Title :
Broadband, Miniaturized Stacked-Patch Antennas for L-Band Operation Based on Magneto-Dielectric Substrates
Author :
Namin, Farhad ; Spence, Thomas G. ; Werner, Douglas H. ; Semouchkina, Elena
Author_Institution :
Dept. of Electr. Eng., Pennsylvania State Univ. (Penn State), University Park, PA, USA
Abstract :
Design of stacked-patch antennas using magneto-dielectric substrates was investigated. In particular, special types of substrates with identical relative permittivity and permeability were considered. The optimal design parameters were determined using a genetic algorithm. It will be shown that by employing these matched magneto-dielectric substrates, a significant miniaturization of up to 60% can be achieved while providing a large operating bandwidth (20%). Several design examples were considered and their performance was evaluated using a full-wave analysis technique based on the method of moments. The tradeoff between antenna gain and degree of miniaturization for a fixed bandwidth was also investigated. A fabrication methodology for obtaining the required matched magneto-dielectric substrate materials is also proposed.
Keywords :
broadband antennas; dielectric materials; genetic algorithms; magnetic materials; method of moments; microstrip antennas; permeability; permittivity; L-band operation; broadband stacked-patch antennas; fabrication methodology; full-wave analysis technique; genetic algorithm; magneto-dielectric substrates; method of moments; miniaturized stacked-patch antennas; permeability; permittivity; Algorithm design and analysis; Bandwidth; Broadband antennas; Dielectric substrates; Genetic algorithms; L-band; Magnetic analysis; Magnetic materials; Permeability; Permittivity; Antenna miniaturization; genetic algorithms; magneto-dielectric material; stacked-patch antennas;
Journal_Title :
Antennas and Propagation, IEEE Transactions on
DOI :
10.1109/TAP.2010.2052574
