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Autores principales: Javed, Nur Uddin, Singh, Yuvraj, Ahmed, Qadeer
Formato: Preprint
Publicado: 2024
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Acceso en línea:https://arxiv.org/abs/2410.12208
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author Javed, Nur Uddin
Singh, Yuvraj
Ahmed, Qadeer
author_facet Javed, Nur Uddin
Singh, Yuvraj
Ahmed, Qadeer
contents Automated driving systems face challenges in GPS-denied situations. To address this issue, kinematic dead reckoning is implemented using measurements from the steering angle, steering rate, yaw rate, and wheel speed sensors onboard the vehicle. However, dead reckoning methods suffer from drift. This paper provides an arc-length-based map matching method that uses a digital 2D map of the scenario in order to correct drift in the dead reckoning estimate. The kinematic model's prediction is used to introduce a temporal notion to the spatial information available in the map data. Results show reliable improvement in drift for all GPS-denied scenarios tested in this study. This innovative approach ensures that automated vehicles can maintain continuous and reliable navigation, significantly enhancing their safety and operational reliability in environments where GPS signals are compromised or unavailable.
format Preprint
id arxiv_https___arxiv_org_abs_2410_12208
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Vehicle Localization in GPS-Denied Scenarios Using Arc-Length-Based Map Matching
Javed, Nur Uddin
Singh, Yuvraj
Ahmed, Qadeer
Robotics
Systems and Control
Automated driving systems face challenges in GPS-denied situations. To address this issue, kinematic dead reckoning is implemented using measurements from the steering angle, steering rate, yaw rate, and wheel speed sensors onboard the vehicle. However, dead reckoning methods suffer from drift. This paper provides an arc-length-based map matching method that uses a digital 2D map of the scenario in order to correct drift in the dead reckoning estimate. The kinematic model's prediction is used to introduce a temporal notion to the spatial information available in the map data. Results show reliable improvement in drift for all GPS-denied scenarios tested in this study. This innovative approach ensures that automated vehicles can maintain continuous and reliable navigation, significantly enhancing their safety and operational reliability in environments where GPS signals are compromised or unavailable.
title Vehicle Localization in GPS-Denied Scenarios Using Arc-Length-Based Map Matching
topic Robotics
Systems and Control
url https://arxiv.org/abs/2410.12208