Experimental Wireless Link and SAR Assessments of an Implantable PIFA for Biotelemetry in the 2.45 GHz Band

IF 3 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC IEEE Journal of Electromagnetics RF and Microwaves in Medicine and Biology Pub Date : 2023-07-28 DOI:10.1109/JERM.2023.3294707
Muhammad Solihin Zulkefli;Kai Zhang;Mariella Sarestoniemi;Sami Myllymäki;William G. Whittow;Sen Yan;Ping Jack Soh
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Abstract

An experimental wireless link and specific absorption rate (SAR) assessment is presented in this work. A compact planar inverted-F antenna (PIFA) is designed and evaluated for biotelemetry application as an antenna at 2.45 GHz band. The proposed antenna provided a satisfactory bandwidth per unit volume using a two-layered stacked structure consisting of a high-frequency laminate and a low loss ceramic layer. The antenna was first co-designed inside several different types of phantom boxes to optimize its performance, considering computational resources. Next, a semisolid intestinal phantom model used in simulations were chosen to be fabricated for experimental evaluations. Evaluation results indicated a satisfactory antenna's operation from 2.13 to 2.81 GHz (bandwidth of 27.8%), with realized gains of −26.49 dBi when implanted at 45 mm inside the phantom. Next, measurements were performed on the antenna's communication link with a wearable antenna to study the effects its depth (from 10 to 45mm), indicating transmission coefficients of between −40 and −60 dB at 2.45 GHz. Finally, its SAR levels are evaluated experimentally using a commercial measurement system when implanted within the human tissue. Results indicated satisfactory level of 0.685 W/kg (averaged over 10 g of tissues) and is suitable for biotelemetry application.
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2.45GHz波段生物遥测用植入式PIFA的实验无线链路和SAR评估
本文介绍了一种实验性的无线链路和比吸收率(SAR)评估方法。设计并评估了一种紧凑型平面倒F天线(PIFA)作为2.45GHz频带的天线,用于生物遥测应用。所提出的天线使用由高频层压板和低损耗陶瓷层组成的双层堆叠结构,提供了令人满意的单位体积带宽。该天线最初是在几种不同类型的幻影盒内共同设计的,以优化其性能,同时考虑到计算资源。接下来,选择模拟中使用的半固体肠道体模模型进行实验评估。评估结果表明,天线在2.13至2.81 GHz(带宽27.8%)范围内的工作令人满意,当植入体模内部45 mm时,实现的增益为-26.49 dBi。接下来,对天线与可穿戴天线的通信链路进行了测量,以研究其深度(从10到45mm)的影响,表明2.45 GHz时的传输系数在−40到−60 dB之间。最后,当植入人体组织内时,使用商业测量系统对其SAR水平进行实验评估。结果表明0.685W/kg(平均超过10g组织)的令人满意的水平,并且适合生物遥测应用。
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CiteScore
5.80
自引率
9.40%
发文量
58
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Front Cover Table of Contents IEEE Journal of Electromagnetics, RF, and Microwaves in Medicine and Biology About this Journal IEEE Journal of Electromagnetics, RF and Microwaves in Medicine and Biology Publication Information Models of Melanoma Growth for Assessment of Microwave-Based Diagnostic Tools
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