Compressive Imaging Reconstruction via Tensor Decomposed Multi-Resolution Grid Encoding
- URL: http://arxiv.org/abs/2507.07707v1
- Date: Thu, 10 Jul 2025 12:36:20 GMT
- Title: Compressive Imaging Reconstruction via Tensor Decomposed Multi-Resolution Grid Encoding
- Authors: Zhenyu Jin, Yisi Luo, Xile Zhao, Deyu Meng,
- Abstract summary: Compressive imaging (CI) reconstruction aims to recover high-dimensional images from low-dimensional measurements compressed.<n>Existing unsupervised representations may struggle to achieve a desired balance between representation ability and efficiency.<n>We propose Decomposed multi-resolution Grid encoding (GridTD), an unsupervised continuous representation framework for CI reconstruction.
- Score: 50.54887630778593
- License: http://creativecommons.org/publicdomain/zero/1.0/
- Abstract: Compressive imaging (CI) reconstruction, such as snapshot compressive imaging (SCI) and compressive sensing magnetic resonance imaging (MRI), aims to recover high-dimensional images from low-dimensional compressed measurements. This process critically relies on learning an accurate representation of the underlying high-dimensional image. However, existing unsupervised representations may struggle to achieve a desired balance between representation ability and efficiency. To overcome this limitation, we propose Tensor Decomposed multi-resolution Grid encoding (GridTD), an unsupervised continuous representation framework for CI reconstruction. GridTD optimizes a lightweight neural network and the input tensor decomposition model whose parameters are learned via multi-resolution hash grid encoding. It inherently enjoys the hierarchical modeling ability of multi-resolution grid encoding and the compactness of tensor decomposition, enabling effective and efficient reconstruction of high-dimensional images. Theoretical analyses for the algorithm's Lipschitz property, generalization error bound, and fixed-point convergence reveal the intrinsic superiority of GridTD as compared with existing continuous representation models. Extensive experiments across diverse CI tasks, including video SCI, spectral SCI, and compressive dynamic MRI reconstruction, consistently demonstrate the superiority of GridTD over existing methods, positioning GridTD as a versatile and state-of-the-art CI reconstruction method.
Related papers
- Mixed-granularity Implicit Representation for Continuous Hyperspectral Compressive Reconstruction [16.975538181162616]
This study introduces a novel method using implicit neural representation for continuous hyperspectral image reconstruction.<n>By leveraging implicit neural representations, the MGIR framework enables reconstruction at any desired spatial-spectral resolution.
arXiv Detail & Related papers (2025-03-17T03:37:42Z) - Graph Image Prior for Unsupervised Dynamic Cardiac Cine MRI Reconstruction [10.330083869344445]
We propose a novel scheme for dynamic MRI representation, named Graph Image Prior'' (GIP)
GIP adopts a two-stage generative network in a new modeling methodology, which first employs independent CNNs to recover the image structure for each frame.
A graph convolutional network is utilized for feature fusion and image generation.
arXiv Detail & Related papers (2024-03-23T08:57:46Z) - MsDC-DEQ-Net: Deep Equilibrium Model (DEQ) with Multi-scale Dilated
Convolution for Image Compressive Sensing (CS) [0.0]
Compressive sensing (CS) is a technique that enables the recovery of sparse signals using fewer measurements than traditional sampling methods.
We develop an interpretable and concise neural network model for reconstructing natural images using CS.
The model, called MsDC-DEQ-Net, exhibits competitive performance compared to state-of-the-art network-based methods.
arXiv Detail & Related papers (2024-01-05T16:25:58Z) - Latent Diffusion Prior Enhanced Deep Unfolding for Snapshot Spectral Compressive Imaging [17.511583657111792]
Snapshot spectral imaging reconstruction aims to reconstruct three-dimensional spatial-spectral images from a single-shot two-dimensional compressed measurement.
We introduce a generative model, namely the latent diffusion model (LDM), to generate degradation-free prior to deep unfolding method.
arXiv Detail & Related papers (2023-11-24T04:55:20Z) - Rank-Enhanced Low-Dimensional Convolution Set for Hyperspectral Image
Denoising [50.039949798156826]
This paper tackles the challenging problem of hyperspectral (HS) image denoising.
We propose rank-enhanced low-dimensional convolution set (Re-ConvSet)
We then incorporate Re-ConvSet into the widely-used U-Net architecture to construct an HS image denoising method.
arXiv Detail & Related papers (2022-07-09T13:35:12Z) - Transformer-empowered Multi-scale Contextual Matching and Aggregation
for Multi-contrast MRI Super-resolution [55.52779466954026]
Multi-contrast super-resolution (SR) reconstruction is promising to yield SR images with higher quality.
Existing methods lack effective mechanisms to match and fuse these features for better reconstruction.
We propose a novel network to address these problems by developing a set of innovative Transformer-empowered multi-scale contextual matching and aggregation techniques.
arXiv Detail & Related papers (2022-03-26T01:42:59Z) - Multi-Channel Convolutional Analysis Operator Learning for Dual-Energy
CT Reconstruction [108.06731611196291]
We develop a multi-channel convolutional analysis operator learning (MCAOL) method to exploit common spatial features within attenuation images at different energies.
We propose an optimization method which jointly reconstructs the attenuation images at low and high energies with a mixed norm regularization on the sparse features.
arXiv Detail & Related papers (2022-03-10T14:22:54Z) - Spectral Compressive Imaging Reconstruction Using Convolution and
Contextual Transformer [6.929652454131988]
We propose a hybrid network module, namely CCoT (Contextual Transformer) block, which can acquire the inductive bias ability of transformer simultaneously.
We integrate the proposed CCoT block into deep unfolding framework based on the generalized alternating projection algorithm, and further propose the GAP-CT network.
arXiv Detail & Related papers (2022-01-15T06:30:03Z) - Adaptive Gradient Balancing for UndersampledMRI Reconstruction and
Image-to-Image Translation [60.663499381212425]
We enhance the image quality by using a Wasserstein Generative Adversarial Network combined with a novel Adaptive Gradient Balancing technique.
In MRI, our method minimizes artifacts, while maintaining a high-quality reconstruction that produces sharper images than other techniques.
arXiv Detail & Related papers (2021-04-05T13:05:22Z) - Limited-angle tomographic reconstruction of dense layered objects by
dynamical machine learning [68.9515120904028]
Limited-angle tomography of strongly scattering quasi-transparent objects is a challenging, highly ill-posed problem.
Regularizing priors are necessary to reduce artifacts by improving the condition of such problems.
We devised a recurrent neural network (RNN) architecture with a novel split-convolutional gated recurrent unit (SC-GRU) as the building block.
arXiv Detail & Related papers (2020-07-21T11:48:22Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.