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Main Authors: Tian, Jijia, Chen, Wangqian, Chen, Junting, Kam, Pooi-Yuen
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2512.08263
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author Tian, Jijia
Chen, Wangqian
Chen, Junting
Kam, Pooi-Yuen
author_facet Tian, Jijia
Chen, Wangqian
Chen, Junting
Kam, Pooi-Yuen
contents Radio maps that describe spatial variations in wireless signal strength are widely used to optimize networks and support aerial platforms. Their construction requires location-labeled signal measurements from distributed users, raising fundamental concerns about location privacy. Even when raw data are kept local, the shared model updates can reveal user locations through their spatial structure, while naive noise injection either fails to hide this leakage or degrades model accuracy. This work analyzes how location leakage arises from gradients in a virtual-environment radio map model and proposes a geometry-aligned differential privacy mechanism with heterogeneous noise tailored to both confuse localization and cover gradient spatial patterns. The approach is theoretically supported with a convergence guarantee linking privacy strength to learning accuracy. Numerical experiments show the approach increases attacker localization error from 30 m to over 180 m, with only 0.2 dB increase in radio map construction error compared to a uniform-noise baseline.
format Preprint
id arxiv_https___arxiv_org_abs_2512_08263
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Geometry-Aligned Differential Privacy for Location-Safe Federated Radio Map Construction
Tian, Jijia
Chen, Wangqian
Chen, Junting
Kam, Pooi-Yuen
Signal Processing
Radio maps that describe spatial variations in wireless signal strength are widely used to optimize networks and support aerial platforms. Their construction requires location-labeled signal measurements from distributed users, raising fundamental concerns about location privacy. Even when raw data are kept local, the shared model updates can reveal user locations through their spatial structure, while naive noise injection either fails to hide this leakage or degrades model accuracy. This work analyzes how location leakage arises from gradients in a virtual-environment radio map model and proposes a geometry-aligned differential privacy mechanism with heterogeneous noise tailored to both confuse localization and cover gradient spatial patterns. The approach is theoretically supported with a convergence guarantee linking privacy strength to learning accuracy. Numerical experiments show the approach increases attacker localization error from 30 m to over 180 m, with only 0.2 dB increase in radio map construction error compared to a uniform-noise baseline.
title Geometry-Aligned Differential Privacy for Location-Safe Federated Radio Map Construction
topic Signal Processing
url https://arxiv.org/abs/2512.08263