Abstract
A deep-learning architecture, dubbed as the 2D-ADMM-Net (2D-ADN), is proposed in this article. It provides effective high-resolution 2D inverse synthetic aperture radar (ISAR) imaging under scenarios of low SNRs and incomplete data, by combining model-based sparse reconstruction and data-driven deep learning. Firstly, mapping from ISAR images to their corresponding echoes in the wavenumber domain is derived. Then, a 2D alternating direction method of multipliers (ADMM) is unrolled and generalized to a deep network, where all adjustable parameters in the reconstruction layers, nonlinear transform layers, and multiplier update layers are learned by an end-to-end training through back-propagation. Since the optimal parameters of each layer are learned separately, 2D-ADN exhibits more representation flexibility and preferable reconstruction performance than model-driven methods. Simultaneously, it is able to better facilitate ISAR imaging with limited training samples than data-driven methods owing to its simple structure and small number of adjustable parameters. Additionally, benefiting from the good performance of 2D-ADN, a random phase error estimation method is proposed, through which well-focused imaging can be acquired. It is demonstrated by experiments that although trained by only a few simulated images, the 2D-ADN shows good adaptability to measured data and favorable imaging results with a clear background can be obtained in a short time.
Highlights
Under ideal observational environments with high signal-to-noise ratios (SNRs) and complete echo matrices, wellfocused imaging can be acquired by classic techniques such as the range-Doppler (RD)
As inverse synthetic aperture radar (ISAR) images are generally sparse in the image domain, high-resolution ISAR imaging under complex observational environments based on the theory of sparse signal reconstruction has received intensive attention in the radar imaging community in recent years [4,5], in which the reconstruction of sparse images from noisy or gapped echoes given the observation dictionary is sought
We will demonstrate the effectiveness of 2D-ADN by high-resolution
Summary
Under ideal observational environments with high signal-to-noise ratios (SNRs) and complete echo matrices, wellfocused imaging can be acquired by classic techniques such as the range-Doppler (RD). For a target with a small radar cross section (RCS) or a long observation distance, the SNR of the received echoes is low due to limited transmitted power. The complex observational environments discussed above, i.e., incomplete data and low SNRs, cause severe performance degradation or even invalidate the available imaging techniques. As ISAR images are generally sparse in the image domain, high-resolution ISAR imaging under complex observational environments based on the theory of sparse signal reconstruction has received intensive attention in the radar imaging community in recent years [4,5], in which the reconstruction of sparse images (i.e., the distribution of dominant scattering centers) from noisy or gapped echoes given the observation dictionary is sought
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