Uncertainty-Driven Radar-Inertial Fusion for Instantaneous 3D Ego-Velocity Estimation

Prashant Kumar Rai; Elham Kowsari; Nataliya Strokina; Reza Ghabcheloo

doi:10.23919/FUSION65864.2025.11124007

Uncertainty-Driven Radar-Inertial Fusion for Instantaneous 3D Ego-Velocity Estimation

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › Scientific › peer-review

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Abstract

We present a method for estimating ego-velocity in autonomous navigation by integrating high-resolution imaging radar with an inertial measurement unit. The proposed approach addresses the limitations of traditional radar-based ego-motion estimation techniques by employing a neural network to process complex-valued raw radar data and estimate instantaneous linear ego-velocity along with its associated uncertainty. This uncertainty-aware velocity estimate is then integrated with inertial measurement unit data using an Extended Kalman Filter. The filter leverages the network-predicted uncertainty to refine the inertial sensor's noise and bias parameters, improving the overall robustness and accuracy of the ego-motion estimation. We evaluated the proposed method on the publicly available Coloradar dataset. Our approach achieves significantly lower error compared to the closest publicly available method, and also outperforms both instantaneous and scan matching-based techniques.

Original language	English
Title of host publication	Proceedings of the 2025 28th International Conference on Information Fusion, FUSION 2025
Publisher	IEEE
Number of pages	8
ISBN (Electronic)	978-1-0370-5623-9
ISBN (Print)	979-8-3315-0350-5
DOIs	https://doi.org/10.23919/FUSION65864.2025.11124007
Publication status	Published - 2025
Publication type	A4 Article in conference proceedings
Event	International Conference on Information Fusion - Rio de Janiero, Brazil Duration: 7 Jul 2025 → 11 Jul 2025

Conference

Conference	International Conference on Information Fusion
Country/Territory	Brazil
City	Rio de Janiero
Period	7/07/25 → 11/07/25

Keywords

4D Radar
Complex Value Neural Network
Ego-velocity
EKF
IMU
Sensor fusion

Publication forum classification

Publication forum level 1

ASJC Scopus subject areas

Information Systems
Signal Processing
Information Systems and Management
Computer Vision and Pattern Recognition

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Uncertainty-Driven Radar-Inertial Fusion for Instantaneous 3D Ego-Velocity Estimation
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@inproceedings{a2b87464176a493fadfbb610f6529657,

title = "Uncertainty-Driven Radar-Inertial Fusion for Instantaneous 3D Ego-Velocity Estimation",

abstract = "We present a method for estimating ego-velocity in autonomous navigation by integrating high-resolution imaging radar with an inertial measurement unit. The proposed approach addresses the limitations of traditional radar-based ego-motion estimation techniques by employing a neural network to process complex-valued raw radar data and estimate instantaneous linear ego-velocity along with its associated uncertainty. This uncertainty-aware velocity estimate is then integrated with inertial measurement unit data using an Extended Kalman Filter. The filter leverages the network-predicted uncertainty to refine the inertial sensor's noise and bias parameters, improving the overall robustness and accuracy of the ego-motion estimation. We evaluated the proposed method on the publicly available Coloradar dataset. Our approach achieves significantly lower error compared to the closest publicly available method, and also outperforms both instantaneous and scan matching-based techniques.",

keywords = "4D Radar, Complex Value Neural Network, Ego-velocity, EKF, IMU, Sensor fusion",

author = "Rai, \{Prashant Kumar\} and Elham Kowsari and Nataliya Strokina and Reza Ghabcheloo",

note = "Publisher Copyright: {\textcopyright} 2025 ISIF.; International Conference on Information Fusion ; Conference date: 07-07-2025 Through 11-07-2025",

year = "2025",

doi = "10.23919/FUSION65864.2025.11124007",

language = "English",

isbn = "979-8-3315-0350-5",

booktitle = "Proceedings of the 2025 28th International Conference on Information Fusion, FUSION 2025",

publisher = "IEEE",

address = "United States",

}

Rai, PK , Kowsari, E , Strokina, N & Ghabcheloo, R 2025, Uncertainty-Driven Radar-Inertial Fusion for Instantaneous 3D Ego-Velocity Estimation. in Proceedings of the 2025 28th International Conference on Information Fusion, FUSION 2025. IEEE, International Conference on Information Fusion, Rio de Janiero, Brazil, 7/07/25. https://doi.org/10.23919/FUSION65864.2025.11124007

Uncertainty-Driven Radar-Inertial Fusion for Instantaneous 3D Ego-Velocity Estimation. / Rai, Prashant Kumar ; Kowsari, Elham ; Strokina, Nataliya et al.
Proceedings of the 2025 28th International Conference on Information Fusion, FUSION 2025. IEEE, 2025.

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › Scientific › peer-review

TY - GEN

T1 - Uncertainty-Driven Radar-Inertial Fusion for Instantaneous 3D Ego-Velocity Estimation

AU - Rai, Prashant Kumar

AU - Kowsari, Elham

AU - Strokina, Nataliya

AU - Ghabcheloo, Reza

PY - 2025

Y1 - 2025

N2 - We present a method for estimating ego-velocity in autonomous navigation by integrating high-resolution imaging radar with an inertial measurement unit. The proposed approach addresses the limitations of traditional radar-based ego-motion estimation techniques by employing a neural network to process complex-valued raw radar data and estimate instantaneous linear ego-velocity along with its associated uncertainty. This uncertainty-aware velocity estimate is then integrated with inertial measurement unit data using an Extended Kalman Filter. The filter leverages the network-predicted uncertainty to refine the inertial sensor's noise and bias parameters, improving the overall robustness and accuracy of the ego-motion estimation. We evaluated the proposed method on the publicly available Coloradar dataset. Our approach achieves significantly lower error compared to the closest publicly available method, and also outperforms both instantaneous and scan matching-based techniques.

AB - We present a method for estimating ego-velocity in autonomous navigation by integrating high-resolution imaging radar with an inertial measurement unit. The proposed approach addresses the limitations of traditional radar-based ego-motion estimation techniques by employing a neural network to process complex-valued raw radar data and estimate instantaneous linear ego-velocity along with its associated uncertainty. This uncertainty-aware velocity estimate is then integrated with inertial measurement unit data using an Extended Kalman Filter. The filter leverages the network-predicted uncertainty to refine the inertial sensor's noise and bias parameters, improving the overall robustness and accuracy of the ego-motion estimation. We evaluated the proposed method on the publicly available Coloradar dataset. Our approach achieves significantly lower error compared to the closest publicly available method, and also outperforms both instantaneous and scan matching-based techniques.

KW - 4D Radar

KW - Complex Value Neural Network

KW - Ego-velocity

KW - EKF

KW - IMU

KW - Sensor fusion

U2 - 10.23919/FUSION65864.2025.11124007

DO - 10.23919/FUSION65864.2025.11124007

M3 - Conference contribution

AN - SCOPUS:105015846291

SN - 979-8-3315-0350-5

BT - Proceedings of the 2025 28th International Conference on Information Fusion, FUSION 2025

PB - IEEE

T2 - International Conference on Information Fusion

Y2 - 7 July 2025 through 11 July 2025

ER -

Uncertainty-Driven Radar-Inertial Fusion for Instantaneous 3D Ego-Velocity Estimation

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