# Low rank plus sparse decomposition of synthetic aperture radar data for   target imaging and tracking

**Authors:** Matan Leibovich, George Papanicolaou, Chrysoula Tsogka

arXiv: 1906.02311 · 2019-06-07

## TL;DR

This paper presents a method using low rank plus sparse decomposition via RPCA to separate stationary and moving targets in SAR data, with a theoretical analysis guiding parameter choice and target velocity detection.

## Contribution

The paper provides a theoretical analysis for optimal RPCA parameter selection in SAR data separation and establishes a lower bound for target velocity detection.

## Key findings

- Effective separation of stationary and moving targets demonstrated
- Rank of sparse component proportional to square root of target speed
- Theoretical guidelines for parameter choice improve separation stability

## Abstract

We analyze synthetic aperture radar (SAR) imaging of complex ground scenes that contain both stationary and moving targets. In the usual SAR acquisition scheme, we consider ways to preprocess the data so as to separate the contributions of the moving targets from those due to stationary background reflectors. Both components of the data, that is, reflections from stationary and moving targets, are considered as signal that is needed for target imaging and tracking, respectively. The approach we use is to decompose the data matrix into a low rank and a sparse part. This decomposition enables us to capture the reflections from moving targets into the sparse part and those from stationary targets into the low rank part of the data. The computational tool for this is robust principal component analysis (RPCA) applied to the SAR data matrix. We also introduce a lossless baseband transformation of the data, which simplifies the analysis and improves the performance of the RPCA algorithm. Our main contribution is a theoretical analysis that determines an optimal choice of parameters for the RPCA algorithm so as to have an effective and stable separation of SAR data coming from moving and stationary targets. This analysis gives also a lower bound for detectable target velocities. We show in particular that the rank of the sparse matrix is proportional to the square root of the target's speed in the direction that connects the SAR platform trajectory to the imaging region. The robustness of the approach is illustrated with numerical simulations in the X-band SAR regime.

## Full text

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## Figures

20 figures with captions in the complete paper: https://tomesphere.com/paper/1906.02311/full.md

## References

21 references — full list in the complete paper: https://tomesphere.com/paper/1906.02311/full.md

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Source: https://tomesphere.com/paper/1906.02311