高效低漏电 WPT 系统,集成了使用超材料导向器和隔离器的简便匹配电路整流器,适用于生物医学应用

IF 3 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC
Shimaa Alshhawy;Adel Barakat;Ramesh K. Pokharel
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引用次数: 0

摘要

为生物医学植入物提供无线供电面临诸多挑战,包括接收器(RX)的紧凑性、效率和生物医学安全性。在这项工作中,我们提出了几种解决方案来克服这些挑战。首先,我们设计了一种基于多环谐振器(MRR)的超材料启发发射器(TX)。该发射器实现了低磁损耗,并用作向 RX 供电的导向器,其特点是集成了不复杂的匹配电路整流器。其次,为了实现整流器,我们利用了所提出的 MRR 超材料实现的高耦合。整流器集成在 RX 衬底的背面,无需额外面积,从而进一步实现了紧凑性。此外,我们还引入了一种基于超材料的隔离器,旨在减少系统背面的磁场泄漏。重要的是,这种隔离器已被证明不会对原始无线功率传输(WPT)系统的性能产生不利影响。原型已成功制作,射频-直流模拟和测量结果表明,在 50 MHz 频率下,鸡胸组织中 9 mm 嵌入式 RX 的峰值效率分别为 43% 和 39%。发射机尺寸为 20 mm × 20 mm,而集成 RX/ 整流器的尺寸为 7 mm × 7 mm。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Efficient and Low Leakage WPT System With Integrated Uncomplicated Matching Circuit Rectifier Using Metamaterial Director and Isolator for Biomedical Application
Supplying wireless power to biomedical implants presents numerous challenges, including the compactness, efficiency, and biomedical safety of the receiver (RX). In this work, we propose several solutions to overcome these challenges. Firstly, we designed a metamaterial-inspired transmitter (TX) based on a multi-ring resonator (MRR). This transmitter achieves low magnetic loss and is used as a director to supply power to the RX, featuring an integrated uncomplicated matching circuit rectifier. Secondly, to realize the rectifier, we leverage the high coupling achieved through the proposed MRR metamaterial. The rectifier is integrated on the backside of the RX substrate without requiring additional area for further compactness. Additionally, we introduce a metamaterial-based isolator designed to reduce magnetic field leakage on the back side of the system. Importantly, this isolator has been proven to have no adverse effects on the original wireless power transfer (WPT) system's performance. A prototype was successfully fabricated, and both RF-dc simulation and measurements indicate a peak efficiency of 43% and 39%, respectively, at 50 MHz for a 9 mm embedded RX in chicken breast tissue. The TX size is 20 mm × 20 mm, while the integrated RX/rectifier has dimensions of 7 mm × 7 mm.
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来源期刊
CiteScore
5.80
自引率
9.40%
发文量
58
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