Abstract
The probability hypothesis density (PHD) filter is well known for addressing the problem of multiple human tracking for a variable number of targets, and the sequential Monte Carlo implementation of the PHD filter, known as the particle PHD filter, can give state estimates with nonlinear and non-Gaussian models. Recently, Mahler et al. have introduced a PHD smoother to gain more accurate estimates for both target states and number. However, as highlighted by Psiaki in the context of a backward-smoothing extended Kalman filter, with a nonlinear state evolution model the approximation error in the backward filtering requires careful consideration. Psiaki suggests that to minimize the aggregated least-squares error over a batch of data. We instead use the term retrodiction PHD filter to describe the backward filtering algorithm in recognition of the approximation error proposed in the original PHD smoother, and we propose an adaptive recursion step to improve the approximation accuracy. This step combines forward and backward processing through the measurement set and thereby mitigates the problems with the original PHD smoother when the target number changes significantly and the targets appear and disappear randomly. Simulation results show the improved performance of the proposed algorithm and its capability in handling a variable number of targets.
Highlights
V IDEO signal processing based human tracking is becoming increasing popular because of its wide potential applications
When evaluating the Retro-probability hypothesis density (PHD) algorithm, we found the approach can improve the tracking results over the PHD filter; its performance deteriorates with an increasing number of targets appearing and disappearing in the monitored area
Following the idea of combination of adaptive filters proposed in [11], in this letter, a new method for the Retro-PHD filter is proposed by using an adaptive recursion step, in which the measurements from both forward and backward processing are employed for target state estimation
Summary
V IDEO signal processing based human tracking is becoming increasing popular because of its wide potential applications. When evaluating the Retro-PHD algorithm, we found the approach can improve the tracking results over the PHD filter; its performance deteriorates with an increasing number of targets appearing and disappearing in the monitored area. In such a scenario, more false measurements for backward estimation are introduced by false alarm or missed detection. Following the idea of combination of adaptive filters proposed in [11], in this letter, a new method for the Retro-PHD filter is proposed by using an adaptive recursion step, in which the measurements from both forward and backward processing are employed for target state estimation. Other recent multiple human target trackers such as cardinality PHD filter [15] and multiBernoulli filter [16] are not included in this short study as they do not involve backward/retrodiction processing
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