Abstract
Activated reconnaissance systems based on target illumination are of high importance for surveillance tasks where targets are nonemitting. Multistatic configurations, wheremultiple illuminators and multiple receivers are located separately, are of particular interest. The fusion of measurements is a prerequisite for extracting and maintaining target tracks. The inherent ambiguity of the data makes the use of adequate algorithms, such as multiple hypothesis tracking, inevitable. For their design, the understanding of the residual clutter, the sensor resolution and the characteristic impact of the propagation medium is important. This leads to precise sensor models, which are able to determine the performance of the surveillance team. Incorporating these models in multihypothesis tracking leads to a situationally aware data fusion and tracking algorithm. Various implementations of this algorithm are evaluated with the help of simulated and measured data sets. Incorporating model knowledge leads to increased performance, but only if the model is in line with the physical reality: we need to find a compromise between refined and robust tracking models. Furthermore, to implement the model, which is inherently nonlinear for multistatic sonar, approximations have to be made. When engineering the multistatic tracking system, sensitivity studies help to tune model assumptions and approximations.
Highlights
Submarines operate covertly, hidden under the surface of the sea
Two different ways to handle the nonlinear measurement equation in these schemes are investigated: (i) the measurement is transformed into Cartesian coordinates and the Kalman Filter updates the target state in Cartesian coordinates; (ii) the predicted state is transformed into the measurement space to perform the filter update
The data set B01 was analysed by detailed postprocessing to determine the exact position of the E/R sound source, quite accurate truth information is available
Summary
Submarines operate covertly, hidden under the surface of the sea. Maneuvering silently is their greatest threat. An antistealth setup consists of multiple sources and receivers This makes it almost impossible for the submarine to hide its strong echo returns. The correct modelling allows a successful multisensor data fusion and by this the full exploitation of the multistatic sonar setup. Key prerequisites to achieve this are (i) a precise modelling of the deterministic features in a multistatic measurement and incorporation of this measurement modelling in the framework of the Unscented Kalman Filter (Section 3) and (ii) an optimal data fusion which can be found by weighting the fusion input by its quality.
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