Efficient near-field inductive wireless power transfer for miniature implanted devices using strongly coupled magnetic resonance at 5.8 GHz

2016 Texas Symposium on Wireless and Microwave Circuits and Systems (WMCS) Pub Date : 2016-03-01 DOI:10.1109/WMCAS.2016.7577481

B. T. Nukala, J. Tsay, D. Lie, J. Lopez, Tam Q. Nguyen

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引用次数: 8

Abstract

In this paper, an efficient wireless power transfer (WPT) design using near-field inductive 4-coil strongly-coupled-magnetic-resonance (SCMR) for powering up miniature biosensors at the ISM band of 5.8 GHz is proposed and analyzed. The miniature device has a tiny square planar inductor of size 110 × 110 μm as a receiver (RX) coil integrated on a standard silicon substrate. Another planar coil of 3 mm in diameter is designed on a FR4 substrate as the transmitting (TX) coil, which is fixed at 1 mm away from the RX coil in this study. The corresponding 4-coil SCMR system has the same TX and RX coils but with two relay coils between them, where the closest distance from the relay coil to the RX coil is also fixed at 1 mm. Analytic equations are used to describe the design for both scenarios, and 3-Dimensional (3-D) S-parameter and B-Field electromagnetic (EM) simulations show that the optimized 4-coil system consistently outperforms the optimized 2-coil WPT system by ~6-7 dB, reaching an impressive inductive power coupling of ~ -20.2 dB (i.e., ~ 1% power transfer efficiency) unto the tiny RX coil for potentially powering up novel implantable and other miniature devices without bulky batteries.

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使用5.8 GHz强耦合磁共振的微型植入设备的高效近场感应无线电力传输

本文提出并分析了一种利用近场4线圈强耦合磁共振(SCMR)为ISM频段5.8 GHz微型生物传感器供电的高效无线电力传输(WPT)设计。该微型器件具有一个尺寸为110 × 110 μm的微小方形平面电感，作为集成在标准硅衬底上的接收器(RX)线圈。在FR4基板上设计了另一个直径为3mm的平面线圈作为发射(TX)线圈，该线圈在本研究中固定在距离RX线圈1mm的位置。相应的4圈SCMR系统具有相同的TX和RX线圈，但在它们之间有两个继电器线圈，其中从继电器线圈到RX线圈的最近距离也固定在1mm。分析方程用于描述这两种情况的设计，三维(3-D) s参数和b场电磁(EM)模拟表明，优化的4线圈系统始终优于优化的2线圈WPT系统~6-7 dB，达到令人印象深刻的~ -20.2 dB(即~ 1%的功率传输效率)的感应功率耦合到微小的RX线圈上，为新型可植入设备和其他小型设备供电，而无需笨重的电池。

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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来源期刊

2016 Texas Symposium on Wireless and Microwave Circuits and Systems (WMCS)

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