Author_Institution :
California Univ., Los Angeles, CA, USA
Abstract :
A full-wave analysis based on the method of moments (MoM) is carried out for a reconfigurable-aperture antenna consisting of a two-dimensional (2-D) array of filamentary microstrip-dipoles interconnected by lossy microelectromechanical-system (MEMS) switches. Activation of specific MEMS switches allows the dipoles to be maintained near the halfwave-resonant length as the frequency is reduced in octave increments between 16 and 2 GHz. This keeps the real part of the dipole self-impedance much higher and the imaginary part much lower than in a dipole having a fixed length of λ/2 at 16 GHz. Hence, the array antenna gain and aperture efficiency remain much higher with frequency than in an array of fixed dipoles. Broad side aperture efficiencies of -3.9, -6.0, -9.5, and -10.6 dB are predicted for 16×16, 8×8, 4×4, and 2×2 recap dipole arrays at frequencies of 16, 8, 4, and 2 GHz, respectively, for MEMS switches having 0.5 dB insertion loss. In contrast, fixed-element λ/2-separated arrays operating at the same frequencies have predicted efficiencies of -3.9, -24.2, -45.0, and -63.0 dB, respectively
Keywords :
aperture antennas; dipole antenna arrays; electric impedance; integral equations; method of moments; micromechanical devices; microstrip antenna arrays; planar antenna arrays; spectral-domain analysis; 0.5 dB; 2 to 16 GHz; 2D array; MEMS switches; MoM; aperture efficiency; array antenna gain; dipole self-impedance; filamentary microstrip-dipoles; full-wave analysis; halfwave-resonant length; insertion loss; lossy microelectromechanical system switches; method of moments; recap dipole arrays; reconfigurable-aperture antenna; two-dimensional array; Antenna arrays; Apertures; Dipole antennas; Frequency; Micromechanical devices; Microstrip antenna arrays; Microstrip antennas; Microswitches; Moment methods; Two dimensional displays;
