Analysis and Design of a Micro-Strip Antenna operating at a Frequency of 6.5 GHz focusing on Cowl’s Research

Authors:

Hammad Afridi,Nasru Minallah,Sheeraz Ahmed,Khalid Zaman,Sozan Sulaiman Maghdid,Atif Sardar Khan,Alamgir Khan,

DOI NO:

http://doi.org/10.26782/jmcms.2019.10.00016

Keywords:

Micro-Strip,Antenna,Frequency,6.5 GHz,Rectangular patch,

Abstract

Micro-strip patch antenna has penetrated deep in the market due to its advantages. After studying micro patch antennas, there are some draw backs of it. One of the drawbacks includes the narrowband performance. The primary reason for this is its resonant nature. An E-shaped micro strip patch antenna is used for the broadband applications. This E-shaped antenna is used for the purpose of improving antenna shrinking and information measurement to name a few. This paper shows the detail study of Cowl’s research by using 2 different aspects of micro strip patch antenna. The antenna operated at a frequency of 5GHz. Antennas used were single part narrow band rectangular micro strip patch antenna and slot cut E-shaped micro strip patch antenna. Simulation method included high frequency structure machine (HFSS). Different properties such as Cable loss, information measurement and VSWR were studied using both types of antennas. These properties were then compared between each other.

Refference:

I. Ahamed, M. M., Bhowmik, K., & Al Suman, A. (2012). Analysis and design
of rectangular microstrip patch antenna on different resonant frequencies for
pervasive wireless communication. International Journal of Scientific &
Technology Research, 1(5), 108-111.
II. Danideh, A., SadeghiFakhr, R., &Hassani, H. R. (2008). Wideband co-planar
microstrip patch antenna. Progress In Electromagnetics Research, 4, 81-89.
III. Divya, R., &Priya, M. (2013). Design and characterization of E-shape
microstrip patch antenna for wireless communication. ICTACT journal on
communication technology, 4(01).
IV. Hammers tad, E. O. (1975).”Equations for micro strip circuit design,” Proc.
Fifth European Microwave Conf., 268-272.

V. Jan, J. Y., & Tseng, L. C. (2004). Small planar monopole antenna with a
shorted parasitic inverted-L wire for wireless communications in the 2.4-,
5.2-, and 5.8-GHz bands. IEEE Transactions on Antennas and
Propagation, 52(7), 1903-1905.
VI. Kumar, S., & Gupta, H. (2013). Design and study of compact and wideband
microstrip u-slot patch antenna for Wi-Max application. IOSR-JECE, 5(2),
45-48.
VII. Prashanth, K. V., Pavani, T., Srivatsav, N. L., Kumar, C. P., Raja, R., Fields,
G., &Vaddeswaram, G. D. (2017). DESIGN OF INSET FEED
RECTANGULAR PATCH ANTENNA FOR WLAN/WI-FI
APPLICATIONS. International Journal of Pure and Applied
Mathematics, 116(6), 43-48.
VIII. Raj, R. K., Joseph, M., Aanandan, C. K., Vasudevan, K., &Mohanan, P.
(2006). A new compact microstrip-fed dual-band coplanar antenna for
WLAN applications. IEEE transactions on antennas and
propagation, 54(12), 3755-3762
IX. Ramna, A. S. S. (2013). Design of rectangular microstrip patch antenna using
particle swarm optimization. International Journal of Advanced Research in
Computer and Communication EngineeringVol, 2.
X. Rop, K. V., &Konditi, D. B. O. (2012). Performance analysis of a rectangular
microstrip patch antenna on different dielectric substrates. Innovative Systems
Design and Engineering, 3(8), 1727-1729.
XI. Roy, A. A., Mom, J. M., &Igwue, G. A. (2013). Enhancing the bandwidth of
a microstrip patch antenna using slots shaped patch. American Journal of
Engineering Research (AJER), 2(9), 23-30.
XII. Singh, D., Gupta, K. A., & Prasad, R. K. (2013). Design and analysis of Cshaped
microstrip patch antenna for wideband application. VSRD Int. J.
Electr.Electron.Commun.Eng, 3(1).
XIII. Singh, J., Tiwari, M., & Neha, P. (2014). Design and simulation of microstrip
E-shaped patch antenna for improved bandwidth and directive gain. Int. J.
Eng. Trends Technol, 9(9), 23-30.
XIV. Wu, J. W., Hsiao, H. M., Lu, J. H., & Chang, S. H. (2004). Dual broadband
design of rectangular slot antenna for 2.4 and 5 GHz wireless
communication. Electronics Letters, 40(23), 1461-1463.

View Download