Reconfigurable Intelligent Surfaces: Bridging the gap between scattering and reflection

TL;DR

This paper explores the near-field behavior of reconfigurable intelligent surfaces (RIS), revealing how their size and phase control influence distance dependence and potentially outperform free-space propagation.

Contribution

It introduces a near-field analysis of RIS, showing how physical size and phase optimization affect distance dependence, and provides a comprehensive signal characterization for various RIS regions.

Findings

Near-field RIS exhibits a second and third power distance dependence for planar and linear configurations.

Optimized phase control can make RIS outperform free-space propagation in near-field conditions.

The paper offers a complete signal characterization for RIS-assisted wireless links.

Abstract

In this work we address the distance dependence of reconfigurable intelligent surfaces (RIS). As differentiating factor to other works in the literature, we focus on the array near-field, what allows us to comprehend and expose the promising potential of RIS. The latter mostly implies an interplay between the physical size of the RIS and the size of the Fresnel zones at the RIS location, highlighting the major role of the phase. To be specific, the point-like (or zero-dimensional) conventional scattering characterization results in the well-known dependence with the fourth power of the distance. On the contrary, the characterization of its near-field region exposes a reflective behavior following a dependence with the second and third power of distance, respectively, for a two-dimensional (planar) and one-dimensional (linear) RIS. Furthermore, a smart RIS implementing an optimized phase control can result in a power exponent of four that, paradoxically, outperforms free-space propagation when operated in its near-field vicinity. All these features have a major impact on the practical applicability of the RIS concept. As one contribution of this work, the article concludes by presenting a complete signal characterization for a wireless link in the presence of RIS on all such regions of operation.