Reconfigurable Intelligent Surfaces for Doppler Effect and Multipath Fading Mitigation

TL;DR

This paper explores the use of reconfigurable intelligent surfaces (RISs) to mitigate Doppler effects and multipath fading in future wireless networks, demonstrating their potential to improve signal stability and reduce fading.

Contribution

It introduces novel solutions utilizing RISs to eliminate or significantly reduce multipath fading and Doppler spread caused by receiver movement in wireless systems.

Findings

RISs can effectively reduce rapid fluctuations in received signal strength.

Coating all reflectors with RISs can eliminate multipath fading.

Even a few RISs can significantly improve signal stability in complex environments.

Abstract

Extensive research has already started on 6G and beyond wireless technologies due to the envisioned new use-cases and potential new requirements for future wireless networks. Although a plethora of modern physical layer solutions have been introduced in the last few decades, it is undeniable that a level of saturation has been reached in terms of the available spectrum, adapted modulation/coding solutions and accordingly the maximum capacity. Within this context, communications through reconfigurable intelligent surfaces (RISs), which enable novel and effective functionalities including wave absorption, tuneable anomalous reflection, and reflection phase modification, appear as a potential candidate to overcome the inherent drawbacks of legacy wireless systems. The core idea of RISs is the transformation of the uncontrollable and random wireless propagation environment into a reconfigurable communication system entity that plays an active role in forwarding information. In this paper, the well-known multipath fading phenomenon is revisited in mobile wireless communication systems, and novel and unique solutions are introduced from the perspective of RISs. The feasibility of eliminating or mitigating the multipath fading effect stemming from the movement of mobile receivers is also investigated by utilizing the RISs. It is shown that rapid fluctuations in the received signal strength due to the Doppler effect can be effectively reduced by using the real-time tuneable RISs. It is also proven that the multipath fading effect can be totally eliminated when all reflectors in a propagation environment are coated with RISs, while even a few RISs can significantly reduce the Doppler spread as well as the deep fades in the received signal for general propagation environments with several interacting objects.