Abstract
Radar maneuvering target detection in clutter background should not only consider the complex characteristics of the target to accumulate its energy as much as possible, but also suppress clutter to improve the signal-to-clutter ratio (SCR). The traditional fractional domain transform-based detection method requires parameters match searching, which costs heavy computational burden in case of a large amount of data. Sparse FT and sparse fractional FT can obtain high-resolution sparse representation of the target, but the signal sparsity needs to be known before, and the sparse representation performance is poor in clutter background. In this article, adaptive filtering method is introduced into the sparse fractional ambiguity function (SFRAF) method, and a SFRAF domain adaptive clutter suppression and highly maneuvering target detection algorithm is proposed, which is named as adaptive SFRAF (ASFRAF). The ASFRAF domain iterative filtering operation can suppress the clutter while retaining the signal energy as much as possible. Simulation results and measured radar data processing results show that the proposed algorithm can overcome the limitation of the SFRAF on the sparsity preset value and achieve high efficiency and robust detection of high-order phase maneuvering targets under a low SCR environment.
Highlights
T HE rapid and effective detection of low observable maneuvering targets is a worldwide difficult problem in the field of radar technology [1]–[4]
By introducing the adaptive filtering method into sparse fractional ambiguity function (SFRAF) processing, a novel adaptive clutter suppression and radar maneuvering target detection algorithm named as adaptive SFRAF (ASFRAF) is proposed
2) ASFRAF algorithm can suppress the clutter effectively while retaining the signal energy to the greatest extent, and has good detection performance for the maneuvering target in low signal-to-clutter ratio (SCR) conditions (−10 dB), which is more suitable for clutter background than SFRAF
Summary
T HE rapid and effective detection of low observable maneuvering targets is a worldwide difficult problem in the field of radar technology [1]–[4]. With the development of novel radar systems such as phased array radar (PAR), ubiquitous radar [7], and multiple-input multiple-output (MIMO) radar [8], [9], the observation time of the target is greatly extended, which is beneficial to increase the integration gain and improve the refinement processing ability of maneuvering target in the clutter background [10]–[12]. This staring observation or the ubiquitous observation mode would increase the number of echo data, and the high system sampling frequency would further increase the amount of data, which puts higher requirements on the algorithm’s calculation efficiency and system real-time performance [13]
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