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Autores principales: Sambon, Baptiste, Monnoyer, Gilles, Vandendorpe, Luc, Oestges, Claude
Formato: Preprint
Publicado: 2026
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Acceso en línea:https://arxiv.org/abs/2602.01947
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author Sambon, Baptiste
Monnoyer, Gilles
Vandendorpe, Luc
Oestges, Claude
author_facet Sambon, Baptiste
Monnoyer, Gilles
Vandendorpe, Luc
Oestges, Claude
contents Extremely Large-scale MIMO (XL-MIMO) systems operating in Near-Field (NF) introduce new degrees of freedom for accurate source localisation, but make dense arrays impractical. Sparse or distributed arrays can reduce hardware complexity while maintaining high resolution, yet sub-Nyquist spatial sampling introduces aliasing artefacts in the localisation ambiguity function. This paper presents a unified framework to jointly characterise resolution and aliasing in NF localisation and study the trade-off between the two. Leveraging the concept of local chirp spatial frequency, we derive analytical expressions linking array geometry and sampling density to the spatial bandwidth of the received field. We introduce two geometric tools--Critical Antenna Elements (CAEs) and the Non-Contributive Zone (NCZ)--to intuitively identify how individual antennas contribute to resolution and/or aliasing. Our analysis reveals that resolution and aliasing are not always strictly coupled, e.g., increasing the array aperture can improve resolution without necessarily aggravating aliasing. These results provide practical guidelines for designing NF arrays that optimally balance resolution and aliasing, supporting efficient XL-MIMO deployment.
format Preprint
id arxiv_https___arxiv_org_abs_2602_01947
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Resolution-Aliasing Trade-off in Near-Field Localisation
Sambon, Baptiste
Monnoyer, Gilles
Vandendorpe, Luc
Oestges, Claude
Signal Processing
Extremely Large-scale MIMO (XL-MIMO) systems operating in Near-Field (NF) introduce new degrees of freedom for accurate source localisation, but make dense arrays impractical. Sparse or distributed arrays can reduce hardware complexity while maintaining high resolution, yet sub-Nyquist spatial sampling introduces aliasing artefacts in the localisation ambiguity function. This paper presents a unified framework to jointly characterise resolution and aliasing in NF localisation and study the trade-off between the two. Leveraging the concept of local chirp spatial frequency, we derive analytical expressions linking array geometry and sampling density to the spatial bandwidth of the received field. We introduce two geometric tools--Critical Antenna Elements (CAEs) and the Non-Contributive Zone (NCZ)--to intuitively identify how individual antennas contribute to resolution and/or aliasing. Our analysis reveals that resolution and aliasing are not always strictly coupled, e.g., increasing the array aperture can improve resolution without necessarily aggravating aliasing. These results provide practical guidelines for designing NF arrays that optimally balance resolution and aliasing, supporting efficient XL-MIMO deployment.
title Resolution-Aliasing Trade-off in Near-Field Localisation
topic Signal Processing
url https://arxiv.org/abs/2602.01947