Cavity model analysis of dual polarized microstrip antennas for wireless body area network application

Cavity model analysis of dual polarized microstrip antennas for wireless body area network application

This paper describes the theoretical formulation of a vertically polarized microstrip antenna and a horizontally polarized microstrip antenna. Cavity model in conjunction with array theory, equivalence theorem, and image theory is used for theoretical analysis. In order to validate the theoretical a...

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Bibliographic Details
Published in:International journal of system assurance engineering and management Vol. 14; no. Suppl 2; pp. 635 - 642
Main Authors: Sahu, Nibash Kumar, Mishra, Sanjeev Kumar
Format: Journal Article
Language:English
Published: New Delhi Springer India 01-05-2023
Springer Nature B.V
Subjects:
Antenna arrays
Body area networks
Dual polarization (waves)
Engineering
Engineering Economics
Ground plane
Horizontal polarization
Logistics
Marketing
Microstrip antennas
Organization
Original Article
Quality Control
Reliability
Safety and Risk
Simulation
Vertical polarization
Equivalence theorem
Horizontally polarized antenna
Cavity model
Image theory
Vertically polarized antenna
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Summary:This paper describes the theoretical formulation of a vertically polarized microstrip antenna and a horizontally polarized microstrip antenna. Cavity model in conjunction with array theory, equivalence theorem, and image theory is used for theoretical analysis. In order to validate the theoretical analysis, both the antennas were simulated using CST microwave studio. A good validation is obtained between theories and simulations. Simulated antennas are resonating at 2.4-GHz with a 38-MHz impedance bandwidth. The proposed antennas are designed for use in WBAN-OFF body communications. SAR analysis averaged over 1 g and 10 g for variant sizes of ground plane of antenna are analyzed and reported. It is observed that the SAR value averaged over 1 g is reduced by 49.68%, 74.06%, and 82.34% and over 10 g is reduced by 42.23%, 65.2%, and 77.3% upon increasing the total size of the antenna by 45.1835%, 98.65%, and 160.407% respectively.
ISSN:0975-6809
0976-4348
DOI:10.1007/s13198-021-01591-0