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Main Authors: Pan, Guangjin, Huang, Kaixuan, Chen, Hui, Zhang, Shunqing, Häger, Christian, Wymeersch, Henk
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2505.10134
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author Pan, Guangjin
Huang, Kaixuan
Chen, Hui
Zhang, Shunqing
Häger, Christian
Wymeersch, Henk
author_facet Pan, Guangjin
Huang, Kaixuan
Chen, Hui
Zhang, Shunqing
Häger, Christian
Wymeersch, Henk
contents Accurate and robust localization is a critical enabler for emerging 5G and 6G applications, including autonomous driving, extended reality (XR), and smart manufacturing. While data-driven approaches have shown promise, most existing models require large amounts of labeled data and struggle to generalize across deployment scenarios and wireless configurations. To address these limitations, we propose a foundation-model-based solution tailored for wireless localization. We first analyze how different self-supervised learning (SSL) tasks acquire general-purpose and task-specific semantic features based on information bottleneck (IB) theory. Building on this foundation, we design a pretraining methodology for the proposed Large Wireless Localization Model (LWLM). Specifically, we propose an SSL framework that jointly optimizes three complementary objectives: (i) spatial-frequency masked channel modeling (SF-MCM), (ii) domain-transformation invariance (DTI), and (iii) position-invariant contrastive learning (PICL). These objectives jointly capture the underlying semantics of wireless channel from multiple perspectives. We further design lightweight decoders for key downstream tasks, including time-of-arrival (ToA) estimation, angle-of-arrival (AoA) estimation, single base station (BS) localization, and multiple BS localization. Comprehensive experimental results confirm that LWLM consistently surpasses both model-based and supervised learning baselines across all localization tasks. In particular, LWLM achieves 26.0%--87.5% improvement over transformer models without pretraining, and exhibits strong generalization under label-limited fine-tuning and unseen BS configurations, confirming its potential as a foundation model for wireless localization.
format Preprint
id arxiv_https___arxiv_org_abs_2505_10134
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Large Wireless Localization Model (LWLM): A Foundation Model for Positioning in 6G Networks
Pan, Guangjin
Huang, Kaixuan
Chen, Hui
Zhang, Shunqing
Häger, Christian
Wymeersch, Henk
Signal Processing
Artificial Intelligence
Machine Learning
Accurate and robust localization is a critical enabler for emerging 5G and 6G applications, including autonomous driving, extended reality (XR), and smart manufacturing. While data-driven approaches have shown promise, most existing models require large amounts of labeled data and struggle to generalize across deployment scenarios and wireless configurations. To address these limitations, we propose a foundation-model-based solution tailored for wireless localization. We first analyze how different self-supervised learning (SSL) tasks acquire general-purpose and task-specific semantic features based on information bottleneck (IB) theory. Building on this foundation, we design a pretraining methodology for the proposed Large Wireless Localization Model (LWLM). Specifically, we propose an SSL framework that jointly optimizes three complementary objectives: (i) spatial-frequency masked channel modeling (SF-MCM), (ii) domain-transformation invariance (DTI), and (iii) position-invariant contrastive learning (PICL). These objectives jointly capture the underlying semantics of wireless channel from multiple perspectives. We further design lightweight decoders for key downstream tasks, including time-of-arrival (ToA) estimation, angle-of-arrival (AoA) estimation, single base station (BS) localization, and multiple BS localization. Comprehensive experimental results confirm that LWLM consistently surpasses both model-based and supervised learning baselines across all localization tasks. In particular, LWLM achieves 26.0%--87.5% improvement over transformer models without pretraining, and exhibits strong generalization under label-limited fine-tuning and unseen BS configurations, confirming its potential as a foundation model for wireless localization.
title Large Wireless Localization Model (LWLM): A Foundation Model for Positioning in 6G Networks
topic Signal Processing
Artificial Intelligence
Machine Learning
url https://arxiv.org/abs/2505.10134