English

Theoretical Analysis for Extended Target Recovery in Randomized Stepped Frequency Radars

Signal Processing 2021-10-05 v1

Abstract

Randomized Stepped Frequency Radar (RSFR) is very attractive for tasks under complex electromagnetic environment. Due to the synthetic high range resolution in RSRFs, a target usually occupies a series of range cells and is called an extended target. To reconstruct the range-Doppler information in a RSFR, previous studies based on sparse recovery mainly exploit the sparsity of the target scene but do not adequately address the extended-target characteristics, which exist in many practical applications. Block sparsity, which combines the sparsity and the target extension, better characterizes a priori knowledge of the target scene in a wideband RSFR. This paper studies the RSFR range-Doppler reconstruction problem using block sparse recovery. Particularly, we theoretically analyze the block coherence and spectral norm of the observation matrix in RSFR and build a bound on the parameters of the radar, under which the exact recovery of the range-Doppler information is guaranteed. Both simulation and field experiment results demonstrate the superiority of the block sparse recovery over conventional sparse recovery in RSFRs.

Keywords

Cite

@article{arxiv.1908.02929,
  title  = {Theoretical Analysis for Extended Target Recovery in Randomized Stepped Frequency Radars},
  author = {Lei Wang and Tianyao Huang and Yimin Liu},
  journal= {arXiv preprint arXiv:1908.02929},
  year   = {2021}
}

Comments

12 pages, 8 figures

R2 v1 2026-06-23T10:42:41.090Z