Saved in:
Bibliographic Details
Main Authors: Gao, Jun, Xing, Zheng, Lin, Wenliang, Zhao, Weibing, Zhang, Xuhui, Chen, Junting, Deng, Zhongliang, Cui, Shuguang
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2605.10004
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866914578911199232
author Gao, Jun
Xing, Zheng
Lin, Wenliang
Zhao, Weibing
Zhang, Xuhui
Chen, Junting
Deng, Zhongliang
Cui, Shuguang
author_facet Gao, Jun
Xing, Zheng
Lin, Wenliang
Zhao, Weibing
Zhang, Xuhui
Chen, Junting
Deng, Zhongliang
Cui, Shuguang
contents Fingerprinting-based localization often suffers from poor cross-environment generalization, especially when only a few labeled samples are available in the target environment. Existing methods mitigate distribution shifts through domain adaptation or improved signal representations, but they usually ignore environmental geometry or use it in a deterministic manner, limiting their ability to capture diverse multipath variations in complex propagation conditions. To address this issue, we propose EnvCoLoc, an environment-conditioned diffusion meta-learning framework for few-shot fingerprinting localization. EnvCoLoc extracts structured descriptors from 3D point clouds and uses them to condition a latent diffusion generator, which produces environment-specific parameter offsets to modulate a shared meta-learned initialization. This design injects geometry-aware priors into the adaptation process and provides more informative initializations for new environments. To learn the stochastic mapping from coarse environmental descriptors to high-dimensional parameter corrections under limited data, the diffusion generator and localization network are jointly optimized within a two-loop meta-learning framework. The generated offsets capture systematic environment-dependent variations, while gradient-based inner-loop adaptation further refines the model to reduce residual task-specific mismatch. We also provide an excess-loss analysis for finite-step adaptation, theoretically supporting the benefit of geometry-aware initialization. Real-world experiments show that EnvCoLoc consistently improves localization accuracy over baseline methods, achieving up to a 20.0% reduction in mean localization error in NLOS scenarios with only 10 support samples.
format Preprint
id arxiv_https___arxiv_org_abs_2605_10004
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Environment-Conditioned Diffusion Meta-Learning for Data-Efficient WiFi Localization
Gao, Jun
Xing, Zheng
Lin, Wenliang
Zhao, Weibing
Zhang, Xuhui
Chen, Junting
Deng, Zhongliang
Cui, Shuguang
Signal Processing
Fingerprinting-based localization often suffers from poor cross-environment generalization, especially when only a few labeled samples are available in the target environment. Existing methods mitigate distribution shifts through domain adaptation or improved signal representations, but they usually ignore environmental geometry or use it in a deterministic manner, limiting their ability to capture diverse multipath variations in complex propagation conditions. To address this issue, we propose EnvCoLoc, an environment-conditioned diffusion meta-learning framework for few-shot fingerprinting localization. EnvCoLoc extracts structured descriptors from 3D point clouds and uses them to condition a latent diffusion generator, which produces environment-specific parameter offsets to modulate a shared meta-learned initialization. This design injects geometry-aware priors into the adaptation process and provides more informative initializations for new environments. To learn the stochastic mapping from coarse environmental descriptors to high-dimensional parameter corrections under limited data, the diffusion generator and localization network are jointly optimized within a two-loop meta-learning framework. The generated offsets capture systematic environment-dependent variations, while gradient-based inner-loop adaptation further refines the model to reduce residual task-specific mismatch. We also provide an excess-loss analysis for finite-step adaptation, theoretically supporting the benefit of geometry-aware initialization. Real-world experiments show that EnvCoLoc consistently improves localization accuracy over baseline methods, achieving up to a 20.0% reduction in mean localization error in NLOS scenarios with only 10 support samples.
title Environment-Conditioned Diffusion Meta-Learning for Data-Efficient WiFi Localization
topic Signal Processing
url https://arxiv.org/abs/2605.10004