TY - JOUR
T1 - Wearable Wideband Textile Coplanar Vivaldi Antenna for Medical and IoT Application
AU - Nurhayati, Nurhayati
AU - Fahmi, Agam N.D.N.
AU - Puspitaningayu, Pradini
AU - Wiriawan, Oce
AU - Raafi’u, Brian
AU - Iskandarianto, Fitri A.
AU - Al-Gburi, Ahmed Jamal Abdullah
AU - Varshney, Atul
AU - Johari, Safpbri
N1 - Publisher Copyright:
© 2024, Electromagnetics Academy. All rights reserved.
PY - 2024
Y1 - 2024
N2 - Wearable technologies will be extremely useful in the future life. This research proposes a textile wideband coplanar Vivaldi antenna constructed from a felt substrate and two distinct types of patches, shieldit, and copper tape integrated with a wearable device. This study also altered the slope of the tapered slot on the antenna’s front and side to see how it affected the bandwidth and directivity antenna performance. An IoT wearable device that was connected to a microcontroller via a DS18B20 body temperature sensor and a MAX30100 sensor for heart rate and oxygen level monitoring was paired with the textile antenna. Based on the simulation findings, it was discovered that a 1 mm thick felt substrate material combined with a copper tape patch produces a workable frequency range of 2.6 GHz to 8.7 GHz, a minimum S11 of −44.93 dB at 3 GHz, and a fractional bandwidth up to 107%. According to the simulation results, the antenna’s side and front tapered slots have an impact on directivity and return loss. Directivity at 3 GHz can be raised by 2.63 dBi, from 1.94 dBi to 4.57 dBi, by varying the Vivaldi antenna form on both sides of the patch. The data from the sensor was successfully conveyed by combining an IoT wearable device with a textile antenna. Thus, we deduce that the textile coplanar Vivaldi antenna is appropriate for Internet of Things applications.
AB - Wearable technologies will be extremely useful in the future life. This research proposes a textile wideband coplanar Vivaldi antenna constructed from a felt substrate and two distinct types of patches, shieldit, and copper tape integrated with a wearable device. This study also altered the slope of the tapered slot on the antenna’s front and side to see how it affected the bandwidth and directivity antenna performance. An IoT wearable device that was connected to a microcontroller via a DS18B20 body temperature sensor and a MAX30100 sensor for heart rate and oxygen level monitoring was paired with the textile antenna. Based on the simulation findings, it was discovered that a 1 mm thick felt substrate material combined with a copper tape patch produces a workable frequency range of 2.6 GHz to 8.7 GHz, a minimum S11 of −44.93 dB at 3 GHz, and a fractional bandwidth up to 107%. According to the simulation results, the antenna’s side and front tapered slots have an impact on directivity and return loss. Directivity at 3 GHz can be raised by 2.63 dBi, from 1.94 dBi to 4.57 dBi, by varying the Vivaldi antenna form on both sides of the patch. The data from the sensor was successfully conveyed by combining an IoT wearable device with a textile antenna. Thus, we deduce that the textile coplanar Vivaldi antenna is appropriate for Internet of Things applications.
UR - http://www.scopus.com/inward/record.url?scp=85207514102&partnerID=8YFLogxK
U2 - 10.2528/PIERC24080402
DO - 10.2528/PIERC24080402
M3 - Article
AN - SCOPUS:85207514102
SN - 1937-8718
VL - 148
SP - 145
EP - 156
JO - Progress In Electromagnetics Research C
JF - Progress In Electromagnetics Research C
ER -