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1,063 results on '"Ye, Wenjing"'

1. Parameter estimation of structural dynamics with neural operators enabled surrogate modeling

Author

Zhou, Mingyuan, Song, Haoze, Ye, Wenjing, Wang, Wei, and Lai, Zhilu

Subjects
Computer Science - Computational Engineering, Finance, and Science, Physics - Data Analysis, Statistics and Probability
Abstract

Parameter estimation generally involves inferring the values of mathematical models derived from first principles or expert knowledge, which is challenging for complex structural systems. In this work, we present a unified deep learning-based framework for parameterization, forward modeling, and inverse modeling of structural dynamics. The parameterization is flexible and can be user-defined, including physical and/or non-physical (customized) parameters. In forward modeling, we train a neural operator for response prediction -- forming a surrogate model, which leverages the defined system parameters and excitation forces as inputs. The inverse modeling focuses on estimating system parameters. In particular, the learned forward surrogate model (which is differentiable) is utilized for preliminary parameter estimation via gradient-based optimization; to further boost the parameter estimation, we introduce a neural refinement method to mitigate ill-posed problems, which often occur in the former. The framework's effectiveness is verified numerically and experimentally, in both interpolation and extrapolation cases, indicating its capability to capture intrinsic dynamics of structural systems from both forward and inverse perspectives. Moreover, the framework's flexibility is expected to support a wide range of applications, including surrogate modeling, structural identification, damage detection, and inverse design of structural systems.

Published
2024

4. Deep learning on tertiary lymphoid structures in hematoxylin-eosin predicts cancer prognosis and immunotherapy response

Author

Chen, Ziqiang, Wang, Xiaobing, Jin, Zelin, Li, Bosen, Jiang, Dongxian, Wang, Yanqiu, Jiang, Mengping, Zhang, Dandan, Yuan, Pei, Zhao, Yahui, Feng, Feiyue, Lin, Yicheng, Jiang, Liping, Wang, Chenxi, Meng, Weida, Ye, Wenjing, Wang, Jie, Qiu, Wenqing, Liu, Houbao, Huang, Dan, Hou, Yingyong, Wang, Xuefei, Jiao, Yuchen, Ying, Jianming, Liu, Zhihua, and Liu, Yun

Published
2024
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6. Research on Carbon Abatement Strategies of Airport Based on LEAP-Airport Model

Author

Ye, Wenjing, Wan, Lili, Shan, Zhanpeng, Lv, Yangyang, Chinese Society of Aeronautics and Astronautics, Chaari, Fakher, Series Editor, Gherardini, Francesco, Series Editor, Ivanov, Vitalii, Series Editor, Haddar, Mohamed, Series Editor, Cavas-Martínez, Francisco, Editorial Board Member, di Mare, Francesca, Editorial Board Member, Kwon, Young W., Editorial Board Member, Trojanowska, Justyna, Editorial Board Member, and Xu, Jinyang, Editorial Board Member

Published
2024
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9. An Adaptive and Scalable ANN-based Model-Order-Reduction Method for Large-Scale TO Designs

Author

Tan, Ren Kai, Qian, Chao, Xu, Dan, and Ye, Wenjing

Subjects
Computer Science - Machine Learning
Abstract

Topology Optimization (TO) provides a systematic approach for obtaining structure design with optimum performance of interest. However, the process requires numerical evaluation of objective function and constraints at each iteration, which is computational expensive especially for large-scale design. Deep learning-based models have been developed to accelerate the process either by acting as surrogate models replacing the simulation process, or completely replacing the optimization process. However, most of them require a large set of labelled training data, which are generated mostly through simulations. The data generation time scales rapidly with the design domain size, decreasing the efficiency of the method itself. Another major issue is the weak generalizability of most deep learning models. Most models are trained to work with the design problem similar to that used for data generation and require retraining if the design problem changes. In this work a scalable deep learning-based model-order-reduction method is proposed to accelerate large-scale TO process, by utilizing MapNet, a neural network which maps the field of interest from coarse-scale to fine-scale. The proposed method allows for each simulation of the TO process to be performed at a coarser mesh, thereby greatly reducing the total computational time. Moreover, by using domain fragmentation, the transferability of the MapNet is largely improved. Specifically, it has been demonstrated that the MapNet trained using data from one cantilever beam design with a specific loading condition can be directly applied to other structure design problems with different domain shapes, sizes, boundary and loading conditions., Comment: 27 pages, 24 figures

Published
2022

13. Allogeneic CD19-targeted CAR-T therapy in patients with severe myositis and systemic sclerosis

Author

Wang, Xiaobing, Wu, Xin, Tan, Binghe, Zhu, Liang, Zhang, Yi, Lin, Li, Xiao, Yi, Sun, An, Wan, Xinyi, Liu, Shiyuan, Liu, Yanfang, Ta, Na, Zhang, Hang, Song, Jialin, Li, Ting, Zhou, Ling, Yin, Jian, Ye, Lingying, Lu, Hongjuan, Hong, Jinwei, Cheng, Hui, Wang, Ping, Li, Weiqing, Chen, Jianfeng, Zhang, Jin, Luo, Jing, Huang, Miaozhen, Guo, Lehang, Pan, Xiaoming, Jin, Yi, Ye, Wenjing, Dai, Lie, Zhu, Jian, Sun, Lingyun, Zheng, Biao, Li, Dali, He, Yanran, Liu, Mingyao, Wu, Huaxiang, Du, Bing, and Xu, Huji

Published
2024
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27. An adaptive artificial neural network-based generative design method for layout designs

Author

Qian, Chao, Tan, Renkai, and Ye, Wenjing

Subjects
Computer Science - Machine Learning
Abstract

Layout designs are encountered in a variety of fields. For problems with many design degrees of freedom, efficiency of design methods becomes a major concern. In recent years, machine learning methods such as artificial neural networks have been used increasingly to speed up the design process. A main issue of many such approaches is the need for a large corpus of training data that are generated using high-dimensional simulations. The high computational cost associated with training data generation largely diminishes the efficiency gained by using machine learning methods. In this work, an adaptive artificial neural network-based generative design approach is proposed and developed. This method uses a generative adversarial network to generate design candidates and thus the number of design variables is greatly reduced. To speed up the evaluation of the objective function, a convolutional neural network is constructed as the surrogate model for function evaluation. The inverse design is carried out using the genetic algorithm in conjunction with two neural networks. A novel adaptive learning and optimization strategy is proposed, which allows the design space to be effectively explored for the search for optimal solutions. As such the number of training data needed is greatly reduced. The performance of the proposed design method is demonstrated on two heat source layout design problems. In both problems, optimal designs have been obtained. Compared with several existing approaches, the proposed approach has the best performance in terms of accuracy and efficiency.

Published
2021

29. Accelerating gradient-based topology optimization design with dual-model neural networks

Author

Qian, Chao and Ye, Wenjing

Subjects
Computer Science - Artificial Intelligence
Abstract

Topology optimization (TO) is a common technique used in free-form designs. However, conventional TO-based design approaches suffer from high computational cost due to the need for repetitive forward calculations and/or sensitivity analysis, which are typically done using high-dimensional simulations such as Finite Element Analysis (FEA). In this work, neural networks are used as efficient surrogate models for forward and sensitivity calculations in order to greatly accelerate the design process of topology optimization. To improve the accuracy of sensitivity analyses, dual-model neural networks that are trained with both forward and sensitivity data are constructed and are integrated into the Solid Isotropic Material with Penalization (SIMP) method to replace FEA. The performance of the accelerated SIMP method is demonstrated on two benchmark design problems namely minimum compliance design and metamaterial design. The efficiency gained in the problem with size of 64x64 is 137 times in forward calculation and 74 times in sensitivity analysis. In addition, effective data generation methods suitable for TO designs are investigated and developed, which lead to a great saving in training time. In both benchmark design problems, a design accuracy of 95% can be achieved with only around 2000 training data.

Published
2020

33. Boundary Integral Analysis for the Non-homogeneous 3D Stokes Equation

Author

Gray, L. J., Jakowski, Jas, Moore, M. N. J., and Ye, Wenjing

Subjects
Mathematics - Numerical Analysis
Abstract

A regular-grid volume-integration algorithm is developed for the non-homogeneous 3D Stokes equation. Based upon the observation that the Stokeslet ${\mathcal U}$ is the Laplacian of a function ${\mathcal H}$, the volume integral is reformulated as a simple boundary integral, plus a remainder domain integral. The modified source term in this remainder integral is everywhere zero on the boundary and can therefore be continuously extended as zero to a regular grid covering the domain. The volume integral can then be evaluated on the grid. Applying this method to the Navier-Stokes equations will require obtaining velocity gradients, and thus an efficient algorithm for post-processing these derivatives is also discussed. To validate the numerical implementation, test results employing a linear element Galerkin approximation are presented.

Published
2018

37. Deep learning based inverse method for layout design

Author

Zhang, Yujie and Ye, Wenjing

Subjects
Electrical Engineering and Systems Science - Signal Processing, Computer Science - Learning, Statistics - Machine Learning
Abstract

Layout design with complex constraints is a challenging problem to solve due to the non-uniqueness of the solution and the difficulties in incorporating the constraints into the conventional optimization-based methods. In this paper, we propose a design method based on the recently developed machine learning technique, Variational Autoencoder (VAE). We utilize the learning capability of the VAE to learn the constraints and the generative capability of the VAE to generate design candidates that automatically satisfy all the constraints. As such, no constraints need to be imposed during the design stage. In addition, we show that the VAE network is also capable of learning the underlying physics of the design problem, leading to an efficient design tool that does not need any physical simulation once the network is constructed. We demonstrated the performance of the method on two cases: inverse design of surface diffusion induced morphology change and mask design for optical microlithography.

Published
2018

42. Research on the Green Transition Path of Airport Development under the Mechanism of Tripartite Evolutionary Game Model.

Author

Lv, Yangyang, Wan, Lili, Zhang, Naizhong, Wang, Zhan, Tian, Yong, and Ye, Wenjing

Abstract

Since existing studies primarily explore green development measures from the static perspective of a single airport stakeholder, this paper constructs an evolutionary game model to analyze the strategic choices of three key stakeholders: airport authorities, third-party organizations, and government departments, based on evolutionary game theory. By solving the stable strategy of the tripartite evolution using the Jacobian matrix, the green transition of airport development can be divided into three stages: "initiation", "development", and "maturity", allowing for the exploration of key factors influencing the green transition of airport development. A simulation analysis is conducted based on real Guangzhou Baiyun International Airport data. The results indicate that the tripartite evolutionary game strategy is stable at E 4 (0 , 0 , 1) and the green transition of Baiyun Airport remains in the development stage. By improving the reward and punishment mechanisms of government departments, the evolutionary game strategy can be stabilized at E 8 (1 , 1 , 1) , promoting the green transition of airport development toward the mature stage. By adjusting the game parameters, the dynamic process of green transition in airports at different levels of development and under varying regulatory environments can be effectively captured, supporting the precise formulation of corresponding policies. [ABSTRACT FROM AUTHOR]

Published
2024
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47. CNCR-YOLO: A Comprehensive Optimization Strategy for Small-Target Defect Detection in Injection-Molded Parts

Author

Jiang, Fei, Ye, Wenjing, Lu, Peicong, Zhang, Shaohui, Wu, Zhaoqian, and Zhu, Haifei

Abstract

Defect detection in injection-molded parts is crucial for quality control in industrial manufacturing. However, it poses challenges due to process complexity, particularly for detecting small defects. To address this challenge, an efficient detection algorithm named CNCR-you only look once (YOLO) is proposed. First, to both improve the quality and quantity of injection-molded parts defect samples, Style-GANv3 data generation and traditional augmentation method are utilized as preprocessing. Moreover, inspired by YOLOv5, CNCR-YOLO combines the strength of normalized Wasserstein distance and complete intersection over union (IoU) metrics together to raise the CI-normalized Gaussian Wasserstein Distance (NWD) loss function for better optimization. Finally, the convolutional block attention module (CBAM) attention mechanism and the Res2net module are embedded into YOLOv5 to enhance the ability of target feature learning and multiscale feature extraction. The experimental results demonstrate that the proposed method outperforms the other algorithms, achieving an improvement of 1.5% in mean average precision (MAP), notably 2.3% for small-target defects. In addition, its generality and robustness are further validated on an industrial printed circuit board (PCB) defect detection dataset.

Published
2024
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49. In-situ sparse-array imaging for through-thickness cracks in plates with A0 Lamb waves and an efficient waveform inversion algorithm

Author

Zhang, Shengyuan, Yang, Jinglei, Ye, Wenjing, Zhang, Shengyuan, Yang, Jinglei, and Ye, Wenjing

Abstract

Structural health monitoring (SHM) requires efficient online crack detection and characterization to prevent structural failures, which mainly arise from fatigue cracks. Existing solutions for crack characterization involve analyzing sensed wave signals directly, but these approaches usually require onerous steps or many sensors to obtain sufficient and clear wave packets. An alternative strategy is a model-based inversion, which takes the full waveform into consideration and does not require analysis on a single wave packet. This approach can achieve accurate characterization with fewer sensors and simpler implementation. We propose an efficient model based on the Huygens’ principle and the no-mode-conversion property of the A0 mode Lamb waves to meet the requirements of online monitoring. We then verify the proposed model-based crack imaging method through simulation and experiments on smooth and rough cracks. The proposed method is easy, cheap, and efficient, making it a desirable option for SHM tasks. © 2024 Elsevier B.V.

Published
2024

50. Learning Stiffness Tensors in Self-Activated Solids via a Local Rule

Author

Tang, Yuxuan, Ye, Wenjing, Jia, Jingjing, Chen, Yangyang, Tang, Yuxuan, Ye, Wenjing, Jia, Jingjing, and Chen, Yangyang

Abstract

Mechanical metamaterials are often designed with particular properties for specific load-bearing functions. Alternatively, this study aims to create a class of active lattice metamaterials, dubbed self-activated solids, that can learn desired stiffness tensors from the elastic deformations they experienced, a crucial feature to improve the performance, efficiency, and functionality of materials. Artificial adaptive matters that combine sensory, control, and actuation elements can offer appealing solutions. However, challenges still remain: The designs will rely on accurate off-line and global computations, as well as intricate coordination among individual elements. Here, a simple online and local learning strategy is initiated based on contrastive Hebbian learning to gradually guide self-activated solids to possess sought-after stiffness tensors autonomously and reversibly. During learning, the bond stiffness of the active lattice varies depending only on its local strain. The numerical tests show that the self-activated solid can not only achieve the desired bulk, shear, and coupling moduli but also manifest uni-mode and bi-mode extremal materials by itself after experiencing the corresponding elastic deformations. Further, the self-activated solid can also achieve the desired time-varying moduli when exposed to temporally different loads. The design is applicable to any lattice geometries and is resistant to damage and instabilities. The material design approach and the physical learning strategy suggested can benefit the design of autonomous materials, physical learning machines, and adaptive robots.

Published
2024

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