Abstract
In extant radar signal processing systems, detection and tracking are carried out independently, and detected measurements are utilized as inputs to the tracking procedure. Therefore, the tracking performance is highly associated with detection accuracy, and this performance may severely degrade when detections include a mass of false alarms and missed-targets errors, especially in dense clutter or closely-spaced trajectories scenarios. To deal with this issue, this paper proposes a novel method for integrating the multiple hypothesis tracker with detection processing. Specifically, the detector acquires an adaptive detection threshold from the output of the multiple hypothesis tracker algorithm, and then the obtained detection threshold is employed to compute the score function and sequential probability ratio test threshold for the data association and track estimation tasks. A comparative analysis of three tracking algorithms in a clutter dense scenario, including the proposed method, the multiple hypothesis tracker, and the global nearest neighbor algorithm, is conducted. Simulation results demonstrate that the proposed multiple hypothesis tracker integrated with detection processing method outperforms both the standard multiple hypothesis tracker algorithm and the global nearest neighbor algorithm in terms of tracking accuracy.
Highlights
IntroductionMulti-target tracking (MTT) aims to obtain an estimation of target states from the measurements (localizations, velocities, etc.) received by a sensor in complex scenarios [1,2]
Multi-target tracking (MTT) aims to obtain an estimation of target states from the measurements received by a sensor in complex scenarios [1,2]
In complex environments with a low detection probability, high density clutter, and/or closely-spaced targets, it has been shown that the performance of multiple hypothesis tracking (MHT) is significantly better than joint probability data association (JPDA) and any other data association algorithms
Summary
Multi-target tracking (MTT) aims to obtain an estimation of target states from the measurements (localizations, velocities, etc.) received by a sensor in complex scenarios [1,2]. In conventional radar target tracking systems, measurement data are obtained by a detector with a specific detection probability, and they are provided to a tracker for target trajectory estimation [2,5]. This radar system simplifies the implementation of the detection and tracking process, thereby easing its computing burden. As the integration structure of detection and tracking can efficiently reduce the number of false tracks, in this paper, we propose a new multiple hypothesis tracking algorthim integrated with detection processing (MHT-IDP) under an efficient TOMHT framework.
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