Two-Port Networks to Model Galvanic Coupling for Intrabody Communications and Power Transfer to Implants

2018 IEEE Biomedical Circuits and Systems Conference (BioCAS) Pub Date : 2018-10-01 DOI:10.1109/BIOCAS.2018.8584691

Laura Becerra-Fajardo, Marc Tudela-Pi, A. Ivorra

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引用次数: 7

Abstract

Galvanic coupling, or more precisely, volume conduction, can be used to communicate with and to transfer power to electronic implants. Since no bulky components for power, such as coils or batteries, are required within the implants, this strategy can yield very thin devices suitable for implantation by injection. To design the circuitry of both the implants and the external systems, it is desirable to possess a model that encompasses the behavior of these circuits and also the volume conduction phenomenon. Here we propose to model volume conduction with a two-port network so that the whole system can be studied in circuit simulators. The two-port network consists only of three impedances whose values can be obtained through simple measurements or through numerical methods. We report a validation of this modeling approach in a geometrically simple in vitro setup that allowed us to determine the impedances of the two-port network not only by performing measurements or through a finite element method study but also through an analytical solution.

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双端口网络模型电耦合体内通信和电力传输到植入物

电偶，或者更准确地说，体积传导，可用于与电子植入物通信并将电力传输到电子植入物。由于植入物中不需要线圈或电池等笨重的电源组件，因此该策略可以产生非常薄的设备，适合通过注射植入。为了设计植入体和外部系统的电路，需要拥有一个包含这些电路行为和体积传导现象的模型。在这里，我们建议用一个双端口网络来模拟体积传导，以便在电路模拟器中研究整个系统。双端口网络仅由三个阻抗组成，其值可以通过简单的测量或通过数值方法获得。我们报告了在几何上简单的体外设置中对这种建模方法的验证，该设置使我们不仅可以通过执行测量或通过有限元方法研究，还可以通过解析解来确定双端口网络的阻抗。

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2018 IEEE Biomedical Circuits and Systems Conference (BioCAS)

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