Evolution of the Electromagnetic Manipulation: From Tunable to Programmable and Intelligent Metasurfaces

Luo, Sisi; Hao, Jianjiao; Ye, Fuju; Li, Jiaxin; Ruan, Ying; Cui, Haoyang; Liu, Wenjun; Chen, Lei

doi:10.3390/mi12080988

Cited by 17 publications

(7 citation statements)

References 118 publications

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“…In general, the control mechanism in RISs can be realized by using ultra-fast switching elements such as varactors, positive-intrinsic-negative (PIN) diodes, or micro-electro-mechanical systems (MEMS) switches that communicate with a central controller. As opposed to requiring human subjective judgement and recognition in controlling the operation of traditional metasurfaces, an RIS controller has the capability to sense the environment [90], and make use of intelligent algorithms to actively identify and judge environmental changes and make autonomous decisions on its operations [91], [92]. As a result, a dense deployment of RISs in any wireless communication network will allow full manipulation of transmitted and reflected waves to enable an intelligent control of the communication channel and signal propagation to enhance the end user's quality of experience.…”

Section: Ris Basics a Ris: The Conceptmentioning

confidence: 99%

RIS-Assisted Visible Light Communication Systems: A Tutorial

Aboagye¹,

Ndjiongue²,

Ngatched³

et al. 2022

Preprint

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Recent intensive and extensive development of the fifth-generation (5G) of cellular networks has led to their deployment throughout much of the world. As part of this implementation, one of the challenges that must be addressed is the skip-zone problem, which occurs when objects such as trees, people, animals, and vehicles obstruct the transmission of signals.In free-space optical (FSO) and radio frequency (RF) systems, dead zones are most often caused by buildings and trees, while in visible light communications (VLC), obstructions are caused by individuals moving around a room or objects placed in the room. A signal obstruction can significantly reduce the signal-to-noise ratio in RF and indoor VLC systems, whereas in FSO systems, where the transmitted signals are directional, the obstruction can completely disrupt data transmission. Therefore, the skipzone dilemma must be resolved to ensure the smooth and efficient operation of 5G and beyond networks. By placing a relay between a transmitter and a receiver, the effects of obstacles can be mitigated. As a result, the signal from the transmitter will reach the receiver. In recent years, reconfigurable intelligent surfaces (RISs) that are more efficient than relays have become widely accepted as a method of mitigating skip-zones and providing reconfigurable radio environments. However, there have been limited studies on RISs for optical wireless communication (OWC) systems. Through the RIS technology, OWC and RF communication channels can be reconfigured. This paper aims to provide a comprehensive tutorial on indoor VLC systems utilizing RIS technology. The article discusses the basics of VLC and RISs and reintroduces RISs for OWC systems, focusing on RIS-assisted indoor VLC systems. We also provide a comprehensive overview of optical RISs and examine the differences between optical RISs, RF-RISs, and optical relays. Furthermore, we discuss in detail how RISs can be used to overcome line-of-sight blockages and the device orientation issue in VLC systems while revealing key challenges such as RIS element orientation design, RIS elements to access point/user assignment design, and RIS array positioning design problems that need to be studied. Moreover, we discuss and propose several research problems on integrating optical RISs with other emerging technologies, including non-orthogonal multiple access, multiple-input multiple-output systems, physical layer security, and simultaneous lightwave and power transfer in VLC systems. Finally, we highlight other important research directions that can further improve the performance of RISassisted VLC systems.

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Section: Ris Basics a Ris: The Conceptmentioning

confidence: 99%

RIS-Assisted Visible Light Communication Systems: A Tutorial

Aboagye¹,

Ndjiongue²,

Ngatched³

et al. 2022

Preprint

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“…A number of approaches to create layered structures and their associated active controls are given in [20], [30], [31]. One such approach is to create layers with switching capabilities.…”

Section: Active Refractive Iementioning

confidence: 99%

Reconfigurable Intelligent Edges: Illuminating the Shadow Region in Wireless Networks

Cotton¹,

Abbasi²,

Machado³

et al. 2022

IEEE Access

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This paper proposes a new wireless enabling technology for future smart radio environments. The approach aims to enhance signal coverage within the shadow region(s) of wireless networks with the aid of so-called 'intelligent edges (IEs)'. IEs may be installed at the fringes of shadowing objects such as buildings, walls and other obstacles which obscure the optical signal path from a transmitter to receiver. We investigate two different approaches to illuminating the shadow region in wireless networks using IEs which exploit refraction or diffraction, operating in passive or active mode. The operation of IE-assisted communications are investigated, in particular the ways they can redirect electromagnetic energy towards regions with little or no wireless network coverage. Following from this, a number of variations of IEs are tested in real-world scenarios which consider illuminating the shadow region behind high-rise buildings, first in a city center, and then along a shoreline. Refractive IEs in particular, are shown to provide significant gains compared to the case when no IEs are involved, enhancing signal reception in the shadow region at street level behind a high rise building by as much as 12 dB. Critically, it is shown that intelligent edges offer a low complexity and cost-effective solution for improving connectivity in shadowing-limited environments.

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“…Progress in computer science enabled the development of such intriguing concepts as coding and digital (or programmable) metasurfaces [145][146][147][148][149][150][151][152] that fill a gap between IT and electrodynamics. Though the ML concepts can also be used just for a straightforward design of such structures [153][154][155][156][157][158][159], they expose a range of additional possibilities.…”

Section: Self-adapting Metasystemsmentioning

confidence: 99%

Intelligent metaphotonics empowered by machine learning

Krasikov,

Tranter,

Bogdanov

et al. 2021

Preprint

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In the recent years, we observe a dramatic boost of research in photonics empowered by the concepts of machine learning and artificial intelligence. The corresponding photonic systems, to which this new methodology is applied, can range from traditional optical waveguides to nanoantennas and metasurfaces, and these novel approaches underpin the fundamental principles of light-matter interaction developed for a smart design of intelligent photonic devices. Concepts and approaches of artificial intelligence and machine learning penetrate rapidly into the fundamental physics of light, and they provide effective tools for the study of the field of metaphotonics driven by opticallyinduced electric and magnetic resonances. Here, we introduce this new field with its application to metaphotonics and also present a summary of the basic concepts of machine learning with some specific examples developed and demonstrated for metasystems and metasurfaces.

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Evolution of the Electromagnetic Manipulation: From Tunable to Programmable and Intelligent Metasurfaces

Cited by 17 publications

References 118 publications

RIS-Assisted Visible Light Communication Systems: A Tutorial

RIS-Assisted Visible Light Communication Systems: A Tutorial

Reconfigurable Intelligent Edges: Illuminating the Shadow Region in Wireless Networks

Intelligent metaphotonics empowered by machine learning

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