Litcius/Paper detail

Learning-Based Extended Object Tracking Using Hierarchical Truncation Measurement Model With Automotive Radar

Yuxuan Xia, Pu Wang, Karl Berntorp, Lennart Svensson, Karl Granström, Hassan Mansour, Petros T. Boufounos, Philip V. Orlik

2021IEEE Journal of Selected Topics in Signal Processing52 citationsDOI

Abstract

This paper presents a data-driven measurement model for extended object tracking (EOT) with automotive radar. Specifically, the spatial distribution of automotive radar measurements is modeled as a hierarchical truncated Gaussian (HTG) with structural geometry parameters that can be learned from the training data. The HTG measurement model provides an adequate resemblance to the spatial distribution of real-world automotive radar measurements. Moreover, large-scale radar datasets can be leveraged to learn the geometry-related model parameters and offload the computationally demanding model parameter estimation from the state update step. The learned HTG measurement model is further incorporated into a random matrix based EOT approach with two (multi-sensor) measurement updates: one is based on a factorized Gaussian inverse-Wishart density representation and the other is based on a Rao-Blackwellized particle density representation. The effectiveness of the proposed approaches is verified on both synthetic data and real-world nuScenes dataset over 300 trajectories.

Topics & Concepts

RadarComputer scienceArtificial intelligenceComputer visionRadar trackerAlgorithmInverse-Wishart distributionGaussianPattern recognition (psychology)Wishart distributionMachine learningMultivariate statisticsTelecommunicationsQuantum mechanicsPhysicsTarget Tracking and Data Fusion in Sensor NetworksGaussian Processes and Bayesian InferenceIndoor and Outdoor Localization Technologies