Design of a Compact Hybrid Moore's Fractal Inspired Wearable Antenna for IoT Enabled Bio-Telemetry in Diagnostic Health Monitoring System

Since the Internet of Things (IoT) enabled medical diagnostic system requires unprecedented precision and automation for better health care delivery, therefore in such systems, the performance of antennas for efficiently transferring data (vital functions of the human body) is an important task. To...

Full description

Saved in:
Bibliographic Details
Published in:IEEE access 2022, Vol.10, p.1-1
Main Authors: Khan, Umhara Rasool, Sheikh, Javaid A., Junaid, Aqib, Amin, Rehana, Ashraf, Shazia, Ahmed, Suhaib
Format: Article
Language:English
Subjects:
Antennas
Bandwidths
Bio-sensor
Biosensors
Diagnostic systems
Fractal geometry
Fractals
Human body
Internet of Things
Internet of Things (IoT)
Layout
Mathematical models
Medical electronics
Monitoring systems
Multilayers
Personal communication
Personal Communication Band
Rate (SAR)
Remote control
Remote sensors
Resonant frequency
Specific Absorption
Specific absorption rate
Substrates
Telemedicine
Telemetry
Ultra-wideband (UWB)
Ultrawideband
Wearable technology
Wireless medical telemetry services (WMTS)
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Since the Internet of Things (IoT) enabled medical diagnostic system requires unprecedented precision and automation for better health care delivery, therefore in such systems, the performance of antennas for efficiently transferring data (vital functions of the human body) is an important task. To address these concerns, a mechanically robust, novel hybrid wearable on-body antenna inspired by Moore's fractal-based geometry and conventional rectangular loop for a diagnostic health monitoring system is proposed. The structure developed involves the etching of Moore's curve onto a conventional rectangular patch and subsequently encasing it in a rectangular loop along with a defected ground structure. The proposed antenna exhibits dual-band with bandwidth ranging from 1.38 - 1.8 GHz and 2.25 - 4.88 GHz respectively, covering WMTS, ISM, and Personal Communication band besides covering a portion of UWB band also. The two operating bands of the antenna are wideband with fractional bandwidth of 38.5% and 73% respectively. It is observed that the average specific absorption rate (SAR) over the multi-layer phantom is 0.025 W/kg for an input power of ≈ 24 dBm. In comparison to the recently reported wearable antennas, the design proposed has a compact footprint of 0.135 λo x 0.093λo x 0.004λo besides offering a dual- band of operation, peak gain of 2.2 dBi, overall radiated efficiency of 95% and SAR below 0.025 W/kg. The design is fabricated using Rogers 5880 substrate (semi-flex) of thickness 0.75 mm. The experimental results validate the simulated results making the proposed antenna a promising candidate for the bio-medical application. On analysing the performance of the proposed antenna onto the human body (human body loading), it is concluded that the proposed antenna structure is appropriate for bio-telemetric application in diagnostic health monitoring systems wherein data is relayed from all bio-sensors to remote control systems.
ISSN:2169-3536
2169-3536
DOI:10.1109/ACCESS.2022.3219442