Metamaterial Inspired Dual Band Antenna

A.Zaheetha Banu¹ , K. S. Joseph Wilson²

Section:Research Paper, Product Type: Isroset-Journal
Vol.6 , Issue.6 , pp.129-133, Dec-2018

CrossRef-DOI:   https://doi.org/10.26438/ijsrpas/v6i6.129133

Online published on Dec 31, 2018

Copyright © A.Zaheetha Banu, K. S. Joseph Wilson . This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
 

View this paper at   Google Scholar | DPI Digital Library

XML View     PDF Download

How to Cite this Paper

433 Views    153 Downloads    158 Downloads

Abstract :
In this paper, a dual-band microstrip patch antenna is designed and analyzed using metamaterial. The proposed antenna is tuned to work at two resonating frequencies in the frequency range from 1GHz to 5GHz. The antenna characteristics are studied before and after inclusion of metamaterial .we have also introduced Nicolson Ross-Weir method (NRW) method to achieve effectively the double- negative properties of the proposed metamaterial structure. The proposed rectangular microstrip patch antenna operates at the resonant frequency of 3.7GHz with a return loss of -37.24 dB.In addition to rectangular microstrip patch`s fundamental resonance; the additional resonance is obtained at 3.45GHz with a return loss of -36.4dB. To satisfy the demand of commonly used wireless communication systems, the metamaterial structure with microstrip patch antenna is designed with enhanced characteristics and exhibits dual bands. Hence the proposed antenna shows good results and can be effectively utilized for WLAN and RF-ID applications and mobile communication.

Key-Words / Index Term :
Metamaterial, SSRR, Microstrip patch antenna, Negative Refractive Index, Finite Element Method

References :
[1]. Si, L.-M., H.-J. Sun, Y. Yuan, and X. Lv, “CPW- fed compact planar UWB antenna with Circular disc and spiral split ring resonators,” PIERS Proceedings, 502–505, Beijing, China, March 23–27, 2009.
[2]. V. G. Veselago, “The electrodynamics of substances with simultaneously negative values Of ε and μ,” Soy. Phys. Usp., 10,509–514, 1968.
[3]. V. I. Slyusar, “Metamaterials on Antenna Solutions,” in Proc. International Conference on
[4]. Antenna Theory and Techniques, 19-24, 6-9 Oct 2009.
[5]. .R. Ziolkowski, “Metamaterial-Based Antennas: Research and Developments,” IEICE Trans Electron, 89, 9, 1267-1275, Sep 2006.
[6]. .S. B. Jacob and U. P. Khot, “Frequency- Tunable Metamaterial for Microstrip Patch Antenna,” in proc. IEEE Conference on circuits, systems, communication and information technology application(CSCITA),2014,DOI:10.1109/CSCITA.2014.6839258, pp. 195- 200, 2014.
[7]. Si, L. M., W. Zhu, and H. J. Sun, “A compact, planar, and CPW-fed metamaterial-inspired dualband antenna,” IEEE Antennas Wireless Propagation. Letters, Vol. 12, 305–308, 2013.
[8]. Jayant G. Joshi, Shyam S. Pattnaik, Swapna Devi and Mohan R. Lohokare, Bandwidth Enhancement and Size Reduction of Microstrip Patch Antenna by Magnetoinductive Waveguide Loading, Wireless Engineering, and Technology, 2(2), 2011, 37-44.
[9]. Yang Liu, Yitung Chen, Jichun Li, Tzu-Chen Hung, Jianping Li, "Study of energy absorption on solar cell using metamaterials”, Solar Energy 86 (2012) 1586–1599.