Główne pojęcia
An acceleration-based constraint approach, termed CREVE, that leverages additional measurements from an inertial measurement unit (IMU) to achieve robust and accurate radar ego-velocity estimation, even in the presence of outliers.
Streszczenie
The paper proposes CREVE, an acceleration-based constraint approach for robust radar ego-velocity estimation. The key highlights are:
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CREVE leverages acceleration data from an accelerometer as an inequality constraint to prevent incorrect radar-based ego-velocity estimation, especially in scenarios with a large number of outliers.
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The authors introduce a practical accelerometer bias estimation method that utilizes two consecutive constrained radar ego-velocity estimates.
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A parameter adaptation rule is developed to dynamically adjust the range of the inequality constraint, improving estimation accuracy.
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Comprehensive evaluation using five open-source drone datasets demonstrates that CREVE significantly outperforms existing state-of-the-art methods, achieving reductions in absolute trajectory error of up to 84%.
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The proposed method functions as a submodule within a radar-inertial odometry (RIO) system, complementing the authors' previous work that does not require accelerometers.
Statystyki
The radar's 3D position points are projected onto a 2D image plane, with each number indicating the corresponding 1D Doppler velocity.
The experimental results show that CREVE reduces the RMSE of ego-velocity estimation by approximately 36% in the x-axis, 51% in the y-axis, and 37% in the z-direction, compared to the conventional RANSAC/LSQ-based approach.
CREVE also reduces the absolute trajectory error by approximately 53%, 84%, and 35% compared to the REVE, DeREVE, and RAVE methods, respectively.
Cytaty
"Ego-velocity estimation from point cloud measurements of a millimeter-wave frequency-modulated continuous wave (mmWave FMCW) radar has become a crucial component of radar-inertial odometry (RIO) systems."
"Conventional approaches often perform poorly when the number of point cloud outliers exceeds that of inliers."
"To further enhance accuracy and robustness against sensor errors, we introduce a practical accelerometer bias estimation method and a parameter adaptation rule."