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A High-Resolution Imaging Method for Multiple-Input Multiple-Output Sonar Based on Deterministic Compressed Sensing.

Ning Gao1,2, Feng Xu1, Juan Yang1

  • 1Ocean Acoustic Technology Laboratory, Institute of Acoustics, Chinese Academy of Sciences, Beijing 100190, China.

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|February 24, 2024
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Summary
This summary is machine-generated.

This study introduces a Compressed Sensing (CS) method to improve Multiple-Input Multiple-Output (MIMO) sonar imaging. The technique suppresses noise, enabling clearer underwater target localization with lower sidelobes.

Keywords:
MIMO sonarcompressed sensinghigh resolutionmatched filteringsignal reconstruction

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Area of Science:

  • Underwater acoustics
  • Signal processing
  • Array signal processing

Background:

  • Conventional sonar and MIMO sonar systems face challenges in achieving high angular and range resolution.
  • MIMO sonar utilizes matched filtering for enhanced spatial resolution, but imperfect correlations lead to high sidelobes, hindering accurate target localization.
  • High sidelobe values in underwater imagery impede precise identification of targets.

Purpose of the Study:

  • To propose a Compressed Sensing (CS) method for reconstructing echo signals in MIMO sonar systems.
  • To suppress correlation noise arising from imperfect correlation characteristics in MIMO sonar.
  • To enhance spatial resolution and improve target localization accuracy in underwater imagery.

Main Methods:

  • A Compressed Sensing (CS) approach is employed, involving echo signal reconstruction to mitigate correlation noise between orthogonal waveforms.
  • A shifted dictionary matrix and a deterministic Discrete Fourier Transform (DFT) measurement matrix are utilized for signal processing.
  • Sparse recovery algorithms optimize signal reconstruction, followed by joint transmit-receive beamforming to generate a 2D sonar image.

Main Results:

  • The proposed CS method effectively suppresses correlation noise, leading to reduced sidelobe values in sonar imagery.
  • Numerical simulations and lake experiments demonstrate the method's capability to produce lower sidelobe sonar images.
  • The approach achieves improved performance under sub-Nyquist sampling rates compared to existing methods.

Conclusions:

  • The developed Compressed Sensing (CS) method offers a viable solution for enhancing spatial resolution and target localization in MIMO sonar systems.
  • This technique effectively addresses the challenge of high sidelobes caused by imperfect correlation characteristics.
  • The study validates the method's effectiveness through simulations and experimental data, highlighting its potential for advanced underwater acoustic imaging.