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Hauptverfasser: Tyrovolas, Dimitrios, Tegos, Sotiris A., Cao, Kunrui, Xiao, Yue, Diamantoulakis, Panagiotis D., Sagias, Nikos C., Asimonis, Stylianos D., Liaskos, Christos K., Karagiannidis, George K.
Format: Preprint
Veröffentlicht: 2026
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Online-Zugang:https://arxiv.org/abs/2604.16638
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author Tyrovolas, Dimitrios
Tegos, Sotiris A.
Cao, Kunrui
Xiao, Yue
Diamantoulakis, Panagiotis D.
Sagias, Nikos C.
Asimonis, Stylianos D.
Liaskos, Christos K.
Karagiannidis, George K.
author_facet Tyrovolas, Dimitrios
Tegos, Sotiris A.
Cao, Kunrui
Xiao, Yue
Diamantoulakis, Panagiotis D.
Sagias, Nikos C.
Asimonis, Stylianos D.
Liaskos, Christos K.
Karagiannidis, George K.
contents Zero-energy reconfigurable intelligent surfaces (zeRISs) have recently emerged as a promising solution for enabling energy-efficient and scalable programmable wireless environments (PWEs) by harvesting their operational energy from impinging radio-frequency signals. However, the operation of zeRIS-assisted systems is inherently constrained by the coupling between energy harvesting and signal reflection, a dependency that becomes more intricate under practical hardware limitations such as finite-resolution phase control. In this paper, we develop a comprehensive analytical framework for zeRIS-assisted communication systems operating under quantized phase shifts and harvest-and-reflect (HaR) schemes. Specifically, we analyze the joint energy-data rate outage probability and the energy efficiency under time switching and element splitting schemes, considering both transmitter-side and user-side deployment scenarios. By explicitly modeling the residual phase error induced by quantization and incorporating its statistical properties into the analysis, we show that quantization jointly affects energy harvesting and signal reflection, thereby inducing non-trivial trade-offs. As a result, the presented framework enables accurate performance evaluation and reveals critical design trade-offs for the selection of the phase resolution, and the applied HaR scheme in zeRIS-assisted wireless networks.
format Preprint
id arxiv_https___arxiv_org_abs_2604_16638
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Quantized Zero-Energy RIS: Residual Phase Modeling and Outage Analysis
Tyrovolas, Dimitrios
Tegos, Sotiris A.
Cao, Kunrui
Xiao, Yue
Diamantoulakis, Panagiotis D.
Sagias, Nikos C.
Asimonis, Stylianos D.
Liaskos, Christos K.
Karagiannidis, George K.
Information Theory
Zero-energy reconfigurable intelligent surfaces (zeRISs) have recently emerged as a promising solution for enabling energy-efficient and scalable programmable wireless environments (PWEs) by harvesting their operational energy from impinging radio-frequency signals. However, the operation of zeRIS-assisted systems is inherently constrained by the coupling between energy harvesting and signal reflection, a dependency that becomes more intricate under practical hardware limitations such as finite-resolution phase control. In this paper, we develop a comprehensive analytical framework for zeRIS-assisted communication systems operating under quantized phase shifts and harvest-and-reflect (HaR) schemes. Specifically, we analyze the joint energy-data rate outage probability and the energy efficiency under time switching and element splitting schemes, considering both transmitter-side and user-side deployment scenarios. By explicitly modeling the residual phase error induced by quantization and incorporating its statistical properties into the analysis, we show that quantization jointly affects energy harvesting and signal reflection, thereby inducing non-trivial trade-offs. As a result, the presented framework enables accurate performance evaluation and reveals critical design trade-offs for the selection of the phase resolution, and the applied HaR scheme in zeRIS-assisted wireless networks.
title Quantized Zero-Energy RIS: Residual Phase Modeling and Outage Analysis
topic Information Theory
url https://arxiv.org/abs/2604.16638