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Auteurs principaux: He, Yizhi, Hoseini, Sayed Amir, Hassan, Mahbub
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2511.22408
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author He, Yizhi
Hoseini, Sayed Amir
Hassan, Mahbub
author_facet He, Yizhi
Hoseini, Sayed Amir
Hassan, Mahbub
contents Intelligent Reflecting Surfaces (IRS) promise low-power coverage extension, yet practical deployments must curb hardware complexity and control overhead. This paper quantifies the performance impact of two cost-saving measures, column-wise element grouping and 1-bit (binary) phase quantization, relative to the ideal fully-controlled, continuous-phase baseline. A single-input single-output link is simulated at 26 GHz (mmWave) across three deployment geometries that vary the relative heights of access point, IRS and user equipment. Results show that switching from continuous to binary phase control reduces median SNR gain by approximately 4 dB, while adopting column-wise grouping introduces a similar penalty; combining both constraints incurs approximately 8 dB loss under height-offset deployments. When all nodes share the same height, the degradation from column-wise control becomes negligible, indicating deployment geometry can offset control-granularity limits. Despite the losses, a 32 x 32 column-wise binary IRS still delivers double-digit SNR gains over the no-IRS baseline in most positions, confirming its viability for cost-constrained scenarios. The study provides quantitative guidelines on when simplified IRS architectures can meet link-budget targets and where full element-wise control remains justified.
format Preprint
id arxiv_https___arxiv_org_abs_2511_22408
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Quantifying Geometry Effects on Low-Cost Intelligent Reflecting Surfaces
He, Yizhi
Hoseini, Sayed Amir
Hassan, Mahbub
Emerging Technologies
Intelligent Reflecting Surfaces (IRS) promise low-power coverage extension, yet practical deployments must curb hardware complexity and control overhead. This paper quantifies the performance impact of two cost-saving measures, column-wise element grouping and 1-bit (binary) phase quantization, relative to the ideal fully-controlled, continuous-phase baseline. A single-input single-output link is simulated at 26 GHz (mmWave) across three deployment geometries that vary the relative heights of access point, IRS and user equipment. Results show that switching from continuous to binary phase control reduces median SNR gain by approximately 4 dB, while adopting column-wise grouping introduces a similar penalty; combining both constraints incurs approximately 8 dB loss under height-offset deployments. When all nodes share the same height, the degradation from column-wise control becomes negligible, indicating deployment geometry can offset control-granularity limits. Despite the losses, a 32 x 32 column-wise binary IRS still delivers double-digit SNR gains over the no-IRS baseline in most positions, confirming its viability for cost-constrained scenarios. The study provides quantitative guidelines on when simplified IRS architectures can meet link-budget targets and where full element-wise control remains justified.
title Quantifying Geometry Effects on Low-Cost Intelligent Reflecting Surfaces
topic Emerging Technologies
url https://arxiv.org/abs/2511.22408