Free-Space Optical Communications for 6G Wireless Networks: Challenges, Opportunities, and Prototype Validation

TL;DR

This paper demonstrates the feasibility of long-distance free-space optical (FSO) communication for 6G networks by successfully transmitting UHD videos over 20 km with turbulence mitigation using FPGA-based prototypes.

Contribution

It presents a novel FPGA-based FSO communication prototype capable of long-distance video transmission and introduces turbulence mitigation techniques like spatial filtering and pointing/tracking.

Findings

Successful transmission of UHD 4K videos over 20 km FSO link

Effective turbulence and misalignment compensation methods demonstrated

High-quality video transmission under severe environmental conditions

Abstract

Numerous researchers have studied innovations in future sixth-generation (6G) wireless communications. Indeed, a critical issue that has emerged is to contend with society's insatiable demand for high data rates and massive 6G connectivity. Some scholars consider one innovation to be a breakthrough--the application of free-space optical (FSO) communication. Owing to its exceedingly high carrier frequency/bandwidth and the potential of the unlicensed spectrum domain, FSO communication provides an excellent opportunity to develop ultrafast data links that can be applied in a variety of 6G applications, including heterogeneous networks with enormous connectivity and wireless backhauls for cellular systems. In this study, we perform video signal transmissions via an FPGA-based FSO communication prototype to investigate the feasibility of an FSO link with a distance of up to 20~km. We use a channel emulator to reliably model turbulence, scintillation, and power attenuation of the long-range FSO channel. We use the FPGA-based real-time SDR prototype to process the transmitted and received video signals. Our study also presents the channel-generation process of a given long-distance FSO link. To enhance the link quality, we apply spatial selective filtering to suppress the background noise generated by sunlight. To measure the misalignment of the transceiver, we use sampling-based pointing, acquisition, and tracking to compensate for it by improving the signal-to-noise ratio. For the main video signal transmission testbed, we consider various environments by changing the amount of turbulence and wind speed. We demonstrate that the testbed even permits the successful transmission of ultra-high-definition (UHD: 3840 x 2160 resolution) 60 fps videos under severe turbulence and high wind speeds.