English

Sparsity and Coefficient Permutation Based Two-Domain AMP for Image Block Compressed Sensing

Computer Vision and Pattern Recognition 2023-08-21 v2 Multimedia Image and Video Processing

Abstract

The learned denoising-based approximate message passing (LDAMP) algorithm has attracted great attention for image compressed sensing (CS) tasks. However, it has two issues: first, its global measurement model severely restricts its applicability to high-dimensional images, and its block-based measurement method exhibits obvious block artifacts; second, the denoiser in the LDAMP is too simple, and existing denoisers have limited ability in detail recovery. In this paper, to overcome the issues and develop a high-performance LDAMP method for image block compressed sensing (BCS), we propose a novel sparsity and coefficient permutation-based AMP (SCP-AMP) method consisting of the block-based sampling and the two-domain reconstruction modules. In the sampling module, SCP-AMP adopts a discrete cosine transform (DCT) based sparsity strategy to reduce the impact of the high-frequency coefficient on the reconstruction, followed by a coefficient permutation strategy to avoid block artifacts. In the reconstruction module, a two-domain AMP method with DCT domain noise correction and pixel domain denoising is proposed for iterative reconstruction. Regarding the denoiser, we proposed a multi-level deep attention network (MDANet) to enhance the texture details by employing multi-level features and multiple attention mechanisms. Extensive experiments demonstrated that the proposed SCP-AMP method achieved better reconstruction accuracy than other state-of-the-art BCS algorithms in terms of both visual perception and objective metrics.

Keywords

Cite

@article{arxiv.2305.12986,
  title  = {Sparsity and Coefficient Permutation Based Two-Domain AMP for Image Block Compressed Sensing},
  author = {Junhui Li and Xingsong Hou and Huake Wang and Shuhao Bi},
  journal= {arXiv preprint arXiv:2305.12986},
  year   = {2023}
}

Comments

The content modification has been upgraded and corrected on a large scale, and request to withdraw this version

R2 v1 2026-06-28T10:41:21.605Z