Fair Beam Allocations Through Reconfigurable Intelligent Surfaces

A fair beam allocation framework through reconfigurable intelligent surfaces (RISs) is proposed, incorporating the Max-min criterion. This framework focuses on designing explicit beamforming functionalities through optimization. Firstly, realistic models, grounded in geometrical optics, are introduc...

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Veröffentlicht in:	IEEE journal on selected areas in communications 2024-11, Vol.42 (11), p.3095-3109
Hauptverfasser:	Xiong, Rujing, Yin, Ke, Mi, Tiebin, Lu, Jialong, Wan, Kai, Qiu, Robert Caiming
Format:	Artikel
Sprache:	eng
Schlagworte:	Antenna arrays Approximation algorithms Array signal processing beam-splitting fair beam allocation max-min optimization Minimax techniques Moreau-Yosida approximation Optimization prototype experiment Reconfigurable intelligent surface (RIS) Reconfigurable intelligent surfaces Resource management wide-beam generation
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container_title	IEEE journal on selected areas in communications
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creator	Xiong, Rujing Yin, Ke Mi, Tiebin Lu, Jialong Wan, Kai Qiu, Robert Caiming
description	A fair beam allocation framework through reconfigurable intelligent surfaces (RISs) is proposed, incorporating the Max-min criterion. This framework focuses on designing explicit beamforming functionalities through optimization. Firstly, realistic models, grounded in geometrical optics, are introduced to characterize the input/output behaviors of RISs, effectively bridging the gap between the requirements on explicit beamforming operations and their practical implementations. Then, a highly efficient algorithm is developed for Max-min optimizations involving quadratic forms. Leveraging the Moreau-Yosida approximation, we successfully reformulate the original problem and propose an iterative algorithm to obtain the optimal solution. A comprehensive analysis of the algorithm's convergence is provided. Importantly, this approach exhibits excellent extensibility, making it readily applicable to address a broader class of Max-min optimization problems. Finally, numerical and prototype experiments are conducted to validate the effectiveness of the framework. With the proposed beam allocation framework and algorithm, we clarify that several crucial redistribution functionalities of RISs, such as explicit beam-splitting, fair beam allocation, and wide-beam generation, can be effectively implemented. These explicit beamforming functionalities have not been thoroughly examined previously.
doi_str_mv	10.1109/JSAC.2024.3431580
format	Article
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This framework focuses on designing explicit beamforming functionalities through optimization. Firstly, realistic models, grounded in geometrical optics, are introduced to characterize the input/output behaviors of RISs, effectively bridging the gap between the requirements on explicit beamforming operations and their practical implementations. Then, a highly efficient algorithm is developed for Max-min optimizations involving quadratic forms. Leveraging the Moreau-Yosida approximation, we successfully reformulate the original problem and propose an iterative algorithm to obtain the optimal solution. A comprehensive analysis of the algorithm's convergence is provided. Importantly, this approach exhibits excellent extensibility, making it readily applicable to address a broader class of Max-min optimization problems. Finally, numerical and prototype experiments are conducted to validate the effectiveness of the framework. With the proposed beam allocation framework and algorithm, we clarify that several crucial redistribution functionalities of RISs, such as explicit beam-splitting, fair beam allocation, and wide-beam generation, can be effectively implemented. 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With the proposed beam allocation framework and algorithm, we clarify that several crucial redistribution functionalities of RISs, such as explicit beam-splitting, fair beam allocation, and wide-beam generation, can be effectively implemented. 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This framework focuses on designing explicit beamforming functionalities through optimization. Firstly, realistic models, grounded in geometrical optics, are introduced to characterize the input/output behaviors of RISs, effectively bridging the gap between the requirements on explicit beamforming operations and their practical implementations. Then, a highly efficient algorithm is developed for Max-min optimizations involving quadratic forms. Leveraging the Moreau-Yosida approximation, we successfully reformulate the original problem and propose an iterative algorithm to obtain the optimal solution. A comprehensive analysis of the algorithm's convergence is provided. Importantly, this approach exhibits excellent extensibility, making it readily applicable to address a broader class of Max-min optimization problems. Finally, numerical and prototype experiments are conducted to validate the effectiveness of the framework. 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subjects	Antenna arrays Approximation algorithms Array signal processing beam-splitting fair beam allocation max-min optimization Minimax techniques Moreau-Yosida approximation Optimization prototype experiment Reconfigurable intelligent surface (RIS) Reconfigurable intelligent surfaces Resource management wide-beam generation
title	Fair Beam Allocations Through Reconfigurable Intelligent Surfaces
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