A Reconfigurable Intelligent Surface at mmWave Based on a Binary Phase Tunable Metasurface

Reconfigurable intelligent surfaces (RISs) are two dimensional (2D) metasurfaces which can intelligently manipulate electromagnetic waves by low-cost near passive reflecting elements. RIS is viewed as a potential key technology for the sixth generation (6G) wireless communication systems mainly due to its advantages in tuning wireless signals, thus smartly controlling propagation environments. In this paper, we aim at addressing channel characterization and modeling issues of RISassisted wireless communication systems. At first, the concept, principle, and potential applications of RIS are given. An overview of RIS based channel measurements and experiments is presented by classifying frequency bands, scenarios, system configurations, RIS constructions, experiment purposes, and channel observations. Then, RIS based channel characteristics are studied, including reflection and transmission, Doppler effect and multipath fading mitigation, channel reciprocity, channel hardening, rank improvement, far field and near field, etc. RIS based channel modeling works are investigated, including largescale path loss models and small-scale multipath fading models. At last, future research directions related to RIS-assisted channels are also discussed.Index Terms-6G wireless communications, reconfigurable intelligent surface (RIS), channel measurements, channel characteristics, channel modeling.

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“…In [51], a RIS was fabricated at 28 GHz based on a binaryphase tunable metasurface. Experiments were conducted in near field and far field cases.…”

Section: Ris Channel Measurements and Experimentsmentioning

confidence: 99%

“…Based on the design described in [51], a RIS was fabricated at 28 GHz in [52]. Four RISs with unit cells of 20×20 were assembled to achieve 40×40 unit cells.…”

Section: Ris Channel Measurements and Experimentsmentioning

confidence: 99%

Reconfigurable Intelligent Surfaces: Channel Characterization and Modeling

et al. 2022

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“…Related Work. RIS design choices in terms of array technology, total number of elements, and inter-element spacing directly affect the achievable performance of RIS-aided wireless networks [7], [8]. In particular, the operating frequency depends on the reflective element geometry and material, whereas the total number of elements N determines the beamforming gain, which in turn may increase the signal-tonoise ratio (SNR) at the receiver up to a factor proportional to N 2 [9].…”

Section: Introductionmentioning

confidence: 99%

A Frequency-Agnostic RIS-based solution to control the Smart Radio Propagation Environment

Maresca¹,

Albanese²,

Mursia³

et al. 2022

Preprint

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The disruptive reconfigurable intelligent surface (RIS) technology is steadily gaining relevance as a key element in future 6G networks. However, a one-size-fits-all RIS hardware design is yet to be defined due to many practical considerations. A major roadblock for currently available RISs is their inability to concurrently operate at multiple carrier frequencies, which would lead to redundant installations to support multiple radio access technologies (RATs).In this paper, we introduce FABRIS, a novel and practical multi-frequency RIS design. FABRIS is able to dynamically operate across different radio frequencies (RFs) by means of frequency-tunable antennas as unit cells with virtually no performance degradation when conventional approaches to RIS design and optimization fail. Remarkably, our design preserves a sufficiently narrow beamwidth as to avoid generating signal leakage in unwanted directions and a sufficiently high antenna efficiency in terms of scattering parameters. Indeed, FABRIS selects the RIS configuration that maximizes the signal at the intended target user equipment (UE) while minimizing leakage to non-intended neighboring UEs. Numerical results and fullwave simulations validate our proposed approach against a naive implementation that does not consider signal leakage resulting from multi-frequency antenna arrays.

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“…Despite MSs potentially offer more advanced reflection control such as achieving perfect reflection to angles larger than 70 − 80 • from the normal [10], the features of their unit cells are much finer than of RAs. For that reason, RAs better fit to the relevant technological constraints that are especially important in the millimeter-wave range [11] and, therefore, serve as RISs in most papers.…”

Section: Introductionmentioning

confidence: 99%

“…A 2-bit version of an RIS controlled with PIN diodes was presented in [25]. While at frequencies below 10 GHz both varactor and PIN diode can be employed, at higher frequencies [26], especially in the 5G FR2 band [11], [27], [28] and above [29], PIN diodes were mostly used due to lower losses. Special DC circuits are to be embedded into the design of the RIS to individually bias the diodes for setting phases of individual patches (or groups of patches).…”

Section: Introductionmentioning

confidence: 99%

A 2D-programmable and Scalable RIS Remotely Controlled via Digital Infrared Code

Sayanskiy¹,

Belov²,

Yafasov³

et al. 2022

Preprint

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Reconfigurable Intelligent Surfaces (RISs) are promising and relatively low-cost tools for improving signal propagation in wireless communications. An RIS assists a base station in optimizing the channel and maximizing its capacity by dynamically manipulating with reflected field. Typically, RISs are based on dynamically reconfigurable reflectarrays, i.e. two-dimensional arrays of passive patch antennas, individually switchable between two or more reflection phases. Different communication scenarios and environments require RISs to provide a different spatial resolution of reflected field patterns, which depends on the aperture dimensions and the number of patches. Here we demonstrate a 1-bit RIS for 5-GHz Wi-Fi band made by assembling together multiple independently operating building blocks all powered by the same DC source. Each block contains four separately phase-switchable patch antennas with varactor diodes and a common microcontroller extracting digital control commands from modulated infrared light illuminating the entire RIS. Such distributed light-sensitive controllers grant the possibility of scaling the aperture by adding or removing blocks without re-designing any control circuitry. Moreover, in the proposed RIS a full 2D phase encoding capability is achieved along with a robust remote infrared control.

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A Reconfigurable Intelligent Surface at mmWave Based on a Binary Phase Tunable Metasurface

Cited by 116 publications

References 40 publications

Reconfigurable Intelligent Surfaces: Channel Characterization and Modeling

Reconfigurable Intelligent Surfaces: Channel Characterization and Modeling

A Frequency-Agnostic RIS-based solution to control the Smart Radio Propagation Environment

A 2D-programmable and Scalable RIS Remotely Controlled via Digital Infrared Code

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