Joint Design of Self-Tuning UHF RFID Antenna and Microfluidic Channel for Liquid Sensing

IF 2.3 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC IEEE journal of radio frequency identification Pub Date : 2024-04-16 DOI:10.1109/JRFID.2024.3389870
Giulio Maria Bianco;Gaetano Marrocco
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Abstract

Microfluidic has been an enabling technology for over a decade, particularly in the field of medical and wearable devices, allowing for the manipulation of small amounts of fluid in confined spaces. Micro-channels can also be used for wireless sensing thanks to the variations in antenna properties when the fluid flows near it. However, up to now, microfluidic channels and sensing antennas have always been designed separately; instead, since the liquid flow and the antenna geometry both contribute to the overall performance, they should be considered simultaneously when optimizing the antenna-microfluidic system. In this paper, the joint design of the antenna and microfluidic channels is investigated for liquid quantification. Self-tuning RFID microchips are exploited to minimize communication degradation due to the increase of lossy liquid amount over the sensing antenna while digitalizing the impedance mismatch itself. To experimentally corroborate the joint design technique, two different geometries are obtained and prototyped starting from a given antenna-microfluidic layout by setting different goals for an optimization function. The two flexible RFID prototypes returned performance in agreement with the simulated ones, achieving a maximum sensitivity of about 20 units of the digital metric per milligram increase of water.
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用于液体传感的自调谐超高频 RFID 天线和微流控通道的联合设计
十多年来,微流体技术一直是一种赋能技术,尤其是在医疗和可穿戴设备领域,它允许在密闭空间内操作少量流体。微通道还可用于无线传感,这要归功于流体在其附近流动时天线特性的变化。然而,迄今为止,微流体通道和传感天线一直是分开设计的;相反,由于液体流动和天线几何形状都会影响整体性能,因此在优化天线-微流体系统时应同时考虑这两个因素。本文针对液体定量研究了天线和微流控通道的联合设计。在对阻抗失配本身进行数字化的同时,利用自调谐射频识别(RFID)微芯片最大限度地降低了因传感天线上方有损液体量增加而导致的通信质量下降。为了在实验中证实联合设计技术,通过为优化函数设定不同的目标,从给定的天线-微流体布局开始,获得了两种不同的几何形状并制作了原型。两个柔性 RFID 原型的性能与模拟的一致,每增加一毫克水的最大灵敏度约为 20 个数字度量单位。
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