Fractal OAM Generation and Detection Schemes

TL;DR

This paper introduces Talbot-effect-based fractal OAM generation and detection schemes that enhance capacity and reduce bit error rates in unaligned optical and radio-frequency OAM communications.

Contribution

It proposes novel fractal OAM schemes leveraging the Talbot effect, improving alignment tolerance, capacity, and BER performance over traditional OAM methods.

Findings

Numerical analysis confirms the effectiveness of the fractal OAM scheme.

Simulation results show improved capacity and BER performance.

Analysis of UCA radius and distance impacts on system performance.

Abstract

Orbital angular momentum (OAM) carried electromagnetic waves have the potential to improve spectrum efficiency in optical and radio-frequency communications due to the orthogonal wavefronts of different OAM modes. However, OAM beams are vortically hollow and divergent, which significantly decreases the capacity of OAM transmissions. In addition, unaligned transceivers in OAM transmissions can result in a high bit error rate (BER). The Talbot effect is a self-imaging phenomenon that can be used to generate optical or radio-frequency OAM beams with periodic repeating structures at multiples of a certain distance along the propagation direction. These periodic structures make it unnecessary for the transceiver antennas to be perfectly aligned and can also alleviate the hollow divergence of OAM beams. In this paper, we propose Talbot-effect-based fractal OAM generation and detection schemes using a uniform circular array (UCA) to significantly improve capacity and BER performance in unaligned OAM transmissions. We first provide a brief overview of fractal OAM. Then, we propose the fractal OAM beam generation and detection schemes. Numerical analysis and simulations verify the effectiveness of our proposed fractal OAM generation scheme and also demonstrate improved capacity and BER performance compared to normal OAM transmissions. We also analyze how the receive UCA radius and the distance between the UCAs impact the capacity and BER performances.