Litcius/Paper detail

Slow-Time FDA-MIMO Technique With Application to STAP Radar

Cai Wen, Yan Huang, Jinye Peng, Jianxin Wu, Guimei Zheng, Yuhong Zhang

2021IEEE Transactions on Aerospace and Electronic Systems112 citationsDOI

Abstract

Unlike the conventional phased array, the frequency-diverse array (FDA) employs a tiny frequency increment across the array elements, which is capable of providing range–angle–time-dependent beampattern, and thereby offers potential benefits in target localization and interference mitigation. Reported literature on FDA mostly focuses on its intrapulse (fast-time) property and ignores the interpulse (slow-time) feature induced by frequency offset. In this article, incorporating the neglected inherent slow-time coding feature, a novel slow-time FDA multiple-input multiple-output (FDA-MIMO) technique is proposed for the space-time adaptive processing (STAP) radar. The new coding scheme can separate transmitting (Tx) signals via slow-time Doppler filtering, and the problem of signal aliasing is tackled by appropriately designing the slow-time codes. At the receiving (Rx) side, two Rx schemes are devised for recovering range-dependent Tx degrees-of-freedom. Moreover, the relevant clutter rank and the rule for code design are derived in detail. The outstanding merits of the proposed slow-time FDA-MIMO STAP radar consist of the following: There is no specific restriction on the probing waveform; the negative effect of time-variant pattern is perfectly eliminated; and both the target localization accuracy and clutter suppression performance are superior over the state-of-the-art FDA radar systems. Numerical results corroborate the superiorities of the proposed waveform strategy for STAP application.

Topics & Concepts

Space-time adaptive processingClutterRadarComputer scienceMIMOMonopulse radarElectronic engineeringJammingWaveformMoving target indicationAlgorithmPulse-Doppler radarEngineeringTelecommunicationsBeamformingRadar imagingPhysicsThermodynamicsRadar Systems and Signal ProcessingAdvanced SAR Imaging TechniquesDirection-of-Arrival Estimation Techniques