Title :
A Substrate Integrated Fluidic Compensation Mechanism for Deformable Antennas
Author :
Long, S. Andrew ; Huff, Gregory H.
Author_Institution :
Dept. of Electr. & Comput. Eng., Texas A&M Univ., College Station, TX, USA
fDate :
July 29 2009-Aug. 1 2009
Abstract :
This work presents the design, theory, and measurement of a linearly polarized microstrip patch antenna with a substrate-integrated compensation mechanism to mitigate the detuning effects from a physical deformation (e.g., bending and twisting). In particular, we investigate the ability of an antenna to maintain its impedance bandwidth as it bends sharply through the center (from flat up to 90deg pivoted about the ground plane). Compensation for this bending occurs through the displacement of electromagnetically functionalized colloidal dispersions (EFCDs) in a substrate-embedded capillary. Stability of the 2:1 VSWR (matched impedance) bandwidth has been examined numerically across the entire range of bending, and demonstrated experimentally using fixed-bend patch antennas on 4 mm thick isocane foam substrates to illustrate this concept.
Keywords :
deformation; dispersion (wave); microstrip antennas; stability; VSWR; deformable antennas; electromagnetically functionalized colloidal dispersions; linearly polarized microstrip patch antenna; matched impedance bandwidth; physical deformation; stability; substrate integrated fluidic compensation; Aerodynamics; Aircraft; Antenna theory; Bandwidth; Electromagnetic coupling; Electromagnetic radiation; Impedance; Microstrip antennas; Patch antennas; Shape; Conformal antennas; compensation; component; dispersion; microfluidic; reconfigurable;
Conference_Titel :
Adaptive Hardware and Systems, 2009. AHS 2009. NASA/ESA Conference on
Conference_Location :
San Francisco, CA
Print_ISBN :
978-0-7695-3714-6
DOI :
10.1109/AHS.2009.70
