Abstract
Robust localization methods that employ distance measurements to predict the position of an emitter are proposed in this paper. The occurrence of outliers due to the non-line-of sight (NLOS) propagation of signals can drastically degrade the localization performance in crowded urban areas and indoor situations. Hence, robust positioning methods are considered to mitigate the effects of outliers. Specifically, localization methods based on robust statistics are considered. Modified multi-stage ML-type method (MM) based weighted least squares (WLS), maximum a posteriori (MAP) expectation maximization (EM) WLS and variational Bayes (VB) EM WLS algorithms are developed under various outlier-contaminated environments. Simulation results show that the position estimation accuracy of the proposed modified MM WLS method, which uses the novel weight, is higher than that of the other methods under most outlier-contaminated conditions. Furthermore, the MAP-EM WLS and VB-EM WLS methods are the most accurate among algorithms that do not require statistical testing. Additionally, the mean square error (MSE) and asymptotic unbiasedness of the proposed algorithms are analyzed.
Highlights
Emitter positioning involves predicting the coordinates of a point emitter using the observations from each receiver
We develop a robust ML-type method (MM) weighted least squares (WLS)-M localization method in which the weight calculation is different from that of existing MM WLS localization algorithm
The Kalman filter has been widely utilized for localization, the robust version of Kalman filter was compared with the proposed algorithm
Summary
Emitter positioning involves predicting the coordinates of a point emitter using the observations from each receiver. Robust statistics are required because the conventional localization methods based on a sample mean are quite vulnerable to outliers in mixed LOS/NLOS environments. Some examples of localization methods based on robust statistics are the M and least median squares (LMedS) algorithms [4]–[9]. The existing MM estimation-based localization algorithm uses a transformed range observation to obtain the position estimate and the weight to reflect the different accuracy of each sensor [15]. The existing statistical testing method requires an optimal threshold for discriminating the inliers and outliers. This is not an easy task under rapidly changing environments or channels, as the threshold should be predetermined according to the changing conditions.
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