Litcius/Paper detail

Miniaturized Dual-Resonant Helix/Spiral Antenna System at MHz-Band for FSK Impulse Radio Intrabody Communications

Jingjing Shi, Hailian Liu, Xin Wang, Jiayu Zhang, Fuye Han, Xiaowei Tang, Jianqing Wang

2020IEEE Transactions on Antennas and Propagation20 citationsDOI

Abstract

In this article, a miniaturized dual-resonant antenna system at MHz-band operating at around 20 and 50 MHz is proposed for frequency-shift keying impulse radio (FSK-IR) intrabody communications. This antenna system comprises a swallowable helix-coil in-body antenna with a hollow cylindrical shape of 10 mm diameter and 30 mm length, and two single band on-body matched planar spiral-coil antennas with a compact size of 79 mm × 72 × 2.8 mm. For in-body antenna design, a nonuniform helical pitch structure is utilized to produce dual-resonant frequencies. The soft ferrite magnetic sheet with high relative permeability and low dissipation factor is used as a flexible conformal substrate to realize antenna miniaturization without lumped element loading. Simulation results for antenna performance, electromagnetic field distribution, and specific absorption rate are presented with different tissue-type phantoms, as well as an anatomical numerical human model. In addition, experimental verification of antenna performance and implant transmission characteristics is also conducted in a liquid phantom. At an implant depth of 50 mm, the measured maximum transmission coefficients are -33 and -45 dB at the dual-resonant frequency bands, respectively. Simulation and measurement results demonstrate that the proposed dual-resonant antenna is suitable for the FSK-IR system and can be expected to realize a data rate as high as 10 Mb/s for biomedical implant applications at MHz-band.

Topics & Concepts

Spiral antennaSpecific absorption rateMaterials scienceAntenna (radio)Imaging phantomFrequency-shift keyingMiniaturizationRadio frequencyOpticsCoaxial antennaAcousticsPhysicsDipole antennaElectrical engineeringEngineeringChannel (broadcasting)DemodulationWireless Body Area NetworksAntenna Design and AnalysisEnergy Harvesting in Wireless Networks