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Gain enhancement of microstrip patch antenna using Sierpinski fractal-shaped EBG

Published online by Cambridge University Press:  25 March 2015

Neeraj Rao*
Affiliation:
Indian Institute of Information Technology Design and Manufacturing Jabalpur, Dumna, Air Port Road 482005, India. Phone: +91 9407852319
Dinesh Kumar Vishwakarma
Affiliation:
Indian Institute of Information Technology Design and Manufacturing Jabalpur, Dumna, Air Port Road 482005, India. Phone: +91 9407852319
*
Corresponding author: N. Rao, Email: [email protected]

Abstract

This is the first report on novel mushroom-type electromagnetic band gap (EBG) structures, consisting of fractal periodic elements, used for enhancing the gain of microstrip patch antennas. Using CST Microwave studio the performance of rectangular patch antenna has been examined on proposed fractal EBG substrates. It is found that fractal EBGs are more effective in suppressing surface wave thus resulting in higher gain. The gain of rectangular patch has been improved from 6.88 to 10.67 dBi. The proposed fractal EBG will open new avenues for the design and development of variety of high-frequency components and devices with enhanced performance.

Type
Research Papers
Copyright
Copyright © Cambridge University Press and the European Microwave Association 2015 

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References

REFERENCES

[1] Waterhouse, R. (ed.): Microstrip Patch Antennas: a Designer's Guide: a Designer's Guide, Springer, Dordrecht, Netherlands, 2003.Google Scholar
[2] Whittow, W.G. et al. : Applications and future prospects for microstrip antennas using heterogeneous and complex 3-D geometry substrates. Prog. Electromagn. Res., 144 (2014), 271280.Google Scholar
[3] Chen, Z.N.; Chia, M.Y.: Broadband probe-fed plate antenna, in 30th European Int. Microwave Conf., 2000, 1–5.Google Scholar
[4] Cella, T., Orten, P.; Hjelmstad, J.: MIMO geometry and antenna design for high capacity and improved coverage in mm-wave systems. Int. J. Antennas Propag., 2013 (2013), 19.Google Scholar
[5] Sievenpiper, D. et al. : High-impedance electromagnetic surfaces with a forbidden frequency band. IEEE Trans. Microw. Theory Tech., 47 (11) (1999), 20592074.Google Scholar
[6] Boutayeb, H.; Denidni, T.A.: Gain enhancement of a microstrip patch antenna using a cylindrical electromagnetic crystal substrate. IEEE Trans. Antennas Propag., 55 (11) (2007), 31403145.Google Scholar
[7] Llombart, N. et al. : Planar circularly symmetric EBG structures for reducing surface waves in printed antennas. IEEE Trans. Antennas Propag., 53 (10) (2005), 32103218.Google Scholar
[8] Yoon, J.H. et al. : Reflect array with EBG elements for improved radiation characteristics. Electron. Lett., 49 (16) (2013), 975976.Google Scholar
[9] Kildal, P.; Alfonso, E.; Chen, H.: 2 × 2-slot element for 60 GHz planar array antenna realized on two doubled-sided PCBs using SIW cavity and EBG-type soft surface fed by microstrip-ridge gap waveguide. IEEE Trans. Antennas Propag., 62 (9) (2014), 45644573.Google Scholar
[10] Yeap, S.B.; Chen, Z.N.: Microstrip patch antennas with enhanced gain by partial substrate removal. IEEE Trans. Antennas Propag., 58 (9) (2010), 28112816.Google Scholar
[11] Yeap, S.B.; Chen, Z.N.; Qing, X.: Gain-enhanced 60-GHz LTCC antenna array with open air cavities. IEEE Trans. Antennas Propag., 59 (9) (2011), 34703473.Google Scholar
[12] Chen, Z.N. et al. : Design and measurement of substrate-integrated planar millimeter wave antenna arrays at 60–325 GHz. Radio and Wireless Symp. (RWS), IEEE, 2014, 25–27.Google Scholar
[13] Rao, N.; Vishwakarma, D.K.: Gain and bandwidth enhancement of a microstrip antenna using partial substrate removal in multiple-layer dielectric substrate, in PIER Proc., Suzhou, China, 2011, 1285–1289.Google Scholar
[14] Rao, N.; Vishwakarma, D.K.: Investigation of a microstrip patch antenna with EBG structures using FDTD method, in Recent Advances in Intelligent Computational Systems (RAICS), IEEE, 2011, 332–337.CrossRefGoogle Scholar
[15] Liang, J.; Yang, H.-Y.D.: Radiation characteristics of a microstrip patch over an electromagnetic bandgap surface. IEEE Trans. Antennas Propag., 55 (6) (2007), 16911697.Google Scholar
[16] Ruaro, A.; Thaysen, J.; Jakobsen, K.B.: Simultaneous out-of-band interference rejection and radiation enhancement in an electronic product via an EBG structure, in Microwave Symp. (IMS), 2014 IEEE MTT-S Int. IEEE, 2014, 1–3.Google Scholar
[17] Soh, P.J. et al. : Wearable dual-band Sierpinski fractal PIFA using conductive fabric. Electron. Lett., 47 (6) (2011), 365367.Google Scholar
[18] Ullah, M.H.; Islam, M.T.: A compact square loop patch antenna on high dielectric ceramic–PTFE composite material. Appl. Phys. A, 113 (1) (2013), 185193.Google Scholar
[19] Quarfoth, R.; Sievenpiper, D.: Artificial tensor impedance surface waveguides. IEEE Trans. Antennas Propag., 61 (7) (2013), 35973606.Google Scholar