对延迟从40 ns增加到4.75 μs，这是相当可测量的。

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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2019 IEEE Biomedical Circuits and Systems Conference (BioCAS)

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