TY - GEN
T1 - Compact Quad-band Meandered Implantable PIFA for Wireless Brain Care
AU - Pournoori, N.
AU - Sydänheimo, L.
AU - Rahmat-Samii, Y.
AU - Ukkonen, L.
AU - Björninen, T.
N1 - Funding Information:
This research was funded by the Doctoral Programme in Biomedical Sciences and Engineering under the Faculty of Medicine and Health Technology of Tampere University, Academy of Finland under funding decision 294616 and supported by The Finnish Foundation for Technology Promotion (TES) and Nokia Foundation.
Publisher Copyright:
© 2021 IEEE.
jufoid=72518
PY - 2022
Y1 - 2022
N2 - In the growing efforts of promoting patients' life quality through health technology solutions, implantable wireless biomedical telemetry systems have been identified as one of the frontrunners. In these systems, the design of implantable antennas is of prime importance in establishing the wireless data link. Small multitasking implantable antennas are an evolving wireless health technology for monitoring medical conditions. These implantable antennas are intended for different functions including wireless data transmission at Medical Device Radiocommunication Service (MedRadio) band (401-406 MHz) and Wireless Medical Telemetry Service (WMTS) bands (1395-1400, and 1427-1432), wireless power transfer, and control signals between sleep/wake-up modes at Industrial, Scientific, and Medical (ISM) bands (902-928 MHz and 2400-2483.5 MHz), respectively. In this paper, we present a meandered quad-band planar inverted-F antenna (PIFA) for wireless brain care. Employing the meandering miniaturizing technique, shorting the radiator to the ground plane, and high-permittivity substrate/superstrate layers (Rogers RO3210; varepsilon {r}=10.2, tan delta=0.003, h=0.635 mm) lead to downsizing the antenna volume greatly to 11 times 20.5 times 1.8 mm{3} that includes the biocompatible silicone coating. We developed and characterized the proposed antenna numerically utilizing a 7-layer human head model in full-wave electromagnetic field simulation, where the antenna was implanted in the cerebrospinal fluid (CSF) layer at the depth of 13.25 mm in the cranial cavity. Overall, we achieve a compact quad-band implantable PIFA with-42.3 dBi of gain with a radiation efficiency of 0.003 % at 402 MHz,-22.7 dBi gain with a radiation efficiency of 0.1 % at 902 MHz,-23.7 dBi gain with a radiation efficiency of 0.1 % at 1430 MHz, and-29.7 dBi gain with a radiation efficiency of 0.02 % at 2450 MHz. To our knowledge, this is the first self-matched quad-band antenna proposed for wireless implant communications.
AB - In the growing efforts of promoting patients' life quality through health technology solutions, implantable wireless biomedical telemetry systems have been identified as one of the frontrunners. In these systems, the design of implantable antennas is of prime importance in establishing the wireless data link. Small multitasking implantable antennas are an evolving wireless health technology for monitoring medical conditions. These implantable antennas are intended for different functions including wireless data transmission at Medical Device Radiocommunication Service (MedRadio) band (401-406 MHz) and Wireless Medical Telemetry Service (WMTS) bands (1395-1400, and 1427-1432), wireless power transfer, and control signals between sleep/wake-up modes at Industrial, Scientific, and Medical (ISM) bands (902-928 MHz and 2400-2483.5 MHz), respectively. In this paper, we present a meandered quad-band planar inverted-F antenna (PIFA) for wireless brain care. Employing the meandering miniaturizing technique, shorting the radiator to the ground plane, and high-permittivity substrate/superstrate layers (Rogers RO3210; varepsilon {r}=10.2, tan delta=0.003, h=0.635 mm) lead to downsizing the antenna volume greatly to 11 times 20.5 times 1.8 mm{3} that includes the biocompatible silicone coating. We developed and characterized the proposed antenna numerically utilizing a 7-layer human head model in full-wave electromagnetic field simulation, where the antenna was implanted in the cerebrospinal fluid (CSF) layer at the depth of 13.25 mm in the cranial cavity. Overall, we achieve a compact quad-band implantable PIFA with-42.3 dBi of gain with a radiation efficiency of 0.003 % at 402 MHz,-22.7 dBi gain with a radiation efficiency of 0.1 % at 902 MHz,-23.7 dBi gain with a radiation efficiency of 0.1 % at 1430 MHz, and-29.7 dBi gain with a radiation efficiency of 0.02 % at 2450 MHz. To our knowledge, this is the first self-matched quad-band antenna proposed for wireless implant communications.
U2 - 10.1109/PIERS53385.2021.9694737
DO - 10.1109/PIERS53385.2021.9694737
M3 - Conference contribution
AN - SCOPUS:85126393340
T3 - Progress in Electromagnetics Research Symposium
SP - 2730
EP - 2736
BT - 2021 Photonics and Electromagnetics Research Symposium, PIERS 2021 - Proceedings
PB - IEEE
T2 - Photonics and Electromagnetics Research Symposium
Y2 - 21 November 2021 through 25 November 2021
ER -