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Abstract

It is well known that microstrip antennas on high permittivity substrates (e.g., ferroelectric materials) suffer from narrow bandwidth and poor efficiency that is due to the energy loss associated with the excitation of surface waves modes. This problem could be solved with several multi-layered antenna configurations presented in this paper. It is known that the optimization of these multi-layer antennas requires simultaneous variation of the dielectric constant, air gap, and the thickness of substrate layer. The simulation studies presented in this paper, using An soft Ensemble shows that for electromagnetically-coupled air gap multi-layered structure, a positive gain of 2 dB is achieved, resulting in a gain improvement of at least 5 dB compared to the poor gain performance of a single layered structure. It is shown that stacking a ferroelectric layer directly on top of a conventional microstrip antenna could eliminate the air gap spacing. This design has additional advantages like improvement in gain and creates a tunable dual band antenna performance. A larger gain improvement is also realized with this direct-stacking arrangement compared to the air-gap coupled structure. These antennas may find wide applications in intelligent systems and structures.

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References

Afzalzadeh, R. and R. N. Karekar . 1992. “X-band Directive Single Microstrip Patch Antenna Using Dielectric Parasite”, Electron Lett, 28: 17-19.

James, J. R. and P. S. Hall . 1989. Handbook of Microstrip Antennas. London, Peter Peregrinus.

Jose, K. A. , V. K. Varadan and V. V. Varadan . 1998. “Experimental Investigations on Electronically Tunable Microstrip Antennas,” Microwave and Optical Technology Letters, 20: 166-169.

Kathei, P. B. and N. G. Alexopoulos . 1983. “On the Effect of Substrate Thickness and Permittivity on Printed Circuit Dipole Properties,” IEEE Trans. Antennas Propagation, 31: 34-39.

Kiely, E. , G. N. Washington and J. Bernhard . 1998. “Design and Development of Smart Microstrip Patch Antennas,” Smart Mater Struct, 7: 792-800.

Lockyer, A. J. , J. N. Kudva and K. H. Alt. 1995. “Development of a Conformal Load-Carrying Smart Skin Antenna for Military Aircraft,” Proc. SPIE, 2448: 53-62.

Moore, S. A. W. and A. R. Moore . 1997. “Dual Frequency Multi-Function Radar Antenna Research,” Tenth Int. Conf. on Antennas and Propagation, 436: 522-526.

Pozar, D. M. 1983. “Considerations for Millimeter Wave Printed Antennas”, IEEE Trans. Antennas Propagation, 31: 740-747.

Pozar, D. M. and S. M. Duffy . 1997. “A Dual-Band Circularly Polarized Aperture-Coupled Stacked Microstrip Antenna for Global Positioning Satellite,” IEEE Trans. Antennas Propagation, 45: 1618-1625.

10.

Rao, J. B. L. , D. P. Patel , L. C. Sengupta and J. Synowczynski . 1997. “Ferroelectric Materials for Phased Array Applications,” Proc. IEEE AP-S Int. Symp, 2284-2287.

11.

Schaubert, D. H. and K. S. Yngvesson . 1986. “Experimental Study of a Microstrip Array on High Permittivity Substrate,” IEEE Trans. Antennas Propagation, 34: 92-96.

12.

Sharrett, P. , Wysocki, J. , Freeload, G. , Brown, D. and Netherland, S. , 1992. ”GPS Performance: An Initial Assessment,” Navigation, 39: 1-24.

13.

Varadan, V. K. , Ghodgaonkar , V. V. Varadan , J. F. Kelly and P. Glikerdas . 1992. “Ceramic Phase Shifters for Electronically Steerable Antenna Systems,” Microwave Journal, 34: 116-125.

14.

Varadan, V. K. and V. V. Varadan . 1996. “Design and Development of Smart Skin Conformal Antenna with MEMS Structural Sensors and Actuators,” Proc. SPIE, 3046: 94.

15.

Varadan, V. K., S. Fathi and V. V. Varadan. 1996. “U.S. Patent 5557286.

16.

Varadan, V. K. , K. A. Jose and V. V. Varadan . 1999. “Design and Development of Electronically Tunable Microstrip Antennas,” Smart Mater Struct, 8: 238-242.

17.

Vinoy, K. J. , K. A. Jose , V. K. Varadan , and V. V. Varadan . 1999. “Gain Enhanced Electronically Tunable Microstrip Patch Antenna,” Microwave and Optical Technology Letters, Accepted for publication.

18.

Washington, G. N. 1996. “Smart Aperture Antennas,” Smart Mater Struct, 5: 801-805.

Design and Development of Tunable Multi-Layer Smart Antennas Using Ferroelectric Materials

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