Electric Field Distributions of NMHA Inside and Outside of a Human Body Phantom

2020 IEEE International RF and Microwave Conference (RFM) Pub Date : 2020-12-14 DOI:10.1109/RFM50841.2020.9344777

Nur Amalina Kamaruddin, K. Kamardin, Yoshihide Yamada

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引用次数: 1

Abstract

In order to establish a communication link between a sensor inside of a human body to a receiver outside of the human body, electric field distribution performances of the antenna inside of the human body need to be clarified. A Normal Mode Helical Antenna (NMHA) is proposed as the antenna used for this research for the purpose of using it as the antenna for Wireless Capsule Endoscopy (WCE). In this paper, the performances of NMHA which are self-resonant structures, input resistance (Rin) and efficiency (n) are presented. The antenna is designed at frequency of 402 MHz. The designed NMHA is placed inside of human body phantom with permittivity (εr) of 11.6 F/m that represents fat layer. The conductivity (σ) of the phantom is from 0 to 1 S/m. The electric field distributions of NMHA inside the phantom are observed in details at σ equals to 0, 0.3 and 1 S/m. From the electric field distributions, propagation loss of signal (Lz) from NMHA across the human body phantom can be estimated. Calculation of electric field degradation is also presented in this paper. A half-wavelength dipole antenna is then added to the NMHA model to act as receiver to check NMHA's signal strength. The result is presented as S21.

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人体幻影内外NMHA的电场分布

为了在人体内部的传感器与人体外部的接收器之间建立通信链路，需要明确人体内部天线的电场分布性能。提出了一种正模螺旋天线(NMHA)作为本研究的天线，目的是将其作为无线胶囊内窥镜(WCE)的天线。本文给出了NMHA自谐振结构的性能、输入电阻(Rin)和效率(n)。天线的设计频率为402mhz。所设计的NMHA放置在人体幻体内，介电常数εr为11.6 F/m，代表脂肪层。模体的电导率(σ)在0 ~ 1 S/m之间。在σ = 0、0.3和1 S/m时，详细观察了NMHA在模体内的电场分布。根据电场分布，可以估计NMHA在人体幻影中的传播损耗(Lz)。本文还对电场退化进行了计算。然后在NMHA模型中加入半波长偶极子天线作为接收器来检测NMHA的信号强度。结果表示为S21。

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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2020 IEEE International RF and Microwave Conference (RFM)

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