International Journal of Computer Applications
Foundation of Computer Science (FCS), NY, USA
|
Volume 56 - Issue 3 |
Published: October 2012 |
Authors: V. V. Mapare, S. V. Mapare, G. G. Sarate |
![]() |
V. V. Mapare, S. V. Mapare, G. G. Sarate . Nonradiating Edges Gap-Coupled Multiple Resonator Dual and Tri-Band Microstrip Antennas. International Journal of Computer Applications. 56, 3 (October 2012), 6-10. DOI=10.5120/8869-2841
@article{ 10.5120/8869-2841, author = { V. V. Mapare,S. V. Mapare,G. G. Sarate }, title = { Nonradiating Edges Gap-Coupled Multiple Resonator Dual and Tri-Band Microstrip Antennas }, journal = { International Journal of Computer Applications }, year = { 2012 }, volume = { 56 }, number = { 3 }, pages = { 6-10 }, doi = { 10.5120/8869-2841 }, publisher = { Foundation of Computer Science (FCS), NY, USA } }
%0 Journal Article %D 2012 %A V. V. Mapare %A S. V. Mapare %A G. G. Sarate %T Nonradiating Edges Gap-Coupled Multiple Resonator Dual and Tri-Band Microstrip Antennas%T %J International Journal of Computer Applications %V 56 %N 3 %P 6-10 %R 10.5120/8869-2841 %I Foundation of Computer Science (FCS), NY, USA
A rectangular microstrip antenna for dual band and tri-band is developed using a parasitic technique. Single rectangular microstrip is splitted into multiple resonators along the width and gap coupled to non-radiating edges. The proposed structure gives sufficient separation between the operating frequencies increasing bandwidth for dual band and tri-band. It covers the frequency range from 1900 MHz to 3 GHz covering Universal Mobile Telecommunication System (UMTS, 1920-2170 MHz), Wireless Local Area Network (WLAN, 2400-2483. 5 MHz) and low band Worldwide Interoperability for Microwave Access (WIMAX, 2. 5 to 2. 8 GHz). Simulation results are presented and discussed.