Design and Analysis of Circular Slotted Microstrip Patch Antenna

Authors

  • Kaustubh Bhattacharyya Assam Don Bosco University
  • Rupanda Thangjam Assam Don Bosco University
  • Sivaranjan Goswami Gauhati University
  • Kumaresh Sarmah Gauhati University
  • Sunandan Baruah Assam Don Bosco University

Abstract

This paper presents a novel complementary CPWfed
slotted microstrip patch antenna for operation at 2.4 GHz,
5.2 GHz and 6.3 GHz frequencies. The primary structure consists
of the complementary split ring resonator slots on a patch
and the design is fabricated on FR-4 epoxy substrate with
substrate thickness of 1.6 mm. The described structure lacks
the presence of a ground plane and makes use of a number of
circular complementary SRRs along with rectangular slots on
the radiating patch. The structure provides a wide bandwidth
of around 390 MHz, 470 MHz and 600 MHz at the three
bands with return losses of -11.5 dB, -24.3996dB and -24.4226
dB, respectively. The inclusion of the rectangular slots in the
CSRR based slot antenna with stairecase structure improved the
performance with respect to return loss.

Author Biographies

Kaustubh Bhattacharyya, Assam Don Bosco University

Department of Electronics and Communication Engineering, Assam Don Bosco University

Assistant Professor

Rupanda Thangjam, Assam Don Bosco University

Department of Electronics and Communication Engineering, Assam Don Bosco University

Sivaranjan Goswami, Gauhati University

Department of Electronics and Communication Technology, Gauhati University

Assistant Professor

Kumaresh Sarmah, Gauhati University

Department of Electronics and Communication Technology, Gauhati University

Assistant Professor

Sunandan Baruah, Assam Don Bosco University

Department of Electronics and Communication Engineering, Assam Don Bosco University

Professor

References

Lal Chand Godara, ”Handbook of Antennas in Wireless Communication”,

The Electrical Engineering and Applied Signal Processing Series,

(2001).

Balanis C. A., ”Handbook of Antennas in Wireless Communication”,

John Wiley & Sons, Inc., (1997).

A. Kundu, Bappadittya Roy, S. Batabyal, U. Chakraborty, A. K. Bhattacharjee,”

A Coaxial fed Compact Rectangular Microstrip Antenna with

Multi-layer Configuration for WLAN2.4/5.2/5.8 GHZ band Applications”,

International Conference on Industrial and Information Systems

(ICIIS), (2014).

S. Gai, Y. C. Jiao, Y. B. Yang, C. Y. Li, and J.-G. Gong, ”Design of A

Novel Microstrip-Fed Dual-Band Slot Antenna for WLAN applications”,

Progress In Electromagnetics Research Letters, 13, 7581, (2010).

Shams, K. M. Z., M. Ali, and H. S. Hwang, ”A planar inductively

coupled bow-tie slot antenna for WLAN application”, Journal of Electromagnetic

Waves and Applications, 20 (7), 861-871, (2006).

Eldek, A. A., A. Z. Elsherbeni, and C. E. Smith, ”Square slot antenna

for dual wideband wireless communication systems”, Journal of Electromagnetic

Waves and Applications, 19 (12), 1571-1581, (2005).

G. BiffiGentili, P. Piazzesi, and C. Salvador, ”Dual-band slot-loaded

patch antenna”,In Microwaves, Antennas and Propagation, IEEE Proceedings,

(3),225-232. IET, (1995).

G. F. Khodaei, J. Nourinia, and C. Ghobadi, ”A practical miniaturized

u-slot patch antenna with enhanced bandwidth”, Progress In Electromagnetics

Research B, 3, 47-62, (2008).

Sivaranjan Goswami, Kumaresh Sarmah, Angana Sarma, Kandarpa

Kumar Sarma, Sunandan Baruah, ”Slot Loaded Square Patch Antenna

with CSRR at Ground Plane”, Microelectronics, Computing and Communications

(MicroCom), (2016).

Li-Ming Si, Weiren Zhu, Hou-Jun Sun, ”A Compact, Planar, and CPWFed

Metamaterial-Inspired Dual-Band Antenna”, IEEE Antennas and

Wireless Propagation Letters, 12, (2013).

Abeesh, T. and M Jayakumar, ”Design and studies on dielectric resonator

on-chip antennas for millimeter wave wireless application”, Proceeding

of 2011 International Conference on Signal Processing Communication

Computing and Networking Technologies (ICSCCN 2011), IEEE, (2011).

Chen, X., Han, L., Chen, X., Zeng, Q., and Zhang, W., ”A Wideband

Coplanar Waveguide Antenna Array with Series Feed”, IEEE Antennas

and Wireless Propagation Letters, 16, 565-568, (2017).

Abdullah, B., Suryani, S., and Bannu., ”Microstrip antenna slot doublebowtie

five-array model with coplanar waveguides for 5.8 GHz communication”,

In AIP Conference Proceedings, 1801 (1), 050004). AIP

Publishing. (2017).

Nugraha, I. P. E. D., Surjati, I., and Alam, S., ”Miniaturized Minkowski-

Island Fractal Microstrip Antenna Fed by Proximity Coupling for Wireless

Fidelity Application”, TELKOMNIKA(Telecommunication Computing

Electronics and Control), 15 (3), (2017).

Sedghi, M. S., Naser-Moghadasi, M., and Zarrabi, F. B., ”Microstrip

antenna miniaturization with fractal EBG and SRR loads for linear and

circular polarizations”, International Journal of Microwave and Wireless

Technologies, 9 (4), 891-901, (2017).

Sedghi, M. S., Naser-Moghadasi, M., and Zarrabi, F. B., ”Broadband

CPW Fed Slotted Ground Antenna”, IOSR Journal of Electronics and

Communication Engineering (IOSRJECE), (2), 36-39, (2012).

Shivnarayan, Shashank Sharma, Babau R Vishwakarma, ”Analysis of

slot-loaded rectangular microstrip patch antenna”, Indian Journal of

Radio and Space Physics,34 (2), 424-430, (2005).

Downloads

Published

2024-04-19

Issue

Section

Antennas, Radars and Radiowave Propagation