Search

Your search keyword '"Wang, Renfang"' showing total 167 results
Start Over Author "Wang, Renfang"
167 results on '"Wang, Renfang"'

1. Low-Dose CT Reconstruction Using Dataset-free Learning

Author

Wang, Feng, Wang, Renfang, and Qiu, Hong

Subjects
Electrical Engineering and Systems Science - Image and Video Processing, Physics - Medical Physics
Abstract

Low-Dose computer tomography (LDCT) is an ideal alternative to reduce radiation risk in clinical applications. Although supervised-deep-learning-based reconstruction methods have demonstrated superior performance compared to conventional model-driven reconstruction algorithms, they require collecting massive pairs of low-dose and norm-dose CT images for neural network training, which limits their practical application in LDCT imaging. In this paper, we propose an unsupervised and training data-free learning reconstruction method for LDCT imaging that avoids the requirement for training data. The proposed method is a post-processing technique that aims to enhance the initial low-quality reconstruction results, and it reconstructs the high-quality images by neural work training that minimizes the $\ell_1$-norm distance between the CT measurements and their corresponding simulated sinogram data, as well as the total variation (TV) value of the reconstructed image. Moreover, the proposed method does not require to set the weights for both the data fidelity term and the plenty term. Experimental results on the AAPM challenge data and LoDoPab-CT data demonstrate that the proposed method is able to effectively suppress the noise and preserve the tiny structures. Also, these results demonstrate the rapid convergence and low computational cost of the proposed method. The source code is available at \url{https://github.com/linfengyu77/IRLDCT}.

Published
2024

2. Seismic Traveltime Tomography with Label-free Learning

Author

Wang, Feng, Yang, Bo, Wang, Renfang, and Qiu, Hong

Subjects
Physics - Geophysics, Computer Science - Machine Learning
Abstract

Deep learning techniques have been used to build velocity models (VMs) for seismic traveltime tomography and have shown encouraging performance in recent years. However, they need to generate labeled samples (i.e., pairs of input and label) to train the deep neural network (NN) with end-to-end learning, and the real labels for field data inversion are usually missing or very expensive. Some traditional tomographic methods can be implemented quickly, but their effectiveness is often limited by prior assumptions. To avoid generating and/or collecting labeled samples, we propose a novel method by integrating deep learning and dictionary learning to enhance the VMs with low resolution by using the traditional tomography-least square method (LSQR). We first design a type of shallow and simple NN to reduce computational cost followed by proposing a two-step strategy to enhance the VMs with low resolution: (1) Warming up. An initial dictionary is trained from the estimation by LSQR through dictionary learning method; (2) Dictionary optimization. The initial dictionary obtained in the warming-up step will be optimized by the NN, and then it will be used to reconstruct high-resolution VMs with the reference slowness and the estimation by LSQR. Furthermore, we design a loss function to minimize traveltime misfit to ensure that NN training is label-free, and the optimized dictionary can be obtained after each epoch of NN training. We demonstrate the effectiveness of the proposed method through the numerical tests on both synthetic and field data., Comment: Accepted by IEEE TGRS

Published
2024

3. A Latent Fingerprint in the Wild Database

Author

Liu, Xinwei, Raja, Kiran, Wang, Renfang, Qiu, Hong, Wu, Hucheng, Sun, Dechao, Zheng, Qiguang, Liu, Nian, Wang, Xiaoxia, Huang, Gehang, Ramachandra, Raghavendra, and Busch, Christoph

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

Latent fingerprints are among the most important and widely used evidence in crime scenes, digital forensics and law enforcement worldwide. Despite the number of advancements reported in recent works, we note that significant open issues such as independent benchmarking and lack of large-scale evaluation databases for improving the algorithms are inadequately addressed. The available databases are mostly of semi-public nature, lack of acquisition in the wild environment, and post-processing pipelines. Moreover, they do not represent a realistic capture scenario similar to real crime scenes, to benchmark the robustness of the algorithms. Further, existing databases for latent fingerprint recognition do not have a large number of unique subjects/fingerprint instances or do not provide ground truth/reference fingerprint images to conduct a cross-comparison against the latent. In this paper, we introduce a new wild large-scale latent fingerprint database that includes five different acquisition scenarios: reference fingerprints from (1) optical and (2) capacitive sensors, (3) smartphone fingerprints, latent fingerprints captured from (4) wall surface, (5) Ipad surface, and (6) aluminium foil surface. The new database consists of 1,318 unique fingerprint instances captured in all above mentioned settings. A total of 2,636 reference fingerprints from optical and capacitive sensors, 1,318 fingerphotos from smartphones, and 9,224 latent fingerprints from each of the 132 subjects were provided in this work. The dataset is constructed considering various age groups, equal representations of genders and backgrounds. In addition, we provide an extensive set of analysis of various subset evaluations to highlight open challenges for future directions in latent fingerprint recognition research., Comment: Submitted to IEEE Transactions on Information Forensics and Security (under review)

Published
2023

4. Adaptive Divergence-based Non-negative Latent Factor Analysis

Author

Yuan, Ye, Yuan, Guangxiao, Wang, Renfang, and Luo, Xin

Subjects
Computer Science - Machine Learning
Abstract

High-Dimensional and Incomplete (HDI) data are frequently found in various industrial applications with complex interactions among numerous nodes, which are commonly non-negative for representing the inherent non-negativity of node interactions. A Non-negative Latent Factor (NLF) model is able to extract intrinsic features from such data efficiently. However, existing NLF models all adopt a static divergence metric like Euclidean distance or {\alpha}-\b{eta} divergence to build its learning objective, which greatly restricts its scalability of accurately representing HDI data from different domains. Aiming at addressing this issue, this study presents an Adaptive Divergence-based Non-negative Latent Factor (ADNLF) model with three-fold ideas: a) generalizing the objective function with the {\alpha}-\b{eta}-divergence to expand its potential of representing various HDI data; b) adopting a non-negative bridging function to connect the optimization variables with output latent factors for fulfilling the non-negativity constraints constantly; and c) making the divergence parameters adaptive through particle swarm optimization, thereby facilitating adaptive divergence in the learning objective to achieve high scalability. Empirical studies are conducted on four HDI datasets from real applications, whose results demonstrate that in comparison with state-of-the-art NLF models, an ADNLF model achieves significantly higher estimation accuracy for missing data of an HDI dataset with high computational efficiency.

Published
2022

26. Hybrid Lossless-Lossy Compression for Real-Time Depth-Sensor Streams in 3D Telepresence Applications

Author

Liu, Yunpeng, Beck, Stephan, Wang, Renfang, Li, Jin, Xu, Huixia, Yao, Shijie, Tong, Xiaopeng, Froehlich, Bernd, Hutchison, David, Series editor, Kanade, Takeo, Series editor, Kittler, Josef, Series editor, Kleinberg, Jon M., Series editor, Mattern, Friedemann, Series editor, Mitchell, John C., Series editor, Naor, Moni, Series editor, Pandu Rangan, C., Series editor, Steffen, Bernhard, Series editor, Terzopoulos, Demetri, Series editor, Tygar, Doug, Series editor, Weikum, Gerhard, Series editor, Ho, Yo-Sung, editor, Sang, Jitao, editor, Ro, Yong Man, editor, Kim, Junmo, editor, and Wu, Fei, editor

Published
2015
Full Text
View/download PDF

28. A Difference Enhanced Neural Network for Semantic Change Detection of Remote Sensing Images

Author

Wang, Renfang, Wu, Hucheng, Qiu, Hong, Liu, Xiufeng, Wang, Feng, Cheng, Xu, Wang, Renfang, Wu, Hucheng, Qiu, Hong, Liu, Xiufeng, Wang, Feng, and Cheng, Xu

Abstract

Change detection (CD) is to obtain the changed objects by joint analysis of two (or more) remote sensing images (RSIs) that obtained in the same area and at different times [1], [2], [3], and it has been applied to various kinds of real-world applications including land and resource survey, environmental monitoring, and urban management [4], [5]. Deep learning is a type of powerful numerical tools for extracting features and has been very popular in the community of CD. Zhang and Lu [6] proposed a spectral–spatial joint learning network using a Siamese convolutional neural network (CNN) to extract a dual-temporal spectral–spatial joint representation. To address the lack of resilience to pseudovariation information, Chen et al. [1] introduced a dual-attentive fully convolutional Siamese neural network (DASNet) that employs weighted double marginal contrast loss (WDMC) to solve the sample imbalance issue. Chen et al. [7] and Dong et al. [8] proposed to improve the capacity to describe contextual information in the network with a dual-time spatial and temporal domain-based Transformer. Although binary CD (BCD) can provide the information about the location and the geometry of changes, the information is usual coarse-grained, and it cannot describe the types of changes. On the contrary, semantic CD (SCD) approaches can provide the location and the geometry of changes as well as the types of changes. Yang et al. [9], Ding et al. [10], and Mou et al. [11] introduced a triple-branch CD paradigm in which two semantic segmentation branches divide the dual-temporal pictures into land cover and land use (LCLU) mappings, respectively, and the third one is used to identify the changes. Yang et al. [9] developed an asymmetric Siamese network (ASN) for locating and identifying semantic changes by incorporating gating and weighting schemes into the decoder. Ding et al. [10] discussed the possible network architecture for SCD and demonstrated that the late fusion

Published
2023

30. ORSI Salient Object Detection via Progressive Semantic Flow and Uncertainty-Aware Refinement

Author

Quan, Yueqian, Xu, Honghui, Wang, Renfang, Guan, Qiu, and Zheng, Jianwei

Abstract

With the prosperity of deep learning (DL) techniques, salient object detection in remote sensing images (RSI-SOD) is concomitantly in full flourishing. However, due to the inherent challenges such as uncertainty in object quantities and scales, cluttered backgrounds, and blurred edges arising from shadows, most current approaches struggle for salient feature learning with the aid of heavy model architecture, yet often result in barely satisfactory performance. Some methods compromise model complexity to improve efficiency, albeit with significantly degraded results. To earn a satisfactory balance of efficacy and efficiency, we propose a new network for RSI-SOD, namely semantic flow and uncertainty-aware refinement network (SFANet), based on progressive semantic flow and uncertainty-aware refinement. Specifically, we design a global semantic enhancement block (GSEB) to reduce background interference and accurately localize salient objects of varying quantities and scales, which further consists of three modularized components, i.e., semantic extraction module (SEM), interscale fusion module (IFM), and deep semantic graph-inference module (DSGM). SEM together with IFM contributes to the effective aggregation of multiscale contexts by extracting fused and progressive semantic cues. DSGM performs semantic inference to better localize salient objects with irregularities in scale and topological structure. Furthermore, we present an uncertainty-aware refinement module (URM) to recognize salient objects in cluttered backgrounds and effectively suppress shadows. Extensive experiments are conducted on three RSI-SOD datasets, from which superior results can be achieved by our SFANet, outperforming the other cutting-edge methods. The code is available at https://github.com/ZhengJianwei2/SFANet.

Published
2024
Full Text
View/download PDF

40. An Adaptive Divergence-Based Non-Negative Latent Factor Model

Author

Yuan, Ye, Wang, Renfang, Yuan, Guangxiao, and Xin, Luo

Abstract

A High-dimensional and incomplete (HDI) matrix is regularly adopted to portray the inherent non-negativity of interactions among numerous nodes, which is involved in countless industrial applications driven by big data. An inherently non-negative latent factor (LF) model can take out the intrinsical features from such data conveniently and effectually due to its unimpeded training process. However, it constructs the learning objective relying on a standard Euclidean distance, thereby seriously restricting its representative ability to HDI data generated by different domains. To address this issue, this work proposes an adaptive divergence-based non-negative LF (ADNLF) model following: 1) constructing a generalized objective function based on $\alpha - \beta $ -divergence to inflate its ability to represent various HDI data; 2) connecting the optimization variables with output LFs by a smooth and single LF-dependent bridging function to satisfy the non-negativity constraints constantly; and 3) facilitating adaptive divergence in the learning objective through particle swarm optimization for high scalability. Empirical studies on eight HDI matrices validate that an ADNLF model evidently outstrips state-of-the-art models in terms of estimation accuracy as well as computational efficiency for missing data of an HDI dataset.

Published
2023
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results