Spatial Mode Multiplexing for Fiber-Coupled IM/DD Optical Wireless Links with Misalignment

TL;DR

This paper investigates the impact of misalignment on spatial mode multiplexing fiber-coupled optical wireless links with IM/DD, proposing a zero-forcing beamforming approach to mitigate crosstalk and significantly enhance capacity.

Contribution

It provides a theoretical model for coupling efficiency under misalignment and introduces a zero-forcing beamforming method to improve data rates in SMM-based OWC systems.

Findings

Coupling efficiency depends on incident mode order and beam properties.

Zero-forcing beamforming effectively reduces intermodal crosstalk.

System capacity can be increased by over 200% with optimal configurations.

Abstract

Optical wireless communication (OWC) emerges as a pivotal solution for achieving terabit-level aggregate throughput in next-generation wireless networks. With the mature high-speed transceivers and advanced (de)multiplexing techniques designed for fiber optics, fiber-coupled OWC can be seamlessly integrated into existing ultra-high-speed networks such as data centres. In particular, OWC leveraging spatial mode multiplexing (SMM) and few-mode fiber (FMF) coupling can significantly increase capacity, though misalignment may reduce performance. This paper presents a thorough investigation into the SMM-enabled FMF coupling OWC systems affected by link misalignment, specifically focusing on systems with intensity modulation with direct detection (IM/DD) receivers. A theoretical analysis is conducted to assess the fiber coupling efficiency of the considered system in the presence of both pointing error and angle of arrival (AOA) fluctuations caused by random device vibrations. Our model elucidates the dependence of coupling efficiency to the order of the incident modes, highlighting the critical role of beam properties in system performance. To mitigate the intermodal crosstalk arising from link misalignment, we employ zero-forcing beamforming (ZFBF) to enhance the overall aggregated data rate. Through extensive numerical results, we identify optimal system configurations encompassing aperture design and mode selection, leading to a capacity boost exceeding 200%.