Keywords:-
Keywords:
HFSS, Fractal, Metamaterial, Return Loss, Gain
Article Content:-
Abstract
Fractal structures have the property of self-similarity and ease of repetitiveness; they remain less used in planar patterned metamaterial structures. A fractal antenna is design based on the metamaterial for multiband applications. The Fractal Antenna design is consist a metamaterial layer with FR4 substrate with .The square shapes with slot are used as metamaterial in substrates. The fractal antenna is designed on the repetition of shape with reduction of the length.
References:-
References
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Conference of millimeter waves , pp 42-48 , 2016
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with a fractal-shapedslot”, IEEE Trans. Antennas Propagation., Vol 7, pp. 2176–2179 , 2009.
14. Matin, M.A., Sharif, B.S., and Tsimenidis, “Probe fed stackedpatch antenna for wideband applications”, IEEE Trans.
Antennas Propag, Vol 8 pp. 2385–2388 ,2009
15. Yousefi, L., Iravani, B.M., and Ramahi, O.M.: “Enhanced band width artificial magnetic ground plane for low-profile
antennas”, IEEE Antennas Wirel. Propag. Letter., Vol. 6, pp. 289–292 , 2007
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Phys. Lett., Vol 11, pp. 1–3 , 2012
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metamaterials”, Radio Eng., Vol 4, pp. 993–998 , 2012.
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Different Substrates ” , IEEE WiSpNET , PP 665 -669 , 2016.
2. G.K Pandey et.al “Metamaterial based UWB antenna” IEEE Microwave Electronic Letter, Vol 50, issue 18 pp1266-
1268, 28 Aug 2014.
3. Balamati Choudhury et.al “Particle Swarm Optimization for Multiband Metamaterial Fractal Antenna”Hindawi
Publishing Corporation Journal of Optimization , Volume 5 , pp 15-22 , July 2013.
4. R.-B. Hwang, H.-W.Liu, and C.-Y. Chin “A Metamaterial based E – Plane Horn Antenna” Progress In Electromagnetics
Research, PIER 93, pp 275-289, 2009.
5. Siddharth Bhat, Rashmi Pattoo “Design and Simulation of Wide Band Fish Shaped UWB Antenna”, IOSR Journal of
Electrical and Electronics Engineering, Volume 9, Issue 3 Ver. V , June 2014.
6. Zuhura Juma Ali “A Miniaturized Ultra Wideband (UWB) Antenna Design for Wireless Communications”, International
Journal of Scientific and Research Publications, Volume 4, Issue 7, pp 1-5 , July 2014.
7. Jingtao Zhu “Gain Enhancement for Planar Quasi-Yagi Antenna with Zero-Index Metamaterial” IEEE conference of
recent microwave research, pp 212-214 , 2016
8. M. I. Ahmed “A Novel Wearable Metamaterial Fractal Antenna for Wireless Applications” IEEE Conference of
Electromagnetic research, pp 119-124 , 2016
9. Karthikeya G S “mm Wave Metamaterial Inspired Coaxial-Fed Microstrip Antenna Array for Femtosat ”Loughborough
Antennas & Propagation Conference (LAPC), pp 783-788 , 2016
10. Natalya N. Kisel,“The Modeling of Characteristics of the Patch Antenna with Non-uniform Substrate Metamaterial” ,
IEEE Conference of Wireless Communication , pp 165-169 ,2016
11. Udaykumar“Improvement of performance parameters of rectangular patch antenna using metamaterial” , IEEE
International Conference On Recent Trends In Electronics Information Communication Technology , pp 1011-1015 ,
2016
12. Zain Bin Khalid “Design of a Metamaterial Inspired Single-Cell Zeroth Order Resonant(ZOR) Antenna”, IEEE
Conference of millimeter waves , pp 42-48 , 2016
13. Chen, W.L., Wang, G.M., and Zhang, C.X. “Bandwidth enhancementof a microstrip-line-fed printed wide-slot antenna
with a fractal-shapedslot”, IEEE Trans. Antennas Propagation., Vol 7, pp. 2176–2179 , 2009.
14. Matin, M.A., Sharif, B.S., and Tsimenidis, “Probe fed stackedpatch antenna for wideband applications”, IEEE Trans.
Antennas Propag, Vol 8 pp. 2385–2388 ,2009
15. Yousefi, L., Iravani, B.M., and Ramahi, O.M.: “Enhanced band width artificial magnetic ground plane for low-profile
antennas”, IEEE Antennas Wirel. Propag. Letter., Vol. 6, pp. 289–292 , 2007
16. Li, L.W., Li, Y.N., Yeo, T.S., Mosig, J.R., and Martin, O.J.F.: ‘A broadband and high-gain metamaterial microstrip
antenna’, Appl. Phys. Lett., Vol 96, pp. 1–3 , 2010
17. Han, X., Song, H.J., Yi, Z.Q., and Lin, J.D.: “Compact ultra-wideband microstrip antenna with metamaterials”, Chin.
Phys. Lett., Vol 11, pp. 1–3 , 2012
18. Xiong, H., Hong, J.S., and Peng, Y.H.: “Impedance bandwidth and gain improvement for microstrip antenna using
metamaterials”, Radio Eng., Vol 4, pp. 993–998 , 2012.
19. Ansoft High Frequency structure Simulator (HFSS), [Online]. Available at http://www.ansoft.com.
20. Koohestani, M., Pires, N., Skrivervik, A.K., and Moreira, “Time-domain performance of patch-loaded band-reject UW
Bantenna”, Electron. Letter., Vol 49 , pp. 385–386 , 2013.
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Chauhan, R., & Singhal, E. A. (2018). Design & Simulation of Fractal Antenna with Metamaterial Substrates for Wireless Application. International Journal Of Mathematics And Computer Research, 6(01), 1847-1851. https://doi.org/10.31142/ijmcr.v6i01.1