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Reconfigurable Intelligent Surface-Aided Near-field Communications for 6G: Opportunities and Challenges


Concepts de base
The author explores the benefits of Reconfigurable Intelligent Surface (RIS)-aided near-field communications for 6G, highlighting the advantages of spherical-wave-based propagation and addressing performance limits, beam training, and beamforming design. The main thesis is to emphasize the necessity of investigating RIS-aided near-field communications due to their unique advantages over far-field communications, paving the way for sustainable and ubiquitous 6G services.
Résumé

Reconfigurable intelligent surface (RIS)-aided near-field communications are crucial for enhancing data rates, latency, and coverage in future wireless networks. The article discusses the benefits of near-field propagation, analyzes performance limits, introduces two types of RISs - patch-array-based and metasurface-based, and proposes a two-stage hierarchical beam training approach. It also presents a low-complexity element-wise beamforming design method for efficient communication. The research opens up opportunities for further exploration in CSI estimation, dynamic RIS configuration, and leveraging generative artificial intelligence in RIS-aided communications.

The content delves into the technical aspects of RIS-aided near-field communications for 6G networks. It covers topics such as power scaling laws, effective degrees-of-freedom analysis, beam training approaches, and beamforming designs. The article provides insights into the challenges faced in optimizing communication systems using Reconfigurable Intelligent Surfaces (RIS) and highlights potential research directions to enhance future wireless technologies.

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Stats
According to [4], the cascaded transmitter-RIS-receiver channel falls within the near-field region if either the transmitter-RIS distance or the RIS-receiver distance is shorter than the Rayleigh distance. For an RIS with an aperture size of 1 meter employed at a frequency of 28 GHz, the resultant Rayleigh distance is approximately 187 meters. In [8], it is mentioned that power scaling laws differ between patch-array-based RISs (linear scaling) and metasurface-based RISs (small scaling slope). Existing study [12] shows that EDoFs of a near-field channel depend on geometries of RIS and receiver. The proposed two-stage hierarchical beam training approach reduces training overhead significantly according to [13].
Citations
"Compared to conventional RIS-aided far-field communications, spherical-wave-based near-field propagation leads to high-rank Line-of-Sight channels." "In contrast to far-field beamsteering where energy is concentrated at a specific angle, spherical wavefront enables precise beamfocusing in near-field communications." "The proposed element-wise optimization framework reduces computational complexity linearly with STAR-RIS elements compared to conventional methods."

Questions plus approfondies

How can metasurface-based RISs overcome challenges posed by Green's function-based channel models?

Metasurface-based RISs can address the complexities associated with Green's function-based channel models through their quasi-continuous phase profile. Unlike patch-array-based RISs, metasurface-based RISs operate using massive periodic cells with dimensions ranging from millimeters to micrometers or even molecular scales. This allows for a more continuous operation across the entire surface, enabling advanced control of electromagnetic properties like conductivity and permittivity. By utilizing these features, metasurface-based RISs can effectively model incident signals as electric currents within the volume of the surface, leading to controlled scattered fields that enhance communication performance in near-field scenarios.

What trade-offs need to be considered when implementing dynamic RIS configurations for adjustable near-field regions?

When implementing dynamic RIS configurations for adjustable near-field regions, several trade-offs must be carefully evaluated: Performance vs. Complexity: Adjusting the aperture size of an RIS to switch between near-field and far-field regions can significantly impact system performance by optimizing signal propagation based on distance requirements. However, this flexibility may introduce complexity in determining optimal configurations dynamically. CSI Estimation Accuracy: Dynamic changes in the configuration require accurate Channel State Information (CSI) estimation to adapt beamforming strategies effectively. Balancing rapid adjustments with precise CSI acquisition is crucial but challenging. Resource Allocation: Shifting between near-field and far-field modes may influence resource allocation efficiency concerning power consumption and spectral utilization. Implementation Costs: Implementing mechanisms for dynamic reconfiguration adds hardware costs and operational overhead that need to be justified against potential performance gains.

How can generative artificial intelligence techniques enhance CSI estimation and resource management in RIS-aided near-field communications?

Generative Artificial Intelligence (GAI) techniques offer significant benefits in enhancing CSI estimation and resource management in RIS-aided near-field communications: Codebook Generation: GAI methods such as Generative Adversarial Networks (GANs) can generate optimized codebooks tailored for specific angular domains required during beam training processes in complex environments like those involving intelligent reflecting surfaces. Adaptive Beamforming Strategies: GAI algorithms like transformers enable adaptive beamforming strategies that adjust dynamically based on changing channel conditions without exhaustive search procedures, improving overall system efficiency. Uncertainty Handling: Diffusion models within GAI frameworks help manage uncertainties related to imperfect CSI estimates by providing probabilistic approaches that optimize resource allocation under varying levels of information accuracy. 4Complex Optimization Tasks:: For high-dimensional optimization tasks involved in managing vast numbers of variables inherent in sophisticated beamforming designs or resource allocations within intricate channels facilitated by reflective surfaces, GAI techniques streamline decision-making processes while maintaining performance standards. By leveraging these capabilities offered by GAI techniques, operators can achieve more robust and efficient operations within complex wireless networks enhanced by Reconfigurable Intelligent Surfaces (RIS).
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