International Journal of Radio Frequency Design

Open Access  Subscription or Fee Access

In the design, firstly design a patch antenna at resonating frequency 2.74 GHz. After that, the antenna design with the planned “split hexagonal rings” of left handed material (LHM) structure, due to this cover of LHM structure the antenna is start resonating at frequency 2.56 GHz. For designing an antenna at resonating frequency 2.56 GHz is required more space than the design. The resonating frequency decreases when the size of antenna is increased. The purpose of this design, the size of antenna is constant and still managed to decrease the resonant frequency. In the design, the microstrip patch antenna (MPA) is incorporated with the LHM cover which has some unique properties so the antenna is reduces return loss, VSWR improves and greatly improve its gain. The purpose of this work is to improvement in parameters of MPA like greatly improve its gain, reduces its return loss and VSWR all simulated results are analyzed by using computer simulation technology (CST-MS) microwave studio software 2010.

C.A. Balanis. Antenna Theory and Design. John Wiley & Sons, Inc.; 1997.

V.G. Veselago. The electrodynamics of substances with simultaneously negative value ε and μ, Sov Phys Uspekekhy. 1968; 10(4): 509–14p.

W.L. Stutzman, G.A. Thiele. Antenna Theory and Design. 2nd Ed., New York: John Wiley & Sons; 1998.

J.B. Pendry, A.J. Holden, D.J. Robbins, W.J. Stewart. magnetism from conductors and enhanced nonlinear phenomena, IEEE Trans Micro Tech. 1999; 47(11): 2075–81p.

D.R. Smith, W.J. Padilla, D.C. Vier, et al. Composite medium with simultaneously negative permeability and permittivity, Phys Rev Lett. 2000; 84: 4184–7p.

J.B. Pendry. Negative refraction males a prefect lens, Phys Rev Lett. 2000; 85: 3966–96p.

D.M. Pozar. Microwave Engineering. 3rd Edn., John Wiley & Sons; 2004.

N. Engheta, R.W. Ziolkowski. LHM Physics & Engineering Explorations. July 11, 2006.

A.A. Sulaiman, A.S. Nasaruddin. Bandwidth Enhancement in patch antenna by LHM substrate, Eur J Sci Res. 2010.

H.A. Mazid, M.K.A. Rahim, T. Masri. Left-handed LHM design for microstrip antenna application, IEEE International RF and Microwave Conference. 2008.

G. Lovat, P. Burghignoli, F. Capolino, D.R. Jackson, R.W. Ziolkowski. Combinations of low/high permittivity and/or permeability substrates for highly directive planar LHM antennas, IET Microw. Anten Propag. 2007; 1: 177p.

S. Pyo, S.-M. Han, J.-W. Baik, W.-S. Yoon, Y.-S. Kim. Offset-fed LHM antenna for radiation mode generation with efficiency improvement, IET Microw Anten Propag. 2010; 4: 1481p.

H.A. Majid, M.K.A. Rahim, T. Marsi. Microstrip antenna gain enhancement using left-handed LHM structure, Prog Electromagn Res. 2009; 8: 235–47p.

R. Varma, S.K. Sharma, B. Singh. Improvement in rectangular microstrip patch antenna parameters using LHM with active devices, IEEE. 2014.

P.K. Singhal, B. Garg, N. Agrawal. A high gain rectangular microstrip patch antenna using “different C patterns” LHM design in L-band, Adv Comput Tech Electromagn. 2012.

P.K. Singhal, B. Garg. A high gain & wide band rectangular microstrip patch antenna loaded with interconnected SRR LHM structure, Int J Eng Technol. 2012.

P.K. Singhal, B. Garg. Design and characterization of compact microstrip patch antenna using “Split Ring” shaped LHM structure, Int J Electr Comput Eng. 2012; 2(5).