CFP last date
20 January 2025
Reseach Article

Design of Novel Wideband CPW Irregular Pentagonal Patch Antenna

by Raad H. Thaher, Saif Nadhim Alsaidy
International Journal of Computer Applications
Foundation of Computer Science (FCS), NY, USA
Volume 139 - Number 4
Year of Publication: 2016
Authors: Raad H. Thaher, Saif Nadhim Alsaidy
10.5120/ijca2016909149

Raad H. Thaher, Saif Nadhim Alsaidy . Design of Novel Wideband CPW Irregular Pentagonal Patch Antenna. International Journal of Computer Applications. 139, 4 ( April 2016), 31-37. DOI=10.5120/ijca2016909149

@article{ 10.5120/ijca2016909149,
author = { Raad H. Thaher, Saif Nadhim Alsaidy },
title = { Design of Novel Wideband CPW Irregular Pentagonal Patch Antenna },
journal = { International Journal of Computer Applications },
issue_date = { April 2016 },
volume = { 139 },
number = { 4 },
month = { April },
year = { 2016 },
issn = { 0975-8887 },
pages = { 31-37 },
numpages = {9},
url = { https://ijcaonline.org/archives/volume139/number4/24481-2016909149/ },
doi = { 10.5120/ijca2016909149 },
publisher = {Foundation of Computer Science (FCS), NY, USA},
address = {New York, USA}
}
%0 Journal Article
%1 2024-02-06T23:40:04.822258+05:30
%A Raad H. Thaher
%A Saif Nadhim Alsaidy
%T Design of Novel Wideband CPW Irregular Pentagonal Patch Antenna
%J International Journal of Computer Applications
%@ 0975-8887
%V 139
%N 4
%P 31-37
%D 2016
%I Foundation of Computer Science (FCS), NY, USA
Abstract

In this paper a printed microstrip patch antenna for bands S, C, X and Parts of L, Ku is proposed. The proposed antenna consists of a beveled CPW irregular pentagonal patch on one side of dielectric substrate and c-shape independent piece in the other side, the dimension of this antenna is (33×30) mm2. Simulated results indicate that the antenna achieved bandwidth (S11≤-10dB) ranges from 1.48-14.2 GHz and give gain varying from 0dBi to 4.3dBi. The proposed antenna exhibits a good characteristics performance. The proposed antenna is fabricated and tested practically and found good agreement between the simulation and measured. This antenna is suitable for the applications that operate in these bands.

References
  1. K. L. Wong, Design of Nonplanar Microstrip Antennas and Transmission Lines. New York: Wiley, 1999.
  2. S. L. Latif, L. Shafai, and S. K. Shaema, “Bandwidth enhancement and size reduction of microstrip slot antenna,” IEEE Trans. Antennas Propag., vol. 53, no. 3, pp. 994–1003, 2005.
  3. H. F. Pues and A. R.Van de Capelle, “An impedance matching technique for increasing the bandwidth of microstrip antennas,” IEEE Trans. Antennas Propag., vol. 37, pp. 1345–1354, Nov. 1989.
  4. G. Ramesh, “Microstrip Antenna Design Handbook,” Artech House, Inc., 2001.
  5. K.-L. Wong, Compact and Broadband Microstrip Antennas. New York: Wiley, 2002.
  6. M. Nagalingam, and C.-P. Tan K.-S. Lim, “Design and Construction of Microstrip UWB Antenna with Time Domain Analysis,” Progress in Electromagnetics Research M, vol. 3, pp. 153-164, October 2008.
  7. S Kulhar Krishan Gopal Jangid, “Design of Compact Microstrip Patch Antenna with DGS Structure for WLAN & Wi-MAX Applications,” European Journal of Advances in Engineering and Technology, vol. 2, no. 1, pp. 8-11, October 2015.
  8. F. Yang, X.-X. Zhang, X. Ye, and Y. Rahmat-Samii, “Wide-band E-patched patch antenna for wireless communications,” IEEE Trans. Antennas Propag., vol. 49, pp. 1094–1100, Jul. 2001.
  9. J.-Y. Sze and K.-L. Wong, “Slotted rectangular microstrip antenna for bandwidth enhancement,” IEEE Trans. Antennas Propag., vol. 48, no. 8, pp. 1149–1152, 2000.
  10. H. K. Kan and R. B. Waterhouse, “Small square dual spiral printed antenna,” Electron. Lett., vol. 37, pp. 478–479, Apr. 2001.
Index Terms

Computer Science
Information Sciences

Keywords

Wide-Band Antenna Return Loss Voltage Standing Wave Ratio Radiation Pattern Group Delay.