用于植入式神经设备的混合磁电天线无线传感和能量采集的电路级建模与仿真。

IF 2.4 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC
Diptashree Das;Ziyue Xu;Mehdi Nasrollahpour;Isabel Martos-Repath;Mohsen Zaeimbashi;Adam Khalifa;Ankit Mittal;Sydney S. Cash;Nian X. Sun;Aatmesh Shrivastava;Marvin Onabajo
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引用次数: 1

摘要

磁电天线(ME)可以在不同频率下表现出无线能量采集和传感的双重能力。在本文中,描述了混合ME天线的行为电路模型,以模拟电路模拟过程中的射频(RF)能量采集和传感操作。这项工作的ME天线与CMOS能量采集器芯片接口,旨在开发用于完全集成植入式设备的无线通信链路。集成系统的一个作用是从附近的发射机接收脉冲调制功率,另一个作用则是感测和传输低幅度神经信号。本文报道的测量结果首次证明了用一个双模ME天线在两个不同频率下同时进行低频无线磁感应和高频无线能量采集。所提出的行为ME天线模型可以在能量收集电路的设计优化期间使用。进行测量以验证具有2.57GHz谐振频率的ME天线的无线功率传输链路,该ME天线连接到以65nm CMOS技术设计的能量采集器芯片。此外,这种双模ME天线能够使用频率与第二63.63MHz谐振模式匹配的载波信号进行并发感测。已经开发了一个无线测试平台,用于评估ME天线,作为神经植入物设计的工具,该原型系统用于提供磁调制动作电位波形传输的首次实验结果。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Circuit-Level Modeling and Simulation of Wireless Sensing and Energy Harvesting With Hybrid Magnetoelectric Antennas for Implantable Neural Devices
A magnetoelectric antenna (ME) can exhibit the dual capabilities of wireless energy harvesting and sensing at different frequencies. In this article, a behavioral circuit model for hybrid ME antennas is described to emulate the radio frequency (RF) energy harvesting and sensing operations during circuit simulations. The ME antenna of this work is interfaced with a CMOS energy harvester chip towards the goal of developing a wireless communication link for fully integrated implantable devices. One role of the integrated system is to receive pulse-modulated power from a nearby transmitter, and another role is to sense and transmit low-magnitude neural signals. The measurements reported in this paper are the first results that demonstrate simultaneous low-frequency wireless magnetic sensing and high-frequency wireless energy harvesting at two different frequencies with one dual-mode ME antenna. The proposed behavioral ME antenna model can be utilized during design optimizations of energy harvesting circuits. Measurements were performed to validate the wireless power transfer link with an ME antenna having a 2.57 GHz resonance frequency connected to an energy harvester chip designed in 65nm CMOS technology. Furthermore, this dual-mode ME antenna enables concurrent sensing using a carrier signal with a frequency that matches the second 63.63 MHz resonance mode. A wireless test platform has been developed for evaluation of ME antennas as a tool for neural implant design, and this prototype system was utilized to provide first experimental results with the transmission of magnetically modulated action potential waveforms.
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