LiquiRIS reduces LC-RIS reconfiguration time by up to 71.61% by incorporating LC molecular dynamics into phase selection and validates the approach on a mmWave prototype.
Reconfigurable intelligent surfaces with liquid crystal technology: A hardware design and communication perspective
3 Pith papers cite this work. Polarity classification is still indexing.
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Develops a physics-based frequency model for LC-RIS and a location-driven phase optimization framework that improves secrecy rates across subcarriers, validated via simulations and hardware experiments.
A physics-based model of LC unit cell dynamics combined with location-based phase design reduces RIS reconfiguration time while maintaining area coverage in TDMA scenarios.
citing papers explorer
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Fast-Reconfiguring Liquid-Crystal RIS for Pervasive Wireless Networks
LiquiRIS reduces LC-RIS reconfiguration time by up to 71.61% by incorporating LC molecular dynamics into phase selection and validates the approach on a mmWave prototype.
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Wideband Illumination with Liquid Crystal Reconfigurable Intelligent Surfaces: Modeling, Design, and Experimental Tests
Develops a physics-based frequency model for LC-RIS and a location-driven phase optimization framework that improves secrecy rates across subcarriers, validated via simulations and hardware experiments.
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Fast Reconfiguration of Liquid Crystal-RISs: Modeling and Algorithm Design
A physics-based model of LC unit cell dynamics combined with location-based phase design reduces RIS reconfiguration time while maintaining area coverage in TDMA scenarios.