Clutter suppression approach for non-sidelooking airborne radar with medium pulse repetition frequency

Baoquan Dai; Tong Wang; Yifeng Wu; Jianxin Wu; Zheng Bao

Clutter suppression approach for non-sidelooking airborne radar with medium pulse repetition frequency

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Author(s): Baoquan Dai ¹ ; Tong Wang ¹ ; Yifeng Wu ¹ ; Jianxin Wu ¹ ; Zheng Bao ¹
- Affiliations: 1: National Laboratory of Radar Signal Processing, Xidian University, Xi'an 710071, People's Republic of China
Source: Volume 8, Issue 9, December 2014, p. 999 – 1007
DOI: 10.1049/iet-rsn.2013.0229 , Print ISSN 1751-8784, Online ISSN 1751-8792

Received 11/07/2013, Accepted 25/02/2014, Revised 15/02/2014, Published 31/03/2014

For non-sidelooking airborne radar operating in medium pulse repetition frequency mode, the space–time adaptive processing (STAP) technique suffers from a significant performance loss due to the range dependence of clutter. Here, an efficient clutter suppression approach is presented to improve STAP performance. Utilising the characteristics of clutter, the near-range clutter, the major reason for the performance degradation, is extracted from raw returns using a specially designed oblique projector firstly, and then is mitigated by an adaptive beamformer estimated from the extracted components. Subsequently, an azimuth-Doppler STAP beamformer is employed to further suppress the residual clutter. To enhance the robustness of the approach, a simple steering vector calibration technique is taken into account. The proposed approach can eliminate the near-range clutter effectively, and therefore alleviate the clutter range dependence greatly. The STAP performance can be improved significantly. Simulation results demonstrate the effectiveness of the presented method.

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Clutter suppression approach for non-sidelooking airborne radar with medium pulse repetition frequency

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