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Main Authors: Lu, Jiachen, Shanbhag, Hailan, Hassanieh, Haitham Al
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2605.29097
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author Lu, Jiachen
Shanbhag, Hailan
Hassanieh, Haitham Al
author_facet Lu, Jiachen
Shanbhag, Hailan
Hassanieh, Haitham Al
contents GeRaF is the first method to use neural implicit learning for near-range 3D geometry reconstruction from radio frequency (RF) signals. Unlike RGB or LiDAR-based methods, RF sensing can see through occlusion but suffers from low resolution and noise due to its lensless imaging nature. While lenses in RGB imaging constrain sampling to 1D rays, RF signals propagate through the entire space, introducing significant noise and leading to cubic complexity in volumetric rendering. Moreover, RF signals interact with surfaces via specular reflections, requiring fundamentally different modeling. To address these challenges, GeRaF (1) introduces filter-based rendering to suppress irrelevant signals, (2) implements a physics-based RF volumetric rendering pipeline, and (3) proposes a novel lensless sampling and lensless alpha blending strategy that makes full-space sampling feasible during training. By learning signed distance functions, reflectiveness, and signal power through MLPs and trainable parameters, GeRaF takes the first step towards reconstructing millimeter-level geometry from RF signals in real-world settings.
format Preprint
id arxiv_https___arxiv_org_abs_2605_29097
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle GeRaF: Neural Geometry Reconstruction from Radio Frequency Signals
Lu, Jiachen
Shanbhag, Hailan
Hassanieh, Haitham Al
Computer Vision and Pattern Recognition
GeRaF is the first method to use neural implicit learning for near-range 3D geometry reconstruction from radio frequency (RF) signals. Unlike RGB or LiDAR-based methods, RF sensing can see through occlusion but suffers from low resolution and noise due to its lensless imaging nature. While lenses in RGB imaging constrain sampling to 1D rays, RF signals propagate through the entire space, introducing significant noise and leading to cubic complexity in volumetric rendering. Moreover, RF signals interact with surfaces via specular reflections, requiring fundamentally different modeling. To address these challenges, GeRaF (1) introduces filter-based rendering to suppress irrelevant signals, (2) implements a physics-based RF volumetric rendering pipeline, and (3) proposes a novel lensless sampling and lensless alpha blending strategy that makes full-space sampling feasible during training. By learning signed distance functions, reflectiveness, and signal power through MLPs and trainable parameters, GeRaF takes the first step towards reconstructing millimeter-level geometry from RF signals in real-world settings.
title GeRaF: Neural Geometry Reconstruction from Radio Frequency Signals
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2605.29097