LiFi through Reconfigurable Intelligent Surfaces: A New Frontier for 6G?

Light fidelity (LiFi), which is based on visible light communications (VLC), is celebrated as a cutting-edge technological paradigm that is envisioned to be an indispensable part of 6G systems. Nonetheless, LiFi performance is subject to efficiently overcoming the line-of-sight blockage, whose adverse effect on the reliability of wireless reception becomes even more pronounced in highly dynamic environments, such as vehicular applications. Meanwhile, reconfigurable intelligent surfaces (RISs) emerged recently as a revolutionary concept that transforms the physical propagation environment into a fully controllable and customisable space in a low-cost low-power fashion. We anticipate that the integration of RISs in LiFi enabled networks will not only support blockage mitigation but will also provision complex interactions among network entities, and is hence manifested as a promising platform that enables a plethora of technological trends and new applications. In this article, for the first time in the open literature, we set the scene for a holistic overview of RIS-assisted LiFi systems. Specifically, we explore the underlying RIS architecture from the perspective of physics and present a forward-looking vision that outlines potential operational elements supported by RIS-enabled transceivers and RIS-enabled environments. Finally, we highlight major associated challenges and offer a look ahead toward promising future directions.

[1]  Octavia A. Dobre,et al.  An Outlook on the Interplay of Artificial Intelligence and Software-Defined Metasurfaces: An Overview of Opportunities and Limitations , 2020, IEEE Vehicular Technology Magazine.

[2]  Mohamed-Slim Alouini,et al.  Smart Radio Environments Empowered by Reconfigurable Intelligent Surfaces: How it Works, State of Research, and Road Ahead , 2020, ArXiv.

[3]  Ana Díaz-Rubio,et al.  From the generalized reflection law to the realization of perfect anomalous reflectors , 2016, Science Advances.

[4]  Harald Haas,et al.  Optical wireless communications for cyber-secure ubiquitous wireless networks , 2020, Proceedings of the Royal Society A.

[5]  Marzieh Najafi,et al.  Intelligent Reflecting Surfaces for Free Space Optical Communications , 2019, 2019 IEEE Global Communications Conference (GLOBECOM).

[6]  Minghui Hong,et al.  Orbital Angular Momentum Multiplexing and Demultiplexing by a Single Metasurface , 2017 .

[7]  Mohamed-Slim Alouini,et al.  Visible Light Communications via Intelligent Reflecting Surfaces: Metasurfaces vs Mirror Arrays , 2021, IEEE Open Journal of the Communications Society.

[8]  George K. Karagiannidis,et al.  Simultaneous Lightwave Information and Power Transfer: Policies, Techniques, and Future Directions , 2019, IEEE Access.

[9]  Octavia A. Dobre,et al.  Re-Configurable Intelligent Surface-Based VLC Receivers Using Tunable Liquid-Crystals: The Concept , 2021, Journal of Lightwave Technology.

[10]  Volker Jungnickel,et al.  Coexistence of WiFi and LiFi toward 5G: concepts, opportunities, and challenges , 2016, IEEE Communications Magazine.

[11]  Bangjiang Lin,et al.  Li-Tect: 3-D Monitoring and Shape Detection Using Visible Light Sensors , 2019, IEEE Sensors Journal.

[12]  Zhaohui Yang,et al.  Reflecting the Light: Energy Efficient Visible Light Communication with Reconfigurable Intelligent Surface , 2020, 2020 IEEE 92nd Vehicular Technology Conference (VTC2020-Fall).

[13]  S. Horsley,et al.  Zero-refractive-index materials and topological photonics , 2020, Nature Physics.

[14]  Miaowen Wen,et al.  Single-RF MIMO: From Spatial Modulation to Metasurface-Based Modulation , 2020, IEEE Wireless Communications.