Related papers: SparseRadNet: Sparse Perception Neural Network on Subsampled Radar Data

SparseRadNet: Sparse Perception Neural Network on Subsampled Radar Data

URL: http://arxiv.org/abs/2406.10600v4
Date: Tue, 16 Jul 2024 08:29:30 GMT
Title: SparseRadNet: Sparse Perception Neural Network on Subsampled Radar Data
Authors: Jialong Wu, Mirko Meuter, Markus Schoeler, Matthias Rottmann,
Abstract summary: Radar raw data often contains excessive noise, whereas radar point clouds retain only limited information. We introduce an adaptive subsampling method together with a tailored network architecture that exploits the sparsity patterns. Experiments on the RADIal dataset show that our SparseRadNet exceeds state-of-the-art (SOTA) performance in object detection and achieves close to SOTA accuracy in freespace segmentation.
Score: 5.344444942640663
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Radar-based perception has gained increasing attention in autonomous driving, yet the inherent sparsity of radars poses challenges. Radar raw data often contains excessive noise, whereas radar point clouds retain only limited information. In this work, we holistically treat the sparse nature of radar data by introducing an adaptive subsampling method together with a tailored network architecture that exploits the sparsity patterns to discover global and local dependencies in the radar signal. Our subsampling module selects a subset of pixels from range-doppler (RD) spectra that contribute most to the downstream perception tasks. To improve the feature extraction on sparse subsampled data, we propose a new way of applying graph neural networks on radar data and design a novel two-branch backbone to capture both global and local neighbor information. An attentive fusion module is applied to combine features from both branches. Experiments on the RADIal dataset show that our SparseRadNet exceeds state-of-the-art (SOTA) performance in object detection and achieves close to SOTA accuracy in freespace segmentation, meanwhile using sparse subsampled input data.

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