Abstract
For K-distributed sea clutter, a constant false alarm rate (CFAR) is crucial as a desired property for automatic target detection in an unknown and non-stationary background. In multiple-target scenarios, the target masking effect reduces the detection performance of CFAR detectors evidently. A machine learning based processor, associating the artificial neural network (ANN) and a clustering algorithm of density-based spatial clustering of applications with noise (DBSCAN), namely, DBSCAN-CFAR, is proposed herein to address this issue. ANN is trained with a symmetrical structure to estimate the shape parameter of background clutter, whereas DBSCAN is devoted to excluding interference targets and sea spikes as outliers in the leading and lagging windows that are symmetrical about the cell under test (CUT). Simulation results verified that the ANN-based method provides the optimal parameter estimation results in the range of 0.1 to 30, which facilitates the control of actual false alarm probability. The effectiveness and robustness of DBSCAN-CFAR are also confirmed by the comparisons of conventional CFAR processors in different clutter conditions, comprised of varying target numbers, shape parameters, and false alarm probabilities. Although the proposed ANN-based DBSCAN-CFAR processor incurs more elapsed time, it achieves superior CFAR performance without a prior knowledge on the number and distribution of interference targets.
Highlights
With the development of radar resolution, numerous studies have shown that the amplitude distribution of a sea clutter exhibits a long tail appreciably [1,2]
A machine learning based density-based spatial clustering of applications with noise (DBSCAN)-constant false alarm rate (CFAR) processor is proposed to minify the deviation of the background level estimation in multiple-target scenarios for K-distributed sea clutter
The shape parameter of the unknown background clutter was evaluated by various methods of the trained four-layer artificial neural network (ANN) model, back propagation neural network (BPNN), MOM-12, and MOM-24
Summary
With the development of radar resolution, numerous studies have shown that the amplitude distribution of a sea clutter exhibits a long tail appreciably [1,2] At this time, the traditional Rayleigh, Weibull, and log-normal distributions cannot describe the statistical characteristics of sea clutter adequately; the K-distribution has been introduced for the modeling and simulation of high-resolution sea clutters [3,4]. Several types of CFAR processors have been proposed based on the mechanism of a sliding reference window They perform statistical analysis on the clutter background, calculate dynamic thresholds, and make a comparison with the cell under test (CUT) to realize automatic detection of the targets.
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