SUMMARY
UCLA researchers in the Departments of Electrical Engineering and Mechanical & Aerospace Engineering and have designed a novel low profile antenna with suppressed platform effect.
BACKGROUND
The increasing applications of antennas in wireless communications have hastened the development of miniature antennas such as low-profile antennas. There has been a growing interest in the use of multiferroic materials for low-profile antennas due to their high permittivity and permeability, which allows miniaturization by several orders of magnitude. However, in traditional conduction current based antennas, the extent to which low-profile antennas can be miniaturized is limited by the platform effect.
INNOVATION
Dr. Yuanxun Ethan Wang and colleagues have designed a strain-mediated multiferroic antenna that uses dynamic strain induced by a bulk acoustic wave resonator to generate the electromagnetic waves. The bulk acoustic wave resonance is used to enhance the coupling between the acoustic waves generated by the dynamic strain and the electromagnetic waves. Dr. Wang and colleagues have also developed a one-dimensional finite-difference time-domain technique to model the dynamic two-way interactions between the acoustic waves and electromagnetic waves. Analytical and simulation analyses showed that the platform effect could be significantly reduced, and an antenna with a thickness of only few micrometers above the conducting plane can be built.
POTENTIAL APPLICATIONS
The proposed invention can be potentially used for all applications of low-profile antennas such as:
ADVANTAGES
RELATED MATERIALS
STATE OF DEVELOPMENT
The antenna structure has been designed and tested using simulations.