Array-Fed RIS: Validation of Friis-Based Modeling Using Full-Wave Simulations
Abstract
Space-fed large antenna arrays offer superior efficiency, simplicity, and reductions in size, weight, power, and cost (SWaP-C) compared to constrained-feed systems. Historically, horn antennas have been used for space feeding, but they suffer from limitations such as bulky designs, low aperture efficiency (), and restricted degrees of freedom at the continuous aperture. In contrast, planar patch arrays achieve significantly higher aperture efficiency () due to their more uniform aperture distribution, reduced weight, and increased degrees of freedom from the discretized aperture. Building on these advantages, we proposed an array-fed Reflective Intelligent Surface (RIS) system, where an active multi-antenna feeder (AMAF) optimizes power transfer by aligning with the principal eigenmode of the AMAF-RIS propagation matrix . While our previous studies relied on the Friis transmission formula for system modeling, we now validate this approach through full-wave simulations in CST Microwave Studio. By comparing the Friis-based matrix, , with the full-wave solution, , we validate the relevance of the Friis-based modeling for top-level system design. Our findings confirm the feasibility of the proposed AMAF-RIS architecture for next-generation communication systems.
Keywords
Cite
@article{arxiv.2502.09184,
title = {Array-Fed RIS: Validation of Friis-Based Modeling Using Full-Wave Simulations},
author = {Krishan Kumar Tiwari and Thomas Flisgen and Wolfgang Heinrich and Giuseppe Caire},
journal= {arXiv preprint arXiv:2502.09184},
year = {2025}
}
Comments
Accepted for The 16th German Microwave Conference (GeMiC), Dresden