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Wearable Metamaterial Textile for Enhanced Spatial Coverage of Deeply Implanted Device Communication System

Authors
Pham, Van LinhTa, Son XuatYoo, Hyoungsuk
Issue Date
Jul-2025
Publisher
Institute of Electrical and Electronics Engineers
Keywords
Antennas; Focusing; Metamaterials; Textiles; Wireless communication; Implants; Communication systems; Broadband antennas; Electromagnetic scattering; Directive antennas; Coverage enhancement; data transmission; implantable medical device; metamaterial textile (MMT); spoof surface plasmon (SSP); wireless communication
Citation
IEEE Transactions on Antennas and Propagation, v.73, no.7, pp 4804 - 4813
Pages
10
Indexed
SCIE
SCOPUS
Journal Title
IEEE Transactions on Antennas and Propagation
Volume
73
Number
7
Start Page
4804
End Page
4813
URI
https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/210126
DOI
10.1109/TAP.2025.3550329
ISSN
0018-926X
1558-2221
Abstract
Wireless communication is essential for deeply implanted devices, enabling remote and instantaneous health monitoring and alert applications. However, their performance is unstable when considered within a human body model, as signal transmission efficiency is limited to a specific direction rather than all directions. In this study, by introducing a metamaterial textile (MMT) structure that incorporates antennas integrated into wearable fabrics, quasi-omnidirectional radiation from a deeply implanted device was achieved. The structure consists of a focusing antenna, a spoof surface plasmon (SSP) structure, and four radiating elements. The focus antenna receives electromagnetic (EM) energy emitted by the deeply implanted device to excite the basic radiation mode of the patches via the SPP waveguide. Therefore, electromagnetic energy radiates in all directions, avoiding unnecessary harm to the human body. The entire system, including the deeply implanted antennas and meta-material structure incorporating the antennas, operates in the 2.45-GHz industrial, scientific, and medical (ISM) band. Experimental results based on a human upper-body model demonstrate that the stable signal spatial coverage is enhanced by up to 3.1 times compared to when the structure is not used.
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