Coherently Enhanced Wireless Power Transfer

TL;DR

This paper introduces a novel method called coherently enhanced wireless power transfer that uses interference to improve energy extraction efficiency in wireless systems, verified through theory, simulations, and experiments.

Contribution

It proposes a new approach employing coherent excitation to dynamically achieve conjugate matching and enhance wireless power transfer performance.

Findings

Significant increase in energy transfer efficiency demonstrated.

Theoretical model aligns with simulation and experimental results.

Potential for dynamic control of wireless power transfer.

Abstract

Extraction of electromagnetic energy by an antenna from impinging external radiation is at the basis of wireless communications and power transfer (WPT). The maximum of transferred energy is ensured when the antenna is conjugately matched, i.e., when it is resonant and it has an equal coupling with free space and its load, which is not easily implemented in near-field WPT. Here, we introduce the concept of coherently enhanced wireless power transfer. We show that a principle similar to the one underlying the operation of coherent perfect absorbers can be employed to improve the overall performance of WPT and potentially achieve its dynamic control. The concept relies on coherent excitation of the waveguide connected to the antenna load with a backward propagating signal of specific amplitude and phase. This signal creates a suitable interference pattern at the load resulting in a modification of the local wave impedance, which in turn enables conjugate matching and a largely increased amount of energy extracted to the waveguide. We develop an illustrative theoretical model describing this concept, demonstrate it with full-wave numerical simulations for the canonical example of a dipole antenna, and verify it experimentally in both near-field and far-field regimes.