Performance of Wireless Optical Communication With Reconfigurable Intelligent Surfaces and Random Obstacles

TL;DR

This paper investigates how reconfigurable intelligent surfaces can enhance wireless optical communication by creating multiple artificial channels, reducing outages, and analyzing factors affecting system performance.

Contribution

It introduces a controllable multi-branch optical communication system using reconfigurable surfaces and derives analytical models for its performance metrics.

Findings

Multi-branch system improves performance over single-path systems.

Reconfigurable surfaces significantly reduce outage probability.

Channel coefficient distribution includes an impulse function causing error floors.

Abstract

It is difficult for free space optical communication to be applied in mobile communication due to the obstruction of obstacles in the environment, which is expected to be solved by reconfigurable intelligent surface technology. The reconfigurable intelligent surface is a new type of digital coding meta-materials, which can reflect, compute and program electromagnetic and optical waves in real time. We purpose a controllable multi-branch wireless optical communication system based on the optical reconfigurable intelligent surface technology. By setting up multiple optical reconfigurable intelligent surface in the environment, multiple artificial channels are built to improve system performance and to reduce the outage probability. Three factors affecting channel coefficients are investigated in this paper, which are beam jitter, jitter of the reconfigurable intelligent surface and the probability of obstruction. Based on the model, we derive the closed-form probability density function of channel coefficients, the asymptotic system's average bit error rate and outage probability for systems with single and multiple branches. It is revealed that the probability density function contains an impulse function, which causes irreducible error rate and outage probability floors. Numerical results indicate that compared with free-space optical communication systems with single direct path, the performance of the multi-branch system is improved and the outage probability is reduced.