Spectrum Learning-Aided Reconfigurable Intelligent Surfaces for 'Green' 6G Networks

TL;DR

This paper proposes a spectrum learning-aided reconfigurable intelligent surface framework to enhance energy efficiency in 6G networks by dynamically controlling RIS elements based on spectral environment insights.

Contribution

It introduces a novel spectrum learning-assisted RIS approach that intelligently manages RIS element states for improved energy efficiency in green 6G networks.

Findings

Energy efficiency is significantly improved with the proposed framework.

Dynamic RIS configuration based on spectrum learning enhances SINR.

The approach is validated through a specific case study.

Abstract

In the sixth-generation (6G) era, emerging large-scale computing based applications (for example processing enormous amounts of images in real-time in autonomous driving) tend to lead to excessive energy consumption for the end users, whose devices are usually energy-constrained. In this context, energy-efficiency becomes a critical challenge to be solved for harnessing these promising applications to realize 'green' 6G networks. As a remedy, reconfigurable intelligent surfaces (RIS) have been proposed for improving the energy efficiency by beneficially reconfiguring the wireless propagation environment. In conventional RIS solutions, however, the received signal-to-interference-plus-noise ratio (SINR) sometimes may even become degraded. This is because the signals impinging upon an RIS are typically contaminated by interfering signals which are usually dynamic and unknown. To address this issue, `learning' the properties of the surrounding spectral environment is a promising solution, motivating the convergence of artificial intelligence and spectrum sensing, termed here as spectrum learning (SL). Inspired by this, we develop an SL-aided RIS framework for intelligently exploiting the inherent characteristics of the radio frequency (RF) spectrum for green 6G networks. Given the proposed framework, the RIS controller becomes capable of intelligently `{think-and-decide}' whether to reflect or not the incident signals. Therefore, the received SINR can be improved by dynamically configuring the binary ON-OFF status of the RIS elements. The energy-efficiency benefits attained are validated with the aid of a specific case study. Finally, we conclude with a list of promising future research directions.