Textile SIW antennas as hybrid energy harvesting and power management platforms

2015 European Microwave Conference (EuMC) Pub Date : 2015-12-03 DOI:10.1109/EUMC.2015.7345689

S. Lemey, S. Agneessens, H. Rogier

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引用次数: 5

Abstract

A compact, highly-integrated and unobtrusive wearable textile antenna system, able to establish a reliable and energy-efficient wireless body-centric communication link in the [2.4-2.4835]-GHz Industrial, Scientific and Medical band and enabling energy harvesting from three different energy sources, is presented. Our design approach relies on further extending the functionality of a carefully selected textile antenna by exploiting its surface as an energy scavenging and power management platform. More specific, two different ultra-flexible solar cells, a micro-energy cell and a flexible power management system are integrated onto a wearable substrate integrated waveguide cavity-backed textile slot antenna to enable energy harvesting from both solar and artificial light. Furthermore, thermal body energy harvesting, via an externally connected thermoelectric generator, is enabled by including an ultra-low voltage step-up converter. Measurements in four well-chosen indoor scenarios demonstrate that a hybrid energy-harvesting approach is necessary to obtain a more continuous flow and a higher amount of scavenged energy, leading to a higher system autonomy and/or reduced battery size.

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纺织SIW天线作为混合能量收集和电源管理平台

提出了一种紧凑、高度集成且不显眼的可穿戴纺织天线系统，该系统能够在[2.4-2.4835]-GHz工业、科学和医疗频段建立可靠且节能的无线身体中心通信链路，并能够从三种不同的能源中收集能量。我们的设计方法依赖于进一步扩展精心挑选的纺织品天线的功能，利用其表面作为能量收集和电源管理平台。更具体地说，两个不同的超柔性太阳能电池，一个微能量电池和一个灵活的电源管理系统被集成到一个可穿戴的衬底集成波导腔背纺织槽天线上，从而能够从太阳能和人造光中收集能量。此外，通过外部连接的热电发电机，通过包括超低电压升压转换器实现热体能量收集。在四种精心选择的室内场景中进行的测量表明，混合能量收集方法对于获得更连续的流量和更多的清除能量是必要的，从而提高系统的自主性和/或减小电池尺寸。

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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2015 European Microwave Conference (EuMC)

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