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Main Authors: Wang, Kaining, Yang, Bo, Lei, Yusheng, Yu, Zhiwen, Cao, Xuelin, Wang, Liang, Guo, Bin, Alexandropoulos, George C., Debbah, Mérouane, Han, Zhu
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2511.01373
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author Wang, Kaining
Yang, Bo
Lei, Yusheng
Yu, Zhiwen
Cao, Xuelin
Wang, Liang
Guo, Bin
Alexandropoulos, George C.
Debbah, Mérouane
Han, Zhu
author_facet Wang, Kaining
Yang, Bo
Lei, Yusheng
Yu, Zhiwen
Cao, Xuelin
Wang, Liang
Guo, Bin
Alexandropoulos, George C.
Debbah, Mérouane
Han, Zhu
contents The integration of reconfigurable intelligent surfaces (RIS) and fluid antenna systems (FAS) has attracted considerable attention due to its tremendous potential in enhancing wireless communication performance. However, under fast-fading channel conditions, rapidly and effectively performing joint optimization of the antenna positions in an FAS system and the RIS phase configuration remains a critical challenge. Traditional optimization methods typically rely on complex iterative computations, thus making it challenging to obtain optimal solutions in real time within dynamic channel environments. To address this issue, this paper introduces a field information-driven optimization method based on three-dimensional Gaussian radiation-field modeling for real-time optimization of integrated FAS-RIS systems. In the proposed approach, obstacles are treated as virtual transmitters and, by separately learning the amplitude and phase variations, the model can quickly generate high-precision channel information based on the transmitter's position. This design eliminates the need for extensive pilot overhead and cumbersome computations. On this framework, an alternating optimization scheme is presented to jointly optimize the FAS position and the RIS phase configuration. Simulation results demonstrate that the proposed method significantly outperforms existing approaches in terms of spectrum prediction accuracy, convergence speed, and minimum achievable rate, validating its effectiveness and practicality in fast-fading scenarios.
format Preprint
id arxiv_https___arxiv_org_abs_2511_01373
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle 3D Gaussian Radiation Field Modeling for Integrated RIS-FAS Systems: Analysis and Optimization
Wang, Kaining
Yang, Bo
Lei, Yusheng
Yu, Zhiwen
Cao, Xuelin
Wang, Liang
Guo, Bin
Alexandropoulos, George C.
Debbah, Mérouane
Han, Zhu
Networking and Internet Architecture
The integration of reconfigurable intelligent surfaces (RIS) and fluid antenna systems (FAS) has attracted considerable attention due to its tremendous potential in enhancing wireless communication performance. However, under fast-fading channel conditions, rapidly and effectively performing joint optimization of the antenna positions in an FAS system and the RIS phase configuration remains a critical challenge. Traditional optimization methods typically rely on complex iterative computations, thus making it challenging to obtain optimal solutions in real time within dynamic channel environments. To address this issue, this paper introduces a field information-driven optimization method based on three-dimensional Gaussian radiation-field modeling for real-time optimization of integrated FAS-RIS systems. In the proposed approach, obstacles are treated as virtual transmitters and, by separately learning the amplitude and phase variations, the model can quickly generate high-precision channel information based on the transmitter's position. This design eliminates the need for extensive pilot overhead and cumbersome computations. On this framework, an alternating optimization scheme is presented to jointly optimize the FAS position and the RIS phase configuration. Simulation results demonstrate that the proposed method significantly outperforms existing approaches in terms of spectrum prediction accuracy, convergence speed, and minimum achievable rate, validating its effectiveness and practicality in fast-fading scenarios.
title 3D Gaussian Radiation Field Modeling for Integrated RIS-FAS Systems: Analysis and Optimization
topic Networking and Internet Architecture
url https://arxiv.org/abs/2511.01373