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Main Authors: Weng, Xu, Ling, K. V., Liu, Haochen, Wang, Bingheng, Cao, Kun
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2508.14336
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author Weng, Xu
Ling, K. V.
Liu, Haochen
Wang, Bingheng
Cao, Kun
author_facet Weng, Xu
Ling, K. V.
Liu, Haochen
Wang, Bingheng
Cao, Kun
contents GNSS localization using everyday mobile devices is challenging in urban environments, as ranging errors caused by the complex propagation of satellite signals and low-quality onboard GNSS hardware are blamed for undermining positioning accuracy. Researchers have pinned their hopes on data-driven methods to regress such ranging errors from raw measurements. However, the grueling annotation of ranging errors impedes their pace. This paper presents a robust end-to-end Neural Ranging Correction (NeRC) framework, where localization-related metrics serve as the task objective for training the neural modules. Instead of seeking impractical ranging error labels, we train the neural network using ground-truth locations that are relatively easy to obtain. This functionality is supported by differentiable moving horizon location estimation (MHE) that handles a horizon of measurements for positioning and backpropagates the gradients for training. Even better, as a blessing of end-to-end learning, we propose a new training paradigm using Euclidean Distance Field (EDF) cost maps, which alleviates the demands on labeled locations. We evaluate the proposed NeRC on public benchmarks and our collected datasets, demonstrating its distinguished improvement in positioning accuracy. We also deploy NeRC on the edge to verify its real-time performance for mobile devices.
format Preprint
id arxiv_https___arxiv_org_abs_2508_14336
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle NeRC: Neural Ranging Correction through Differentiable Moving Horizon Location Estimation
Weng, Xu
Ling, K. V.
Liu, Haochen
Wang, Bingheng
Cao, Kun
Machine Learning
GNSS localization using everyday mobile devices is challenging in urban environments, as ranging errors caused by the complex propagation of satellite signals and low-quality onboard GNSS hardware are blamed for undermining positioning accuracy. Researchers have pinned their hopes on data-driven methods to regress such ranging errors from raw measurements. However, the grueling annotation of ranging errors impedes their pace. This paper presents a robust end-to-end Neural Ranging Correction (NeRC) framework, where localization-related metrics serve as the task objective for training the neural modules. Instead of seeking impractical ranging error labels, we train the neural network using ground-truth locations that are relatively easy to obtain. This functionality is supported by differentiable moving horizon location estimation (MHE) that handles a horizon of measurements for positioning and backpropagates the gradients for training. Even better, as a blessing of end-to-end learning, we propose a new training paradigm using Euclidean Distance Field (EDF) cost maps, which alleviates the demands on labeled locations. We evaluate the proposed NeRC on public benchmarks and our collected datasets, demonstrating its distinguished improvement in positioning accuracy. We also deploy NeRC on the edge to verify its real-time performance for mobile devices.
title NeRC: Neural Ranging Correction through Differentiable Moving Horizon Location Estimation
topic Machine Learning
url https://arxiv.org/abs/2508.14336