DR2-Net: Deep Residual Reconstruction Network for image compressive sensing

Yao, Hantao; Dai, Feng; Zhang, Shiliang; Zhang, Yongdong; Tian, Qi; Xu, Changsheng

doi:10.1016/j.neucom.2019.05.006

Cited by 264 publications

(201 citation statements)

References 35 publications

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“…In [17], [34], the RefineNet block is directly used as the last layer. However, in CsiNet, a convolutional layer follows the last RefineNet block, thereby disturbing the refinement.…”

Section: ) Modificationmentioning

confidence: 99%

“…Training the entire neural network DR 2 -Net in [17] is conducted in two steps. First, the encoder and the first FC layer at the decoder are trained using a large learning rate to obtain a preliminary reconstructed image.…”

Section: ) Modificationmentioning

confidence: 99%

“…From [17], it is a good strategy to generate a preliminary reconstruction at the decoder via a linear mapping network and then use a residual network to refine estimates. In [18], the random Gaussian measurement matrix is replaced by a learned measurement matrix at the encoder.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Convolutional Neural Network-Based Multiple-Rate Compressive Sensing for Massive MIMO CSI Feedback: Design, Simulation, and Analysis

Guo

Wen

Jin

et al. 2020

IEEE Trans. Wireless Commun.

269

178

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Massive multiple-input multiple-output (MIMO) is a promising technology to increase link capacity and energy efficiency. However, these benefits are based on available channel state information (CSI) at the base station (BS). Therefore, user equipment (UE) needs to keep on feeding CSI back to the BS, thereby consuming precious bandwidth resource. Large-scale antennas at the BS for massive MIMO seriously increase this overhead. In this paper, we propose a multiple-rate compressive sensing neural network framework to compress and quantize the CSI. This framework not only improves reconstruction accuracy but also decreases storage space at the UE, thus enhancing the system feasibility. Specifically, we establish two network design principles for CSI feedback, propose a new network architecture, CsiNet+, according to these principles, and develop a novel quantization framework and training strategy.Next, we further introduce two different variable-rate approaches, namely, SM-CsiNet+ and PM-CsiNet+, which decrease the parameter number at the UE by 38.0% and 46.7%, respectively. Experimental results show that CsiNet+ outperforms the state-of-the-art network by a margin but only slightly increases the parameter number. We also investigate the compression and reconstruction mechanism behind deep learning-based CSI feedback methods via parameter visualization, which provides a guideline for subsequent research.

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“…In [17], [34], the RefineNet block is directly used as the last layer. However, in CsiNet, a convolutional layer follows the last RefineNet block, thereby disturbing the refinement.…”

Section: ) Modificationmentioning

confidence: 99%

Section: ) Modificationmentioning

confidence: 99%

See 1 more Smart Citation

Convolutional Neural Network-Based Multiple-Rate Compressive Sensing for Massive MIMO CSI Feedback: Design, Simulation, and Analysis

Guo

Wen

Jin

et al. 2020

IEEE Trans. Wireless Commun.

269

178

View full text Add to dashboard Cite

show abstract

“…We first provide relevant literatures in solving inverse problems from other domains. In particular, we focus on deep neural network related techniques [1,14,19,49,50,55]. In general, those different deep-learning based methods for solving inverse problems can be categorized into four types [29]: 1) to learn an end-to-end regression with vanilla convolutional neural network (CNN), 2) to learn higher-level representation, 3) to gradual refinement of inversion procedure, and 4) to incorporate with analytical methods and to learn a denoiser.…”

Section: A Data-driven Inverse Problemsmentioning

confidence: 99%

Data-Driven Seismic Waveform Inversion: A Study on the Robustness and Generalization

Zhang

Lin

2020

IEEE Trans. Geosci. Remote Sensing

101

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Acoustic-and elastic-waveform inversion is an important and widely used method to reconstruct subsurface velocity image. Waveform inversion is a typical non-linear and ill-posed inverse problem. Existing physics-driven computational methods for solving waveform inversion suffer from the cycle skipping and local minima issues, and not to mention solving waveform inversion is computationally expensive. In recent years, data-driven methods become a promising way to solve the waveform inversion problem. However, most deep learning frameworks suffer from generalization and over-fitting issue. In this paper, we developed a real-time data-driven technique and we call it VelocityGAN, to accurately reconstruct subsurface velocities. Our VelocityGAN is built on a generative adversarial network (GAN) and trained end-to-end to learn a mapping function from the raw seismic waveform data to the velocity image. Different from other encoder-decoder based data-driven seismic waveform inversion approaches, our VelocityGAN learns regularization from data and further impose the regularization to the generator so that inversion accuracy is improved. We further develop a transfer learning strategy based on VelocityGAN to alleviate the generalization issue. A series of experiments are conducted on the synthetic seismic reflection data to evaluate the effectiveness, efficiency, and generalization of VelocityGAN. We not only compare it with existing physics-driven approaches and data-driven frameworks but also conduct several transfer learning experiments. The experiment results show that VelocityGAN achieves state-of-the-art performance among the baselines and can improve the generalization results to some extent.

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“…Since the linear projection of CS represented by = Φ can be understood as a fully connected layer having an identity activation and without bias [11], the fully connected layer shares the same practical problem of high signal dimensionality as the conventional frame-based compressed sensing. As a result, most research on DL-based CS (DCS) has focused on block-based schemes [11][12][13][14] and relied mostly on the learned prior from big data. Recently, multi-scale prior has been applied in image reconstruction as can be seen in the layer-wise wavelet network in [15], or multiwavelet convolutional network (MWCNN) [10] which greatly improves the restoration performance.…”

mentioning

confidence: 99%

Multi-Scale Deep Compressive Sensing Network

Canh

2018

2018 IEEE Visual Communications and Image Processing (VCIP)

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With joint learning of sampling and recovery, the deep learning-based compressive sensing (DCS) has shown significant improvement in performance and running time reduction. Its reconstructed image, however, losses highfrequency content especially at low subrates. This happens similarly in the multi-scale sampling scheme which also samples more low-frequency components. In this paper, we propose a multi-scale DCS convolutional neural network (MS-DCSNet) in which we convert image signal using multiple scale-based wavelet transform, then capture it through convolution block by block across scales. The initial reconstructed image is directly recovered from multi-scale measurements. Multi-scale wavelet convolution is utilized to enhance the final reconstruction quality. The network is able to learn both multi-scale sampling and multi-scale reconstruction, thus results in better reconstruction quality.

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DR2-Net: Deep Residual Reconstruction Network for image compressive sensing

Cited by 264 publications

References 35 publications

Convolutional Neural Network-Based Multiple-Rate Compressive Sensing for Massive MIMO CSI Feedback: Design, Simulation, and Analysis

Convolutional Neural Network-Based Multiple-Rate Compressive Sensing for Massive MIMO CSI Feedback: Design, Simulation, and Analysis

Data-Driven Seismic Waveform Inversion: A Study on the Robustness and Generalization

Multi-Scale Deep Compressive Sensing Network

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