A Miniaturized Low Frequency (LF) Magnetoelectric Receiving Antenna with an Integrated DC Magnetic Bias

TL;DR

This paper introduces a miniaturized low-frequency magnetoelectric antenna with an integrated DC magnetic bias, significantly reducing size and enhancing performance for applications like underwater and IoT communications.

Contribution

The development of a compact LF ME antenna with integrated DC magnetic bias that improves performance and reduces size compared to prior designs.

Findings

Maximum operation distance of 2.5m with magnetic bias

2.27 times longer operation distance than without bias

Characterized efficiency, gain, and quality factor

Abstract

Due to the applications in meteorological broadcasts, radio navigation and underwater communications, low-frequency(LF) receiving antennas have been actively studied. However, because the frequency range of LF antenna is 30kHz to 300kHz, its electromagnetic wavelength is 1km to 10km, which makes LF electromagnetic antennas difficult to be implemented in miniaturized or portable devices. This article presents a miniaturized LF magnetoelectric(ME) receiving antenna with an integrated DC magnetic bias. The antenna is based on the magnetoelectric effect and operates by resonance at its mechanical resonant frequency. Thus, compared with traditional LF wire antennas, the dimension of ME antenna is reduced significantly. Compared with prior art of ME antennas which do not have DC magnetic bias, higher performance can be achieved by integrating the miniaturized DC magnetic bias. Compared with prior art of an ME antenna with bulky external DC magnetic bias, the ME antenna with an integrated DC magnetic bias significantly reduce its dimension. Magnetostrictive TbDyFe2(Terfenol-D) and piezoelectric lead zirconate titanate(PZT) thin films are bonded together to form the 38x12x5.8mm3 ME receiving antenna. Four 10x10x10mm3 Rb magnets are implemented to provide an optimal DC bias for the antenna. A maximum operation distance of 2.5m is demonstrated with the DC magnetic field bias, 2.27 times of the maximum operation distance of the antenna without DC magnet field bias. The efficiency, gain and quality factor the ME receiving antenna is also characterized. The miniaturized LF ME antenna could have potential applications in portable electronics, internet of things and underwater communications.