Coordinate-based Neural Network for Fourier Phase Retrieval
- URL: http://arxiv.org/abs/2311.14925v2
- Date: Mon, 8 Jan 2024 07:30:22 GMT
- Title: Coordinate-based Neural Network for Fourier Phase Retrieval
- Authors: Tingyou Li, Zixin Xu, Yong S. Chu, Xiaojing Huang, Jizhou Li
- Abstract summary: Single impliCit neurAl Network (SCAN) is a tool built upon coordinate neural networks meticulously designed for enhanced phase retrieval performance.
SCAN adeptly connects object coordinates to their amplitude and phase within a unified network in an unsupervised manner.
- Score: 8.827173113748703
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Fourier phase retrieval is essential for high-definition imaging of nanoscale
structures across diverse fields, notably coherent diffraction imaging. This
study presents the Single impliCit neurAl Network (SCAN), a tool built upon
coordinate neural networks meticulously designed for enhanced phase retrieval
performance. Remedying the drawbacks of conventional iterative methods which
are easiliy trapped into local minimum solutions and sensitive to noise, SCAN
adeptly connects object coordinates to their amplitude and phase within a
unified network in an unsupervised manner. While many existing methods
primarily use Fourier magnitude in their loss function, our approach
incorporates both the predicted magnitude and phase, enhancing retrieval
accuracy. Comprehensive tests validate SCAN's superiority over traditional and
other deep learning models regarding accuracy and noise robustness. We also
demonstrate that SCAN excels in the ptychography setting.
Related papers
- Meta-Exploiting Frequency Prior for Cross-Domain Few-Shot Learning [86.99944014645322]
We introduce a novel framework, Meta-Exploiting Frequency Prior for Cross-Domain Few-Shot Learning.
We decompose each query image into its high-frequency and low-frequency components, and parallel incorporate them into the feature embedding network.
Our framework establishes new state-of-the-art results on multiple cross-domain few-shot learning benchmarks.
arXiv Detail & Related papers (2024-11-03T04:02:35Z) - Hybrid Convolutional and Attention Network for Hyperspectral Image Denoising [54.110544509099526]
Hyperspectral image (HSI) denoising is critical for the effective analysis and interpretation of hyperspectral data.
We propose a hybrid convolution and attention network (HCANet) to enhance HSI denoising.
Experimental results on mainstream HSI datasets demonstrate the rationality and effectiveness of the proposed HCANet.
arXiv Detail & Related papers (2024-03-15T07:18:43Z) - PRISTA-Net: Deep Iterative Shrinkage Thresholding Network for Coded
Diffraction Patterns Phase Retrieval [6.982256124089]
Phase retrieval is a challenge nonlinear inverse problem in computational imaging and image processing.
We have developed PRISTA-Net, a deep unfolding network based on the first-order iterative threshold threshold algorithm (ISTA)
All parameters in the proposed PRISTA-Net framework, including the nonlinear transformation, threshold, and step size, are learned-to-end instead of being set.
arXiv Detail & Related papers (2023-09-08T07:37:15Z) - Untrained neural network embedded Fourier phase retrieval from few
measurements [8.914156789222266]
This paper proposes an untrained neural network embedded algorithm to solve FPR with few measurements.
We use a generative network to represent the image to be recovered, which confines the image to the space defined by the network structure.
To reduce the computational cost mainly caused by the parameter updates of the untrained NN, we develop an accelerated algorithm that adaptively trades off between explicit and implicit regularization.
arXiv Detail & Related papers (2023-07-16T16:23:50Z) - Degradation-Noise-Aware Deep Unfolding Transformer for Hyperspectral
Image Denoising [9.119226249676501]
Hyperspectral images (HSIs) are often quite noisy because of narrow band spectral filtering.
To reduce the noise in HSI data cubes, both model-driven and learning-based denoising algorithms have been proposed.
This paper proposes a Degradation-Noise-Aware Unfolding Network (DNA-Net) that addresses these issues.
arXiv Detail & Related papers (2023-05-06T13:28:20Z) - NAF: Neural Attenuation Fields for Sparse-View CBCT Reconstruction [79.13750275141139]
This paper proposes a novel and fast self-supervised solution for sparse-view CBCT reconstruction.
The desired attenuation coefficients are represented as a continuous function of 3D spatial coordinates, parameterized by a fully-connected deep neural network.
A learning-based encoder entailing hash coding is adopted to help the network capture high-frequency details.
arXiv Detail & Related papers (2022-09-29T04:06:00Z) - LWGNet: Learned Wirtinger Gradients for Fourier Ptychographic Phase
Retrieval [14.588976801396576]
We propose a hybrid model-driven residual network that combines the knowledge of the forward imaging system with a deep data-driven network.
Unlike other conventional unrolling techniques, LWGNet uses fewer stages while performing at par or even better than existing traditional and deep learning techniques.
This improvement in performance for low-bit depth and low-cost sensors has the potential to bring down the cost of FPM imaging setup significantly.
arXiv Detail & Related papers (2022-08-08T17:22:54Z) - SignalNet: A Low Resolution Sinusoid Decomposition and Estimation
Network [79.04274563889548]
We propose SignalNet, a neural network architecture that detects the number of sinusoids and estimates their parameters from quantized in-phase and quadrature samples.
We introduce a worst-case learning threshold for comparing the results of our network relative to the underlying data distributions.
In simulation, we find that our algorithm is always able to surpass the threshold for three-bit data but often cannot exceed the threshold for one-bit data.
arXiv Detail & Related papers (2021-06-10T04:21:20Z) - Learning Frequency-aware Dynamic Network for Efficient Super-Resolution [56.98668484450857]
This paper explores a novel frequency-aware dynamic network for dividing the input into multiple parts according to its coefficients in the discrete cosine transform (DCT) domain.
In practice, the high-frequency part will be processed using expensive operations and the lower-frequency part is assigned with cheap operations to relieve the computation burden.
Experiments conducted on benchmark SISR models and datasets show that the frequency-aware dynamic network can be employed for various SISR neural architectures.
arXiv Detail & Related papers (2021-03-15T12:54:26Z) - Learning Frequency Domain Approximation for Binary Neural Networks [68.79904499480025]
We propose to estimate the gradient of sign function in the Fourier frequency domain using the combination of sine functions for training BNNs.
The experiments on several benchmark datasets and neural architectures illustrate that the binary network learned using our method achieves the state-of-the-art accuracy.
arXiv Detail & Related papers (2021-03-01T08:25:26Z) - DeepPhaseCut: Deep Relaxation in Phase for Unsupervised Fourier Phase
Retrieval [31.380061715549584]
We propose a novel, unsupervised, feed-forward neural network for Fourier phase retrieval.
Unlike the existing deep learning approaches that use a neural network as a regularization term or an end-to-end blackbox model for supervised training, our algorithm is a feed-forward neural network implementation of PhaseCut algorithm in an unsupervised learning framework.
Our network is composed of two generators: one for the phase estimation using PhaseCut loss, followed by another generator for image reconstruction, all of which are trained simultaneously using a cycleGAN framework without matched data.
arXiv Detail & Related papers (2020-11-20T16:10:08Z)
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.