Modified Groove Coupled Compact EBG Unit Cell as Notch Filter in a UWB Antenna

Authors

  • Kumaresh Sarmah Assistant Professor, Electronics and Communication Technology, Gauhati Uninersity
  • Angana Sarma Department of Electronics and Communication Technology, Gauhati University
  • Sivaranjan Goswami Department of Electronics and Communication Technology, Gauhati University
  • Sunandan Baruah Department of Electronics and Communication Engineering, Assam Don Bosco University

Abstract

In this paper, a conventional mushroom-type EBG
unit cell is made compact by etching a C-slot at its conducting
surface. Further, the C-slotted mushroom-type EBG unit cell is
coupled with a microstrip line using a novel groove-coupling
technique to design a notch filter. The arrangement has achieved
in the reduction of the electrical size of the mushroom type EBG
unit cell by 46.15% and create a stop band suppression of -12 dB.
The proposed EBG is applied to notch a narrow band centered
at 5.2 GHz along with an ultra-wideband antenna. The far field
gain of the antenna is suppressed by- 5.8 dBi along the direction
of its major lobe at 5.2 GHz. The overall size of the antenna
system is 19×27×1.6mm3 which is compact. The performance
of the antenna is validated from the simulation and measured
results.

Author Biography

Kumaresh Sarmah, Assistant Professor, Electronics and Communication Technology, Gauhati Uninersity

Assistant Professor,

Department of Electronics and Communication Technology

Gauhati University

References

Yablonovitch E.“Inhibited spontaneous emission in solid-statephysics

and electronics”, Phys. Rev. Lett., vol. 58, issue. 20, pp. 2059-2062,

John S. “Strong localization of photons in certain disordered dielectric

superlattices”, Phys. Rev. Lett., vol. 58, issue. 23, pp. 2486-2489, 1987.

Yang F.,RahmatSamii Y. “Microstrip Antennas Integrated with

ElectromagneticBand-Gap (EBG) Structures: A Low Mutual Coupling

Design for Array Applications”, IEEE Trans., Antennas Propag., vol.51,

issue. 10, pp. 2936-2946, 2003.

Abedin M. F., Azad M. Z. “Ali M.Wideband Smaller Unit-Cell Planar

EBG Structures, and their Application”, IEEE Trans., Antennas Propag.,

vol. 56, issue. 3, pp. 903-908, 2008

Peng L., Ruan C.,Xiong J. “Compact EBG for Multi-Band Applications”, IEEE Trans., Antennas Propag., vol. 60, issue. 9, pp. 4440-4444,

FCC. “First Report and Order, Revision of part 15 of the commission’s

rule regarding ultra-wideband transmission system”’, 2002 USA: pp.

-153.

Zhuang W., Shenand X., Bi Qi.“Ultra-wideband wireless communications”, Wireless Com. Mobile Computing, John Wiley and Sons Ltd.,

vol. 3, pp. 663-685, 2003.

Wong K. L., Chi Y. W., Su C. M., Chang F. S. “Band-notched ultrawideband circular-disk monopole antenna with an arc-shaped slot”,

Microw. and Opt. Technol. Lett., vol. 45, issue. 3, pp. 188-191, 2005.

Chu Q. X., Yang Y. Y.“A compact ultra-wideband antenna with

4/5.5GHz dual band-notched characteristics”, IEEE Trans., Antennas

Propag., vol. 56, issue. 12:pp. 3637-3644, 2008.

Kumar, A. and Singh, M.K. “Band-Notched Planar UWB Microstrip

Antenna with T-Shaped Slot”, Radioelectron.Commun.Syst., vol. 61, pp.

, 2018.

Peng L., Ruan C. L., Yin X. C. “Analysis of the small slot-loaded

elliptical patch antenna with a band-notched for UWB applications”,

Microw. Opt. Technol. Lett., vol. 51, issue. 4, pp. 973-976, 2009.

Peng L., Ruan C. L., Chen Y. L., Zhang G. M. “A novel band notched

elliptical ring monopole antenna with a coplanar parasitic elliptical patch

for UWB applications”, J. Electro. Waves Appl., vol. 22, issue. 4, pp.

-528, 2008.

Jaglan N., Gupta S. D., Kumar B. K., Srivastava S. “Band notched

UWB circular monopole antenna with inductance enhanced modified

mushroom EBG structures”, Wireless Newt., vol. 24, issue. 2, pp. 383-

, 2018.

Trinh Van S., Dao Ngoc C. “Dual band-notched UWB antenna based

on electromagnetic bandgap structures”, Review-Journal on Electronics

and Communications, vol. 1, issue. 2, pp. 130-136, 2011.

Kushwaha N., Kumar R. “Study of different shape electromagnetic band

gap (EBG) structures for single and dual-band applications”, J. Microw.

Optoelectron. Electromagn. Appl, vol. 13, issue. 1, pp. 16-30, 2014.

Peng, L., Ruan C. L. “UWB band-notched monopole antenna design

using electromagnetic bandgap structures”, IEEE Transactions on Microwave Theory and Techniques, vol. 59, issue. 4, pp. 1074-1081, 2011.

Xu, F., Wang Z. X., Chen X., Wang X. A. “Dual band-notched UWB

antenna based on spiral electromagnetic-bandgap structure”, Progress in

Electromagnetics Research B, vol. 39, pp. 393-409, 2012.

Kovacs P.,Urbanec T. “Electromagnetic band gap structures: practical

tips and advice for antenna engineers”, Radioengineering, vol. 21, issue.

, pp. 414-421, 2012.

Sievenpiper D., Zhang L., Romulo F., Jimenez B., Alexopolous N.

G., Yablonovitch E. “High-impedance electromagnetic surfaces with a

forbidden frequency band”, IEEE Trans., Antennas Propag., vol. 47,

issue. 11, pp. 2059-2074, 1999.

Gupta K.C., Garg R., Bhal I.,Bhartia P. “Microstrip Lines, and Slotlines,2nd edition”, Norwood, MA, 1996

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Published

2024-04-19

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Section

Antennas, Radars and Radiowave Propagation