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Autores principales: Vega-Sánchez, J. D., Pacheco, V. H. Garzón, Garzón, N. V. Orozco, Almeida, D. A. Riofrío, Osorio, D. P. Moya
Formato: Preprint
Publicado: 2025
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Acceso en línea:https://arxiv.org/abs/2511.18675
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author Vega-Sánchez, J. D.
Pacheco, V. H. Garzón
Garzón, N. V. Orozco
Almeida, D. A. Riofrío
Osorio, D. P. Moya
author_facet Vega-Sánchez, J. D.
Pacheco, V. H. Garzón
Garzón, N. V. Orozco
Almeida, D. A. Riofrío
Osorio, D. P. Moya
contents This work examines the secrecy outage probability (SOP) in Fluid Reconfigurable Intelligent Surfaces (FRIS) and contrasts their performance against two alternative RIS architectures: a traditional planar RIS and a compact RIS layout. To characterize the end-to-end FRIS channel, a maximum likelihood estimation (MLE) approach is introduced, while a Q-learning algorithm is employed to adaptively select the spatial positions of FRIS elements. Numerical evaluations show that optimizing element placement in FRIS significantly improves SOP compared to conventional RIS without phase adaptation. However, these improvements become less evident once the conventional RIS implements optimized beamforming (BF) and phase-shift (PS) controlling. In addition, FRIS maintains a clear advantage over compact RIS designs with optimized BF and PS, mainly due to its lower spatial correlation. Results further indicate that reducing the inter-element distance negatively impacts SOP, highlighting the importance of spatial diversity.
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publishDate 2025
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spellingShingle Exploring Spatial Flexibility and Phase Design in Fluid Reconfigurable Intelligent Surfaces: A Physical Layer Security Perspective
Vega-Sánchez, J. D.
Pacheco, V. H. Garzón
Garzón, N. V. Orozco
Almeida, D. A. Riofrío
Osorio, D. P. Moya
Information Theory
This work examines the secrecy outage probability (SOP) in Fluid Reconfigurable Intelligent Surfaces (FRIS) and contrasts their performance against two alternative RIS architectures: a traditional planar RIS and a compact RIS layout. To characterize the end-to-end FRIS channel, a maximum likelihood estimation (MLE) approach is introduced, while a Q-learning algorithm is employed to adaptively select the spatial positions of FRIS elements. Numerical evaluations show that optimizing element placement in FRIS significantly improves SOP compared to conventional RIS without phase adaptation. However, these improvements become less evident once the conventional RIS implements optimized beamforming (BF) and phase-shift (PS) controlling. In addition, FRIS maintains a clear advantage over compact RIS designs with optimized BF and PS, mainly due to its lower spatial correlation. Results further indicate that reducing the inter-element distance negatively impacts SOP, highlighting the importance of spatial diversity.
title Exploring Spatial Flexibility and Phase Design in Fluid Reconfigurable Intelligent Surfaces: A Physical Layer Security Perspective
topic Information Theory
url https://arxiv.org/abs/2511.18675