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Bibliographic Details
Main Authors: Adolfsson, Daniel, Hilger, Maximilian
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2404.01781
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author Adolfsson, Daniel
Hilger, Maximilian
author_facet Adolfsson, Daniel
Hilger, Maximilian
contents This article describes the method CFEAR Radar odometry, submitted to a competition at the Radar in Robotics workshop, ICRA 20241. CFEAR is an efficient and accurate method for spinning 2D radar odometry that generalizes well across environments. This article presents an overview of the odometry pipeline with new experiments on the public Boreas dataset. We show that a real-time capable configuration of CFEAR - with its original parameter set - yields surprisingly low drift in the Boreas dataset. Additionally, we discuss an improved implementation and solving strategy that enables the most accurate configuration to run in real-time with improved robustness, reaching as low as 0.61% translation drift at a frame rate of 68 Hz. A recent release of the source code is available to the community https://github.com/dan11003/CFEAR_Radarodometry_code_public, and we publish the evaluation from this article on https://github.com/dan11003/cfear_2024_workshop
format Preprint
id arxiv_https___arxiv_org_abs_2404_01781
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle An evaluation of CFEAR Radar Odometry
Adolfsson, Daniel
Hilger, Maximilian
Robotics
This article describes the method CFEAR Radar odometry, submitted to a competition at the Radar in Robotics workshop, ICRA 20241. CFEAR is an efficient and accurate method for spinning 2D radar odometry that generalizes well across environments. This article presents an overview of the odometry pipeline with new experiments on the public Boreas dataset. We show that a real-time capable configuration of CFEAR - with its original parameter set - yields surprisingly low drift in the Boreas dataset. Additionally, we discuss an improved implementation and solving strategy that enables the most accurate configuration to run in real-time with improved robustness, reaching as low as 0.61% translation drift at a frame rate of 68 Hz. A recent release of the source code is available to the community https://github.com/dan11003/CFEAR_Radarodometry_code_public, and we publish the evaluation from this article on https://github.com/dan11003/cfear_2024_workshop
title An evaluation of CFEAR Radar Odometry
topic Robotics
url https://arxiv.org/abs/2404.01781