Your search keyword '"WANG Yifan"' showing total 5,015 results

1. Effects of Water and Root Separation on Nitrogen Uptake, Utilization and Transfer in a Gramineae-Legume Intercropping System

Author

WANG Yifan, LIU Huaqing, ZHAO Xining, and GAO Xiaodong

Subjects

gramineae-legume intercropping, root separation, water treatment, nitrogen utilization, nitrogen transfer efficiency, Environmental sciences, GE1-350, Agriculture

Abstract

[Objective] Gramineae-legume intercropping can give consideration to production and ecological benefits, improve nitrogen use efficiency and reduce nitrogen pollution. At present, the process of nitrogen utilization, absorption and transfer distribution in gramineae-legume intercropping systems under different water conditions is not clear. [Methods] The above ground biomass, nitrogen absorption and utilization, nitrogen fixation rate, and nitrogen transfer rate of gramineae-legume intercropping were studied by using water treatment with the same total water amount in 2 periods but with an interval of 3 or 5 days, combined with root separation (non-separation, nylon mesh separation and plastic plate separation) and nitrogen isotope labeling methods. [Results] The aboveground biomass, nitrogen content and nitrogen accumulation of E. dahuricus intercropped with alfalfa were significantly increased compared with monoculture E. dahuricus, while, for alfalfa, the intercropping with E. dahuricus resulted in a decrease compared to monoculture alfalfa. Under the condition of the same total water amount, the above-ground biomass of the herbage increased by 6.28% and 17.32%, respectively, by high-frequency water treatment compared with medium and low frequency water treatments, and the nitrogen fixation rate of alfalfa was increased by 39.82% and 44.81%, respectively, under high-frequency water treatment compared with medium and low frequency water treatments. However, the nitrogen concentration and nitrogen accumulation under some middle and low frequency water treatments were significantly higher than those under high frequency water treatment (p < 0.05), and promoted nitrogen transfer. Root separation weakened the interaction between grass and bean, and showed that as root separation increased the aboveground biomass, nitrogen concent and aboveground nitrogen accumulation of intercropping alfalfa, and decreased the corresponding indexes of intercropping E. dahuricus. The nitrogen fixation and nitrogen transfer rate of alfalfa intercropping were in the order of no separation > nylon mesh separation > plastic plate separation. [Conclusion] Moderate water regulation can improve the advantages of gramineae-legume intercropping, and root interaction is the key to promote the biological nitrogen fixation and nitrogen transfer of legume herbage.

Published

2024

2. A review of gallium phosphide nanophotonics towards omnipotent nonlinear devices

Author

Wang Yifan, Pan Ziyu, Yan Yongxian, Yang Yatao, Zhao Wenhua, Ding Ning, Tang Xingyu, Wu Pengzhuo, Zhao Qiancheng, and Li Yi

Subjects

gallium phosphide, nonlinear optics, optical devices, nano-optics, integrated photonics, Physics, QC1-999

Abstract

Gallium phosphide (GaP) has been increasingly prioritized, fueled by the enormous demands in visible light applications such as biomedical and quantum technologies. GaP has garnered tremendous attention in nanophotonics thanks to its high refractive index, indirect bandgap width of 2.26 eV, lattice perfectly matched with silicon, and omnipotent and competitive nonlinear optical properties. Herein, we review the progress and application of GaP in nanoscale devices over the past two decades. The material properties of bulk GaP are first listed, followed by a summary of the methodologies for fabricating nanoscale devices and related integration techniques. Then, we digest the operational mechanisms across different GaP-based devices on their optical linear responses. Following this, we categorize the GaP nonlinear optical effects into multiple aspects including second-harmonic generation, four-wave mixing, Kerr optical frequency combs, etc. Ultimately, we present a perspective on GaP nanophotonics in the context of coexisting and competing modes of various nonlinear effects. We believe that a comprehensive overview of unique GaP will propel these nanophotonic devices toward a mature state, underpinning foundational understanding and leveraging practical innovations.

Published

2024

3. Path planning of coal mine underground robot based on improved artificial potential field algorithm

Author

XUE Guanghui, WANG Zijie, WANG Yifan, LI Yanan, and LIU Wenhai

Subjects

coal mine robots, path planning, artificial potential field method, target unreachable, path oscillation, correction of repulsive potential field, corner restriction coefficient, Mining engineering. Metallurgy, TN1-997

Abstract

Path planning is one of the key technologies that urgently need to be solved in the application of coal mine robots in narrow underground roadways. A path planning method for coal mine robots based on improved APF algorithm is proposed to address the issues of traditional artificial potential field (APF) algorithms that planning paths in narrow roadway environments may be too close to the roadway boundary, as well as the possibility of unreachable targets and path oscillations near obstacles. Referring to the relevant provisions of the Coal Mine Safety Regulations, the boundary potential field between the two sides of the roadway is established. The robot's path is planned as much as possible in the middle of the roadway to improve the safety of robot travel. The method introduces regulatory factors into the repulsive potential field of obstacles to solve the problem of unreachable targets. The method introduces corner constraint coefficients to smooth the planned path, reduce oscillations, improve planning efficiency, and ensure the safety of the planned path. The simulation results show that when the target point is very close to the obstacle, the improved APF algorithm can successfully plan a path that can reach the target point. The improved APF algorithm reduces the planning cycle by an average of 14.48% compared to traditional algorithms. The cumulative value of steering angle reduces by an average of 87.41%, and the sum of absolute curvature values is reduced by an average of 78.09%. The results indicate that the improved APF algorithm plans smoother paths, shorter path lengths, and has higher planning efficiency and safety.

Published

2024

4. Numerical simulation of ductile crack propagation velocity in CO2 pipeline

Author

FU Yaru, ZHANG Dong, YAN Feng, WANG Yifan, BAI Fang, ZHANG Hong, and LIU Xiaoben

Subjects

supercritical co2 pipeline, crack propagation, cohesive zone model(czm), crack arrest pressure, Oils, fats, and waxes, TP670-699, Gas industry, TP751-762

Abstract

[Objective] Carbon Capture, Utilization, and Storage(CCUS) technology is recognized as a crucial technology for strategically reducing CO2 emissions. Supercritical CO2 pipeline transmission represents the most cost-effective method to connect carbon capture with carbon storage. Due to the decompression wave characteristics of supercritical CO2 and the Joule-Thomson effect of CO2, CO2 pipelines are susceptible to long-distance crack propagation following fractures, posing a threat to the safety of pipeline operation. [Methods] Instrumented impact experiments were conducted, using transverse specimens from the base metal of L360M pipes, to investigate the crack propagation mechanism of supercritical CO2 pipelines. Following that, a numerical simulation model was established and the Cohesive Zone Model(CZM) was utilized to describe material damage. By comparing curves from the experiments and simulations, parameters were calibrated for the CZM, leading to the development of a finite element model for crack propagation in supercritical CO2 pipelines. Simulations were performed after inputting the calibrated CZM parameters into the finite element model, to explore the effects of internal pressure, wall thickness, and pipe diameter on the crack propagation velocity. [Results] The CZM effectively simulated the dynamic progression of crack propagation, and the simulation results exhibited an overall trend consistent with the experimental results. The CZM parameters calibrated and verified through comparison with experimental results proved effective in numerically simulating crack propagation within the pipeline model. In supercritical CO2pipelines, the crack propagation velocity increased with higher internal pressure, larger pipe diameter, and lower wall thickness.[Conclusion] Crack arrest pressures corresponding to different pipe diameters and wall thicknesses and the minimum wall thickness suitable for a pipe diameter of 323 mm were identified for supercritical CO2 pipelines through calculations based on the above results.The research outcomes lay a theoretical groundwork for understanding crack arrest in supercritical CO2 pipelines and offer practical engineering applications with a useful reference point.

Published

2024

5. Detection method of false data injection attack based on unsupervised and supervised learning

Author

HUANG Dongmei, WANG Yifan, HU Anduo, ZHOU You, SHI Shuai, and HU Wei

Subjects

false data injection attack(fdia), supervised learning, unsupervised learning, contrastive learning, data expansion, feature enhancement, Applications of electric power, TK4001-4102

Abstract

False data injection attack (FDIA) is a serious threat to the security and stable operation of smart grids. In this paper, a FDIA detection algorithm that combines unsupervised and supervised learning is proposed, solving the problems of scarce labeled data and extremely imbalanced normal and attack samples. Firstly, contrastive learning is introduced to capture the features of a small amount of attack data, and it generates new attack samples to achieve data augmentation. Then, various unsupervised detection algorithms are used to perform feature self-learning on a large number of unlabeled samples, addressing the problem of scarce labeled samples. Finally, the features extracted by the unsupervised algorithm are fused with the historical feature set, and a supervised XGBoost classifier is constructed to identify and output the detection results. The results on the IEEE 30-node system show that the proposed method can enhance the stability of the FDIA detection model under scarce labeled samples and imbalanced data, compared with other FDIA detection algorithms. The proposed method can improve recognition accuracy and reduce false alarm rate.

Published

2024

6. Cloning and analysis of BpFLS gene from rape pollen based on transcriptome sequencing

Author

LIU Xiaoning, GUO Yujin, JIANG Yuxuan, WANG Yifan, LU Yuqing, and XU Quanle

Subjects

menyuan rapeseed, pollen, transcriptome, bpfls gene, bioinformatics analysis, cloning, Biology (General), QH301-705.5, Botany, QK1-989

Abstract

Abstract [Objective] Menyuan rapeseed in Qinghai Province is cold resistant and has strong resistance. Its pollen accumulates rich flavonoids. This study aims to provide reference for genetic engineering breeding to improve flavonol content. [Methods] This study used transcriptome sequencing technology to screen differentially expressed flavonol synthase genes from rapeseed pollen in Menyuan of Qinghai Province and Zhengzhou of Henan Province, and performed bioinformatics analysis and RACE-PCR cloning of the Bp- FLS gene. [Results] (1) Six differentially expressed flavonol synthase genes in rape pollen were identified, and BpFLS1-1 was the most differentially expressed and up-regulated in the pollen of Menyuan rapeseed. (2) The amino acid sequence encoded by BpFLS1-1 had both flavonol synthase activity and flavanone-3- hydroxylase activity. (3) BpFLS1-1 gene might contain a new coding region sequence with a length of 1 170 bp. [Conclusion] Results suggest that the BpFLS1-1 gene plays an important role in the accumulation of flavonoids in Menyuan rapeseed pollen and the stress resistance of rapeseed.

Published

2024

7. Application Progress of Deep Learning in Imaging Examination of Breast Cancer

Author

WANG Yifan, LIU Jing, MA Jingang, SHAO Runhua, CHEN Tianzhen, LI Ming

Subjects

breast cancer, deep learning, computer-aided diagnosis, imaging examination, Electronic computers. Computer science, QA75.5-76.95

Abstract

Breast cancer is the most common malignant tumor in women and its early detection is decisive. Breast imaging plays an important role in early detection of breast cancer as well as monitoring and evaluation during treatment, but manual detection of medical images is usually time-consuming and labor-intensive. Recently, deep learning algorithms have made significant progress in early breast cancer diagnosis. By combing the relevant literature in recent years, a systematic review of the application of deep learning techniques in breast cancer diagnosis with different imaging modalities is conducted, aiming to provide a reference for in-depth research on deep learning-based breast cancer diagnosis. Firstly, four breast cancer imaging modalities, namely mammography, ultrasonography, magnetic resonance imaging and positron emission tomography, are outlined and briefly compared, and the public datasets corresponding to multiple imaging modalities are listed. Focusing on the different tasks (lesion detection, segmentation and classification) of deep learning architectures based on the above four different imaging modalities, a systematic review of the algorithms is conducted, and the performance of each algorithm, improvement ideas, and their advantages and disadvantages are compared and analyzed. Finally, the problems of the existing techniques are analyzed and the future development direction is prospected with respect to the limitations of the current work.

Published

2024

8. From Virtual Power Plant to Real Electricity: Summary and Prospect of Virtual Power Plant Research

Author

SUN Qiuye, YAO Jia, and WANG Yifan

Subjects

virtual power plant, energy market, flexible resources, distributed energy resources, Applications of electric power, TK4001-4102, Production of electric energy or power. Powerplants. Central stations, TK1001-1841, Science

Abstract

With a large number of distributed energy resources connected to the grid,virtual power plants as a distributed energy management technology have received a lot of attention because of their flexibility,efficiency and sustainability. This paper briefly discussed the background of virtual power plants, analyzed the hot directions and emerging directions in virtual power plants,and introduced the composition and structure of virtual power plants. According to the different goals and functions of virtual power plants,virtual power plants can be divided into mission-driven virtual power plants, economy-driven virtual power plants and hybrid driven virtual power plants. On this basis, the different operation modes and different solution methods of different types of virtual power plants were further discussed. Finally,the future development prospects of virtual power plants were prospected.

Published

2023

9. Research on Intelligent Management System of Gas Pipeline with Multi-source Data Fusion

Author

Cao Xin, Tan Jianxin, Li Hao, Li Rui, Wang Yifan, and Zhang Junfeng

Subjects

gas leakage model, gaussian plume model, ds evidence theory, kalman filter algorithm, multi-source data fusion, gas pipeline, 05c82, Mathematics, QA1-939

Abstract

Aiming at the current challenges of enormous scale, complex structure, difficult control and frequent accidents of city gas high-pressure pipeline network, there are still three aspects of difficulties in the risk monitoring and control of China’s city gas high-pressure pipeline network, namely, rough data, shallow assessment, and lack of power. This paper proposes an intelligent management system for gas pipelines based on C/S model and J2EE enterprise-level framework, in which the failure warning models of gas leakage, Gaussian plume diffusion, and fire and explosion are established. And the Kalman filter algorithm improved by DS evidence theory is used for intelligent fusion of Multi-source data, analyzing and screening the unified adequate information on data types, extracting state characteristics, classifying warning levels, and developing an integrated and visualized pipeline remote diagnosis and warning platform. In the simulation of the intelligent management system of gas pipeline, when the wind speed is 1.5m/s in winter, the ground surface is a safe area within 12.15m of the gas pipeline. When the maximum wind speed is 10m/s, the upper limit distance of the gas leading to fire and explosion is only 2.43m, and the hazardous range of the gas pipeline jet fire is within 12.69m. Relying on the gas high-pressure pipeline network in L city for practical experiments and applications, it provides technical support and decision-making basis for the construction of intelligent pipeline network, comprehensively improves the risk control capability of city gas high-pressure pipeline network, and has reference significance for the risk control of national city gas high-pressure pipeline network.

Published

2024

10. Preparation of poly(N, N-dimethylaminoethyl methacrylate)-TiO2 photocatalyst by radiation grafting and its adsorption and reduction performance for Cr(VI)

Author

WANG Yayang, WANG Yifan, ZHANG Bin, YANG Xiaojie, and LI Yuesheng

Subjects

tio2, polymethacrylate n, n-dimethylaminoethyl methacrylate (pdmaema), radiation grafting, photocatalytic, cr（vi）, adsorption-photocatalytic reduction, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798, Medical physics. Medical radiology. Nuclear medicine, R895-920

Abstract

TiO2-doped polymethacrylate N, N-dimethylaminoethyl methacrylate (DMAEMA) (TiO2-g-PDMAEMA) was successfully synthesized by the co-radiation grafting method with titanium dioxide (TiO2) and DMAEMA as the base and the monomer, respectively. Meanwhile, the effects of monomer concentration and absorbed dose on the adsorption of heavy metal ion were investigated. A series of characterizations, including X-ray diffraction, scanning electron microscopy, Fourier-transform infrared spectroscopy, thermogravimetry, X-ray photoelectron spectroscopy and contact angle, confirmed that DMAEMA monomer was successfully grafted onto TiO2 surface by electron beam co-radiation grafting method. When the absorbed dose was 60 kGy and the monomer concentration was 20%, TiO2-g-PDMAEMA exhibited excellent adsorption capacity for Cr (VI, 10 mg/L), up to 10.75 mg/g. In addition, the TiO2-g-PDMAEMA prepared at 60 kGy absorption dose and 10% monomer concentration displayed the optimal adsorption-photocatalytic reduction ability under visible-light irradiation, and the removal rate of Cr (VI, 10 mg/L) reached 85.56%. In conclusion, the adsorption-photocatalytic synergistic effect of this new photocatalyst could meet the requirement of removing Cr (VI) from water.

Published

2023

11. Text recognition of power equipment nameplates based on deep learning

Author

WANG Yifan, WANG Jiayu, ZHONG Linlin, and GAO Bingtuan

Subjects

power equipment nameplate, computer vision, deep learning, object detection, text detection, text recognition, Applications of electric power, TK4001-4102

Abstract

There is abundant information in power equipment nameplates. Extracting information from nameplates through image and text recognition technology enables the high effective and quick works on statics and account check of power equipment,which is also beneficial to improve the equipment management level of power system. Considering the great difference of text recognition between power equipment nameplates and ordinary images,an algorithm of automatic recognition of power equipment nameplates based on deep learning is proposed in this paper. This algorithm consists of three parts,namely nameplate detection,text detection and text recognition. By improving the design of loss functions,adding the correction of text recognition,and synthesizing text images,the mean average precision of the nameplate detection model on the test set reaches 92.2%,the F1 of the text detection model on the test set reaches 91.2%,and the character recognition accuracy rate of the text recognition model reaches 94.0%,the text line recognition accuracy rate of the text recognition model reaches 82.3%.

Published

2022

12. A Study on Financial Innovation and Risk Management Methods from an Accounting Perspective

Author

Wang Yifan

Subjects

Social Sciences

Abstract

With the continuous development of global financial markets and rapid technological advances, a growing number of innovative products and services in the financial sector have emerged, providing new impetus to economic growth but at the same time bringing new risks. We study financial innovation and risk management methods from an accounting perspective, examining how accounting plays a key role in ensuring financial stability and transparency. First, this paper summarizes the definition and classification of financial innovation and analyzes its positive and negative effects on economic development. Second, our main focus is on the fundamental roles of accounting in risk management, which involve supplying financial data for decision-making, overseeing financial innovation and operational risks, and evaluating the efficiency of risk management actions. In addition, this paper discusses the risk management methods from the accounting perspective, such as improving the accuracy and transparency of financial reports, selecting and adjusting prudent accounting policies, strengthening internal control and external audit mechanisms, and improving the accuracy of asset and liability assessment. Enhancing accounting standards and regulatory frameworks to better align with the evolving trends in financial markets is recommended. Furthermore, we will strengthen the professional training of accounting personnel, improve the risk management capabilities of financial institutions, and promote the integration of accounting innovation and financial innovation.

Published

2024

13. Research on the Optimization of Coalbed Methane Utilization Based on Hydraulic Fracturing Enhanced Permeability Technology

Author

Wang Yifan

Subjects

Environmental sciences, GE1-350

Abstract

This study presents the solution of the extraction and coal seam. Through the combination of numerical simulation study and field investigation, the fracturing radius is 12 meters after 30 days of hydraulic fracturing in the 6th coal seam, and the implementation measures of fracturing hole spacing of 20 meters and 5 meters were formulated. The results showed that the hydraulic fracturing technology significantly increased the gas concentration of drilling extraction to 93%, and the attenuation rate of gas concentration in 120 days was 14%. This technology has significantly increased the extraction flow, and effectively controlled the occurrence of coal seam fire. The methods and results of this study are instructive for coalbed methane utilization in other mines.

Published

2024

14. Classifying Order-Two Spatial Symmetries in Non-Hermitian Hamiltonians: Point-gapped AZ and AZ$^\dag$ Classes

Author

Wang, Yifan

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Crystalline topological insulators and superconductors have been a prominent topic in the field of condensed matter physics. These systems obey certain crystalline (spatial) symmetries that depend on the geometry of the lattice. The presence of spatial symmetries can lead to shift in the classification of ten fold Altland Zirnbauer class, given rise to new symmetry protected topological phases. If the constraint of Hermiticity is broken, the classification expand into 38 fold. In this paper, following procedures in Hermitian systems, we classify all possible types of order-two spatial symmetries for point gapped non Hermitian systems within 16 out of 38 non Hermitian topological classes. These 16 classes are denoted by AZ and AZ^$\dag$ classes. We show that, similar to the Hermitian case, spatial symmetries will also lead to a shift in the classification of AZ and AZ^$\dag$ classes. There also exist novel symmetry protected topological phases exclusive to point gapped non Hermitian Hamiltonians. Toy models are also given based on our classifications.

Published

2024

15. Efficient Feature Aggregation and Scale-Aware Regression for Monocular 3D Object Detection

Author

Wang, Yifan, Yang, Xiaochen, Pu, Fanqi, Liao, Qingmin, and Yang, Wenming

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

Monocular 3D object detection has attracted great attention due to simplicity and low cost. Existing methods typically follow conventional 2D detection paradigms, first locating object centers and then predicting 3D attributes via neighboring features. However, these methods predominantly rely on progressive cross-scale feature aggregation and focus solely on local information, which may result in a lack of global awareness and the omission of small-scale objects. In addition, due to large variation in object scales across different scenes and depths, inaccurate receptive fields often lead to background noise and degraded feature representation. To address these issues, we introduces MonoASRH, a novel monocular 3D detection framework composed of Efficient Hybrid Feature Aggregation Module (EH-FAM) and Adaptive Scale-Aware 3D Regression Head (ASRH). Specifically, EH-FAM employs multi-head attention with a global receptive field to extract semantic features for small-scale objects and leverages lightweight convolutional modules to efficiently aggregate visual features across different scales. The ASRH encodes 2D bounding box dimensions and then fuses scale features with the semantic features aggregated by EH-FAM through a scale-semantic feature fusion module. The scale-semantic feature fusion module guides ASRH in learning dynamic receptive field offsets, incorporating scale priors into 3D position prediction for better scale-awareness. Extensive experiments on the KITTI and Waymo datasets demonstrate that MonoASRH achieves state-of-the-art performance.

Published

2024

16. Room-temperature vacancy emission from the jog on edge dislocation in FCC nickel under glide force

Author

Wang, Yifan, Jian, Wu-Rong, and Cai, Wei

Subjects

Condensed Matter - Materials Science

Abstract

Jogs, atomic-scale steps on dislocations, play an important role in crystal plasticity, yet they are often ignored in discrete dislocation dynamics (DDD) simulations due to their small sizes. While jogs on screw dislocations are known to move non-conservatively (i.e. climb) accompanied by vacancy emission, jogs on edge dislocations are commonly expected to move conservatively (i.e. glide) with the dislocation under ambient conditions. Here we report unexpected findings from molecular dynamics simulations of an edge dislocation containing a pair of unit jogs in face-centered cubic nickel at 300K. While the jogs glide conservatively with the edge dislocation at low stresses, we observe that one of the jogs climbs and emits vacancies intermittently at higher stresses. This observation is unexpected at such a low temperature, as climb is typically associated with temperatures closer to the creep temperature (roughly half of the melting temperature). Our results highlight the significance of the complex interplay between point defects (i.e., vacancies) and dislocations in room-temperature plasticity, suggesting that these interactions may be more significant than previously thought.

Published

2024

17. MonoDGP: Monocular 3D Object Detection with Decoupled-Query and Geometry-Error Priors

Author

Pu, Fanqi, Wang, Yifan, Deng, Jiru, and Yang, Wenming

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

Perspective projection has been extensively utilized in monocular 3D object detection methods. It introduces geometric priors from 2D bounding boxes and 3D object dimensions to reduce the uncertainty of depth estimation. However, due to depth errors originating from the object's visual surface, the height of the bounding box often fails to represent the actual projected central height, which undermines the effectiveness of geometric depth. Direct prediction for the projected height unavoidably results in a loss of 2D priors, while multi-depth prediction with complex branches does not fully leverage geometric depth. This paper presents a Transformer-based monocular 3D object detection method called MonoDGP, which adopts perspective-invariant geometry errors to modify the projection formula. We also try to systematically discuss and explain the mechanisms and efficacy behind geometry errors, which serve as a simple but effective alternative to multi-depth prediction. Additionally, MonoDGP decouples the depth-guided decoder and constructs a 2D decoder only dependent on visual features, providing 2D priors and initializing object queries without the disturbance of 3D detection. To further optimize and fine-tune input tokens of the transformer decoder, we also introduce a Region Segment Head (RSH) that generates enhanced features and segment embeddings. Our monocular method demonstrates state-of-the-art performance on the KITTI benchmark without extra data. Code is available at https://github.com/PuFanqi23/MonoDGP.

Published

2024

18. RSA-Control: A Pragmatics-Grounded Lightweight Controllable Text Generation Framework

Author

Wang, Yifan and Demberg, Vera

Subjects

Computer Science - Artificial Intelligence, Computer Science - Computation and Language

Abstract

Despite significant advancements in natural language generation, controlling language models to produce texts with desired attributes remains a formidable challenge. In this work, we introduce RSA-Control, a training-free controllable text generation framework grounded in pragmatics. RSA-Control directs the generation process by recursively reasoning between imaginary speakers and listeners, enhancing the likelihood that target attributes are correctly interpreted by listeners amidst distractors. Additionally, we introduce a self-adjustable rationality parameter, which allows for automatic adjustment of control strength based on context. Our experiments, conducted with two task types and two types of language models, demonstrate that RSA-Control achieves strong attribute control while maintaining language fluency and content consistency. Our code is available at https://github.com/Ewanwong/RSA-Control., Comment: Accepted to EMNLP 2024 (main conference)

Published

2024

19. GBCT: An Efficient and Adaptive Granular-Ball Clustering Algorithm for Complex Data

Author

Xia, Shuyin, Shi, Bolun, Wang, Yifan, Xie, Jiang, Wang, Guoyin, and Gao, Xinbo

Subjects

Computer Science - Machine Learning

Abstract

Traditional clustering algorithms often focus on the most fine-grained information and achieve clustering by calculating the distance between each pair of data points or implementing other calculations based on points. This way is not inconsistent with the cognitive mechanism of "global precedence" in human brain, resulting in those methods' bad performance in efficiency, generalization ability and robustness. To address this problem, we propose a new clustering algorithm called granular-ball clustering (GBCT) via granular-ball computing. Firstly, GBCT generates a smaller number of granular-balls to represent the original data, and forms clusters according to the relationship between granular-balls, instead of the traditional point relationship. At the same time, its coarse-grained characteristics are not susceptible to noise, and the algorithm is efficient and robust; besides, as granular-balls can fit various complex data, GBCT performs much better in non-spherical data sets than other traditional clustering methods. The completely new coarse granularity representation method of GBCT and cluster formation mode can also used to improve other traditional methods.

Published

2024

20. FusionSense: Bridging Common Sense, Vision, and Touch for Robust Sparse-View Reconstruction

Author

Fang, Irving, Shi, Kairui, He, Xujin, Tan, Siqi, Wang, Yifan, Zhao, Hanwen, Huang, Hung-Jui, Yuan, Wenzhen, Feng, Chen, and Zhang, Jing

Subjects

Computer Science - Robotics, Computer Science - Artificial Intelligence, Computer Science - Computer Vision and Pattern Recognition, Computer Science - Graphics, I.4.5, I.4.8

Abstract

Humans effortlessly integrate common-sense knowledge with sensory input from vision and touch to understand their surroundings. Emulating this capability, we introduce FusionSense, a novel 3D reconstruction framework that enables robots to fuse priors from foundation models with highly sparse observations from vision and tactile sensors. FusionSense addresses three key challenges: (i) How can robots efficiently acquire robust global shape information about the surrounding scene and objects? (ii) How can robots strategically select touch points on the object using geometric and common-sense priors? (iii) How can partial observations such as tactile signals improve the overall representation of the object? Our framework employs 3D Gaussian Splatting as a core representation and incorporates a hierarchical optimization strategy involving global structure construction, object visual hull pruning and local geometric constraints. This advancement results in fast and robust perception in environments with traditionally challenging objects that are transparent, reflective, or dark, enabling more downstream manipulation or navigation tasks. Experiments on real-world data suggest that our framework outperforms previously state-of-the-art sparse-view methods. All code and data are open-sourced on the project website.

Published

2024

21. Formalism to Image the Dynamics of Coherent and Incoherent Phonon with Dark-Field X-ray Microscopy using Kinematic Diffraction Theory

Author

Chalise, Darshan, Wang, Yifan, Trigo, Mariano, and Dresselhaus-Marais, Leora E.

Subjects

Condensed Matter - Materials Science, Physics - Optics

Abstract

Dark-field X-ray microscopy (DFXM) is a novel X-ray imaging technique developed at synchrotrons to image along the diffracted beam with a real space resolution of ~100 nm and reciprocal space resolution of $10^{-4}$. Recent implementations of DFXM at X-ray free electron lasers (XFELs) have demonstrated DFXM's ability to visualize the real-time evolution of coherent GHz phonons produced by ultrafast laser excitation of metal transducers. Combining this with DFXM's ability to visualize strain fields due to dislocations makes it possible to study the interaction of GHz coherent phonons with the strain fields of dislocations, along with studying the damping of coherent phonons due to interactions with thermal phonons. For quantitative analysis of phonon-dislocation interactions and phonon damping, a formalism is required to relate phonon dynamics to the strains measured by DFXM. In this work, we use kinematic diffraction theory to simulate DFXM images of the specific coherent phonons in diamond that are generated by the ultrafast laser excitation of a metal transducer. We extend this formalism to also describe imaging of incoherent phonons of sufficiently high frequency, which are relevant for thermal transport, offering future opportunities for DFXM to image signals produced by thermal diffuse scattering. For both coherent and incoherent phonons, we discuss the optimal sampling of real space, reciprocal space and time, and the opportunities offered by the advances in DFXM optics.

Published

2024

22. Two-Stage Radio Map Construction with Real Environments and Sparse Measurements

Author

Wang, Yifan, Sun, Shu, Liu, Na, Xu, Lianming, and Wang, Li

Subjects

Electrical Engineering and Systems Science - Signal Processing, Computer Science - Artificial Intelligence

Abstract

Radio map construction based on extensive measurements is accurate but expensive and time-consuming, while environment-aware radio map estimation reduces the costs at the expense of low accuracy. Considering accuracy and costs, a first-predict-then-correct (FPTC) method is proposed by leveraging generative adversarial networks (GANs). A primary radio map is first predicted by a radio map prediction GAN (RMP-GAN) taking environmental information as input. Then, the prediction result is corrected by a radio map correction GAN (RMC-GAN) with sparse measurements as guidelines. Specifically, the self-attention mechanism and residual-connection blocks are introduced to RMP-GAN and RMC-GAN to improve the accuracy, respectively. Experimental results validate that the proposed FPTC-GANs method achieves the best radio map construction performance, compared with the state-of-the-art methods.

Published

2024

23. Over-the-Air Federated Learning in Cell-Free MIMO with Long-term Power Constraint

Author

Wang, Yifan, Zhang, Cheng, Zhuang, Yuanndon, Dai, Mingzeng, Wang, Haiming, and Huang, Yongming

Subjects

Computer Science - Machine Learning, Computer Science - Artificial Intelligence

Abstract

Wireless networks supporting artificial intelligence have gained significant attention, with Over-the-Air Federated Learning emerging as a key application due to its unique transmission and distributed computing characteristics. This paper derives error bounds for Over-the-Air Federated Learning in a Cell-free MIMO system and formulates an optimization problem to minimize optimality gap via joint optimization of power control and beamforming. We introduce the MOP-LOFPC algorithm, which employs Lyapunov optimization to decouple long-term constraints across rounds while requiring only causal channel state information. Experimental results demonstrate that MOP-LOFPC achieves a better and more flexible trade-off between the model's training loss and adherence to long-term power constraints compared to existing baselines.

Published

2024

24. Hawk: An Efficient NALM System for Accurate Low-Power Appliance Recognition

Author

Wang, Zijian, Zhang, Xingzhou, Wang, Yifan, Peng, Xiaohui, and Xu, Zhiwei

Subjects

Electrical Engineering and Systems Science - Signal Processing, Computer Science - Artificial Intelligence, Computer Science - Machine Learning

Abstract

Non-intrusive Appliance Load Monitoring (NALM) aims to recognize individual appliance usage from the main meter without indoor sensors. However, existing systems struggle to balance dataset construction efficiency and event/state recognition accuracy, especially for low-power appliance recognition. This paper introduces Hawk, an efficient and accurate NALM system that operates in two stages: dataset construction and event recognition. In the data construction stage, we efficiently collect a balanced and diverse dataset, HawkDATA, based on balanced Gray code and enable automatic data annotations via a sampling synchronization strategy called shared perceptible time. During the event recognition stage, our algorithm integrates steady-state differential pre-processing and voting-based post-processing for accurate event recognition from the aggregate current. Experimental results show that HawkDATA takes only 1/71.5 of the collection time to collect 6.34x more appliance state combinations than the baseline. In HawkDATA and a widely used dataset, Hawk achieves an average F1 score of 93.94% for state recognition and 97.07% for event recognition, which is a 47. 98% and 11. 57% increase over SOTA algorithms. Furthermore, selected appliance subsets and the model trained from HawkDATA are deployed in two real-world scenarios with many unknown background appliances. The average F1 scores of event recognition are 96.02% and 94.76%. Hawk's source code and HawkDATA are accessible at https://github.com/WZiJ/SenSys24-Hawk., Comment: Accepted to the 22nd ACM Conference on Embedded Networked Sensor Systems (SenSys 2024)

Published

2024

25. StreetSurfGS: Scalable Urban Street Surface Reconstruction with Planar-based Gaussian Splatting

Author

Cui, Xiao, Ye, Weicai, Wang, Yifan, Zhang, Guofeng, Zhou, Wengang, and Li, Houqiang

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

Reconstructing urban street scenes is crucial due to its vital role in applications such as autonomous driving and urban planning. These scenes are characterized by long and narrow camera trajectories, occlusion, complex object relationships, and data sparsity across multiple scales. Despite recent advancements, existing surface reconstruction methods, which are primarily designed for object-centric scenarios, struggle to adapt effectively to the unique characteristics of street scenes. To address this challenge, we introduce StreetSurfGS, the first method to employ Gaussian Splatting specifically tailored for scalable urban street scene surface reconstruction. StreetSurfGS utilizes a planar-based octree representation and segmented training to reduce memory costs, accommodate unique camera characteristics, and ensure scalability. Additionally, to mitigate depth inaccuracies caused by object overlap, we propose a guided smoothing strategy within regularization to eliminate inaccurate boundary points and outliers. Furthermore, to address sparse views and multi-scale challenges, we use a dual-step matching strategy that leverages adjacent and long-term information. Extensive experiments validate the efficacy of StreetSurfGS in both novel view synthesis and surface reconstruction.

Published

2024

26. Inverse Painting: Reconstructing The Painting Process

Author

Chen, Bowei, Wang, Yifan, Curless, Brian, Kemelmacher-Shlizerman, Ira, and Seitz, Steven M.

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

Given an input painting, we reconstruct a time-lapse video of how it may have been painted. We formulate this as an autoregressive image generation problem, in which an initially blank "canvas" is iteratively updated. The model learns from real artists by training on many painting videos. Our approach incorporates text and region understanding to define a set of painting "instructions" and updates the canvas with a novel diffusion-based renderer. The method extrapolates beyond the limited, acrylic style paintings on which it has been trained, showing plausible results for a wide range of artistic styles and genres., Comment: Project Page: https://inversepainting.github.io

Published

2024

27. Extended one-dimensional reduced model for blood flow within a stenotic artery

Author

Canic, Suncica, Guo, Shihan, Wang, Yifan, Yue, Xiaohe, and Zheng, Haibiao

Subjects

Mathematics - Numerical Analysis

Abstract

In this paper, we introduce an adapted one-dimensional (1D) reduced model aimed at analyzing blood flow within stenosed arteries. Differing from the prevailing 1D model \cite{Formaggia2003, Sherwin2003_2, Sherwin2003, Quarteroni2004, 10.1007/978-3-642-56288-4_10}, our approach incorporates the variable radius of the blood vessel. Our methodology begins with the non-dimensionalization of the Navier-Stokes equations for axially symmetric flow in cylindrical coordinates and then derives the extended 1D reduced model, by making additional adjustments to accommodate the effects of variable radii of the vessel along the longitudinal direction. Additionally, we propose a method to extract radial velocity information from the 1D results during post-processing, enabling the generation of two-dimensional (2D) velocity data. We validate our model by conducting numerical simulations of blood flow through stenotic arteries with varying severities, ranging from 23% to 50%. The results were compared to those from the established 1D model and a full three-dimensional (3D) simulation, highlighting the potential and importance of this model for arteries with variable radius. All the code used to generate the results presented in the paper is available at https://github.com/qcutexu/Extended-1D-AQ-system.git.

Published

2024

28. Single-crystalline GaAs/Si Heterojunction Tunnel Diodes Interfaced by an Ultrathin Oxygen-enriched Layer

Author

Zhou, Jie, Wang, Yifan, Yao, Ziqian, Wang, Qingxiao, Banda, Yara S., Gong, Jiarui, Liu, Yang, Adamo, Carolina, Marshall, Patrick, Lu, Yi, Tsai, Tsung-Han, Li, Yiran, Gambin, Vincent, Ng, Tien Khee, Ooi, Boon S., and Ma, Zhenqiang

Subjects

Physics - Applied Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We report the fabrication and characteristics of GaAs/Si p+/n+ heterojunction tunnel diodes. These diodes were fabricated via grafting the freestanding single-crystalline p-type degenerately doped GaAs (4E19 cm-3) nanomembrane (NM) onto single-crystalline n-type Si (5E19 cm-3) substrate. At the heterointerface, an amorphous ultrathin oxygen-enriched layer (UOL) was intentionally engineered through chemical oxidation and atomic layer deposition (ALD). Scanning transmission electron microscopy (STEM) confirmed the formation of the UOL and the single crystallinity of the grafted junction. The resulting tunnel diodes consistently exhibited negative differential resistance (NDR) behavior at room temperature, with a high maximum peak-to-valley current ratio (PVCR) of 36.38, valley voltages ranging from 1.3 to 1.8 V, and a peak tunneling current density of 0.95 kA/cm2. This study not only highlights the critical roles of the UOL as both an interface improvement layer and a quantum tunneling medium, but also establishes "semiconductor grafting" as an effective and versatile method for high-performance, lattice-mismatched heterojunction devices., Comment: 4 pages, 5 figures

Published

2024

29. CFVNet: An End-to-End Cancelable Finger Vein Network for Recognition

Author

Wang, Yifan, Gui, Jie, Tang, Yuan Yan, and Kwok, James Tin-Yau

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

Finger vein recognition technology has become one of the primary solutions for high-security identification systems. However, it still has information leakage problems, which seriously jeopardizes users privacy and anonymity and cause great security risks. In addition, there is no work to consider a fully integrated secure finger vein recognition system. So, different from the previous systems, we integrate preprocessing and template protection into an integrated deep learning model. We propose an end-to-end cancelable finger vein network (CFVNet), which can be used to design an secure finger vein recognition system.It includes a plug-and-play BWR-ROIAlign unit, which consists of three sub-modules: Localization, Compression and Transformation. The localization module achieves automated localization of stable and unique finger vein ROI. The compression module losslessly removes spatial and channel redundancies. The transformation module uses the proposed BWR method to introduce unlinkability, irreversibility and revocability to the system. BWR-ROIAlign can directly plug into the model to introduce the above features for DCNN-based finger vein recognition systems. We perform extensive experiments on four public datasets to study the performance and cancelable biometric attributes of the CFVNet-based recognition system. The average accuracy, EERs and Dsys on the four datasets are 99.82%, 0.01% and 0.025, respectively, and achieves competitive performance compared with the state-of-the-arts.

Published

2024

30. A Fully Parallelizable Loosely Coupled Scheme for Fluid-Poroelastic Structure Interaction Problems

Author

Guo, Shihan, Sun, Yizhong, Wang, Yifan, Yue, Xiaohe, and Zheng, Haibiao

Subjects

Mathematics - Numerical Analysis

Abstract

We investigate the fluid-poroelastic structure interaction problem in a moving domain, governed by Navier-Stokes-Biot (NSBiot) system. First, we propose a fully parallelizable, loosely coupled scheme to solve the coupled system. At each time step, the solution from the previous time step is used to approximate the coupling conditions at the interface, allowing the original coupled problem to be fully decoupled into seperate fluid and structure subproblems, which are solved in parallel. Since our approach utilizes a loosely coupled scheme, no sub-iterations are required at each time step. Next, we conduct the energy estimates of this splitting method for the linearized problem (Stokes-Biot system), which demonstrates that the scheme is unconditionally stable without any restriction of the time step size from the physical parameters. Furthermore, we illustrate the first-order accuracy in time through two benchmark problems. Finally, to demonstrate that the proposed method maintains its excellent stability properties also for the nonlinear NSBiot system, we present numerical results for both $2D$ and $3D$ NSBiot problems related to real-world physical applications.

Published

2024

31. Model-in-the-Loop (MILO): Accelerating Multimodal AI Data Annotation with LLMs

Author

Wang, Yifan, Stevens, David, Shah, Pranay, Jiang, Wenwen, Liu, Miao, Chen, Xu, Kuo, Robert, Li, Na, Gong, Boying, Lee, Daniel, Hu, Jiabo, Zhang, Ning, and Kamma, Bob

Subjects

Computer Science - Human-Computer Interaction, Computer Science - Artificial Intelligence, Computer Science - Computation and Language, Computer Science - Machine Learning

Abstract

The growing demand for AI training data has transformed data annotation into a global industry, but traditional approaches relying on human annotators are often time-consuming, labor-intensive, and prone to inconsistent quality. We propose the Model-in-the-Loop (MILO) framework, which integrates AI/ML models into the annotation process. Our research introduces a collaborative paradigm that leverages the strengths of both professional human annotators and large language models (LLMs). By employing LLMs as pre-annotation and real-time assistants, and judges on annotator responses, MILO enables effective interaction patterns between human annotators and LLMs. Three empirical studies on multimodal data annotation demonstrate MILO's efficacy in reducing handling time, improving data quality, and enhancing annotator experiences. We also introduce quality rubrics for flexible evaluation and fine-grained feedback on open-ended annotations. The MILO framework has implications for accelerating AI/ML development, reducing reliance on human annotation alone, and promoting better alignment between human and machine values.

Published

2024

32. Generalizability of Graph Neural Network Force Fields for Predicting Solid-State Properties

Author

Mohanty, Shaswat, Wang, Yifan, and Cai, Wei

Subjects

Computer Science - Machine Learning, Condensed Matter - Materials Science, Mathematics - Numerical Analysis

Abstract

Machine-learned force fields (MLFFs) promise to offer a computationally efficient alternative to ab initio simulations for complex molecular systems. However, ensuring their generalizability beyond training data is crucial for their wide application in studying solid materials. This work investigates the ability of a graph neural network (GNN)-based MLFF, trained on Lennard-Jones Argon, to describe solid-state phenomena not explicitly included during training. We assess the MLFF's performance in predicting phonon density of states (PDOS) for a perfect face-centered cubic (FCC) crystal structure at both zero and finite temperatures. Additionally, we evaluate vacancy migration rates and energy barriers in an imperfect crystal using direct molecular dynamics (MD) simulations and the string method. Notably, vacancy configurations were absent from the training data. Our results demonstrate the MLFF's capability to capture essential solid-state properties with good agreement to reference data, even for unseen configurations. We further discuss data engineering strategies to enhance the generalizability of MLFFs. The proposed set of benchmark tests and workflow for evaluating MLFF performance in describing perfect and imperfect crystals pave the way for reliable application of MLFFs in studying complex solid-state materials., Comment: 17 pages, 7 figures

Published

2024

33. GigaGS: Scaling up Planar-Based 3D Gaussians for Large Scene Surface Reconstruction

Author

Chen, Junyi, Ye, Weicai, Wang, Yifan, Chen, Danpeng, Huang, Di, Ouyang, Wanli, Zhang, Guofeng, Qiao, Yu, and He, Tong

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

3D Gaussian Splatting (3DGS) has shown promising performance in novel view synthesis. Previous methods adapt it to obtaining surfaces of either individual 3D objects or within limited scenes. In this paper, we make the first attempt to tackle the challenging task of large-scale scene surface reconstruction. This task is particularly difficult due to the high GPU memory consumption, different levels of details for geometric representation, and noticeable inconsistencies in appearance. To this end, we propose GigaGS, the first work for high-quality surface reconstruction for large-scale scenes using 3DGS. GigaGS first applies a partitioning strategy based on the mutual visibility of spatial regions, which effectively grouping cameras for parallel processing. To enhance the quality of the surface, we also propose novel multi-view photometric and geometric consistency constraints based on Level-of-Detail representation. In doing so, our method can reconstruct detailed surface structures. Comprehensive experiments are conducted on various datasets. The consistent improvement demonstrates the superiority of GigaGS.

Published

2024

34. Comment on 'Comments regarding 'Transonic dislocation propagation in diamond' by Katagiri, et al. (Science 382, 69-72, 2023)' by Hawreliak, et al. (arXiv:2401.04213)

Author

Katagiri, Kento, Pikuz, Tatiana, Fang, Lichao, Albertazzi, Bruno, Egashira, Shunsuke, Inubushi, Yuichi, Kamimura, Genki, Kodama, Ryosuke, Koenig, Michel, Kozioziemski, Bernard, Masaoka, Gooru, Miyanishi, Kohei, Nakamura, Hirotaka, Ota, Masato, Rigon, Gabriel, Sakawa, Youichi, Sano, Takayoshi, Schoofs, Frank, Smith, Zoe J., Sueda, Keiichi, Togashi, Tadashi, Vinci, Tommaso, Wang, Yifan, Yabashi, Makina, Yabuuchi, Toshinori, Dresselhaus-Marais, Leora E., and Ozaki, Norimasa

Subjects

Condensed Matter - Materials Science

Abstract

In their comment (1), Hawreliak et al. claims that our observation of stacking fault formation and transonic dislocation propagation in diamond (2) is not valid as they interpret the observed features as cracks. In this response letter, we describe our rationale for interpreting the observed features as stacking faults. We also address other points raised in their comments, including the clarifications of how the results of Makarov et al. (3) are not in conflict with our study., Comment: Comment on arXiv:2401.04213. 10 pages, 2 figures

Published

2024

35. Multiagent Reinforcement Learning Enhanced Decision-making of Crew Agents During Floor Construction Process

Author

Yang, Bin, Liu, Boda, Han, Yilong, Meng, Xin, Wang, Yifan, Yang, Hansi, and Xia, Jianzhuang

Subjects

Computer Science - Computational Engineering, Finance, and Science

Abstract

Fine-grained simulation of floor construction processes is essential for supporting lean management and the integration of information technology. However, existing research does not adequately address the on-site decision-making of constructors in selecting tasks and determining their sequence within the entire construction process. Moreover, decision-making frameworks from computer science and robotics are not directly applicable to construction scenarios. To facilitate intelligent simulation in construction, this study introduces the Construction Markov Decision Process (CMDP). The primary contribution of this CMDP framework lies in its construction knowledge in decision, observation modifications and policy design, enabling agents to perceive the construction state and follow policy guidance to evaluate and reach various range of targets for optimizing the planning of construction activities. The CMDP is developed on the Unity platform, utilizing a two-stage training approach with the multi-agent proximal policy optimization algorithm. A case study demonstrates the effectiveness of this framework: the low-level policy successfully simulates the construction process in continuous space, facilitating policy testing and training focused on reducing conflicts and blockages among crews; and the high-level policy improving the spatio-temporal planning of construction activities, generating construction patterns in distinct phases, leading to the discovery of new construction insights.

Published

2024

36. Computing virtual dark-field X-ray microscopy images of complex discrete dislocation structures from large-scale molecular dynamics simulations

Author

Wang, Yifan, Bertin, Nicolas, Pal, Dayeeta, Irvine, Sara J., Katagiri, Kento, Rudd, Robert E., and Dresselhaus-Marais, Leora E.

Subjects

Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Computational Physics, Physics - Instrumentation and Detectors

Abstract

Dark-field X-ray Microscopy (DFXM) is a novel diffraction-based imaging technique that non-destructively maps the local deformation from crystalline defects in bulk materials. While studies have demonstrated that DFXM can spatially map 3D defect geometries, it is still challenging to interpret DFXM images of the high dislocation density systems relevant to macroscopic crystal plasticity. This work develops a scalable forward model to calculate virtual DFXM images for complex discrete dislocation (DD) structures obtained from atomistic simulations. Our new DD-DFXM model integrates a non-singular formulation for calculating the local strain from the DD structures and an efficient geometrical optics algorithm for computing the DFXM image from the strain. We apply the model to complex DD structures obtained from a large-scale molecular dynamics (MD) simulation of compressive loading on a single-crystal silicon. Simulated DFXM images exhibit prominent feature contrast for dislocations between the multiple slip systems, demonstrating the DFXM's potential to resolve features from dislocation multiplication. The integrated DD-DFXM model provides a toolbox for DFXM experimental design and image interpretation in the context of bulk crystal plasticity for the breadth of measurements across shock plasticity and the broader materials science community.

Published

2024

37. In-containment hydrogen behavior simulation and hydrogen concentration control under LBLOCA accidents

Author

Wu Tianfan, Xue Feng, Ding Shuo, Wang Li, Li Wanai, and Wang Yifan

Subjects

design basis accident, large break loss coolant accident, containment modeling, hydrogen risk, 3D CFD simulation, General Works

Abstract

During a design basis accident in a pressurized water reactor (PWR), the released hydrogen through reactor breaks would induce the hydrogen detonation. The hydrogen passive autocatalytic recombiner (PAR) is widely used as a hydrogen elimination measure in nuclear power plants due to its passive capability, low starting threshold and easy installation. The present work aims to study the hydrogen risk after the occurrence of cold section double-end shear fracture large break loss coolant accident (LBLOCA) by using the 3D computational fluid dynamics program GASFLOW. A full containment model of CPR1000 is built. The hydrogen production rate inside the containment after LBLOCA is calculated from the related physicochemical reactions. The hydrogen transport, hydrogen concentration distribution and temperature distribution inside the containment are simulated. The effects of different roughness of the structure surface on the simulation are investigated, and it is proved that the operation of PAR can control the hydrogen concentration under the safety threshold of 4 vol%. The effects of hydrogen flow rate and PAR’s position on the hydrogen elimination efficiency are studied. Based on these studies, this paper makes some suggestions and theoretical references for the spatial arrangement scheme of PAR in the containment to optimize the hydrogen elimination efficiency.

Published

2022

38. Research on Prediction and Optimization Design Method of Slip Anchoring Performance Based on BP&NSGA-II

Author

Lu Ming, Liao Hualin, Wang Huajian, Liu Jiansheng, He Yuhang, Qu Fengtao, Niu Wenlong, and Wang Yifan

Subjects

prediction model, BP neural network, numerical analysis, slip sealing, indoor test, General Works

Abstract

The slip of the packer is the core part of the anchoring system. Unreasonable design of the slip structure can easily cause damage to the anchor claw of the slip, unstable anchoring, and even damage to the casing. At present, the main methods of slip anchoring performance tests are indoor design and field tests, and slips with different structural parameters need to be processed to verify their anchoring performance. In order to ensure that the slips can play a good anchoring effect and reduce the damage to the casing, this study uses a combination of finite element analysis, BP&NSGA-II, and indoor tests to study the mechanical behavior of the slips during the anchoring process. A prediction model was established to optimize the key parameters affecting anchoring performance, such as slip angle, inclination angle, inner cone angle, the radius of curvature, and spacing. Indoor experiments show that the prediction method can greatly improve the efficiency and accuracy of the design and test the anchoring performance of slips.

Published

2022

39. SARS-CoV-2 vaccine development and challenges

Author

Duan Fugang, Wang Yifan, and Qiu Xiaoyan

Subjects

sars-cov-2, sars-cov-2 vaccine, immunology, Medicine, Biotechnology, TP248.13-248.65

Abstract

In 2020, the SARS-CoV-2 epidemic has made the world’s public system withstand extremetests. Therefore, it is urgently expected to develop a vaccine that can effectively prevent the SARS-CoV-2in the worldwide. At present, more than 200 vaccines are in the preclinical research or undergoing clinicaltrials. However, much remains to be studied because SARS-CoV-2 ravaged humans for the first time, and themechanisms underlying its inducing immune response are not yet fully understood. Moreover, with limitedtime and clinical application data, it is still uncertain which SARS-CoV-2 vaccine can provide better protectionand higher safety. This article reviews the key structure of SARS-CoV-2, the characteristics of immuneresponse, the existing technical routes of SARS-CoV-2 research and the challenges faced by the currentvaccine development, in order to provide a theoretical basis for the development of the SARS-CoV-2 vaccine.

Published

2021

40. Characterizing User Platforms for Video Streaming in Broadband Networks

Author

Wang, Yifan, Lyu, Minzhao, and Sivaraman, Vijay

Subjects

Computer Science - Networking and Internet Architecture

Abstract

Internet Service Providers (ISPs) bear the brunt of being the first port of call for poor video streaming experience. ISPs can benefit from knowing the user's device type (e.g., Android, iOS) and software agent (e.g., native app, Chrome) to troubleshoot platform-specific issues, plan capacity and create custom bundles. Unfortunately, encryption and NAT have limited ISPs' visibility into user platforms across video streaming providers. We develop a methodology to identify user platforms for video streams from four popular providers, namely YouTube, Netflix, Disney, and Amazon, by analyzing network traffic in real-time. First, we study the anatomy of the connection establishment process to show how TCP/QUIC and TLS handshakes vary across user platforms. We then develop a classification pipeline that uses 62 attributes extracted from the handshake messages to determine the user device and software agent of video flows with over 96% accuracy. Our method is evaluated and deployed in a large campus network (mimicking a residential broadband network) serving users including dormitory residents. Analysis of 100+ million video streams over a four-month period reveals insights into the mix of user platforms across the video providers, variations in bandwidth consumption across operating systems and browsers, and differences in peak hours of usage., Comment: This paper is accepted at ACM Internet Measurement Conference (IMC) 2024. Proc. ACM IMC, Madrid, Spain, Nov 2024

Published

2024

41. ND-SDF: Learning Normal Deflection Fields for High-Fidelity Indoor Reconstruction

Author

Tang, Ziyu, Ye, Weicai, Wang, Yifan, Huang, Di, Bao, Hujun, He, Tong, and Zhang, Guofeng

Subjects

Computer Science - Computer Vision and Pattern Recognition, Computer Science - Artificial Intelligence

Abstract

Neural implicit reconstruction via volume rendering has demonstrated its effectiveness in recovering dense 3D surfaces. However, it is non-trivial to simultaneously recover meticulous geometry and preserve smoothness across regions with differing characteristics. To address this issue, previous methods typically employ geometric priors, which are often constrained by the performance of the prior models. In this paper, we propose ND-SDF, which learns a Normal Deflection field to represent the angular deviation between the scene normal and the prior normal. Unlike previous methods that uniformly apply geometric priors on all samples, introducing significant bias in accuracy, our proposed normal deflection field dynamically learns and adapts the utilization of samples based on their specific characteristics, thereby improving both the accuracy and effectiveness of the model. Our method not only obtains smooth weakly textured regions such as walls and floors but also preserves the geometric details of complex structures. In addition, we introduce a novel ray sampling strategy based on the deflection angle to facilitate the unbiased rendering process, which significantly improves the quality and accuracy of intricate surfaces, especially on thin structures. Consistent improvements on various challenging datasets demonstrate the superiority of our method.

Published

2024

42. Rank and Align: Towards Effective Source-free Graph Domain Adaptation

Author

Luo, Junyu, Xiao, Zhiping, Wang, Yifan, Luo, Xiao, Yuan, Jingyang, Ju, Wei, Liu, Langechuan, and Zhang, Ming

Subjects

Computer Science - Machine Learning, Computer Science - Artificial Intelligence, Computer Science - Information Retrieval

Abstract

Graph neural networks (GNNs) have achieved impressive performance in graph domain adaptation. However, extensive source graphs could be unavailable in real-world scenarios due to privacy and storage concerns. To this end, we investigate an underexplored yet practical problem of source-free graph domain adaptation, which transfers knowledge from source models instead of source graphs to a target domain. To solve this problem, we introduce a novel GNN-based approach called Rank and Align (RNA), which ranks graph similarities with spectral seriation for robust semantics learning, and aligns inharmonic graphs with harmonic graphs which close to the source domain for subgraph extraction. In particular, to overcome label scarcity, we employ the spectral seriation algorithm to infer the robust pairwise rankings, which can guide semantic learning using a similarity learning objective. To depict distribution shifts, we utilize spectral clustering and the silhouette coefficient to detect harmonic graphs, which the source model can easily classify. To reduce potential domain discrepancy, we extract domain-invariant subgraphs from inharmonic graphs by an adversarial edge sampling process, which guides the invariant learning of GNNs. Extensive experiments on several benchmark datasets demonstrate the effectiveness of our proposed RNA., Comment: Published in IJCAI2024

Published

2024

43. NeuRodin: A Two-stage Framework for High-Fidelity Neural Surface Reconstruction

Author

Wang, Yifan, Huang, Di, Ye, Weicai, Zhang, Guofeng, Ouyang, Wanli, and He, Tong

Subjects

Computer Science - Computer Vision and Pattern Recognition, Computer Science - Artificial Intelligence

Abstract

Signed Distance Function (SDF)-based volume rendering has demonstrated significant capabilities in surface reconstruction. Although promising, SDF-based methods often fail to capture detailed geometric structures, resulting in visible defects. By comparing SDF-based volume rendering to density-based volume rendering, we identify two main factors within the SDF-based approach that degrade surface quality: SDF-to-density representation and geometric regularization. These factors introduce challenges that hinder the optimization of the SDF field. To address these issues, we introduce NeuRodin, a novel two-stage neural surface reconstruction framework that not only achieves high-fidelity surface reconstruction but also retains the flexible optimization characteristics of density-based methods. NeuRodin incorporates innovative strategies that facilitate transformation of arbitrary topologies and reduce artifacts associated with density bias. Extensive evaluations on the Tanks and Temples and ScanNet++ datasets demonstrate the superiority of NeuRodin, showing strong reconstruction capabilities for both indoor and outdoor environments using solely posed RGB captures. Project website: https://open3dvlab.github.io/NeuRodin/

Published

2024

44. Atomic Resolution Observations of Nanoparticle Surface Dynamics and Instabilities Enabled by Artificial Intelligence

Author

Crozier, Peter A., Leibovich, Matan, Haluai, Piyush, Tan, Mai, Thomas, Andrew M., Vincent, Joshua, Mohan, Sreyas, Morales, Adria Marcos, Kulkarni, Shreyas A., Matteson, David S., Wang, Yifan, and Fernandez-Granda, Carlos

Subjects

Condensed Matter - Materials Science

Abstract

Nanoparticle surface structural dynamics is believed to play a significant role in regulating functionalities such as diffusion, reactivity, and catalysis but the atomic-level processes are not well understood. Atomic resolution characterization of nanoparticle surface dynamics is challenging since it requires both high spatial and temporal resolution. Though ultrafast transmission electron microscopy (TEM) can achieve picosecond temporal resolution, it is limited to nanometer spatial resolution. On the other hand, with the high readout rate of new electron detectors, conventional TEM has the potential to visualize atomic structure with millisecond time resolutions. However, the need to limit electron dose rates to reduce beam damage yields millisecond images that are dominated by noise, obscuring structural details. Here we show that a newly developed unsupervised denoising framework based on artificial intelligence enables observations of metal nanoparticle surfaces with time resolutions down to 10 ms at moderate electron dose. On this timescale, we find that many nanoparticle surfaces continuously transition between ordered and disordered configurations. The associated stress fields can penetrate below the surface leading to defect formation and destabilization making the entire nanoparticle fluxional. Combining this unsupervised denoiser with electron microscopy greatly improves spatio-temporal characterization capabilities, opening a new window for future exploration of atomic-level structural dynamics in materials.

Published

2024

45. B2MAPO: A Batch-by-Batch Multi-Agent Policy Optimization to Balance Performance and Efficiency

Author

Zhang, Wenjing, Zhang, Wei, Hu, Wenqing, and Wang, Yifan

Subjects

Computer Science - Multiagent Systems

Abstract

Most multi-agent reinforcement learning approaches adopt two types of policy optimization methods that either update policy simultaneously or sequentially. Simultaneously updating policies of all agents introduces non-stationarity problem. Although sequentially updating policies agent-by-agent in an appropriate order improves policy performance, it is prone to low efficiency due to sequential execution, resulting in longer model training and execution time. Intuitively, partitioning policies of all agents according to their interdependence and updating joint policy batch-by-batch can effectively balance performance and efficiency. However, how to determine the optimal batch partition of policies and batch updating order are challenging problems. Firstly, a sequential batched policy updating scheme, B2MAPO (Batch by Batch Multi-Agent Policy Optimization), is proposed with a theoretical guarantee of the monotonic incrementally tightened bound. Secondly, a universal modulized plug-and-play B2MAPO hierarchical framework, which satisfies CTDE principle, is designed to conveniently integrate any MARL models to fully exploit and merge their merits, including policy optimality and inference efficiency. Next, a DAG-based B2MAPO algorithm is devised, which is a carefully designed implementation of B2MAPO framework. Comprehensive experimental results conducted on StarCraftII Multi-agent Challenge and Google Football Research demonstrate the performance of DAG-based B2MAPO algorithm outperforms baseline methods. Meanwhile, compared with A2PO, our algorithm reduces the model training and execution time by 60.4% and 78.7%, respectively.

Published

2024

46. DisenSemi: Semi-supervised Graph Classification via Disentangled Representation Learning

Author

Wang, Yifan, Luo, Xiao, Chen, Chong, Hua, Xian-Sheng, Zhang, Ming, and Ju, Wei

Subjects

Computer Science - Machine Learning, Computer Science - Artificial Intelligence, Computer Science - Information Retrieval, Computer Science - Social and Information Networks

Abstract

Graph classification is a critical task in numerous multimedia applications, where graphs are employed to represent diverse types of multimedia data, including images, videos, and social networks. Nevertheless, in real-world scenarios, labeled graph data can be limited or scarce. To address this issue, we focus on the problem of semi-supervised graph classification, which involves both supervised and unsupervised models learning from labeled and unlabeled data. In contrast to recent approaches that transfer the entire knowledge from the unsupervised model to the supervised one, we argue that an effective transfer should only retain the relevant semantics that align well with the supervised task. In this paper, we propose a novel framework named DisenSemi, which learns disentangled representation for semi-supervised graph classification. Specifically, a disentangled graph encoder is proposed to generate factor-wise graph representations for both supervised and unsupervised models. Then we train two models via supervised objective and mutual information (MI)-based constraints respectively. To ensure the meaningful transfer of knowledge from the unsupervised encoder to the supervised one, we further define an MI-based disentangled consistency regularization between two models and identify the corresponding rationale that aligns well with the current graph classification task. Experimental results on a range of publicly accessible datasets reveal the effectiveness of our DisenSemi., Comment: Accepted by IEEE Transactions on Neural Networks and Learning Systems (TNNLS 2024)

Published

2024

47. DeepCSNet: a deep learning method for predicting electron-impact doubly differential ionization cross sections

Author

Wang, Yifan and Zhong, Linlin

Subjects

Physics - Plasma Physics, Physics - Computational Physics

Abstract

Electron-impact ionization cross sections of atoms and molecules are essential for plasma modelling. However, experimentally determining the absolute cross sections is not easy, and ab initio calculations become computationally prohibitive as molecular complexity increases. Existing AI-based prediction methods suffer from limited data availability and poor generalization. To address these issues, we propose DeepCSNet, a deep learning approach designed to predict electron-impact ionization cross sections using limited training data. We present two configurations of DeepCSNet: one tailored for specific molecules and another for various molecules. Both configurations can typically achieve a relative L2 error less than 5%. The present numerical results, focusing on electron-impact doubly differential ionization cross sections, demonstrate DeepCSNet's generalization ability, predicting cross sections across a wide range of energies and incident angles. Additionally, DeepCSNet shows promising results in predicting cross sections for molecules not included in the training set, even large molecules with more than 10 constituent atoms, highlighting its potential for practical applications., Comment: 18 pages, 16 figures, 2 tables

Published

2024

48. Improvement of Sensitivity of Capacitive Micromachined Ultrasound Transducer

Author

Wang, Yifan and Liu, Yunfei

Subjects

Electrical Engineering and Systems Science - Signal Processing

Abstract

Capacitive Micromachined Ultrasonic Transducer (CMUT) has a wild range of applications in medical detecting and imaging fields. However, operating under self-generating-self-receiving (SGSR) method usually results in poor sensitivity. But the sensitivity cannot be improved simply by increasing the resonant frequency since the frequency of a specific kind of CMUT is designed for specific usage. In this paper, based on one specific type of CMUT, mechanical model is built and simulation analysis is demonstrated. A brand-new method one-generating-multiple-receiving (OGMR) is introduced and a special circuit model has been designed to improve the signal to thermal noise ratio. By increasing the number of receiving capacitors from 1 to 8, we increased the signal-noise ratio to 2.83 times., Comment: 6 pages, 18 figures

Published

2024

49. Deconvolving Complex Neuronal Networks into Interpretable Task-Specific Connectomes

Author

Wang, Yifan, Ravindra, Vikram, and Grama, Ananth

Subjects

Quantitative Biology - Neurons and Cognition, Computer Science - Machine Learning, Electrical Engineering and Systems Science - Image and Video Processing

Abstract

Task-specific functional MRI (fMRI) images provide excellent modalities for studying the neuronal basis of cognitive processes. We use fMRI data to formulate and solve the problem of deconvolving task-specific aggregate neuronal networks into a set of basic building blocks called canonical networks, to use these networks for functional characterization, and to characterize the physiological basis of these responses by mapping them to regions of the brain. Our results show excellent task-specificity of canonical networks, i.e., the expression of a small number of canonical networks can be used to accurately predict tasks; generalizability across cohorts, i.e., canonical networks are conserved across diverse populations, studies, and acquisition protocols; and that canonical networks have strong anatomical and physiological basis. From a methods perspective, the problem of identifying these canonical networks poses challenges rooted in the high dimensionality, small sample size, acquisition variability, and noise. Our deconvolution technique is based on non-negative matrix factorization (NMF) that identifies canonical networks as factors of a suitably constructed matrix. We demonstrate that our method scales to large datasets, yields stable and accurate factors, and is robust to noise., Comment: 9 pages, 5 figures

Published

2024

50. Cascade Reward Sampling for Efficient Decoding-Time Alignment

Author

Li, Bolian, Wang, Yifan, Grama, Ananth, and Zhang, Ruqi

Subjects

Computer Science - Computation and Language, Computer Science - Machine Learning, Statistics - Machine Learning

Abstract

Aligning large language models (LLMs) with human preferences is critical for their deployment. Recently, decoding-time alignment has emerged as an effective plug-and-play technique that requires no fine-tuning of model parameters. However, generating text that achieves both high reward and high likelihood remains a significant challenge. Existing methods often fail to generate high-reward text or incur substantial computational costs. In this paper, we propose Cascade Reward Sampling (CARDS) to address both issues, guaranteeing the generation of high-reward and high-likelihood text with significantly low costs. Based on our analysis of reward models (RMs) on incomplete text and our observation that high-reward prefixes induce high-reward complete text, we use rejection sampling to iteratively generate small semantic segments to form such prefixes. The segment length is dynamically determined by the predictive uncertainty of LLMs. This strategy guarantees desirable prefixes for subsequent generations and significantly reduces wasteful token re-generations and the number of reward model scoring. Our experiments demonstrate substantial gains in both generation efficiency and alignment ratings compared to the baselines, achieving five times faster text generation and 99\% win-ties in GPT-4/Claude-3 helpfulness evaluation.

Published

2024