DNOI-4DRO: Deep 4D Radar Odometry with Differentiable Neural-Optimization Iterations
DOI:
https://doi.org/10.1609/aaai.v40i22.38914Abstract
A novel learning-optimization-combined 4D radar odometry model, named DNOI-4DRO, is proposed in this paper. The proposed model seamlessly integrates traditional geometric optimization with end-to-end neural network training, leveraging an innovative differentiable neural-optimization iteration operator. In this framework, point-wise motion flow is first estimated using a neural network, followed by the construction of a cost function based on the relationship between point motion and pose in 3D space. The radar pose is then refined using Gauss-Newton updates. Additionally, we design a dual-stream 4D radar backbone that integrates multi-scale geometric features and clustering-based class-aware features to enhance the representation of sparse 4D radar point clouds. Extensive experiments on the VoD and Snail-Radar datasets demonstrate the superior performance of our model, which outperforms recent classical and learning-based approaches. Notably, our method even achieves results comparable to A-LOAM with mapping optimization using LiDAR point clouds as input.
Published
2026-03-14
How to Cite
Lu, S., Zhou, H., Zhuo, G., & Tang, X. (2026). DNOI-4DRO: Deep 4D Radar Odometry with Differentiable Neural-Optimization Iterations. Proceedings of the AAAI Conference on Artificial Intelligence, 40(22), 18487–18495. https://doi.org/10.1609/aaai.v40i22.38914
Issue
Section
AAAI Technical Track on Intelligent Robotics
